Operating Manual For The R&S FSL R&S/R&S Operating_Manual_FSL_v11 V11

User Manual: R&S/R&S Operating_Manual_FSL_v11

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Operating Manual for the R&S FSL

1300.2519.12-11

Operating Manual

Spectrum Analyzer

R&SFSL3

1300.2502K03

1300.2502K13

R&SFSL6

1300.2502K06

1300.2502K16

R&SFSL18

1300.2502K18

1300.2502K28

Test and Measurement

Throughout this manual, the Spectrum Analyzer R&S®FSL is abbreviated as R&S FSL.

R&S®is a registered trademark of Rohde & Schwarz GmbH & Co. KG

Trade names are trademarks of the owners

Grouped Safety Messages

Make sure to read through and observe the following safety instructions!

All plants and locations of the Rohde & Schwarz group of companies make every effort to keep the safety

standard of our products up to date and to offer our customers the highest possible degree of safety. Our

products and the auxiliary equipment required for them are designed and tested in accordance with the

relevant safety standards. Compliance with these standards is continuously monitored by our quality

assurance system. The product described here has been designed and tested in accordance with the EC

Certificate of Conformity and has left the manufacturer’s plant in a condition fully complying with safety

standards. To maintain this condition and to ensure safe operation, observe all instructions and warnings

provided in this manual. If you have any questions regarding these safety instructions, the Rohde &

Schwarz group of companies will be happy to answer them.

Furthermore, it is your responsibility to use the product in an appropriate manner. This product is designed

for use solely in industrial and laboratory environments or, if expressly permitted, also in the field and must

not be used in any way that may cause personal injury or property damage. You are responsible if the

product is used for an intention other than its designated purpose or in disregard of the manufacturer's

instructions. The manufacturer shall assume no responsibility for such use of the product.

The product is used for its designated purpose if it is used in accordance with its product documentation

and within its performance limits (see data sheet, documentation, the following safety instructions). Using

the product requires technical skills and a basic knowledge of English. It is therefore essential that only

skilled and specialized staff or thoroughly trained personnel with the required skills be allowed to use the

product. If personal safety gear is required for using Rohde & Schwarz products, this will be indicated at

the appropriate place in the product documentation. Keep the basic safety instructions and the product

documentation in a safe place and pass them on to the subsequent users.

Symbols and safety labels

Observe

product

documentation

Weight

indication for

units >18 kg

Danger of

electric

shock

Warning!

Hot

surface

PE terminal Ground Ground

terminal

Attention!

Electrostatic

sensitive devices

Supply

voltage

ON/OFF

Standby

indication

Direct

current

(DC)

Alternating

current (AC)

Direct/alternating

current (DC/AC)

Device fully protected

by double/reinforced

insulation

Observing the safety instructions will help prevent personal injury or damage of any kind caused by

dangerous situations. Therefore, carefully read through and adhere to the following safety instructions

before putting the product into operation. It is also absolutely essential to observe the additional safety

instructions on personal safety that appear in relevant parts of the product documentation. In these safety

instructions, the word "product" refers to all merchandise sold and distributed by the Rohde & Schwarz

group of companies, including instruments, systems and all accessories.

1171.0000.42-04.00 Sheet 1

Grouped Safety Messages

Tags and their meaning

DANGER DANGER indicates a hazardous situation which, if not avoided, will result in death or

serious injury.

WARNING WARNING indicates a hazardous situation which, if not avoided, could result in death or

serious injury.

CAUTION CAUTION indicates a hazardous situation which, if not avoided, may result in minor or

moderate injury.

NOTICE NOTICE indicates a property damage message.

In the product documentation, the word ATTENTION is used synonymously.

These tags are in accordance with the standard definition for civil applications in the European Economic

Area. Definitions that deviate from the standard definition may also exist in other economic areas or

military applications. It is therefore essential to make sure that the tags described here are always used

only in connection with the related product documentation and the related product. The use of tags in

connection with unrelated products or documentation can result in misinterpretation and thus contribute to

personal injury or material damage.

Basic safety instructions

1. The product may be operated only under the

operating conditions and in the positions

specified by the manufacturer. Its ventilation

must not be obstructed during operation.

Unless otherwise specified, the following

requirements apply to Rohde & Schwarz

products:

prescribed operating position is always with

the housing floor facing down, IP protection

2X, pollution severity 2, overvoltage category

2, use only in enclosed spaces, max.

operation altitude 2000 m above sea level,

max. transport altitude 4500 m above sea

level.

A tolerance of ±10% shall apply to the

nominal voltage and of ±5% to the nominal

frequency.

Rohde & Schwarz. Only original parts may

be used for replacing parts relevant to safety

(e.g. power switches, power transformers,

fuses). A safety test must always be

performed after parts relevant to safety have

been replaced (visual inspection, PE

conductor test, insulation resistance

measurement, leakage current

measurement, functional test).

3. As with all industrially manufactured goods,

the use of substances that induce an allergic

reaction (allergens, e.g. nickel) such as

aluminum cannot be generally excluded. If

you develop an allergic reaction (such as a

skin rash, frequent sneezing, red eyes or

respiratory difficulties), consult a physician

immediately to determine the cause.

2. Applicable local or national safety

regulations and rules for the prevention of

accidents must be observed in all work

performed. The product may be opened only

by authorized, specially trained personnel.

Prior to performing any work on the product

or opening the product, the product must be

disconnected from the supply network. Any

adjustments, replacements of parts,

maintenance or repair must be carried out

only by technical personnel authorized by

4. If products/components are mechanically

and/or thermically processed in a manner

that goes beyond their intended use,

hazardous substances (heavy-metal dust

such as lead, beryllium, nickel) may be

released. For this reason, the product may

only be disassembled, e.g. for disposal

purposes, by specially trained personnel.

Improper disassembly may be hazardous to

your health. National waste disposal

regulations must be observed.

1171.0000.42-04.00 Sheet 2

Grouped Safety Messages

of the connecting cable is regarded as the

disconnecting device. In such cases, it must

be ensured that the power plug is easily

reachable and accessible at all times

(corresponding to the length of connecting

cable, approx. 2 m). Functional or electronic

switches are not suitable for providing

disconnection from the AC supply. If

products without power switches are

integrated in racks or systems, a

disconnecting device must be provided at

the system level.

5. If handling the product yields hazardous

substances or fuels that must be disposed of

in a special way, e.g. coolants or engine oils

that must be replenished regularly, the safety

instructions of the manufacturer of the

hazardous substances or fuels and the

applicable regional waste disposal

regulations must be observed. Also observe

the relevant safety instructions in the product

documentation.

6. Depending on the function, certain products

such as RF radio equipment can produce an

elevated level of electromagnetic radiation.

Considering that unborn life requires

increased protection, pregnant women

should be protected by appropriate

measures. Persons with pacemakers may

also be endangered by electromagnetic

radiation. The employer/operator is required

to assess workplaces where there is a

special risk of exposure to radiation and, if

necessary, take measures to avert the

danger.

12. Never use the product if the power cable is

damaged. Check the power cable on a

regular basis to ensure that it is in proper

operating condition. By taking appropriate

safety measures and carefully laying the

power cable, ensure that the cable cannot be

damaged and that no one can be hurt by e.g.

tripping over the cable or suffering an electric

shock.

13. The product may be operated only from

TN/TT supply networks fused with max. 16 A

(higher fuse only after consulting with the

Rohde & Schwarz group of companies).

7. Operating the products requires special

training and intense concentration. Make

certain that persons who use the products

are physically, mentally and emotionally fit

enough to handle operating the products;

otherwise injuries or material damage may

occur. It is the responsibility of the employer

to select suitable personnel for operating the

products.

14. Do not insert the plug into sockets that are

dusty or dirty. Insert the plug firmly and all

the way into the socket. Otherwise, this can

result in sparks, fire and/or injuries.

15. Do not overload any sockets, extension

cords or connector strips; doing so can

cause fire or electric shocks.

8. Prior to switching on the product, it must be

ensured that the nominal voltage setting on

the product matches the nominal voltage of

the AC supply network. If a different voltage

is to be set, the power fuse of the product

may have to be changed accordingly.

16. For measurements in circuits with voltages

Vrms > 30 V, suitable measures (e.g.

appropriate measuring equipment, fusing,

current limiting, electrical separation,

insulation) should be taken to avoid any

hazards.

9. In the case of products of safety class I with

movable power cord and connector,

operation is permitted only on sockets with

earthing contact and protective earth

connection.

17. Ensure that the connections with information

technology equipment comply with IEC

950/EN 60950.

18. Unless expressly permitted, never remove

the cover or any part of the housing while the

product is in operation. Doing so will expose

circuits and components and can lead to

injuries, fire or damage to the product.

10. Intentionally breaking the protective earth

connection either in the feed line or in the

product itself is not permitted. Doing so can

result in the danger of an electric shock from

the product. If extension cords or connector

strips are implemented, they must be

checked on a regular basis to ensure that

they are safe to use.

19. If a product is to be permanently installed,

the connection between the PE terminal on

site and the product's PE conductor must be

made first before any other connection is

made. The product may be installed and

connected only by a license electrician.

11. If the product has no power switch for

disconnection from the AC supply, the plug

1171.0000.42-04.00 Sheet 3

Grouped Safety Messages

20. For permanently installed equipment without

built-in fuses, circuit breakers or similar

protective devices, the supply circuit must be

fused in such a way that suitable protection

is provided for users and products.

21. Do not insert any objects into the openings in

the housing that are not designed for this

purpose. Never pour any liquids onto or into

the housing. This can cause short circuits

inside the product and/or electric shocks, fire

or injuries.

22. Use suitable overvoltage protection to

ensure that no overvoltage (such as that

caused by a thunderstorm) can reach the

product. Otherwise the operating personnel

will be endangered by electric shocks.

23. Rohde & Schwarz products are not protected

against penetration of liquids, unless

otherwise specified (see also safety

instruction 1.). If this is not taken into

account, there exists the danger of electric

shock for the user or damage to the product,

which can also lead to personal injury.

24. Never use the product under conditions in

which condensation has formed or can form

in or on the product, e.g. if the product was

moved from a cold to a warm environment.

25. Do not close any slots or openings on the

product, since they are necessary for

ventilation and prevent the product from

overheating. Do not place the product on soft

surfaces such as sofas or rugs or inside a

closed housing, unless this is well ventilated.

26. Do not place the product on heat-generating

devices such as radiators or fan heaters.

The temperature of the environment must

not exceed the maximum temperature

specified in the data sheet.

27. Batteries and storage batteries must not be

exposed to high temperatures or fire. Keep

batteries and storage batteries away from

children. Do not short-circuit batteries and

storage batteries.

If batteries or storage batteries are

improperly replaced, this can cause an

explosion (warning: lithium cells). Replace

the battery or storage battery only with the

matching Rohde & Schwarz type (see spare

parts list). Batteries and storage batteries

must be recycled and kept separate from

residual waste. Batteries and storage

batteries that contain lead, mercury or

cadmium are hazardous waste. Observe the

national regulations regarding waste

disposal and recycling.

28. Please be aware that in the event of a fire,

toxic substances (gases, liquids etc.) that

may be hazardous to your health may

escape from the product.

29. The product can be very heavy. Be careful

when moving it to avoid back or other

physical injuries.

30. Do not place the product on surfaces,

vehicles, cabinets or tables that for reasons

of weight or stability are unsuitable for this

purpose. Always follow the manufacturer's

installation instructions when installing the

product and fastening it to objects or

structures (e.g. walls and shelves).

31. Handles on the products are designed

exclusively for personnel to hold or carry the

product. It is therefore not permissible to use

handles for fastening the product to or on

means of transport such as cranes, fork lifts,

wagons, etc. The user is responsible for

securely fastening the products to or on the

means of transport and for observing the

safety regulations of the manufacturer of the

means of transport. Noncompliance can

result in personal injury or material damage.

32. If you use the product in a vehicle, it is the

sole responsibility of the driver to drive the

vehicle safely. Adequately secure the

product in the vehicle to prevent injuries or

other damage in the event of an accident.

Never use the product in a moving vehicle if

doing so could distract the driver of the

vehicle. The driver is always responsible for

the safety of the vehicle. The manufacturer

assumes no responsibility for accidents or

collisions.

33. If a laser product (e.g. a CD/DVD drive) is

integrated in a Rohde & Schwarz product, do

not use any other settings or functions than

those described in the product documen-

tation. Otherwise this may be hazardous to

your health, since the laser beam can cause

irreversible damage to your eyes. Never try

to take such products apart, and never look

into the laser beam.

34. Prior to cleaning, disconnect the product

from the AC supply. Use a soft, non-linting

cloth to clean the product. Never use

chemical cleaning agents such as alcohol,

acetone or diluent for cellulose lacquers.

1171.0000.42-04.00 Sheet 4

Informaciones elementales de seguridad

¡Es imprescindible leer y observar las siguientes instrucciones e informaciones

de seguridad!

El principio del grupo de empresas Rohde & Schwarz consiste en tener nuestros productos siempre al día

con los estándares de seguridad y de ofrecer a nuestros clientes el máximo grado de seguridad. Nuestros

productos y todos los equipos adicionales son siempre fabricados y examinados según las normas de

seguridad vigentes. Nuestra sección de gestión de la seguridad de calidad controla constantemente que

sean cumplidas estas normas. El presente producto ha sido fabricado y examinado según el comprobante

de conformidad adjunto según las normas de la CE y ha salido de nuestra planta en estado impecable

según los estándares técnicos de seguridad. Para poder preservar este estado y garantizar un

funcionamiento libre de peligros, el usuario deberá atenerse a todas las indicaciones, informaciones de

seguridad y notas de alerta. El grupo de empresas Rohde & Schwarz está siempre a su disposición en

caso de que tengan preguntas referentes a estas informaciones de seguridad.

Además queda en la responsabilidad del usuario utilizar el producto en la forma debida. Este producto

está destinado exclusivamente al uso en la industria y el laboratorio o, si ha sido expresamente

autorizado, para aplicaciones de campo y de ninguna manera deberá ser utilizado de modo que alguna

persona/cosa pueda sufrir daño. El uso del producto fuera de sus fines definidos o despreciando las

informaciones de seguridad del fabricante queda en la responsabilidad del usuario. El fabricante no se

hace en ninguna forma responsable de consecuencias a causa del mal uso del producto.

Se parte del uso correcto del producto para los fines definidos si el producto es utilizado dentro de las

instrucciones de la correspondiente documentación de producto y dentro del margen de rendimiento

definido (ver hoja de datos, documentación, informaciones de seguridad que siguen). El uso del producto

hace necesarios conocimientos profundos y conocimientos básicas del idioma inglés. Por eso se debe

tener en cuenta que el producto sólo pueda ser operado por personal especializado o personas

minuciosamente instruidas con las capacidades correspondientes. Si fuera necesaria indumentaria de

seguridad para el uso de productos de R&S, encontrará la información debida en la documentación del

producto en el capítulo correspondiente. Guarde bien las informaciones de seguridad elementales, así

como la documentación del producto y entréguela a usuarios posteriores.

Símbolos y definiciones de seguridad

Ver

documen-

tación de

producto

Informaciones

para

maquinaria

con un peso

de > 18kg

Peligro de

golpe de

corriente

¡Advertencia!

Superficie

caliente

Conexión a

conductor

protector

Conexión

a tierra

Conexión

a masa

conductora

¡Cuidado!

Elementos de

construcción con

peligro de carga

electroestática

Potencia EN

MARCHA/PARADA

Indicación

Stand-by

Corriente

continua DC

Corriente

alterna AC

Corriente continua/-

alterna DC/AC

El aparato está protegido en

su totalidad por un

aislamiento de doble refuerzo

1171.0000.42-04.00 Sheet 5

Informaciones elementales de seguridad

Tener en cuenta las informaciones de seguridad sirve para tratar de evitar daños y peligros de toda clase.

Es necesario de que se lean las siguientes informaciones de seguridad concienzudamente y se tengan en

cuenta debidamente antes de la puesta en funcionamiento del producto. También deberán ser tenidas en

cuenta las informaciones para la protección de personas que encontrarán en el capítulo correspondiente

de la documentación de producto y que también son obligatorias de seguir. En las informaciones de

seguridad actuales hemos juntado todos los objetos vendidos por el grupo de empresas Rohde &

Schwarz bajo la denominación de „producto“, entre ellos también aparatos, instalaciones así como toda

clase de accesorios.

Palabras de señal y su significado

PELIGRO Identifica un peligro directo con riesgo elevado de provocar muerte o

lesiones de gravedad si no se toman las medidas oportunas.

ADVERTENCIA Identifica un posible peligro con riesgo medio de provocar muerte o

lesiones (de gravedad) si no se toman las medidas oportunas.

ATENCIÓN Identifica un peligro con riesgo reducido de provocar lesiones de

gravedad media o leve si no se toman las medidas oportunas.

AVISO Indica la posibilidad de utilizar mal el producto y a consecuencia

dañarlo.

En la documentación del producto se emplea de forma sinónima el

término CUIDADO.

Las palabras de señal corresponden a la definición habitual para aplicaciones civiles en el área

económica europea. Pueden existir definiciones diferentes a esta definición en otras áreas económicas o

en aplicaciones militares. Por eso se deberá tener en cuenta que las palabras de señal aquí descritas

sean utilizadas siempre solamente en combinación con la correspondiente documentación de producto y

solamente en combinación con el producto correspondiente. La utilización de las palabras de señal en

combinación con productos o documentaciones que no les correspondan puede llevar a

malinterpretaciones y tener por consecuencia daños en personas u objetos.

Informaciones de seguridad elementales

trabajo y de prevención de accidentes. El

producto solamente debe de ser abierto por

personal especializado autorizado. Antes de

efectuar trabajos en el producto o abrirlo

deberá este ser desconectado de la corriente.

El ajuste, el cambio de partes, la manutención

y la reparación deberán ser solamente

efectuadas por electricistas autorizados por

R&S. Si se reponen partes con importancia

para los aspectos de seguridad (por ejemplo

el enchufe, los transformadores o los fusibles),

solamente podrán ser sustituidos por partes

originales. Después de cada recambio de

partes elementales para la seguridad deberá

ser efectuado un control de seguridad (control

a primera vista, control de conductor protector,

medición de resistencia de aislamiento,

medición de la corriente conductora, control

de funcionamiento).

1. El producto solamente debe ser utilizado

según lo indicado por el fabricante referente a

la situación y posición de funcionamiento sin

que se obstruya la ventilación. Si no se

convino de otra manera, es para los productos

R&S válido lo que sigue:

como posición de funcionamiento se define

por principio la posición con el suelo de la caja

para abajo, modo de protección IP 2X, grado

de suciedad 2, categoría de sobrecarga

eléctrica 2, utilizar solamente en estancias

interiores, utilización hasta 2000 m sobre el

nivel del mar, transporte hasta 4.500 m sobre

el nivel del mar.

Se aplicará una tolerancia de ±10% sobre el

voltaje nominal y de ±5% sobre la frecuencia

nominal.

2. En todos los trabajos deberán ser tenidas en

cuenta las normas locales de seguridad de

1171.0000.42-04.00 Sheet 6

Informaciones elementales de seguridad

3. Como en todo producto de fabricación

industrial no puede ser excluido en general de

que se produzcan al usarlo elementos que

puedan generar alergias, los llamados

elementos alergénicos (por ejemplo el

níquel). Si se producieran en el trato con

productos R&S reacciones alérgicas, como

por ejemplo urticaria, estornudos frecuentes,

irritación de la conjuntiva o dificultades al

respirar, se deberá consultar inmediatamente

a un médico para averiguar los motivos de

estas reacciones.

4. Si productos / elementos de construcción son

tratados fuera del funcionamiento definido de

forma mecánica o térmica, pueden generarse

elementos peligrosos (polvos de sustancia de

metales pesados como por ejemplo plomo,

berilio, níquel). La partición elemental del

producto, como por ejemplo sucede en el

tratamiento de materias residuales, debe de

ser efectuada solamente por personal

especializado para estos tratamientos. La

partición elemental efectuada

inadecuadamente puede generar daños para

la salud. Se deben tener en cuenta las

directivas nacionales referentes al tratamiento

de materias residuales.

5. En el caso de que se produjeran agentes de

peligro o combustibles en la aplicación del

producto que debieran de ser transferidos a

un tratamiento de materias residuales, como

por ejemplo agentes refrigerantes que deben

ser repuestos en periodos definidos, o aceites

para motores, deberán ser tenidas en cuenta

las prescripciones de seguridad del fabricante

de estos agentes de peligro o combustibles y

las regulaciones regionales para el tratamiento

de materias residuales. Cuiden también de

tener en cuenta en caso dado las

prescripciones de seguridad especiales en la

descripción del producto.

6. Ciertos productos, como por ejemplo las

instalaciones de radiocomunicación RF,

pueden a causa de su función natural, emitir

una radiación electromagnética aumentada.

En vista a la protección de la vida en

desarrollo deberían ser protegidas personas

embarazadas debidamente. También las

personas con un bypass pueden correr peligro

a causa de la radiación electromagnética.

El empresario/usuario está comprometido a

valorar y señalar áreas de trabajo en las que

se corra un riesgo aumentado de exposición a

radiaciones para evitar riesgos.

7. La utilización de los productos requiere

instrucciones especiales y una alta

concentración en el manejo. Debe de ponerse

por seguro de que las personas que manejen

los productos estén a la altura de los

requerimientos necesarios referente a sus

aptitudes físicas, psíquicas y emocionales, ya

que de otra manera no se pueden excluir

lesiones o daños de objetos. El empresario

lleva la responsabilidad de seleccionar el

personal usuario apto para el manejo de los

productos.

8. Antes de la puesta en marcha del producto se

deberá tener por seguro de que la tensión

preseleccionada en el producto equivalga a la

del la red de distribución. Si es necesario

cambiar la preselección de la tensión también

se deberán en caso dabo cambiar los fusibles

correspondientes del producto.

9. Productos de la clase de seguridad I con

alimentación móvil y enchufe individual de

producto solamente deberán ser conectados

para el funcionamiento a tomas de corriente

de contacto de seguridad y con conductor

protector conectado.

10. Queda prohibida toda clase de interrupción

intencionada del conductor protector, tanto en

la toma de corriente como en el mismo

producto. Puede tener como consecuencia el

peligro de golpe de corriente por el producto.

Si se utilizaran cables o enchufes de

extensión se deberá poner al seguro que es

controlado su estado técnico de seguridad.

11. Si el producto no está equipado con un

interruptor para desconectarlo de la red, se

deberá considerar el enchufe del cable de

distribución como interruptor. En estos casos

deberá asegurar de que el enchufe sea de

fácil acceso y nabejo (según la medida del

cable de distribución, aproximadamente 2 m).

Los interruptores de función o electrónicos no

son aptos para el corte de la red eléctrica. Si

los productos sin interruptor están integrados

en bastidores o instalaciones, se deberá

instalar el interruptor al nivel de la instalación.

1171.0000.42-04.00 Sheet 7

Informaciones elementales de seguridad

20. En caso de que los productos que son

instalados fijamente en un lugar sean sin

protector implementado, autointerruptor o

similares objetos de protección, el circuito de

suministro de corriente deberá estar protegido

de manera que usuarios y productos estén

suficientemente protegidos.

12. No utilice nunca el producto si está dañado el

cable eléctrico. Compruebe regularmente el

correcto estado de los cables de conexión a

red. Asegure a través de las medidas de

protección y de instalación adecuadas de que

el cable de eléctrico no pueda ser dañado o

de que nadie pueda ser dañado por él, por

ejemplo al tropezar o por un golpe de

corriente. 21. Por favor, no introduzca ningún objeto que no

esté destinado a ello en los orificios de la caja

del aparato. No vierta nunca ninguna clase de

líquidos sobre o en la caja. Esto puede

producir cortocircuitos en el producto y/o

puede causar golpes de corriente, fuego o

heridas.

13. Solamente está permitido el funcionamiento

en redes de distribución TN/TT aseguradas

con fusibles de como máximo 16 A (utilización

de fusibles de mayor amperaje sólo previa

consulta con el grupo de empresas Rohde &

Schwarz). 22. Asegúrese con la protección adecuada de que

no pueda originarse en el producto una

sobrecarga por ejemplo a causa de una

tormenta. Si no se verá el personal que lo

utilice expuesto al peligro de un golpe de

corriente.

14. Nunca conecte el enchufe en tomas de

corriente sucias o llenas de polvo. Introduzca

el enchufe por completo y fuertemente en la

toma de corriente. Si no tiene en

consideración estas indicaciones se arriesga a

que se originen chispas, fuego y/o heridas. 23. Los productos R&S no están protegidos contra

líquidos si no es que exista otra indicación, ver

también punto 1. Si no se tiene en cuenta esto

se arriesga el peligro de golpe de corriente

para el usuario o de daños en el producto lo

cual también puede llevar al peligro de

personas.

15. No sobrecargue las tomas de corriente, los

cables de extensión o los enchufes de

extensión ya que esto pudiera causar fuego o

golpes de corriente.

16. En las mediciones en circuitos de corriente

con una tensión de entrada de Ueff > 30 V se

deberá tomar las precauciones debidas para

impedir cualquier peligro (por ejemplo medios

de medición adecuados, seguros, limitación

de tensión, corte protector, aislamiento etc.).

24. No utilice el producto bajo condiciones en las

que pueda producirse y se hayan producido

líquidos de condensación en o dentro del

producto como por ejemplo cuando se

desplaza el producto de un lugar frío a un

lugar caliente.

17. En caso de conexión con aparatos de la

técnica informática se deberá tener en cuenta

que estos cumplan los requisitos del estándar

IEC950/EN60950.

25. Por favor no cierre ninguna ranura u orificio

del producto, ya que estas son necesarias

para la ventilación e impiden que el producto

se caliente demasiado. No pongan el producto

encima de materiales blandos como por

ejemplo sofás o alfombras o dentro de una

caja cerrada, si esta no está suficientemente

ventilada.

18. A menos que esté permitido expresamente, no

retire nunca la tapa ni componentes de la

carcasa mientras el producto esté en servicio.

Esto pone a descubierto los cables y

componentes eléctricos y puede causar

heridas, fuego o daños en el producto.

26. No ponga el producto sobre aparatos que

produzcan calor, como por ejemplo radiadores

o calentadores. La temperatura ambiental no

debe superar la temperatura máxima

especificada en la hoja de datos.

19. Si un producto es instalado fijamente en un

lugar, se deberá primero conectar el conductor

protector fijo con el conductor protector del

aparato antes de hacer cualquier otra

conexión. La instalación y la conexión deberán

ser efectuadas por un electricista

especializado.

1171.0000.42-04.00 Sheet 8

Informaciones elementales de seguridad

1171.0000.42-04.00 Sheet 9

27. Baterías y acumuladores no deben de ser

expuestos a temperaturas altas o al fuego.

Guardar baterías y acumuladores fuera del

alcance de los niños. No cortocircuitar

baterías ni acumuladores. Si las baterías o los

acumuladores no son cambiados con la

debida atención existirá peligro de explosión

(atención células de litio). Cambiar las

baterías o los acumuladores solamente por los

del tipo R&S correspondiente (ver lista de

piezas de recambio). Las baterías y

acumuladores deben reutilizarse y no deben

acceder a los vertederos. Las baterías y

acumuladores que contienen plomo, mercurio

o cadmio deben tratarse como residuos

especiales. Respete en esta relación las

normas nacionales de evacuación y reciclaje.

28. Por favor tengan en cuenta que en caso de un

incendio pueden desprenderse del producto

agentes venenosos (gases, líquidos etc.) que

pueden generar daños a la salud.

29. El producto puede poseer un peso elevado.

Muévalo con cuidado para evitar lesiones en

la espalda u otras partes corporales.

30. No sitúe el producto encima de superficies,

vehículos, estantes o mesas, que por sus

características de peso o de estabilidad no

sean aptas para él. Siga siempre las

instrucciones de instalación del fabricante

cuando instale y asegure el producto en

objetos o estructuras (por ejemplo paredes y

estantes).

31. Las asas instaladas en los productos sirven

solamente de ayuda para el manejo que

solamente está previsto para personas. Por

eso no está permitido utilizar las asas para la

sujeción en o sobre medios de transporte

como por ejemplo grúas, carretillas elevadoras

de horquilla, carros etc. El usuario es

responsable de que los productos sean

sujetados de forma segura a los medios de

transporte y de que las prescripciones de

seguridad del fabricante de los medios de

transporte sean observadas. En caso de que

no se tengan en cuenta pueden causarse

daños en personas y objetos.

32. Si llega a utilizar el producto dentro de un

vehículo, queda en la responsabilidad

absoluta del conductor que conducir el

vehículo de manera segura. Asegure el

producto dentro del vehículo debidamente

para evitar en caso de un accidente las

lesiones u otra clase de daños. No utilice

nunca el producto dentro de un vehículo en

movimiento si esto pudiera distraer al

conductor. Siempre queda en la

responsabilidad absoluta del conductor la

seguridad del vehículo. El fabricante no

asumirá ninguna clase de responsabilidad por

accidentes o colisiones.

33. Dado el caso de que esté integrado un

producto de láser en un producto R&S (por

ejemplo CD/DVD-ROM) no utilice otras

instalaciones o funciones que las descritas en

la documentación de producto. De otra

manera pondrá en peligro su salud, ya que el

rayo láser puede dañar irreversiblemente sus

ojos. Nunca trate de descomponer estos

productos. Nunca mire dentro del rayo láser.

34. Antes de proceder a la limpieza, desconecte el

producto de la red. Realice la limpieza con un

paño suave, que no se deshilache. No utilice

de ninguna manera agentes limpiadores

químicos como, por ejemplo, alcohol, acetona

o nitrodiluyente.

1171.0300.41 D/E/ESP/F-1

Kundeninformation zur Batterieverordnung (BattV)

Dieses Gerät enthält eine schadstoffhaltige Batterie. Diese darf nicht

mit dem Hausmüll entsorgt werden.

Nach Ende der Lebensdauer darf die Entsorgung nur über eine

Rohde&Schwarz-Kundendienststelle oder eine geeignete

Sammelstelle erfolgen.

Safety Regulations for Batteries (according to BattV)

This equipment houses a battery containing harmful substances that

must not be disposed of as normal household waste.

After its useful life, the battery may only be disposed of at a Rohde &

Schwarz service center or at a suitable depot.

Normas de Seguridad para Baterías (Según BattV)

Este equipo lleva una batería que contiene sustancias perjudiciales,

que no se debe desechar en los contenedores de basura

domésticos.

Después de la vida útil, la batería sólo se podrá eliminar en un

centro de servicio de Rohde & Schwarz o en un depósito apropiado.

Consignes de sécurité pour batteries (selon BattV)

Cet appareil est équipé d'une pile comprenant des substances

nocives. Ne jamais la jeter dans une poubelle pour ordures

ménagéres.

Une pile usagée doit uniquement être éliminée par un centre de

service client de Rohde & Schwarz ou peut être collectée pour être

traitée spécialement comme déchets dangereux.

1171.0200.52-01.01

Customer Information Regarding Product Disposal

The

German

Electrical

and

Electronic

Equipment

(ElektroG)

Act

implementation

the following

directives:

•

2002/96/EC

waste

electrical

and

electronic

equipment

(WEEE)

and

•

2002/95/EC

the

restriction

the

use

certain

hazardous

substances

lectrical

and

electronic

equipment

(RoHS).

Product

labeling

accordance

with

50419

Once

the

lifetime

aproduct

has

ended,

this

product

must

not

disposed

the standard

domestic

refuse.

Even

disposal

via

the

municipal

collection

points

for

waste electrical

and

electronic

equipment

not

permitted.

Rohde

&Schwarz

GmbH

&Co.

has

developed

adisposal

concept

for

the

environmental-friendly

disposal

recycling

waste

material

and

fully

assumes

its

obligation

aproducer

take

back

and

dispose

electrical

and

electronic

waste

in accordance

with

the

ElektroG

Act.

Please

contact

your

local

service

representative

dispose

the

product.

1171.0200.11-03.00

QUALITÄTSZERTIFIKAT

Sehr geehrter Kunde,

Sie haben sich für den Kauf eines

Rohde & Schwarz-Produktes ent-

schieden. Hiermit erhalten Sie ein

nach modernsten Fertigungsme-

thoden hergestelltes Produkt. Es

wurde nach den Regeln unseres

Managementsystems entwickelt,

gefertigt und geprüft.

Das Rohde & Schwarz Management-

system ist zertifiziert nach:

DIN EN ISO 9001:2000

DIN EN 9100:2003

DIN EN ISO 14001:2004

CERTIFICATE OF QUALITY

Dear Customer,

you have decided to buy a Rohde &

Schwarz product. You are thus as-

sured of receiving a product that is

manufactured using the most modern

methods available. This product was

developed, manufactured and tested

in compliance with our quality mana-

gement system standards.

The Rohde & Schwarz quality

management system is certified

according to:

DIN EN ISO 9001:2000

DIN EN 9100:2003

DIN EN ISO 14001:2004

CERTIFICAT DE QUALITÉ

Cher Client,

vous avez choisi d‘acheter un produit

Rohde & Schwarz. Vous disposez

donc d‘un produit fabriqué d‘après les

méthodes les plus avancées. Le

développement, la fabrication et les

tests respectent nos normes de ges-

tion qualité.

Le système de gestion qualité de

Rohde & Schwarz a été homologué

conformément aux normes:

DIN EN ISO 9001:2000

DIN EN 9100:2003

DIN EN ISO 14001:2004

PD 5213.8744.99

V 01.00

May 2007

1171.0200.22-03.00

Customer Support

Technical support – where and when you need it

For quick, expert help with any Rohde & Schwarz equipment, contact one of our Customer Support

Centers. A team of highly qualified engineers provides telephone support and will work with you to find a

solution to your query on any aspect of the operation, programming or applications of Rohde & Schwarz

equipment.

Up-to-date information and upgrades

To keep your instrument up-to-date and to be informed about new application notes related to your

instrument, please send an e-mail to the Customer Support Center stating your instrument and your wish.

We will take care that you will get the right information.

USA & Canada Monday to Friday (except US public holidays)

8:00 AM – 8:00 PM Eastern Standard Time (EST)

Tel. from USA 888-test-rsa (888-837-8772) (opt 2)

From outside USA +1 410 910 7800 (opt 2)

Fax +1 410 910 7801

E-mail CustomerSupport@rohde-schwarz.com

East Asia Monday to Friday (except Singaporean public holidays)

8:30 AM – 6:00 PM Singapore Time (SGT)

Tel. +65 6 513 0488

Fax +65 6 846 1090

E-mail CustomerSupport@rohde-schwarz.com

Rest of the World Monday to Friday (except German public holidays)

08:00 – 17:00 Central European Time (CET)

Tel. from Europe +49 (0) 180 512 42 42*

From outside Europe +49 89 4129 13776

Fax +49 (0) 89 41 29 637 78

E-mail CustomerSupport@rohde-schwarz.com

*0.14 €/Min within the German fixed-line telephone network, varying prices

for the mobile telephone network and in different countries.

1171.0200.42-02.00

Address List

Headquarters, Plants and Subsidiaries

Headquarters

ROHDE& SCHWARZ GmbH & Co. KG

Mühldorfstraße 15 · D-81671 München

P.O.Box 80 14 69 · D-81614 München

Plants

ROHDE&SCHWARZ Messgerätebau GmbH

Riedbachstraße 58 · D-87700 Memmingen

P.O.Box 16 52 · D-87686 Memmingen

ROHDE& SCHWARZ GmbH & Co. KG

Werk Teisnach

Kaikenrieder Straße 27 · D-94244 Teisnach

P.O.Box 11 49 · D-94240 Teisnach

ROHDE& SCHWARZ závod

Vimperk, s.r.o.

Location Spidrova 49

CZ-38501 Vimperk

ROHDE& SCHWARZ GmbH & Co. KG

Dienstleistungszentrum Köln

Graf-Zeppelin-Straße 18 · D-51147 Köln

P.O.Box 98 02 60 · D-51130 Köln

Subsidiaries

R&S BICK Mobilfunk GmbH

Fritz-Hahne-Str. 7 · D-31848 Bad Münder

P.O.Box 20 02 · D-31844 Bad Münder

ROHDE&SCHWARZ FTK GmbH

Wendenschloßstraße 168, Haus 28

D-12557 Berlin

ROHDE&SCHWARZ SIT GmbH

Am Studio 3

D-12489 Berlin

R&S Systems GmbH

Graf-Zeppelin-Straße 18

D-51147 Köln

GEDIS GmbH

Sophienblatt 100

D-24114 Kiel

HAMEG Instruments GmbH

Industriestraße 6

D-63533 Mainhausen

Locations Worldwide

Please refer to our homepage: www.rohde-schwarz.com

◆Sales Locations

◆Service Locations

◆National Websites

Phone +49 (89) 41 29-0

Fax +49 (89) 41 29-121 64

info.rs@rohde-schwarz.com

Phone +49 (83 31) 1 08-0

+49 (83 31) 1 08-1124

info.rsmb@rohde-schwarz.com

Phone +49 (99 23) 8 50-0

Fax +49 (99 23) 8 50-174

info.rsdts@rohde-schwarz.com

Phone +420 (388) 45 21 09

Fax +420 (388) 45 21 13

Phone +49 (22 03) 49-0

Fax +49 (22 03) 49 51-229

info.rsdc@rohde-schwarz.com

service.rsdc@rohde-schwarz.com

Phone +49 (50 42) 9 98-0

Fax +49 (50 42) 9 98-105

info.bick@rohde-schwarz.com

Phone +49 (30) 658 91-122

Fax +49 (30) 655 50-221

info.ftk@rohde-schwarz.com

Phone +49 (30) 658 84-0

Fax +49 (30) 658 84-183

info.sit@rohde-schwarz.com

Phone +49 (22 03) 49-5 23 25

Fax +49 (22 03) 49-5 23 36

info.rssys@rohde-schwarz.com

Phone +49 (431) 600 51-0

Fax +49 (431) 600 51-11

sales@gedis-online.de

Phone +49 (61 82) 800-0

Fax +49 (61 82) 800-100

info@hameg.de

R&S FSL Documentation Overview

1300.2519.12 0.1 E-11

Documentation Overview

The user documentation for the R&S FSL is divided as follows:

•Quick Start Guide

•Online Help

•Operating Manual

•Internet Site

•Service Manual

•Release Notes

Quick Start Guide

This manual is delivered with the instrument in printed form and in PDF format on the CD. It provides the

information needed to set up and start working with the instrument. Basic operations and basic measurements

are described. Also a brief introduction to remote control is given. The manual includes general information

(e.g. Safety Instructions) and the following chapters:

Chapter 1 Front and Rear Panel

Chapter 2 Putting into Operation

Chapter 3 Firmware Update and Installation of Firmware Options

Chapter 4 Basic Operations

Chapter 5 Basic Measurement Examples

Chapter 6 Brief Introduction to Remote Control

Appendix A Printer Interface

Appendix B LAN Interface

Online Help

The Online Help is part of the firmware. It provides a quick access to the description of the instrument functions

and the remote control commands. For information on other topics refer to the Quick Start Guide, Operating

Manual and Service Manual provided in PDF format on CD or in the Internet. For detailed information on how

to use the Online Help, refer to the chapter "Basic Operations" in the Quick Start Guide.

Operating Manual

This manual is a supplement to the Quick Start Guide and is available in PDF format on the CD delivered with

the instrument. To retain the familiar structure that applies to all operating manuals of Rohde&Schwarz Test &

Measurement instruments, the chapters 1 and 3 exist, but only in form of references to the corresponding

Quick Start Guide chapters.

Documentation Overview R&S FSL

1300.2519.12 0.2 E-11

In this manual, all instrument functions are described in detail. For additional information on default settings

and parameters, refer to the data sheets. The set of measurement examples in the Quick Start Guide is

expanded by more advanced measurement examples. In addition to the brief introduction to remote control in

the Quick Start Guide, a description of the commands and programming examples is given. Information on

maintenance, instrument interfaces and error messages is also provided.

The manual includes the following chapters:

Chapter 1 Putting into Operation, see Quick Start Guide chapters 1 and 2

Chapter 2 Advanced Measurement Examples

Chapter 3 Manual Operation, see Quick Start Guide chapter 4

Chapter 4 Instrument Functions

Chapter 5 Remote Control - Basics

Chapter 6 Remote Control - Commands

Chapter 7 Remote Control - Programming Examples

Chapter 8 Maintenance

Chapter 9 Error Messages

This manual is delivered with the instrument on CD only. The printed manual can be ordered from Rohde &

Schwarz GmbH & Co. KG.

Internet Site

The Internet site at: R&S FSL Spectrum Analyzer provides the most up to date information on the R&S FSL.

The current operating manual at a time is available as printable PDF file in the download area. Also provided

for download are firmware updates including the associated release notes, instrument drivers, current data

sheets and application notes.

Service Manual

This manual is available in PDF format on the CD delivered with the instrument. It informs on how to check

compliance with rated specifications, on instrument function, repair, troubleshooting and fault elimination. It

contains all information required for repairing the R&S FSL by the replacement of modules. The manual

includes the following chapters:

Chapter 1 Performance Test

Chapter 2 Adjustment

Chapter 3 Repair

Chapter 4 Software Update / Installing Options

Chapter 5 Documents

Release Notes

The release notes describe the installation of the firmware, new and modified functions, eliminated problems,

and last minute changes to the documentation. The corresponding firmware version is indicated on the title

page of the release notes. The current release notes are provided in the Internet.

R&S FSL Conventions Used in the Documentation

1300.2519.12 0.3 E-11

Conventions Used in the Documentation

To visualize important information quickly and to recognize information types faster, a few conventions has

been introduced. The following character formats are used to emphasize words:

Bold All names of graphical user interface elements as

dialog boxes, softkeys, lists, options, buttons etc.

All names of user interface elements on the front

and rear panel as keys, connectors etc.

Courier All remote commands (apart from headings, see

below)

Capital letters All key names (front panel or keyboard)

The description of a softkey (Operating Manual and Online Help) always starts with the softkey name, and is

followed by explaining text and one or more remote control commands framed by two lines. Each remote

command is placed in a single line.

The description of remote control commands (Operating Manual and Online Help) always starts with the

command itself, and is followed by explaining text including an example, the characteristics and the mode

(standard or only with certain options) framed by two grey lines. The remote commands consist of

abbreviations to accelerate the procedure. All parts of the command that have to be entered are in capital

letters, the rest is added in small letters to complete the words and transport their meaning.

R&S FSL Putting into Operation

1300.2519.12 1.1 E-11

1Putting into Operation

For details refer to the Quick Start Guide chapters 1, "Front and Rear Panel", and 2, "Preparing for

Use".

Putting into Operation R&S FSL

1300.2519.12 1.2 E-11

R&S FSL Advanced Measurement Examples

1300.2519.12 I-2.1 E-11

Contents of Chapter 2

2Advanced Measurement Examples ............................................................. 2.1

Test Setup .........................................................................................................................................2.2

Measurement of Harmonics ............................................................................................................2.2

High–Sensitivity Harmonics Measurements ...............................................................................2.4

Measuring the Spectra of Complex Signals ..................................................................................2.6

Separating Signals by Selecting an Appropriate Resolution Bandwidth ....................................2.6

Intermodulation Measurements ..................................................................................................2.7

Measurement example – Measuring the R&S FSL's intrinsic intermodulation...............2.9

Measuring Signals in the Vicinity of Noise ..................................................................................2.13

Measurement example – Measuring level at low S/N ratios.........................................2.14

Noise Measurements .....................................................................................................................2.17

Measuring Noise Power Density...............................................................................................2.17

Measurement example – Measuring the intrinsic noise power density of the R&S FSL at

1GHz and calculating the R&S FSL's noise figure ......................................................2.17

Measurement of Noise Power within a Transmission Channel ................................................2.19

Measurement example – Measuring the intrinsic noise of the R&S FSL at 1 GHz in a

1.23 MHz channel bandwidth with the channel power function....................................2.20

Measuring Phase Noise............................................................................................................2.23

Measurement example – Measuring the phase noise of a signal generator at a carrier

offset of 10 kHz .............................................................................................................2.23

Measurements on Modulated Signals ..........................................................................................2.25

Measuring Channel Power and Adjacent Channel Power .......................................................2.25

Measurement example 1 – ACPR measurement on an CDMA 2000 signal................2.26

Measurement example 2 – Measuring adjacent channel power of a W–CDMA uplink

signal.............................................................................................................................2.30

Amplitude Distribution Measurements......................................................................................2.33

Measurement example – Measuring the APD and CCDF of white noise generated by

the R&S FSL .................................................................................................................2.34

Bluetooth Measurements (Option K8)..........................................................................................2.36

Bluetooth Overview...................................................................................................................2.36

Bluetooth technical parameters ....................................................................................2.37

Power classes...............................................................................................................2.37

Structure of a Bluetooth data packet ............................................................................2.38

Supported Tests .......................................................................................................................2.38

Overview of Transmitter Tests..................................................................................................2.39

Functional Description – Block Diagram...................................................................................2.40

Bandwidths ...............................................................................................................................2.41

Measurement Filter (Meas Filter On)........................................................................................2.41

Oversampling............................................................................................................................2.42

Determining Average or Max/Min Values .................................................................................2.43

Impact of the sweep count on the measurement results ..............................................2.44

Trigger Concepts ......................................................................................................................2.44

Cable TV Measurements (Option K20) .........................................................................................2.46

Advanced Measurement Examples R&S FSL

1300.2519.12 I-2.2 E-11

Analog TV Basics .....................................................................................................................2.47

Analog TV Measurement Examples .........................................................................................2.48

Analog TV settings........................................................................................................2.48

Analog TV test setup.....................................................................................................2.49

Spectrum measurement................................................................................................2.50

Carriers measurement ..................................................................................................2.51

Video Scope measurement...........................................................................................2.52

Vision Modulation measurement ..................................................................................2.53

Hum measurement .......................................................................................................2.55

C/N measurement.........................................................................................................2.56

CSO measurement .......................................................................................................2.60

CTB measurement........................................................................................................2.63

Digital TV Basics.......................................................................................................................2.65

Digital TV Measurement Examples ..........................................................................................2.70

Digital TV settings .........................................................................................................2.71

Digital TV test setup......................................................................................................2.72

Spectrum measurement................................................................................................2.72

Overview measurement ................................................................................................2.73

Constellation Diagram measurement (modulation analysis) ........................................2.75

Modulation Errors measurement (modulation analysis) ...............................................2.76

Echo Pattern measurement (channel analysis) ............................................................2.78

Channel Power measurement ......................................................................................2.79

APD measurement........................................................................................................2.80

CCDF measurement .....................................................................................................2.81

TV Analyzer Measurements .....................................................................................................2.82

Tilt measurement ..........................................................................................................2.82

Channel Tables and Modulation Standards .............................................................................2.83

Channel tables ..............................................................................................................2.84

Modulation standards....................................................................................................2.85

Example: Creating a channel table...............................................................................2.90

Example: Restoring the default channel tables ............................................................2.96

Performing a Measurement without a Channel Table ..............................................................2.96

Performing a Measurement Using a Channel Table ................................................................2.98

Noise Figure Measurements Option (K30).................................................................................2.101

Direct Measurements..............................................................................................................2.101

Basic Measurement Example .....................................................................................2.101

DUTs with very Large Gain.........................................................................................2.103

Frequency–Converting Measurements ..................................................................................2.104

Fixed LO Measurements.............................................................................................2.104

Image–Frequency Rejection (SSB, DSB)...................................................................2.104

3GPP Base Station Measurements (Option K72) ......................................................................2.108

Measuring the Signal Channel Power ....................................................................................2.108

Measuring the Spectrum Emission Mask ...............................................................................2.110

Measuring the Relative Code Domain Power.........................................................................2.111

Synchronization of the reference frequencies ............................................................2.112

Behavior with deviating center frequency setting .......................................................2.113

R&S FSL Advanced Measurement Examples

1300.2519.12 I-2.3 E-11

Behavior with incorrect scrambling code ....................................................................2.113

Measuring the Relative Code Domain Power Triggered ........................................................2.113

Trigger offset...............................................................................................................2.114

Setup for Base Station Tests..................................................................................................2.115

Standard test setup.....................................................................................................2.115

Basic settings ..............................................................................................................2.115

CDMA2000 Base Station Measurements (Option K82).............................................................2.116

Measuring the Signal Channel Power ....................................................................................2.116

Measuring the Spectrum Emission Mask ...............................................................................2.118

Measuring the Relative Code Domain Power and the Frequency Error ................................2.119

Synchronization of the reference frequencies ............................................................2.121

Behavior with deviating center frequency setting .......................................................2.121

Measuring the triggered Relative Code Domain Power .........................................................2.122

Adjusting the trigger offset ..........................................................................................2.123

Behaviour with the wrong PN offset............................................................................2.123

Measuring the Composite EVM..............................................................................................2.124

Measuring the Peak Code Domain Error and the RHO Factor ..............................................2.126

Displaying RHO ..........................................................................................................2.127

Test Setup for Base Station Tests..........................................................................................2.127

WLAN TX Measurements (Option K91/K91n)............................................................................2.129

Signal Processing of the IEEE 802.11a application ...............................................................2.129

Abbreviations ..............................................................................................................2.129

Literature .....................................................................................................................2.134

Signal Processing of the IEEE 802.11b application ...............................................................2.134

Abbreviations ..............................................................................................................2.134

Literature .....................................................................................................................2.138

802.11b RF carrier suppression .............................................................................................2.138

Definition .....................................................................................................................2.138

Measurement with the R&S FSL ................................................................................2.138

Comparison to IQ offset measurement in K91 list mode ............................................2.139

IQ Impairments .......................................................................................................................2.140

IQ Offset......................................................................................................................2.140

Gain Imbalance...........................................................................................................2.140

Quadrature Error.........................................................................................................2.141

WiMAX, WiBro Measurements (Options K92/K93)....................................................................2.142

Basic Measurement Example.................................................................................................2.142

Setting up the measurement.......................................................................................2.142

Performing the level detection ....................................................................................2.144

Performing the main measurement ............................................................................2.144

Signal Processing of the IEEE 802.16–2004 OFDM Measurement Application ....................2.145

Analysis Steps ............................................................................................................2.149

Subchannelization.......................................................................................................2.150

Synchronization ..........................................................................................................2.150

Channel Results..........................................................................................................2.150

Frequency and Clock Offset .......................................................................................2.151

EVM ............................................................................................................................2.151

Advanced Measurement Examples R&S FSL

1300.2519.12 I-2.4 E-11

IQ Impairments ...........................................................................................................2.152

RSSI............................................................................................................................2.152

CINR ...........................................................................................................................2.153

Literature .....................................................................................................................2.153

Signal Processing of the IEEE802.16–2005 OFDMA/WiBro Measurement Application........2.153

Introduction .................................................................................................................2.155

Signal Processing Block Diagram...............................................................................2.155

Synchronization ..........................................................................................................2.156

Channel Estimation / Equalization ..............................................................................2.156

Analysis.......................................................................................................................2.157

Literature .....................................................................................................................2.158

R&S FSL Advanced Measurement Examples

1300.2519.12 2.1 E-11

2Advanced Measurement Examples

This chapter explains how to operate the R&S FSL using typical measurements as examples.

Additional background information on the settings is given. Examples of more basic character are

provided in the Quick Start Guide, chapter 5, as an introduction. The following topics are included in the

Quick Start Guide:

•Performing a Level and Frequency Meaurement

•Measuring a Sinusoidal Signal

Measuring the Level and Frequency Using Markers

Measuring the Signal Frequency Using the Frequency Counter

•Measuring Harmonics of Sinusoidal Signals

Measuring the Suppression of the First and Second Harmonic of an Input Signal

•Measuring Signal Spectra with Multiple Signals

Separating Signals by Selecting the Resolution Bandwidth

Measuring the Modulation Depth of an AM–Modulated Carrier (Span > 0)

Measuring of AM–Modulated Signals

•Measurements with Zero Span

Measuring the Power Characteristic of Burst Signals

Measuring the Signal–to–Noise Ratio of Burst Signals

Measurement of FM–Modulated Signals

•Storing and Loading Instrument Settings

Storing an Instrument Configuration (without Traces)

Storing Traces

Loading an Instrument Configuration (with Traces)

Configuring Automatic Loading

Test Setup R&S FSL

1300.2519.12 2.2 E-11

Test Setup

All of the following examples are based on the standard settings of the R&S FSL. These are set with the

PRESET key. A complete listing of the standard settings can be found in chapter "Instrument

Functions", section "Initializing the Configuration – PRESET Key".

In the following examples, a signal generator is used as a signal source. The RF output of the signal

generator is connected to the RF input of R&S FSL.

If a 65 MHz signal is required for the test setup, as an alternative to the signal generator, the internal 65

MHz reference generator can be used:

1. Switch on the internal reference generator.

Press the SETUP key.

Press the Service softkey.

Press the Input RF/Cal/TG softkey, until Cal is highlighted.

The internal 65 MHz reference generator is now on. The R&S FSL's RF input is switched off.

2. Switch on the RF input again for normal operation of the R&S FSL. Two ways are possible:

Press the PRESET key

Press the SETUP key.

Press the Service softkey.

Press the Input RF/Cal/TG softkey, until RF is highlighted.

The internal signal path of the R&S FSL is switched back to the RF input in order to resume

normal operation.

Measurement of Harmonics

Measuring the harmonics of a signal is a frequent problem which can be solved best by means of a

spectrum analyzer. In general, every signal contains harmonics which are larger than others.

Harmonics are particularly critical regarding high–power transmitters such as transceivers because

large harmonics can interfere with other radio services.

Harmonics are generated by nonlinear characteristics. They can often be reduced by lowpass filters.

Since the spectrum analyzer has a nonlinear characteristic, e.g. in its first mixer, measures must be

taken to ensure that harmonics produced in the spectrum analyzer do not cause spurious results. If

necessary, the fundamental wave must be selectively attenuated with respect to the other harmonics

with a highpass filter.

When harmonics are being measured, the obtainable dynamic range depends on the second harmonic

intercept of the spectrum analyzer. The second harmonic intercept is the virtual input level at the RF

input mixer at which the level of the 2nd harmonic becomes equal to the level of the fundamental wave.

In practice, however, applying a level of this magnitude would damage the mixer. Nevertheless the

available dynamic range for measuring the harmonic distance of a DUT can be calculated relatively

easily using the second harmonic intercept.

R&S FSL Measurement of Harmonics

1300.2519.12 2.3 E-11

As shown in Fig. 2-1,the level of the 2ndharmonic drops by 20 dB if the level of the fundamental wave

isreduced by 10 dB.

-50

-30

-20 0-10 10 20 30 40 50

-20

-10

RF level

/dBm

-40

-60

-70

-80

Level display

/dBm

2nd harmonic

intercept point /

dBm

-30

1st harmonic

2nd harmonic

Fig. 2-1 Extrapolation of the 1st and 2nd harmonics to the 2nd harmonic intercept at 40 dBm

The following formula for the obtainable harmonic distortion d

2in dB is derived from the straight–line

equations and the given intercept point:

d2=S.H.I – PI(1)

d2=harmonic distortion

I=mixer level/dBm

S.H.I. = second harmonic intercept

Note: The mixer level is the RF level applied to the RF input minus the set RF attenuation.

The formula for the internally generated level P1at the 2nd harmonic in dBm is:

P1= 2



PI–S.H.I. (2)

The lower measurement limit for the harmonic is the noise floor of the spectrum analyzer. The harmonic

of the measured DUT should – if sufficiently averaged by means of a video filter – be at least 4 dB

above the noise floor so that the measurement error due to the input noise is less than 1 dB.

The following rules for measuring high harmonic ratios can be derived:

Select the smallest possible IF bandwidth for a minimal noise floor.

Select an RF attenuation which is high enough to just measure the harmonic ratio.

The maximum harmonic distortion is obtained if the level of the harmonic equals the intrinsic noise level

of the receiver. The level applied to the mixer, according to (2), is:

2/ IPdBmP

Pnoise

=(3)

At a resolution bandwidth of 10 Hz (noise level –143 dBm, S.H.I. = 40 dBm), the optimum mixer level is

–51.5 dBm. According to (1) a maximum measurable harmonic distortion of 91.5 dB minus a minimum

S/N ratio of 4 dB is obtained.

Measurement of Harmonics R&S FSL

1300.2519.12 2.4 E-11

Note: If the harmonic emerges from noise sufficiently (approx. >15 dB), it is easy to check (by

changing the RF attenuation) whether the harmonics originate from the DUT or are generated

internally by the spectrum analyzer. If a harmonic originates from the DUT, its level remains

constant if the RF attenuation is increased by 10 dB. Only the displayed noise is increased by

10 dB due to the additional attenuation. If the harmonic is exclusively generated by the

spectrum analyzer, the level of the harmonic is reduced by 20 dB or is lost in noise. If both – the

DUT and the spectrum analyzer – contribute to the harmonic, the reduction in the harmonic

level is correspondingly smaller.

High–Sensitivity Harmonics Measurements

If harmonics have very small levels, the resolution bandwidth required to measure them must be

reduced considerably. The sweep time is, therefore, also increased considerably. In this case, the

measurement of individual harmonics is carried out with the R&S FSL set to a small span. Only the

frequency range around the harmonics will then be measured with a small resolution bandwidth.

Signal generator settings (e.g. R&S SMU):

Frequency: 128 MHz

Level: – 25 dBm

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is set to its default state.

2. Set the center frequency to 128 MHz and the span to 100 kHz.

Press the FREQ key.

The frequency menu is displayed.

In the dialog box, enter 128 using the numeric keypad and confirm with the MHz key.

Press the SPAN key.

In the dialog box, enter 100 using the numeric keypad and confirm with the kHz key.

The R&S FSL displays the reference signal with a span of 100 kHz and resolution bandwidth of

3kHz.

3. Switching on the marker.

Press the MKR key.

The marker is positioned on the trace maximum.

4. Set the measured signal frequency and the measured level as reference values

Press the Phase Noise/Ref Fixed softkey.

The position of the marker becomes the reference point. The reference point level is indicated

by a horizontal line, the reference point frequency with a vertical line. At the same time, the

delta marker 2 is switched on.

Press the Ref Fixed softkey.

R&S FSL Measurement of Harmonics

1300.2519.12 2.5 E-11

The mode changes from phase noise measurement to reference fixed, the marker readout

changes from dB/Hz to dB.

Fig. 2-2 Fundamental wave and the frequency and level reference point

5. Make the step size for the center frequency equal to the signal frequency

Press the FREQ key.

The frequency menu is displayed.

Press the CF–Stepsize softkey and press the =Marker softkey in the submenu.

The step size for the center frequency is now equal to the marker frequency.

6. Set the center frequency to the 2nd harmonic of the signal

Press the FREQ key.

The frequency menu is displayed.

Press the UPARROW key once.

The center frequency is set to the 2nd harmonic.

7. Place the delta marker on the 2nd harmonic.

Press the MKR–> key.

Press the Peak softkey.

Measuring the Spectra of Complex Signals R&S FSL

1300.2519.12 2.6 E-11

The delta marker moves to the maximum of the 2ndharmonic. The displayed level result is

relative to the reference point level (= fundamental wave level).

Fig. 2-3 Measuring the level difference between the fundamental wave (= reference point

level) and the 2nd harmonic

The other harmonics are measured with steps 5 and 6, the center frequency being incremented or

decremented in steps of 128 MHz using the UPARROW or DNARROW key.

Measuring the Spectra of Complex Signals

Separating Signals by Selecting an Appropriate Resolution

Bandwidth

Abasic feature of a spectrum analyzer is being able to separate the spectral components of a mixture

of signals. The resolution at which the individual components can be separated is determined by the

resolution bandwidth. Selecting a resolution bandwidth that is too large may make it impossible to

distinguish between spectral components, i.e. they are displayed as a single component.

An RF sinusoidal signal is displayed by means of the passband characteristic of the resolution filter

(RBW) that has been set. Its specified bandwidth is the 3 dB bandwidth of the filter.

Two signals with the same amplitude can be resolved if the resolution bandwidth is smaller than or

equal to the frequency spacing of the signal. If the resolution bandwidth is equal to the frequency

spacing, the spectrum display screen shows a level drop of 3 dB precisely in the center of the two

signals. Decreasing the resolution bandwidth makes the level drop larger, which thus makes the

individual signals clearer.

If there are large level differences between signals, the resolution is determined by selectivity as well as

by the resolution bandwidth that has been selected. The measure of selectivity used for spectrum

analyzers is the ratio of the 60 dB bandwidth to the 3 dB bandwidth (= shape factor).

For the R&S FSL, the shape factor for bandwidths is < 5, i.e. the 60 dB bandwidth of the 30 kHz filter is

<150 kHz.

R&S FSL Measuring the Spectra of Complex Signals

1300.2519.12 2.7 E-11

The higher spectral resolution with smaller bandwidths is won by longer sweep times for the same

span. The sweep time has to allow the resolution filters to settle during a sweep at all signal levels and

frequencies to be displayed. It is given by the following formula.

Span/RBWkSWT •= (4)

SWT = max. sweep time for correct measurement

k = factor depending on type of resolution filter

= 1 for digital IF filters

Span = frequency display range

RBW = resolution bandwidth

If the resolution bandwidth is reduced by a factor of 3, the sweep time is increased by a factor of 9.

Note: The impact of the video bandwidth on the sweep time is not taken into account in (4). For the

formula to be applied, the video bandwidth must be



3 x the resolution bandwidth.

FFT filters can be used for resolution bandwidths up to 30 kHz. Like digital filters, they have a shape

factor of less than 5 up to 30 kHz. For FFT filters, however, the sweep time is given by the following

formula:

SWT = k



span/RBW (5)

If the resolution bandwidth is reduced by a factor of 3, the sweep time is increased by a factor of 3 only.

Intermodulation Measurements

If several signals are applied to a transmission two–port device with nonlinear characteristic,

intermodulation products appear at its output by the sums and differences of the signals. The nonlinear

characteristic produces harmonics of the useful signals which intermodulate at the characteristic. The

intermodulation products of lower order have a special effect since their level is largest and they are

near the useful signals. The intermodulation product of third order causes the highest interference. It is

the intermodulation product generated from one of the useful signals and the 2nd harmonic of the

second useful signal in case of two–tone modulation.

The frequencies of the intermodulation products are above and below the useful signals. Fig. 2-4 shows

intermodulation products PI1 and PI2 generated by the two useful signals PU1 and PU2.

Fig. 2-4 Intermodulation products PU1 and PU2

Measuring the Spectra of Complex Signals R&S FSL

1300.2519.12 2.8 E-11

The intermodulation product at f

I2 is generated by mixing the 2nd harmonic of useful signal P

U2 and

signal PU1,the intermodulation product at fI1bymixing the 2nd harmonic of useful signal PU1and signal

PU2.

fi1 = 2 x fu1 – fu2 (6)

fi2 = 2 x fu2 – fu1 (7)

The level of the intermodulation products depends on the level of the useful signals. If the two useful

signals are increased by 1 dB, the level of the intermodulation products increases by 3 dB, which

means that spacing aD3 between intermodulation signals and useful signals are reduced by 2 dB. This is

illustrated in Fig. 2-5.

Fig. 2-5 Dependence of intermodulation level on useful signal level

The useful signals at the two–port output increase proportionally with the input level as long as the two–

port is in the linear range. A level change of 1 dB at the input causes a level change of 1 dB at the

output. Beyond a certain input level, the two–port goes into compression and the output level stops

increasing. The intermodulation products of the third order increase three times as much as the useful

signals. The intercept point is the fictitious level where the two lines intersect. It cannot be measured

directly since the useful level is previously limited by the maximum two–port output power.

It can be calculated from the known line slopes and the measured spacing a

D3 at a given level

according to the following formula.

IP aP

(8)

The 3rd order intercept point (TOI), for example, is calculated for an intermodulation of 60 dB and an

input level PUof –20 dBm according to the following formula:

IP dBm dBm3

20 10= + =( ) (9)

R&S FSL Measuring the Spectra of Complex Signals

1300.2519.12 2.9 E-11

Measurement example – Measuring the R&S FSL's intrinsic intermodulation

Test setup:

Signal

Generator 1

Signal

Generator 2

Coupler

[- 6 dB] R&S FSL

Signal generator settings (e.g. R&S SMU):

Level Frequency

Signal generator 1 –4 dBm 999.7 MHz

Signal generator 2 –4 dBm 1000.3 MHz

Procedure:

1. Set the R&S FSL to its default settings.

Press the PRESET key.

The R&S FSL is in its default state.

2. Set center frequency to 1 GHz and the frequency span to 3 MHz.

Press the FREQ key and enter 1GHz.

Press the SPAN key and enter 3MHz.

3. Set the reference level to –10 dBm and RF attenuation to 0 dB.

Press the AMPT key and enter –10 dBm.

Press the RF Atten Manual softkey and enter 0dB.

4. Set the resolution bandwidth to 10 kHz.

Press the BW key.

Press the Res BW Manual softkey and enter 10 kHz.

The noise is reduced, the trace is smoothed further and the intermodulation products can be

clearly seen.

Press the Video BW Manual softkey and enter 1kHz.

Measuring the Spectra of Complex Signals R&S FSL

1300.2519.12 2.10 E-11

5. Measuring intermodulation by means of the 3rdorder intercept measurement function

Press the MEAS key.

Press the TOI softkey.

The R&S FSL activates four markers for measuring the intermodulation distance. Two markers

are positioned on the useful signals and two on the intermodulation products. The 3rdorder

intercept is calculated from the level difference between the useful signals and the

intermodulation products. It is then displayed on the screen:

Fig. 2-6 Result of intrinsic intermodulation measurement on the R&S FSL. The 3rd order

intercept (TOI) is displayed at the top right corner of the grid.

The level of a spectrum analyzer's intrinsic intermodulation products depends on the RF level of the

useful signals at the input mixer. When the RF attenuation is added, the mixer level is reduced and

the intermodulation distance is increased. With an additional RF attenuation of 10 dB, the levels of

the intermodulation products are reduced by 20 dB. The noise level is, however, increased by 10

dB.

6. Increasing RF attenuation to 10 dB to reduce intermodulation products.

Press the AMPT key.

Press the RF Atten Manual softkey and enter 10 dB.

The R&S FSL's intrinsic intermodulation products disappear below the noise floor.

R&S FSL Measuring the Spectra of Complex Signals

1300.2519.12 2.11 E-11

Fig. 2-7 If the RF attenuation is increased, the R&S FSL's intrinsic intermodulation products

disappear below the noise floor.

Calculation method:

The method used by the R&S FSL to calculate the intercept point takes the average useful signal level

Puin dBm and calculates the intermodulation d3in dB as a function of the average value of the levels of

the two intermodulation products. The third order intercept (TOI) is then calculated as follows:

TOI/dBm = ½ d3+ Pu

Intermodulation– free dynamic range

The Intermodulation – free dynamic range, i.e. the level range in which no internal intermodulation

products are generated if two–tone signals are measured, is determined by the 3rd order intercept point,

the phase noise and the thermal noise of the spectrum analyzer. At high signal levels, the range is

determined by intermodulation products. At low signal levels, intermodulation products disappear below

the noise floor, i.e. the noise floor and the phase noise of the spectrum analyzer determine the range.

The noise floor and the phase noise depend on the resolution bandwidth that has been selected. At the

smallest resolution bandwidth, the noise floor and phase noise are at a minimum and so the maximum

range is obtained. However, a large increase in sweep time is required for small resolution bandwidths.

It is, therefore, best to select the largest resolution bandwidth possible to obtain the range that is

required. Since phase noise decreases as the carrier–offset increases, its influence decreases with

increasing frequency offset from the useful signals.

The following diagrams illustrate the intermodulation–free dynamic range as a function of the selected

bandwidth and of the level at the input mixer (= signal level – set RF attenuation) at different useful

signal offsets.

Measuring the Spectra of Complex Signals R&S FSL

1300.2519.12 2.12 E-11

Distortion free Dynamic Range

(1 MHz carrier offset)

-120

-110

-100

-90

-80

-70

-60

-50

-40

-60 -50 -40 -30 -20 -10

Mixer level /dBm

Dynrange/

T.O.I.

Thermal Noise

+Phase Noise

RWB = 1 kHz

RWB = 100 Hz

RWB = 10 Hz

Fig. 2-8 Intermodulation–free range of the R&S FSL as a function of level at the input mixer and the

set resolution bandwidth (useful signal offset = 1 MHz, DANL = –145 dBm /Hz, TOI = 15 dBm; typical

values at 2 GHz)

The optimum mixer level, i.e. the level at which the intermodulation distance is at its maximum, depends

on the bandwidth. At a resolution bandwidth of 10 Hz, it is approx. –35 dBm and at 1 kHz increases to

approx. –30 dBm.

Phase noise has a considerable influence on the intermodulation–free range at carrier offsets between

10 and 100 kHz (Fig. 2-9). At greater bandwidths, the influence of the phase noise is greater than it

would be with small bandwidths. The optimum mixer level at the bandwidths under consideration

becomes almost independent of bandwidth and is approx. –40 dBm.

Distortion free Dynamic Range

(10 to 100 kHz carrier offset)

-120

-110

-100

-90

-80

-70

-60

-50

-40

-60 -50 -40 -30 -20 -10

Mixer level /dBm

Dyn.range/dB

RBW = 1 kHz

Thermal Noise

+Phase Noise

TOI

RBW = 100 Hz

RBW = 10 Hz

Fig. 2-9 Intermodulation–free dynamic range of the R&S FSL as a function of level at the input

mixer and of the selected resolution bandwidth (useful signal offset = 10 to 100 kHz, DANL = –145 dBm

/Hz, TOI = 15 dBm; typical values at 2 GHz).

R&S FSL Measuring Signals in the Vicinity of Noise

1300.2519.12 2.13 E-11

Note: If the intermodulation products of a DUT with a very high dynamic range are to be measured

and the resolution bandwidth to be used is therefore very small, it is best to measure the levels

of the useful signals and those of the intermodulation products separately using a small span.

The measurement time will be reduced– in particular if the offset of the useful signals is large.

To find signals reliably when frequency span is small, it is best to synchronize the signal

sources and the R&S FSL.

Measuring Signals in the Vicinity of Noise

The minimum signal level a spectrum analyzer can measure is limited by its intrinsic noise. Small

signals can be swamped by noise and therefore cannot be measured. For signals that are just above

the intrinsic noise, the accuracy of the level measurement is influenced by the intrinsic noise of the

spectrum analyzer.

The displayed noise level of a spectrum analyzer depends on its noise figure, the selected RF

attenuation, the selected reference level, the selected resolution and video bandwidth and the detector.

The effect of the different parameters is explained in the following.

Impact of the RF attenuation setting

The sensitivity of a spectrum analyzer is directly influenced by the selected RF attenuation. The highest

sensitivity is obtained at a RF attenuation of 0 dB. The attenuation can be set in 10 dB steps up to 70

dB. Each additional 10 dB step reduces the sensitivity by 10 dB, i.e. the displayed noise is increased by

10 dB.

Impact of the resolution bandwidth

The sensitivity of a spectrum analyzer also directly depends on the selected bandwidth. The highest

sensitivity is obtained at the smallest bandwidth (for the R&S FSL: 10 Hz, for FFT filtering: 1 Hz). If the

bandwidth is increased, the reduction in sensitivity is proportional to the change in bandwidth. The

R&S FSL has bandwidth settings in 1, 3, 10 sequence. Increasing the bandwidth by a factor of 3

increases the displayed noise by approx. 5 dB (4.77 dB precisely). If the bandwidth is increased by a

factor of 10, the displayed noise increases by a factor of 10, i.e. 10 dB.

Impact of the video bandwidth

The displayed noise of a spectrum analyzer is also influenced by the selected video bandwidth. If the

video bandwidth is considerably smaller than the resolution bandwidth, noise spikes are suppressed,

i.e. the trace becomes much smoother. The level of a sinewave signal is not influenced by the video

bandwidth. A sinewave signal can therefore be freed from noise by using a video bandwidth that is

small compared with the resolution bandwidth, and thus be measured more accurately.

Impact of the detector

Noise is evaluated differently by the different detectors. The noise display is therefore influenced by the

choice of detector. Sinewave signals are weighted in the same way by all detectors, i.e. the level

display for a sinewave RF signal does not depend on the selected detector, provided that the signal–to–

noise ratio is high enough. The measurement accuracy for signals in the vicinity of intrinsic spectrum

analyzer noise is also influenced by the detector which has been selected. For details on the detectors

of the R&S FSL refer to chapter "Instrument Functions", section "Detector overview" or the Online Help.

Measuring Signals in the Vicinity of Noise R&S FSL

1300.2519.12 2.14 E-11

Measurement example – Measuring level at low S/N ratios

The example shows the different factors influencing the S/N ratio.

Signal generator settings (e.g. R&S SMU):

Frequency: 128 MHz

Level: – 80 dBm

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is in its default state.

2. Set the center frequency to 128 MHz and the frequency span to 100 MHz.

Press the FREQ key and enter 128 MHz.

Press the SPAN key and enter 100 MHz.

3. Set the RF attenuation to 60 dB to attenuate the input signal or to increase the intrinsic noise.

Press the AMPT key.

Press the RF Atten Manual softkey and enter 60 dB.

The RF attenuation indicator is marked with an asterisk (*Att 60 dB) to show that it is no longer

coupled to the reference level. The high input attenuation reduces the reference signal which

can no longer be detected in noise.

Fig. 2-10 Sinewave signal with low S/N ratio. The signal is measured with the auto peak

detector and is completely hidden in the intrinsic noise of the R&S FSL.

4. To suppress noise spikes the trace can be averaged.

Press the TRACE key.

Press the Trace Mode key.

R&S FSL Measuring Signals in the Vicinity of Noise

1300.2519.12 2.15 E-11

Press the Average softkey.

The traces of consecutive sweeps are averaged. To perform averaging, the R&S FSL

automatically switches on the sample detector. The RF signal, therefore, can be more clearly

distinguished from noise.

Fig. 2-11 RF sinewave signal with low S/N ratio if the trace is averaged.

5. Instead of trace averaging, a video filter that is narrower than the resolution bandwidth can be

selected.

Press the Trace Mode key.

Press the Clear Write softkey.

Press the BW key.

Press the Video BW Manual softkey and enter 10 kHz.

The RF signal can be more clearly distinguished from noise.

Fig. 2-12 RF sinewave signal with low S/N ratio if a smaller video bandwidth is selected.

Measuring Signals in the Vicinity of Noise R&S FSL

1300.2519.12 2.16 E-11

6. By reducing the resolution bandwidth by a factor of 10, the noise is reduced by 10 dB.

Press the Res BW Manual softkey and enter 300 kHz.

The displayed noise is reduced by approx. 10 dB. The signal, therefore, emerges from noise by

about 10 dB. Compared to the previous setting, the video bandwidth has remained the same,

i.e. it has increased relative to the smaller resolution bandwidth. The averaging effect of the

video bandwidth is therefore reduced. The trace will be noisier.

Fig. 2-13 Reference signal at a smaller resolution bandwidth

R&S FSL Noise Measurements

1300.2519.12 2.17 E-11

Noise Measurements

Noise measurements play an important role in spectrum analysis. Noise e.g. affects the sensitivity of

radio communication systems and their components.

Noise power is specified either as the total power in the transmission channel or as the power referred

to a bandwidth of 1 Hz. The sources of noise are, for example, amplifier noise or noise generated by

oscillators used for the frequency conversion of useful signals in receivers or transmitters. The noise at

the output of an amplifier is determined by its noise figure and gain.

The noise of an oscillator is determined by phase noise near the oscillator frequency and by thermal

noise of the active elements far from the oscillator frequency. Phase noise can mask weak signals near

the oscillator frequency and make them impossible to detect.

Measuring Noise Power Density

To measure noise power referred to a bandwidth of 1 Hz at a certain frequency, the R&S FSL provides

marker function. This marker function calculates the noise power density from the measured marker

level.

Measurement example – Measuring the intrinsic noise power density of the

R&S FSL at 1 GHz and calculating the R&S FSL's noise figure

Test setup:

Connect no signal to the RF input; terminate RF input with 50 P.

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is in its default state.

2. Set the center frequency to 1.234 GHz and the span to 1 MHz.

Press the FREQ key and enter 1.234 GHz.

Press the SPAN key and enter 1MHz.

3. Switch on the marker and set the marker frequency to 1.234 GHz.

Press the MKR key and enter 1.234 GHz.

4. Switch on the noise marker function.

Switch on the Noise Meas softkey.

The R&S FSL displays the noise power at 1 GHz in dBm (1 Hz).

Note: Since noise is random, a sufficiently long measurement time has to be selected to obtain stable

measurement results. This can be achieved by averaging the trace or by selecting a very small

video bandwidth relative to the resolution bandwidth.

Noise Measurements R&S FSL

1300.2519.12 2.18 E-11

5. The measurement result is stabilized by averaging the trace.

Press the TRACE key.

Press the Trace Mode key.

Press the Average softkey.

The R&S FSL performs sliding averaging over 10 traces from consecutive sweeps. The

measurement result becomes more stable.

Conversion to other reference bandwidths

The result of the noise measurement can be referred to other bandwidths by simple conversion. This is

done by adding 10 log (BW) to the measurement result, BW being the new reference bandwidth.

Example

Anoise power of –150 dBm (1 Hz) is to be referred to a bandwidth of 1 kHz.

P[1kHz] = –150 + 10 * log (1000) = –150 +30 = –120 dBm (1 kHz)

Calculation method for noise power

If the noise marker is switched on, the R&S FSL automatically activates the sample detector. The video

bandwidth is set to 1/10 of the selected resolution bandwidth (RBW).

To calculate the noise, the R&S FSL takes an average over 17 adjacent pixels (the pixel on which the

marker is positioned and 8 pixels to the left, 8 pixels to the right of the marker). The measurement result

is stabilized by video filtering and averaging over 17 pixels.

Since both video filtering and averaging over 17 trace points is performed in the log display mode, the

result would be 2.51 dB too low (difference between logarithmic noise average and noise power). The

R&S FSL, therefore, corrects the noise figure by 2.51 dB.

To standardize the measurement result to a bandwidth of 1 Hz, the result is also corrected by –10 * log

(RBWnoise), with RBWnoise being the power bandwidth of the selected resolution filter (RBW).

Detector selection

The noise power density is measured in the default setting with the sample detector and using

averaging. Other detectors that can be used to perform a measurement giving true results are the

average detector or the RMS detector. If the average detector is used, the linear video voltage is

averaged and displayed as a pixel. If the RMS detector is used, the squared video voltage is averaged

and displayed as a pixel. The averaging time depends on the selected sweep time (=SWT/501). An

increase in the sweep time gives a longer averaging time per pixel and thus stabilizes the measurement

result. The R&S FSL automatically corrects the measurement result of the noise marker display

depending on the selected detector (+1.05 dB for the average detector, 0 dfor the RMS detector). It is

assumed that the video bandwidth is set to at least three times the resolution bandwidth. While the

average or RMS detector is being switched on, the R&S FSL sets the video bandwidth to a suitable

value.

The Pos Peak, Neg Peak, Auto Peak and Quasi Peak detectors are not suitable for measuring noise

power density.

Determining the noise figure

The noise figure of amplifiers or of the R&S FSL alone can be obtained from the noise power display.

Based on the known thermal noise power of a 50 resistor at room temperature (–174 dBm (1Hz)) and

the measured noise power Pnoise the noise figure (NF) is obtained as follows:

NF = Pnoise + 174 – g,

where g = gain of DUT in dB

R&S FSL Noise Measurements

1300.2519.12 2.19 E-11

Example

The measured internal noise power of the R&S FSL at an attenuation of 0 dB is found to be –143

dBm/1 Hz. The noise figure of the R&S FSL is obtained as follows

NF = –143 + 174 = 31 dB

Note: If noise power is measured at the output of an amplifier, for example, the sum of the internal

noise power and the noise power at the output of the DUT is measured. The noise power of the

DUT can be obtained by subtracting the internal noise power from the total power (subtraction

of linear noise powers). By means of the following diagram, the noise level of the DUT can be

estimated from the level difference between the total and the internal noise level.

-10

-9

-8

-7

-6

-5

-4

-3

-2

-1

012345678910111213141516

Total power/intrinsic noise power in dB

Correction

factor in dB

Fig. 2-14 Correction factor for measured noise power as a function of the ratio of total power to the

intrinsic noise power of the spectrum analyzer

Measurement of Noise Power within a Transmission

Channel

Noise in any bandwidth can be measured with the channel power measurement functions. Thus the

noise power in a communication channel can be determined, for example. If the noise spectrum within

the channel bandwidth is flat, the noise marker from the previous example can be used to determine the

noise power in the channel by considering the channel bandwidth. If, however, phase noise and noise

that normally increases towards the carrier is dominant in the channel to be measured, or if there are

discrete spurious signals in the channel, the channel power measurement method must be used to

obtain correct measurement results.

Noise Measurements R&S FSL

1300.2519.12 2.20 E-11

Measurement example – Measuring the intrinsic noise of the R&S FSL at 1 GHz in a

1.23 MHz channel bandwidth with the channel power function

Test setup:

Leave the RF input of the R&S FSL open–circuited or terminate it with 50 .

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is in its default state.

2. Set the center frequency to 1 GHz and the span to 1 MHz.

Press the FREQ key and enter 1GHz.

Press the SPAN key and enter 2MHz.

3. To obtain maximum sensitivity, set RF attenuation on the R&S FSL to 0 dB.

Press the AMPT key.

Press the RF Atten Manual softkey and enter 0dB.

4. Switch on and configure the channel power measurement.

Press the MEAS key.

Press the CP, ACP, MC–ACP softkey.

The R&S FSL activates the channel or adjacent channel power measurement according to the

currently set configuration.

Press the CP/ACP Config softkey.

The submenu for configuring the channel is displayed.

Press the Channel Settings softkey.

The submenu for channel settings is displayed.

Press the Channel Bandwidth softkey and enter 1.23 MHz.

The R&S FSL displays the 1.23 MHz channel as two vertical lines which are symmetrical to the

center frequency.

Press the Adjust Settings softkey.

The settings for the frequency span, the bandwidth (RBW and VBW) and the detector are

automatically set to the optimum values required for the measurement.

R&S FSL Noise Measurements

1300.2519.12 2.21 E-11

Fig. 2-15 Measurement of the R&S FSL's intrinsic noise power in a 1.23 MHz channel

bandwidth.

5. Stabilizing the measurement result by increasing the sweep time

Press the Hkey twice.

The main menu for channel and adjacent channel power measurement is displayed.

Press the Sweep Time softkey and enter 1 s.

The trace becomes much smoother because of the RMS detector and the channel power

measurement display is much more stable.

Method of calculating the channel power

When measuring the channel power, the R&S FSL integrates the linear power which corresponds to the

levels of the pixels within the selected channel. The spectrum analyzer uses a resolution bandwidth

which is far smaller than the channel bandwidth. When sweeping over the channel, the channel filter is

formed by the passband characteristics of the resolution bandwidth (see Fig. 2-16).

Channel bandwith

Resolution filter

-3 dB

Sweep

Fig. 2-16 Approximating the channel filter by sweeping with a small resolution bandwidth

Noise Measurements R&S FSL

1300.2519.12 2.22 E-11

The following steps are performed:

•The linear power of all the trace pixels within the channel is calculated.

Pi=10(Li/10)

where Pi=power of the trace pixel i

i=displayed level of trace point i

•The powers of all trace pixels within the channel are summed up and the sum is divided by the

number of trace pixels in the channel.

•The result is multiplied by the quotient of the selected channel bandwidth and the noise bandwidth

of the resolution filter (RBW).

Since the power calculation is performed by integrating the trace within the channel bandwidth, this

method is also called the IBW method (Integration Bandwidth method).

Parameter settings

For selection of the sweep time, see next section. For details on the parameter settings refer to chapter

"Instrument Functions", section "Settings of the CP / ACP test parameters" or the Online Help.

Sweep time selection

The number of A/D converter values, N, used to calculate the power, is defined by the sweep time. The

time per trace pixel for power measurements is directly proportional to the selected sweep time.

If the sample detector is used, it is best to select the smallest sweep time possible for a given span and

resolution bandwidth. The minimum time is obtained if the setting is coupled. This means that the time

per measurement is minimal. Extending the measurement time does not have any advantages as the

number of samples for calculating the power is defined by the number of trace pixels in the channel.

If the RMS detector is used, the repeatability of the measurement results can be influenced by the

selection of sweep times. Repeatability is increased at longer sweep times.

Repeatability can be estimated from the following diagram:

10 1000

100 10000 100000

0.5

1.5

2.5

Number of samples

max. error/dB

95 % Confidence

level

99 % Confidence

level

Fig. 2-17 Repeatability of channel power measurements as a function of the number of samples

used for power calculation

R&S FSL Noise Measurements

1300.2519.12 2.23 E-11

The curves in Fig. 2-17 indicate the repeatability obtained with a probability of 95% and 99% depending

onthe number of samples used.

The repeatability with 600 samples is ±0.5 dB. This means that – if the sample detector and a channel

bandwidth over the whole diagram (channel bandwidth = span) is used – the measured value lies within

±0.5 dB of the true value with a confidence level of 99%.

If the RMS detector is used, the number of samples can be estimated as follows:

Since only uncorrelated samples contribute to the RMS value, the number of samples can be calculated

from the sweep time and the resolution bandwidth.

Samples can be assumed to be uncorrelated if sampling is performed at intervals of 1/RBW. The

number of uncorrelated samples is calculated as follows:

Ndecorr = SWT



RBW (Ndecorr means uncorrelated samples)

The number of uncorrelated samples per trace pixel is obtained by dividing Ndecorr by 501 (= pixels per

trace).

Example

At a resolution bandwidth of 30 kHz and a sweep time of 100 ms, 3000 uncorrelated samples are

obtained. If the channel bandwidth is equal to the frequency display range, i.e. all trace pixels are used

for the channel power measurement, a repeatability of 0.2 dB with a probability of 99% is the estimate

that can be derived from Fig. 2-17.

Measuring Phase Noise

The R&S FSL has an easy–to–use marker function for phase noise measurements. This marker

function indicates the phase noise of an RF oscillator at any carrier in dBc in a bandwidth of 1 Hz.

Measurement example – Measuring the phase noise of a signal generator at a

carrier offset of 10 kHz

Test setup:

Signal

generator R&S FSL

Signal generator settings (e.g. R&S SMU):

Frequency: 100 MHz

Level: 0 dBm

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

R&S FSL is in its default state.

Noise Measurements R&S FSL

1300.2519.12 2.24 E-11

2. Set the center frequency to 100 MHz and the span to 50 kHz.

Press the FREQ key and enter 100 MHz.

Press the SPAN key and enter 50 kHz.

3. Set the R&S FSL's reference level to 0 dBm (=signal generator level).

Press the AMPT key and enter 0dBm.

4. Enable phase noise measurement.

Press the MKR key.

Press the Phase Noise/Ref Fixed softkey.

The R&S FSL activates phase noise measurement. Marker 1 (=main marker) and marker 2 (=

delta marker) are positioned on the signal maximum. The position of the marker is the

reference (level and frequency) for the phase noise measurement. A horizontal line represents

the level of the reference point and a vertical line the frequency of the reference point. The

dialog box for the delta marker is displayed so that the frequency offset at which the phase

noise is to be measured can be entered directly.

5. Set the frequency offset to 10 kHz for determining phase noise.

Enter 10 kHz.

The R&S FSL displays the phase noise at a frequency offset of 10 kHz. The magnitude of the

phase noise in dBc/Hz is displayed in the delta marker output field at the top right of the screen

(Phn2).

6. Stabilize the measurement result by activating trace averaging.

Press the TRACE key.

Press the Trace Mode key.

Press the Average softkey.

Fig. 2-18 Measuring phase noise with the phase–noise marker function

The frequency offset can be varied by moving the marker with the rotary knob or by entering a

new frequency offset as a number.

R&S FSL Measurements on Modulated Signals

1300.2519.12 2.25 E-11

Measurements on Modulated Signals

For measurements on AM and FM signals refer to the Quick Start Guide, chapter 5, "Basic

Measurements Examples".

Measuring Channel Power and Adjacent Channel Power

Measuring channel power and adjacent channel power is one of the most important tasks in the field of

digital transmission for a spectrum analyzer with the necessary test routines. While, theoretically,

channel power could be measured at highest accuracy with a power meter, its low selectivity means

that it is not suitable for measuring adjacent channel power as an absolute value or relative to the

transmit channel power. The power in the adjacent channels can only be measured with a selective

power meter.

Aspectrum analyzer cannot be classified as a true power meter, because it displays the IF envelope

voltage. However, it is calibrated such as to correctly display the power of a pure sinewave signal

irrespective of the selected detector. This calibration cannot be applied for non–sinusoidal signals.

Assuming that the digitally modulated signal has a Gaussian amplitude distribution, the signal power

within the selected resolution bandwidth can be obtained using correction factors. These correction

factors are normally used by the spectrum analyzer's internal power measurement routines in order to

determine the signal power from IF envelope measurements. These factors apply if and only if the

assumption of a Gaussian amplitude distribution is correct.

Apart from this common method, the R&S FSL also has a true power detector, i.e. an RMS detector. It

correctly displays the power of the test signal within the selected resolution bandwidth irrespective of

the amplitude distribution, without additional correction factors being required. The absolute

measurement uncertainty of the R&S FSL is < 1.5 dB and a relative measurement uncertainty of < 0.5

dB (each with a confidence level of 95%).

There are two possible methods for measuring channel and adjacent channel power with a spectrum

analyzer:

•IBW method (Integration Bandwidth Method)

The spectrum analyzer measures with a resolution bandwidth that is less than the channel

bandwidth and integrates the level values of the trace versus the channel bandwidth. This method

is described in section "Method of calculating the channel power".

•Using a channel filter

For a detailed description, refer to the following section.

Measurement using a channel filter

In this case, the spectrum analyzer makes zero span measurements using an IF filter that corresponds

to the channel bandwidth. The power is measured at the output of the IF filter. Until now, this method

has not been used for spectrum analyzers, because channel filters were not available and the

resolution bandwidths, optimized for the sweep, did not have a sufficient selectivity. The method was

reserved for special receivers optimized for a particular transmission method. It is available in R&S

FSQ, FSU, FSP, FSL and ESL series.

The R&S FSL has test routines for simple channel and adjacent channel power measurements. These

routines give quick results without any complex or tedious setting procedures.

Measurements on Modulated Signals R&S FSL

1300.2519.12 2.26 E-11

Measurement example 1 – ACPR measurement on an CDMA 2000 signal

Test setup:

Signal

generator R&S FSL

Signal generator settings (e.g. R&S SMU):

Frequency: 850 MHz

Level: 0 dBm

Modulation: CDMA 2000

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is in its default state.

2. Set the center frequency to 850 MHz and span to 4 MHz.

Press the FREQ key and enter 850 MHz.

Press the SPAN key and enter 4MHz.

3. Set the reference level to +10 dBm.

Press the AMPT key and enter 10 dBm.

4. Configuring the adjacent channel power for the CDMA 2000 MC1.

Press the MEAS key.

Press the CP, ACP, MC–ACP softkey.

Press the CP / ACP Standard softkey.

In the standards list, mark CDMA 2000 MC1 using the rotary knob or the arrow keys and confirm

pressing the rotary knob or the ENTER key.

The R&S FSL sets the channel configuration according to the 2000 MC1 standard for mobile

stations with 2 adjacent channels above and below the transmit channel. The spectrum is

displayed in the upper part of the screen, the numeric values of the results and the channel

configuration in the lower part of the screen. The various channels are represented by vertical

lines on the graph.

The frequency span, resolution bandwidth, video bandwidth and detector are selected

automatically to give correct results. To obtain stable results – especially in the adjacent

channels (30 kHz bandwidth) which are narrow in comparison with the transmission channel

bandwidth (1.23 MHz) – the RMS detector is used.

R&S FSL Measurements on Modulated Signals

1300.2519.12 2.27 E-11

5. Set the optimal reference level and RF attenuation for the applied signal level.

Press the Adjust Ref Level softkey.

The R&S FSL sets the optimal RF attenuation and the reference level based on the

transmission channel power to obtain the maximum dynamic range. Fig. 2-19 shows the result

of the measurement.

Fig. 2-19 Adjacent channel power measurement on a CDMA 2000 MC1 signal

The repeatability of the results, especially in the narrow adjacent channels, strongly depends on

the measurement time since the dwell time within the 30 kHz channels is only a fraction of the

complete sweep time. A longer sweep time may increase the probability that the measured

value converges to the true value of the adjacent channel power, but this increases

measurement time.

To avoid long measurement times, the R&S FSL measures the adjacent channel power with

zero span (fast ACP mode). In the fast ACP mode, the R&S FSL measures the power of each

channel at the defined channel bandwidth, while being tuned to the center frequency of the

channel in question. The digital implementation of the resolution bandwidths makes it possible

to select filter characteristics that is precisely tailored to the signal. In case of CDMA 2000 MC1,

the power in the useful channel is measured with a bandwidth of 1.23 MHz and that of the

adjacent channels with a bandwidth of 30 kHz. Therefore the R&S FSL changes from one

channel to the other and measures the power at a bandwidth of 1.23 MHz or 30 kHz using the

RMS detector. The measurement time per channel is set with the sweep time. It is equal to the

selected measurement time divided by the selected number of channels. The five channels

from the above example and the sweep time of 100 ms give a measurement time per channel

of 20 ms.

Compared to the measurement time per channel given by the span (= 5 MHz) and sweep time

(= 100 ms, equal to 0.600 ms per 30 kHz channel) used in the example, this is a far longer

dwell time on the adjacent channels (factor of 12). In terms of the number of uncorrelated

samples this means 20000/33 Rs = 606 samples per channel measurement compared to

600/33Rs = 12.5 samples per channel measurement.

Repeatability with a confidence level of 95% is increased from ±1.4 dB to ±0.38 dB as shown

in Fig. 2-17.For the same repeatability, the sweep time would have to be set to 1.2 s with the

integration method. Fig. 2-20 shows the standard deviation of the results as a function of the

sweep time.

Measurements on Modulated Signals R&S FSL

1300.2519.12 2.28 E-11

ACPR Repeatability IS95

IBW Method

0,2

0,4

0,6

0,8

1,2

1,4

10 100 1000

Sweep time/ms

Standard dev / dB

Adjacent channels

Alternate channels

Tx channel

Fig. 2-20 Repeatability of adjacent channel power measurement on CDMA 2000 standard

signals if the integration bandwidth method is used

6. Switch to fast ACP mode to increase the repeatability of results.

Switch the Fast ACP softkey to On.

The R&S FSL measures the power of each channel with zero span. The trace represents

power as a function of time for each channel (see Fig. 2-23). The numerical results over

consecutive measurements become much more stable.

Fig. 2-21 Measuring the channel power and adjacent channel power ratio for 2000 MC1

signals with zero span (Fast ACP)

Fig. 2-22 shows the repeatability of power measurements in the transmit channel and of relative

power measurements in the adjacent channels as a function of sweep time. The standard

deviation of measurement results is calculated from 100 consecutive measurements as shown

in Fig. 2-22.Take scaling into account if comparing power values.

R&S FSL Measurements on Modulated Signals

1300.2519.12 2.29 E-11

ACPR IS95 Repeatability

0,05

0,1

0,15

0,2

0,25

0,3

0,35

10 100 1000

Sweep tim e/m s

Standard dev /dB

Adjacent channels

Alternate channels

Txchannel

Fig. 2-22 Repeatability of adjacent channel power measurements on CDMA 2000 signals in

the fast ACP mode

Note on adjacent channel power measurements on 2000 MC1 base–station signals:

When measuring the adjacent channel power of 2000 MC1 base–station signals, the frequency spacing

of the adjacent channel to the nominal transmit channel is specified as ±750 kHz. The adjacent

channels are, therefore, so close to the transmit channel that the power of the transmit signal

leaks across and is also measured in the adjacent channel if the usual method using the 30

kHz resolution bandwidth is applied. The reason is the low selectivity of the 30 kHz resolution

filter. The resolution bandwidth, therefore, must be reduced considerably, e.g. to 3 kHz to avoid

this. This causes very long measurement times (factor of 100 between a 30 kHz and 3 kHz

resolution bandwidth).

This effect is avoided with the zero span method which uses steep IF filters. The 30 kHz channel filter

implemented in the R&S FSL has a very high selectivity so that even with a ± 750 kHz spacing

to the transmit channel the power of the useful modulation spectrum is not measured.

Measurements on Modulated Signals R&S FSL

1300.2519.12 2.30 E-11

The following figure shows the passband characteristics of the 30 kHz channel filter in the R&S FSL.

Fig. 2-23 Frequency response of the 30 kHz channel filter for measuring the power in the 2000 MC1

adjacent channel

Measurement example 2 – Measuring adjacent channel power of a W–CDMA uplink

signal

Test setup:

Signal

generator R&S FSL

Signal generator settings (e.g. R&S SMU):

Frequency: 1950 MHz

Level: 4 dBm

Modulation: 3 GPP W–CDMA Reverse Link

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is in its default state.

2. Set the center frequency to 1950 MHz.

Press the FREQ key and enter 1950 MHz.

R&S FSL Measurements on Modulated Signals

1300.2519.12 2.31 E-11

3. Switch on the ACP measurement for W–CDMA.

Press the MEAS key.

Press the CP, ACP, MC–ACP softkey.

Press the CP / ACP Standard softkey.

In the standards list, mark W–CDMA 3GPP REV using the rotary knob or the arrow keys and

confirm pressing the rotary knob or the ENTER key.

The R&S FSL sets the channel configuration to the 3GPP W–CDMA standard for mobiles with

two adjacent channels above and below the transmit channel. The frequency span, the

resolution and video bandwidth and the detector are automatically set to the correct values. The

spectrum is displayed in the upper part of the screen and the channel power, the level ratios of

the adjacent channel powers and the channel configuration in the lower part of the screen. The

individual channels are displayed as vertical lines on the graph.

4. Set the optimum reference level and the RF attenuation for the applied signal level.

Press the Adjust Ref Level softkey.

The R&S FSL sets the optimum RF attenuation and the reference level for the power in the

transmission channel to obtain the maximum dynamic range. The following figure shows the

result of the measurement.

Fig. 2-24 Measuring the relative adjacent channel power on a W–CDMA uplink signal

5. Measuring adjacent channel power with the fast ACP mode.

Set Fast ACP softkey to On.

Press the Adjust Ref Level softkey.

The R&S FSL measures the power of the individual channels with zero span. A root raised

cosine filter with the parameters =0.22 and chip rate 3.84 Mcps (= receive filter for 3GPP W–

CDMA) is used as channel filter.

Measurements on Modulated Signals R&S FSL

1300.2519.12 2.32 E-11

Fig. 2-25 Measuring the adjacent channel power of a W–CDMA signal with the fast ACP

mode

Note: With W–CDMA, the R&S FSL's dynamic range for adjacent channel measurements is limited by

the 12–bit A/D converter. The greatest dynamic range is, therefore, obtained with the IBW

method.

Optimum Level Setting for ACP Measurements on W–CDMA Signals

The dynamic range for ACPR measurements is limited by the thermal noise floor, the phase noise and

the intermodulation (spectral regrowth) of the spectrum analyzer. The power values produced by the

R&S FSL due to these factors accumulate linearly. They depend on the applied level at the input mixer.

The three factors are shown in the figure below for the adjacent channel (5 MHz carrier offset).

-80

-75

-70

-65

-60

-55

-50

-45

-40

-35

-30

-40 -35 -30 -25 -20 -15 -10

Mixer Level / dBm

ACLR / dBc

S.R.I.

Optimum Range

Phase

Noise

Total

ACLR

Thermal Noise

Fig. 2-26 The R&S FSL's dynamic range for adjacent channel power measurements on W–CDMA

uplink signals is a function of the mixer level.

R&S FSL Measurements on Modulated Signals

1300.2519.12 2.33 E-11

The level of the W–CDMA signal at the input mixer is shown on the horizontal axis, i.e. the measured

signal level minus the selected RF attenuation. The individual components which contribute to the

power in the adjacent channel and the resulting relative level (total ACPR) in the adjacent channel are

displayed on the vertical axis. The optimum mixer level is –21 dBm. The relative adjacent channel

power (ACPR) at an optimum mixer level is –65 dBc. Since, at a given signal level, the mixer level is set

in 10 dB steps with the 10 dB RF attenuator, the optimum 10 dB range is shown in the figure: it spreads

from –16 dBm to –26 dBm. In this range, the obtainable dynamic range is 62 dB.

To set the attenuation parameter manually, the following method is recommended:

•Set the RF attenuation so that the mixer level (= measured channel power – RF attenuation) is

between –11 dBm and –21 dBm.

•Set the reference level to the largest possible value where no overload (IFOVL) is indicated.

This method is automated with the Adjust Ref Level function. Especially in remote control mode, e.g.

in production environments, it is best to correctly set the attenuation parameters prior to the

measurement, as the time required for automatic setting can be saved.

Note: To measure the R&S FSL's intrinsic dynamic range for W–CDMA adjacent channel power

measurements, a filter which suppresses the adjacent channel power is required at the output

of the transmitter. A SAW filter with a bandwidth of 4 MHz, for example, can be used.

Amplitude Distribution Measurements

If modulation types are used that do not have a constant zero span envelope, the transmitter has to

handle peak amplitudes that are greater than the average power. This includes all modulation types that

involve amplitude modulation –QPSK for example. CDMA transmission modes in particular may have

power peaks that are large compared to the average power.

For signals of this kind, the transmitter must provide large reserves for the peak power to prevent signal

compression and thus an increase of the bit error rate at the receiver.

The peak power or the crest factor of a signal is therefore an important transmitter design criterion. The

crest factor is defined as the peak power / mean power ratio or, logarithmically, as the peak level minus

the average level of the signal.

To reduce power consumption and cut costs, transmitters are not designed for the largest power that

could ever occur, but for a power that has a specified probability of being exceeded (e.g. 0.01%).

To measure the amplitude distribution, the R&S FSL has simple measurement functions to determine

both the APD = Amplitude Probability Distribution and CCDF = Complementary Cumulative Distribution

Function.

In the APD display mode, the probability of occurrence of a certain level is plotted against the level.

In the CCDF display mode, the probability that the mean signal power will be exceeded is shown in

percent.

Measurements on Modulated Signals R&S FSL

1300.2519.12 2.34 E-11

Measurement example – Measuring the APD and CCDF of white noise generated by

the R&S FSL

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is in its default state.

2. Configure the R&S FSL for APD measurement

Press the AMPT key and enter –60 dBm.

The R&S FSL's intrinsic noise is displayed at the top of the screen.

Press the MEAS key.

Press the More softkey.

Press the APD softkey.

The R&S FSL sets the frequency span to 0 Hz and measures the amplitude probability

distribution (APD). The number of uncorrelated level measurements used for the measurement

is 100000. The mean power and the peak power are displayed in dBm. The crest factor (peak

power – mean power) is output as well.

Fig. 2-27 Amplitude probability distribution of white noise

3. Switch to the CCDF display mode.

Press the Hkey.

Press the CCDF softkey.

The CCDF display mode is switched on.

R&S FSL Measurements on Modulated Signals

1300.2519.12 2.35 E-11

Fig. 2-28 CCDF of white noise

The CCDF trace indicates the probability that a level will exceed the mean power. The level

above the mean power is plotted along the x–axis of the graph. The origin of the axis

corresponds to the mean power level. The probability that a level will be exceeded is plotted

along the y–axis.

4. Bandwidth selection

When the amplitude distribution is measured, the resolution bandwidth must be set so that the

complete spectrum of the signal to be measured falls within the bandwidth. This is the only way of

ensuring that all the amplitudes will pass through the IF filter without being distorted. If the

resolution bandwidth which is selected is too small for a digitally modulated signal, the amplitude

distribution at the output of the IF filter becomes a Gaussian distribution according to the central

limit theorem and so corresponds to a white noise signal. The true amplitude distribution of the

signal therefore cannot be determined.

5. Selecting the number of samples

For statistics measurements with the R&S FSL, the number of samples NSamples is entered for

statistical evaluation instead of the sweep time. Since only statistically independent samples

contribute to statistics, the measurement or sweep time is calculated automatically and displayed.

The samples are statistically independent if the time difference is at least 1/RBW. The sweep time

SWT is, therefore, expressed as follows:

SWT = NSamples / RBW

Bluetooth Measurements (Option K8) R&S FSL

1300.2519.12 2.36 E-11

Bluetooth Measurements (Option K8)

This section gives background information on Bluetooth Measurements (option K8). It provides

information on the following topics:

Bluetooth Overview

Supported Tests

Overview of Transmitter Tests

Functional Description – Block Diagram

Bandwidths

Measurement Filter (Meas Filter On)

Oversampling

Determining Average or Max/Min Values

Trigger Concepts

For further information on measurement examples refer also to the Quick Start Guide, chapter 5 "Basic

Measurement Examples".

This option is available from firmware version 1.30.

Bluetooth Overview

This section provides the following general information on Bluetooth measurements:

Bluetooth technical parameters

Power classes

Structure of a Bluetooth data packet

R&S FSL Bluetooth Measurements (Option K8)

1300.2519.12 2.37 E-11

Bluetooth technical parameters

Table 2–1 Common Parameters

frequency bands 2402 + (0...78) MHz

channel spacing 1 MHz

symbol rate 1 Msym/s

slot length

(frequency hopping)

625 µsec

packet sizes 1, 3, 5 slot packets

Table 2–2 Modulation Parameters Basic Rate

modulation GFSK

TX filter Gaussian

BT / 0.5

modulation index 0.28 – 0.35 nominal 0.32

frequency deviation 160 kHz settled

141 kHz 010101 suite

bandwidth

–3dB

–20dB

220 kHz

1MHz

bit rate 1 Mbps

Table 2–3 Modulation Parameters Enhanced Data Rate

modulation T/4–DQPSK 8DPSK

TX filter RRC RRC

roll–off factor 0.4 0.4

bandwidth –3dB ± 500kHz ± 500kHz

bit rate 2 Mbps 3 Mbps

Power classes

Power Class Maximum (Pmax)Nominal Minimum (Pmin)Power Control

1100 mW (20 dBm) 1 mW (0 dBm) from Pmin (< +4 dBm) to

Pmax

22.5 mW (4dBm) 1 mW (0 dBm) 0.25 mW (–6dBm) optional

3 1 mW (0dBm) optional

Bluetooth Measurements (Option K8) R&S FSL

1300.2519.12 2.38 E-11

Structure of a Bluetooth data packet

Every Bluetooth data packet is divided into 3 basic section: access code, header and payload. The

following figures show the order and bit lengths of the individual sections:

access code 72 bits

4bits

preamble

64 bits

sync word

4bits

trailer

54 bits

header

240 / 1496 / 2744 bits

payload*)

*) During EUT evaluation the payload contains certain bit sequences: PRBS9 (Pseudo Random Bit

Sequence) or 11110000 or 10101010.

The sync word is transmitted as the major part of the access code. For this purpose, the LAP (lower

address part) of the BD address is expanded to 64 bit by adding the BCH code and baker.

sync word 64 bits

BCH code 34 bits LAP 24 bits Barker 6 bits

The LAP (lower address part) of the BD address serves as a basis for the sync word.

BD – address 48 bits

NAP 16 bits UAP 8 bits LAP 24 bits

In case of EDR packets the payload is divided into 6 other sections:

DPSK

guard

5Rs

SYNC payload

header

user payload

0–2723Symb

CRC

code

trailer

Supported Tests

The Bluetooth Measurements Option supports measurements according to the Bluetooth RF Test

Specification (Bluetooth SIG) , Revision 2.0.E.3, Mar 2005, on the R&S FSL. The following tests are

currently implemented according to this specification:

Output Power

TX Output Spectrum – Adjacent Channel Power

Modulation Characteristics

Initial Carrier Frequency Tolerance (ICFT)

Carrier Frequency Drift

EDR Relative Transmit Power

EDR Carrier Frequency Stability and Modulation Accuracy

EDR Differential Phase Encoding

EDR In–band Spurious Emissions

R&S FSL Bluetooth Measurements (Option K8)

1300.2519.12 2.39 E-11

Overview of Transmitter Tests

Table 2–4 Basic Rate Measurements

Output Power TX Output

Spectrum –

Adjacent

Channel Power

Modulation

Characteristics

Initial Carrier

Frequency

Tolerance

Carrier

Frequency

Drift

Hop on off off on / off on / off

Trigger extern – – – –

Synchronization Yes (p0), but also

possible without

no yes (p0) yes (p0) yes (p0)

Packet Type longest supported DH1 longest supported DH1 all supported

packets

(DH1/3/5)

Payload PRBS 9 PRBS 9 11110000

10101010

PRBS 9 10101010

Test Mode loop back loop back loop back loop back loop back

Operating Mode IQ mode analyzer zero

span

IQ mode IQ mode IQ mode

RBW 3MHz 100 kHz – – –

VBW 3MHz 300 kHz – – –

Power supported

maximum

supported

maximum

supported

maximum

supported

maximum

not specified

Sweep Time one complete

packet

79s per sweep

(= 100ms * 10 *

79)

one complete

packet

–one complete

packet

Sweep Count –10 10 (extern) 10 10

Trace Mode Maxh Maxh – – –

Detector Peak Aver – – –

Frequency in

MHz

low /

middle /

high

each channel low /

middle /

high

low /

middle /

high

low /

middle /

high

Span – – – – –

Test cond norm / ext norm / ext norm / ext norm / ext norm / ext

Results peak and average

power

1) PAV < 100 mW

(20 dBm)

2) PPK < 200 mW

(23 dBm)

3) Pmax > PAV

>Pmin at maximum

power step

AV < 1

mW (0 dBm)

channel power of

all channels

1) PTX (f) –20

dBm for |M–N| =

2) PTX (f) –40

dBm for |M–N| 

all 8 bit peak

deviations and

average

deviations

carrier offset

within the 4

preamble bits

carrier offsets

of the 4 bit

preamble, of all

10 bit payload

sequences;

maximum drift

rate of all 10 bit

payload

sequences at

50 µsoffset

Bluetooth Measurements (Option K8) R&S FSL

1300.2519.12 2.40 E-11

Table 2–5 Enhanced Data Rate Measurements

EDR Relative TX

Power

EDR Carrier

Frequency

Stability and

Modulation

Accuracy

EDR Differential

Phase Encoding

EDR In–band

Spurious

Emissions

Hop off off off off

Trigger – – – extern/

IF power

Synchronization yes yes yes yes, needed for

gate adjustment

Packet Type longest supported longest

supported

longest supported longest supported

Payload PRBS 9 PRBS9 PRBS9 PRBS9

Test Mode loop back loop back TX mode loop back

Operating Mode IQ mode IQ mode IQ mode analyzer zero

span

RBW 3MHz – – 100 kHz

VBW 3MHz – – 300 kHz

Power supported

minimum/

maximum

supported

minimum/

maximum

supported

minimum/

maximum

supported

minimum/

maximum

Sweep Time one complete

packet

one complete

packet

one complete

packet

10*79*

gate length

Sweep Count 10 200 blocks 100 10

Trace Mode ClrWr – – Maxh

Detector Aver – – Aver

Frequency in

MHz

low /

middle /

high

low /

middle /

high

low /

middle /

high

each channel

Span – – – 79 MHz

Test cond norm / ext norm / ext norm / ext norm / ext

Results ratio of DPSK and

GFSK power

carrier frequency

stability and

error vector

magnitude

number of failed

packets

channel power of

all channels

Functional Description – Block Diagram

The Adjacent Channel Power and EDR In–band Spurious Emissions measurements are performed in

the Spectrum Analyzer mode. For this test case the complete frequency band is scanned using a

sequence of zero span measurements.

All other test cases are based on a digital I/Q demodulator which determines the temporal

characteristics of power and frequency. The output data of the demodulator are the basis for calculation

of all relevant measurement results like modulation characteristics or output power. The demodulator

reaches a maximum in accuracy and temperature stability by sampling the IF signal and converting it

digitally down into the base band (I/Q area).

R&S FSL Bluetooth Measurements (Option K8)

1300.2519.12 2.41 E-11

The measurements are performed by passing the following signal processing steps:

LAP (Lower Address Part) trigger detection

Resampling

Channel filtering

Automated packet and bit pattern detection

Limit check

Parallel display of measurement curves and numeric results on the screen

Fig. 2-1 shows the R&S FSL hardware from the IF to the processor. The analog IF filter is fixed to

20MHz. The A/D converter samples the 20 MHz IF signal with a sampling frequency of 65.83 MHz.

Low pass filtering is performed after the signal has been down–converted into the complex base band

and the data rate is reduced in the sequence. The amount of decimation depends on the selected

oversampling factor = points / symbol. The default setting is 4, resulting in a 4 MHz sampling rate. For

EDR–measurements, the oversampling factor is always fixed to 4. The resulting I/Q data are stored in a

memory of 512 k words for I and Q respectively. The hardware trigger (external or IF power) controls

the memory access.

IMemory

512 k

Processor

Analogfilter

Bandwidths

20 MHz

Analyzer IF

47,9 MHz

A/D

converter

65,83 MHz

sampling

clock

Digital down conversion

+decimation

cos

sin

decimation

filters

NCO

47,9 MHz

QMemory

512 k

sampling rate

65,83 MHz / x

Data aquisition hardware

Idata

Qdata

Trigger

SW -

Resampler

Fig. 2-29 Block diagram of the signal processing architecture of the R&S FSL

Bandwidths

The Bluetooth RF Specification defines a minimal bandwidth of 3 MHz. The digital bandwidth depends

on the selected oversampling factor (= points / symbol). With the default setting of 4, the digital

bandwidth is 3 MHz. This digital filter has a flat amplitude characteristics and does not affect the

frequency deviation of the signal.

Measurement Filter (Meas Filter On)

The RF Specification allows high distortion power in the first adjacent channels. The 3 MHz filter does

not suppress this kind of distortion, which leads to a high interference in modulation. Therefore a

precise measurement of the frequency deviation is not possible.

In order to obtain correct deviation results, the spectrum analyzer supplies an optional filter with a

passband only appropriate for the channel to measure. This filter is used by default. The Bluetooth

spectrum has a bandwidth of 1 MHz. The filter is flat within 1.04 MHz (ripple: only 0.02 dB) and has

steep edges. This measurement filter is not dependent on the selected oversampling factor. As a result

Bluetooth Measurements (Option K8) R&S FSL

1300.2519.12 2.42 E-11

the displayed deviation value is increased by 3.2%, but without the filter the displayed deviation value

can increase dramatically due to interference from adjacent channels. Generally the result is more

precise, if the displayed deviation is lower with filtering than without filtering. In these cases the

inaccuracy caused by the adjacent channel interference is higher than the systematic inaccuracy

caused by the filter.

-30

-50

-10

-2.0 -1.6 -1.2 -0.8 -0.4 +2.0+1.6+1.2

-60

-20

-40

MHz

+0.8+0.40

-60

-40

-20

Fig. 2-30 Selection of digital filters

Dashed–dotted curve: Standard filter with 4 points / symbol

Solid curve: Optional measurement filter, independent of the points / symbol setting

Oversampling

The number of samples per symbol is equivalent to the sampling rate in MHz (due to the symbol length

of 1 Rs).

Digital

bandwidth

(flat area)

Points per

Symbol

Sampling rate

10 MHz 32 32 MHz

8MHz 16 16 MHz

5MHz 8 8 MHz

3.0 MHz 4 4 MHz

1.6 MHz 2 2 MHz

According to the RF Test Specification an oversampling factor of 4 is required at minimum. For Basic

Rate measurements, this oversampling factor can be selected as oversampling factor in a range from 2

to 32. For EDR–measurements, the oversampling factor is fixed to 4 which is also the default value.

Although possible but not recommended is a value > 4. It increases the measurement time due to the

extended calculation effort. Additionally the resulting bandwidth will be larger than required, which leads

to lower measurement accuracy, unless the optional measurement filter (Meas Filter On) is used as

described in section Bandwidths.

The spectrum analyzer uses a timing offset correction in order to move the samples to the zero

trespassing points. As a result there is one sample per symbol time, which is especially important for a

0101 symbol sequence in order to obtain the precise value for the peak frequency deviation.

R&S FSL Bluetooth Measurements (Option K8)

1300.2519.12 2.43 E-11

Sampling times before timing offset correction Sampling times after timing offset correction

Fig. 2-31 Operation of the timing offset correction

Advantages of the timing offset correction:

No jitter with low sampling rates

With one sample per zero, the trespassing point is always a sample in the middle of the bit length.

Therefore the maximum values in the frequency deviation of 0101 bit patterns can be detected

precisely also with low sampling rates.

The immunity to interference when determining the data bits is improved.

Higher suppression of the distortion during peak detection.

Determining Average or Max/Min Values

These functions are very useful in order to obtain more stable results or to find sporadic spurious

signals not included in every burst. In many cases the RF Test Specification defines measurements

over a 10 burst period.

The number of measurements can be selected using sweep count function, thus adapting the

measurement to the individual requirements.

In single sweep mode, the calculation of average or maximum / minimum values is performed over a

well–defined number of sweeps (= sweep count).

Continuous sweep mode yields continuous averaging and calculation of maximum / minimum values

over the whole measurement time.

Modulation measurements

They are performed in the Clear Write trace mode.

In continuous sweep mode, a "live" display is obtained, which allows e.g. an instant view of changes

during alignment of a DUT.

In single sweep mode and with the sweep count set to 10, the spectrum analyzer will evaluate 10 bursts

as required by the RF Test Specification. This means that a result is obtained after exactly 10 bursts.

Power measurements

They are performed in the Maxhold trace mode in relation with the defined measurement time. The

measurement time is selected in order to make sure that always one complete burst is acquired. In this

case, several sweeps are combined to one trace before this result trace is evaluated.

Bluetooth Measurements (Option K8) R&S FSL

1300.2519.12 2.44 E-11

Impact of the sweep count on the measurement results

Trace Mode Continuous Sweep Single Sweep & Sweep Count

Clear Write All measurement results (min., max.,

average) are updated with every sweep.

The corresponding values are

calculated based on the current curve.

Starts a measurement with n sweeps (n

=sweep count).

All measurement results (min., max.,

average) are calculated based on these

nsweeps.

AVG, MaxHold, MinHold All measurement results (min., max.,

average) are updated with every sweep.

The corresponding values are

calculated based on the current curve.

The trace is the continuous average

value (AVG) or the extreme value

(MaxHold, MinHold) since the start of

the measurement.

Starts a measurement with n sweeps (n

=sweep count).

ndefines the number of sweeps that

are taken into account for the trace

math functions (AVG, MaxHold,

MinHold). The n sweeps result in one

trace and the measurement results

(Min, Max, Average) are calculated

based on this summarized trace.

The functions described above differ from the detector functions of the instrument:

Detectors combine the measurement data obtained by oversampling to one measurement point on

the screen. The kind of combination (Max Peak, Min Peak, Average, RMS) can be selected.

The trace functions affect complete measurement curves: A resulting curve is calculated from

several subsequent sweeps. The method of calculation (Average, Maxhold, Minhold) can be

selected here as well.

Thus the detector is the arithmetic rule for how sample data collected with a high data rate are

combined to a measurement point of one individual measurement curve, whereas the trace mode is the

rule of how samples taken from several measurement curves are to be combined to a new resulting

curve.

For the ACP measurement, the Average detector is set.

Trigger Concepts

As the DUT (Device Under Test) uses frequency hopping, a trigger method is necessary for two

reasons:

Ameasurement is only possible during the period of time, when there is a TX signal (burst) at the

frequency under request.

In order to determine the modulation characteristics correctly, a synchronization with the preamble

of the signal must be supplied.

If the Find Sync softkey is activated, the synchronization is supplied towards the 64 bit sync word. For

this purpose, in a first step a burst is searched automatically within the RF signal, or, if selected, the

external trigger or the IF power trigger are used to determine the burst position.

In a second step the sync word position is searched by correlation of the signal with the sync word

defined in the initialization phase. The correlation is performed directly with the FM signal, not with the

data bits, which are only available after the phase shifter has been processed. The find burst process is

continued as long as no sync word is found.

After the position of the sync word has been determined, the position of the p0 bit is calculated from the

average value of all zero trespassing points, as defined in the RF test specification. Finally the samples

are moved in a way that each sample matches one zero trespassing point (phase shifting).

The only measurement possible without synchronization is the Output Power measurement. The

specified measurement time is 20% to 80% of the burst length. Without synchronization the burst length

is defined via the –3dB points of the power curve. With synchronization the burst starts with the p0 bit.

R&S FSL Bluetooth Measurements (Option K8)

1300.2519.12 2.45 E-11

Therefore varying measurement results is possible if the power of the EUT is not constant within the

burst.

In order to supply stable synchronization the EUT must be operated in reduced hopping mode. The

EUT is only allowed to toggle between two frequencies, because otherwise the repetition time for the

same frequency would become higher than the record length.

If the test environment supplies an external trigger that marks the channel to be measured a

synchronization is also possible with normal hopping operation.

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 2.46 E-11

Cable TV Measurements (Option K20)

This section describes measurement examples for the Cable TV Measurements option (K20). and is

divided into the following topics:

Analog TV Basics

gives an introduction into the fundamentals of analog modulated TV signals.

Analog TV Measurement Examples

describes the test setup, settings for analog TV measurements and gives examples for the different

measurement type.

Digital TV Basics

gives an introduction into the fundamentals of digital modulated TV signals.

Digital TV Measurement Examples

gives an introduction into the fundamentals of digital modulated TV signals.

Channel Tables and Modulation Standards

explains the use of channel tables and modulation standards.

Performing a Measurement without a Channel Table

shows how to perform a measurement without using a channel table.

Performing a Measurement Using a Channel Table

gives an example how to perform a measurement using a channel table.

For further information on measurement examples refer also to the Quick Start Guide, chapter 5 "Basic

Measurement Examples".

This option is available from firmware version 1.30.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 2.47 E-11

Analog TV Basics

This section gives an introduction into the fundamentals of analog modulated TV signals. A special

focus is laid on the parameters that the Cable TV Measurements option (K20) uses to characterize

signals.

For analog modulated TV signals based on PAL, SECAM, and NTSC, Fig. 2-32 shows the situation in

principle: the components of the signal, and both frequency and level at the output of a TV transmitter

(RF range).

Fig. 2-32 Analog modulated signals in the RF range

The gray area marks the TV channel. Inside this area, all components of a TV signal are located. A TV

signal consists of the following:

•The vision carrier, indicated in Fig. 2-32 with "vision", is located 1.25 MHz above the channel

start. The vision carrier has the highest level and mainly assesses the total power of the

channel. It transmits the luminance information and is amplitude modulated. The amplitude

modulation is mostly negative (the smaller the luminance signal the larger the vision carrier

level), apart from SECAM/L (large vision carrier level combined with a large luminance signal).

Only a part (around 0.75 MHz) of the lower sidebands of the vision carrier is transmitted.

Therefore it is called "residual sideband modulation". The video bandwidth BWvideo amounts to,

depending on the standard, approx. 5 MHz (e.g. PAL B/G) or approx. 4 MHz (e.g. M/NTSC).

•The color carrier, indicated in Fig. 2-32 with "color", is shifted by fcolor to a higher frequency

value in respect to the vision carrier. The magnitude of fcolor depends on the standard. The level

of the color carrier is by far smaller than that of the vision carrier. Depending on the standard,

the signal is analog quadrature amplitude modulated (e.g. PAL B/G) or frequency modulated

(SECAM).

The color carrier is not considered in the measurements of the Cable TV Measurements option.

•One or two sound carriers, indicated in Fig. 2-32 with "sound 1" and "sound 2", are shifted by

fsound1 or fsound2 to a higher frequency value in respect to the vision carrier. The magnitude of

fsound1 or fsound2 depends on the standard. The level of the sound carriers is by far smaller than

that of the vision carrier. Depending on the standard, the sound carriers are frequency,

amplitude, or NICAM (digitally) modulated. The sound carriers do not need to possess the

same modulation. For example, a combination of a frequency modulated carrier with a NICAM

modulated carrier is possible.

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 2.48 E-11

The large diversity of TV standards based on PAL, SECAM und NTSC differ not only in the parameter

described above. Some other parameter are for example:

•number of picture lines and their duration

•form and group delay of the residual sideband filter

•parameters of the used AM / FM / NICAM modulations (e.g. modulation depth, frequency

deviation, symbol rate)

•channel width and frequency range of the channels (different from country to country)

•stereo and mono sound signals, stereo transmission type

Analog TV Measurement Examples

These measurements are set up to carry out single channel measurements of analog TV signals. The

settings for analog TV measurements are described in section Analog TV settings.The test setup for

the following measurement types is provided in section Analog TV test setup.

Spectrum measurement

Carriers measurement

Video Scope measurement

Vision Modulation measurement

Hum measurement

C/N measurement

CSO measurement

CTB measurement

Analog TV settings

The Cable TV Measurements option needs to know some of the parameters described in section

Analog TV Basics to perform correct measurements. It therefore stores these parameters in the so–

called "modulation standard". Refer to section Modulation standards for the creation and usage of a

modulation standard. Section Analog TV modulation standards contains the description of the

parameters that have to be characterized for an analog TV signal. The following list explains the

meaning of the parameters:

•Name:Choose an arbitrary name for the new modulation standard.

•Signal Type:If you want to characterize an analog TV signal, select Analog TV.

•TV Standard:The standard used to modulate the luminance information. Can be "B/G", "M",

"D/K" and so on.

•Sound System:Are one ore two sound carriers in use? What type of modulation is used for

each of them? What are their frequencies, relative to the vision carrier?

The selection "FM 5.5/ FM 5.742" for example specifies, that two frequency modulated sound

carriers are used. One is 5.5 MHz and is about 5.472 MHz above the vision carrier.

The values you can choose depend on the selected TV standard. Not all combinations are

allowed!

•Group Delay:What group delay shall the residual sideband filter have?

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 2.49 E-11

•Color System:The color information of the video signal is transmitted according to either the

PAL or NTSC or SECAM standard. The values you can choose depend on the selected TV

standard. Not all combinations are allowed!

•Bar Line: The Vision Modulation measurement needs a special test signal, containing a peak

white value. You must specify the type and the number of the horizontal line that contains the

peak white value.

•Quiet Line: Some measurements need a horizontal line with no video information in it. You

must specify the number of this horizontal line here. For further information see also Example:

Creating a channel table.

•Sideband Position: Is the signal in normal position or inverted?

Note: In the dialog boxes, set the parameters always from top to bottom, since all parameters depend

on the parameters above them. Otherwise your input might be rejected, e.g. if it specifies an

unusual TV standard.

Analog TV test setup

This section describes the setup used for the analog TV measurement examples. All analog

measurement examples are performed in the Cable TV Analyzer mode.

1. Press the MENU key to display the cable TV measurements main menu.

2. Press the Channel Setup softkey.

3. In the Channel Tables dialog box, select channel table <none>.

4. Press the Activate softkey.

The TV standard is automatically set to the default analog TV modulation standard, which has the

following parameters (see also Analog TV settings).

Signal Type = Analog TV

TV Standard = B/G

Sound System = FM 5.5 / FM 5.742

What kind of sound carrier(s) are used.

Group Delay = General

This setting has no effect on the measurements in this firmware release.

Color System = PAL

Bar Line = 18

Type = CCIR 17

Where is the "white reference'' and of what kind is it? The Vision Modulation measurement

demands correct settings!

Quiet Line = 22

Which horizontal line shall be used for "Quiet Line'' based CNR / CSO measurement. This line

shall have no video information!

Sideband Position = Normal

Only change this setting if you have inverted sidebands.

As long as you measure without a channel table, the Cable TV Measurements option expects a

signal with these parameters. If your signal does not fit, some measurements may fail.

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 2.50 E-11

5. If you use an analog TV test transmitter, configure it to transmit a suitable signal:

Choose a reasonable, not too high output level.

Set the transmitters's vision carrier frequency to 210.25 MHz.

6. If your test transmitter is not capable of this or if you want to connect the R&S FSL to your CATV

network, which does not contain a suitable signal, change the default analog TV modulation

standard:

Press the MEAS key.

Press the Analog TV softkey.

Press the Analog TV Settings softkey.

Change the default analog TV modulation standard as described in section Analog TV

modulation standards in order to adapt it to the signal you provide for the R&S FSL.

Spectrum measurement

This measurement gives an overview of the active measurement channel. It is a swept measurement

like in the Spectrum Analyzer mode. All parameters are set automatically according to the used

modulation standard. The spectrum is displayed in a full screen trace.

Test setup:

Refer to the section Analog TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the Spectrum softkey.

4. To adjust the input attenuator, press the Adjust Attenuation softkey.

5. Press the FREQ key.

6. Enter 210.25 MHz for the vision carrier frequency of the input signal. Note that this frequency is not

the middle of the shown span.

7. Press the RUN key.

The spectrum of the input signal is displayed.

The vertical lines mark the vision carrier (VC) and sound carrier (SC1 and SC2) frequencies. They

mark the ideal frequencies according to the chosen standard and RF frequency, not the measured

ones.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 2.51 E-11

Fig. 2-33 Analog TV Spectrum measurement

Carriers measurement

This measurement determines the carrier power (vision carrier, one or two sound carriers) and the

frequency distances. It also compares them against the default values. The sound carrier power is

displayed relative to the measured vision carrier power.

The measurement display is split into two panes. In the upper pane, the spectrum as in the

corresponding Spectrum measurement is displayed. In the lower pane, the result table for the

measurement is displayed.

Test setup:

Refer to the section Analog TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the Carriers softkey.

4. To change the limits, press the Edit Table softkey.

5. To adjust the input attenuator, press the Adjust Attenuation softkey.

6. Press the FREQ key.

7. Enter 210.25 MHz for the vision carrier frequency of the input signal.

8. Press the RUN key.

The upper pane gives a quick overview of the channel, just like in the Spectrum measurement.

In the lower pane, you can check whether the signal meets the requirements. Absolute and relative

powers and frequencies are measured and compared against the limits. The result is either Pass or

Fail.

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 2.52 E-11

In the measurement example, all results were within the chosen limits, except the absolute power of

the vision carrier. This is indicated by red color and a star.

Fig. 2-34 Analog TV Carriers measurement

Note: The "frequency offsets'' are measured in this way:

For sound carriers:

The TV standard demands that the sound carrier frequency shall be f1Hz greater than the

vision carrier frequency. The actual frequency distance might be measured to be f2.

The value "Intercarrier frequency offset'' is therefore: f2– f1.

For the vision carrier:

The value ''frequency offset'' is the measured vision carrier frequency minus the RF frequency.

Video Scope measurement

This measurement determines the luminance signal in dependence of the time. The video scope is

triggered by the chosen trigger event, i.e. the line to be analyzed. From the result trace, the effects of

hum are eliminated ("back porch clamping").

Test setup:

Refer to the section Analog TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the More softkey.

4. Press the Video Scope softkey.

5. For the TV standard Min combination with another color system than PAL,press the Field 1/2

softkey to select field 1 or 2.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 2.53 E-11

6. Press the Line softkey to enter the line number.

7. To change the sweep time, press the Sweeptime Manual softkey and enter a value (25Rs up to

100 Rs).

8. To define a trigger offset, press the Trigger Offset softkey and enter a value (–50 Rs up to 50 Rs).

Choose 0 Rsto make the display start with the horizontal sync of the specified line. Negative values

make the display start earlier.

9. To adjust the input attenuator, press the Adjust Attenuation softkey.

10. Press the FREQ key.

11. Enter 210.25 MHz for the vision carrier frequency of the input signal.

12. Press the RUN key.

The trace shows the luminance signal during the selected period versus time. The group delay is

not compensated internally.

Fig. 2-35 Video Scope measurement

Vision Modulation measurement

This measurement determines the "residual picture carrier'' and the modulation depth of the vision

carrier.

The vision carrier is amplitude modulated (AM). To be more precise, it uses the residual sideband

amplitude modulation. Most standards use negative amplitude modulation. Therefore, the vision carrier

has its highest level when the luminance signal is equal to the "synchronizing level''. And it has its

lowest level when the luminance signal is equal to the "peak white level''. The "synchronizing level'' can

be measured in every horizontal synchronizing pulse. The "peak white level'' can be measured in

special test lines ("bar line"), where a white reference is transmitted.

The residual picture carrier is the ratio of the "peak white level" to the "synchronizing level". The sum of

the vision carrier's modulation depth and the residual picture carrier value must equal 1.

The measurement display is split into two panes. In the upper pane, the RF level of the vision carrier

during one horizontal line is displayed. In the lower pane, the result table for the measurement is

displayed.

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Test setup:

Refer to the section Analog TV test setup.

Procedure:

1. Press the MEAS key.

2.Press the Analog TV softkey.

3. Press the More softkey.

4. Press the Vision Modulation softkey.

5. To change the limits, press the Edit Table softkey. A limit change in the lower two lines leads to a

change of the other limits, since the measurement results depend on each other.

6. To adjust input attenuator, press the Adjust Attenuation softkey.

7. Press the FREQ key.

8. Enter 210.25 MHz for the vision carrier frequency of the input signal.

9. Press the RUN key.

The upper pane shows the RF level of the vision carrier versus time in the "bar line''. The "bar line''

is a specific horizontal line, that holds a white reference. The number of this line is specified in the

modulation standard of the measured channel. To be more exactly: It is specified in the analog TV

default modulation standard, since no channel table is used right now.

If the input signal does not contain a white reference in the specified line, the results are not correct!

The lower pane shows the numeric results and whether they are within the limits or not.

Fig. 2-36 Vision Modulation measurement

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 2.55 E-11

Hum measurement

This measurement determines whether the signal comprises hum, a not–wanted amplitude modulation

of the analog TV signal, mostly due to defective amplifiers. For the Hum measurement, the AM

modulated frequency must be below 1 kHz and is typically equal to the power line frequency times one

or two, e.g. 50 Hz, 60 Hz, 100 Hz, 120 Hz.

Test setup:

Refer to the section Analog TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the More softkey.

4. Press the Hum softkey.

5. If you want to adjust the range of the y–axis, press the Auto Range softkey.

6. To change the limits, press the Edit Table softkey.

7. To adjust the input attenuator, press the Adjust Attenuation softkey.

8. Press the FREQ key.

9. Enter 210.25 MHz for the vision carrier frequency of the input signal.

10. Press the RUN key.

In case you use a TV test transmitter or your CATV network is in good condition, you will see a

rather flat line, since there will be little hum.

Fig. 2-37 Hum measurement

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1300.2519.12 2.56 E-11

C/N measurement

This measurement determines the ratio of signal power and noise power (carrier to noise), a very

important figure of merit.

The signal power is normally the peak power of the modulated vision carrier, which is the power of the

unmodulated vision carrier. You can modify this default setting with the Reference Power softkey (for

details refer to chapter 4, section "Cable TV Measurements (Option K20)").

The power of the noise is internally measured with a small resolution filter, and then translated to a

user–defined bandwidth, the so–called reference noise bandwidth. This bandwidth should normally be

as large as the video signal bandwidth, i.e. 4 MHz for M/NTSC and 5 MHz otherwise.

The measurement can be performed in 3 different ways, as shown in the following examples:

•C/N Off–Service measurement

•C/N In–Service measurement

•C/N Quiet Line measurement

The measurement display is split into two panes. The upper pane displays the spectrum of the

measured noise. The lower pane displays the result table for the measurement and whether the limits

are passed or failed.

C/N Off–Service measurement

Test setup:

Refer to the section Analog TV test setup.

Procedure:

1. Press the SWEEP key.

2. Press the Single Sweep softkey.

3. Press the FREQ key.

4. Enter 210.25 MHz for the vision carrier frequency of the input signal.

5. Press the MEAS key.

6. Press the Analog TV softkey.

7. Press the C/N softkey.

8. To change the limits, press the Edit Table softkey.

9. To adjust the input attenuator, press the Adjust Attenuation softkey.

10. Press the C/N Setup softkey to open the C/N Setup dialog box.

Make sure, that Off–Service is chosen as measurement mode.

Set the Reference Noise Bandwidth to 5MHz (or another value).

Specify the span for the noise measurement in the table: Change the CF value to 2.5 MHz

(denotes the middle of the span relative to the vision carrier) and the Span value to 5MHz.

If desired, activate the Noise Floor Correction option.

11. Press the RUN key.

12. Turn on the signal when prompted and confirm by pressing the ENTER key.

The R&S FSL will measure the carrier power. This is not visible on the screen.

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13. Turn off the test transmitter or remove the cable when prompted and confirm by pressing the

ENTER key.

The R&S FSL will measure the noise sweeping with a small resolution filter in the span specified in

the C/N Setup dialog box.

14. Press the MKR key and, using the rotary knob, move the marker to the frequency you want to

measure the noise at. The noise density at this marker is measured and translated to the reference

noise bandwidth you specified in step 10.

Fig. 2-38 C/N Off–Service measurement

The lower pane shows the final C/N ratio and whether it is passed or failed. It also shows the most

important correction factors used to calculate the C/N ratio. The Off–Service mode is the most accurate

way to measure C/N, but you must turn off the active channel.

C/N In–Service measurement

Test setup:

Refer to the section Analog TV test setup.

Procedure:

1. Press the SWEEP key.

2. Press the Single Sweep softkey.

3. Press the FREQ key.

4. Enter 210.25 MHz for the vision carrier frequency of the input signal.

5. Press the MEAS key.

6. Press the Analog TV softkey.

7. Press the C/N softkey.

8. To change the limits, press the Edit Table softkey.

9. To adjust the input attenuator, press the Adjust Attenuation softkey.

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10. Press the C/N Setup softkey to open the C/N Setup dialog box.

Make sure, that In–Service is chosen as measurement mode.

Set the Reference Noise Bandwidth to 5MHz (or another value).

Specify the span for the noise measurement: Change the CF value, which denotes the middle of

the span relative to the vision carrier and the Span value in this table. Chose the value CF in a

way, that the span is centered on the gap between 2 analog TV signals. The default value of

–1.25 MHz should be suitable in most cases.

If desired, activate the Noise Floor Correction option.

11. Press the RUN key.

The R&S FSL will first measure the carrier power. This is not visible on the screen. In contrast to

the Off–Service mode, the R&S FSL will not ask you to turn off the signal in the measurement

channel. The noise spectrum is measured in the gap between two active channels. The R&S FSL

measures the noise by sweeping with a small resolution filter in the span you defined in step 10.

12. A marker was automatically set by the R&S FSL. To move this marker, press the MKR key and turn

the rotary knob. The noise density at this marker is measured and translated to the reference noise

bandwidth you specified in step 10.

Fig. 2-39 C/N In–Service measurement

The lower pane shows the final C/N ratio and whether it is passed or failed. It also shows the most

important correction factors used to calculate the C/N ratio.

In In–Service mode the noise reading will be higher and therefore the C/N ratio lower and not as

accurate as in Off–Service mode, due to the active channels. The resulting C/N ratio is just an upper

bound of the real value: If your network passes this quick measurement, it should also pass the more

accurate Off–Service–measurement.

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C/N Quiet Line measurement

Test setup:

Refer to the section Analog TV test setup.

Procedure:

1. Press the SWEEP key.

2. Press the Single Sweep softkey.

3. Press the FREQ key.

4. Enter 210.25 MHz for the vision carrier frequency of the input signal.

5. Press the MEAS key.

6. Press the Analog TV softkey.

7. Press the C/N softkey.

8. To change the limits, press the Edit Table softkey.

9. To adjust the input attenuator, press the Adjust Attenuation softkey.

10. Press the C/N Setup softkey to open the C/N Setup dialog box.

Make sure, that Quiet Line is chosen as measurement mode.

Set the Reference Noise Bandwidth to 5MHz (or another value).

If desired, activate the Noise Floor Correction option.

11. Press the RUN key.

The R&S FSL will first measures the carrier power. This is not visible on the screen. In contrast to

the Off–Service mode, the R&S FSL will not ask you to turn off the signal in the measurement

channel. The noise spectrum is measured by a gated FFT.

Note: The active modulation standard contains a Quiet Line parameter. It tells, in which video line the

vision carrier is not modulated. Be sure to set this parameter correctly (for details refer to

Modulation standards)! The R&S FSL captures IQ data during this line and calculates an FFT.

The result is shown in the upper pane as noise measurement trace.

You do not have to choose the noise measurement frequency by moving a marker like in the Off–

Service mode, instead the R&S FSL automatically calculates the mean noise power. Measurement

values close to any typical CSO beat frequency are omitted in this process (vision carrier and vision

carrier ± n* 0.25 MHz).

This automatically calculated average noise level is translated to the reference noise bandwidth you

specified in step 10.

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Fig. 2-40 C/N Quiet Line measurement

The lower pane shows the final C/N ratio and whether it is passed or failed. It also shows the most

important correction factors used to calculate the C/N ratio.

In Quiet Line mode the noise reading will be not as accurate as in Off–Service mode, due to the still

active channel. But you don't have to turn off channels for a quick check.

CSO measurement

This measurement determines the ratio of signal power and the level of second order beats.

The signal power is normally the peak power of the modulated vision carrier, which is the power of the

unmodulated vision carrier. You can modify this default setting with the softkey Reference Power (for

details refer to chapter 4, section "Cable TV Measurements (Option K20)").

The measurement can be performed in 2 different ways, as shown in the following examples:

•CSO Off–Service measurement

•CSO Quiet Line measurement

The measurement display is split into two panes. The upper pane displays the spectrum of the

measured beats. The lower pane displays the result table for the measurement and whether the limits

are passed or failed.

CSO Off–Service measurement

Test setup:

Refer to the section Analog TV test setup.

Procedure:

1. Press the SWEEP key.

2. Press the Single Sweep softkey.

3. Press the FREQ key.

4. Enter 210.25 MHz for the vision carrier frequency of the input signal.

R&S FSL Cable TV Measurements (Option K20)

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5. Press the MEAS key.

6. Press the Analog TV softkey.

7. Press the CSO softkey.

8. To change the limits, press the Edit Table softkey.

9. To adjust the input attenuator, press the Adjust Attenuation softkey.

10. Press the CSO Setup softkey to open the CSO Setup dialog box.

Make sure, that Off–Service is chosen as measurement mode.

Specify one or multiple spans for the beat measurements, as shown in the figure below. Change

the CF value, which denotes the middle of the span relative to the vision carrier and the Span

value in this table. The measurement ranges should be centered around frequencies where you

expect second order beats in your network.

If desired, activate the Noise Floor Correction option.

11. Press the RUN key.

12. Turn on the signal when prompted and confirm by pressing the ENTER key.

The R&S FSL will measure the carrier power. This is not visible on the screen.

13. Turn off the test transmitter or remove the cable when prompted and confirm by pressing the

ENTER key.

The R&S FSL will measure the beats by sweeping with a small resolution filter in the span specified

in the CSO Setup dialog box.

14. A marker is automatically set. Press the MKR key and, using the rotary knob, move the marker to

the frequency you want to measure the beats at. You should take care not to measure a CTB beat

instead of a CSO beat.

15. Activate all possible second order beat frequencies by pressing the Next Meas Frequency softkey

and then the RUN key. This measures beats in the next span, that is defined in the CSO Setup

dialog box.

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Fig. 2-41 CSO Off–Service measurement

The lower pane shows the final C/N ratio and whether it is passed or failed. It also shows the most

important correction factors used to calculate the CSO ratio. The Off–Service mode is the most

accurate way to measure CSO, but you must turn off the active channel.

CSO Quiet Line measurement

Test setup:

Refer to the section Analog TV test setup.

Procedure:

1. Press the SWEEP key.

2. Press the Single Sweep softkey.

3. Press the FREQ key.

4. Enter 210.25 MHz for the vision carrier frequency of the input signal.

5. Press the MEAS key.

6. Press the Analog TV softkey.

7. Press the CSO softkey.

8. To change the limits, press the Edit Table softkey.

9. To adjust the input attenuator, press the Adjust Attenuation softkey.

10. Press the CSO Setup softkey to open the CSO Setup dialog box.

Make sure, that Quiet Line is chosen as measurement mode.

If desired, activate the Noise Floor Correction option.

11. Press the RUN key.

The R&S FSL will first measures the carrier power. This is not visible on the screen. In contrast to

the Off–Service mode, the R&S FSL will not ask you to turn off the signal in the measurement

channel. The spectrum of the noise and beats is measured by a gated FFT.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 2.63 E-11

12. A marker is automatically set. Press the MKR key and, using the rotary knob, move the marker to

the frequency you want to measure the beat at. You should take care not to measure a CTB beat

instead of a CSO beat.

Note: The active modulation standard contains a Quiet Line parameter. It tells, in which video line the

vision carrier is not modulated. Be sure to set this parameter correctly (Modulation standards)!

The R&S FSL captures IQ data during this line and calculates an FFT.

Fig. 2-42 CSO Quiet Line measurement

The lower pane shows the final CSO ratio and whether it is passed or failed. It also shows the most

important correction factors used to calculate the CSO ratio.

In Quiet Line mode the beat reading will be not as accurate as in Off–Service mode, due to the still

active channel. But you do not have to turn off channels for a quick check.

CTB measurement

This measurement determines the ratio of signal power and the level of composite triple (order) beats.

These beats normally fall onto the vision carrier.

The signal power is normally the peak power of the modulated vision carrier, which is the power of the

unmodulated vision carrier. You can modify this default setting with the softkey Reference Power (for

details refer to chapter 4, section "Cable TV Measurements (Option K20)").

The measurement display is split into two panes. The upper pane displays the spectrum of the

measured beats. The lower pane displays the result table for the measurement and whether the limits

are passed or failed.

Test setup:

Refer to the section Analog TV test setup.

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Procedure:

1. Press the SWEEP key.

2. Press the Single Sweep softkey.

3. Press the FREQ key.

4. Enter 210.25 MHz for the vision carrier frequency of the input signal.

5. Press the MEAS key.

6. Press the Analog TV softkey.

7. Press the CTB softkey.

8. To change the limits, press the Edit Table softkey.

9. To adjust the input attenuator, press the Adjust Attenuation softkey.

10. Press the CTB Setup softkey to open the CTB Setup dialog box.

Specify a single span for the beat measurement: Change the CF value, which denotes the

middle of the span relative to the vision carrier and the Span value in the table. The

measurement range should be centered around frequencies where you expect triple order beats

in your network, i.e. the CF value should normally be about 0Hz.

If desired, activate the Noise Floor Correction option.

11. Press the RUN key.

12. Turn on the signal when prompted and confirm by pressing the ENTER key.

The R&S FSL will measure the carrier power. This is not visible on the screen.

13. Turn off the test transmitter or remove the cable when prompted and confirm by pressing the

ENTER key.

The R&S FSL will measure the beats in the span specified in the CTB Setup dialog box.

14. Using the rotary knob, move the marker to the frequency you want to measure the beat at. The beat

level at this marker is measured and used to compute the CTB ratio. You should take care not to

measure a CSO beat instead of a CTB beat.

Fig. 2-43 CTB measurement

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The lower pane shows the final CTB ratio and whether it is passed or failed. It also shows the most

important correction factors used to calculate the CTB ratio.

Digital TV Basics

Cable TV networks use single carrier QAM signals. These signals are continuously modulated. The

Cable TV Measurements option does not support burst signals as used in cable modems (e.g.

DOCSIS) which rely on TDMA techniques that share the same channel with several subscribers. To get

abetter understanding, we now want to have a closer look at an ideal QAM transmitter.

Binary

Source

Symbol

Mapping

bits

Idirac(t)

Qdirac(t)

RRC

Filter

RRC

Filter

IRRC(t)

QRRC(t)

cos(2fCFt)

/2

IQRF(t)

Fig. 2-44 Ideal QAM transmitter

To keep things simple we start with a binary source providing a never ending bit stream. Please keep in

mind that in reality these bits originate from a video stream which will be source encoded e.g. by a

MPEG encoder. To allow errors during the transmission via the cable channel coding (e.g. convolutional

coding) will be applied. Finally we get something like "…010010111101010101110110101111010…''

The symbol mapping block transforms the digital information (bits) into the continuous signals I

dirac(t)

and Qdirac (t). Idirac(t) and Qdirac (t) (see Fig. 2-45)consist of dirac pulses that appear at times t=n*Tsymbol

and that can be distinguished by their in–phase "I'' and quadrature "Q'' levels. For example a 16QAM

constellation has 16 different I and Q combinations and 4 different I and Q levels (4*4=16). Typically

this is visualized in a constellation diagram (see Fig. 2-46). With 16=24we are able to transmit 4 bits per

symbol. Therefore we can calculate:

bit_rate = symbol_rate * 4 = 4/ Tsymbol [bits/second]

or more general:

bit_rate = symbol_rate * log2(M) [bits/second] for MQAM.

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Fig. 2-45 Pulse signals Idirac (t) and Qdirac (t) for 16QAM

Fig. 2-46 16QAM constellation diagram

Unfortunately the required bandwidth for transmitting dirac pulses is infinite. Let's reduce the bandwidth

by applying a so–called pulse shaping filter (as referred to as TX filters). In most QAM systems root

raised cosine filters are used. Root raised cosine filters are exclusive supported by the Cable TV

Measurements option. Via the filter's roll–off factor the occupied bandwidth can be controlled.

OccupiedBandwidth = SymbolRate (1 + RollOff)

In a cable TV receiver, a filter of the same shape is used as RX filter. The combination of two root

raised cosine filters, one in the transmitter (TX) and another one in the receiver (RX), has a very strong

property: There will be no inter–symbol interference at the RX filter's output. Due to this property it is

very easy for the receiver to retrieve the transmitted symbols. Please note, that in a real–world scenario

the channel (causing echoes / multipath propagation) causes inter–symbol interference. In that case the

use of an equalizer is recommendable. Fig. 2-47 shows the signals IRRC(t) and QRRC(t) that result from

filtering Idirac (t) and Qdirac (t) with the root raised cosine filter RRC.

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Fig. 2-47 Root raised cosine filtered dirac signals IRRC(t) and QRRC(t)

We notice that the symbol instants (highlighted with squares) are not on the horizontal lines (possible

symbol levels) anymore. This is due to the inter–symbol interference introduced by the root raised

cosine TX filter. Contrary to the signal filtered with two root raised cosine filters (TX and RX) the one

filtered with a single root raised cosine filter (TX) does not satisfy the condition for zero inter–symbol

interference. Fig. 2-48 shows the signal obtained by filtering the dirac signals with two root raised

cosine filters. The convolution of two root raised cosine filters is also called raised cosine filter and it

results in an overall inter–symbol interference free system. We observe that all symbol instants

(highlighted with squares) of IRC(t) and QRC(t) have exactly the same levels as the signals Idirac (t) and

Qdirac (t) in Fig. 2-45.Please note that this is only true for the signals IRC(t) and QRC(t) if there is no noise

present in the receiver. In the case of noise points will turn into clouds, that is what can be seen in the

Constellation Diagram measurement (modulation analysis).

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Fig. 2-48 Raised cosine filtered dirac signals IRC(t) and QRC(t)

Let us get back to the ideal transmitter from Fig. 2-44. The next task is to modulate the base band

signals RC(t) and QRRC(t) onto a carrier. The carrier frequency fCF stands for the center of a given TV

channel. Fig. 2-49 shows the modulated signal IQ

RF(t) with a carrier frequency f

CF=4*symbol_rate.

Please note that in real system the carrier frequency is much higher than here in our example.

Fig. 2-49 QAM modulated RF signal IQRF(t)

In a real cable TV transmission system however, the receiver would encounter a much worse situation.

The measurement signal, i.e. the signal fed into the R&S FSL's RF input, suffers from distortion. Some

of it is caused by a non–ideal transmitter, some originates from the TV cable and last but not least there

is thermal noise in every transmission system. Very often it is even not possible to find out from which

component the distortion comes from. Luckily this can be found out by driving measurements starting at

the transmitters location and continuing at different test points in the cable TV network up to the plug at

the subscriber's home.

The objective of the digital TV measurements offered by the Cable TV Measurements option is to

analyze and separate different sources of distortion and erroneous parameters.

R&S FSL Cable TV Measurements (Option K20)

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Binary

Source

Symbol

Mapping

RRC

Filter

RRC

Filter

cos[2(fCF+f)t+(t)]

/2+

cIn(t)

Channel IQRF(t)

Fig. 2-50 Real–world QAM transmitter and distortion model

Fig. 2-50 shows the transmitter and distortion model assumed by the measurement demodulator of the

Cable TV Measurements option. The error parameters and signals are given in the table below.

Table 2–6: Error parameters and signals in a QAM transmission system

Parameter Ideal Value Description

vI, vQvI=vQGains of I and Q path

cI, cQcI=cQ=0 Carrier leakage in I and Q path

 =0 Quadrature error

ff=0 Carrier frequency error

(t) (t)=0 Phase noise signal

Channel h(t) h(t)=(t) Channel impulse response

n(t) n(t)=0 Thermal noise

Instead of directly displaying the parameters from the table above, derived parameters are displayed in

the result table of the Overview measurement and the Modulation Errors measurement (modulation

analysis).To give an example: The ratio between vIand vQrepresents the gain imbalance which is a

more reasonable measure for a transmitter than the absolute values of vIand vQ.

The amplitude imbalance can be calculated as follows:

(

)

%1001_ =vv QI

imbalanceamplitude

Please note that the 2T/4 rad (90 deg) rotational symmetry of the QAM constellation (see Fig. 2-46)

leads to an ambiguity in the calculation of the amplitude imbalance. Ambiguity means that the QAM

demodulator of the Cable TV Measurements option has no knowledge of the absolute phase in the

transmitter but chooses one out of four possible phase angles (0, T/2, T,or 3 T/2 rad). It can be shown

that the phase ambiguity leads to two possible amplitude imbalance values. For the amplitude

imbalance the ambiguity can be resolved by using the definition as follows:

{

}

{

}

%1001,min,max_











=vvvv QIQI

imbalanceamplitude

In real–world analog IQ modulators there is never perfect carrier suppression. Carrier suppression is

modeled by adding the constants c

Iand c

Qto the in–phase (I) and quadrature (Q) signal paths

respectively. It is calculated with respect to the peak envelope power (PEP).

Quadrature error is the effect that appears if the IQ modulator's cosine and sine waves have not exactly

aphase difference of T/2 rad. The ideal value for the quadrature error thus is 0 rad.

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If the transmitter's (DUT) local oscillator does not provide the exact nominal carrier frequency (CF), a

carrier frequency error results. The carrier frequency error is displayed in the result table of the

Overview measurement.

measuredCFidealCF

errorfrequencycarrier =__

Good local oscillators have low phase noise. Phase noise causes an unwanted phase modulation. The

Cable TV Measurements option measures the phase jitter that corresponds to the variance of the phase

error. .(/)represents the phase difference between the (noisy) measurement meas(/)signal and the

ideal transmit signal ref(/). The phase jitter is only evaluated at symbol instants, i.e. for symbol

Tt =



{

}

(

)

{

}

{

}

)()()(_ 2



ErefmeasEjitterphase ==

Anon–flat frequency response of the analog hardware (amplifiers) or the transmit channel

(reflections or echoes in the TV cable) causes inter–symbol interference (ISI). To much ISI leads to

wrong symbol decisions in the QAM measurement demodulator. The QAM measurement demodulator

can suppress the channel's influence by filtering the receive signal with the inverse of the channel's

response. This operation is done by the so–called equalizer. With the equalizer activated (see Digital

TV Settings dialog box in Fig. 2-51), the EVM and MER values decrease by the ISI which was removed

by the equalizer. Activating the equalizer leads to two things: First of all the equalizer is trained based

on the received data of the current measurement (Freeze Equalizer option deactivated). Furthermore,

the measured signal will be filtered / "equalized'' with the previously estimated equalizer filter. If the

equalizer has reached a stable state and the channel does not change (time invariant channel) the

equalizer can be frozen by activating the Freeze Equalizer option. By this means the equalizer will not

be trained anymore but will still equalize the signal. Please also refer to the Echo Pattern measurement

(channel analysis).

The term n(/)is the synonym for any kind of distortion and thermal noise that has not been covered by

the transmitter and distortion model of Fig. 2-50 yet. In classical communication theory n(/)is modeled

as additive white Gaussian noise (AWGN).

EVM and MER result parameters are calculated based on the error vector signal, which corresponds to

the difference between the measurement signal meas(/)and the ideal transmit signal ref(/). The error

vector signal is only evaluated at symbol instants, i.e. for symbol

Tt =



To a certain extend the QAM measurement demodulator is insensitive to distortion, but if there is to

much of it, erroneous symbol decisions may occur and the results will not be valid anymore. A

possibility to check this is to have a look at the constellation diagram. If the clouds around the

constellation points are getting much bigger than the (horizontal and vertical) decision borders or if

there is even only one single big cloud, this will be a strong indication for a faulty QAM analysis. The

QAM measurement demodulator of the Cable Measurements option was designed by taking the

transmitter and distortion model from above (see Fig. 2-50) into account.

Digital TV Measurement Examples

These measurements are set up to carry out single channel measurements of digital TV signals. The

settings for digital TV measurements are described in section Digital TV settings.The test setup for the

following measurement types is provided in section Digital TV test setup.

The digital TV measurements offered by the Cable TV Measurements option can be divided into two

groups:

spectrum analyzer measurements

measurements based on the measurement QAM demodulator

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Measurements of the first group can also be done in the Spectrum Analyzer mode. The advantage of

the measurements of the Cable TV Measurements option is that they are automatically parameterized

with information according to the channel table and the modulation standards. Measurements of this

type are:

Spectrum measurement

Channel Power measurement

APD measurement

CCDF measurement

Digital TV measurements that base on output of the QAM measurement demodulator are:

Overview measurement

Constellation Diagram measurement (modulation analysis)

Modulation Errors measurement (modulation analysis)

Echo Pattern measurement (channel analysis)

Digital TV settings

The Cable TV Measurements option needs to know some of the parameters described in section Digital

TV Basics to perform correct measurements. It therefore stores these parameters in the so–called

"modulation standard". Refer to section Modulation standards for the creation and usage of a

modulation standard. Section Digital TV modulation standards contains the description of the

parameters that have to be characterized for a digital TV signal. The following list explains the meaning

of the parameters:

•Name:Choose an arbitrary name for the new modulation standard.

•Signal Type:If you want to characterize an digital TV signal, select Digital TV.

•TV Standard:Select a TV standard to initialize the following parameters.

•Constellation used in the transmitter, e.g. 64QAM.

•Symbol Rate of QAM signal.

•Roll–Off factor of root raised cosine TX filter.

•Sideband Position: Is the signal in normal position or inverted?

Note: In the dialog boxes, set the parameters always from top to bottom, since all parameters depend

on the parameters above them. Otherwise your input might be rejected, e.g. if it specifies an

unusual TV standard.

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Digital TV test setup

Perform all measurement examples in the Cable TV Analyzer mode.

Use a digital TV generator as signal source.

Connect the generator directly to the R&S FSL.

Set the TV generator to the following parameters:

center frequency = 100 MHz

single carrier 64QAM modulation.

root raised cosine transmit filter with a roll–off factor of 0.15.

symbol rate = 6.9 MSymbols/s.

This test setup is used throughout all digital TV measurement examples.

Spectrum measurement

This measurement gives an overview of the active measurement channel. All parameters are set

according to the modulation standard, referenced in the channel table or by the default digital TV

modulation standard. The spectrum is displayed in a full screen trace.

Test setup:

Refer to the section Digital TV test setup.

Procedure:

1. Press the FREQ key and enter 100 MHz for the center frequency.

2. Press the MEAS key.

3. Press the Digital TV softkey.

4. Press the Digital TV Settings softkey and compare the modulation parameters.

Fig. 2-51 Digital TV Settings dialog box

5. Press the Spectrum softkey.

6. To adjust the input attenuator, press the Adjust Attenuation softkey.

7. Press the RUN key.

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The spectrum of the input signal is displayed.

Fig. 2-52 Digital TV Spectrum measurement

Overview measurement

This measurement determines the modulation accuracy of a digitally modulated single carrier QAM

signals. The measurement results are checked against the limits and displayed in a table. In this table,

only the important result parameters of digital TV signals are displayed. Less important result

parameters are provided by the Modulation Errors measurement (modulation analysis).

Result parameters that failed the check are displayed in red and bold characters, the table cell is

marked with a star. Result parameters that passed the checks are displayed in green characters. A

global pass or fail comment is displayed in the upper left table corner on a green (for passed) or red (for

failed) background.

Table 2–7: Result parameters – Overview

Parameter Description Definition

MER (rms) root mean square of modulation

error rate

MER (peak) peak of modulation error rate

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Parameter Description Definition

EVM (rms) root mean square of error vector

magnitude

EVM (peak) peak of error vector magnitude

Carrier Frequency

Offset

frequency offset between the

received digital TV signal and the

frequency setting

Symbol Rate Offset frequency offset between the

measured symbol rate of the

received TV signal and the set

symbol rate

Test setup:

Refer to the section Digital TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the Overview softkey.

4. To magnify one parameter, press the Zoom softkey and activate the parameter. To go back to the

default setting, activate None.

5. To change the limits, press the Edit Table softkey.

6. To adjust the input attenuator, press the Adjust Attenuation softkey.

7. Press the RUN key.

The Table 2–7 lists the result parameters: meas(/)is the measured signal and ref(/)the ideal transmit

signal that is used for comparison; /means that the continuous signals are sampled at symbol instants

symbol

Tt =



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The result of the measurement is shown below.

Fig. 2-53 Digital TV Overview measurement

8. To form the average over a defined number of sweeps:

Press the TRACE key.

Press the Result Mode softkey and select the Average trace mode.

Press the Sweep Count softkey and enter the number of sweeps used for averaging.

Every result parameter in the table is averaged by a suitable averaging method over the

number of sweeps set.

Constellation Diagram measurement (modulation analysis)

This measurement displays the constellation diagram of the demodulated signal. Amplitude imbalance,

quadrature error and carrier leakage (see. Modulation Errors measurement (modulation analysis))are

still present in the used data. The probability of occurrence of points in the complex I/Q plane is

represented by different colors. The constellation results are provided only graphically, i.e. reading

results via remote control returns only a hardcopy of the display, but not a list of I/Q samples.

Test setup:

Refer to the section Digital TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the Modulation Analysis softkey.

4. Press the Const Diagram softkey.

5. To zoom in on one single quadrant, press the Zoom softkey and choose the desired quadrant. To

go back to the complete constellation, select None.

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6. To display the constellation diagram unchanged, while the I/Q samples are collected in the

background, press the Freeze softkey. To switch back to the continual update of the display, press

the Freeze softkey again.

7. To adjust the input attenuator, press the Adjust Attenuation softkey.

8. Press the RUN key.

Fig. 2-54 Digital TV constellation measurement

Modulation Errors measurement (modulation analysis)

This measurement determines the modulation accuracy. The measurement results are checked against

the limits and displayed in a table. In this table, only the less important result parameters of digital TV

signals are displayed (for details see Table 2–8). The important result parameters are provided by the

Overview measurement.

Result parameters that failed the check are displayed in red and bold characters, the table cell is

marked with a star. Result parameters that passed the checks are displayed in green characters. A

global pass or fail comment is displayed in the upper left table corner on a green (for passed) or red (for

failed) background.

Table 2–8: Result parameters – Modulation Errors

Parameter Description Definition

Amplitude

Imbalance

Measure for unequal amplitude

gains of in–phase and quadrature

singal paths of the transmitter's IQ

mixer. An ideal IQ mixer results in

0%.

{

}

{

}

%1001,min,max 













vvvv QIQI

:amplification of in–phase signal path

:amplification of quadrature signal path

Quadrature Error Phase offset relative to the ideal

phase difference (i.e. 90 deg)

between the in–phase and

quadrature signal paths. An ideal

IQ mixer results in 0 deg.

Carrier Suppression Suppression of carrier; perfect

suppression results in –\dB.

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Parameter Description Definition

Phase Jitter (rms) Root mean square of phase jitter

in deg. An ideal IQ mixer results in

0deg.

Test setup:

Refer to the section Digital TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the Modulation Analysis softkey.

4. Press the Modulation Errors softkey.

5. To magnify one parameter, press the Zoom softkey and activate the parameter. To go back to the

default setting, select None.

6. To change the limits, press the Edit Table softkey.

7. To adjust the input attenuator, press the Adjust Attenuation softkey.

8. Press the RUN key.

Fig. 2-55 Digital TV Modulation Errors measurement

9. To form the average over a defined number of sweeps:

Press the TRACE key.

Press the Result Mode softkey and select the Average trace mode.

Press the Sweep Count softkey and enter the number of sweeps used for averaging.

Every result parameter in the table is averaged by a suitable averaging method over the

number of sweeps set.

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Echo Pattern measurement (channel analysis)

This measurement determines the magnitude of the channel impulse response in respect to the

corresponding time delay. Damage of TV cables causes unwanted reflections of the TV signal. These

reflections lead to echoes in the TV receiver. These echoes can be seen by looking at the echo pattern

trace. If the unit of the x–axle is changed into meters or miles (this requires knowledge of the

propagation speed of the cable, i.e. the velocity factor) the location of the cable damage can be

measured. This kind of measurement is sometimes referred to as distance–to–fault measurement: as

the position of a peak in the echo pattern trace represents the distance between the faulty part of the

cable and the location of the R&S FSL.

Test setup:

Refer to the section Digital TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the Channel Analysis softkey.

4. Press the Echo Pattern softkey.

5. To change the unit from Rsto km or miles:

Press the Velocity Factor softkey to define the velocity of propagation for the unit conversion.

Press the Unit softkey to select the unit.

6. To zoom into the echo pattern, press the Zoom softkey.

7. To adjust the input attenuator, press the Adjust Attenuation softkey.

8. Press the RUN key.

Fig. 2-56 Digital TV Echo Pattern measurement

9. To get correct measurement results the equalizer should be activated. A non–flat frequency

response of the cable channel may cause demodulation errors and thus corrupt the measurement

results. Inter–symbol interference can be suppressed by the use of the equalizer.

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1300.2519.12 2.79 E-11

Please note that the Echo Pattern can also be measured with the equalizer switched off. As long as

there are only few decision errors in the QAM demodulator this will lead to the same echo pattern.

Press the PREVIOUS key twice to go two menu levels up.

Press the Digital TV Settings softkey (see Fig. 2-51).

If the equalizer should get into an instable state (e.g. if the signal was removed), press the

Reset button.

If the equalizer was properly trained and the channel does not change anymore, activate the

Freeze Equalizer option. Freezing the equalizer can speed up all demodulation–based digital

TV measurements.

Close the Digital TV Settings dialog with the ESC key.

What is the difference between the equalizer filter and the echo pattern?

The echo pattern is the amplitude of the channel impulse response. The equalizer in contrast estimates

the inverse of the channel response which is required to remove the channel's influence from the

measurement signal.

Channel Power measurement

This measurement determines the channel power of a digital TV channel.

For details on the applied measurement modes refer to section Measuring Channel Power and

Adjacent Channel Power.

The measurement is setup automatically with data relating to the modulation standard.

The measurement display is split into two panes. In the upper pane, the spectrum trace is displayed. In

the lower pane, the result table for the measurement is displayed.

Test setup:

Refer to the section Digital TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the More softkey.

4. Press the Channel Power softkey.

5. To change the limits, press the Edit Table softkey.

6. To adjust the input attenuator, press the Adjust Attenuation softkey.

7. Press the RUN key.

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Fig. 2-57 Digital TV Channel Power measurement

APD measurement

This measurement determines the amplitude probability density function (APD). The measurement can

also be performed in Spectrum Analyzer mode, but in the Cable TV Analyzer mode most of the

parameters are set automatically. For details on the background refer to section Amplitude Distribution

Measurements.

Test setup:

Refer to the section Digital TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the More softkey.

4. Press the APD softkey.

5. To change the scaling parameters of the x– and y–axis:

Press the Scaling softkey.

Press the corresponding softkey to change the parameters: x–Axis Signal Level, x–Axis Range,

y–Axis Max. Value, y–Axis Min. Value, Default Settings.

6. To adjust the input attenuator, press the Adjust Attenuation softkey.

7. Press the RUN key.

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Fig. 2-58 Digital TV APD measurement

CCDF measurement

This measurement determines the complementary cumulative distribution function (CCDF) of the

complex base band signal. The measurement can also be performed in Spectrum Analyzer mode, but

in the Cable TV Analyzer mode most of the parameters are set automatically. For details on the

measurement background refer to chapter section Amplitude Distribution Measurements.

Test setup:

Refer to the section Digital TV test setup.

Procedure:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the More softkey.

4. Press the CCDF softkey.

5. To determine the power exceeded with a given probability, press the Percent Marker softkey.

6. To change the scaling parameters of the x– and y–axis:

Press the Scaling softkey.

Press the corresponding softkey to change the parameters: x–Axis Signal Level, x–Axis Range,

y–Axis Max. Value, y–Axis Min. Value, Default Settings.

7. To adjust the input attenuator, press the Adjust Attenuation softkey.

8. Press the RUN key.

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Fig. 2-59 Digital TV CCDF measurement

TV Analyzer Measurements

The measurement here is set up to carry out multiple channel measurements of TV networks. The

measurement provides a fast, automatic change of the measurement channel in order to support a

quick succession of measurements.

The following measurement type is provided:

Tilt measurement

Tilt measurement

This measurement can determine the amplitude response of the CATV network by measuring the

channel power of every channel. Both analog and digital TV channels can be measured. The setup

configuration allows to limit the frequency range or to choose particular modulation standards in order to

measure only a channel subset of the TV network.

The channel levels are measured in a series of zero–span measurements. Each channel is measured

using the information stored in the channel table (modulation standard). Therefore the use of a channel

table is mandatory. Channels with the modulation standard <unused > are not measured (for details

on modulation standards refer to chapter "Instrument Functions", section "Cable TV Measurements

Option (K20)". Depending on the set modulation standard one the following measurements is used

internally by the firmware:

analog TV: Carriers measurement

digital TV: Channel Power measurement

The measurement result is displayed in form of a bar graph. The colors of the bars indicate the signal

type of the modulation standard.

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Test setup:

Connect the R&S FSL to your CATV network.

It is not possible to work without a channel table. You cannot even enter the TV Analyzer sub menu, if

you have not activated a channel table before. Create a channel table according to you CATV network

(or a subset of your network). This task is described in section Example: Creating a channel table.If

you do not want to create your own channel table, you can use the example channel table from section

Example: Creating a channel table,which is delivered with the Cable TV Measurements option.

Procedure:

1. Press the MENU key.

2. Press the Channel Setup softkey.

3. Select the appropriate channel table and activate it by pressing the Activate softkey.

4. Press the MEAS key.

5. Press the TV Analyzer softkey.

6. Press the Tilt softkey.

7. To restrict the channels to be measured, press the Tilt Setup softkey:

The Tilt Setup dialog box is displayed.

To limit the frequency range, under Span,enter a start and stop frequency. Be sure that at least

one channel's RF frequency is in this range. Otherwise the measurement display will be empty!

To select certain modulation standards for the measurement, under Modulation Standards,

activate the modulation standards to be included in the measurement.

8. To adjust the range of the y–axis, if logarithmic, press the Auto Range softkey.

9. Press the RUN key.

10. Observe the exact levels of different channels by turning the rotary knob.

11. Check your network:

Do all signals of the same type (e.g. all analog TV signals) have similar levels?

You can do this by selecting the modulation standards to measure before the measurement.

Or you can measure all kinds of signals and distinguish different modulation standards after the

measurement by their different colors.

You can measure the amplitude response of the network (or of an amplifier) by looking at the

levels of signals at different frequencies. Prerequisite is either that you measure before and after

the amplifier and compare the results. Or that you know, that the levels are equal at the

transmitter.

Channel Tables and Modulation Standards

Measurements with the Cable TV Measurements option can be speeded up significantly if a channel

table is used. First of all a channel table, sometimes also referred as channel plan, contains the

frequency plan of a cable TV network. Furthermore, for every channel it contains the information about

the service broadcast or the information that the channel is <unused >.

Typically every country has its own regulations concerning the frequency plan, i.e. the channel locations

and the channel widths. Unfortunately the services or programs assigned to this frequency plan differ

from one CATV network to another. For example the CATV network of the city of Munich offers different

programs than Erding which is only about 40 kilometers away. Therefore the Cable TV Measurements

option provides empty channel tables for most countries in the world, where empty means, that all

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channels are marked as <unused >.However, it is not possible to do measurements without any

precise information about the services. Therefore the Cable TV Measurements option introduces the

concept of the so–called modulation standard.

Modulation standards describe the signal characteristics, or physical layer, transmitted via a channel.

The Cable TV Measurements option supports modulation standards that characterize analog TV signals

(e.g. NTSC, SECAM, PAL) or digital TV signals (single carrier QAM as for example in DVB–C). Every

channel table can comprise several modulation standards. Once defined, every channel can reference

one of these modulation standards. Provided that at least one channel references a modulation

standard, measurements based on a channel table can easily be done.

You can create numerous channel tables (e.g. for different locations in the network / different

measurement tasks) and save them on the R&S FSL. But there can always be only one channel table

active at a time. Working without a channel table is realized by activating the special, pseudo channel

table called <none >.

Normally, the easiest way is not to create a channel table from the scratch, but to load pre–defined

channel tables delivered with the Cable TV Measurements option. They already hold the typical

frequency plans for many countries. You only have to fill in the modulation standards.

For detailed information on channel tables refer to section Channel tables,for modulation standards

refer to section Modulation standards. A detailed example is provided in section Example: Creating a

channel table.Fig. 2-60 gives an example of a channel table that references the modulation standard

"PAL_BG_STEREO''. Fig. 2-62 shows that modulation standard.

Channel tables

This section gives a detailed description of channel tables and their properties.

•Channel tables (see Fig. 2-60)have a Name.The name should comprise geographical

information, e.g. "SOUTHAMPTON'' or "EXAMPLE_WIPFING''.

•If desired, a Description giving further information on the channel table can be entered.

•Channel tables consist of Channels.The Cable TV Measurements option displays one channel

per line. A channel table must contain at least one channel.

Fig. 2-60 The channel table and its properties

Every channel has the following properties:

•The unique channel number No. can be used within measurements to change over from one

channel to another quickly.

•AComment can be specified, e.g. the name of the program or the frequency band.

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•AModulation Standard is referenced. In case of an empty channel, the modulation standard is

set to <unused >.Be aware that modulation standards have to be created before making use

of them. For details refer to section Create modulation standards Note, that in order to perform

channel table based measurements, there must be at least one channel, that references a

modulation standard. It is not possible to do any measurements, if in all channels the

modulation standard equals <unused >.

•The RF frequency represents the characteristic frequency of a channel. For analog TV

channels RF is equal to the vision carrier frequency. For digital TV channels and <unused >

channels it equals the center frequency.

•Width stands for the channel's bandwidth.

Channel 2Channel 1 Channel 3

Analog TV<unused > Digital TV

RF 1

RF 2

RF 3

1.25 MHz

Start 1

Start 2

Start 3

Stop 3

Stop 2

Stop 1

Width 1 Width 2 Width 3

Frequency

Amplitude

Fig. 2-61 Channel start and stop frequencies versus RF frequency and channel width

Except for <unused > channels the calculation of the start and stop frequencies depends on the signal

type property (digital or analog TV) of the referenced modulation standard. All corresponding formulae

are listed in the table below.

Table 2–9: Channel start and stop frequencies versus RF frequency and channel width

Signal type Analog TV Digital TV < unused >

RF frequency Start + 1.25 MHz Start + (Stop – Start) / 2

Channel Width Stop – Start

Start frequency RF – 1.25 MHz RF – Width/2

Stop frequency Start + Width

Note: The Cable TV Measurements option automatically adapts the RF frequency if the user changes

the modulation standard of a channel (e.g. from an analog to digital modulation standard). This

is done in order to keep the channels start and stop frequencies constant.

Modulation standards

All over the world many different transmission standards for TV signals exist. As a guide through the

jungle of parameters that describe TV signals (including video and sound sub–signals) the concept of

the modulation standard has been introduced.

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Most important when dealing with modulation standards is the order of the parameters. Modulation

standards (see Fig. 2-62)have always to be created and edited from top to bottom of the Modulation

Standard Options dialog box. The most important parameters are located at the top of the dialog box.

For example, changing the signal type from Analog TV to Digital TV also alters the complete set of

parameters below. Whereas the modulation technique for transmitting the color information is essential

in analog TV systems (see Color System in Fig. 2-62), it does not exist for digital TV systems. The

constellation instead is crucial in digital TV systems (see Fig. 2-63). For that reason the Cable TV

Measurements option automatically guides you through the whole process of creating a new modulation

standard and only confronts you with mandatory parameters.

Amodulation standard is structured as follows:

•The Name is arbitrary, but should refer to the main properties of the TV signal, e.g.

"PAL_BG_STEREO''.

•The Signal Type specifies whether the signal is an analog TV or a digital TV signal.

As mentioned above, all described parameters below depend on the chosen signal type. Therefore the

remaining parameters will be discussed separately in the sequel.

Fig. 2-62 Modulation Standard Options dialog box for analog TV

Analog TV modulation standards

This section describes the parameters that characterize analog cable TV signals. Refer to section

Analog TV Basics to learn more about analog cable TV signals. The parameters discussed here can

also be modified (temporarily) in the Analog TV Settings dialog box.

For analog TV the Modulations Standard Options dialog box (see Fig. 2-62)is structured as follows:

The channel table references modulation standards by their Name.Its name (see Fig. 2-63)should

comprise information about the used TV standard, the color system and the sound system, e.g.

"PAL_BG_STEREO''.

Here the Signal Type is always set to Analog TV.

The TV Standard characterizes the way the luminance information is modulated. The following

analog TV standards exist:

B/G

D/K

I

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K1

L

M

N

The Sound System parameter specifies how the audio will be transmitted. The possible values

depend on the TV Standard selected in the TV Standard list. The sound systems are named in the

form "sound carrier 1 / sound carrier 2'', e.g. "FM 6.5 / FM 6.258''. Information about the sound

modulation format and the carrier frequency with respect to the vision carrier is included.

Table 2–10: Possible values for the sound systems

TV Standard Sound System

FM 5.5 / NICAM 5.85

FM 5.5 / FM 5.742

B/G

FM 5.5 MONO

FM 6.5 / NICAM 5.85

FM 6.5 / FM 6.258

FM 6.5 / FM 6.742

D/K

FM 6.5 MONO

FM 6.0 / NICAM 6.552 I

FM 6.0 MONO

AM 6.5 / NICAM 5.85 L

AM 6.5 MONO

FM 4.5 BTSC

FM 4.5 EIA–J

FM 4.5 / FM 4.724

FM 4.5 MONO

What Group Delay shall the residual sideband filter have? The Group Delay setting has no effect

on the measurements in this firmware release.

The Color System parameter specifies how color information will be transmitted. The possible

values depend on the TV Standard selected in the TV Standard list.

Table 2–11: Possible values for the Color Systems

TV Standard Color System

PAL B/G

D/K SECAM

PAL

SECAM

NTSC M

PAL

Bar Line:The Vision Modulation measurement needs a special test signal, containing a peak white

value. You must specify the type and the number of the horizontal line that contains the peak white

value.

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Quiet Line:Some measurements need a horizontal line with no video information in it. You must

specify the number of this horizontal line here. For further information see also Example: Creating a

channel table.

Sideband Position:Is the signal in normal position or inverted?

Sometimes the analog TV signal to be analyzed is only available with an inverted sideband. This

can for example happen if the cable operator feds – for some reason – an inverted signal into the

network. It may also happen in R&D labs where measurements on different IF stages of a new TV

transmitter or a receiver hardware are to be performed. Please be aware, that these two

applications also lead to two different cases when measuring with the Cable TV Measurements

option:

Measurements with channel tables

Measurements without a channel table, i.e. <none >.

The sideband position can either be altered in the modulation standard or in the Analog TV

settings dialog box. When measuring with a channel table, switching the sideband position (from

normal to inverse or vice versa) keeps the channel's start and stop frequencies constant. As a

consequence the RF frequency will be modified.

Example:

Channel Information:

RF frequency = 401.25 MHz

Width = 8 MHz

Modulation standard = analog TV with sideband position = normal.

This leads to the following channel borders:

Start frequency = RF – 1.25 MHz = 400 MHz

Stop frequency = Start frequency + Width = 408 MHz.

Next, the sideband position of the referenced modulation standard will be set to inverse. In order

to keep the start and stop frequencies constant the RF frequency will be adapted as follows:

RF frequency = Stop frequency – 1.25 MHz = 206.75 MHz.

In case of measurements without a channel table, i.e. <none >,we realize that there are no start

and stop frequencies existing. Hence, changing the sideband position keeps the RF frequency

constant. As a consequence you will analyze different parts of the spectrum depending on the

selected sideband position.

Digital TV modulation standards

In the Cable TV Measurements option, digital TV is used as a synonym for quadrature amplitude

modulated (QAM) signals. In digital Cable TV networks exclusively single carrier modulated signals are

used. The Cable TV Measurements option does not support multicarrier techniques such as OFDM in

terrestrial TV networks.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 2.89 E-11

Fig. 2-63 Modulation Standard Options dialog box for digital TV

This section describes the parameters that characterize digital cable TV signals. Refer to section Digital

TV Basics to learn more about digital TV signals. The parameters discussed here can also be modified

(temporarily) in the Digital TV Settings dialog box.

For digital TV the Modulations Standard Options dialog box is structured as follows:

The channel table references modulation standards by their Name.Its name (see Fig. 2-63)should

comprise information about the used constellation and the symbol rate, e.g. "64QAM_6900''.

Here the Signal Type is always set to Digital TV.

Depending on the TV Standard the default values of the parameters below are set. The following

digital TV standards exist:

QAM J.83/A (DVB–C Europe)

QAM J.83/B (US Cable)

QAM J.83/C (Japanese Cable)

The Constellation parameter supports the values below:

4QAM

16QAM

32QAM

64QAM

128QAM

256QAM

512QAM

1024QAM

Fig. 2-64 shows ideal 16QAM and 32QAM constellation diagrams. 4QAM, 16QAM, 64QAM,

256QAM and 1024QAM have a square structure, whereas 32QAM, 128QAM and 512QAM have a

cross structure.

The Symbol Rate and the Roll–off factor of the pulse shaping filter determine the occupied

bandwidth of the digital TV signal. In the Cable TV Measurements option only root raised cosine

filters are supported. The bandwidth can be calculated by the following formula:

OccupiedBandwidth = SymbolRate (1 + RollOff)

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1300.2519.12 2.90 E-11

The symbol rate can be entered in MHz. For the roll–off factor, the following values are supported:

0.120

0.130

0.150

0.180

The Sideband Position parameter can be used to invert the sidebands. The following values are

supported:

Auto

Inverse

Normal

Fig. 2-64 16QAM (square) and 32QAM (cross) constellation diagrams

Example: Creating a channel table

This section gives an exemplary step–by–step instruction for creating a channel table. The basic

procedure consists of three steps:

1. Enter frequency plan,i.e. a channel table solely containg < unused > channels.

2. Create modulation standards.

3. Assign modulation standards to channels.

The following sections address these steps.

The channel tables described in this example are delivered with the Cable TV Measurements option.

Please note, that contrary to the example here, their names are as follows.

–RS_EXAMPLE_BAVARIA (in example: "EXAMPLE BAVARIA'')

–RS_EXAMPLE_WIPFING (in example: "EXAMPLE WIPFING'')

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1300.2519.12 2.91 E-11

Enter frequency plan

Typically every country has its own regulations concerning the frequency plan, i.e. the channel locations

and the channel widths. That is what we call a country–specific frequency plan. Table 2–12 shows the

frequency plan of "Bavaria''. This plan applies to all cable TV networks of Bavaria. Hence, there is no

information about the programs included yet, as this information depends on the (local) operator of a

particular network. In the first step, we merely want to enter this frequency plan with the Cable TV

Measurements option and call this channel table "EXAMPLE BAVARIA''.

Table 2–12: Frequency plan example of channel table "EXAMPLE BAVARIA''

Channel No. Band name Start frequency in MHz Width in MHz

2VHF 1 50.5 7

21 UHF 474 8

22 UHF 482 8

23 UHF 490 8

24 UHF 498 8

1. Press the MENU key.

2. Press the Channel Setup softkey.

3. Press the New softkey to create a new channel table.

4. In the Name field, enter EXAMPLE BAVARIA as channel table name with the keypad, and press

ESC.

5. In the Description field, enter in the same way EXAMPLE FOR COUNTRY SPECIFIC

FREQUENCY PLAN.

6. To enter the first channel (line 2 of Table 2–12):

Use the knob or the cursor keys to move to the No. column of the existing channel.

Enter 2for the channel number.

Enter VHF 1 as Comment.

Set the Modulation Standard to <unused >.

Therefore RF represents the center frequency and can be calculated as

RF = Start + Width / 2 = 50.5 MHz + 7 MHz / 2 = 54 MHz.

Set the RF frequency to 54 MHz.

Set the channel Width to 7MHz.

7. To enter the second channel (line 3 of Table 2–12):

Move down to focus the last channel.

Press the Copy Channel softkey to copy the last channel.

Move down to the copied channel.

Set the channel number No. to 21.

Enter UHF as Comment.

Set the Modulation Standard to <unused >,

i.e. RF = 474 MHz + 8 MHz / 2 = 478 MHz.

Set the RF frequency to 478 MHz.

Set the channel Width to 8MHz.

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8. To enter the remaining channels proceed as in step 7

Channel 22:RF = 486 MHz

Channel 23:RF = 494 MHz

Channel 24:RF = 502 MHz

9.To save your work, press the Save Changes softkey.

Having finished the first step, you have build a channel table as shown in Fig. 2-65.Please note,

that it is not possible yet, to do any measurements, as all channels are marked as <unused >.

Nevertheless, you can use the EXAMPLE BAVARIA channel table as a base model for all channel

tables required all over Bavaria.

Fig. 2-65 Channel table "EXAMPLE BAVARIA'' with entered frequency plan

Create modulation standards

For detailed information on channel tables refer to section Channel tables,for modulation standards

refer to section Modulation standards. A worked out example can be found in Example: Creating a

channel table.

The second and third steps require knowledge about a particular network. Thus, information about the

programs (see Channel tables)and the possible services (see Modulation standards)has to be

collected. For our example, we retrieved this information from the operator of the small cable TV

network of Wipfing, a village in Bavaria. We found out, that there is a traditional TV chain, broadcasting

their TV program using analog transmission techniques with stereo sound. The technical details are

summarized in Table 2–13.Besides, another TV chain, equipped with state–of–the–art Bavarian

broadcast technology, feeds two digital DVB–C programs into Wipfing's cable TV network. The

parameters are listed in Table 2–14.

Table 2–13: Analog TV service data for PAL_BG_STEREO modulation standard

Video PAL B/G

Sound Stereo: FM 5.5 MHz / FM 5.7421875 MHz

Group delay profile general

VITS: Bar line CCIR17, line 17

VITS: Quiet line line 22

Sideband position normal

R&S FSL Cable TV Measurements (Option K20)

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Table 2–14: Digital TV service data for 64QAM_6900 modulation standard

Standard QAM J.83/A (DVB–C Europe)

Constellation 64QAM

Symbol rate 6.9 MSymbols/s

Roll–off factor of root raised cosine filter 0.15

Sideband position normal

First of all in the second step, we will copy the EXAMPLE BAVARIA channel table to a new channel

table EXAMPLE WIPFING. We do this, because we want to keep the pure frequency plan (as

EXAMPLE BAVARIA channel table), and create an additional channel table EXAMPLE WIPFING for

our measurements in Wipfing.

1. Press the previous key, to go back to the Channel Tables dialog box.

2. Focus the channel table EXAMPLE BAVARIA via the knob or cursor keys.

3. Press the Copy softkey to copy the EXAMPLE BAVARIA channel table.

4. The Channel Table dialog box is displayed (see Fig. 2-65).

5. In the field Name,enter EXAMPLE WIPFING as channel table name, with the keypad.

6. In the field Description,enter in the same way EXAMPLE FOR PARTICULAR CATV NETWORK.

7. To save the new channel table, press the Save Changes softkey. You will be prompted if any

errors are encounterd. In that case, please correct all errors. If you followed the steps above

everthing should be fine.

We will then create the analog modulation standard, which we will call PAL_BG_STEREO and which is

based on the information of Table 2–13:We will continue with the channel table EXAMPLE WIPFING

from above.

8. Press the Modulation Options softkey.

The appearing list of all exisiting modulation standards is empty right now.

9. In the Modulation Options submenu, press the New softkey.

The Modulation Standard Options dialog box appears (see for example Fig. 2-66).

10. Enter the parameters for the modulation standard:

In the field Name,enter PAL_BG_STEREO as modulation standard name with the keypad.

Select Analog TV as Signal Type from the list.

This is done, because PAL B/G is an analog TV standard.

Select B/G as TV Standard.

This means that the luminance information of the video signal is transmitted via an AM

modulated carrier according to the standard B/G.

Select FM 5.5 / FM 5.742 as Sound System from the list.

That means that there are two sound carriers present, one 5.5 MHz and the other 5.7421875

MHz above (for a normal sideband position) the vision carrier frequency.

Select General for the Group Delay from the list.

Select PAL for the Color System from the list.

The color information of the video signal is transmitted according to the PAL standard.

For the Bar Line,set Line to 17 and the Type to CCIR17.

That means, that a special test signal, the so called bar line, is transmitted in the horizontal line

17 of the TV signal.

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1300.2519.12 2.94 E-11

For the Quiet Line,set Line to 22.

That means, that the horizontal line 22 transmits no luminance information.

Select Normal as Sideband Postion from the list.

The Modulation Standard Options dialog box should now look as in Fig. 2-66.

11. Press the previous key twice to go back to the Channel Table dialog box.

12. Press the Save Changes softkey to save the channel table and the new modulation standard.

Fig. 2-66 Analog TV modulation standard PAL_BG_STEREO

Up to now, we successfully created the channel table EXAMPLE WIPFING, which contains a frequency

plan and the analog TV modulation standard PAL_BG_STEREO. Next, we will create the digital

modulation standard 64QAM_6900 based on the information of Table 2–14.

13. Press the Modulation Options softkey.

Alist with one modulation standard PAL_BG_STEREO is displayed.

14. In the Modulation Options submenu, press the New softkey.

The Modulation Standard Options dialog box is displayed (see for example Fig. 2-66).

15. Enter the parameters for the modulation standard:

In the field Name,enter 64QAM_6900 as modulation standard name with the keypad.

Select Digital TV as Signal Type from the list.

This is done, because the desired QAM DVB–C signal is a digital TV signal.

Select QAM J.83/A (DVB–C Europe) as TV Standard.

By this means, all parameters below are set to their default values.

Set Constellation to 64QAM.

Set the Symbol Rate value to 6.9 MSyms/s.

This can be done by entering 6.9 via the keypad and confirming the input with the MHz key.

Set the Roll–off factor to 0.150.

Select Auto as Sideband Postion from the list.

The Modulation Standard Options dialog box should now look as in Fig. 2-67.

16. Press the previous key twice to go back to the Channel Table dialog box.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 2.95 E-11

17. Press the Save Changes softkey to save the channel table and the new modulation standard.

Fig. 2-67 Digital TV modulation standard 64QAM_6900

We have now finished step two, i.e. the channel table EXAMPLE WIPFING contains a frequency plan,

the analog modulation standard PAL_BG_STEREO and the digital modulation standard 64QAM_6900.

Assign modulation standards to channels

Finally, in step three, the links between the frequency plan and the modulation standards have to be

set. Table 2–15 shows the desired combinations.

Table 2–15: Assignment of programs and services to channels

Channel No. Program Name Modulation Standard

2 – < unused >

21 BRASS CHANNEL PAL_BG_STEREO

22 XYZ NEWS PAL_BG_STEREO

23 ARTE 64QAM_6900

24 GANESH 64QAM_6900

1. Do not change channel 2, as no service is available (<unused >).

2. To edit channel 21:

Enter BRASS CHANNEL into the Comment field of channel 21.

The band name, entered before, is now replaced by the more meaningful program name.

Select PAL_BG_STEREO as Modulation Standard from the list.

The list now offers: <unused >,64QAM_6900 and PAL_BG_STEREO.Furthermore, the RF

frequency will be automatically changed from 478 MHz to 475.25 MHz.

3. To edit the channels 22, 23, and 24, proceed to step 2 using the information from Table 2–15.

4. Press the Save Changes softkey, to save the channel table.

The complete channel table is shown in Fig. 2-68.

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 2.96 E-11

Fig. 2-68 Digital Channel table "EXAMPLE WIPFING''

We now have sucessfully finished the creation of the channel table "EXAMPLE WIPFING''. Please refer

to section Performing a Measurement without a Channel Table to learn more about measurements

based on a channel table.

Example: Restoring the default channel tables

The Cable TV Measurements option brings several channel tables with it:

The typical frequency plans used in different countries, e.g.

TV–CHINA

TV–EUROPE

TV–USA–CATV

etc…

Example channel tables (see Example: Creating a channel table), e.g.

RS_EXAMPLE_BAVARIA

RS_EXAMPLE_WIPFING

If you have modified or deleted one of these channel tables, you can restore them in the following way:

1. Press the MENU key.

2. Press the Channel Setup softkey.

3. Press the Restore Default Tables softkey.

Only missing channel tables will be restored. If you want to replace an existing channel table by its

default channel table, you have to delete it before.

Performing a Measurement without a Channel Table

The Cable TV Measurements option intends to help network engineers. Network engineers will onces

create a channel table, and then use it to visit many, many test points, all located in the same cable TV

network. If you are a network engineer please see section Performing a Measurement Using a Channel

Table.If you work in R&D or you do not have a cable TV network at all (all you have is a single TV

transmitter or a frequency where you want to do a measurement ignoring any signals apart), this

section describes how to setup an analog TV Spectrum measurement without a channel table.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 2.97 E-11

Test setup:

Connect a analog TV generator to your R&S FSL. Set the TV generator to send an analog TV PAL

B/G signal with a vision carrier frequency of 210.25 MHz.

Procedure:

1.Press the MENU key.

2. Press the Channel Setup softkey.

The Channel Tables dialog box is displayed. It lists all available channel tables.

3. Select no channel table <none > and press the ENTER key.

You should always select <none > if you do not have a channel table. In this mode you can do all

kind of measurements except the Tilt measurement.

4. Press the MEAS key.

5. Press the Analog TV softkey.

By pressing this softkey you tell the Cable TV Measurements option, that your signal is an analog

TV signal and that the Default Analog Modulation Standard has to be used. This modulation

standard is used for all analog TV measurements knowing the fact that there is no channel table

where a modulation standard can be retrieved from.

6. Press the Spectrum softkey.

In our example we want to check the spectrum of our analog TV source.

7. Press the FREQ key.

8. Press the RF softkey.

9. Enter 210.35 MHz as the RF frequency.

10. To adjust the input attenuator, press the Adjust Attenuation softkey.

The following figure is displayed:

Fig. 2-69 Example for a measurement without a channel table

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 2.98 E-11

In practice you would now continue to adapt the modulation settings in depth, i.e. the sound system the

test lines and so on. For our example we will stop here.

For further details on analog TV modulation parameters please refer to section Analog TV settings.

Performing a Measurement Using a Channel Table

The use of a channel table can speed up most of the routine measurement tasks. This section will

demonstrate how to perform measurements using channel tables.

Test setup:

No special test setup is required. You do not need to supply a signal. We do not need meaningful

measurement results here, since the focus is on the operation only.

Procedure:

1. Press the MENU key.

2. Press the Channel Setup softkey.

3. You should now see a list of Channel Tables, including the example channel table

RS_EXAMPLE_WIPFING,that was used in section Example: Creating a channel table. If you have

deleted it, you must first restore it as shown in section Example: Restoring the default channel

tables.

4. Move the cursor to RS_EXAMPLE_WIPFING and press the Activate softkey.

The Cable TV Measurements option automatically switched to the first channel in the Channel

Table.

5. Press the MEAS key.

6. Press the Analog TV softkey.

7. Press the Carriers softkey.

The resulting measurement is displayed (see Fig. 2-70).

The Cable TV Measurements option configures the measurement according to the information

stored in the channel table:

It automatically sets the span to measure the channel with number 21. The channel borders are

marked with red vertical lines.

It also knows how large the ideal intercarrier frequency offset (vision carrier to audio carriers)

should be. This information is needed to calculate the deviation from the ideal value. The ideal

sound carrier positions are also marked via red vertical lines.

The measurement principle is chosen according to the modulation standard given for the current

measurement channel. For example: The powers of a NICAM and a FM sound carrier must be

measured in different ways.

The display tells you the actual RF frequency and what modulation standard the channel

contains.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 2.99 E-11

Fig. 2-70 Carriers measurement using a Channel Table. No input signal!

8. Press the Channel No softkey.

9. Input a channel number via the numeric keyboard. The Cable TV Measurements option will only

allow analog TV channels defined in the active channel table, since we are in a measurement for

analog TV channels and digital TV signals would not make sense! The same is true when you use

the rotary knob for changing the measurement channel.

So, the very small example channel table only allows us to switch to channel 22. Observe how the

RF frequency changes.

10. Press the MEAS key.

11. Press the Digital TV softkey.

This switches to measurements for Digital TV signals.

12. Press the Spectrum softkey.

The resulting measurement is displayed (see Fig. 2-71).

The Cable TV Measurements option once again configures the measurement automatically and

gives you information about the channel borders and the modulation standard.

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 2.100 E-11

Fig. 2-71 Digital TV spectrum using a Channel Table. No input signal!

13. Press the Channel No softkey.

14. Choose one of the digital TV channels that are present in the channel table, because we are in a

measurement designed for digital TV signals.

15. Press the MEAS key.

16. Press the TV Analyzer softkey.

17. Press the Tilt softkey.

18. Press the Auto Range softkey.

The resulting measurement is displayed (see Fig. 2-72).

Fig. 2-72 Tilt measurement using a Channel Table. No input signal!

R&S FSL Noise Figure Measurements Option (K30)

1300.2519.12 2.101 E-11

The use of a channel table is mandatory for the Tilt measurement. Because the Cable TV

Measurements option must know where a channel's power has to be measured and how it has to be

done. Each vertical line represents a channel. The blue ones are digital TV channels, the yellow ones

are analog TV.

Noise Figure Measurements Option (K30)

This section describes measurement examples for the Noise Figure Measurements option (K30). For

further information on measurement examples refer to the Quick Start Guide, chapter 5 "Basic

Measurement Examples", or the Operating Manual on CD, chapter "Advanced Measurement

Examples".

This option is available from firmware version 1.50.

Direct Measurements

Direct measurements are designed for DUTs without frequency–conversion, e.g. amplifiers. For details

refer also to the Operating Manual on CD, chapter "Instrument Functions", section "Noise Figure

Measurements Option (K30)".

Basic Measurement Example

This section provides step–by–step instructions for working through an ordinary noise figure

measurement. The following steps are described:

1. Setting up the measurement

2. Performing the calibration

3. Performing the main measurement

The gain and noise figure of an amplifier are to be determined in the range from 220 MHz to 320 MHz.

Setting up the measurement

1. Activate the Noise mode (for details refer to chapter "Instrument Functions", section "Measurement

Mode Selection – MODE Key").

2. Press the Freq Settings softkey to open the Frequency Settings dialog box.

In the Start Freq field, enter 550 MHz.

In the Stop Freq field, enter 560 MHz.

In the Step Freq field, enter 2MHz.

Ameasurement at 6 frequency points is performed: 550 MHz, 552 MHz, 554 MHz, ..., 560

MHz.

Noise Figure Measurements Option (K30) R&S FSL

1300.2519.12 2.102 E-11

3. Press the ENR Settings softkey to open the ENR dialog box.

In the ENR Constant field, enter the average ENR value of the used noise source for the

frequency range of interest, for example 15 dB.

4. Press the Meas Settings softkey to open the Measurement Settings dialog box.

Activate the 2nd Stage Correction option to perform the measurement as accurately as

possible.

Performing the calibration

1. Connect the

noise source to the RF input of the R&S FSL (see Fig. 2-73).

2. If you perform the measurement in an environment with radiated emissions, you may consider to

connect a lowpass filter to the voltage supply input of the noise source.

3. Provide the voltage supply for the noise source by connecting it to the +28 V connector of the

R&S FSL (labeled NOISE SOURCE CONTROL on the rear panel of the instrument) via a coax

cable and the lowpass filter. Connect the lowpass filter between the noise source itself and the

NOISE SOURCE CONTROL connector of the R&S FSL as shown in Fig. 2-73.

The purpose of the lowpass filter is to suppress any interference (e.g. due to RF interference),

including interference from the supply line. This makes it possible to perform very precise

measurements.

Fig. 2-73: Preparation for calibration

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1300.2519.12 2.103 E-11

4. Start

the calibration for the Noise Figure Measurements option.

Press the SWEEP key.

Press the Cal softkey.

The progress bar indicates the progress of the calibration measurement. After successful

calibration, in the status bar, a corresponding message is displayed and the title bar at the top of

the screen shows the status on the right–hand–side.

Performing the main measurement

1. Insert the DUT (in this example, the amplifier) into the test setup between the noise source and RF

input of the R&S FSL (see Fig. 2-74).

Fig. 2-74: Test setup for the main measurement

2. To select the sweep mode, press the SWEEP key.

3. Press the RUN key to start the measurement.

Measurement results are updated as the measurement is in progress. The results are displayed in

graphical form. There are two traces, one for noise figure/temperature and one for the gain of the

DUT.

4. To change the display from the graphical form to a tabular list of measurement points, press the

Display List/Graph softkey.

Note: If a measurement is started while another measurement is still in progress, the first

measurement is aborted and the new measurement started immediately.

DUTs with very Large Gain

If the gain of the DUT exceeds 60 dB, the total gain must be reduced by an external attenuator. The

total gain of the DUT together with the external attenuator should lie within the range from 10 dB to

60 dB. A total gain of 20 dB to 30 dB is recommended. For a DUT with a gain of e.g. 64 dB, it is

recommended to use an external 40 dB–attenuator.

If an external attenuator is used, in the Measurement Settings dialog box, the entry in the Range field

should be modified according to the total gain ( = GDUT – external attenuator).

The attenuation values of the external attenuator are entered in the Loss Settings dialog box under

Loss Output Settings.

Inaccuracies when entering this attenuation mainly influence the measured gain. The noise figure

remains to a large extent unaffected.

Noise Figure Measurements Option (K30) R&S FSL

1300.2519.12 2.104 E-11

Fig. 2-75: Calibration and measurement on DUTs with a high gain

Frequency–Converting Measurements

The frequency–converting measurement is used for DUTs with an output frequency that differs from the

input frequency, e.g. mixers and frequency converters. The frequency–converting measurement allows

many variations, which differ from each other in two criteria:

Fixed LO Measurements

Image–Frequency Rejection (SSB, DSB)

Fixed LO Measurements

In the Frequency Settings dialog box, select one of the following settings for the Mode parameter:

fixed LO, IF=RF+LO, for up–converting devices

fixed LO, IF=abs(RF–LO), for down converters or image measurements

Image–Frequency Rejection (SSB, DSB)

Frequency–converting DUTs often do not only convert the desired input frequency but also the image

frequency. A broadband noise source offers noise to the DUT not only at the input frequency but also at

the image frequency. If the noise power at the IF gate is measured, the origin of the noise can no longer

be determined. It may have been converted both from the input and from the image frequency range.

Test setup

Set the following parameters:

IF (intermediate frequency): 100 MHz

RF (input frequency): 400 MHz

LO (local oscillator frequency): 500 MHz

image (image frequency): 600 MHz

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1300.2519.12 2.105 E-11

freq.

LORFIFImage

If a DUT, which equally converts the useful signal and the image to the IF frequency, is measured using

the conventional y factor method or with the 2nd stage correction switched on, a measuring error of 3

dB is produced. The noise figure is displayed 3 dB lower and the gain 3 dB higher. The following

examples help to configure the test setup in order to measure the actual values.

Measurement on a single–sideband mixer

freq.

LORFIF

In general, a single–sideband mixer with a very high image rejection causes very few problems. The

measurement is analogous to an amplifier. In this case, set the image rejection in the Frequency

Settings dialog box to a large value (e.g. 999.99 dB).

Measurement on a mixer without sideband suppression

freq.

LORFIFImage

If the input and image frequencies are converted with the same application, an error of 3 dB occurs in

the measurement results if the image rejection is not taken into account. In this case, set the image

rejection in the Frequency Settings dialog box to a small value (e.g. 0.0 dB).

Noise Figure Measurements Option (K30) R&S FSL

1300.2519.12 2.106 E-11

Measurement on a mixer with an average sideband suppression

freq.

LORFIFImage

4dB

For measurements on a mixer with a low image–frequency rejection, a measuring error of 0 to 3 dB is

obtained if the image–frequency rejection is not taken into account. In this case, set the image rejection

in the Frequency Settings dialog box to 4 dB to produce the correct results.

Measurement on a mixer with unknown sideband suppression

freq.

LORFIFImage

XdB

If the image rejection is not known, accurate noise results can still be produced. However, the gain of

the DUT must be known and an additional filter is required.

Test setup

Fig. 2-76: Preparation for calibration

Fig. 2-77: Test setup for the main measurement

In this test setup, a low pass filter prevents noise from the noise source from being fed in at the image

frequency. Depending on the position of the frequency bands, a highpass or bandpass filter may also

be necessary for the RF frequency instead of the lowpass filter. The important point is that noise from

R&S FSL Noise Figure Measurements Option (K30)

1300.2519.12 2.107 E-11

the noise source is not converted by a further receive path of the mixer. The noise of the noise source

atthe receive frequency must not be reduced. The insertion loss must be considered, if applicable.

With this test setup, the measurement on a mixer without sideband suppression corresponds to the

measurement on a single–sideband mixer. As in that case, set the image rejection in the Frequency

Settings dialog box to a large value (e.g. 999.99 dB) to produce accurate results.

To take the characteristics of the filter into account, in the Loss Settings dialog box, enter the insertion

loss of the filter at the RF frequency. To consider the actual filter suppression at the image frequency,

do not enter 999 dB but the actual attenuation for the image rejection.

Measurement on a harmonics mixer

For a harmonics mixer, the input signals are not only converted to the IF by the wanted harmonic, but

also by the harmonic of the LO signal produced in the mixer. In many cases, the mixer even features a

lower conversion loss in the case of unwanted harmonics. For measurements on this type of mixer, a

bandpass filter must be used to make sure that that there is only noise at the desired input frequency at

the input of the DUT. This measurement is similar to measurements on a mixer with an average

sideband suppression.

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3GPP Base Station Measurements (Option K72)

This section explains basic 3GPP FDD base station tests by means of a setup with a signal generator,

e.g. an R&S SMU. It describes how operating and measurement errors can be avoided using correct

settings. The measurements are performed with an R&S FSL equipped with the 3GPP Base Station

Measurements option (K72).

The following measurements are described:

Measuring the Signal Channel Power

Measuring the Spectrum Emission Mask

Measuring the Relative Code Domain Power

Synchronization of the reference frequencies

Behavior with deviating center frequency setting

Behavior with incorrect scrambling code

Measuring the Relative Code Domain Power

Trigger offset

Furthermore, the test setup for base station tests is given:

Setup for Base Station Tests

For measurements on base–station signals in line with 3GPP, test models with different channel

configurations are specified in the document "Base Station (BS) conformance testing (FDD)" (3GPP TS

25.141 V7.4.0).

For further information on measurement examples refer also to the Quick Start Guide, chapter 5 "Basic

Measurement Examples".

This option is available from firmware version 1.60.

Measuring the Signal Channel Power

The R&S FSL measures the unweighted RF signal power in a bandwidth of

22.0|84.3)1(5 =+=



MHzMHzfBW

The power is measured in zero span using a digital channel filter of 5 MHz in bandwidth. According to

the 3GPP standard, the measurement bandwidth (5 MHz) is slightly larger than the minimum required

bandwidth of 4.7 MHz.

Test setup:

Connect the RF output of the signal generator to the RF input of the R&S FSL (coaxial cable with N

connectors).

Signal generator settings (e.g. R&S SMU):

Frequency: 2.1175 GHz

Level: 0 dBm

Standard: WCDMA/3GPP

Test model: 1, 32 DPCH channels

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1300.2519.12 2.109 E-11

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is set to its default state.

2. Change into the 3G FDD BTS mode.

Press the MODE key and activate the 3G FDD BTS option.

3. Set the center frequency to 2.1175 GHz.

Press the FREQ key.

The frequency menu is displayed.

In the dialog box, enter 2.1175 using the numeric keypad and confirm with the GHz key.

4. Set the reference level to 0 dBm.

Press the AMPT key and enter 0dBm.

5. Start the Power measurement.

Press the MEAS key.

Press the Power softkey.

The signal channel power of the WCDMA signal is displayed.

Fig. 2-78 Power measurement

3GPP Base Station Measurements (Option K72) R&S FSL

1300.2519.12 2.110 E-11

Measuring the Spectrum Emission Mask

The 3GPP specification defines a measurement that monitors compliance with a spectral mask in a

range of at least ±12.5 MHz around the WCDMA carrier. To assess the power emissions in the

specified range, the signal power is measured in the range near the carrier by means of a 30 kHz filter,

and in the ranges far away from the carrier by means of a 1 MHz filter. The resulting trace is compared

to a limit line defined in the 3GPP specification.

Test setup:

Connect the RF output of the signal generator to the RF input of the R&S FSL (coaxial cable with N

connectors).

Signal generator settings (e.g. R&S SMU):

Frequency: 2.1175 GHz

Level: 0 dBm

Standard: WCDMA/3GPP

Test model: 1, 32 DPCH channels

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is set to its default state.

2. Change into the 3G FDD BTS mode.

Press the MODE key and activate the 3G FDD BTS option.

3. Set the center frequency to 2.1175 GHz.

Press the FREQ key.

The frequency menu is displayed.

In the dialog box, enter 2.1175 using the numeric keypad and confirm with the GHz key.

4. Set the reference level to 0 dBm.

Press the AMPT key and enter 0dBm.

5. Start the Spectrum Emission Mask measurement.

Press the MEAS key.

Press the Spectrum Emission Mask softkey.

The spectrum of the 3GPP FDD signal is displayed.

R&S FSL 3GPP Base Station Measurements (Option K72)

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Fig. 2-79 Spectrum Emission Mask measurement

Measuring the Relative Code Domain Power

Acode domain power measurement on one of the test models (model 1 with 32 channels) is shown in

the following. To demonstrate the effects, the basic parameters of the Code Domain Power

measurements permitting an analysis of the signal are changed one after the other from values adapted

to the measurement signal to non–adapted values.

Test setup:

Connect the RF output of the signal generator to the input of the R&S FSL.

Connect the reference input (EXT REF) on the rear panel of the R&S FSL to the reference input of

the signal generator (coaxial cable with BNC connectors).

Signal generator settings (e.g. R&S SMU):

Frequency: 2.1175 GHz

Level: 0 dBm

Standard: WCDMA/3GPP

Test model: 1, 32 DPCH channels

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is set to its default state.

2. Change into the 3G FDD BTS mode.

Press the MODE key and activate the 3G FDD BTS option.

3GPP Base Station Measurements (Option K72) R&S FSL

1300.2519.12 2.112 E-11

3. Set the center frequency to 2.1175 GHz.

Press the FREQ key.

The frequency menu is displayed.

In the dialog box, enter 2.1175 using the numeric keypad and confirm with the GHz key.

4. Adjust the reference level and scrambling code.

Press the MEAS key.

The measurement menu is displayed.

Press the Auto Level & Code softkey.

The firmware adjusts the reference level and then searches the scrambling code automatically.

5. Select the Code Domain Power measurement.

Press the MEAS key.

Press the Code Dom Power Diagram softkey.

The Code Domain Power of signal according to test model 1 with 32 channels is displayed.

Fig. 2-80 Relative Code Domain Power measurement

Synchronization of the reference frequencies

Synchronization of the reference oscillators both of the DUT and the R&S FSL strongly reduces the

measured frequency error.

1. Press the SETUP key.

2. Press the Reference Int/Ext softkey to switch to external reference.

The displayed frequency error should be <10 Hz.

R&S FSL 3GPP Base Station Measurements (Option K72)

1300.2519.12 2.113 E-11

Behavior with deviating center frequency setting

In the following, the behavior of the DUT and the R&S FSL with an incorrect center frequency setting is

shown.

1. Tune the center frequency of the signal generator in 0.5 kHz steps.

2. Watch the R&S FSL screen.

ACode Domain Power measurement on the R&S FSL is still possible with a frequency error of up

to approx. 1 kHz. Up to 1 kHz, a frequency error causes no apparent difference in the accuracy of

the Code Domain Power measurement.

Above a frequency error of 1 kHz, the probability of impaired synchronization increases. With

continuous measurements, all channels are at times displayed in blue with almost the same level.

Above a frequency error of approx. 2 kHz, a Code Domain Power measurement cannot be

performed. The R&S FSL displays all possible codes in blue with a similar level.

3. Set the signal generator center frequency to 2.1175 GHz again.

Behavior with incorrect scrambling code

Acorrect Code Domain Power measurement can be carried out only if the scrambling code set on the

R&S FSL is identical to that of the transmitted signal.

1. Set the scrambling code of the signal generator to 0001.

With the scrambling code still set to 0 (default setting), the Code Domain Power Diagram result

display of the R&S FSL shows all possible codes with approximately the same level.

2. Set the correct scrambling code on the R&S FSL.

Press the MENU key.

Press the Scrambling Code softkey.

In the submenu, press the Scrambling Code softkey and enter 1using the numeric keypad.

The Code Domain Power display again shows the test model.

Measuring the Relative Code Domain Power Triggered

If the code domain power measurement is performed without external triggering, a section of

approximately 20 ms of the test signal is recorded at an arbitrary moment to detect the start of a 3GPP

FDD frame in this section. Depending on the position of the frame start, the required computing time

can be quite long. Applying an external (frame) trigger can reduce the computing time.

Test setup:

Connect the RF output of the signal generator to the input of the R&S FSL.

Connect the reference input (EXT REF) on the rear panel of the R&S FSL to the reference input of

the signal generator (coaxial cable with BNC connectors).

Connect the external trigger input on the rear panel of the R&S FSL (EXT TRIGGER/GATE IN) to

the external trigger output of the signal generator.

3GPP Base Station Measurements (Option K72) R&S FSL

1300.2519.12 2.114 E-11

Signal generator settings (e.g. R&S SMU):

Frequency: 2.1175 GHz

Level: 0 dBm

Standard: WCDMA/3GPP

Test model: 1, 32 DPCH channels

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

The R&S FSL is set to its default state.

2. Change into the 3G FDD BTS mode.

Press the MODE key and activate the 3G FDD BTS option.

3. Set the center frequency to 2.1175 GHz.

Press the FREQ key.

The frequency menu is displayed.

In the dialog box, enter 2.1175 using the numeric keypad and confirm with the GHz key.

4. Adjust the reference level and scrambling code.

Press the MEAS key.

The measurement menu is displayed.

Press the Auto Level & Code softkey.

The firmware adjusts the reference level and then searches the scrambling code automatically.

5. Select the Code Domain Power measurement.

Press the MEAS key.

Press the Code Dom Power Diagram softkey.

6. Select an external trigger source.

Press the TRIG key.

Press the Trigger Source softkey and select the External option.

The Code Domain Power of signal according to test model 1 with 32 channels is displayed.

The repetition rate of the measurement increases considerably compared to the repetition rate

of a measurement without an external trigger.

Trigger offset

Adelay of the trigger event referenced to the start of the 3GPP FDD frame can be compensated by

modifying the trigger offset.

1. Press the TRIG key.

2. Press the Trigger Offset softkey and enter 100 using the numeric keypad and confirm with the µs

key.

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1300.2519.12 2.115 E-11

Setup for Base Station Tests

This section describes how to set up the R&S FSL for 3GPP FDD base station tests. As a prerequisite

for starting the test, the instrument must be correctly set up and connected to the AC power supply as

described in the Quick Start Guide, chapter 1. Furthermore, the R&S FSL must be equipped with the

3GPP Base Station Measurements option (R&S FSL–K72). Installation instructions are provided in the

Quick Start Guide, chapter 3.:

Standard test setup

Base

Transmission

Station

EXT TRIGGER

Frame

Trigger

INPUT

TX signal

ext. reference signal

EXT

REF

R&S FSL

Fig. 2-81 Base Transmission station test setup

Connect the antenna output (or TX output) of the base transmission station to RF input of the

R&S FSL via a power attenuator of suitable attenuation.

The following values are recommended for the external attenuator to ensure that the RF input of the

R&S FSL is protected and the sensitivity of the R&S FSL is not reduced too much.

Max. power Recommended ext. attenuation

55 to 60 dBm 35 to 40 dB

50 to 55 dBm 30 to 35 dB

45 to 50 dBm 25 to 30 dB

40 to 45 dBm 20 to 25 dB

35 to 40 dBm 15 to 20 dB

30 to 35 dBm 10 to 15 dB

25 to 30 dBm 5to 10 dB

20 to 25 dBm 0to 5 dB

<20 dBm 0 dB

For signal measurements at the output of two–port networks, connect the reference frequency of

the signal source to the reference input of the R&S FSL (EXT REF).

To ensure that the error limits specified by the 3GPP standard are met, the R&S FSL should use an

external reference frequency for frequency measurements on base stations. For instance, a

rubidium frequency standard may be used as a reference source.

If the base station is provided with a trigger output, connect this output to the trigger input of the

R&S FSL (EXT TRIGGER/GATE IN).

Basic settings

1. Enter the external attenuation).

2. Enter the reference level.

3. Enter the center frequency.

4. Set the trigger.

5. Select the standard and measurement.

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CDMA2000 Base Station Measurements (Option K82)

This section explains basic CDMA2000 base station tests by means of a setup with a signal generator,

e.g. an R&S SMU. It describes how operating and measurement errors can be avoided using correct

settings. The measurements are performed with an R&S FSL equipped with the CDMA2000 Base

Station Measurements option (K82).

The following measurements are described:

Measuring the Signal Channel Power

Measuring the Spectrum Emission Mask

Measuring the Relative Code Domain Power and the Frequency Error

–Synchronization of the reference frequencies

–Behavior with deviating center frequency setting

Measuring the triggered Relative Code Domain Power

– Adjusting the trigger offset

–Behaviour with the wrong PN offset

Measuring the Composite EVM

Measuring the Peak Code Domain Error and the RHO Factor

–Displaying RHO

Furthermore, the test setup for base station tests is given:

Test Setup for Base Station Tests

As the CDMA2000 Base Station Measurements option also supports the CDMA2000 Standard, the

examples are performed on an CDMA2000 signal.

General test setup:

The measurements are performed with the following units and accessories:

R&S FSL equipped with the CDMA2000 Base Station Measurements option

R&S SMU signal generator equipped with option SMU-B9 / B10 / B11 baseband generator and SMU-

K46 CDMA2000 incl. 1xEVDV.

1 coaxial cable, 50



,approximately 1 m, N connector

2 coaxial cables, 50



,approximately 1 m, BNC connector

This option is available from firmware version 1.90.

Measuring the Signal Channel Power

In the Power measurement, the total channel power of the CDMA2000 signal is displayed. The

measurement also displays spurious emeissions like harmonics or intermodulation products that occur

close to the carrier.

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1300.2519.12 2.117 E-11

Test setup:

Connect the RF output of the signal generator to the RF input of the R&S FSL (coaxial cable with N

connectors).

Signal generator settings:

Frequency: 878.49 MHz

Level: 0 dBm

Standard: CDMA2000

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

2. Activate the CDMA2000 BTS Analyzer mode.

Press the MODE key and activate the CDMA2000 BTS Analyzer option.

3. Start the Power measurement

Press the MEAS key.

Press the Power softkey.

4. Set the center frequency.

Press the FREQ key and enter 878.49 MHz.

5. Set the reference level.

Press the AMPT key and enter 0dBm.

On the screen, the spectrum of the signal and the corresponding power levels within the 1.2288 MHz

channel bandwidth are displayed. In the table below the diagram, the numeric values of the channel

bandwidth of the TX xhannel and power level of the analyzed signal are listed.

Fig. 2-82: Measurement of the signal channel power

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1300.2519.12 2.118 E-11

Measuring the Spectrum Emission Mask

To detect spurious emissions such as harmonics or intermodulation products, the R&S FSL offers a

spectrum emission mask measurement. The measurement compares the power against the spurious

emissions mask in the range from -4 MHz to 4 MHz around the carrier. The exact measurement

settings like the filter that is used depend on the Band Class parameter (for supported Band Classes

see chapter 4 "Instrument Functions").

Test setup:

Connect the RF output of the signal generator to the RF input of the R&S FSL (coaxial cable with N

connectors).

Signal generator settings:

Frequency: 878.49 MHz

Level: 0 dBm

Standard: CDMA2000

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

2. Activate the CDMA2000 BTS Analyzer mode.

Press the MODE key and activate the CDMA2000 BTS Analyzer option.

3. Start the measurement.

Press the MEAS key.

Press the Spectrum Emission Mask softkey.

4. Set the center frequency.

Press the FREQ key and enter 878.49 MHz.

5. Set the reference level.

Press the AMPT key and enter 0dBm.

6. Select a bandclass

Press the Bandclass softkey and select BandClass 0: 800 MHz Cellular Band from the list.

On the screen, the spectrum of the signal is displayed, including the limit line defined in the standard.

To understand where and about how much the measurement has failed, the List Evaluation table shows

the frequencies, where spurious emissions occur (for details on the table structure see chapter 4

"Instrument Functions").

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Fig. 2-83: Measurement of the Spectrum Emission Mask

Measuring the Relative Code Domain Power and the

Frequency Error

ACode Domain Power measurement analyses the signal over a single Power Control Group (PCG). It

also determines the power of all channels.

ACode Domain Power measurement on a test model (having 9 channels) is performed. The basic

parameters of the Code Domain Power measurements, which allows an analysis of the signal, are

changed one after the other to demonstrate the ensuing effects: values adapted to the measurement

signal are changed to non–adapted values.

Note: In the following examples, adjusting the settings of the code domain measurements is described

using the dialog boxes. Alternately the settings can also be modified by using the

corresponding hardkeys as in the base unit (e.g. the center frequency can be either set via the

Frontend Settings dialog box, but also via the FREQ key).

Test setup:

Connect the RF output of the signal generator to the RF input of the R&S FSL.

Connect the reference input (EXT REF) on the rear panel of the R&S FSL to the reference output

(REF) of the signal generator (coaxial cable with BNC connectors).

Signal generator settings:

Frequency: 878.49 MHz

Level: 0 dBm

Standard: CDMA2000

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1300.2519.12 2.120 E-11

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

2. Activate the CDMA2000 BTS Analyzer Mode.

Press the MODE key and select CDMA2000 BTS Analyzer.

3. Enter the Code Domain Analyzer.

Press the MEAS key

Press the Code Domain Analyzer softkey.

4. Start the measurement

In the Code Domain Analyzer softkey menu, press the Select Meas softkey.

Press the Code Domain Power softkey.

5. Enter the Settings Overview dialog box.

Press the Settings softkey.

Press the Settings Overview softkey.

The Settings Overview dialog box is displayed.

6. Set the center frequency and the reference level.

In the Settings Overview dialog box select the Frontend button.

In the Center Frequency field enter 878.49 MHz.

In the Ref Level field enter 10 dBm.

Close the Frontend Settings dialog box.

Close the Settings Overview box.

In the two screens, the following results are displayed: screen A shows the power of the code domain of

the signal. The x-axis represents the individual channels (or codes), while the y-axis shows the power of

each channel. In screen B the result summary is displayed. It shows the numeric results of the code

domain power measurement, including the frequency error.

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Fig. 2-84: Measurement of the code domain power without external reference

Synchronization of the reference frequencies

The frequency error can be reduced by synchronizing the transmitter and the receiver to the same

reference frequency.

7. Press the SETUP key.

Press the Reference Int/Ext softkey to switch to an external reference.

Screen A again shows the CDP measurement and screen B the result summary. After the

synchronization of the reference frequencies of the devices, the frequency error should now be smaller

than 10 Hz.

Behavior with deviating center frequency setting

Ameasurement can only be valid if the center frequency of the DUT and the analyzer are balanced.

8. On the signal generator, change the center frequency in steps of 0.1 kHz and observe the analyzer

screen.

Up to a frequency error of approximately 1.0 kHz, a Code Domain Power measurement on the

R&S FSL is still possible. A frequency error within this range causes no apparent difference in the

accuracy of the Code Domain Power measurement.

Above a frequency error of 1.0 kHz, the probability of incorrect synchronization increases. This is

indicated by the SYNC FAILED error message.

If the frequency error exceeds approximately 1.5 kHz, a Code Domain Power measurement cannot

be performed. This is indicated by the SYNC FAILED error message.

Reset the center frequency of the signal generator to 878.49 MHz.

Note: The center frequency of the DUT should not deviate by more than 1.0 kHz from that of the

R&S FSL.

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Measuring the triggered Relative Code Domain Power

If the code domain power measurement is performed without external triggering, a section of the test

signal is recorded at an arbitrary point of time and the firmware attempts to detect the start of a power

control group (PCG). To detect this start, all possibilities of the PN sequence location have to be tested

in Free Run trigger mode. This requires computing time. This computing time can be reduced by using

an external (frame) trigger and entering the correct PN offset. If the search range for the start of the

power control group and the PN offset are known then fewer possibilities have to be tested. This

increases the measurement speed.

Test setup:

Connect the RF output of the signal generator to the input of the R&S FSL.

Connect the reference input (EXT REF) on the rear panel of the R&S FSL to the reference input of

the signal generator (coaxial cable with BNC connectors).

Connect the external trigger input on the rear panel of the R&S FSL (EXT TRIGGER/GATE IN) to

the external trigger output of the signal generator.

Signal generator settings (e.g. R&S SMU):

Frequency: 878.49 MHz

Level: 0 dBm

Standard: CDMA2000

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

2. Activate the CDMA2000 BTS Analyzer Mode.

Press the MODE key and select CDMA2000 BTS Analyzer.

3. Enter the Code Domain Analyzer.

Press the MEAS key

Press the Code Domain Analyzer softkey.

4. Start the measurement.

In the Code Domain Analyzer softkey menu, press the Select Meas softkey.

Press the Code Domain Power softkey.

5. Enter the Settings Overview dialog box.

Press the Settings softkey.

Press the Settings Overview softkey.

The Settings Overview dialog box is displayed.

6. Set the center frequency and the reference level.

In the Settings Overview dialog box select the Frontend button.

In the Center Frequency field enter 878.49 MHz.

In the Ref Level field enter 10 dBm.

Close the Frontend Settings dialog box.

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Close the Settings Overview box.

In the two screens, the following results are displayed: by default, screen A shows the code domain

power of the signal. Compared to the measurement without an external trigger (see previous example),

the repetition rate of the measurement increases. In screen B the result summary is displayed. In the

row Trigger to Frame, the offset between the trigger event and and the start of the PCG (Power Control

Group) is shown.

Fig. 2-85: Measurement of the code domain power with an external trigger source

Note that the Trigger to Frame parameter is only visible in the full screen mode of the Result Summary

display.

7. Change into full screen mode..

Set the focus on screen B by pressing the Screen Focus A/B softkey.

Press the Screen Size Split/Full softkey.

The display is now in full screen mode

Adjusting the trigger offset

The delay between the trigger event and the start of the PCG can be compensated for by adjusting the

trigger offset.

8. Set an external trigger source and the trigger offset.

In the Settings Overview dialog box select the IQ Capture button.

Set the Trigger Source radio button to External.

Set the Trigger Offset to 100Rsto compensate analog delays of the trigger event.

In the two screens, the following results are displayed: Screen A shows the the same as above. In

screen B the result summary is displayed. In the Trg to Frame result, the offset between the trigger

event and the start of the PCG has been adjusted.

Behaviour with the wrong PN offset

The last adjustment to be made is setting the PN (Pseudo Noise) offset correctly. The measurement

can only be valid, if the PN offset on the analyzer is the same as that of the transmit signal.

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9. Set a PN Offset.

–In the Settings Overview dialog box select the Demodulation Settings button.

–In the PN Offset field enter 200.

Again, screen A shows the CDP measurement, screen B the result summary. In the result summary,

the Trigger to Frame result is not correct. Also, the error message SYNC FAILED indicates that the

synchronization has failed.

–In the PN Offset field enter 0

After adjusting it, the PN offset on the R&S FSL is the same as that of the signal. In the result summary

the Trg To Frame value is now shown correctly.

Fig. 2-86: Result summary of the code domain measurement with the Trigger to Frame

value

Measuring the Composite EVM

The Error Vector Magnitude (EVM) describes the quality of the measured signal compared to an ideal

reference signal generated by the R&S FSL. In the I-Q plane, the error vector represents the ratio of the

measured signal to the ideal signal on symbol level. The error vector is equal to the square root of the

ratio of the measured signal to the reference signal. The result is given in %.

In the Composite EVM measurement the error is averaged over all channels (by means of the root

mean square) for a given Power Control Group (PCG). The measurement covers the entire signal

during the entire observation time. On screen the results are shown in a diagram, in which the x-axis

represents the examined PCGs and the y-axis shows the EVM values.

Test Setup:

Connect the RF output of the Signal Generator to the RF input of the R&S FSL (coaxial cables with

Nconnectors).

Connect the reference input (EXT REF IN/OUT) on the rear panel of the R&S FSL to the reference

output (REF) on the signal generator (coaxial cable with BNC connectors).

Connect external triggering of the analyzer (EXT TRIG GATE) to the signal generator’s trigger

(TRIGOUT1 at PAR DATA).

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Signal generator settings:

Frequency. 878.49 MHz

Level: 0 dBm

Standard: CDMA2000

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

2. Activate the CDMA2000 BTS Analyzer Mode.

Press the MODE key and select CDMA2000 BTS Analyzer.

3. Enter the Code Domain Analyzer.

Press the MEAS key

Press the Code Domain Analyzer softkey.

4. Start the measurement.

Press the Select Meas softkey

Press the More softkey

Select the Composite EVM softkey and the measurement begins.

5. Enter the Settings Overview dialog box.

Press the Settings softkey.

Press the Settings Overview softkey.

The Settings Overview dialog box is displayed.

6. Set the center frequency and the reference level.

In the Settings Overview dialog box select the Frontend button.

In the Center Frequency field enter 878.49 MHz.

In the Ref Level field enter 10 dBm.

Close the Frontend Settings dialog box.

7. Set an external trigger source.

In the Settings Overview dialog box, select the IQ Capture button.

Set the Trigger Source radio button to External.

Close the Settings Overview box

In the two screens, the following results are displayed: by default, Screen A shows the diagram of the

Composite EVM measurement result. In screen B the result summary is displayed. It shows the

numeric results of the Code Domain Power measurement, including the values for the Composite EVM.

CDMA2000 Base Station Measurements (Option K82) R&S FSL

1300.2519.12 2.126 E-11

Measuring the Peak Code Domain Error and the RHO Factor

The Code Domain Error Power describes the quality of the measured signal compared to an ideal

reference signal generated by the R&S FSL. In the I-Q plane, the error vector represents the difference

of the measured signal and the ideal signal. The Code Domain Error is the difference in power on

symbol level of the measured and the reference signal projected to the class of of the base spreading

factor. The unit of the result is dB.

In the Peak Code Domain Error (PCDE) measurement, the maximum error value over all channels is

determined and displayed for a given PCG. The measurement covers the entire signal during the entire

observation time. On screen the results are shown in a diagram, in which the x-axis represents the

PCGs and the y-axis shows the PCDE values.

Ameasurement of the RHO factor is shown in the second part of the example. RHO is the normalized,

correlated power between the measured and the ideal reference signal. The maximum value of RHO is

1. In that case the measured signal and the reference signal are identical. When measuring RHO, it is

required that only the pilot channel is active.

Test setup:

Connect the RF output of the signal generator to the RF input of the R&S FSL (coaxial cable with N

connectors).

Connect the reference input (EXT REF IN/OUT) on the rear panel of the R&S FSL to the reference

output (REF) on the signal generator (coaxial cable with BNC connectors).

Connect external triggering of the R&S FSL (EXT TRIG GATE) to the signal generator trigger

(TRIGOUT1 at PAR DATA).

Signal generator settings:

Frequency: 878.49 MHz

Level: 0 dBm

Standard: CDMA2000

Procedure:

1. Set the R&S FSL to its default state.

Press the PRESET key.

2. Activate the CDMA2000 BTS Analyzer mode.

Press the MODE key and activate the CDMA2000 BTS Analyzer option.

3. Enter the Code Domain Analyzer.

Press the MEAS key.

Press the Code Domain Analyzer softkey.

4. Start the Peak Code Domain Error measurement.

Press the Select Meas softkey

Press the More softkey

Select the Peak Code Domain Error softkey and start the measurement.

5. Enter the Settings Overview dialog box.

Press the Settings softkey.

Press the Settings Overview softkey.

R&S FSL CDMA2000 Base Station Measurements (Option K82)

1300.2519.12 2.127 E-11

The Settings Overview dialog box is displayed.

6. Set the center frequency and the reference level.

In the Settings Overview dialog box select the Frontend button.

In the Center Frequency field enter 878.49 MHz.

In the Ref Level field enter 0dBm.

Close the Frontend Settings dialog box.

7. Set an external trigger source.

In the Settings Overview dialog box, select the IQ Capture button.

Set the Trigger Source radio button to External.

Close the Settings Overview box

In the two screens, the following results are displayed: by default, screen A shows the diagram of the

Peak Code Domain Error. In screen B the result summary is displayed. It shows the numeric results of

the code domain power measurement, but nothing specific about the Peak Code Domain Error.

Displaying RHO

Note: Make sure that all channels except the pilot channel (code 0.64) are OFF, so that only the pilot

channel is available in the measurement.

No specific measurement is required to get the value for RHO. The R&S FSL always calculates this

value automatically regardless of the code domain measurement performed. Besides the results of the

code domain measurements, the numeric result of the RHO measurement is shown in the result

summary, by default shown in screen B.

Test Setup for Base Station Tests

This section describes the default settings of the R&S FSL, if it is used as a CDMA2000 base station

tester. Before starting the measurements, the R&S FSL has to be configured correctly and supplied with

power as described in the Quick Start Guide, "Preparing For Use". Furthermore, the application

firmware of the R&S FSL-K82 must be enabled. Installation and enabling of the application firmware are

described in chapter 4 "Instrument Functions". :

NOTICE Risk of damage to the instrument

Before taking the instrument into operation, make sure that

•the housing covers are in place and their screws have been tightened,

•the ventilation slits are free,

•no signal voltage levels above the permissible limits are applied to the inputs,

•the outputs of the unit are not overloaded or wrongly connected.

Failure to comply may result in damage to the instrument

CDMA2000 Base Station Measurements (Option K82) R&S FSL

1300.2519.12 2.128 E-11

Standard test setup:

BTS

RF INPUT

EXTERNAL

ATTENUATION

EVEN SECOND

CLOCK TRIGGER

EXT TRIGGER

EXT REF

EXTERNAL

REFERENCE

SIGNAL

TX SIGNAL

R&S FSL

Connect the antenna output (or TX output) of the base station to the RF input of the R&S FSL. Use

power attenuator exhibiting suitable attenuation.

The following values for external attenuation are recommended to ensure that the RF input of the

analyzer is protected and the sensitivity of the unit is not reduced too much:

Maximum Power Recommended external attenuation



55 to 60 dBm 35 to 40 dB



50 to 55 dBm 30 to 35 dB



45 to 50 dBm 25 to 30 dB



40 to 45 dBm 20 to 25 dB



35 to 40 dBm 15 to 20 dB



30 to 35 dBm 10 to 15 dB



25 to 30 dBm 5to 10 dB



20 to 25 dBm 0to 5 dB

20 dBm 0 dB

For signal measurements at the output of two-port networks, connect the reference frequency of the

signal source to the rear reference input of the analyzer.

The R&S FSL must be operated with an external frequency reference to ensure that the error limits

of the CDMA2000 specification for frequency measurements on base stations are met. A rubidium

frequency standard can be used as a reference source for example.

If the base station has a trigger output, connect the trigger output of the base station to the rear

trigger input of the analyzer (EXT TRIG GATE).

Presettings

Enter the external attenuation

Enter the reference level

Enter the center frequency

Set the trigger

If used, enable the external reference

Select the standard and the desired measurement

Set the PN offset

R&S FSL WLAN TX Measurements (Option K91)

1300.2519.12 2.129 E-11

WLAN TX Measurements (Option K91/K91n)

This section describes measurement examples for the WLAN TX Measurements option (K91) and gives

details to signal processing. For further information on measurement examples refer also to the Quick

Start Guide, chapter 5 "Basic Measurement Examples".

This option is available from firmware version 1.20. The option R&S FSL-K91n is available from firmware

Signal Processing of the IEEE 802.11a application

Abbreviations

a,symbol at symbol lof sub carrier k

EVM error vector magnitude of sub carrier k

EVM error vector magnitude of current packet

signal gain

ffrequency deviation between Tx and Rx

lsymbol index ]_,1[ Symbolsnofl

symbolsnof _number of symbols of payload

Hchannel transfer function of sub carrier k

kchannel index ]32,31[=k

mod

Kmodulation dependant normalization factor



relative clock error of reference oscillator

r,sub carrier kof symbol l

This description gives a rough view of the IEEE 802.11a application signal processing. Details are

disregarded in order to get a concept overview.

Adiagram of the interesting blocks is shown in Fig. 2-87 First the RF signal is down converted to the IF

frequency =

f20.4 MHz. The resulting IF signal )(trIF is shown on the left–hand side of the figure. After

bandpass filtering, the signal is sampled by an Analog to Digital Converter (ADC) at a sampling rate of

f81.6 MHz. This digital sequence is resampled to the new sampling frequency of =

f80 MHz which is

amultiple of the Nyquist rate (20 MHz). The subsequent digital down converter shifts the IF signal to the

complex base band. In the next step the base band signal is filtered by a FIR filter. To get an idea, the rough

transfer function is plotted in the figure. This filter fulfills two tasks: first it suppresses the IF image frequency,

secondly it attenuates the aliasing frequency bands caused by the subsequent down sampling. After filtering,

the sequence is sampled down by the factor of 4. Thus the sampling rate of the down sampled sequence

)(ir is the Nyquist rate of =

f20 MHz. Up to this point the digital part is implemented in an ASIC.

version 1.90.

WLAN TX Measurements (Option K91) R&S FSL

1300.2519.12 2.130 E-11

frequency

compensation

FIR

FFT

estimation

gain, frequency, time

user defined

compensation

payload

window

packet search:

1.coarse timing

2.fine timing

timing

pilot

table

16.4 MHz

estimate

data symbols

channel

estimation

measurement

parameters

pilots + data

fs3=20MHz

e-j

F·kT S

!HFIR(f)

4"r(i)

rl,k

al,k

r'l,k

data

r''l,k

fs1=81.6 MHz

F(t)~

~Resampler

fs2=80 MHz

ADC

full

compensation

N=64

fcoarse



(LS

)

(PL)

fres

t,d

l

al,k

Fig. 2-87 Signal processing of the IEEE 802.11a application

In the lower part of the figure the subsequent digital signal processing is shown. In the first block the

packet search is performed. This block detects the Long Symbol (LS) and recovers the timing. The

coarse timing is detected first. This search is implem ented in the time domain. The algorithm is based on

cyclic repetition within the LS after 64

Nsamples. Numerous treatises exist on this subject, e.g. [1] to

[3]. Furthermore a coarse estimate coarse

1o f t h e R x –T x f r eq ue n c y o f fs e t fis derived from the metric in

[6]. This can easily be understood because the phase of )()( *Nirir +is determined by the frequency

offset. As the frequency deviation fcan exceed half a bin (distance between neighbor sub–carriers)

the preceding Short Symbol (SS) is also analyzed in order to detect the ambiguity.

After the coarse timing calculation the time estimate is improved by the fine timing calculation.This is

achieved by first estimating the coarse frequency response )LS(

ˆk

H,with ]26,26[=kdenoting the channel

ind e x o f th e o c c up ie d s u b –c ar ri er s. Firs t the F FT o f th e L S i s ca lc ulate d . Af t e r t h e F FT c a lc u lat i o n t h e k no wn

symbol information of the LS sub–carriers is removed by dividing by the symbols. The result is a coarse

estimate k

ˆof the channel transfer function. In the next step the complex channel impulse response is

computed by an IFFT. Next the energy of the windowed impulse response (the window size is equal to

the guard period) is calculated for every trial time. Afterwards the trail time of the maximum energy is

detected. This trial time is used to adjust the timing.

Now the position of the LS is known and the starting point of the useful part of the first payload symbol

can be derived. In the next block this calculated time instant is used to position the payload window

Only the payload part is windowed. This is sufficient because the payload is the only subject of the

subsequent measurements.

In the next block the windowed sequence is compensated by the coarse frequency estimate coarse

.This is

necessary because otherwise inter channel interference (ICI) would occur in the frequency domain.

The transition to the frequency domain is achieved by an FFT of length 64. The FFT is performed

symbol–wise for every of the symbolsnof _symbols of the payload. The calculated FFTs are described

by kl

r,with

the symbol index ]_,1[ symbolsnofl=and

the channel index ]32,31[ =k.

1The hat generally describes an estimate. Example: x

)

is the estimate of x.

R&S FSL WLAN TX Measurements (Option K91)

1300.2519.12 2.131 E-11

In case of an additive white Gaussian noise (AWGN) channel the FFT is described by [4], [5]

phasephasej

klkl neHgaKr kl

common

kl ,

(

,mod

)timing(

)(

,+××××= +(10)

with

the modulation–dependant normalization factor mod

the symbol kl

a,of sub–carrier kat symbol l,

the gain l

gat the symbol lin relation to the reference gain 1

gat the long symbol (LS),

the channel frequency response k

Hat the long symbol (LS),

the common phase drift )common(

phase of all sub–carriers at symbol l(see below),

the phase )timing(

,kl

phase of sub–carrier kat symbol lcaused by the timing drift (see below),

the independent Gaussian distributed noise samples kl

n,.

The common phase drift in equation (10) is given by

lrests

common

ldylTfNNphase +×××= /2

)(



(11)

with

80=

Nbeing the number of Nyquist samples of the symbol period,

Nbeing the number of Nyquist samples 64

Nof the useful part of the symbol,

rest

fbeing the (not yet compensated) frequency deviation,

being the phase jitter at the symbol l.

In general, the coarse frequency estimate coarse

(see figure 1) is not error–free. Therefore the remaining

frequency error rest

frepresents the not yet compensated frequency deviation in kl

r,.Consequently the

overall frequency deviation of the device under test (DUT) is calculated by restcoarse fff +=ˆ.Remark:

The only motivation for dividing the common phase drift in equation (11) into two parts is to be able to

calculate the overall frequency deviation of the DUT.

The reason for the phase jitter l

in equation (11) may be different. The nonlinear part of the phase

jitter may be caused by the phase noise of the DUT oscillator. Another reason for nonlinear phase jitter

may be the increase of the DUT amplifier temperature at the beginning of the burst. Please note that

besides the nonlinear part the phase jitter l

also contains a constant part. This constant part is

caused by the not yet compensated frequency deviation rest

f.To understand this, please keep in mind

that the measurement of the phase starts at the first symbol 1

lof the payload. In contrast the channel

frequency response k

Hin equation (10) represents the channel at the long symbol of the preamble.

Consequently the not yet compensated frequency deviation rest

fproduces a phase drift between the

long symbol and the first symbol of the payload. Therefore this phase drift appears as a constant value

("DC value'') in l

Referring to the IEEE 802.11a measurement standard Chapter 17.3.9.7 "Transmit modulation accuracy test''

[6], the common phase drift )common(

phase must be estimated and compensated from the pilots. Therefore this

"symbol wise phase tracking'' (Tracking Phase) is activated as the default setting of the R&S FSL–K91/K91n.

Furthermore the timing drift in equation (10) is given by

lkNNphase s

kl ××××=



)timing(

,(12)

WLAN TX Measurements (Option K91) R&S FSL

1300.2519.12 2.132 E-11

with



being the relative clock deviation of the reference oscillator. Normally a symbol–wise timing jitter

is negligible and thus not modeled in equation (12). There may be situations where the timing drift has

to be taken into account. This is illustrated by an example: In accordance to [6] the allowed clock

deviation of the DUT is up to =

max



20 ppm. Furthermore a long packet with 400_=symbolsnof symbols

is assumed. From equations (10) and (12), it results that the phase drift of the highest sub–carrier

kin the last symbol symbolsnofl_=is 93 degrees. Even in the noise–free case, this would lead to

symbol errors. The example shows that it is actually necessary to estimate and compensate the clock

deviation, which is accomplished in the next block.

Referring to the IEEE 802.11a measurement standard [6], the timing drift )timing(

,kl

phase is not part of the

requirements. Therefore the "time tracking'' (Tracking Time) is not activated as the default setting of the

R&S FSL–K91/K91n.

The time tracking option should rather be seen as a powerful analyzing option.

In addition the tracking of the gain l

gin equation (10) is supported for each symbol in relation to the

reference gain 1

gat the time instant of the long symbol (LS). At this time the coarse channel transfer

function )L(

ˆS

His calculated. This makes sense since the sequence kl

'is compensated by the coarse

channel transfer function )L(

ˆS

Hbefore estimating the symbols. Consequently a potential change of the

gain at the symbol l(caused, for example, by the increase of the DUT amplifier temperature) may lead

to symbol errors especially for a large symbol alphabet

of the MQAM transmission. In this case the

estimation and the subsequent compensation of the gain are useful.

Referring to the IEEE 802.11a measurement standard [6], the compensation of the gain l

gis not part

of the requirements. Therefore the "gain tracking'' (Tracking Gain) is not activated as the default setting

of the R&S FSL–K91/K91n.

How can the parameters above be calculated? In this application the optimum maximum likelihood

algorithm is used. In the first estimation step the symbol–independent parameters rest

fand



are

estimated. The symbol dependent parameters can be neglected in this step i.e. the parameters are set

to 1=

gand 0=

.Referring to equation (10) the log likelihood function2

lkNNhasep

lTfNNhasep

with

eHarfL

gti

rests

common

symbolsnof

hasephasepj

klklrest

gti

common

××××=

×××=

××=%%

==







)

(

)min(

)(

121,7,7,21

(

)(

,,1

)min(

)(

)

(13)

must be calculated as a function of the trial parameters rest

and



.The trial parameters leading to

the minimum of the log likelihood function are used as estimates rest

and



ˆ.In equation (13)(13) the

known pilot symbols kl

a,are read from a table.

In the second step for every symbol lthe log likelihood function

lkNNhasep

dlTfNNhasep

with

eHgardgL

gti

lrests

common

hasephasepj

lklklll

gti

common

××××=

+×××=

×××=%

=



#

)

(

)min(

)(

21,7,7,21

(

)(

,,2

)min(

)(

2The tilde generally describes an estimate. Example: x

is the trial parameter of x.

R&S FSL WLAN TX Measurements (Option K91)

1300.2519.12 2.133 E-11

is calculated as a function of the trial parameters l

and l

.Finally, the trial parameters leading to the

minimum of the log likelihood function are used as estimates l

ˆand l

ˆ.

This robust algorithm works well even at low signal to noise ratios with the Cramer Rao Bound being

reached.

After estimation of the parameters, the sequence kl

r,is compensated in the compensation blocks.

In the upper analyzing branch the compensation is user–defined i.e. the user determines which of the

parameters are compensated. This is useful in order to extract the influence of these parameters. The

resulting output sequence is described by k

In the lower compensation branch the full compensation is always performed. This separate

compensation is necessary in order to avoid symbol errors. After the full compensation the secure

estimation of the data symbols kl

ˆis performed. From equation (10) it is clear that first the channel

transfer function k

Hmust be removed. This is achieved by dividing the known coarse channel estimate

)

LS(

ˆk

Hcalculated from the LS. Usually an error free estimation of the data symbols can be assumed.

In the next block a better channel estimate )PL(

ˆk

Hof the data and pilot sub–carriers is calculated by using all

symbolsnof _symbols of the payload (PL). This can be accomplished at this point because the phase is

compensated and the data symbols are known. The long observation interval of symbolsnof _s ym bols (comp ared

to the short interval of 2 symbols for the estimation of )L(

ˆS

H)leads to a nearly error–free channel estimate.

In the following equalizer block k

'is compensated by the channel estimate. The resulting channel–

compensated sequence is described by kl

'' .The user may either choose the coarse channel estimate

)L(

ˆS

H(from the long symbol) or the nearly error–free channel estimate )L(

ˆS

H(from the payload) for

equalization. In case of using the improved estimate )L(

ˆS

Ha 2 dB reduction of the subsequent EVM

measurement can be expected.

According to the IEEE 802.11a measurement standard [6], the coarse channel estimation )L(

ˆS

H(from

the long symbol) has to be used for equalization. Therefore the default setting of the R&S FSL–K91 is

equalization from the coarse channel estimate derived from the long symbol.

In the last block the measurement variables are calculated. The most important variable is the error

vector magnitude

×=

symbolsnof

klklk aKr

symbolsnof

EVM

,mod

'',

1(14)

of the sub–carrier kof the current packet. Furthermore the packet error vector magnitude

%&=

)0(26

EVMEVM (15)

is derived by averaging the squared k

EVM versus k.Finally the average error vector magnitude

packetsnof

counter

counterEVM

packetsnof

EVM

2)(

1(16)

is calculated by averaging the packet EVM of all packetsnof _detected packets. This parameter is

equivalent to the so–called "RMS average of all errors RMS

Error '' of the IEEE 802.11a measurement

commandment (see [6], Chapter 17.3.9.7).

WLAN TX Measurements (Option K91) R&S FSL

1300.2519.12 2.134 E-11

Literature

[1] Speth, Classen, Meyr: ''Frame synchronization of OFDM systems in frequency selective fading

channels", VTC '97, pp. 1807–1811

[2] Schmidl, Cox: ''Robust Frequency and Timing Synchronization of OFDM", IEEE Trans. on

Comm., Dec. 1997, pp. 1613–621

[3] Minn, Zeng, Bhargava: ''On Timing Offset Estimation for OFDM", IEEE Communication Letters,

July 2000, pp. 242–244

[4] Speth, Fechtel, Fock, Meyr: ''Optimum Receiver Design for Wireless Broad–Band Systems

Using OFDM – Part I", IEEE Trans. On Comm. VOL. 47, NO 11, Nov. 1999

[5] Speth, Fechtel, Fock, Meyr: ''Optimum Receiver Design for Wireless Broad–Band Systems

Using OFDM – Part II", IEEE Trans. On Comm. VOL. 49, NO 4, April. 2001

[6] IEEE 802.11a, Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY)

specifications

Signal Processing of the IEEE 802.11b application

Abbreviations

timing offset



frequency offset

(



phase offset

{

}

KRGAcalculation of the angle of a complex value

EVM error vector magnitude

ˆestimate of the gain factor in the I–branch

ˆestimate of the gain factor in the Q–branch

accurate estimate of the crosstalk factor of the Q–branch in the I–branch

)(

vhs

estimated baseband filter of the transmitter

)(

vhr

estimated baseband filter of the receiver

ˆestimate of the IQ–offset in the I–branch

)(vr measurement signal

)(

vs estimate of the reference signal

)(

ˆvsnestimate of the power normalized and undisturbed reference signal

{

}

KREAL calculation of the real part of a complex value

{

}

KIMAG calculation of the imaginary part of a complex value

R&S FSL WLAN TX Measurements (Option K91)

1300.2519.12 2.135 E-11

This description gives a rough overview of the signal processing concept of the IEEE 802.11b

application.

Ablock diagram of the measurement application is shown in Fig. 2-88.The baseband signal of an IEEE

802.11b wireless LAN system transmitter is sampled with a sampling rate of 44 MHz.

Fig. 2-88 Signal processing of the IEEE 802.11b application

The first task of the measurement application is to detect the position of the bursts within the

measurement signal )(

1vr .The detection algorithm is able to find the positions of the beginning of

short and long bursts and can distinguish between them. The algorithm also detects the initial state of

the scrambler. This is required if IEEE 802.11 signals should be analyzed, because this standard does

not specify the initial state of the scrambler.

With the knowledge of the start position of the burst, the header of the burst can be demodulated. The

bits transmitted in the header provide information about the length of the burst and the modulation type

used in the PSDU.

After the start position and the burst length is fully known, better estimates of timing offset, timing drift,

frequency offset and phase offset can be calculated using the entire data of the burst.

At this point of the signal processing a demodulation can be performed without decision error. After

demodulation the normalized and undisturbed reference signal )(vs is available.

If the frequency offset is not constant and varies with time, the frequency– and phase offset in several

partitions of the burst must be estimated and corrected. Additionally, timing offset, timing drift and gain

factor can be estimated and corrected in several partitions of the burst. These corrections can be

separately switched off in the demodulation settings menu.

Knowing the normalized power and undisturbed reference signal, the transmitter baseband filter is

estimated by minimizing the cost function

WLAN TX Measurements (Option K91) R&S FSL

1300.2519.12 2.136 E-11



=

 ×××=

1~~

)()(

)(

QIns

jfj ojoisiheerL



(



)(17)

of a maximum–likelihood–based estimator, where )(vr isthe over sampled measurement signal,

)(

ˆvsnthe over sampled power normalized and undisturbed reference signal, Nthe observation

length,

the filter length, f

,

(

,I

and )(

vhsthe variation parameters of the frequency–,

the phase, the IQ–offset and the coefficients of the transmitter filter. The frequency–, the phase– and

the IQ–offset are estimated jointly with the coefficients of the transmitter filter to increase the estimation

quality.

Once the transmitter filter is known, all other unknown signal parameters are estimated with a

maximum–likelihood–based estimation, which minimizes the cost function



 ×+××××=

2~~

)(

)

(

QIQQQQII

jfj ojosgsgjsgeerL



( '

(18)

where I

resp. Q

are the variation parameters of the gain used in the I– resp. the Q–branch, Q

is

the crosstalk factor of the Q–branch into the I–branch and )(vsIresp. )(vsQare the filtered reference

signal of the I– resp. the Q–branch. The unknown signal parameters are estimated in a joint estimation

process to increase the accuracy of the estimates.

The accurate estimates of the frequency offset, the IQ–imbalance, the quadratur–mismatch and the

normalized IQ–offset are displayed by the measurement software. The IQ–imbalance

ImbalanceIQ )

)

+

=(19)

is the quotient of the estimates of the gain factor of the Q–branch, the crosstalk factor and the gain

factor of the I–branch, the quadrature–mismatch

{

}

QQ gjgARGMismatchQuadrature

)

×+=(20)

is a measure for the crosstalk of the Q–branch into the I–branch. The normalized IQ–offset

ˆˆ

IQ Offset 1ˆˆ

=

+

(21)

is defined as the magnitude of the IQ–offset normalized by the magnitude of the reference signal.

At this point of the signal processing all unknown signal parameters such as timing–, frequency–,

phase–, IQ–offset and IQ–imbalance have been evaluated and the measurement signal can be

corrected accordingly.

Using the corrected measurement signal )(vr and the estimated reference signal )(

ˆvs the modulation

quality parameters can be calculated. The mean error vector magnitude (EVM)



)(

vsvr

EVM

(22)

is the quotient of the root–mean–square values of the error signal power and the reference signal

power, whereas the instant error vector magnitude

R&S FSL WLAN TX Measurements (Option K91)

1300.2519.12 2.137 E-11



)(

)( N

vsvr

vEVM

(23)

is the momentary error signal magnitude normalized by the root mean square value of the reference

signal power.

In [2] a different algorithm is proposed to calculate the error vector magnitude. In a first step the IQ–

offset in the I–branch

{}



REAL

Ir(v)

(24)

and the IQ–offset of the Q–branch

{}



IMAG

Qr(v)

(25)

are estimated separately, where r(v) is the measurement signal which has been corrected with the

estimates of the timing–, frequency– and phase offset, but not with the estimates of the IQ–imbalance

and IQ–offset. With these values the IQ–imbalance of the I–branch

{}



=

REAL

II or(v)

(26)

and the IQ–imbalance of the Q–branch

{}



=

IMAG

QQ or(v)

(27)

are estimated in a non–linear estimation in a second step. Finally, the mean error vector magnitude

{}

[]

{}

[]

err

)(IMAG

)(REAL

)(

govrgovr

))

))))

+

+

%% 





(28)

can be calculated with a non data aided calculation. The instant error vector magnitude

{}

[]

{}

[]

err

ˆˆ

)(IMAG

ˆˆ

)(REAL

)(

QQII

govrgovr

+

+

=(29)

is the error signal magnitude normalized by the root mean square value of the estimate of the

measurement signal power. The advantage of this method is that no estimate of the reference signal is

needed, but the IQ–offset and IQ–imbalance values are not estimated in a joint estimation procedure.

Therefore, each estimation parameter is disturbing the estimation of the other parameter and the

accuracy of the estimates is lower than the accuracy of the estimations achieved by equation (17). If the

EVM value is dominated by Gaussian noise this method yields similar results as equation (18).

WLAN TX Measurements (Option K91) R&S FSL

1300.2519.12 2.138 E-11

Literature

[1] Institute of Electrical and Electronic Engineers, Part 11: Wireless LAN Medium Access

Control (MAC) and Physical Layer (PHY) specifications,IEEE Std 802.11–1999, Institute of

Electrical and Electronic Engineers, Inc., 1999.

[2] Institute of Electrical and Electronic Engineers, Part 11: Wireless LAN Medium Access

Control (MAC) and Physical Layer (PHY) specifications: Higher–Speed Physical Layer

Extensions in the 2.4 GHz Band, IEEE Std 802.11b–1999, Institute of Electrical and

Electronic Engineers, Inc., 1999.

802.11b RF carrier suppression

Definition

The RF carrier suppression, measured at the channel center frequency, shall be at least 15 dB below

the peak SIN(x)/x power spectrum. The RF carrier suppression shall be measured while transmitting a

repetitive 01 data sequence with the scrambler disabled using DQPSK modulation. A 100 kHz

resolution bandwidth shall be used to perform this measurement.

Measurement with the R&S FSL

The RF carrier suppression as defined in the standard is a determination of peak ratios. The

unscrambled 01 data sequence provides a spectrum with distinct peaks enveloped by the transmit filter

spectrum. An IQ offset leads to an additional peak at the center frequency.

The following measurement sequence can be used in normal spectrum mode:

1. Use power trigger or external trigger

1. Use gated sweep with gate delay at payload start and gate length = payload length

(Delay–Comp ON and RBW = 50 MHz for gate settings)

2. Set RBW = 100 kHz

3. Set Sweep Time = 100 ms

4. Set Span = 20 MHz

5. Set Detector = RMS

6. Set Marker 1 to center frequency

7. Use Marker 2 as Delta Marker and set it to max. peak

Fig. 2-89 is a screenshot of this measurement. The delta marker shows directly the RF carrier

suppression in dB (white circled value).

R&S FSL WLAN TX Measurements (Option K91)

1300.2519.12 2.139 E-11

Fig. 2-89 RF carrier suppression measurement

Comparison to IQ offset measurement in K91/K91n list mode

The IQ offset measurement in K91 returns the actual carrier feed through normalized to the mean

power at the symbol timings. This measurement doesn't need a special test signal and is independent

of the transmit filter shape.

The RF carrier suppression measured according to the standard is inversely proportional to the IQ

offset measured in K91 list mode. The difference (in dB) between the two values depends on the

transmit filter shape and should be determined with one reference measurement.

The following table lists exemplary the difference for three transmit filter shapes

(

)

0.5 dB

±:

Transmit filter

IQ-Offset [dB] RF-Carrier-Suppression [d



rectangular 11 dB

Root raised cosine,

0.22



10 dB

Gaussian,

0.3



9dB

WLAN TX Measurements (Option K91) R&S FSL

1300.2519.12 2.140 E-11

IQ Impairments

IQ Offset

An IQ–Offset indicates a carrier offset with fixed amplitude. This results in a constant shift of the IQ

axes. The offset is normalized by the mean symbol power and displayed in dB.

Gain Imbalance

An ideal I/Q modulator amplifies the I and Q signal path by exactly the same degree. The imbalance

corresponds to the difference in amplification of the I and Q channel and therefore to the difference in

amplitude of the signal components. In the vector diagram, the length of the I vector changes relative to

the length of the Q vector.

The entry is displayed in dB and %, where 1 dB offset is roughly 12 % according to the following:

Imbalance [dB] = 20log ( | GainQ|/|GainI|)

Positive values mean that the Q vector is amplified more than the I vector by the corresponding

percentage:

Negative values mean that the I vector is amplified more than the Q vector by the corresponding

percentage:

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1300.2519.12 2.141 E-11

Quadrature Error

An ideal I/Q modulator sets the phase angle to exactly 90 degrees. With a quadrature error, the phase

angle between the I and Q vector deviates from the ideal 90 degrees, the amplitudes of both

components are of the same size. In the vector diagram, the quadrature error causes the coordinate

system to shift.

Apositive quadrature error means a phase angle greater than 90 degrees:

Anegative quadrature error means a phase angle less than 90 degrees:

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 2.142 E-11

WiMAX, WiBro Measurements (Options K92/K93)

This section describes measurement examples for the WiMAX IEEE 802.16 OFDM, OFDMA

Measurements option (R&S FSL–K93) and gives details to signal processing. For further information on

measurement examples refer also to the Quick Start Guide, chapter 5 "Basic Measurement Examples".

The WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K92/K93) includes the

functionality of the WiMAX 802.16 OFDM Measurements option (R&S FSL–K92). Accordingly both

options are described together in this section, differentiated by the corresponding standards:

WiMAX 802.16 OFDM Measurements (R&S FSL–K92/K93)

IEEE 802.16–2004/Cor 1–2005 OFDM physical layer mode

The corresponding remote control mode is OFDM.In chapter 2, "Instrument Functions", the

short forms IEEE 802.16–2004 OFDM is used to reference this standard.

WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K93)

IEEE 802.16–2004/Cor 1–2005, IEEE 802.16e–2005 OFDMA physical layer mode

The corresponding remote control mode is OFDMA.In chapter 2, "Instrument Functions", the

short form IEEE 802.16e–2005 OFDMA is used to reference this standard.

IEEE 802.16–2004/Cor 1–2005, IEEE 802.16e–2005 based WiBro

The corresponding remote control mode is WiBro.In chapter 2, "Instrument Functions", the

short form IEEE 802.16e–2005 WiBro is used to reference this standard.

The options are available from firmware version 1.40 (R&S FSL–K92) and 1.50 (R&S FSL–K93).

Basic Measurement Example

This section provides step–by–step instructions for working through an ordinary measurement. The

following steps are described:

1. Setting up the measurement

2. Performing the level detection

3. Performing the main measurement

Test setup

In this example, a DUT using IEEE 802.16–2004 is be used.

Connect the DUT to the R&S FSL using the RF input of the R&S FSL. The DUT generates a signal

modulated using 16QAM 2/3.

Setting up the measurement

1. Activate the WIMAX mode (for details refer to chapter "Instrument Functions", section "Measurement

Mode Selection – MODE Key").

2. Press the Settings General/Demod softkey once to select and open the General Settings dialog

box.

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 2.143 E-11

In the Frequency field, enter the desired frequency to measure.

If a frequency is entered, which maps to a specific channel, the Channel No field updates.

In the Frequency Band field, select the signal to be analyzed. The target band is either one of

the bands given as example in the IEEE 802.16–2004 standard3or an unspecified band.

In the Channel BW or Sampling Rate field depending on the characteristics of the signal to be

analyzed, select a value. The second parameter is derived from the first according to the

standard4.

In the G = Tg/Tb field, select a useful time ratio according to the characteristics of the signal to

be analyzed.

Under Level Settings,deactivate the Auto Lev option. In this example, the level detection

measurement is executed manually (for details see Performing the level detection).

3. Press the Settings General/Demod softkey twice to select and open the Demod Settings dialog

box.

3B.3.2 Wireless MAN-OFDM/OFDMA PHY symbol and performance parameters.

48.3.2.2 Derived Parameter definitions

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 2.144 E-11

In the Link Mode field, select the link mode of the bursts to be analyzed.

In the Demodulator field, select the used modulation scheme.

Performing the level detection

1. Connect the DUT to the RF input of the R&S FSL.

2. Start the level detection measurement by pressing the SWEEP hardkey and then the Auto Level

softkey.

During the level detection measurement the status message Running is displayed in the status bar

at the bottom of the screen.

After successful level detection, the status message Measurement Complete is displayed, the

signal level field for the selected input displays the detected signal level and the Magnitude Capture

Buffer (screen A) displays the zero span trace obtained during the measurement sequence.

Note: An automatic level detection can be performed in two ways:

Once by pressing the Auto Level softkey in the sweep menu.

At the start of each measurement sweep by activating the Auto Lev option in the General

settings dialog box under Level Settings.

Performing the main measurement

1. Select single sweep measurements by pressing the SWEEP hardkey and then the Run softkey to

select Single.

2. Start the measurement by pressing the RUN hardkey.

During the measurement, the status message Running is displayed.

Measurement results are updated once the measurement has completed. The results are displayed

in graphical form. The display can be toggled to a tabular list of measurement points by pressing

the Display Graph/List softkey (in the WiMAX/WiBro menu or trace menu).

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 2.145 E-11

Signal Processing of the IEEE 802.16–2004 OFDM

Measurement Application

Abbreviation Description

256=

FFT

NFFT length

a,symbol from the alphabet at symbol–index lof sub carrier k

EVM error vector magnitude of sub carrier k

EVM error vector magnitude of current packet

signal gain

ffrequency deviation between Tx and Rx

lsymbol index ]_,1[ Symbolsnofl

symbolsnof _number of symbols of payload

Hchannel transfer function of sub carrier k

kchannel index ]127,128[=k

mod

Kmodulation dependent normalization factor



relative clock error of reference oscillator

r,received symbol at symbol–index lof sub carrier k

Pilots = {–88, –63, –38, –13, 13, 38, 63, 88}

This description gives a rough view of the IEEE 802.16–2004 OFDM measurement application signal

processing. Details are disregarded in order to get a concept overview.

Adiagram of the interesting blocks is shown in Fig. 2-90.First the RF signal is down–converted to the

IF frequency =

f20.4 MHz. The resulting IF signal )(trIF is shown on the left–hand side of the figure.

After bandpass filtering, the signal is sampled by an Analog to Digital Converter (ADC) at a sampling

rate of =

f81.6 MHz. This digital sequence is resampled to the new sampling frequency of

f80 MHz which is a multiple of the Nyquist rate (20 MHz). The subsequent digital down–converter

shifts the IF signal to the complex base band. In the next step the base band signal is filtered by a FIR

filter. To get an idea, the rough transfer function is plotted in the figure. This filter fulfils two tasks: first it

suppresses the IF image frequency, secondly it attenuates the aliasing frequency bands caused by the

subsequent down–sampling. After filtering, the sequence is sampled down by the factor of 4. Thus the

sampling rate of the down–sampled sequence )(ir is the Nyquist rate of =

f20 MHz. Up to this point

the digital part is implemented in an ASIC.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 2.146 E-11

Fig. 2-90 Signal processing of the IEEE 802.16 OFDM measurement application

In the lower part of the figure the subsequent digital signal processing is shown. In the first block the

packet search is performed. This block detects the Short Preamble (SP) and recovers the timing. The

coarse timing is detected first. This search is implemented in the time domain. The algorithm is based

on cyclic repetition within the SP after 1282== FFT

NN samples. Note this cyclic repetition occurs also

in the Long Preamble (LP). Numerous treatises exist on this subject, e.g. [1]–[3]. Furthermore a coarse

estimate coarse

5of the Rx–Tx frequency offset fis derived from the metric in [6]. This can easily be

understood because the phase of )()( *Nirir +is determined by the mod 2frequency offset. As the

frequency deviation fcan exceed several bins (distance between neighbor sub–carriers) the SP is

further used to solve this n2[offset over several bins] ambiguities.

After the coarse timing calculation the time estimate is improved by the fine timing calculation.This is

achieved by first estimating the coarse frequency response )S(

ˆP

H,with ]100,100[=kdenoting the

channel index of the occupied sub–carriers. First the FFT of the SP is calculated. After the FFT

calculation the known symbol information of the SP sub–carriers is removed by dividing by the symbols.

The result is a coarse estimate k

ˆof the channel transfer function. In the next step the complex

channel impulse response is computed by an IFFT. Next the energy of the windowed impulse response

(the window size is equal to the guard period) is calculated for every trial time. Afterwards the trail time

of the maximum energy is detected. This trial time is used to adjust the timing.

Now the position of the SP is known and the starting point of the useful part of the first payload symbol

can be derived. In the next block this calculated time instant is used to position the payload window

Only the payload part is windowed. This is sufficient because the payload is the only subject of the

subsequent measurements.

In the next block the windowed sequence is compensated by the coarse frequency estimate coarse

.

This is necessary because otherwise inter channel interference (ICI) would occur in the frequency

domain.

The transition to the frequency domain is achieved by an FFT of length 256. The FFT is performed

symbol–wise for every of the symbolsnof _symbols of the payload. The calculated FFTs are described

by kl

r,with

5In this paper the hat generally describes an estimate. Example: x

is the estimate of x.

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 2.147 E-11

the symbol index ]_,1[ symbolsnofl=and

the channel index ]127,128[=k.

In case of an additive white Gaussian noise (AWGN) channel the FFT is described by [4], [5]

(

)

phasephasej

klklkl neHgaKr kll

,,mod,

)

timing(

)

commom(

+=+

(30)

with

the modulation–dependent normalization factor mod

the alphabet symbol kl

a,at symbol–index lof sub–carrier k

the gain l

gat the symbol lin relation to the reference gain 1

gat the Short Preamble (SP)

the channel frequency response k

Hat the Short Preamble (SP)

the common phase drift )common(

phase of all sub–carriers at symbol l(see below)

the phase )timing(

,kl

phase of sub–carrier kat symbol lcaused by the timing drift (see below)

the independent Gaussian distributed noise samples k

The common phase drift in equation (29) is given by

lrestsl dlTfNNphase

#

+=2

)common(

(31)

with

bgs NNN += being the number of Nyquist samples of the symbol period

256== b

NN being the number of Nyquist samples of the useful part of the symbol

rest

fbeing the (not yet compensated) frequency deviation

being the phase jitter at the symbol l

In general, the coarse frequency estimate coarse

(see Fig. 2-90)is not error–free. Therefore the

remaining frequency error rest

frepresents the not yet compensated frequency deviation in kl

r,.

Consequently the overall frequency deviation of the device under test (DUT) is calculated by

restcoarse fff +=ˆ.Remark: The only motivation for dividing the common phase drift in equation (11)

into two parts is to be able to calculate the overall frequency deviation of the DUT.

The reason for the phase jitter l

in equation (11) may be different. The nonlinear part of the phase

jitter may be caused by the phase noise of the DUT oscillator. Another reason for nonlinear phase jitter

may be the increase of the DUT amplifier temperature at the beginning of the burst. Please note that

besides the nonlinear part the phase jitter l

also contains a constant part. This constant part is

caused by the not yet compensated frequency deviation rest

f.To understand this, please keep in mind

that the measurement of the phase starts at the first symbol 1

lof the payload. In contrast the channel

frequency response k

Hin equation (29) represents the channel at the Short Preamble of the preamble.

Consequently the not yet compensated frequency deviation rest

fproduces a phase drift between the

Short Preamble and the first symbol of the payload. Therefore this phase drift appears as a constant

value ("DC value'') in l

Referring to the IEEE 802.16–2004 measurement standard Chapter 8.3.10.1.2 "Transmitter

constellation error and test method'' [6], the common phase drift )common(

phase must be estimated and

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 2.148 E-11

compensated from the pilots. Therefore the "symbol wise phase tracking'' (Tracking Phase) is activated

asthe default setting of the R&S FSL–K92/K93.

Furthermore the timing drift in equation (29) is given by

lkNNphase skl =



)timing(

,(32)

with



being the relative clock deviation of the reference oscillator. Normally a symbol–wise timing jitter

is negligible and thus not modeled in equation (32). There may be situations where the timing drift has

to be taken into account. This is illustrated by an example: In accordance to [6] the allowed clock

deviation of the DUT is up to =

max



8ppm. Furthermore the maximal length of a frame

2420_=symbolsnof symbols6is assumed. From equations (29) and (32), it results that the phase drift

of the highest sub–carrier 100=kin the last symbol symbolsnofl_=is to–do degrees. Even in the

noise–free case, this would lead to symbol errors. The example shows that it is actually necessary to

estimate and compensate the clock deviation, which is accomplished in the next block.

Referring to the IEEE 802.16–2004 measurement standard [6], the timing drift )timing(

,kl

phase is not part of

the requirements. Therefore the "time tracking'' (Tracking Time) is not activated as the default setting of

the R&S FSL–K92/K93.

The time tracking option should rather be seen as a powerful analyzing option.

In addition the tracking of the gain l

gin equation (29) is supported for each symbol in relation to the

reference gain 1

gat the time instant of the Short Preamble (SP). At this time the coarse channel

transfer function )(

ˆSP

His calculated. This makes sense since the sequence k

'is compensated by the

coarse channel transfer function )(

ˆSP

Hbefore estimating the symbols. Consequently a potential change

of the gain at the symbol l(caused, for example, by the increase of the DUT amplifier temperature)

may lead to symbol errors especially for a large symbol alphabet

of the MQAM transmission. In this

case the estimation and the subsequent compensation of the gain are useful.

Referring to the IEEE 802.16–2004 measurement standard [6], the compensation of the gain l

gis not

part of the requirements. Therefore the "gain tracking'' (Tracking Gain) is not activated as the default

setting of the R&S FSL–K92/K93.

The unknown deviations of gain, frequency and time are calculated by an optimum maximum likelihood

procedure, which works well even at low signal to noise ratios with the Cramer Rao Bound being

reached. After estimation of these parameters, the received signal is fully compensated for the decision

of the ideal reference signal kl

ˆand compensated according to the user settings to get the

measurement signal kl

'.Then the measurement signal is equalized by the inverse channel transfer

function. According to the chosen setting, either the preamble estimation of the channel transfer

function or a data aided estimation using the ideal reference signal is used. According to the IEEE

802.16–2004 measurement standard [6], the coarse channel estimation )(

ˆSP

H(from the short

preamble) has to be used for equalization. Therefore the default setting of the R&S FSL–K92/K93 is

equalization from the coarse channel estimate derived from the short preamble.

In the last block the measurement variables are calculated. The most important variable is the error

vector magnitude

,mod,

1'' klkl

Symbolsnof

kaKrEVM =%

=(33)

of the sub–carrier kof the current packet. Furthermore the packet error vector magnitude

6Assuming the maximal System Sampling Rate Fs = 32MHz.

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 2.149 E-11

100

)

100

200

EVMEVM %

&

=

(34)

is derived by averaging the squared k

EVM versus k.Finally the average error vector magnitude

)(

1counterEVMEVM

packetsnof

counter

packetsnof %=

(35)

is calculated by averaging the packet EVM of all packetsnof _detected packets. This parameter is

equivalent to the so–called "RMS average of all errors RMS

Error '' of the IEEE 802.16–2004

measurement commandment (see [6], Chapter 8.3.10.1.2).

Analysis Steps

Preamble related result Remark

Rough frequency estimation In case of subchannelization, a rough frequency estimation is obtained by

exploiting the cyclic prefix of the OFDM symbols.

Preamble power

Preamble EVM Uses payload channel estimation for equalization.

Frequency error vs. preamble

Phase error vs. preamble

Channel estimation Used for equalizing

Payload related result Remark

Fine frequency estimation Estimation on pilots used for phase correction if 'Phase Tracking' is

selected. Phase tracking needs at least one pilot.

In case of subchannelization, the value shown in the result summary table

is estimated on pilots and data.

Clock offset estimation Estimation on pilots used for timing correction if 'Timing Tracking' is

selected. Timing tracking needs at least two pilots.

In case of subchannelization, the value shown in the result summary table

is estimated on pilots and data.

IQ Offset Power at spectral line 0 normalized to the total transmitted power.

Gain Imbalance Estimation not available in case of subchannelization.

Quadrature Error Estimation not available in case of subchannelization.

Payload channel estimation Combined with the preamble channel estimation.

Burst related result Remark

EVM All carriers

EVM Data carriers

EVM Pilot carriers

According to standard normalized to the average power of all 200 used

carriers.

Burst Power

Crest Factor

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 2.150 E-11

Subchannelization

Subchannelization can be used in uplink bursts to allocate only a subset of the available OFDM sub

carriers. The measurement software can distinguish between downlink bursts, uplink bursts without

subchannelization and uplink bursts with a selectable subchannel index. Thus it is possible to analyze

the complete WirelessMAN traffic with one capture buffer shot.

Synchronization

The synchronization of uplink bursts using subchannelization is performed after the synchronization on

standard downlink and uplink preambles:

1. Synchronization of downlink and uplink bursts without subchannelization.

2. Pre–analysis of the bursts without subchannelization to determine their length.

3. Extraction of TX power areas without already detected bursts.

4. Synchronization of uplink bursts with the selected subchannel index.

In the following sections, the influence of subchannelization on results is discussed.

Channel Results

The standard requires an interpolation of order 0 for the channel estimation on unallocated sub carriers,

i.e. the estimated channel coefficient of the nearest allocated sub carrier shall be used for those sub

carriers not part of the allocated subchannels.

For the derived channel results like group delay or flatness difference, the unallocated carriers are not

taken into account.

Fig. 2-91 Spectrum Flatness

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 2.151 E-11

Frequency and Clock Offset

The measurement software allows selectable compensation of phase, timing and gain errors based on

pilot estimations. However, in case of subchannelization the number of pilots is decreased. Bursts with

odd subchannel indices do not provide pilots at all. The following table lists the restrictions on the

tracking ability for subchannelization:

Tracking Subchannel Index

16 (8 Pilots)

8, 24 (4 Pilots)

4, 12, 20, 28 (2 Pilots)

2, 6, 10, 14, 18, 22, 26, 30

(1 Pilot)

1, 3, 5, 7, 9, 11, 13, 15, 17, 19,

21, 23, 25, 27, 29, 31 (No

Pilot)

Phase Available Available Available, but uses rough

frequency offset estimation

from the synchronization step

only

Timing Available Not available Not available

Gain Available Available Not available

While the tracking functionality has to use pilot based estimates, the actual results for frequency and

clock offset in the result summary can be data aided. In case of subchannelization the final estimation

of frequency and clock offset is done using the already decided data sequence, which gives stable

results even without pilots.

EVM

The error vector magnitude of a single constellation point is defined by

used

(, ) (, )

EVM(l,k) 1

(, )

rlk alk

alk

=&



where ),( klr is the received constellation point and ),( kla is the transmitted constellation point at the

lth symbol and carrier number k.

In case of subchannelization, it is required by the standard to include the unallocated carriers unalloc

kby

assuming 0),( =

unalloc

kla in the denominator of the EVM calculation.

Thus the EVM All Carriers result for one burst in the result summary equals

used

1/2

used 0

/2 2

1/2

used

(, ) (, )

EVM_All_Carr 11 (, )

lkN

rlk alk

alk

==&



where

is the number of symbols in the burst.

This definition is according to the relative constellation error defined in the IEEE 802.16–2004 standard.

Using the equations above, the error power is normalized by the average transmitted power in all 200

carriers. Please notify, that by this definition the same absolute error power leads to different EVM

results depending on the number of allocated carriers in case of subchannelization.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 2.152 E-11

IQ Impairments

IQ imbalance in an OFDM transmitter or receiver leads to an interference of the symbols kl

a,with the

symbols kl

a,.In case of subchannelization, the used sub carriers are always situated in such a way, that

kl

a,if 0

a.There is no impact of IQ imbalance on the actually allocated carriers of a

subchannelization transmission. The effect can only be seen on the unallocated carriers and yields a

pattern around the origin of the constellation diagram.

Fig. 2-92 Constellation vs Symbol

The unsymmetrical allocation of the sub carriers prevents a measurement of gain imbalance and

quadrature error in case of subchannelization. The influence of the occupied carriers kl

a,on the

unoccupied carriers kl

a,could be measured, but there is no possibility to distinguish them from an

unknown channel coefficient.

RSSI

See [6] section "8.3.9.2 RSSI mean and standard deviation''. The Received Signal Strength Indication

[RSSI] is basically the preamble power. The result summary provides the RSSI statistics according to

the standard. A possible method to compute RSSI[k] at the antenna connector is given in [6] equation

(87). RSSI[k] is the RSSI measurement based on the k–th signal/preamble.

The RSSI statistics of the result summary is calculated as follows:

1. RSSI row:

Statistic {min, mean, max} of the R[k]=RSSI[k].

The mean value is dBmRSSI

ˆ[k] according to [6] formula (89).

2. RSSI Standard Deviation row:

dBRSSI

ˆaccording to [6] formula (91).

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 2.153 E-11

CINR

See [6] section "8.3.9.3 CINR mean and standard deviation''. The result summary provides the Carrier

Interference Noise Ratio [CINR] statistics according to the standard. One possible method to estimate

the CINR of a single message is to compute the ratio of the sum of signal power and the sum of

residual error for each data sample, using equation [6] (92).



],[],[

],[

][ N

nksnkr

nks

kCINR

with

r[k,n] received/measured sample n within message k

s[k,n] corresponding detected/reference sample (with channel state weighting)

corresponding to received symbol n

The CINR statistics of the result summary is calculated as follows:

1. CINR row:

Statistic {min, mean, max} of the CINR[k].

The mean value is dBCINR

ˆ[k] according to [6] formula (94).

2. CINR Standard Deviation row

dBCINR

ˆaccording to [6] formula (96).

Literature

[1] Speth, Classen, Meyr: ''Frame synchronisation of OFDM systems in frequency selective fading channels", VTC '97,

pp. 1807–1811

[2] Schmidl, Cox: ''Robust Frequency and Timing Synchronization of OFDM", IEEE Trans. on Comm., Dez. 1997, pp. 1613–

621

[3] Minn, Zeng, Bhargava: ''On Timing Offset Estimation for OFDM", IEEE Communication Letters, July 2000, pp. 242–244

[4] Speth, Fechtel, Fock, Meyr: ''Optimum Receiver Design for Wireless Broad–Band Systems Using OFDM – Part I", IEEE

Trans. On Comm. VOL. 47, NO 11, Nov. 1999

[5] Speth, Fechtel, Fock, Meyr: ''Optimum Receiver Design for Wireless Broad–Band Systems Using OFDM – Part II", IEEE

Trans. On Comm. VOL. 49, NO 4, April. 2001

[6] IEEE 802.16–2004, Part 16: Air Interface for Fixed Broadband Wireless Access Systems; 1 October 2004; Medium

Access Control (MAC) and Physical Layer (PHY) specifications

Signal Processing of the IEEE802.16–2005 OFDMA/WiBro

Measurement Application

Symbol Description

klkl aa ,, ˆ

,data symbol (actual, decided)

res

fresidual carrier frequency offset

coarse

,ff  carrier frequency offset between transmitter and receiver (actual, coarse estimate)

relative sampling frequency offset

ggain

klkl HH ,, ˆ

,channel transfer function (actual, estimate)

itime index

finecoarse ˆ

ˆii timing estimate (coarse, fine)

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 2.154 E-11

Symbol Description

kkkk chdp ,,, subcarrier index (general, pilot, data, subchannel

)

lOFDM symbol index

FFT

Nlength of FFT

Nnumber of samples in cyclic prefix (guard interval)

Nnumber of Nyquist samples

Nnumber of subcarriers

subchannel index, subframe index

n,noise sample

1common phase error

QQ ˆ

, I/Q imbalance (actual, estimate)

)(ir received sample in the time domain

klklklkl rrrr ,,,, ,,,

received sample (uncompensated, fully compensated, partially compensated,

equalized) in the frequency domain

useful symbol time

Tguard time

Tsymbol time

Abbreviation Description

AWGN additive white Gaussian noise

BER bit error rate

CFO carrier frequency offset

CINR carrier to interference and noise ratio

CIR channel impulse response

CP cyclic prefix (guard interval)

CPE common phase error

CTF channel transfer function

DL downlink

EVM error vector magnitude

FFT fast Fourier transformation

IF intermediate frequency

ISI intersymbol interference

OFDM orthogonal frequency division multiplexing

OFDMA orthogonal frequency division multiple access

PAPR peak to average power ratio

RSSI received signal strength indicator

SFO sampling frequency offset

UL uplink

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 2.155 E-11

Introduction

The following description provides a brief overview of the digital signal processing used in the IEEE

802.16 OFDMA measurement application.

From the received IF signal as the point of origin to the actual analysis results like EVM or CINR, the

digital signal processing can be divided into four major groups:

napplicatio tmeasuremenOFDMA

Analysis

onequalizati /estimation Channel

ationSynchroniz

capturing Data

•

The description of the IEEE802.16–2005 OFDMA/WiBro measurement signal processing is structured

accordingly.

Signal Processing Block Diagram

pow er

detection

window

subfram e

detection

window fre q u e n c y

com pensation

coarse

c h a n n e l e s t.

(pream ble)

fin e tim in g

FFT

coarse

c h a n n e l e s t.

(p ilo ts )

equalizer

a n d s y m b o l

decision

M U X

MUX

fin e

c h a n n e l e s t.

(s y m b o ls )

I/Q -im b a la n c e

estim ation

equalizer

fu ll

com pensation

u s e r d e fin e d

com pensation

tra c k in g

estim ation

SFO

re s . C F O analysis

subcarrier

selection

Dfcoarse



I/Q -d a ta

(c a p tu re b u ffe r)

coarse



fin e



pream ble



Hfin e



Hpilots



pream ble



l,k



re fe re n c e p a th

me a s u re m e n t p a th

c a rrie d o u t tw ic e

fo r U L s u b fra m e s

rl,k

l,k

rl,k

'''

CPE

gain

Fig. 2-93 Signal processing of the IEEE 802.16 OFDMA measurement application

The block diagram in Fig. 2-93 shows the OFDMA measurement application from the capture buffer

containing the I/Q data to the actual analysis block. Outcome of the fully compensated reference path

(green) are the estimates kl

ˆof the transmitted data symbols kl

a,.Depending on the user defined

compensation, the received samples kl

of the measurement path (orange) still contain the transmitted

signal impairments of interest. The analysis block reveals these impairments by comparing the

reference and the measurement path. Prior to the analysis, diverse synchronization and channel

estimation tasks have to be accomplished.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 2.156 E-11

Synchronization

The first of the synchronization tasks is to detect areas of sufficient power within the captured I/Q data

stream. The subframe detection block determines the beginning and end of each subframe and

coarsely estimates both timing and carrier frequency offset. The fine timing block prior to the FFT allows

atiming improvement using a level–based search for the beginning and end of the coarsely estimated

channel impulse response. In the DL the coarse estimate of the CIR can be directly obtained from the

preamble. Other than that the UL consists only of payload information with scattered pilots in the

subcarrier–symbol plane, thus several OFDM symbols have to be observed to get a reliable estimate of

the CIR. Since the OFDM symbols need to be phase synchronized prior to the channel estimation, the

blue blocks in Fig. 2-93 have to be carried out twice. In the first iteration the timing estimate coarse

iis

used to position the window of the FFT. Having found the pilot–based estimate of the CIR, the fine

timing estimate fine

iis used in the second iteration.

After the time to frequency transformation by an FFT of length FFT

N,the tracking estimation block is

used to estimate the following:

•relative sampling frequency offset

•residual carrier frequency offset res

f

•common phase error l

•gain l

Corresponding to [3] and [4], the uncompensated samples kl

r,can be expressed as

{

lTfNNlkNN

klkllkl nHagr l

CFO res.

SFO

CPE

,,,

resFFTsFFTseee +=1 44 344 2144 344 21

0

(36)

with

•data symbol kl

a,on subcarrier kat OFDM symbol l

•channel transfer function kl

•number of Nyquist samples s

Nwithin the symbol time s

•useful symbol time gs TTT =

•independent and Gaussian distributed noise sample kl

Within one OFDM symbol both the CPE and the residual CFO respectively cause the same phase

rotation for each subcarrier, while the rotation due to the SFO linearly depends on the subcarrier index.

Alinear phase increase in symbol direction can be observed for the residual CFO as well as the SFO.

The results of the tracking estimation block are used to compensate the samples kl

r,.While a full

compensation is performed in the reference path, the signal impairments that are of interest to the user

are left uncompensated in the measurement path.

Channel Estimation / Equalization

According to Fig. 2-93,there are two coarse and one fine channel estimation blocks. Which of the two

coarse estimation blocks is used depends on the link direction. For DL subframes the coarse channel

estimation is based on the preamble and directly follows the coarse frequency compensation block. The

pilot–based estimation for UL subframes is tapped behind the full compensation block of the reference

path. Both of the coarse estimation blocks use available training symbols to determine initial estimates

ˆof the channel transfer function at fixed positions in the subcarrier–symbol plane. Based on these

nodes, the missing CTF values are obtained by interpolation in both time and frequency direction. The

coarse estimation results are used for the above mentioned fine timing and to equalize the samples kl

of the reference path prior to symbol decision. Based on the decided data symbols, a fine channel

estimation is performed and then used to equalize the partially compensated samples of the

measurement path.

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 2.157 E-11

Analysis

The analysis block of the OFDMA measurement application allows to calculate a variety of

measurement variables.

EVM

The most important variable is the error vector magnitude (EVM).

klkl

EVM

,ˆ



222

=(37)

on subcarrier kat OFDM symbol l.The subsequent average values can be derived from (37).

1. EVM of subchannel

at OFDM symbol l:

klnl EVM

EVM

subchannel,

1(38)

2. EVM of all pilot subcarriers:

EVM

pilots

1(39)

3. EVM of all data subcarriers:

EVM

data

1(40)

4. EVM of all used subcarriers:

%%%7

)+=

kl EVMEVM

EVM

all

1(41)

The number of subcarriers respectively taken into account is denoted by sc

CINR

The carrier to interference and noise ratio is determined for each subframe

.The computation is

based on the partially compensated samples kl

,the decided symbols kl

ˆ,and the channel estimates

ˆ(DL: preamble and fine; UL: fine).





kklkl

kkl

Har

nCINR 2

)( (42)

Further CINR statistics are defined in the standards [5], [6].

dB ))(

)(

(log5)(

0)()1(

)1(

0)0(

)(

dB )(

log10)(

0)()1(

)1(

0)0(

)(

CINR

(dB)

CINR

avg

CINRavg

CINR

(dB)

CINR

avgCINRavg

CINR

nnxn

nnCINRnx

nCINR

nnCINRn

nCINR

µ/



µµ

µ

=

;

>+

=

;

>+

(43)

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 2.158 E-11

RSSI

The received signal strength indicator is determined for each subframe

.The computation is based on

the time domain samples )(ir extracted by the subframe detection block.

|)(|~)( irnRSSI (44)

Further RSSI statistics are defined in the standard [5], [6].

dB ))(

)(

(log5)(

0)()1(

)1(

0)0(

)(

dB )(

log10)(

0)()1(

)1(

0)0(

)(

RSSI

(dB)

RSSI

avg

RSSIavg

RSSI

(dB)

RSSI

avgRSSIavg

RSSI

nnxn

nnRSSInx

nRSSI

nnRSSIn

nRSSI

µ/



µµ

µ

=

;

>+

=

;

>+

(45)

I/Q Imbalance

The I/Q imbalance estimation block allows to evaluate the

|1| Qbalance gain modulator



(46)

and the

}1{arg Qmismatch quadrature += (47)

respectively based on the block's estimate Q

.

Other Measurement Variables

Without going into detail, the OFDMA measurement application additionally provides the following

results:

•Burst power

•Constellation diagram

•Group delay

•I/Q offset

•PAPR

•Pilot BER

•Spectral flatness

Literature

[1] Speth, M., Classen, F., and Meyr, H.: Frame Synchronization of OFDM Systems in Frequency Selective Fading

Channels. IEEE VTC'97, May 1997, pp. 1807–1811.

[2] Schmidl, T. M. and Cox, D. C.: Robust Frequency and Timing Synchronization of OFDM. IEEE Trans. on Commun. Vol.

45 (1997) No. 12, pp. 1613–1621.

[3] Speth, M., Fechtel, S., Fock, G., and Meyr, H.: Optimum Receiver Design for Wireless Broad–Band Systems Using

OFDM – Part I. IEEE Trans. on Commun. Vol. 47 (1999) No. 11, pp. 1668–1677.

[4] Speth, M., Fechtel, S., Fock, G., and Meyr, H.: Optimum Receiver Design for OFDM–Based Broadband Transmission –

Part II: A Case Study. IEEE Trans. on Commun. Vol. 49 (2001) No. 4, pp. 571–578.

[5] IEEE 802.16–2004™: Air Interface for Fixed Broadband Wireless Access Systems (2004).

[6] IEEE Std 802.16e™–2005 and IEEE Std 802.16™–2004/Cor1–2005: Air Interface for Fixed and Mobile Broadband

Wireless Access Systems (2006)

R&S FSL Manual Operation

1300.2519.12 3.1 E-11

3Manual Operation

For details refer to the Quick Start Guide chapter 4, "Basic Operations".

R&S FSL Instrument Functions

1300.2519.12 I-4-1 E-11

Contents of Chapter 4

Instrument Functions – Analyzer....................................................................................................4.1

Measurement Parameters................................................................................................................4.2

Initializing the Configuration – PRESET Key..............................................................................4.3

Selecting the Frequency and Span – FREQ Key .......................................................................4.5

Setting the Frequency Span – SPAN Key................................................................................4.11

Setting the Level Display and Configuring the RF Input – AMPT Key .....................................4.13

Setting the Bandwidths and Sweep Time – BW Key................................................................4.18

Configuring the Sweep Mode – SWEEP Key...........................................................................4.24

Triggering the Sweep – TRIG Key............................................................................................4.28

Setting Traces – TRACE Key ...................................................................................................4.39

Measurement Functions ................................................................................................................4.52

Using Markers and Delta Markers – MKR Key.........................................................................4.53

Changing Settings via Markers – MKR–> Key .........................................................................4.66

Power Measurements – MEAS Key .........................................................................................4.75

Using Limit Lines and Display Lines – LINES Key .................................................................4.118

Measurement Modes ....................................................................................................................4.128

Measurement Mode Selection – MODE Key..........................................................................4.129

Measurement Mode Menus – MENU Key..............................................................................4.131

Models and Options .....................................................................................................................4.133

Tracking Generator (Models 13, 16 and 28)...........................................................................4.134

Analog Demodulation (Option K7)..........................................................................................4.140

Bluetooth Measurements (Option K8) ....................................................................................4.158

Power Meter (Option K9)........................................................................................................4.186

Spectrogram Measurement (Option K14)...............................................................................4.191

Cable TV Measurements (Option K20) ..................................................................................4.203

Noise Figure Measurements Option (K30) .............................................................................4.247

3GPP Base Station Measurements (Option K72) ..................................................................4.271

CDMA2000 BTS Analyzer (Option K82).................................................................................4.295

1xEV-DO BTS Analyzer (Option K84) ....................................................................................4.356

WLAN TX Measurements (Option K91 / K91n)......................................................................4.409

WiMAX, WiBro Measurements (Options K92/K93) ................................................................4.441

Instrument Functions - Basic Settings.......................................................................................4.490

General Settings, Printout and Instrument Settings.................................................................4.491

Instrument Setup and Interface Configuration - SETUP Key .................................................4.492

Saving and Recalling Settings Files - FILE Key .....................................................................4.510

Manual Operation - Local Menu .............................................................................................4.519

Measurement Documentation - PRINT Key ...........................................................................4.520

R&S FSL Instrument Functions – Analyzer

1300.2519.12 4.1 E-11

Instrument Functions – Analyzer

Inthis section, all analyzer functions of the R&S FSL and their application are explained in detail. The

basic settings functions are described in section "Instrument Functions – Basic Settings".

For every key a table is provided in which all submenus and corresponding commands are listed. The

description of the submenus and commands follows the order of the table. The commands for the

optional remote control (if any) are indicated for each softkey. The description is divided into the

following topics:

•"Measurement Parameters" on page 4.2

This section describes how to reset the instrument, to set up specific measurements and to set the

measurement parameters. Examples of basic operations are provided in the Quick Start Guide,

chapter 5 "Basic Measurement Examples". Advanced examples are described in chapter

"Advanced Measurement Examples".

•"Measurement Functions" on page 4.52

This section informs about how to select and configure the measurement functions. Examples of

basic operations are provided in the Quick Start Guide, chapter 5 "Basic Measurement Examples".

Advanced examples are described in chapter "Advanced Measurement Examples".

•"Measurement Modes" on page 4.128

This section describes the provided measurement modes, the change of measurement modes and

the access to the menus of all active measurement modes.

•"Models and Options" on page 4.133

This section informs about optional functions and their application that are included in the basic unit

configuration.

More basic information on operation is given in the Quick Start Guide. The front and the rear view of the

instrument together with a table of all available keys and a short description are provided in chapter

"Front and Rear Panel". Chapter "Preparing for Use" informs how to start working with the instrument

for the first time. A brief introduction on handling the instrument is given in chapter "Basic Operations".

This includes also the description of the keys for basic operations like switching the instrument on and

off or starting a measurement.

Measurement Parameters R&S FSL

1300.2519.12 4.2 E-11

Measurement Parameters

In this section all menus necessary for setting measurement parameters are described. This includes

the following topics and keys. For details on changing the mode refer to "Measurement Mode Selection

–MODE Key" on page 4.129.

•"Initializing the Configuration – PRESET Key" on page 4.3

•"Selecting the Frequency and Span – FREQ Key" on page 4.5

•"Setting the Frequency Span – SPAN Key" on page 4.11

•"Setting the Level Display and Configuring the RF Input – AMPT Key" on page 4.13

•"Setting the Bandwidths and Sweep Time – BW Key" on page 4.18

•"Configuring the Sweep Mode – SWEEP Key" on page 4.24

•"Triggering the Sweep – TRIG Key" on page 4.28

•"Setting Traces – TRACE Key" on page 4.39

Table 4-1: Sweep range variables

Abbreviation Definition R&S FSL3

value

R&S FSL6

value

R&S FSL18

value

fmax max. frequency 3 GHz 6 GHz 18 GHz*

fmin min. frequency available 0 Hz 0 Hz 0 Hz

spanmin smallest selectable span > 0 Hz 10 Hz 10 Hz 10 Hz

*In remote control, the query of the maximum frequency returns 20 GHz. For further details refer to

chapter 6.

R&S FSL Initializing the Configuration – PRESET Key

1300.2519.12 4.3 E-11

Initializing the Configuration – PRESET Key

The PRESET key resets the instrument to the default setting and therefore provides a defined initial

state as a known starting point for measurements

Note: If the LOCAL LOCKOUT function is active in the remote control mode, the PRESET key is

disabled.

Further information

–"Initial configuration" on page 4.4

Task

–To preset the instrument

To preset the instrument

1. Define the data set for the preset:

–To retrieve the originally provided settings file (see Initial configuration), in the file menu,

deactivate the Startup Recall softkey.

–To retrieve a customized settings file, in the file menu, activate the Startup Recall softkey,

press the Startup Recall Setup softkey, and select the corresponding file.

For details refer to section "Saving and Recalling Settings Files – FILE Key".

2. Press the PRESET key to trigger a preset.

Remote: *RST or SYSTem:PRESet (for details refer to chapter "Remote Control – Commands",

section "Common Commands" or section "SYSTem Subsystem").

Note: In order to save the current settings after reboot of the instrument, create a shutdown file by

switching the analyzer in the standby mode (press the On/Off key on the FRONT panel and

wait until the yellow LED is ON). With the battery pack option, use a USB keyboard and

terminate the analyzer firmware with ALT+F4 to create the shutdown file.

Initializing the Configuration – PRESET Key R&S FSL

1300.2519.12 4.4 E-11

Initial configuration

The initial configuration is selected in a way that the RF input is always protected against overload,

provided that the applied signal levels are in the allowed range for the instrument.

The parameter set of the initial configuration can be customized by using the Startup Recall softkey in

the file menu. For further information refer to section "Instrument Functions – Basic Settings", "Saving

and Recalling Settings Files – FILE Key".

Table 4-2: Initial configuration

Parameter Setting

mode Spectrum Analyzer

center frequency fmax / 2

center frequency step size 0.1 * center frequency

span R&S FSL3: 3 GHz

R&S FSL6: 6 GHz

R&S FSL18: 18 GHz

RF attenuation auto

(R&S FSL3/6: 0 dB;

R&S FSL18: 10 dB)

reference level R&S FSL3/6: –20 dBm;

R&S FSL18: –10 dBm

level range 100 dB log

level unit dBm

sweep time auto

resolution bandwidth auto (3 MHz)

video bandwidth auto (10 MHz)

FFT filters off

span / RBW 50

RBW / VBW 0.33

sweep cont

trigger free run

trace 1 clr write

trace 2/3/4/5/6 blank

detector auto peak

frequency offset 0 Hz

reference level offset 0 dB

reference level position 100 %

grid abs

cal correction on

noise source off

input RF

tracking generator (models 13, 16, 28) off

R&S FSL Selecting the Frequency and Span – FREQ Key

1300.2519.12 4.5 E-11

Selecting the Frequency and Span – FREQ Key

The FREQ key is used to specify the frequency axis, and to set the frequency offset and the signal track

function. The frequency axis can be specified either by the start and stop frequency or by the center

frequency and the span.

To open the frequency menu

Press the FREQ key.

The frequency menu is displayed. The Frequency Center edit dialog box is displayed.

Menu and softkey description

–"Softkeys of the frequency menu" on page 4.7

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Tasks

–To specify the frequency axis by the start and stop frequency

–To specify the frequency axis by the center frequency and the span

–To specify the step size for the arrow keys and the rotary knob

–To modify the frequency axis by an offset

–To track signals (only possible if span >0)

Selecting the Frequency and Span – FREQ Key R&S FSL

1300.2519.12 4.6 E-11

To specify the frequency axis by the start and stop frequency

1. Press the Start softkey and enter a start frequency.

2. Press the Stop softkey and enter a stop frequency.

To specify the frequency axis by the center frequency and the span

3. Press the FREQ key and enter a center frequency in the Frequency Center edit dialog box.

4. Press the SPAN key and enter the bandwidth you want to analyze.

Note: Entering a value of 0 Hz will cause a change to the zero span analysis mode.

To specify the step size for the arrow keys and the rotary knob

1. Press the CF Stepsize softkey.

The softkeys are displayed according to the selected frequency span (zero span or span > 0).

2. To define the step size of the center frequency:

–Only if span > 0: Press 0.1*Span,0.5*Span or x*Span to define the step size for the center

frequency as percentage of the span.

–Only if span = 0: Press 0.1*RBW,0.5*RBW or x*RBW to define the step size for the center

frequency as percentage of the resolution bandwidth.

–Press the =Center softkey to set the step size to the value of the center frequency and to

remove the dependency of the step size to span or resolution bandwidth.

–Press the =Marker softkey to set the step size to the value of the marker and to remove the

dependency of the step size to span or resolution bandwidth.

–Press the Manual softkey and enter a fixed step size for the center frequency.

Note: The step size assigned to arrow keys corresponds to the selected value; the step size of the

rotary knob is 1/10 of it.

To modify the frequency axis by an offset

Press the Frequency Offset softkey and enter the offset to shift the displayed frequency span.

To track signals (only possible if span >0)

1. Press the Signal Track softkey.

The softkeys of this submenu are displayed to start and stop signal tracking with specified

parameters.

2. Press the Track On/Off softkey to switch signal tracking on or off.

3. Press the Track BW softkey and enter a bandwidth for signal tracking.

4. Press the Track Threshold softkey and enter the threshold for signal tracking.

5. Press the Select Trace softkey and select the trace for signal tracking.

R&S FSL Selecting the Frequency and Span – FREQ Key

1300.2519.12 4.7 E-11

Softkeys of the frequency menu

The following table shows all softkeys available in the frequency menu. It is possible that your

instrument configuration does not provide all softkeys. If a softkey is only available with a special option,

model or (measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Command

Center

Start

Stop

CF Stepsize 0.1*Span/0.1*RBW

0.5*Span/0.5*RBW

x*Span/x*RBW

=Center

=Marker

Manual

Frequency Offset

Signal Track Track On/Off

Track BW

Track Threshold

Select Trace

Center

Opens an edit dialog box to enter the center frequency. The allowed range of values for the

center frequency depends on the frequency span.

span > 0: spanmin / 2



fcenter



fmax – spanmin / 2

span = 0: 0 Hz



fcenter



fmax

fmax and spanmin are specified in the data sheet. To help analyze signals located at the end of the

frequency range, for R&S FSL models with an upper frequency limit of 6 GHz or less, the fmax

value is extended by 0.05 GHz for direct entry via the key pad. The preset and full span values

remain unchanged.

Remote: FREQ:CENT 100MHz

Selecting the Frequency and Span – FREQ Key R&S FSL

1300.2519.12 4.8 E-11

Start

Opens an edit dialog box to define the start frequency. The following range of values is allowed:

fmin



fstart



fmax – spanmin

fmin, fmax and spanmin are specified in the data sheet. To help analyze signals located at the end of

the frequency range, for R&S FSL models with an upper frequency limit of 6 GHz or less, the

fmax value is extended by 0.05 GHz for direct entry via the key pad. The preset and full span

values remain unchanged.

Remote: FREQ:STAR 20MHz

Stop

Opens an edit dialog box to define the stop frequency. The following range of values for the stop

frequency is allowed:

fmin + spanmin



fstop



fmax

fmin, fmax and spanmin are specified in the data sheet. To help analyze signals located at the end of

the frequency range, for R&S FSL models with an upper frequency limit of 6 GHz or less, the

fmax value is extended by 0.05 GHz for direct entry via the key pad. For the R&S FSL18 model,

the fmax value is extended to 20 GHz. The preset and full span values remain unchanged.

Remote: FREQ:STOP 2000MHz

CF Stepsize

Opens a submenu to set the step size of the center frequency. In addition to the =Center,

=Marker and Manual softkeys, the other softkeys are displayed depending on the selected

frequency span.

The step size can be coupled to the span (span > 0) or the resolution bandwidth (span = 0) or it

can be manually set to a fixed value.

0.1*Span (span > 0)

Sets the step size for the center frequency to 10% of the span.

Remote: FREQ:CENT:STEP:LINK SPAN

Remote: FREQ:CENT:STEP:LINK:FACT 10PCT

0.1*RBW (zero span)

Sets the step size for the center frequency to 10% of the resolution bandwidth. This is the

default setting.

Remote: FREQ:CENT:STEP:LINK RBW

Remote: FREQ:CENT:STEP:LINK:FACT 10PCT

R&S FSL Selecting the Frequency and Span – FREQ Key

1300.2519.12 4.9 E-11

0.5*Span (span > 0)

Sets the step size for the center frequency to 50% of the span.

Remote: FREQ:CENT:STEP:LINK SPAN

Remote: FREQ:CENT:STEP:LINK:FACT 50PCT

0.5*RBW (zero span)

Sets the step size for the center frequency to 50% of the resolution bandwidth.

Remote: FREQ:CENT:STEP:LINK RBW

Remote: FREQ:CENT:STEP:LINK:FACT 50PCT

x*Span (span > 0)

Opens an edit dialog box to set the step size for the center frequency as % of the span.

Remote: FREQ:CENT:STEP:LINK SPAN

Remote: FREQ:CENT:STEP:LINK:FACT 20PCT

x*RBW (zero span)

Opens an edit dialog box to set the step size for the center frequency as % of the resolution

bandwidth. Values between 1 and 100% in steps of 1% are allowed. The default setting is 10%.

Remote: FREQ:CENT:STEP:LINK RBW

Remote: FREQ:CENT:STEP:LINK:FACT 20PCT

=Center

Sets the step size to the value of the center frequency and removes the coupling of the step size

to span or resolution bandwidth. This function is especially useful during measurements of the

signal harmonic content because by entering the center frequency each stroke of the arrow key

selects the center frequency of another harmonic.

=Marker

Sets the step size to the value of the current marker and removes the coupling of the step size

to span or resolution bandwidth. This function is especially useful during measurements of the

signal harmonic content at the marker position because by entering the center frequency each

stroke of the arrow key selects the center frequency of another harmonic.

Manual

Opens an edit dialog box to enter a fixed step size for the center frequency.

Remote: FREQ:CENT:STEP 120MHz

Selecting the Frequency and Span – FREQ Key R&S FSL

1300.2519.12 4.10 E-11

Frequency Offset

Opens an edit dialog box to enter a frequency offset that shifts the displayed frequency range by

the specified offset. The allowed values range from –100 GHz to 100 GHz. The default setting is

0Hz.

Remote: FREQ:OFFS 10 MHz

Signal Track (span > 0)

Opens a submenu to modify the parameters for signal tracking: search bandwidth, threshold

value and trace.

The search bandwidth and the threshold value are shown in the diagram by two vertical lines

and one horizontal line, which are labeled as TRK.After each sweep the center frequency is set

to the maximum signal found within the searched bandwidth. If no maximum signal above the

set threshold value is found in the searched bandwidth, the track mechanism stops.

Remote: CALC:MARK:FUNC:STR OFF

Track On/Off (span > 0)

Switches the signal tracking on or off.

Remote: CALC:MARK:FUNC:STR OFF

Track BW (span > 0)

Opens an edit dialog box to set the search bandwidth for signal tracking. The frequency range is

calculated as a function of the center frequency.

Remote: CALC:MARK:FUNC:STR:BAND 1MHZ

Track Threshold (span > 0)

Opens an edit dialog box to set the threshold value for signal tracking.

Remote: CALC:MARK:FUNC:STR:THR –70DBM

Select Trace (span > 0)

Opens an edit dialog box to select the trace on which the signal is tracked.

Remote: CALC:MARK:FUNC:STR:TRAC 1

R&S FSL Setting the Frequency Span – SPAN Key

1300.2519.12 4.11 E-11

Setting the Frequency Span – SPAN Key

The SPAN key is used to set the frequency span to be analyzed.

To open the span menu

Press the SPAN key.

The span menu is displayed. For span > 0 an edit dialog box to enter the frequency is displayed.

For zero span, an edit dialog box to enter the sweep time is displayed.

Menu and softkey description

–"Softkeys of the span menu" on page 4.11

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Task

–To specify the span (alternatives)

To specify the span (alternatives)

1. To set the span, use the Span Manual,Full Span,Zero Span and Last Span softkeys.

2. To define a frequency range, use the Start and Stop softkeys.

3. For zero span, press the Sweeptime Manual softkey and enter a sweep time.

Softkeys of the span menu

The following table shows all softkeys available in the span menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

Command

Span Manual

Sweeptime Manual

Start

Stop

Full Span

Zero Span

Last Span

Setting the Frequency Span – SPAN Key R&S FSL

1300.2519.12 4.12 E-11

Span Manual

Opens an edit dialog box to enter the frequency span. The center frequency is kept constant.

The following range is allowed:

span = 0: 0 Hz

span >0: spanmin



fspan



fmax

fmax and spanmin are specified in the data sheet. To help analyze signals located at the end of the

frequency range, for R&S FSL models with an upper frequency limit of 6 GHz or less, the fmax

value is extended by 0.05 GHz for direct entry via the key pad. The preset and full span values

remain unchanged.

Remote: FREQ:SPAN 2GHz

Start

Opens an edit dialog box to enter the start frequency. For details see Start softkey in the

frequency menu.

Remote: FREQ:STAR 20MHz

Stop

Opens an edit dialog box to enter the stop frequency. For details see Stop softkey in the

frequency menu.

Remote: FREQ:STOP 2000MHz

Full Span

Sets the span to the full frequency range of the R&S FSL specified in the data sheet. This

setting is useful for overview measurements.

Remote: FREQ:SPAN:FULL

Zero Span

Sets the span to 0 Hz (zero span). The x–axis becomes the time axis with the grid lines

corresponding to 1/10 of the current sweep time (SWT).

Remote: FREQ:SPAN 0Hz

Last Span

Sets the span to the previous value. With this function e.g. a fast change between overview

measurement and detailed measurement is possible.

R&S FSL Setting the Level Display and Configuring the RF Input – AMPT Key

1300.2519.12 4.13 E-11

Setting the Level Display and Configuring the RF Input –

AMPT Key

The AMPT key is used to set the reference level, the level range and unit, the scaling and the RF

attenuation.

To open the amplitude menu

Press the AMPT key.

The amplitude menu is displayed. The Reference Level dialog box is displayed.

Menu and softkey description

–"Softkeys of the amplitude menu" on page 4.14

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Task

–To specify the amplitude

Setting the Level Display and Configuring the RF Input – AMPT Key R&S FSL

1300.2519.12 4.14 E-11

To specify the amplitude

1. Set the reference level, offset and position, using the Ref Level,Ref Level Offset and Ref Level

Position softkeys.

2. Select the level range and the unit for the level axis, using the Range Log and Unit softkeys.

3. Set the scaling, using the Range Linear and/or Grid Abs / Rel softkeys.

4. Set the attenuation, using the RF Atten Manual or RF Atten Auto softkeys.

Softkeys of the amplitude menu

The following table shows all softkeys available in the amplitude menu. It is possible that your

instrument configuration does not provide all softkeys. If a softkey is only available with a special option,

model or (measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Command

Ref Level

Range Log

Range Linear Range Linear %

Range Lin. Unit

Preamp On/Off

RF Atten Manual

RF Atten Auto

More 

Ref Level Offset

Ref Level Position

Grid Abs / Rel

Unit

Input 50 L/75 L

Ref Level

Opens an edit dialog box to enter the reference level in the currently active unit (dBm, dBMV,

etc).

The reference level value is the maximum value the AD converter can handle without distortion

of the measured value. Signal levels above this value will not be measured correctly, which is

indicated by the IFOVL status display.

Remote: DISP:TRAC:Y:RLEV –60dBm

Range Log

Selects logarithmic scaling for the level display range and opens the Range Log dialog box to

select a value for the level range.

Remote: DISP:TRAC:Y:SPAC LOG

Remote: DISP:TRAC:Y 120DB

R&S FSL Setting the Level Display and Configuring the RF Input – AMPT Key

1300.2519.12 4.15 E-11

Range Linear

Selects linear scaling for the level display range and opens a submenu to select the type of

linear scaling.

Range Linear %

Selects linear scaling in % for the level display range, i.e. the horizontal grid lines are labelled in

%. The grid is divided in decadic steps.

Markers are displayed in the selected unit (Unit softkey). Delta markers are displayed in %

referenced to the voltage value at the position of marker 1. This is the default setting for linear

scaling.

This softkey is available from firmware version 1.80.

Remote: DISP:TRAC:Y:SPAC LIN

Range Lin. Unit

Selects linear scaling in dB for the level display range, i.e. the horizontal lines are labelled in dB.

Markers are displayed in the selected unit (Unit softkey). Delta markers are displayed in dB

referenced to the power value at the position of marker 1.

This softkey is available from firmware version 1.80.

Remote: DISP:TRAC:Y:SPAC LDB

Preamp On/Off (option RF Preamplifier, B22)

Switches the preamplifier on or off.

The preamplifier has only an effect below 6 GHz.

Remote: INP:GAIN:STAT 0N

RF Atten Manual

Opens an edit dialog box to enter the attenuation, irrespective of the reference level.

The attenuation can be set in 5 dB steps. The range is specified in the data sheet. If the defined

reference level cannot be set for the set RF attenuation, the reference level will be adjusted

accordingly.

The RF attenuation defines the level at the input mixer according to the formula:

levelmixer = levelinput – RF attenuation

The maximum mixer level allowed is –10 dBm. Mixer levels above this value may lead to

incorrect measurement results, which are indicated by the OVLD status display.

Remote: INP:ATT 30 DB

Setting the Level Display and Configuring the RF Input – AMPT Key R&S FSL

1300.2519.12 4.16 E-11

RF Atten Auto

Sets the RF attenuation automatically as a function of the selected reference level. This ensures

that the optimum RF attenuation is always used. It is the default setting.

Remote: INP:ATT:AUTO ON

Ref Level Offset

Opens an edit dialog box to enter the arithmetic level offset. This offset is added to the

measured level irrespective of the selected unit. The scaling of the y–axis is changed

accordingly. The setting range is ±200 dB in 0.1 dB steps.

Remote: DISP:WIND:TRAC:Y:RLEV:OFFS –10dB

Ref Level Position

Opens an edit dialog box to enter the reference level position, i.e. the position of the maximum

AD converter value on the level axis. The setting range is from –200 to +200%, 0%

corresponding to the lower and 100% to the upper limit of the diagram.

Remote: DISP:WIND:TRAC:Y:RPOS 100PCT

Grid Abs / Rel (not available with Range Linear)

Switches between absolute and relative scaling of the level axis.

Absolute scaling The labeling of the level lines refers to the absolute value of the

reference level. Absolute scaling is the default setting.

Relative scaling The upper line of the grid is always at 0 dB. The scaling is in dB

whereas the reference level is always in the set unit (for details on unit

settings see Unit softkey).

Remote: DISP:WIND:TRAC:Y:MODE ABS

Unit

Opens the Unit dialog box to select the unit for the level axis. The default setting is dBm. If a

transducer is switched on, the softkey is not available.

In general, the spectrum analyzer measures the signal voltage at the RF input. The level display

is calibrated in RMS values of an unmodulated sinewave signal. In the default state, the level is

displayed at a power of 1 mW (= dBm). Via the known input impedance (50 Lor 75 L),

conversion to other units is possible. The units dBm, dBmV, dBµV, V and W are directly

convertible.

Remote: CALC:UNIT:POW DBM

R&S FSL Setting the Level Display and Configuring the RF Input – AMPT Key

1300.2519.12 4.17 E-11

Input 50 D/75 D

Uses 50 Lor 75 Las reference impedance for the measured levels. Default setting is 50 L.

Changes the reference impedance for the measured levels

The setting 75 Lshould be selected, if the 50 Linput impedance is transformed to a higher

impedance using a 75 Ladapter of the RAZ type (= 25 Lin series to the input impedance of the

instrument). The correction value in this case is 1.76 dB = 10 log ( 75 L/50 L).

All levels specified in this Operating Manual refer to the default setting of the instrument (50 L)R.

Remote: INP:IMP 50OHM

Setting the Bandwidths and Sweep Time – BW Key R&S FSL

1300.2519.12 4.18 E-11

Setting the Bandwidths and Sweep Time – BW Key

The BW key is used to set the resolution bandwidth, video bandwidth (VBW) and sweep time (SWT).

The values available for resolution bandwidth and video bandwidth depend on the selected filter type.

For details on channel filters see also "List of available RRC and channel filters" on page 4.20.

To open the bandwidth menu

Press the BW key.

The bandwidth menu is displayed.

Menu and softkey description

–"Softkeys of the bandwidth menu" on page 4.22

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"List of available RRC and channel filters" on page 4.20

Tasks

–To specify the bandwidth

–To choose the appropriate filter type

R&S FSL Setting the Bandwidths and Sweep Time – BW Key

1300.2519.12 4.19 E-11

To specify the bandwidth

1. Set the resolution bandwidth using the Res BW Manual or Res BW Auto softkey.

2. Set the video bandwidth using the Video BW Manual or Video BW Auto softkey.

3. Set the sweep time using the Sweeptime Manual or Sweeptime Auto softkey.

4. Press the Filter Type softkey and select the appropriate filters.

To choose the appropriate filter type

All resolution bandwidths are realized with digital filters. With option Narrow IF Filters, R&S FSL–B7, the

range is enlarged (for details refer to the data sheet).

The video filters serve for smoothing the displayed trace. Using video bandwidths that are small

compared to the resolution bandwidth, only the signal average is displayed and noise peaks and pulsed

signals are repressed. If pulsed signals are to be measured, it is recommended to use a video

bandwidth that is large compared to the resolution bandwidth (VBW * 10 x RBW) for the amplitudes of

pulses to be measured correctly.

The following filter types are available:

•Gaussian filters

The Gaussian filters are set by default. The available bandwidths are specified in the data sheet.

•EMI (6dB) filters

The EMI (6dB) filters are available from firmware version 1.30. The available bandwidths are

specified in the data sheet.

•FFT filters

The available bandwidths are specified in the data sheet.

The FFT algorithm offers considerably higher measurement speeds with all the other settings

remaining the same. The reason is that for analog filters the sweep time required for a particular

span is proportional to (span/RBW2). When using the FFT algorithm, however, the sweep time is

proportional to (span/RBW).

FFT filters are particularly suitable for stationary signals (sinusoidal signals or signals that are

continuously modulated in time). For burst signals (TDMA) or pulsed signals, normal filters are

preferable. When the tracking generator is used as signal source for the DUT, filtering with the FFT

algorithm is not useful. The FFT option is thus not available if the tracking generator is switched on.

If the FFT filters are activated, the sweep time display (SWT)is replaced by the acquisition time

(AQT)display. The sweep time is defined by the selected bandwidth and span, and cannot be

changed. The video bandwidth is not defined and therefore cannot be set.

The sample detector and the peak detector are available. If the Detector Auto Select softkey in the

trace menu is activated, the peak detector is selected.

•channel filters

details see "List of available RRC and channel filters"

•RRC filters

details see "List of available RRC and channel filters"

Setting the Bandwidths and Sweep Time – BW Key R&S FSL

1300.2519.12 4.20 E-11

List of available RRC and channel filters

For power measurement a number of especially steep–edged channel filters are available (see the

following table).

For filters of type RRC (Root Raised Cosine), the filter bandwidth indicated describes the sampling rate

of the filter. For all other filters (CFILter) the filter bandwidth is the 3 dB bandwidth.

Table 4-3: Filter types

Filter Bandwidth Filter Type Application

100

200

300

500

CFILter

1.5

2.4

2.7

3.4

4.5

8.5

kHz

CFILter

SSB

DAB, Satelite

ETS300 113 (12.5 kHz channels)

AM radio

12.5

24.3

kHz

kHz,



=0.35

kHz

kHz,



=0.35

kHz

CFILter

RRC

CFILter

RRC

CFILter

CDMAone

ETS300 113 (20 kHz channels)

ETS300 113 (25 kHz channels)

TETRA

PDC

IS 136 (NADC)

CDPD, CDMAone

100

150

192

200

300

500

kHz

CFILter

FM radio

PHS

J.83 (8-VSB DVB, USA)

R&S FSL Setting the Bandwidths and Sweep Time – BW Key

1300.2519.12 4.21 E-11

Filter Bandwidth Filter Type Application

1.0

1.2288

1,28

1.5

2.0

3.0

3.75

3.84

4.096

5.0

20 MHz

MHz

MHz,



=0.22*

MHz,



=0.22*

MHz

CFILter

RRC

CFILter

RRC

CFILter

CDMAone

DAB

W-CDMA 3GPP

W-CDMA NTT DOCoMo

Note: The 20 MHz channel filter is unavailable in sweep mode.

The 3.84 and 4.096 MHz filters (marked with an asterisk in the table) require an IF filter model

index



Setting the Bandwidths and Sweep Time – BW Key R&S FSL

1300.2519.12 4.22 E-11

Softkeys of the bandwidth menu

The following table shows all softkeys available in the bandwidth menu. It is possible that your

instrument configuration does not provide all softkeys. If a softkey is only available with a special option,

model or (measurement) mode, this information is delivered in the corresponding softkey description.

Command

Res BW Manual

Res BW Auto

Video BW Manual

Video BW Auto

Sweeptime Manual

Sweeptime Auto

Filter Type

Res BW Manual

Opens an edit dialog box to enter a value for the resolution bandwidth. The available resolution

bandwidths are specified in the data sheet. For details on the correlation between resolution

bandwidth and filter type refer to "To choose the appropriate filter type" on page 4.19.

Numeric input is always rounded to the nearest possible bandwidth. For rotary knob or

UP/DNARROW key inputs, the bandwidth is adjusted in steps either upwards or downwards.

The manual input mode of the resolution bandwidth is indicated by a green asterisk (*) at the

RBW display.

Remote: BAND:AUTO OFF

Remote: BAND 1MHz

Res BW Auto (span > 0)

Couples the resolution bandwidth to the selected span. If the span is changed, the resolution

bandwidth is automatically adjusted.

This setting is recommended, if a favorable setting of the resolution bandwidth in relation to the

selected span is desired.

Remote: BAND:AUTO ON

Video BW Manual (not available for FFT filter)

Opens an edit dialog box to enter the video bandwidth. The available video bandwidths are

specified in the data sheet.

Numeric input is always rounded to the nearest possible bandwidth. For rotary knob or

UP/DNARROW key inputs, the bandwidth is adjusted in steps either upwards or downwards.

The manual input mode of the video bandwidth is indicated by a green asterisk (*) at the VBW

display.

Remote: BAND:VID:AUTO OFF

Remote: BAND:VID 10 kHz

R&S FSL Setting the Bandwidths and Sweep Time – BW Key

1300.2519.12 4.23 E-11

Video BW Auto (not available for FFT filter)

Couples the video bandwidth to the resolution bandwidth. If the resolution bandwidth is changed,

the video bandwidth is automatically adjusted.

This setting is recommended, if a minimum sweep time is required for a selected resolution

bandwidth. Narrow video bandwidths require longer sweep times due to the longer settling time.

Wide bandwidths reduce the signal/noise ratio.

Remote: BAND:VID:AUTO ON

Sweeptime Manual (not available for FFT filter)

Opens an edit dialog box to enter the sweep time.

Sweep time Option TV Trigger, B6

(available from version 1.10)

absolute max. sweep time value: 16000 s 100 µs (zero span)

absolute min. sweep time value: 1 µs (zero span) 25 µs (zero span)

2.5 ms (span > 0) –

Allowed values depend on the ratio of span to RBW and RBW to VBW. For details refer to the

data sheet.

Numeric input is always rounded to the nearest possible sweep time. For rotary knob or

UPARROW/DNARROW key inputs, the sweep time is adjusted in steps either downwards or

upwards.

The manual input mode of the sweep time is indicated by a green asterisk (*) at the SWT

display. If the selected sweep time is too short for the selected bandwidth and span, level

measurement errors will occur due to a too short settling time for the resolution or video filters. In

this case, the R&S FSL displays the error message UNCAL and marks the indicated sweep time

with a red asterisk (*).

Remote: SWE:TIME:AUTO OFF

Remote: SWE:TIME 10s

Sweeptime Auto (not available for FFT filter and zero span)

Couples the sweep time to the span, video bandwidth (VBW) and resolution bandwidth (RBW). If

the span, resolution bandwidth or video bandwidth are changed, the sweep time is automatically

adjusted.

The R&S FSL always selects the shortest sweep time that is possible without falsifying the

signal. The maximum level error is < 0.1 dB, compared to using a longer sweep time.

Remote: SWE:TIME:AUTO ON

Filter Type

Opens the Filter Type dialog box to select the filter type.

For detailed information on filters see "To choose the appropriate filter type"on page 4.19 and

"List of available RRC and channel filters" on page 4.20.

Remote: BAND:TYPE NORM

Configuring the Sweep Mode – SWEEP Key R&S FSL

1300.2519.12 4.24 E-11

Configuring the Sweep Mode – SWEEP Key

The SWEEP key is used to configure the sweep mode. Continuous sweep or single sweep are

possible. The sweep time and the number of measured values are set.

To open the sweep menu

Press the SWEEP key.

The sweep menu is displayed.

Menu and softkey description

–"Softkeys of the sweep menu" on page 4.25

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Task

–To specify the sweep settings

R&S FSL Configuring the Sweep Mode – SWEEP Key

1300.2519.12 4.25 E-11

To specify the sweep settings

1. Press the Sweep Count softkey and enter the sweep count.

2. Set the sweep time by using the Sweeptime Manual or Sweeptime Auto softkey.

3. Press the Sweep Points softkey and enter the number of sweep points.

4. Select the sweep mode using the Continuous Sweep or Single Sweep softkey.

5. To repeat the single sweep, press the Continue Single Sweep softkey.

Softkeys of the sweep menu

The following table shows all softkeys available in the sweep menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

If the Spectrogram Measurement option (K14) is activated, this menu provides additional functionality.

For details refer to "Softkeys of the sweep menu (Spectrogram view)" on page 4.195.

Command

Continuous Sweep

Single Sweep

Continue Single Sweep

Sweeptime Manual

Sweeptime Auto

Sweep Count

Sweep Points

Continuous Sweep

Sets the continuous sweep mode: the sweep takes place continuously according to the trigger

settings. This is the default setting. The trace averaging is determined by the sweep count value

(see Sweep Count softkey).

If the Spectrogram Measurement option (K14) is activated, this softkey provides additional

functionality. For details refer to Continuous Sweep Start/Stop softkey in the sweep menu of

this option.

Remote: INIT:CONT ON

Single Sweep

Sets the single sweep mode: after triggering, starts the number of sweeps that are defined by

using the Sweep Count softkey. The measurement stops after the defined number of sweeps

has been performed.

Remote: INIT:CONT OFF

Configuring the Sweep Mode – SWEEP Key R&S FSL

1300.2519.12 4.26 E-11

Continue Single Sweep

Repeats the number of sweeps set by using the Sweep Count softkey, without deleting the

trace of the last measurement.

This is particularly of interest when using the trace configurations Average or Max Hold to take

previously recorded measurements into account for averaging / maximum search. For details on

trace configuration refer to "Setting Traces – TRACE Key" on page 4.39.

Remote: INIT:CONM

Sweeptime Manual

Opens an edit dialog box to enter the sweep time. For details see Sweeptime Manual softkey in

the bandwidth menu.

Remote: SWE:TIME 10s

Sweeptime Auto

Sets the automatic sweep time mode. For details see Sweeptime Auto softkey in the bandwidth

menu.

Remote: SWE:TIME:AUTO ON

Sweep Count

Opens an edit dialog box to enter the number of sweeps to be performed in the single sweep

mode. Values from 0 to 32767 are allowed. If the values 0 or 1 are set, one sweep is performed.

The sweep count is applied to all the traces in a diagram.

The sweep count set in the sweep menu is the same as that in the trace menu (for further details

see Sweep Count softkey). If the trace configurations Average,Max Hold or Min Hold are set,

the sweep count value also determines the number of averaging or maximum search

procedures (for details on trace configuration see "Setting Traces – TRACE Key" on page 4.39.

Example:

TRACE key – Trace Mode softkey – Mode Max Hold softkey

SWEEP key – Sweep Count softkey – Average Sweep Count dialog box: enter 10

Single Sweep softkey: R&S FSL performs the Max Hold function over 10 sweeps.

Remote: SWE:COUN 64

R&S FSL Configuring the Sweep Mode – SWEEP Key

1300.2519.12 4.27 E-11

Sweep Points

Opens an edit dialog box to enter the number of measured values to be collected during one

sweep.

–Entry via rotary knob:

In the range from 101 to 1001, the sweep points are increased or decreased in steps of 100

points.

In the range from 1001 to 32001, the sweep points are increased or decreased in steps of 1000

points.

–Entry via keypad:

All values in the defined range can be set.

The default value is 501 sweep points. If a value 501 is set, the auto peak detector is turned

off automatically.

Remote: SWE:POIN 501

Triggering the Sweep – TRIG Key R&S FSL

1300.2519.12 4.28 E-11

Triggering the Sweep – TRIG Key

The TRIG key is used to set trigger mode, trigger threshold, trigger delay, trigger polarity and for gated

sweep the gate configuration.

To open the trigger menu

Press the TRIG key.

The trigger menu is displayed.

Menu and softkey description

–"Softkeys of the trigger menu" on page 4.33

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"Trigger mode overview" on page 4.31

Tasks

–To specify the trigger settings

–To use gated sweep operation (option Gated Sweep, B8)

–To trigger on TV signals (zero span and option TV Trigger, B6)

R&S FSL Triggering the Sweep – TRIG Key

1300.2519.12 4.29 E-11

To specify the trigger settings

1. Press the Trg / Gate Source softkey to select the trigger mode (for details see "Trigger mode

overview"on page 4.31).

2. Press the Trg / Gate Level softkey to set the trigger level.

3. Press the Trigger Offset softkey to set the trigger offset.

4. For details on gated sweep operation, see "To use gated sweep operation (option Gated Sweep,

B8)"on page 4.29.

5. For details on TV signal triggering, see "To trigger on TV signals (zero span and option TV Trigger,

B6)".

To use gated sweep operation (option Gated Sweep, B8)

By using a gate in sweep mode and stopping the measurement while the gate signal is inactive, the

spectrum for pulsed RF carriers can be displayed without the superposition of frequency components

generated during switching. Similarly, the spectrum can also be examined for an inactive carrier. The

sweep can be controlled by an external gate or by the internal power trigger.

Gated sweep operation is also possible for span = 0. This enables – e.g. in burst signals – level

variations of individual slots to be displayed versus time.

1. Press the Gate Settings submenu softkey to define the settings of the gate mode.

At the center frequency a transition to zero span is made and the time parameters gate delay and

gate length are displayed as vertical lines to adjust them easily.

When quitting the Gate Settings submenu, the original span is retrieved so the desired

measurement can be performed with the accurately set gate.

2. To set the parameters gate delay and gate length highly accurate, press the Sweep Time softkey to

alter the x–axis in a way that the signal range concerned (e.g. one full burst) is displayed.

3. Press the Gate Delay softkey to set the sampling time in a way that the desired portion of the signal

is shown.

4. Press the Gate Mode Lvl/Edge softkey to set the gate mode.

5. If the Edge gate mode has been selected, press the Gate Length softkey to set the sampling

duration in a way that the desired portion of the signal is shown.

6. Press the Trg / Gate Polarity Pos/Neg softkey to set the polarity of the trigger source.

7. Press the Gated Trigger softkey to activate the gated sweep mode.

To indicate that a gate is used for the sweep, the enhancement label GAT is displayed on the

screen. This label appears to the right of the window for which the gate is configured.

Triggering the Sweep – TRIG Key R&S FSL

1300.2519.12 4.30 E-11

Fig. 4-1: TDMA signal with GATE OFF

Fig. 4-2: Pulsed signal with GATE ON

R&S FSL Triggering the Sweep – TRIG Key

1300.2519.12 4.31 E-11

Fig. 4-3: Timing diagram for GATE, GATE DELAY and GATE LENGTH

To trigger on TV signals (zero span and option TV Trigger, B6)

1. Press the TV Trig Settings submenu softkey to switch the TV trigger on and define the settings for

triggering on TV signal.

2. To configure the TV trigger, press the Vert Sync,Vert Sync Odd Field,Vert Sync Even Field or

Hor Sync softkey.

3. Press the Video Pol Pos/Neg softkey to set the polarity of the video signal.

4. Press the Lines 625/525 softkey to set the line system to be used.

Option TV Trigger, B6, is available from firmware version 1.10.

Trigger mode overview

The R&S FSL offers the following trigger modes:

•Free Run

The start of a sweep is not triggered. Once a measurement is completed, another is started

immediately.

•External

Triggering via a TTL signal at the input connector EXT TRIG / GATE IN on the rear panel.

•Video

Triggering by the displayed voltage.

Ahorizontal trigger line is shown in the diagram. It is used to set the trigger threshold from 0% to

100% of the diagram height.

•IF Power

Triggering of the measurement via signals which are outside the measurement channel.

For this purpose, the R&S FSL uses a level detector at the second intermediate frequency. Its

threshold can be set in a range between –50 dBm and –10 dBm at the input mixer. The resulting

trigger level at the RF input is calculated via the following formula:

Mixerlevelmin + RFAtt – PreampGain



Input Signal



Mixerlevelmax + RFAtt – PreampGain

Triggering the Sweep – TRIG Key R&S FSL

1300.2519.12 4.32 E-11

The bandwidth at the intermediate frequency is 20 MHz. The R&S FSL is triggered as soon as the

trigger threshold is exceeded within a 10 MHz range around the selected frequency (= start

frequency in the frequency sweep).

Thus, the measurement of spurious emissions, e.g. for pulsed carriers, is possible even if the

carrier lies outside the selected frequency span.

•TV (option TV Trigger, B6, available from firmware version 1.10)

Triggering of the measurement on TV signals. In this trigger mode, only the Auto Peak and the

Sample detectors are available (for details refer to "Detector overview" on page 4.42).

In order to display different sections of a TV video signal, the R&S FSL derives several trigger

signals from the video signals. This allows triggering as well on the frame repetition as on each line

of the TV video signal.

The filter bandwidth is constant: 4.0 MHz for standards with 525 lines or 5.0 MHz for standards with

625 lines. The position of the filter is determined by the firmware in order to place the 3 dB filter

bandwidth on the center frequency, as shown in the diagramm below. For the center frequency, the

value of the vision carrier frequency should be set.

fv = vision carrier frequency fa = aural carrier frequency

fc = chrominance sub–carrier frequency BW = –3dB filter bandwidth

Fig. 4-4: 3 dB Filter bandwidth (option TV Trigger, B6, available from firmware version 1.10)

•Time Trigger (available from firmware version 1.60)

Triggering of the measurement by a time intervall, set via the Repetition Intervall softkey.

R&S FSL Triggering the Sweep – TRIG Key

1300.2519.12 4.33 E-11

Softkeys of the trigger menu

The following table shows all softkeys available in the trigger menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Command

Trg / Gate Source

Trg / Gate Level

Trg / Gate Polarity Pos/Neg

Trigger Offset / Repetition Intervall

Gated Trigger

Gate SettingsGate Mode Lvl/Edge

Gate Delay

Gate Length

Trg / Gate Source

Trg / Gate Level

Trg / Gate Polarity Pos/Neg

Sweep Time

More 

IF Power Retrigger Holdoff

IF Power Retrigger Hysteresis

TV Trig Settings Vert Sync

Vert Sync Odd Field

Vert Sync Even Field

Hor Sync

Video Pol Pos/Neg

Lines 625/525

TV Free Run On/Off

Trg / Gate Source

Opens the Trigger / Gate Source dialog box to select the trigger / gate mode. For detailed

information on trigger modes see "Trigger mode overview" on page 4.31.

The gate–related settings are only available with option Gated Sweep, R&S FSL–B8. As gate

modes, all modes apart from the TV Trigger mode (option TV Trigger, B6, available from

firmware version 1.10) are available. For details see also "To use gated sweep operation (option

Gated Sweep, B8)" on page 4.29.

The default setting is Free Run.If a trigger mode other than Free Run has been set, the

enhancement label TRG is displayed.

Remote: TRIG:SOUR IMM | VID | IFP | EXT | TV | TIME (Free Run, Video, IF Power,

Extern,TV Trigger, Time Trigger)

Remote: SWE:EGAT:SOUR EXT (Extern)

Triggering the Sweep – TRIG Key R&S FSL

1300.2519.12 4.34 E-11

Trg / Gate Level

Opens an edit dialog box to enter the trigger / gate level. The gate–related settings are only

available with option Gated Sweep, R&S FSL–B8. For details see also "Trigger mode overview"

on page 4.31 and "To use gated sweep operation (option Gated Sweep, B8)"on page 4.29.

In the Time Trigger mode, this softkey is not available.

Remote: TRIG:LEV:VID 50PCT

Remote: TRIG:LEV:IFP –30DBM

Trg / Gate Polarity Pos/Neg

Sets the polarity of the trigger / gate source. The gate–related settings are only available with

option Gated Sweep, R&S FSL–B8.

The sweep starts after a positive or negative edge of the trigger signal. The default setting is

Pos.The setting applies to all modes with the exception of the Free Run mode.

level triggering In the setting Pos the sweep is stopped by the logic ´0´ signal and

restarted by the logical ´1´ signal after the gate delay time has elapsed.

edge triggering The sweep is continued on a ´0´ to ´1´ transition for the gate length

duration after the gate delay time has elapsed.

In the Time Trigger mode, this softkey is not available.

For details also see "To use gated sweep operation (option Gated Sweep, B8)" on page 4.29.

Remote: TRIG:SLOP POS

Remote: SWE:EGAT:POL POS

Trigger Offset

Opens an edit dialog box to enter the time offset between the trigger signal and the start of the

sweep. The time may be entered in multiples of 125 ns in the range –100 s to 100 s (default

0s).

offset > 0: start of the sweep is delayed

offset < 0: sweep starts earlier (pre–trigger)

only possible for span = 0 and gated trigger switched off

not possible if RMS or average detector activated

maximum allowed range and the maximum resolution limited by the sweep time:

rangemax = – 499/500 x sweep time

resolutionmax = sweep time/500

Note: For the option TV Trigger, B6 (available from firmware version 1.10), the allowed offset ranges

from –50 Bsto +50 Bs. If the trigger source is changed to TV trigger and the set trigger offset is

out of range, the trigger offset is adopted to the closest value allowed.

In the External or IF Power trigger mode, a common input signal is used for both trigger and

gate. Therefore changes to the gate delay will affect the trigger delay (trigger offset) as well.

In the Time Trigger mode, this softkey is not available.

Remote: TRIG:HOLD 10US

R&S FSL Triggering the Sweep – TRIG Key

1300.2519.12 4.35 E-11

Repetition Intervall (Time Trigger mode)

Opens an edit dialog box to enter the time intervall after which the sweep is started. The

possible values range from 100 ms to 5000 s.

This softkey is available from firmware version 1.60.

Remote: TRIG:TIME:RINT 50

Gated Trigger (option Gated Sweep, B8)

Switches the sweep mode with gate on or off .

This softkey requires the following trigger mode:

span > 0 External or IF Power

span = 0 External or IF Power or Video

If a different mode is active, the IF Power trigger mode is automatically selected.

If the gate is switched on, a gate signal applied to the rear panel connector EXT

TRIGGER/GATE or the internal IF power detector controls the sweep of the analyzer.

In the Time Trigger mode, this softkey is not available.

For details also see "To use gated sweep operation (option Gated Sweep, B8)" on page 4.29.

Remote: SWE:EGAT ON

Remote: SWE:EGAT:SOUR IFP | EXT

Gate Settings (option Gated Sweep, B8)

Opens a submenu to make all the settings required for gated sweep operation.

In the Time Trigger mode, this softkey is not available.

For details also see "To use gated sweep operation (option Gated Sweep, B8)" on page 4.29.

Gate Mode Lvl/Edge (option Gated Sweep, B8)

Sets the gate mode. As settings level–triggered or edge–triggered gate mode can be selected.

For details also see "To use gated sweep operation (option Gated Sweep, B8)" on page 4.29.

Remote: SWE:EGAT:TYPE EDGE

Triggering the Sweep – TRIG Key R&S FSL

1300.2519.12 4.36 E-11

Gate Delay (option Gated Sweep, B8)

Opens an edit dialog box to enter the gate delay time between the gate signal and the

continuation of the sweep. Values between 125 ns and 100 s are allowed. The delay position on

the time axis in relation to the sweep is indicated by a line labeled GD.

This is useful for e.g. taking into account a delay between the gate signal and the stabilization of

an RF carrier.

As a common input signal is used for both trigger and gate when selecting the External or IF

Power trigger mode, changes to the gate delay will affect the trigger delay (trigger offset) as

well.

For details also see "To use gated sweep operation (option Gated Sweep, B8)" on page 4.29.

Remote: SWE:EGAT:HOLD 1US

Gate Length (Gate Mode Edge)

Opens an edit dialog box to enter the gate length. Values between 125 ns and 100 s are

allowed. The gate length in relation to the sweep is indicated by a line labeled GL.

The length of the gate signal defines if the sweep is to be interrupted. Only in the edge–triggered

mode the gate length can be set, while in the level–triggered the gate length depends on the

length of the gate signal.

For details also see "To use gated sweep operation (option Gated Sweep, B8)" on page 4.29.

Remote: SWE:EGAT:LENG 100US

Sweep Time (option Gated Sweep, B8)

Opens an edit dialog box to change the sweep time in order to obtain a higher resolution for

positioning gate delay and gate length. When quitting the Gate Settings submenu, the original

sweep time is retrieved.

For details also see "To use gated sweep operation (option Gated Sweep, B8)" on page 4.29.

IF Power Retrigger Holdoff

Opens an edit dialog box to define the value for the IF power trigger holdoff. This softkey is only

available if the IF power trigger is selected as the trigger source. The holdoff value in s is the

time which must pass since another IF power trigger event may happen. The range of the value

is between 150 ns and 10 s in the step width of 10 ns.

This softkey is available from firmware version 1.30.

Remote: TRIG:IFP:HOLD 200 ns

R&S FSL Triggering the Sweep – TRIG Key

1300.2519.12 4.37 E-11

IF Power Retrigger Hysteresis

Opens an edit dialog box to define the value for the IF power trigger hysteresis. This softkey is

only available if the IF power trigger is selected as the trigger source. The hysteresis in dB is the

value the input signal must decay below the IF power trigger level in order to allow an IF power

trigger starting the measurement. The range of the value is between 3 dB and 50 dB in the step

width of 1 dB.

This softkey is available from firmware version 1.30.

Remote: TRIG:IFP:HYST 10DB

TV Trig Settings (zero span and option TV Trigger, B6)

Switches the TV trigger on and opens a submenu to configure the TV signal parameters.

Option TV Trigger, B6, is available from firmware version 1.10.

Remote: TRIG:SOUR TV

Vert Sync (zero span and option TV Trigger, B6)

Sets the trigger on the vertical sync signal. The R&S FSL triggers on the frame repetition signal

without distinction between the two fields.

Option TV Trigger, B6, is available from firmware version 1.10.

Remote: TRIG:VID:FIEL:SEL ALL

Vert Sync Odd Field (zero span and option TV Trigger, B6)

Sets the trigger on the vertical sync signal of the first field.

Option TV Trigger, B6, is available from firmware version 1.10.

Remote: TRIG:VID:FIEL:SEL ODD

Vert Sync Even Field (zero span and option TV Trigger, B6)

Sets the trigger on the vertical sync signal of the second field.

Option TV Trigger, B6, is available from firmware version 1.10.

Remote: TRIG:VID:FIEL:SEL EVEN

Hor Sync (zero span and option TV Trigger, B6)

Sets the trigger on the horizontal sync signal and opens an edit dialog box to enter the

corresponding line. Depending on the selected line system (for details see Lines 625/525

softkey), values from 1 to 525 or 1 to 625 are allowed. If the range is exceeded, the maximum

possible line number will be set.

The default setting is 17, which is used to trigger according to CCIR 473–4 on test line 17.

Option TV Trigger, B6, is available from firmware version 1.10.

Remote: TRIG:VID:LINE:NUM 17

Triggering the Sweep – TRIG Key R&S FSL

1300.2519.12 4.38 E-11

Video Pol Pos/Neg (zero span and option TV Trigger, B6)

Sets the polarity of the video signal. Default setting is Neg.

Positive video polarity is to be selected e.g. for standard L signals, negative video polarity for

signals according to the standards B/G/I/M (color standard PAL or NTSC).

Option TV Trigger, B6, is available from firmware version 1.10.

Remote: TRIG:VID:SSIG:POL NEG

Lines 625/525 (zero span and option TV Trigger, B6)

Sets the line system to be used. Default setting is 625 lines.

Option TV Trigger, B6, is available from firmware version 1.10.

Remote: TRIG:VID:FORM:LPFR 625

TV Free Run On/Off (zero span and option TV Trigger, B6)

Activates or deactivates the free run trigger mode for option TV Trigger, B6. For details on

trigger modes refer to "Trigger mode overview" on page 4.31. In this mode, only the trace modes

Clear Write and View are available (see also "Trace mode overview" on page 4.40).

This softkey is available from firmware version 1.30.

Remote: TRIG:VID:CONT ON

R&S FSL Setting Traces – TRACE Key

1300.2519.12 4.39 E-11

Setting Traces – TRACE Key

The TRACE key is used to configure the data acquisition for measurement and the analysis of the

measurement data.

The R&S FSL is capable of displaying up to six different traces at a time in a diagram. A trace consists

of a maximum of 501 measurement points on the horizontal axis (frequency or time). If more measured

values than measurement points are available, several measured values are combined in one

measurement point.

The trace functions are subdivided as follows:

•Display mode of trace (Clear Write,View and Blank). For details on trace modes see "Trace mode

overview" on page 4.40.

•Evaluation of the trace as a whole (Average,Max Hold and Min Hold). For details on trace modes

see "Trace mode overview" on page 4.40. For details on averaging see "Description of the

averaging method" on page 4.41.

•Evaluation of individual measurement points of a trace. For details on detectors see "Detector

overview" on page 4.42.

To open the trace menu

Press the TRACE key.

The trace menu is displayed. The Trace Configuration dialog box is displayed.

Menu and softkey description

–"Softkeys of the trace menu" on page 4.43

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"Trace mode overview" on page 4.40

–"Detector overview" on page 4.42

– "Description of the averaging method" on page 4.41

–"ASCII file export format" on page 4.51

Task

–To specify the trace settings

Setting Traces – TRACE Key R&S FSL

1300.2519.12 4.40 E-11

To specify the trace settings

1. Press the Trace 1 2 3 4 5 6 softkey to select the trace.

2. Press the Trace Mode softkey to select the trace mode for the selected trace (for details see "Trace

mode overview" on page 4.40).

3. Press the Detector Auto Select softkey for automatic detector selection or press the Detector

Manual Select softkey to select a detector (for details see "Detector overview" on page 4.42).

4. To change the sweep count setting, which also determines trace averaging, press the Sweep

Count softkey.

5. To deactivate the reset of the traces in Min Hold and Max Hold mode after some specific

parameter changes, press the Hold/Cont softkey.

6. To copy a trace into another trace memory, press the Copy Trace softkey.

Upon copying, the contents of the selected memory are overwritten and the new contents are

displayed in the View mode.

7. To export the active trace in ASCII format:

–Press the More softkey.

–If necessary, press the Decim Sep softkey to change the decimal separator with floating–point

numerals.

–Press the ASCII File Export softkey to enter the ASCII file export name.

The active trace is saved in ASCII format on the flash disk or a USB device.

Trace mode overview

The traces can individually be activated for a measurement or frozen after completion of a

measurement. Traces that are not activated are hidden. Each time the trace mode is changed, the

selected trace memory is cleared.

The R&S FSL offers 6 different trace modes:

•Clear Write

Overwrite mode: the trace is overwritten by each sweep. All available detectors can be selected.

This is the default setting.

•Max Hold

The maximum value is determined over several sweeps and displayed. The R&S FSL saves the

sweep result in the trace memory only if the new value is greater than the previous one. The

detector is automatically set to Positive Peak.

This mode is especially useful with modulated or pulsed signals. The signal spectrum is filled up

upon each sweep until all signal components are detected in a kind of envelope.

This mode is not available for statistics measurements or if the TV trigger is active and the TV Free

Run On/Off softkey is set to ON (option TV Trigger, B6).

•Min Hold

The minimum value is determined from several measurements and displayed. The R&S FSL saves

for each sweep the smallest of the previously stored/currently measured values in the trace

memory. The detector is automatically set to Negative Peak.

This mode is useful e.g. for making an unmodulated carrier in a composite signal visible. Noise,

interference signals or modulated signals are suppressed whereas a CW signal is recognized by its

constant level.

R&S FSL Setting Traces – TRACE Key

1300.2519.12 4.41 E-11

This mode is not available for statistics measurements or if the TV trigger is active and the TV Free

Run On/Off softkey is set to ON (option TV Trigger, B6).

•Average

The average is formed over several sweeps. All available detectors can be selected. If the detector

is automatically selected, the sample detector is used. For details see also "Description of the

averaging method" on page 4.41.

This mode is not available for statistics measurements or if the TV trigger is active and the TV Free

Run On/Off softkey is set to ON (option TV Trigger, B6).

•View

The current contents of the trace memory is frozen and displayed.

If a trace is frozen, the instrument settings, apart from level range and reference level (see below),

can be changed without impact on the displayed trace. The fact that the trace and the current

instrument setting do not correspond any more is indicated by the enhancement label "*"at the left

edge of the grid.

If level range or reference level are changed, the R&S FSL automatically adapts the measured data

to the changed display range. This allows an amplitude zoom to be made after the measurement in

order to show details of the trace.

•Blank

Hides the selected trace.

Description of the averaging method

Averaging is carried out over the measurement points derived from the measurement samples. Several

measured values may be combined in a measurement point. This means that with linear level display

the average is formed over linear amplitude values. The sweep mode (continuous or single sweep, for

details see "Configuring the Sweep Mode – SWEEP Key" on page 4.24) and running averaging apply to

the average display analogously. In principle, two methods for calculating the average are used:

continuous averaging and averaging over the selected number of sweeps.

•sweep count > 1

Depending on the relation of the following two parameters, two different situations exist:

n = number of sweeps performed since measurement start

c = sweep count (number of sweeps forming one statistics cycle)

– n



In single sweep or continuous sweep mode during the first statistics cycle, averaging over the

selected number of sweeps is performed. The average trace nis calculated at each

measurement point according to:

)(

)1(

)( nCurr

nAvg

nAvg +



=Equ. 4–1

with Avg = average trace; Curr = current trace

Until the first statistics cycle is completed (n < c), a preliminary average is displayed which

represents the arithmetic mean value over all measured sweeps. With n increasing, the

displayed trace is increasingly smoothed since there are more single sweeps for averaging.

When the first statistics cycle is completed (n = c), the average trace is saved in the trace

memory.

– n > c

Setting Traces – TRACE Key R&S FSL

1300.2519.12 4.42 E-11

In continuous sweep mode after the first statistics cycle, continuous averaging is performed.

The average trace nis calculated at each measurement point according to:

)(

)1(

)( nCurr

nAvg

nAvg +



=Equ. 4–2

with Avg = average trace; Curr = current trace

In single sweep mode, the same formula holds true if the Continue Single Sweep softkey is

pressed.

•sweep count = 0

In continuous sweep mode, a continuous average is calculated according to Equ. 4–3.

with c = 10:

)(

)1(

)( nCurrnAvgnAvg +=Equ. 4–3

with Avg = average trace; Curr = current trace

Due to the weighting between the current trace and the average trace, past values have practically

no influence on the displayed trace after about ten sweeps. With this setting, signal noise is

effectively reduced without need for restarting the averaging process after a change of the signal.

•sweep count = 1

The current trace is displayed. No averaging is performed. This is a special case of Equ. 4–1 with

n = 0.

Detector overview

The measurement detector for the individual display modes can be selected directly by you or set

automatically by R&S FSL. The detector activated for the specific trace is identified in the respective

trace display field in form of an abbreviation (for details see detector list).

The detectors of the R&S FSL are implemented as pure digital devices. They collect signal power data

within each measured point during a sweep. The default number of sweep points is 501. The following

detectors are available:

Detector Indicator

Function

auto peak detector

(Auto Peak)

Ap determines the maximum and the minimum value within a

measurement point

peak detector

(Positive Peak)

Pk determines the maximum value within a measurement point

min peak detector

(Negative Peak)

Mi determines the minimum value within a measurement point

sample detector

(Sample)

Sa selects a random value within a measurement point

RMS detector (RMS)Rm determines the root mean square power within a

measurement point

average detector

(Average)

Av determines the linear average power within a measurement

point

quasi peak detector

(Quasi Peak)

QP determines the quasipeak power within a measurement point

for EMI measurements (available from firmware version 1.10)

R&S FSL Setting Traces – TRACE Key

1300.2519.12 4.43 E-11

If the TV trigger is active, only the auto peak and the sample detector are available.

The result obtained from the selected detector within a measurement point is displayed as the power

value at this measurement point.

All detectors work in parallel in the background, which means that the measurement speed is

independent of the detector combination used for different traces.

Note: During a frequency sweep, R&S FSL increments the 1st local oscillator in steps that are smaller

than approximately 1/10 of the bandwidth. This makes sure that the oscillator step speed is

conforming to the hardware settling times and does not affect the precision of the measured

power.

The number of measured values taken during a sweep is independent of the number of

oscillator steps. It is always selected as a multiple or a fraction of 501 (= default number of trace

points displayed on the screen). Choosing less then 501 measured values (e.g. 125 or 251) will

lead to an interpolated measurement curve, choosing more than 501 points (e.g. 1001, 2001 ...)

will result in several measured values being overlaid at the same frequency position.

Softkeys of the trace menu

The following table shows all softkeys available in the trace menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Command

Trace 1 2 3 4 5 6

Trace Mode Clear Write

Max Hold

Min Hold

Average

View

Blank

Detector Auto Select

Detector Manual Select Detector Auto Peak

Detector Positive Peak

Detector Negative Peak

Detector Sample

Detector RMS

More 

Detector Average

Detector Quasi Peak

Sweep Count

Hold/Cont

More 

Trace 1 2 3 4 5 6

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Menu / Command Command

Copy Trace

ASCII File Export

Decim Sep

Trace Math

Trace Math Position

Average Mode LOG

LIN

POWER

Trace 1 2 3 4 5 6

Selects the active trace (1, 2, 3, 4, 5, 6). The default setting is trace 1 in the overwrite mode (see

Clear Write mode), the other traces are switched off (see Blank mode).

Remote: (selected via numeric suffix of :TRACe<1...6>)

Trace Mode

Opens a submenu to select the trace mode. For details see "Trace mode overview" on page

4.40.

Clear Write

Selects the Clear Write mode. For details see "Trace mode overview" on page 4.40.

This softkey is available from firmware version 1.80.

Remote: DISP:TRAC:MODE WRIT

Max Hold

Selects the Max Hold mode. For details see "Trace mode overview" on page 4.40.

This softkey is available from firmware version 1.80.

Remote: DISP:TRAC:MODE MAXH

Min Hold

Selects the Min Hold mode. For details see "Trace mode overview" on page 4.40.

This softkey is available from firmware version 1.80.

Remote: DISP:TRAC:MODE MINH

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Average

Selects the Average mode. For details see "Trace mode overview" on page 4.40.

This softkey is available from firmware version 1.80.

Remote: DISP:TRAC:MODE AVER

View

Selects the View mode. For details see "Trace mode overview" on page 4.40.

This softkey is available from firmware version 1.80.

Remote: DISP:TRAC:MODE VIEW

Blank

Selects the Blank mode. For details see "Trace mode overview" on page 4.40.

This softkey is available from firmware version 1.80.

Remote: DISP:TRAC OFF

Detector Auto Select

Selects the optimum detector for the selected trace and filter mode. This is the default setting.

For details see also "Detector overview" on page 4.42.

Trace mode Detector (band–pass filter) Detector (FFT filter)

Clear/Write Auto Peak Max Peak

Average Sample Sample

Max Hold Max Peak Max Peak

Min Hold Min Peak Max Peak

Remote: DET:AUTO ON

Detector Manual Select

Opens a submenu to select the detector. For details see "Detector overview" on page 4.42.

Detector Auto Peak

Selects the Auto Peak detector. For details see "Detector overview" on page 4.42.

This softkey is available from firmware version 1.80.

Remote: DET APE

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Detector Positive Peak

Selects the Positive Peak detector. For details see "Detector overview" on page 4.42.

This softkey is available from firmware version 1.80.

Remote: DET POS

Detector Negative Peak

Selects the Negative Peak detector. For details see "Detector overview" on page 4.42.

This softkey is available from firmware version 1.80.

Remote: DET NEG

Detector Sample

Selects the Sample detector. For details see "Detector overview" on page 4.42.

This softkey is available from firmware version 1.80.

Remote: DET SAMP

Detector RMS

Selects the RMS detector. For details see "Detector overview" on page 4.42.

This softkey is available from firmware version 1.80.

Remote: DET RMS

Detector Average

Selects the Average detector. For details see "Detector overview" on page 4.42.

This softkey is available from firmware version 1.80.

Remote: DET AVER

Detector Quasi Peak

Selects the Quasi Peak detector. For details see "Detector overview" on page 4.42.

This softkey is available from firmware version 1.80.

Remote: DET QPE

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Sweep Count

Opens an edit dialog box to enter the number of sweeps used for averaging. Values from 0 to

32767 are allowed. The default setting is 0. The sweep count is applied to all the traces in a

diagram. The sweep count set in the trace menu is the same as that in the sweep menu (for

further details see Sweep Count softkey).

In the continuous sweep mode, the sweep count value determines the trace averaging:

–sweep count = 0: continuous averaging

–sweep count = 1: no averaging

–sweep count > 1: averaging over the selected number of sweeps; in the continuous sweep

mode averaging is performed until the set number of sweeps is attained and is then continued

as continuous averaging (see also "Description of the averaging method" on page 4.41).

Remote: SWE:COUN 64

Hold/Cont

Switches on or off the reset of the traces in Min Hold, Max Hold and Average mode after some

specific parameter changes have been made. The default setting is off.

Normally, the measurement is started anew after parameter changes, before the measurement

results are evaluated (e.g. using a marker). In all cases that require a new measurement after

parameter changes, the trace is reset automatically to avoid false results (e.g. with span

changes). For applications that require no reset after parameter changes, the automatic reset

can be switched off.

Remote: DISP:TRAC:MODE:HCON ON

Copy Trace

Opens an edit dialog box to enter the number of the trace memory, in which the currently

selected trace shall be copied.

Remote: TRAC:COPY TRACE1,TRACE2

ASCII File Export

Opens the ASCII File Export Name dialog box and saves the active trace in ASCII format to the

specified file and directory.

The file consists of the header containing important scaling parameters and a data section

containing the trace data. For details on an ASCII file see "ASCII file export format" on page

4.51.

This format can be processed by spreadsheet calculation programs, e.g. MS Excel. It is

necessary to define ';' as a separator for the data import. Different language versions of

evaluation programs may require a different handling of the decimal point. It is therefore possible

to select between separators '.' (decimal point) and ',' (comma) using the Decim Sep softkey.

Remote: FORM ASC

Remote: MMEM:STOR:TRAC 1,'TRACE.DAT'

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Decim Sep

Selects the decimal separator with floating–point numerals for the ASCII file export to support

evaluation programs (e.g. MS Excel) in different languages. The values '.' (decimal point) and ','

(comma) can be set. For details see also ASCII File Export softkey.

Remote: FORM:DEXP:DSEP POIN

Trace Math

Opens the Trace Mathematics dialog box to define which trace is subtracted from trace 1. The

result is displayed in trace 1 and refers to the zero point defined with the Trace Math Position

softkey. The following substractions can be performed:

T1–>T1–T2 Substracts trace 2 from trace 1.

T1–>T1–T3 Substracts trace 3 from trace 1

T1–>T1–T4 Substracts trace 4 from trace 1

T1–>T1–T5 Substracts trace 5 from trace 1

T1–>T1–T6 Substracts trace 6 from trace 1

If the Trace Math Off option is activated, the function is switched off (default setting).

This softkey is available from firmware version 1.30.

Remote: CALC1:MATH (TRACE1 – TRACE2)

Remote: CALC:MATH:STAT ON

Trace Math Position

Opens an edit dialog box to define the zero point in % of the diagram height. The range of

values extends from –100% to +200%.

This softkey is available from firmware version 1.30.

Remote: CALC:MATH:POS 50PCT

Average Mode

Opens a submenu to select the averaging method for the average trace mode. The submenu

contains the following softkeys.

This softkey is available from firmware version 1.90.

Command

LOG

LIN

POWER

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Logarithmic averaging is preferred to display signals with a low signal to noise ratio. While

positive peak values are decreased in logarithmic averaging due to the characteristics involved,

it is also true that negative peaks are increased relative to the average value.If the distorted

amplitude distribution is averaged, a value is obtained that is smaller than the actual average

value. The difference is -2.5 dB.

This low average value is usually corrected in noise power measurements by a 2.5 dB factor.

Therefore the R&S FSL offers the selection of linear averaging. The trace data is converted to

linear values prior to averaging, then averaged and reconverted to logarithmic values. After

these conversions the data is displayed on the screen. The average value is always correctly

displayed irrespective of the signal characteristic.

In case of stationary sinusoidal signals all averaging methods have the same results.

LOG

Activates logarithmic averaging.

This averaging method only takes effect if the grid is set to a logarithmic scale (see Range Log

softkey). In this case the values are averaged in dBm. Otherwise (i.e. with linear scaling) the

behaviour is the same as with linear averaging (see LIN softkey). For further information on

logarithmic scaling refer to the Average Mode softkey.

This softkey is available from firmware version 1.90.

Remote: CALC:MATH:MODE LOG

LIN

Activates linear voltage or power averaging, depending on the selected unit.

Linear averaging means that the power level values are converted into linear units prior to

averaging. After the averaging, the data is converted back into its original unit.

The averaging is done in two ways (depending on the set unit – see Unit softkey):

–The unit is set to either W or dBm: the data is converted into W prior to averaging, i.e.

averaging is done in W.

–The unit is set to either V, A, dBmV, dBMV, dBMAor dBpW: the data is converted into V prior to

averaging, i.e. averaging is done in V.

This softkey is available from firmware version 1.90.

Remote: CALC:MATH:MODE LIN

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POWER

Activates linear power averaging.

The power level values are converted into unit Watt prior to averaging. After the averaging, the

data is converted back into its original unit.

Unlike the LIN softkey, the averaging is always done in W.

This softkey is available from firmware version 1.90.

Remote: CALC:MATH:MODE POW

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ASCII file export format

The data of the file header consist of three columns, each separated by a semicolon: parameter name;

numeric value; basic unit. The data section starts with the keyword "Trace <n>" (<n> = number of

stored trace), followed by the measured data in one or several columns (depending on measurement)

which are also separated by a semicolon.

File contents: header Description

Type;FSL; Instrument model

Version;5.00; Firmware version

Date;01.Oct 2006; Date of data set storage

Mode;ANALYZER; Instrument mode

Center Freq;55000;Hz Center frequency

Freq Offset;0;Hz Frequency offset

Span;90000;Hz Frequency range (0 Hz in zero span and statistics measurements)

x–Axis;LIN; Scaling of x–axis linear (LIN) or logarithmic (LOG)

Start;10000;Hz

Stop;100000;Hz

Start/stop of the display range.

Unit: Hz for span > 0, s for span = 0, dBm/dB for statistics measurements

Ref Level;–30;dBm Reference level

Level Offset;0;dB Level offset

Ref Position;75;% Position of reference level referred to diagram limits (0% = lower edge)

y–Axis;LOG; Scaling of y–axis linear (LIN) or logarithmic (LOG)

Level Range;100;dB Display range in y direction. Unit: dB with x–axis LOG, % with x–axis LIN

Rf Att;20;dB Input attenuation

RBW;100000;Hz Resolution bandwidth

VBW;30000;Hz Video bandwidth

SWT;0.005;s Sweep time

Trace Mode;AVERAGE; Display mode of trace: CLR/WRITE,AVERAGE,MAXHOLD,MINHOLD

Detector;AUTOPEAK; Detector set: AUTOPEAK,MAXPEAK,MINPEAK,AVERAGE,RMS,SAMPLE,QUASIPEAK

Sweep Count;20; Number of sweeps set

File contents:

data section of the file

Description

Trace 1:;; Selected trace

x–Unit;Hz; Unit of x values: Hz with span > 0; s with span = 0; dBm/dB with statistics measurements

y–Unit;dBm; Unit of y values: dB*/V/A/W depending on the selected unit with y–axis LOG or % with y–

axis LIN

Values; 501; Number of measurement points

10000;–10.3;–15.7

10180;–11.5;–16.9

10360;–12.0;–17.4

...;...;

Measured values: <x value>, <y1>, <y2>; <y2> being available only with detector

AUTOPEAK and containing in this case the smallest of the two measured values for a

measurement point.

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Measurement Functions

In this section all menus necessary for setting measurement functions are described. This includes the

following topics and keys:

•"Using Markers and Delta Markers – MKR Key" on page 4.53

•"Changing Settings via Markers – MKR–> Key" on page 4.66

•"Power Measurements – MEAS Key" on page 4.75

•"Using Limit Lines and Display Lines – LINES Key" on page 4.118

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Using Markers and Delta Markers – MKR Key

The markers are used for marking points on traces, reading out measurement results and for quickly

selecting a display section. The R&S FSL provides four markers per trace.

M3 T1

Marker

Delta marker

Active marker Temporary marker

Fig. 4-5: Marker types

All markers can be used either as markers or delta markers. The marker that can be moved by the user

is defined in the following as the active marker. Temporary markers are used in addition to the markers

and delta markers to evaluate the measurement results. They disappear when the associated function

is deactivated.

The measurement results of the active marker (also called marker values) are displayed in the marker

field. The marker field is located at the upper right corner of the display and shows the following:

•marker type (M1 in the example)

•trace in square brackets ([1] in the example)

•level (–33.09 dBm in the example)

•marker location (3 GHz in the example)

Fig. 4-6: Marker values

The MKR key is used to select and position the absolute and relative measurement markers (markers

and delta markers). In addition, the functions for frequency counter, fixed reference point for relative

measurement markers and enlargement of the measurement area are assigned to this key.

Also the following measurements can be carried out:

•Noise density (Noise Meas On/Off softkey; see also "Measurement of noise density" on page 4.56)

•Frequency measurement (Sig Count On/Off softkey; see also "Frequency measurement with the

frequency counter" on page 4.56)

•Filter or signal bandwidth (ndB down softkey)

•AF demodulation (Marker Demod softkey; see also "AF demodulation" on page 4.56)

For further information on markers see also "Changing Settings via Markers – MKR–> Key" on page

4.66.

To open the marker menu

Press the MKR key.

The marker menu is displayed. If no marker is active, marker 1 is activated and a peak search on

the trace is carried out. Otherwise, the edit dialog box for the last activated marker is opened and

the current frequency / time value is displayed.

Using Markers and Delta Markers – MKR Key R&S FSL

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Menu and softkey description

–"Softkeys of the marker menu" on page 4.57

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"AF demodulation" on page 4.56

–"Frequency measurement with the frequency counter" on page 4.56

–"Measurement of noise density" on page 4.56

Tasks

–To define the basic marker settings

–To set a fixed reference point (phase noise measurement)

–To set the demodulation mode and duration

R&S FSL Using Markers and Delta Markers – MKR Key

1300.2519.12 4.55 E-11

To define the basic marker settings

1. Press the MKR key to open the marker menu.

Marker 1 is activated and positioned on the maximum value of the trace as normal marker. If

several traces are being displayed, the marker is set to the maximum value (peak) of the trace

which has the lowest number (1 to 3) and is not frozen (View mode). In case a marker is already

located there, it will be set to the frequency of the next lowest level (next peak).

2. To change to another trace, press the Marker to Trace softkey and enter the number of the trace

on which the marker is to be placed.

The marker changes to selected trace, but remains on the previous frequency or time. If a trace is

turned off, the corresponding markers and marker functions are also deactivated.

3. To switch on a delta marker, press the Marker 2 softkey.

Marker 2 is switched on as a delta marker. The frequency and level of marker 2 are displayed in

relation to marker 1 in the marker field.

4. To change the marker type of marker 2, press the /Marker Norm/Delta softkey.

Marker 2 becomes a normal marker. The frequency and level of marker 2 are displayed as absolute

values in the marker field.

5. To switch off marker 2, press the Marker 2 softkey again.

Marker 2 is deactivated. Marker 1 becomes the active marker for entry. The frequency and level of

marker 1 are displayed in the marker field.

To set a fixed reference point (phase noise measurement)

1. Press the Phase Noise/Ref Fixed softkey.

The submenu with the Phase Noise On/Off softkey switched on is displayed. The level and

frequency or time values of marker 1 immediately become the reference point.

2. To set the maximum of the selected trace as reference point, press the Peak Search softkey.

3. To define the values for the reference point, proceed as follows:

–Press the Ref Point Level softkey and enter a reference level value.

–If span > 0, press the Ref Point Frequency softkey and enter a frequency reference value.

–If span = 0, press the Ref Point Time softkey and enter a reference time value.

To set the demodulation mode and duration

1. Press the Marker Demod softkey.

The submenu with the Mkr Demod On/Off softkey switched on is displayed.

2. To change the demodulation mode, press the AM or FM softkey.

For details see "AF demodulation" on page 4.56.

3. To modify the demodulation time for span > 0, press the Mkr Stop Time softkey.

4. To change to continuous demodulation for span > 0, press the Cont Demod softkey.

5. To tune the volume for acoustic monitoring, press the Volume softkey.

Using Markers and Delta Markers – MKR Key R&S FSL

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AF demodulation

The R&S FSL provides demodulators for AM and FM signals. With these demodulators, a displayed

signal can be identified acoustically by using headphones.

CAUTION Risk of hearing damage

Check the volume setting carefully before putting on the headphones in order to

protect your hearing.

For span > 0, the demodulation is not continuous. The frequency at which the demodulation takes place

is set by the active marker. If the level of the selected frequency is above the threshold line, the sweep

stops for the selected time (stop time) and the RF signal is demodulated. For span = 0, the

demodulation is continuously active irrespective of the stop time set.

Frequency measurement with the frequency counter

In order to accurately determine the frequency of a signal, the R&S FSL is equipped with a frequency

counter which measures the frequency of the RF signal at the intermediate frequency. Using the

measured IF, the R&S FSL calculates the frequency of the RF input signal by applying the known

frequency conversion factors.

The frequency measurement uncertainty depends only upon the accuracy of the frequency reference

used (external or internal reference). Although the R&S FSL always operates synchronously

irrespective of the set span, the frequency counter delivers a more exact result than a measurement

performed with a marker. This is due to the following:

•The marker measures only the position of the point on the trace and infers from this value the signal

frequency. The trace, however, contains only a limited number of points. Depending upon the

selected span, each point may contain many measurement values, which therefore limits the

frequency resolution.

•The resolution, with which the frequency can be measured with a marker, is dependant on the

selected resolution bandwidth which in return affects the necessary measurement time. For this

reason, the bandwidth is normally made as wide as possible and the sweep time as short as

possible. This results in a loss of frequency resolution.For the measurement with the frequency

counter, the sweep is stopped at the reference marker, the frequency is counted with the desired

resolution and then the sweep is allowed to continue.

Measurement of noise density

During noise measurement, the noise power density is measured at the position of the marker. For

span = 0, all points of the trace are used to determine the noise power density. For span > 0, two points

to the right and left of the marker are used for the measurement to obtain a stable result.

The noise power density is indicated in the marker field. With logarithmic amplitude units (dBm, dBmV,

dBmMV, dBMA), the noise power density is output in dBm/Hz, i.e. as level in 1 Hz bandwidth with

reference to 1 mW. With linear amplitude units (V, A, W), the noise voltage density is evaluated in

MV/Hz, the noise current density in MA/Hz or the noise power density in MW/Hz.

In the default setting, the R&S FSL uses the sample detector for the noise function.

With the sample detector, the trace can additionally be set to Average to stabilize the measured values.

With RMS detector used, trace averaging must not be used since in this case it produces too low noise

levels which cannot be corrected. Instead, the sweep time can be increased to obtain stable

measurement results.

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The following settings have to be made to ensure that the power density measurement yields correct

values:

•Detector: Sample or RMS

•Video bandwidth:



0.1 resolution bandwidth with sample detector



3 x resolution bandwidth with RMS detector

•Trace averaging:

With the sample detector, the trace can additionally be set to average to stabilize the measured

values. With RMS detector used, trace averaging must not be used since in this case it produces

too low noise levels which cannot be corrected. Instead, the sweep time can be increased to obtain

stable measurement results.

The R&S FSL uses the following correction factors to evaluate the noise density from the marker level:

•Since the noise power is indicated with reference to 1 Hz bandwidth, the bandwidth correction value

is deducted from the marker level. It is 10 x lg (1 Hz/BWNoise), where BWNoise is the noise or

power bandwidth of the set resolution filter (RBW).

•RMS detector: With the exception of bandwidth correction, no further corrections are required since

this detector already indicates the power with every point of the trace.

•Sample detector: As a result of video filter averaging and trace averaging, 1.05 dB is added to the

marker level. This is the difference between the average value and the RMS value of white noise.

With a logarithmic level axis, 1.45 dB is added additionally. Logarithmic averaging is thus fully taken

into account which yields a value that is 1.45 dB lower than that of linear averaging.

•To allow a more stable noise display the adjacent (symmetric to the measurement frequency) points

of the trace are averaged.

•For span > 0, the measured values are averaged versus time (after a sweep).

Note: The R&S FSL noise figure can be calculated from the measured power density level. It is

calculated by deducting the set RF attenuation (RF Att) from the displayed noise level and

adding 174 to the result.

Softkeys of the marker menu

The following table shows all softkeys available in the marker menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

If the Spectrogram Measurement option (K14) is activated, the edit dialog box for markers and delta

markers is extended. For details refer to "Markers and marker values" on page 4.193.

Menu / Command Submenu / Command Command

Marker 1

Marker 2

Marker Norm/Delta

Noise Meas On/Off

Phase Noise/Ref Fixed Phase Noise On/Off

Ref Point Level

Ref Point Frequency/

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Menu / Command Submenu / Command Command

Ref Point Time

Peak Search

Phase Noise 1 2 3 4



Reference Fixed Reference Fixed On/Off

Ref Point Level

Ref Point Frequency/

Ref Point Time

Peak Search

Sig Count On/Off

More 

Marker 3

Marker 4

Marker to Trace

Marker Demod Mkr Demod On/Off

Mkr Stop Time

Cont Demod

Volume

ndB down

All Marker Off

More 

Marker Zoom

Marker Peak List New Search

Sort Mode Freq/Lvl

Peak Excursion

Left Limit

Right Limit

Threshold

More 

Peak List Off

Threshold

ASCII File Export

Decim Sep

Marker Stepsize Stepsize Standard

Stepsize Sweep Points

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Marker 1/Marker 2/Marker 3/Marker 4/Marker Norm/Delta

The Marker <no> softkey activates the corresponding marker and opens an edit dialog box to

enter a value for the marker to be set to. Pressing the softkey again deactivates the selected

marker.

If a marker value is changed using the rotary knob, the step size is defined via the Stepsize

Standard or Stepsize Sweep Points softkeys.

Marker 1 is always the reference marker for relative measurements. If activated, markers 2 to 4

are delta markers that refer to marker 1. These markers can be converted into markers with

absolute value display by means of the Marker Norm/Delta softkey. If marker 1 is the active

marker, pressing the Marker Norm/Delta softkey switches on an additional delta marker.

Remote: CALC:MARK ON

Remote: CALC:MARK:X <value>

Remote: CALC:MARK:Y?

Remote: CALC:DELT ON

Remote: CALC:DELT:X <value>

Remote: CALC:DELT:X:REL?

Remote: CALC:DELT:Y?

Noise Meas On/Off

Switches the noise measurement for the active marker on or off. The corresponding marker

becomes the normal marker. For more details on noise measurement see "Measurement of

noise density" on page 4.56.

Remote: CALC:MARK:FUNC:NOIS ON

Remote: CALC:MARK:FUNC:NOIS:RES?

Phase Noise/Ref Fixed

The function of this softkey depends on the setting of the Noise Meas softkey:

–Noise Meas On:activates phase noise measurements.

–Noise Meas Off:freezes the current position of marker 1 as a reference for relative

measurements. Additionally it opens a submenu to set all values of a reference point.Instead of

using the current values of the reference marker (marker 1) as reference point for the delta

markers, level and frequency or time are set to fixed values and used as reference point.

Phase Noise On/Off

Switches the relative measurement to a fixed reference value on or off. The level and frequency

or time values of marker 1 immediately become the reference point, but can be altered using the

corresponding softkeys (Ref Point Level,Ref Point Frequency,Ref Point Time and Peak

Search).

Remote: CALC:DELT2:FUNC:FIX ON

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Ref Point Level

Opens an edit dialog box to enter a reference level value. All relative level values of the delta

markers refer to this reference level.

Remote: CALC:DELT2:FUNC:FIX:RPO:Y –10dBm

Ref Point Frequency (span > 0) / Ref Point Time (zero span)

Opens an edit dialog box to enter a frequency reference or time value. All relative frequency or

time values of the delta markers refer to this frequency reference. For phase noise

measurement, input of reference time is not possible..

Remote: CALC:DELT2:FUNC:FIX:RPO:X 10.7MHz

Remote: CALC:DELT2:FUNC:FIX:RPO:X 5MS

Peak Search

Sets the maximum value of the selected trace as the reference point.

Remote: CALC:DELT:FUNC:FIX:RPO:MAX

Phase Noise 1 2 3 4



Selects the normal marker or the delta markers, activates the marker and opens an edit dialog

box to enter a value for the marker to be set to.



stands for delta marker 1.

Reference Fixed

Opens a submenu for relative measurement to a fixed reference value.

Reference Fixed On/Off

Switches the relative measurement to a fixed reference value on or off. The level and frequency

or time values of marker 1 immediately become the reference point, but can be altered using the

corresponding softkeys (Ref Point Level,Ref Point Frequency,Ref Point Time and Peak

Search).

Remote: CALC:DELT2:FUNC:FIX ON

Sig Count On/Off

Switches the frequency counter on/off. The frequency is counted at the position of the reference

marker (marker 1). If no marker is activated, marker 1 is switched on and set at the largest

signal.

The sweep stops at the reference marker until the frequency counter has delivered a result. The

result is displayed in the marker field (see "Fig. 4-6: Marker values"on page 4.53), labeled with

[Tx CNT]. For more details see "Frequency measurement with the frequency counter" on page

4.56.

Remote: CALC:MARK1:COUN ON

Remote: CALC:MARK:COUN:FREQ?

R&S FSL Using Markers and Delta Markers – MKR Key

1300.2519.12 4.61 E-11

Marker to Trace

Opens an edit dialog box to enter the number of the trace, on which the marker is to be placed.

Remote: CALC:MARK1:TRAC 1

Remote: CALC:DELT:TRAC 1

Marker Demod

Opens a submenu to set the demodulation mode and duration. For more details see also "AF

demodulation" on page 4.56.

Mkr Demod On/Off

Switches the demodulation on/off. For more details see also "AF demodulation" on page 4.56.

Remote: CALC:MARK1:FUNC:DEM ON

Sets AM as demodulation mode. This is the default setting. For more details see also "AF

demodulation" on page 4.56.

Remote: CALC:MARK1:FUNC:DEM:SEL AM

Sets FM as demodulation mode. Default setting is AM. For more details see also "AF

demodulation" on page 4.56.

Remote: CALC:MARK1:FUNC:DEM:SEL FM

Mkr Stop Time

Opens an edit dialog box to enter the demodulation stop time for span > 0. For more details see

also "AF demodulation" on page 4.56.

Remote: CALC:MARK1:FUNC:DEM:HOLD 3s

Cont Demod (span > 0)

Switches the continuous demodulation on or off. If the sweep time is long enough, the set

frequency range can be monitored acoustically. For more details see also "AF demodulation" on

page 4.56.

Remote: CALC:MARK1:FUNC:DEM:CONT ON

Volume

Opens an edit dialog box to regulate the volume for acoustic monitoring. For more details see

also "AF demodulation" on page 4.56.

Remote: SYST:SPE:VOL 0.5

Using Markers and Delta Markers – MKR Key R&S FSL

1300.2519.12 4.62 E-11

ndB down

Opens an edit dialog box to enter a value to define the level spacing of the two temporary

markers to the right and left of marker 1 (default setting: 3 dB). Activates the temporary markers

T1 and T2. The values of the temporary markers (T1, T2) and the entered value (ndB) are

displayed in the marker field.

If a positive value is entered, the markers T1 and T2 are placed below the active reference

marker. If a negative value (e.g. for notch filter measurements) is entered, the markers T1 and

T2 are placed above the active reference marker. Marker T1 is placed to the left and marker T2

to the right of the reference marker.

In the marker field, the following results are displayed:

Span setting Parameter name Description

span > 0 Bw frequency spacing of the two temporary markers

Qfactor quality of the displayed bandwidth value (Bw)

span = 0 PWid pulse width between the two temporary markers

If it is not possible to form the frequency spacing for the n dB value (e.g. because of noise

display), dashes instead of a measured value are displayed.

Remote: CALC:MARK1:FUNC:NDBD:STAT ON

Remote: CALC:MARK1:FUNC:NDBD 3dB

Remote: CALC:MARK1:FUNC:NDBD:RES?

Remote: CALC:MARK:FUNC:NDBD:QFAC?

Remote: CALC:MARK1:FUNC:NDBD:FREQ? (span > 0)

Remote: CALC:MARK1:FUNC:NDBD:TIME? (span = 0)

All Marker Off

Switches all markers off.

Remote: CALC:MARK:AOFF

Marker Zoom (span > 0)

Opens an edit dialog box to enter a display range for the zoom. The area around marker 1 is

expanded accordingly and more details of the spectrum can be seen. If no marker is activated,

marker 1 is switched on and set on the largest signal..

The following sweep is stopped at the position of the reference marker. The frequency of the

signal is counted and the measured frequency becomes the new center frequency. The zoomed

display range is then configured and the new settings are used by the R&S FSL for further

measurements.

As long as switching to the new frequency display range has not yet taken place, pressing the

softkey will abort the procedure. If an instrument setting is changed while using this function, the

procedure is aborted.

Remote: CALC:MARK1:FUNC:ZOOM 1kHz

R&S FSL Using Markers and Delta Markers – MKR Key

1300.2519.12 4.63 E-11

Marker Peak List

Opens the Peak List dialog box and a submenu to define criterias for the sort order and the

contents of the peak list. The number of listed peaks is indicated in the title bar. For all listed

peaks the frequency and level values are given. Maximal 50 entries are listed.

This softkey is available from firmware version 1.30.

Remote: CALC:MARK:FUNC:FPE:COUN?

Remote: CALC:MARK:FUNC:FPE:X?

Remote: CALC:MARK:FUNC:FPE:Y?

New Search

Starts a new peak search and enters the results in the peak list.

This softkey is available from firmware version 1.30.

Remote: CALC:MARK:FUNC:FPE 3

Sort Mode Freq/Lvl

Defines the criteria for sorting:

Freq sorting in ascending order of frequency values (span > 0) or time

values (span = 0)

Lvl sorting in ascending order of the level

This softkey is available from firmware version 1.30.

Remote: CALC:MARK:FUNC:FPE:SORT Y

Peak List Off

Switches the peak list function off.

This softkey is available from firmware version 1.30.

Using Markers and Delta Markers – MKR Key R&S FSL

1300.2519.12 4.64 E-11

ASCII File Export

Opens the ASCII File Export Name dialog box and saves the content of the marker peak list in

ASCII format to the specified file and directory. The file consists of a data section containing the

peak list.

Example:

Peak;1

1089743590;Hz

–105.24;dBm

...

This format can be processed by spreadsheet calculation programs, e.g. MS Excel. It is

necessary to define ';' as a separator for the data import. Different language versions of

evaluation programs may require a different handling of the decimal point. It is therefore possible

to select between separators '.' (decimal point) and ',' (comma) using the Decim Sep softkey.

This softkey is available from firmware version 1.80.

Remote: FORM ASC

Remote: MMEM:STOR:PEAK 'test'

Decim Sep

For details refer to the Decim Sep softkey in the trace menu of the base unit.

This softkey is available from firmware version 1.80.

Marker Stepsize

Opens a submenu to set the step size of all markers and delta markers.

This softkey is available from firmware version 1.60.

Stepsize Standard

Moves the marker or delta marker from one measurement point to the next, if the marker or

delta marker value is changed via the rotary knob (Marker 1/Marker 2/Marker 3/Marker 4

softkeys). If more measured values than measurement points exist, it is not possible to read out

all measured values. In this case, use the Stepsize Sweep Points softkey.

This softkey is available from firmware version 1.60.

Remote: CALC:MARK:X:SSIZ STAN

R&S FSL Using Markers and Delta Markers – MKR Key

1300.2519.12 4.65 E-11

Stepsize Sweep Points

Moves the marker or delta marker from one measured value to the next, if the marker or delta

marker value is changed via the rotary knob (Marker 1/Marker 2/Marker 3/Marker 4 softkeys). If

more measured values than measurement points exist, every single measured value is

accessible and its value is displayed in the marker field.

The number of measured values is defined in the sweep menu via the Sweep Points softkey.

This functionality is available for all base unit measurements with the exception of statistics

(APD and CCDF softkeys in the measurement menu).

This softkey is available from firmware version 1.60.

Remote: CALC:MARK:X:SSIZ POIN

Changing Settings via Markers – MKR–> Key R&S FSL

1300.2519.12 4.66 E-11

Changing Settings via Markers – MKR–> Key

The MKR–> key is used for search functions of measurement markers, assignment of the marker

frequency as center frequency, restriction of the search area and characterization of maxima and

minima. For details on markers in general, see "Using Markers and Delta Markers – MKR Key" on page

4.53.

To open the marker–> menu

Press the MKR–> key.

The marker–> menu is displayed. If no marker is active, marker 1 will be activated and a peak

search on the trace carried out. Otherwise, the edit dialog box for the last activated marker is

opened and the current frequency / time value is displayed.

Menu and softkey description

–"Softkeys of the marker–> menu" on page 4.70

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"Effect of different peak excursion settings (example)" on page 4.68

Tasks

–To search for a maximum

–To search for a minimum

–To specify the search limits

–To specify the search range

–To examine a signal at the center in detail

–To specify the suitable peak excursion

R&S FSL Changing Settings via Markers – MKR–> Key

1300.2519.12 4.67 E-11

To search for a maximum

1. To search the highest maximum, press the Peak softkey.

2. To define the search mode for the next maximum, use the Next Peak Mode < abs > softkey.

3. To start the search, press Next Peak the softkey.

To search for a minimum

1. To search the minimum, press the Min softkey.

2. To define the search mode for the next maximum, use the Next Min Mode < abs > softkey.

3. To start the search, press the Next Min softkey.

To specify the search limits

1. To define the lower limit, press the Left Limit softkey.

2. To define the upper limit, press the Right Limit softkey.

3. To define the threshold, press the Threshold softkey.

4. To switch the search limits off, press the Search Lim Off softkey.

To specify the search range

Press the Exclude LO softkey to include the frequency 0 Hz in the marker search functions.

To examine a signal at the center in detail

1. Press the PRESET key to set the R&S FSL to the default setting.

2. Press the MKR–> key to open the marker–> menu.

3. Marker 1 is activated and set to the largest signal of the trace.

4. Press the Center =Mkr Freq softkey to set to the marker frequency.

5. The span is adapted in such a way that the minimum frequency (= 0 Hz) or the maximum frequency

is not exceeded.

6. Press the Ref Lvl =Mkr Lvl softkey to set the reference level to the measured marker level.

7. Press the SPAN key.

8. The edit dialog box to enter a frequency span is displayed.

9. Reduce the span, e.g. using the rotary knob.

To specify the suitable peak excursion

1. If the next peak mode abs of softkey Next Peak Mode < abs > / Next Min Mode < abs > is used,

the default value is sufficient, since, in this mode, the next lower maximum or next higher minimum

will always be detected.

2. If the next peak mode <or >of softkey Next Peak Mode < abs > / Next Min Mode < abs > is used,

the 6 dB level change set as a default value may be attained already by the inherent noise of the

instrument. To avoid identifying noise peaks as maxima or minima, enter a peak excursion value

that is higher than the difference between the highest and the lowest value measured for the

displayed inherent noise.

Changing Settings via Markers – MKR–> Key R&S FSL

1300.2519.12 4.68 E-11

Effect of different peak excursion settings (example)

The following figure shows a trace to be examined.

Fig. 4-7: Trace example

The following table lists the signals as indicated by the marker numbers in the diagram above, as well

as the minimum of the amplitude decrease to both sides of the signal:

signal # min. amplitude decrease to both sides of the signal

1 30 dB

229.85 dB

3 7 dB

4 7 dB

The detected signals and their order are different depending on the peak excursion setting and the peak

search method (whether the next lower maximum or the next relative maximum are searched). The

following results are obtained. All tests start with the marker set to signal 1 by pressing the softkey

Peak.

R&S FSL Changing Settings via Markers – MKR–> Key

1300.2519.12 4.69 E-11

•40 dB peak excursion

Result: With both methods apart from signal 1 no signal is detected, as the signal level does not

decrease by more than 30 dB to either side of any signal.

next lower maximum next relative maximum

next peak mode abs:signal 1

(no further signal detected)

next peak mode <:signal 1

(no further signal detected)

next peak mode >:signal 1

(no further signal detected)

•20 dB peak excursion

Result: With both methods apart from signal 1 signal 2 is detected, as the signal level decreases at

least by 29.85 dB to either side of this signal, which is now greater than the peak excursion.

next lower maximum next relative maximum

next peak mode abs:signal 2 next peak mode <:signal 1

(no further signal detected)

next peak mode abs:signal 2

(no further signal detected)

next peak mode >:signal 2

(no further signal detected)

•6dB peak excursion

Result: With both methods all signals are detected.

next lower maximum next relative maximum

next peak mode abs:signal 2 next peak mode <:signal 3

next peak mode abs:signal 3 next peak mode >:signal 1

next peak mode abs:signal 4 next peak mode >:signal 2

next peak mode >:signal 4

Changing Settings via Markers – MKR–> Key R&S FSL

1300.2519.12 4.70 E-11

Softkeys of the marker–> menu

The following table shows all softkeys available in the marker–> menu. It is possible that your

instrument configuration does not provide all softkeys. If a softkey is only available with a special option,

model or (measurement) mode, this information is delivered in the corresponding softkey description.

If the Spectrogram Measurement option (K14) is activated, this menu provides additional functionality.

For details refer to "Softkeys of the marker–> menu (Spectrogram view)" on page 4.197.

Menu / Command Command

Select 1 2 3 4



Peak

Next Peak

Next Peak Mode < abs >

Center =Mkr Freq

Ref Lvl =Mkr Lvl

More 

Select 1 2 3 4



Min

Next Min

Next Min Mode < abs >

Search Limits Left Limit

Right Limit

Threshold

Search Lim Off

Peak Excursion

More 

Exclude LO

Auto Max Peak/Auto Min Peak

Select 1 2 3 4



Selects the normal marker or the delta markers, activates the marker and opens an edit dialog

box to enter a value for the marker to be set to.



stands for delta marker 1.

If the Spectrogram Measurement option (K14) is activated, the edit dialog box for markers and

delta markers is extended. For details refer to "Markers and marker values" on page 4.193.

Remote: CALC:MARK1 ON

Remote: CALC:MARK1:X <value>

Remote: CALC:MARK1:Y?

R&S FSL Changing Settings via Markers – MKR–> Key

1300.2519.12 4.71 E-11

Peak

Sets the active marker/delta marker to the highest maximum of the trace.

If the Spectrogram Measurement option (K14) is activated, this softkey provides altered

functionality. For details refer to Peak softkey in the marker–> menu of this option.

Remote: CALC:MARK:MAX

Remote: CALC:DELT:MAX

Next Peak

Sets the active marker/delta marker to the next maximum of the selected trace according to the

mode selected using the Next Peak Mode < abs > softkey.

If the Spectrogram Measurement option (K14) is activated, this softkey provides altered

functionality. For details refer to Next Peak softkey in the marker–> menu of this option.

Next Peak Mode < abs >

Selects the mode of the Next Peak softkey. Three settings are available:

<Sets the active marker/delta marker to the next maximum left to the marker of the

selected trace.

abs Sets the active marker/delta marker to the next lower maximum of the selected

trace.

>Sets the active marker/delta marker to the next maximum right to the marker of the

selected trace.

If the Spectrogram Measurement option (K14) is activated, this softkey provides altered

functionality. For details refer to Next Peak X Search < abs > and Next Peak Y Search

up/abs/dn softkeys in the marker–> menu of this option.

Remote: CALC:MARK:MAX:LEFT (>)

Remote: CALC:DELT:MAX:LEFT (<)

Remote: CALC:MARK:MAX:RIGH (>)

Remote: CALC:DELT:MAX:RIGH (>)

Remote: CALC:MARK:MAX:NEXT (abs)

Remote: CALC:DELT:MAX:NEXT (abs)

Center =Mkr Freq (span > 0)

Sets the center frequency to the current marker or delta marker frequency. A signal can thus be

set to as center frequency, for example to examine it in detail with a smaller span.

Remote: CALC:MARK:FUNC:CENT

Ref Lvl =Mkr Lvl

Sets the reference level to the current marker level.

Remote: CALC:MARK:FUNC:REF

Changing Settings via Markers – MKR–> Key R&S FSL

1300.2519.12 4.72 E-11

Min

Sets the active marker/delta marker to the minimum of the selected trace.

If the Spectrogram Measurement option (K14) is activated, this softkey provides altered

functionality. For details refer to Min softkey in the marker–> menu of this option.

Remote: CALC:MARK:MIN

Remote: CALC:DELT:MIN

Next Min

Sets the active marker/delta marker to the next minimum of the selected trace according to the

mode selected using the Next Min Mode < abs > softkey.

If the Spectrogram Measurement option (K14) is activated, this softkey provides altered

functionality. For details refer to Next Min softkey in the marker–> menu of this option.

Remote: CALC:MARK:MIN:NEXT

Remote: CALC:DELT:MIN:NEXT

Next Min Mode < abs >

Selects the mode of the Next Min softkey. Three settings are available:

<Sets the active marker/delta marker to the next minimum left to the marker of the

selected trace.

abs Sets the active marker/delta marker to the next higher minimum of the selected

trace.

>Sets the active marker/delta marker to the next minimum right to the marker of the

selected trace.

If the Spectrogram Measurement option (K14) is activated, this softkey provides altered

functionality. For details refer to Next Min X Search < abs > and Next Min Y Search up/abs/dn

softkeys in the marker–> menu of this option.

Remote: CALC:MARK:MAX:LEFT

Remote: CALC:DELT:MAX:LEFT

Search Limits

Opens a submenu to set the limits for maximum or minimum search in the x and y direction.

Remote: CALC:MARK:X:SLIM ON

Left Limit

Opens an edit dialog box to enter a value for the lower limit (left vertical line: S1 for span > 0; T1

for zero span). The search is performed between the lines of the left and right limit (see also

Right Limit softkey).

Remote: CALC:MARK:X:SLIM:LEFT 1MHZ

R&S FSL Changing Settings via Markers – MKR–> Key

1300.2519.12 4.73 E-11

Right Limit

Opens an edit dialog box to enter a value for the upper limit (left vertical line: S2 for span > 0; T2

for zero span). The search is performed between the lines of the left and right limit (see also Left

Limit softkey). If no value is set, the upper limit corresponds to the stop frequency.

Remote: CALC:MARK:X:SLIM:RIGH 10MHZ

Threshold

Opens an edit dialog box to define the threshold line. The threshold line represents the lower

level limit for a Peak search and the upper level limit for a Min search.

Opens an edit dialog box to define the threshold line. The threshold line represents the lower

limit of the peak search level range.

Remote: CALC:THR –20dBm

Remote: CALC:THR ON

Search Lim Off

Deactivates all limits of the search range.

Remote: CALC:MARK:X:SLIM OFF

Remote: CALC:THR:STAT OFF

Peak Excursion

Opens – for level measurements – an edit dialog box to enter the minimum level value by which

asignal must rise or fall so that it will be identified as a maximum or a minimum by the search

functions. Entries from 0 dB to 80 dB are allowed; the resolution is 0.1 dB. The default setting for

the peak excursion is 6 dB.

For details see also "To specify the suitable peak excursion" on page 4.67 and "Effect of

different peak excursion settings (example)" on page 4.68.

Remote: CALC:MARK:PEXC 10dB

Exclude LO

Switches the frequency range limit for the marker search functions on or off.

activated minimum frequency



6×resolution bandwidth (RBW)

Because of the interference by the first local oscillator to the first

intermediate frequency at the input mixer, the LO is represented as a

signal at 0 Hz. To avoid the marker jumping to the LO at 0 Hz with the

peak function when setting the display range, this frequency is

excluded.

deactivated no restriction to the search range. The frequency 0 Hz is included in

the marker search functions.

Remote: CALC:MARK:LOEX ON

Changing Settings via Markers – MKR–> Key R&S FSL

1300.2519.12 4.74 E-11

Auto Max Peak / Auto Min Peak

Adds an automatic peak search action for marker 1 at the end of each particular sweep. This

function may be used during adjustments of a device under test to keep track of the actual peak

marker position and level.

The actual marker search limit settings (Left Limit,Right Limit,Threshold,Exclude LO

softkeys) are taken into account.

This softkey is available from firmware version 1.50.

Remote: CALC:MARK:MIN:AUTO ON

Remote: CALC:MARK:MAX:AUTO ON

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.75 E-11

Power Measurements – MEAS Key

With its power measurement functions, the R&S FSL is able to measure all the necessary parameters

with high accuracy in a wide dynamic range.

Amodulated carrier is almost always used (except e.g. SSB–AM) for high–frequency transmission of

information. Due to the information modulated upon the carrier, the latter covers a spectrum which is

defined by the modulation, the transmission data rate and the signal filtering. Within a transmission

band each carrier is assigned a channel taking into account these parameters. In order to ensure error–

free transmission, each transmitter must be conforming to the specified parameters. These include

among others:

•the output power

•the occupied bandwidth, i.e. the bandwidth which must contain a defined percentage of the power

•the power dissipation allowed in the adjacent channels

The MEAS key is used for complex measurement functions as power measurements, occupied

bandwidth, signal statistic, carrier to noise spacing, AM modulation depth, third–order intercept point,

harmonics and spurious emissions. For measurement examples refer to chapter "Advanced

Measurement Examples" and to the Quick Start Guide, chapter 5, "Basic Measurement Examples".

The following measurements can be performed:

•Power in zero span (Time Domain Power softkey; for details see "Power measurement in zero

span" on page 4.78)

•Channel power and adjacent–channel power with span > 0 and with a single or several carriers

(CP, ACP, MC–ACP softkey)

•Occupied bandwidth (OBW softkey, for details see "Measurement of occupied bandwidth"on page

4.78)

•Carrier–to–noise ratio (C/N, C/No softkey)

•Amplitude probability distribution (APD and CCDF softkeys, for details refer to hapter "Advanced

Measurement Examples", "Amplitude Distribution Measurement")

•Modulation depth (AM Mod Depth softkey)

•3rd order intercept (TOI softkey, for details refer to chapter "Advanced Measurement Examples",

"Intermodulation Measurements")

To open the power measurement menu

Press the MEAS key.

The power measurement menu is displayed.

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.76 E-11

Menu and softkey description

–"Softkeys of the power measurement menu" on page 4.88

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"Power measurement in zero span" on page 4.78

–"Measurement of occupied bandwidth" on page 4.78

–"Predefined CP / ACP standards" on page 4.79

–"Settings of CP / ACP test parameters" on page 4.80

–"Ranges and range settings"on page 4.81

–"Provided XML files for the Spectrum Emission Mask measurement" on page 4.82

–"Format description of Spectrum Emission Mask XML files" on page 4.83

–"ASCII file export format (Spectrum Emission Mask)" on page 4.88

Tasks

–To measure the power in zero span

–To set the channel configuration

–To measure the occupied bandwidth

–To measure signal statistics

–To measure the carrier–to–noise ratio

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.77 E-11

To measure the power in zero span

1. Press the Time Domain Power softkey to activate the power measurement.

The corresponding submenu is displayed.

2. To limit the power evaluation range, switch on the limits (Limits On/Off softkey) and enter the limits

by using the Left Limit and Right Limit softkeys.

3. Select the type of power measurement by using the Mean or RMS softkey. (RMS or mean power),

the settings for max hold and averaging as well as the definition of limits.

4. To calculate and display the peak value, press the Peak softkey.

5. To calculate and display the standard deviation from the mean value, press the Std Dev softkey.

To set the channel configuration

1. Press the CP, ACP, MC–ACP softkey to active channel or adjacent–channel power measurement.

The corresponding submenu is displayed.

2. To use a predefined standard for measurement, press the CP / ACP Standard softkey (for details

on available standards see "Predefined CP / ACP standards" on page 4.79).

3. To configure the parameters independently of the predefined standards, press the CP / ACP

Config softkey (for details see "Settings of CP / ACP test parameters" on page 4.80).

4. To enter the sweep time, press the Sweep Time softkey.

5. To display the whole diagram, press the Full Size Diagram softkey.

6. To adjust the reference level to the measured channel power, press the Adjust Ref Level softkey.

To measure the occupied bandwidth

1. Press the OBW softkey to activate the measurement of the occupied bandwidth (for details see also

"Measurement of occupied bandwidth" on page 4.78).

The corresponding submenu is displayed.

2. Press the %Power Bandwidth softkey to enter the percentage of power.

3. To change the channel bandwidth for the transmission channel, press the Channel Bandwidth

softkey.

4. To optimize the settings for the selected channel configuration, press the Adjust Settings softkey

(for details see also "Settings of CP / ACP test parameters" on page 4.80).

5. To adjust the reference level to the measured total power after the first sweep, press the Adjust

Ref Level softkey.

To measure signal statistics

•To activate and configure the measurement of the amplitude probability distribution (APD), press

the APD softkey (for details refer to chapter "Advanced Measurement Examples", "Amplitude

Distribution Measurement").

The corresponding submenu is displayed.

•To activate and configure the measurement of the complementary cumulative distribution (CCDF),

press the CCDF softkey (for details refer to hapter "Advanced Measurement Examples", "Amplitude

Distribution Measurement").

The corresponding submenu is displayed.

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.78 E-11

To measure the carrier–to–noise ratio

1. Press the C/N, C/No softkey to configure the carrier–to–noise ratio measurement.

The corresponding submenu is displayed.

2. To activate the measurements without reference to the bandwidth, press the C/N softkey.

3. To activate the measurements with reference to the bandwidth, press the C/No softkey.

4. To change the channel bandwidth for the transmission channel, press the Channel Bandwidth

softkey.

5. To optimize the settings for the selected channel configuration, press the Adjust Settings softkey

(for details see also "Settings of CP / ACP test parameters" on page 4.80).

Power measurement in zero span

With the aid of the power measurement function, the R&S FSL determines the power of the signal in

zero span by summing up the power at the individual measurement points and dividing the result by the

number of measurement points. In this way it is possible to measure for example the power of TDMA

signals during transmission or during the muting phase. Both the mean power and the RMS power can

be measured by means of the individual power values.

The result is displayed in the marker field. The measured values are updated after each sweep or

averaged over a user–defined number of sweeps in order to determine e.g. the mean power over

several bursts. For determination of the peak value the maximum value from several sweeps is

displayed.

If both the on and off phase of a burst signal are displayed, the measurement range can be limited to

the transmission or to the muting phase with the aid of vertical lines. The ratio between signal and noise

power of a TDMA signal for instance can be measured by using a measurement as a reference value

and after that varying the measurement range.

Upon switching on power measurement the sample detector is activated.

Measurement of occupied bandwidth

An important characteristic of a modulated signal is its occupied bandwidth. In a radio communications

system for instance the occupied bandwidth must be limited to enable distortion–free transmission in

adjacent channels. The occupied bandwidth is defined as the bandwidth containing a defined

percentage of the total transmitted power. A percentage between 10% and 99.9% can be set.

The measurement principle is the following: The bandwidth containing 99% of the signal power is to be

determined, for example. The routine first calculates the total power of all displayed points of the trace.

In the next step, the points from the right edge of the trace are summed up until 0.5% of the total power

is reached. Auxiliary marker 1 is positioned at the corresponding frequency. Then the points from the

left edge of the trace are summed up until 0.5% of the power is reached. Auxiliary marker 2 is

positioned at this point. 99% of the power is now between the two markers. The distance between the

two frequency markers is the occupied bandwidth which is displayed in the marker field.

To ensure correct power measurement, especially for noise signals, and to obtain the correct occupied

bandwidth, the following prerequisites and settings are necessary:

•Only the signal to be measured is displayed on the screen. An additional signal would falsify the

measurement.

•RBW << occupied bandwidth

(approx. 1/20 of occupied bandwidth, for voice communication type 300 Hz or 1 kHz)

•VBW



3 x RBW

•RMS detector

•Span



2to 3 x occupied bandwidth

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Some of the measurement specifications (e.g. PDC, RCR STD–27B) require measurement of the

occupied bandwidth using a peak detector. The detector setting of the R&S FSL has to be changed

accordingly then.

Predefined CP / ACP standards

The test parameters for the channel and adjacent–channel measurements are set according to the

mobile radio standard. The available standards are listed below.

Parameter Standard

CDMA2000 CDMA 2000

CDMA IS95A FWD CDMA IS95A forward

CDMA IS95A REV CDMA IS95A reverse

CDMA IS95C Class 0 FWD CDMA IS95C Class 0 forward

CDMA IS95C Class 0 REV CDMA IS95C Class 0 reverse

CDMA IS95C Class 1 FWD CDMA IS95C Class 1 forward

CDMA IS95C Class 1 REV CDMA IS95C Class 1 reverse

CDMA J–STD008 FWD CDMA J–STD008 forward

CDMA J–STD008 REV CDMA J–STD008 reverse

CDPD CDPD

NADC IS136 NADC IS136

PDC PDC

PHS PHS

RFID 14443 RFID 14443

TD–SCDMA FWD TD–SCDMA forward

TD–SCDMA REV TD–SCDMA reverse

TETRA TETRA

W–CDMA 3GPP FWD W–CDMA 3.84 MHz forward

W–CDMA 3GPP REV W–CDMA 3.84 MHz reverse

WIBRO WIBRO

WiMAX WiMAX

WLAN 802.11A WLAN 802.11A

WLAN 802.11B WLAN 802.11B

Note: For the R&S FSL, the channel spacing is defined as the distance between the center frequency

of the adjacent channel and the center frequency of the transmission channel. The definition of

the adjacent–channel spacing in standards IS95 B / C, IS97 B / C, IS98 B / C and CDMA2000

DS / MC1 / MC3 is different. These standards define the adjacent–channel spacing from the

center of the transmission channel to the closest border of the adjacent channel. This definition

is also used for the R&S FSL if the standard settings marked with a dagger are selected.

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Settings of CP / ACP test parameters

•Frequency span

The frequency span must at least cover the channels to be measured plus a measurement margin

of approx. 10%.

Note: If the frequency span is large in comparison to the channel bandwidth (or the adjacent–channel

bandwidths) being examined, only a few points on the trace are available per channel. This

reduces the accuracy of the waveform calculation for the channel filter used, which has a

negative effect on the measurement accuracy. It is therefore strongly recommended that the

formulas mentioned be taken into consideration when selecting the frequency span.

For channel power measurements the Adjust Settings softkey sets the frequency span as follows:

(No. of transmission channels – 1) x transmission channel spacing + 2 x transmission channel

bandwidth + measurement margin

For adjacent–channel power measurements, the Adjust Settings softkey sets the frequency span

as a function of the number of transmission channels, the transmission channel spacing, the

adjacent–channel spacing, and the bandwidth of one of adjacent–channels ADJ, ALT1 or ALT2,

whichever is furthest away from the transmission channels:

(No. of transmission channels – 1) x transmission channel spacing + 2 x (adjacent–channel

spacing + adjacent–channel bandwidth) + measurement margin

The measurement margin is approx. 10% of the value obtained by adding the channel spacing and

the channel bandwidth.

•Resolution bandwidth (RBW)

To ensure both, acceptable measurement speed and required selection (to suppress spectral

components outside the channel to be measured, especially of the adjacent channels), the

resolution bandwidth must not be selected too small or too large. As a general approach, the

resolution bandwidth is to be set to values between 1% and 4% of the channel bandwidth.

Alarger resolution bandwidth can be selected if the spectrum within the channel to be measured

and around it has a flat characteristic. In the standard setting, e.g. for standard IS95A REV at an

adjacent channel bandwidth of 30 kHz, a resolution bandwidth of 30 kHz is used. This yields correct

results since the spectrum in the neighborhood of the adjacent channels normally has a constant

level. For standard NADC/IS136 this is not possible for example, since the spectrum of the transmit

signal penetrates into the adjacent channels and a too large resolution bandwidth causes a too low

selection of the channel filter. The adjacent–channel power would thus be measured too high.

With the exception of the IS95 CDMA standards, the Adjust Settings softkey sets the resolution

bandwidth (RBW) as a function of the channel bandwidth:

RBW



1/40 of channel bandwidth

The maximum possible resolution bandwidth (with respect to the requirement RBW



1/40)

resulting from the available RBW steps (1, 3) is selected.

•Video bandwidth (VBW)

For a correct power measurement, the video signal must not be limited in bandwidth. A restricted

bandwidth of the logarithmic video signal would cause signal averaging and thus result in a too low

indication of the power (–2.51 dB at very low video bandwidths). The video bandwidth should

therefore be selected at least three times the resolution bandwidth:

VBW



3 x RBW

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The Adjust Settings softkey sets the video bandwidth (VBW) as a function of the channel

bandwidth (see formula above) and the smallest possible VBW with regard to the available step

size will be selected.

•Detector

The Adjust Settings softkey selects the RMS detector. This detector is selected since it correctly

indicates the power irrespective of the characteristics of the signal to be measured. The whole IF

envelope is used to calculate the power for each measurement point. The IF envelope is digitized

using a sampling frequency which is at least five times the resolution bandwidth which has been

selected. Based on the sample values, the power is calculated for each measurement point using

the following formula:



=

iRMS s

si=linear digitized video voltage at the output of the A/D converter

N = number of A/D converter values per measurement point

PRMS = power represented by a measurement point

When the power has been calculated, the power units are converted into decibels and the value is

displayed as a measurement point.

In principle, the sample detector would be possible as well. Due to the limited number of

measurement points used to calculate the power in the channel, the sample detector would yield

less stable results.

•Trace averaging

The Adjust Settings softkey switches off this function. Averaging, which is often performed to

stabilize the measurement results, leads to a too low level indication and should therefore be

avoided. The reduction in the displayed power depends on the number of averages and the signal

characteristics in the channel to be measured.

•Reference level

The Adjust Settings softkey does not influence the reference level. It can be separately adjusted

using the Adjust Settings softkey.

Ranges and range settings

In the Spectrum Emission Mask and Spurious Emissions measurements, a range defines a segment,

for which you can define the following parameters separately: start and stop frequency, RBW, VBW,

sweep time, sweep points, reference level, attenuator settings, and limit values. Via the sweep list, you

define the ranges and their settings (for details on settings refer to the Sweep List softkey).

The following rules apply to ranges:

•The minimum span of a range is 20 Hz.

•The individual ranges must not overlap (but need not directly follow one another).

•The maximum number of ranges is 20.

•Spectrum Emission Mask measurement only: A minimum of three ranges is mandatory.

•Spectrum Emission Mask measurement only: The reference range cannot be deleted (it is marked

in blue color).

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Provided XML files for the Spectrum Emission Mask measurement

You can change the settings manually or via XML files. The XML files offer a quick way to change the

configuration. A set of ready–made XML files for different standards is already provided. For details see

Table 4-4. You can also create and use your own XML files (for details see "Format description of

Spectrum Emission Mask XML files" on page 4.83). All XML files are stored under C:\r_s\instr\sem_std.

Use the Edit Power Classes softkey for quick access to the available XML files.

Table 4-4: Provided XML files

Path XML file name Displayed standard characteristics*

C:\r_s\instr\sem_std\cdma2000\DL default0.xml CDMA2000 BC0 default DL

default1.xml CDMA2000 BC1 default DL

C:\r_s\instr\sem_std\cdma2000\UL default0.xml CDMA2000 BC0 default UL

default1.xml CDMA2000 BC1 default UL

C:\r_s\instr\sem_std\WCDMA\3GPP\DL PowerClass_31_39.xml W–CDMA 3GPP (31,39)dBm DL

PowerClass_39_43.xml W–CDMA 3GPP (39,43)dBm DL

PowerClass_43_INF.xml W–CDMA 3GPP (43,INF)dBm DL

PowerClass_negINF_31.xml W–CDMA 3GPP (–INF,31)dBm DL

C:\r_s\instr\sem_std\WIBRO\DL PowerClass_29_40.xml WiBro TTA (29,40)dBm DL

PowerClass_40_INF.xml WiBro TTA (40,INF)dBm DL

PowerClass_negINF_29.xml WiBro TTA (–INF,29)dBm DL

C:\r_s\instr\sem_std\WIBRO\UL PowerClass_23_INF.xml WiBro TTA (23,INF)dBm UL

PowerClass_negINF_23.xml WiBro TTA (23,INF)dBm UL

C:\R_S\instr\sem_std\WIMAX\DL\ETSI\...MHz

(1.75 MHz, 2.00 MHz, 3.5 MHz, 7.00 MHz,

14.00 MHz, 28 MHz)

System_Type_E.xml WIMAX DL ETSI–System Type E

System_Type_F.xml WIMAX ETSI–System Type F DL

System_Type_G.xml WIMAX ETSI–System Type G DL

C:\R_S\instr\sem_std\WIMAX\DL\IEEE 10MHz.xml WIMAX 10MHz DL

20MHz.xml WIMAX 20MHz DL

C:\R_S\instr\sem_std\WIMAX\UL\ETSI...MHz

(1.75 MHz, 2.00 MHz, 3.5 MHz, 7.00 MHz,

14.00 MHz, 28 MHz)

System_Type_E.xml WIMAX System Type E UL

System_Type_F.xml WIMAX System Type F UL

System_Type_G.xml WIMAX System Type G UL

C:\R_S\instr\sem_std\WIMAX\UL\IEEE 10MHz.xml WIMAX 10MHz UL

20MHz.xml WIMAX 20MHz UL

C:\R_S\instr\sem_std\WLAN\802_11_TURBO ETSI.xml IEEE 802.11

IEEE.xml IEEE 802.11

C:\R_S\instr\sem_std\WLAN\802_11a ETSI.xml IEEE 802.11a)

IEEE.xml IEEE 802.11a

C:\R_S\instr\sem_std\WLAN\802_11b IEEE.xml IEEE 802.11b

C:\R_S\instr\sem_std\WLAN\802_11j_10MHz ETSI.xml IEEE. 802.11j

IEEE.xml IEEE 802.11j

R&S FSL Power Measurements – MEAS Key

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Path XML file name Displayed standard characteristics*

C:\R_S\instr\sem_std\WLAN\802_11j_20MHz ETSI.xml IEEE 802.11j

IEEE.xml IEEE 802.11j

*Used abbreviations:

BC: band class

UL: uplink

DL: downlink

TTA: Telecommunications Technology Association

Note: For the WIBRO standards, the 1 MHz channel filter is used for every occurrence of a 1 MHz

filter. Within the R&S FSL–K92/93, the 1 MHz filter are Gaussian filters.

Format description of Spectrum Emission Mask XML files

The files for importing range settings are in XML format and therefore obey the rules of the XML

standard. Below, the child nodes, attributes, and structure defined for the data import is described. Build

your own XML files according to these conventions because the R&S FSL can only interpret XML files

of a known structure. For example files look in the C:\r_s\instr\sem_std directory.

Note: It is mandatory to follow the structure exactly as shown below or else the R&S FSL is not able

to interpret the XML file and error messages are shown on the screen. For this reason is it

recommended to make a copy of an existing file (see Save As Standard softkey) and edit the

copy of the file. The default files can be found in the C:\r_s\instr\sem_std directory.

Alternatively, edit the settings using the Edit Power Classes dialog box and the Sweep List

dialog box and save the XML file with the Save As Standard softkey afterwards. This way, no

modifications have to be done in the XML file itself.

Basically, the file consists of three elements that can be defined.

•The first element of the structure is the BaseFormat element. It carries information about basic

settings. In this element only the ReferencePower child node has any effects on the measurement

itself. The other attributes and child nodes are used to display information about the Spectrum

Emission Mask Standard on the measurement screen. The child nodes and attributes of this

element are shown in Table 4-5.

In the example above (PowerClass_39_43.xml under C:\r_s\instr\sem_std\WCDMA\3GPP), these

attributes are defined as follows:

Power Measurements – MEAS Key R&S FSL

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–Standard="W–CDMA 3GPP"

–LinkDirection="DL"

–PowerClass="(39,43)dBm"

•The second element is the PowerClass element, which is embedded in the BaseFormat element. It

carries settings information about the power classes. Up to four different power classes can be

defined. For details refer to the Sweep List softkey and the corresponding parameter description.

The child nodes and attributes of this element are shown in Table 4-6.

•The third element is the Range element, which in turn is embedded in the PowerClass element. It

carries the settings information of the range. There have to be at least three defined ranges: one

reference range and at least one range to either side of the reference range. The maximum number

of ranges is twenty. Note that the R&S FSL uses the same ranges in each power class. Therefore,

the contents of the ranges of each defined power class have to be identical to the first power class.

An exception are the Start amd Stop values of the two Limit nodes that are used to determine the

power class. Note also, that there are two Limit nodes to be defined: one that gives the limit in

absolute values and one in relative values. Make sure units for the Start and Stop nodes are

identical for each Limit node. For details refer to the Sweep List softkey and the corresponding

parameter description. The child nodes and attributes of this element are shown in Table 4-7.

The following tables show the child nodes and attributes of each element and show if a child node or

attribute is mandatory for the R&S FSL to interpret the file or not. Since the hierarchy of the XML can

not be seen in the tables, either view one of the default files already stored on the R&S FSL in the

C:\r_s\instr\sem_std directory or check the structure as shown below.

Below, a basic example of the structure of the file is shown, containing all mandatory attributes and

child nodes. Note that the PowerClass element and the range element are themselves elements of the

Base Format element and are to be inserted where noted. The separation is done here simply for

reasons of a better overview. Also, no example values are given here to allow a quick reference to the

tables above. Italic font shows the placeholders for the values.

•The Base Format element is structered as follows:

<RS_SEM_ACP_FileFormat Version=”1.0.0.0”>

<Name>Standard</Name>

<Type>Instrument Type</Type>

<Application>Application</Application>

</Instrument>

<Method>Method</Method>

</ReferencePower>

<!—- For contents of the PowerClass node see

Table 4-6 -->

</PowerClass>

</LinkDirection>

</RS_SEM_ACP_File>

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•The PowerClass element is structered as follows:

<DefaultLimitFailMode>Limit Fail Mode</DefaultLimitFailMode>

</Range>

…

</PowerClass>

•The Range element is structered as follows:

<Name="Name">

<ChannelType>Channel Type</Channel Type>

<Type>FilterType</Type>

<RollOffFactor>Factor</RollOffFactor>

<Bandwith>Bandwidth</Bandwidth>

</WeightingFilter>

<Start>RangeStart</Start>

<Stop>RangeStop</Stop>

</FrequencyRange>

<Limit>

</Limit>

<Limit>

</Limit>

<Detector>Detector</Detector>

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</Amplitude>

</Range>

Table 4-5: Attributes and child nodes of the BaseFormat element

Child Node Attribute Value Parameter Description Mandatory

FileFormatVersion 1.0.0.0 Yes

Date “YYYY-MM-DD

HH:MM:SS”

Date in ISO 8601 format No

Name <string> Name of the standard Yes

Instrument Type FSL Name of the instrument No

Application SA | K72 | K82 Name of the application No

LinkDirection Name Downlink | Uplink |

None

Yes

ShortName DL | UL No

ReferencePower Yes

Method TX Channel Power |

TX Channel Peak

Power

Yes

ReferenceChannel <string> No

Table 4-6: Attributes and child nodes of the PowerClass element

Child Node Attribute Value Parameter Description Mandatory

Index 0…3 Indexes are continuous and

have to start with 0

Yes

StartPower Value <power in dBm> The start power must equal

the stop power of the

previous power class. The

StartPower value of the first

range is -200

Yes

Unit dBm Yes

InclusiveFlag "true" Yes

StopPower Value <power in dBm> The stop power must equal

the start power of the next

power class. The StopPower

value of the last range is 200

Yes

Unit dBm Yes

InclusiveFlag "false" Yes

DefaultLimitFailMode Absolute | Relative |

Absolute and Relative |

Absolute or Relative

Yes

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Table 4-7: Attributes and child nodes of the Range element (normal ranges)

Child Node Attribute Value Parameter Description Mandatory

Index 0…19 Indexes are continous and

have to start with 0

Yes

Name <string> Name of the range Only if ReferenceChannel

contains a name and the

range is the reference

range

ShortName <string> Short name of the range No

ChannelType TX | Adjacent Yes

WeightingFilter Only if ReferencePower

method is “TX Channel

Power” and the range is

the reference range”

Type RRC | CFILter Type of the weighting filter Yes

RollOffFactor 0…1 Excess bandwidth of the filter Only if the filter type is

RRC

Bandwidth <Bandwidth in Hz> Filter bandwidth Only if the filter type is

RRC

FrequencyRange Yes

Start <frequency in Hz> Start value of the range Yes

Stop <frequency in Hz> Stop value of the range Yes

Limit A Range must contain exactly

two limit nodes; one of the

limit nodes has to have a

relative unit (e.g. dBc), the

other one must have an

absolute unit (e.g. dBm)

Yes

Start Value <numeric_value> Power limit at start frequency Yes

Unit dBm/Hz | dBm | dBc |

dBr | dB

Sets the unit of the start value Yes

Stop Value <numeric_value> Power limit at stop frequency Yes

Unit dBm/Hz | dBm | dBc |

dBr | dB

Sets the unit of the stop value Yes

LimitFailMode Absolute | Relative |

Absolute and Relative |

Absolute or Relative

No (if quoted, it has to be

equal to

DefaultLimitFailMode)

RBW Bandwidth <bandwidth in Hz> RBW Yes

Type NORM | PULS | CFIL |

RRC

VBW Bandwidth <bandwidth in Hz> VBW Yes

Detector NEG | POS | SAMP |

RMS | AVER | QUAS

Detector No (if quoted, it has to be

equal in all ranges)

Sweep Mode Manual | Auto Sweep Time Mode Yes

Time <time in sec> Sweep Time No

Amplitude No

ReferenceLevel Value <power in dBm> Ref. Level Yes, if the ReferenceLevel

child node is used

Unit dBm Yes, if the ReferenceLevel

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Child Node Attribute Value Parameter Description Mandatory

node is used

RF Atennuation Mode Manual | Auto RF Attenuator Yes, if the ReferenceLevel

child node is used

Preamplifier ON | OFF Preamp Yes

ASCII file export format (Spectrum Emission Mask)

The first part of the file lists information about the spectrum analyzer and the general setup. For a

detailed description refer to "ASCII file export format" on page 4.51.

File contents Description

RefType; CPOWER;

TxBandwidth;9540000;Hz

Filter State; ON;

Alpha;0.22;

reference range setup, for details see

Edit Reference Range softkey

PeaksPerRange;1;

Values;4;

evaluation list information

0;–22500000;–9270000;1000000;2986455000;–74.762840270996094;

–10.576210021972656;–45.762840270996094;PASS;

1;–9270000;–4770000;100000;2991405000;–100.17695617675781;

–35.990325927734375;–1.490325927734375;PASS

3;4770000;9270000;100000;3005445000;–100.17695617675781;

–35.990325927734375;–1.490325927734375;PASS;

4;9270000;22500000;1000000;3018225000;–74.762840270996094;

–10.576210021972656;–45.762840270996094;PASS;

information about each peak:

<range number>;

<start frequency>;

<stop frequency>;

<resolution bandwidth of range>;

<frequency of peak>;

<absolute power in dBm of peak>;

<relative power in dBc of peak

(related to the channel power)>;

<distance to the limit line in dB

(positive value means above the limit)>;

<limit fail (pass = 0, fail =1)>;

Softkeys of the power measurement menu

The following table shows all softkeys available in the power measurement menu. It is possible that

your instrument configuration does not provide all softkeys. If a softkey is only available with a special

option, model or (measurement) mode, this information is delivered in the corresponding softkey

description.

Menu / Command Submenu / Command Submenu / Command Command

All Functions Off

TOI Marker 1

Marker 2

Marker 3

Marker 4

Search Signals

AM Mod Depth same contents as TOI

Time Domain Power Peak

RMS

Mean

R&S FSL Power Measurements – MEAS Key

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Menu / Command Submenu / Command Submenu / Command Command

Std Dev

Limits On/Off

Left Limit

Right Limit

C/N, C/No C/N

C/No

Channel Bandwidth

Adjust Settings

CP, ACP, MC–ACP CP / ACP Standard

CP / ACP Config #of TX Chan

#of Adj Chan

Channel Settings Channel

Bandwidth

Channel Spacing

Chan Pwr/Hz

ACP Ref Settings

Adjust Ref Level

Adjust Settings

Limit Checking Limit Chk On/Off

Edit ACP Limit

Power Mode Clear/Write

Max Hold

Select Trace

Adjust Settings

Sweep Time

Fast ACP On/Off

ACP Abs/Rel

Adjust Ref Level

More 

All Functions Off

OBW %Power Bandwidth

Channel Bandwidth

Adjust Ref Level

Adjust Settings

APD Percent Marker

Res BW

#of Samples

Scaling x–Axis Ref Level

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Menu / Command Submenu / Command Submenu / Command Command

x–Axis Range

y–Axis Max Value

y–Axis Min Value

y–Unit %/Abs

Default Settings

Adjust Settings

CCDF same contents as APD

Spectrum Emission Mask Sweep List Edit Sweep List/Close

Sweep List

Insert before Range

Insert after Range

Delete Range

Edit Reference Range

List Evaluation List Evaluation On/Off

List Full Screen

Margin

Show Peaks

List Up

List Down

Save Evaluation List ASCII File Export

Decim Sep

Edit Reference Range

Edit Power Classes

Load Standard

Save As Standard

Restore Standard Files

Meas Start/Stop

Spurious Emissions Sweep List Edit Sweep List/Close

Sweep List

Insert before Range

Insert after Range

Delete Range

Adjust X–Axis

List Evaluation List Evaluation On/Off

List Full Screen

Details On/Off

Peaks per Range

R&S FSL Power Measurements – MEAS Key

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Menu / Command Submenu / Command Submenu / Command Command

Margin

Show Peaks

More 

List Up

List Down

Save Evaluation List ASCII File Export

Decim Sep

Meas Start/Stop

More 

All Functions Off

Harmonic Distortion Harmonic On/Off

No. of Harmonics

Harmonic Sweep Time

Harmonic RBW Auto

Adjust Settings

Full Size Diagram

All Functions Off

Switches off all power measurement functions.

Remote: CALC:MARK:FUNC:<function> OFF

TOI

Opens a submenu and activates the measurement of the 3rd order intercept point.

Atwo–tone signal with equal carrier levels is expected at the R&S FSL input. Marker 1 and

marker 2 (both normal markers) are set to the maximum of the two signals. Marker 3 and marker

4(also both normal markers) are placed on the intermodulation products. When the function is

enabled, the frequency entry is activated for the delta markers. They can be set manually.

The R&S FSL calculates the third order intercept point from the level spacing between normal

markers and delta markers and displays it in the marker field.

Remote: CALC:MARK:FUNC:TOI ON

Remote: CALC:MARK:FUNC:TOI:RES?

Search Signals

Activates all markers.

Remote: CALC:MARK:FUNC:TOI:RES?

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AM Mod Depth

Opens a submenu and activates the measurement of the AM modulation depth. An AM–

modulated carrier is required on the screen for ensuring correct operation.

The level value of marker 1 is taken as the carrier level. When this function is activated, marker

2and marker 3 are automatically set symmetrically to the carrier on the adjacent peak values of

the trace as delta markers and marker 2 is activated for the entry.

When the position of marker 2 (delta) is changed, marker 3 (delta) is moved symmetrically with

respect to the reference marker (marker 1).

If the edit dialog box is opened for marker 3, the latter can be moved for fine adjustment

irrespective of marker 2.

The R&S FSL calculates the power at the marker positions from the measured levels. The AM

modulation depth is calculated from the ratio between the power values at the reference marker

and at the delta markers. If the powers of the two AM side bands are unequal, the mean value of

the two power values is used for AM modulation depth calculation.

Remote: CALC:MARK:FUNC:MDEP ON

Remote: CALC:MARK:FUNC:MDEP:RES?

Time Domain Power (zero span)

Activates the power measurement in zero span and opens a submenu to configure the power

measurement. For more details see also "Power measurement in zero span" on page 4.78.

Remote: CALC:MARK:FUNC:SUMM:STAT ON

Peak (zero span)

Activates the calculation of the peak value from the points of the displayed trace or a segment

thereof. For more details see also "Power measurement in zero span" on page 4.78.

Remote: CALC:MARK:FUNC:SUMM:PPE ON

Remote: CALC:MARK:FUNC:SUMM:PPE:RES?

RMS (zero span)

Activates the calculation of the RMS value from the points of the displayed trace or a segment

thereof. For more details see also "Power measurement in zero span" on page 4.78.

Remote: CALC:MARK:FUNC:SUMM:RMS ON

Remote: CALC:MARK:FUNC:SUMM:RMS:RES?

Mean (zero span)

Activates the calculation of the mean value from the points of the displayed trace or a segment

thereof. The linear mean value of the equivalent voltages is calculated.

This can be used for instance to measure the mean power during a GSM burst.

For more details see also "Power measurement in zero span" on page 4.78.

Remote: CALC:MARK:FUNC:SUMM:MEAN ON

Remote: CALC:MARK:FUNC:SUMM:MEAN:RES?

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.93 E-11

Std Dev (zero span)

Activates the calculation of the standard deviation of measurement points from the mean value

and displays them as measured value. The measurement of the mean power is automatically

switched on at the same time. For more details see also "Power measurement in zero span" on

page 4.78.

Remote: CALC:MARK:FUNC:SUMM:SDEV ON

Remote: CALC:MARK:FUNC:SUMM:SDEV:RES?

Limits On/Off (zero span)

Switches the limitation of the evaluation range on or off. Default setting is off.

If switched off, the evaluation range is not limited. If switched on, the evaluation range is defined

by the left and right limit. If only one limit is set, it corresponds to the left limit and the right limit is

defined by the stop frequency. If the second limit is also set, it defines the right limit.

For more details see also "Power measurement in zero span" on page 4.78.

Remote: CALC:MARK:X:SLIM OFF

Left Limit (zero span)

Opens an edit dialog box to enter a value for line 1. For more details see also "Power

measurement in zero span" on page 4.78.

Remote: CALC:MARK:X:SLIM:LEFT <value>

Right Limit (zero span)

Opens an edit dialog box to enter a value for line 2. For more details see also "Power

measurement in zero span" on page 4.78.

Remote: CALC:MARK:X:SLIM:RIGH <value>

C/N, C/No (span > 0)

Opens a submenu to configure the carrier/noise ratio measurement. Measurements without

(C/N) and measurements with reference to the bandwidth (C/No) are possible.

C/N (span > 0)

Switches the measurement of the carrier/noise ratio on or off. If no marker is active, marker 1 is

activated.

The measurement is performed on the trace where marker 1 is located. To shift marker 1 and

measure another trace, use the Marker to Trace softkey in the marker menu. To determine the

maximum value of the current trace, use the Phase Noise/Ref Fixed softkey in the marker

menu.

Remote: CALC:MARK:FUNC:POW:SEL CN

Remote: CALC:MARK:FUNC:POW:RES? CN

Remote: CALC:MARK:FUNC:POW OFF

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1300.2519.12 4.94 E-11

C/No (span > 0)

Switches the measurement of the carrier/noise ratio with reference to a 1 Hz bandwidth on or

off. If no marker is active, marker 1 is activated.

The measurement is performed on the trace where marker 1 is located. To shift marker 1 and

measure another trace, use the Marker to Trace softkey in the marker menu. To determine the

maximum value of the current trace, use the Phase Noise/Ref Fixed softkey in the marker

menu.

Remote: CALC:MARK:FUNC:POW:SEL CN0

Remote: CALC:MARK:FUNC:POW:RES? CN0

Remote: CALC:MARK:FUNC:POW OFF

Channel Bandwidth (span > 0)

Opens an edit dialog box to enter the measurement channel bandwidth. The default setting is 14

kHz.

Remote: POW:ACH:BWID 30kHz

Adjust Settings (span > 0)

Enables the RMS detector (see also "Detector overview" on page 4.42) and adjusts the span to

the selected channel bandwidth according to:

4 x channel bandwidth + measurement margin

The adjustment is performed once; if necessary, the setting can be changed later on.

Remote: POW:ACH:PRES CN | CN0

CP, ACP, MC–ACP

Activates the active channel or adjacent–channel power measurement either for a single carrier

signal or for several carrier signals, depending on the current measurement configuration, and

opens a submenu to configure the channel power measurement. With default settings the

measurement is performed by integrating the powers at the display points within the specified

channels (IBW method).

If multi–carrier ACP measurement is activated, the number of measured values is increased to

ensure that adjacent–channel powers are measured with adequate accuracy.

Remote: CALC:MARK:FUNC:POW:SEL CPOW|ACP|MCAC

Remote: CALC:MARK:FUNC:POW:RES? CPOW|ACP|MCAC

Remote: CALC:MARK:FUNC:POW OFF

CP / ACP Standard

Opens an edit dialog box to select the settings according to predefined standards. For details on

the available standards see "Predefined CP / ACP standards" on page 4.79. By default no

standard is set.

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.95 E-11

The selection of the standard influences the following parameters:

–channel spacing and adjacent–channel spacing

–channel bandwidth, adjacent–channel bandwidth, and type of filtering

– resolution bandwidth

–video bandwidth

–detector

– # of adjacent channels

–trace averaging (switched off)

Remote: CALC:MARK:FUNC:POW:PRES <standard>

CP / ACP Config

Opens a submenu to configure the channel power and adjacent channel power measurement

independently of the predefined standards (for details see also "To set the channel

configuration" on page 4.77 and "Settings of CP / ACP test parameters" on page 4.80).

#of TX Chan (MC–ACP)

Opens an edit dialog box to enter the number of carrier signals to be taken into account in

channel and adjacent–channel power measurements. Values from 1 to 12 are allowed.

Remote: POW:ACH:TXCH:COUN 4

#of Adj Chan

Opens an edit dialog box to enter the number of adjacent channels to be considered in the

adjacent–channel power measurement. Values from 0 to 12 are allowed.

The following measurements are performed depending on the number of the channels:

0Only the channel powers are measured.

1The channel powers and the power of the upper and lower adjacent channel are

measured.

2The channel powers, the power of the upper and lower adjacent channel, and of the

next higher and lower channel (alternate channel 1) are measured.

3The channel power, the power of the upper and lower adjacent channel, the power of

the next higher and lower channel (alternate channel 1), and of the next but one

higher and lower adjacent channel (alternate channel 2) are measured.

... ...

12 The channel power, the power of the upper and lower adjacent channel, and the

power of the all higher and lower channels (alternate channel 1 to 11) are measured.

Remote: POW:ACH:ACP 1

Channel Settings

Opens a submenu to define the channel settings.

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.96 E-11

Channel Bandwidth

Opens the TX/ACP Channel Bandwidth dialog box to enter the channel bandwidths for the

transmission channels and the adjacent channels. The entry TX is only available for the multi–

carrier ACP measurement.

The transmission–channel bandwidth is normally defined by the transmission standard. The

correct bandwidth is set automatically for the selected standard (see CP / ACP Standard

softkey).

Measurements in zero span (see Fast ACP On/Off softkey) are performed in the zero span

mode. The channel limits are indicated by vertical lines. For measurements requiring channel

bandwidths deviating from those defined in the selected standard the IBW method is to be used.

With the IBW method (see Fast ACP On/Off softkey), the channel bandwidth limits are marked

by two vertical lines right and left of the channel center frequency. It can in this way be visually

checked whether the entire power of the signal under test is within the selected channel

bandwidth.

If measuring according to the IBW method (Fast ACP Off), the bandwidths of the different

adjacent channels are to be entered numerically. Since all adjacent channels often have the

same bandwidth, the other channels Alt1 and Alt2 are set to the bandwidth of the adjacent

channel on entering the adjacent–channel bandwidth (ADJ). Thus only one value needs to be

entered in case of equal adjacent channel bandwidths. The same holds true for the Alt2

channels (alternate channels 2) if the bandwidth of the Alt1 channel (alternate channel 1) is

entered.

For details on available channel filters see "List of available RRC and channel filters" on page

4.20.

Remote: POW:ACH:BWID 30kHz

Remote: POW:ACH:BWID:ACH 30kHz

Remote: POW:ACH:BWID:ALT2 30kHz

Channel Spacing

Opens the TX/ACP Channel Spacing dialog box to enter the channel spacings for the TX

channels and for the adjacent channels.

The entry TX is only available for the multi–carrier ACP measurement.

–TX channels (left column)

TX1–

spacing between the first and the second carrier

TX2–

spacing between the second and the third carrier

... ...

The spacings between all adjacent TX channels can be defined separately. In order to allow a

convenient setup for the system with equal TX channel spacing, the value of TX spacing 1–2 is

copied in all the spacing below after entry, the TX spacing 2–3 is copied in all the spacing

below after entry and so forth. For different spacings, a setup from top to bottom is necessary.

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.97 E-11

If the spacings are not equal, the channel distribution according to the center frequency is as

follows:

Odd number of TX channels The middle TX channel is centered to center frequency.

Even number of TX channels The two TX channels in the middle are used to calculate

the frequency between those two channels. This

frequency is aligned to the center frequency.

–Adjacent channels (right column)

Since all the adjacent channels often have the same distance to each other, the modification of

of the adjacent–channel spacing (ADJ) causes a change in all higher adjacent–channel

spacings (Alt1, Alt2, ...): they are all multiplied by the same factor (new spacing value / old

spacing value). Thus only one value needs to be entered in case of equal channel spacing. A

modification of a higher adjacent–channel spacing (Alt1, Alt2, ...) causes a change by the same

factor in all higher adjacent–channel spacings, while the lower adjacent–channel spacings

remain unchanged.

Example:

In the default setting, the adjacent channels have the following spacing: 20 kHz (ADJ), 40

kHz (Alt1), 60 kHz (Alt2), 80 kHz (Alt3), 100 kHz (Alt4), ...

If the spacing of the first adjacent channel (ADJ)is set to 40 kHz, the spacing of all other

adjacent channels is multiplied by factor 2 to result in 80 kHz (Alt1), 120 kHz (Alt2), 160 kHz

(Alt3), ...

If, starting from the default setting, the spacing of the 5th adjacent channel (Alt4)is set to 150

kHz, the spacing of all higher adjacent channels is multiplied by factor 1.5 to result in 180 kHz

(Alt5), 210 kHz (Alt6), 240 kHz (Alt7), ...

If a ACP or MC–ACP measurement is started, all settings according to the standard including

the channel bandwidths and channel spacings are set and can be adjusted afterwards.

Remote: POW:ACH:SPAC:CHAN 25kHz

Remote: POW:ACH:SPAC 33kHz

Remote: POW:ACH:SPAC:ALT1 100kHz

Chan Pwr/Hz

If deactivated, the channel power is displayed in dBm. If activated, the channel power density is

displayed instead. Thus, the absolute unit of the channel power is switched from dBm to

dBm/Hz. The channel power density in dBm/Hz corresponds to the power inside a bandwidth of

1Hz and is calculated as follows:

channel power density = channel power – log10(channel bandwidth)

By means of this function it is possible e.g. to measure the signal/noise power density or use the

additional functions ACP Abs/Rel and ACP Ref Settings to obtain the signal to noise ratio.

This softkey is available from firmware version 1.50.

Remote: CALC:MARK:FUNC:POW:RES:PHZ ON

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.98 E-11

ACP Ref Settings (MC–ACP)

Opens an edit dialog box to select the transmission channel to which the adjacent–channel

relative power values should be referenced.

TX Channel 1 – 12 Selection of one of channels 1 to 12.

Min Power TX Channel The transmission channel with the lowest power is used as a

reference channel.

Max Power TX Channel The transmission channel with the highest power is used as a

reference channel.

Lowest & Highest

Channel

The outer left–hand transmission channel is the reference

channel for the lower adjacent channels, the outer right–hand

transmission channel that for the upper adjacent channels.

Remote: POW:ACH:REF:TXCH:MAN 3

Remote: POW:ACH:REF:TXCH:AUTO MAX

Limit Checking

Opens a submenu to activate and define the limits for the ACP measurement.

This softkey is available from firmware version 1.30.

Limit Chk On/Off

Activates or deactivates the limit check for the ACP measurement.

Remote: CALC:LIM:ACP ON

Remote: CALC:LIM:ACP:ACH:RES?

Remote: CALC:LIM:ACP:ALT:RES?

Edit ACP Limit

Opens the ACP Limits dialog box to define the limits for the ACP measurement.

The following rules apply for the limits:

– A separate limit can be defined for each adjacent channel. The limit applies to both the upper

and the lower adjacent channel.

– A relative and/or absolute limit can be defined. The check of both limit values can be activated

independently.

–The R&S FSL checks adherence to the limits irrespective of whether the limits are absolute or

relative or whether the measurement is carried out with absolute or relative levels. If both limits

are active and if the higher of both limit values is exceeded, the measured value is marked by a

preceding asterisk.

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.99 E-11

Remote: CALC:LIM:ACP ON

Remote: CALC:LIM:ACP:<adjacent–channel> 0dB,0dB

Remote: CALC:LIM:ACP:<adjacent–channel>:STAT ON

Remote: CALC:LIM:ACP:<adjacent–channel>:ABS –10dBm,–10dBm

Remote: CALC:LIM:ACP:<adjacent–channel>:ABS:STAT ON

For details refer to chapter "Remote Control – Commands", section "CALCulate:LIMit:ACPower

Subsystem".

Power Mode

Opens a submenu to select the power mode.

This softkey is available from firmware version 1.30.

Clear/Write

If this mode is activated, the channel power and the adjacent channel powers are calculated

directly from the current trace (default mode).

This softkey is available from firmware version 1.30.

Remote: CALC:MARK:FUNC:POW:MODE WRIT

Max Hold

If this mode is activated, the power values are calculated from the current trace and compared

with the previous power value using a maximum algorithm. The higher value is retained. If

activated, the enhancement label Pwr Max is displayed.

This softkey is available from firmware version 1.30.

Remote: CALC:MARK:FUNC:POW:MODE MAXH

Select Trace

Opens an edit dialog box to enter the trace number on which the CP/ACP measurement is to be

performed. Only activated traces can be selected (for details on trace modes see "Trace mode

overview" on page 4.40).

Remote: POW:TRAC 2

Adjust Settings

Automatically optimizes all instrument settings for the selected channel configuration (channel

bandwidth, channel spacing) within a specific frequency range (channel bandwidth). The

adjustment is carried out only once. If necessary, the instrument settings can be changed later.

For details on the settings of span, resolution bandwidth, video bandwidth, detector and trace

averaging see "Settings of CP / ACP test parameters" on page 4.80.

Remote: POW:ACH:PRES ACP

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.100 E-11

Sweep Time

Opens an edit dialog box to enter the sweep time. With the RMS detector, a longer sweep time

increases the stability of the measurement results.

The function of this softkey is identical to the Sweeptime Manual softkey in the bandwidth

menu.

Remote: SWE:TIM <value>

Fast ACP On/Off

Switches between the IBW method (Fast ACP Off)and the zero span method (Fast ACP On).

When switched on, the R&S FSL sets the center frequency consecutively to the different

channel center frequencies and measures the power with the selected measurement time (=

sweep time/number of channels). The RBW filters suitable for the selected standard and

frequency offset are automatically used (e.g. root raised cos with IS 136). For details on

available channel filters see "List of available RRC and channel filters" on page 4.20.

The RMS detector is used for obtaining correct power measurement results. Therefore this

requires no software correction factors.

Measured values are output as a list. The powers of the transmission channels are output in

dBm, the powers of the adjacent channels in dBm.

The sweep time is selected depending on the desired reproducibility of results. Reproducibility

increases with sweep time since power measurement is then performed over a longer time

period. As a general approach, it can be assumed that approx. 500 non–correlated measured

values are required for a reproducibility of 0.5 dB (99% of the measurements are within 0.5 dB of

the true measured value). This holds true for white noise. The measured values are considered

as non–correlated if their time interval corresponds to the reciprocal of the measured bandwidth.

With IS 136 the measurement bandwidth is approx. 25 kHz, i.e. measured values at an interval

of 40 Msare considered as non–correlated. A measurement time of 40 ms is thus required per

channel for 1000 measured values. This is the default sweep time which the R&S FSL sets in

coupled mode. Approx. 5000 measured values are required for a reproducibility of 0.1 dB (99%),

i.e. the measurement time is to be increased to 200 ms.

Remote: POW:HSP ON

ACP Abs/Rel

Switches between absolute and relative power measurement in the adjacent channels.

Abs The absolute power in the adjacent channels is displayed in the unit of the y–axis,

e.g. in dBm, dBMV.

Rel The level of the adjacent channels is displayed relative to the level of the

transmission channel in dBc.

Remote: POW:ACH:MODE REL

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.101 E-11

Adjust Ref Level

Adjusts the reference level to the measured channel power. This ensures that the settings of the

RF attenuation and the reference level are optimally adjusted to the signal level without

overloading the R&S FSL or limiting the dynamic range by a too small S/N ratio. For details on

manual settings see "Settings of CP / ACP test parameters" on page 4.80.

The reference level is not influenced by the selection of a standard. To achieve an optimum

dynamic range, the reference level has to be set in a way that places the signal maximum close

to the reference level without forcing an overload message. Since the measurement bandwidth

for channel power measurements is significantly lower than the signal bandwidth, the signal path

may be overloaded although the trace is still significantly below the reference level.

Remote: POW:ACH:PRES:RLEV

OBW (span > 0)

Activates measurement of the occupied bandwidth according to the current configuration and

opens a submenu to configure the measurement. The occupied bandwidth is displayed in the

marker display field and marked on the trace by temporary markers. For details see also

"Measurement of occupied bandwidth" on page 4.78.

The measurement is performed on the trace with marker 1. In order to evaluate another trace,

marker 1 must be placed on another trace (see Marker to Trace softkey in the marker menu).

Remote: CALC:MARK:FUNC:POW:SEL OBW

Remote: CALC:MARK:FUNC:POW:RES? OBW

Remote: CALC:MARK:FUNC:POW OFF

%Power Bandwidth (span > 0)

Opens an edit dialog box to enter the percentage of total power in the displayed frequency range

which defines the occupied bandwidth. Values from 10% to 99.9% are allowed.

Remote: POW:BWID 95PCT

Channel Bandwidth (span > 0)

Opens an edit dialog box to enter the channel bandwidth for the transmission channel. The

specified channel bandwidth is used for optimization of the test parameters (for details see

"Settings of CP / ACP test parameters" on page 4.80). The default setting is 14 kHz.

For measurements in line with a specific transmission standard, the bandwidth specified by the

standard for the transmission channel must be entered.

Remote: POW:ACH:BWID 30kHz

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.102 E-11

Adjust Ref Level (span > 0)

Adjusts the reference level to the measured total power of the signal. The softkey is activated

after the first sweep with active measurement of the occupied bandwidth has been completed

and the total power of the signal is thus known.

Adjusting the reference level ensures that the signal path will not be overloaded and the

dynamic range not limited by too low a reference level. Since the measurement bandwidth for

channel power measurements is significantly lower than the signal bandwidth, the signal path

may be overloaded although the trace is distinctly below the reference level. If the measured

channel power is equal to the reference level, the signal path cannot be overloaded.

Remote: POW:ACH:PRES:RLEV

APD

Activates the function to measure the amplitude probability density (APD) and opens a

submenu.

Remote: CALC:STAT:APD ON

Percent Marker

Opens an edit dialog box to enter a probability value and to position marker 1. Thus, the power

which is exceeded with a given probability can be determined very easily. If marker 1 is

deactivated, it will be switched on automatically.

Remote: CALC:MARK:Y:PERC 0...100%

Res BW

Opens an edit dialog box to set the resolution bandwidth directly. The function of this softkey is

identical to the Res BW Manual softkey in the bandwidth menu.

For correct measurement of the signal statistics the resolution bandwidth has to be wider than

the signal bandwidth in order to measure the actual peaks of the signal amplitude correctly. In

order not to influence the peak amplitudes the video bandwidth is automatically set to 10 MHz.

The sample detector is used for detecting the video voltage.

Remote: BAND 3 MHz

#of Samples

Opens an edit dialog box to set the number of power measurements that are taken into account

for the statistics.

Apart from the number of measurements the overall measurement time depends also on the set

resolution bandwidth as the resolution bandwidth directly influences the sampling rate.

Remote: CALC:STAT:NSAM <value>

Scaling

Opens a submenu to change the scaling parameters of x– and y–axis.

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.103 E-11

x–Axis Ref Level

Opens an edit dialog box to enter the reference level in the currently active unit (dBm, dBMV,

etc). The function of this softkey is identical to the Ref Level softkey in the amplitude menu.

For the APD function this value is mapped to the right diagram border. For the CCDF function

there is no direct representation of this value on the diagram as the x–axis is scaled relatively to

the measured mean power.

Remote: CALC:STAT:SCAL:X:RLEV <value>

x–Axis Range

Opens the Range Log dialog box to select a value for the level range to be covered by the

statistics measurement selected. The function is identical to the Range Log softkey in amplitude

menu.

Remote: CALC:STAT:SCAL:X:RANG <value>

y–Axis Max Value

Opens an edit dialog box to define the upper limit of the displayed probability range. Values on

the y–axis are normalized which means that the maximum value is 1.0. The y–axis scaling is

defined via the y–Unit %/Abs softkey. If the y–axis has logarithmic scale, the distance between

max and min value must be at least one decade.

Remote: CALC:STAT:SCAL:Y:UPP <value>

y–Axis Min Value

Opens an edit dialog box to define the lower limit of the displayed probability range. Values in

the range 0 < value < 1 are allowed. The y–axis scaling is defined via the y–Unit %/Abs softkey.

If the y–axis has logarithmic scale, the distance between max and min value must be at least

one decade.

Remote: CALC:STAT:SCAL:Y:LOW <value>

y–Unit %/Abs

Defines the scaling type of the y–axis. The default value is absolute scaling.

This softkey is available from firmware version 1.80.

Remote: CALC:STAT:SCAL:Y:UNIT PCT

Default Settings

Resets the x– and y–axis scalings to their preset values.

x–axis ref level: –20 dBm

x–axis range APD: 100 dB

x–axis range CCDF: 20 dB

y–axis upper limit: 1.0

y–axis lower limit: 1E–6

Power Measurements – MEAS Key R&S FSL

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Remote: CALC:STAT:PRES

Adjust Settings

Adjusts the level settings according to the measured difference between peak and minimum

power for APD measurement or peak and mean power for CCDF measurement in order to

obtain maximum power resolution. Adapts the probability scale to the selected number of

samples. Adjusts the reference level to the current input signal. For details see also Adjust Ref

Level softkey.

Remote: CALC:STAT:SCAL:AUTO ONCE

CCDF

Activates the function to measure the complementary cumulative distribution function (CCDF)

and opens a submenu.

Remote: CALC:STAT:CCDF ON

Spectrum Emission Mask

Opens a submenu to configure the Spectrum Emission Mask measurement.

The Spectrum Emission Mask (SEM) measurement defines a measurement that monitors

compliance with a spectral mask. The SEM measurement of the base unit allows a flexible

definition of all parameters in the SEM measurement.

This softkey is available from firmware version 1.80.

Remote: SWE:MODE ESP

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.105 E-11

Sweep List

Opens a submenu to edit the sweep list and displays the Sweep List dialog box. After a preset,

the sweep list contains a set of default ranges and parameters. For each range, you can change

the parameters listed below. To insert or delete ranges, use the Insert before Range,Insert

after Range,Delete Range softkeys. The measurement results are not updated during editing

but on closing the dialog box (Close Sweep List softkey).

Note: If you edit the sweep list, always follow the rules described in "Ranges and range settings" on

page 4.81.

Parameter Restriction

Range Start

Range Stop

Filter Type

RBW

VBW

Sweep Time Mode

Sweep Time

Detector Spurious Emissions measurement only

Ref. Level

RF Att. Mode

RF Attenuator

Preamp

Sweep Points Spurious Emissions measurement only

Stop after Sweep Spurious Emissions measurement only

Transd. Factor

Limit Check 1 to 4

Abs Limit Start

Abs Limit Stop

Rel Limit Start Spectrum Emission Mask measurement only

Rel Limit Stop Spectrum Emission Mask measurement only

–Spectrum Emission Mask measurement:

The changes of the sweep list are only kept until you load another parameter set (via a preset

or by loading an XML file). If you want to have a parameter set permanently available, create an

XML file for this configuration (for details refer to "Format description of Spectrum Emission

Mask XML files" on page 4.83).

If you load one of the provided XML files (Load Standard softkey), the sweep list contains

ranges and parameters according to the selected standard. For further details refer also to

"Provided XML files for the Spectrum Emission Mask measurement" on page 4.82.

This softkey is available from firmware version 1.80.

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.106 E-11

Range Start/Range Stop (Sweep List dialog box)

Sets the start frequency/stop frequency of the selected range. Follow the rules described in

"Ranges and range settings" on page 4.81.

In order to change the start/stop frequency of the first/last range, select the appropriate span

with the SPAN key. If you set a span that is smaller than the overall span of the ranges, the

measurement includes only the ranges that lie within the defined span and have a minimum

span of 20 Hz. The first and last range are adapted to the given span as long as the minimum

span of 20 Hz is not violated.

–Spectrum Emission Mask measurement:

Frequency values for each range have to be defined relative to the center frequency. The

reference range has to be centered on the center frequency. The minimum span of the

reference range is given by the current TX Bandwidth. For details refer to the Edit Reference

Range softkey description.

Remote: ESP:RANG1:STAR 100000000 (Spectrum Emission Mask)

Remote: ESP:RANG3:STOP 10000000 (Spectrum Emission Mask)

Remote: LIST:RANG1:STAR 100000000 (Spurious Emissions)

Remote: LIST:RANG3:STOP 10000000 (Spurious Emissions)

Filter Type (Sweep List dialog box)

Sets the filter type for this range. For details on filters see also "To choose the appropriate filter

type" on page 4.19.

Remote: ESP:RANG1:FILT:TYPE RRC (Spectrum Emission Mask)

Remote: LIST:RANG1:FILT:TYPE RRC (Spurious Emissions)

RBW (Sweep List dialog box)

Sets the RBW value for this range.

Remote: ESP:RANG2:BAND:RES 5000 (Spectrum Emission Mask)

Remote: LIST:RANG2:BAND:RES 5000 (Spurious Emissions)

VBW (Sweep List dialog box)

Sets the VBW value for this range.

Remote: ESP:RANG1:BAND:VID 5000000 (Spectrum Emission Mask)

Remote: LIST:RANG1:BAND:VID 5000000 (Spurious Emissions)

Sweep Time Mode (Sweep List dialog box)

Activates or deactivates the auto mode for the sweep time.

Remote: ESP:RANG3:SWE:TIME:AUTO OFF (Spectrum Emission Mask)

Remote: LIST:RANG3:SWE:TIME:AUTO OFF (Spurious Emissions)

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.107 E-11

Sweep Time (Sweep List dialog box)

Sets the sweep time value for the range.

Remote: ESP:RANG1:SWE:TIME 1 (Spectrum Emission Mask)

Remote: LIST:RANG1:SWE:TIME 1 (Spurious Emissions)

Detector (Sweep List dialog box, Spurious Emissions)

Sets the detector for the range. For details refer to "Detector overview" on page 4.42.

Remote: LIST:RANGe3:DET SAMP

Ref. Level (Sweep List dialog box)

Sets the reference level for the range.

Remote: ESP:RANG2:RLEV 0 (Spectrum Emission Mask)

Remote: LIST:RANG2:RLEV 0 (Spurious Emissions)

RF Att. Mode (Sweep List dialog box)

Activates or deactivates the auto mode for RF attenuation.

Remote: ESP:RANG2:INP:ATT:AUTO OFF (Spectrum Emission Mask)

Remote: LIST:RANG2:INP:ATT:AUTO OFF (Spurious Emissions)

RF Attenuator (Sweep List dialog box)

Sets the attenuation value for that range.

Remote: ESP:RANG3:INP:ATT 10 (Spectrum Emission Mask)

Remote: LIST:RANG3:INP:ATT 10 (Spurious Emissions)

Preamp (Sweep List dialog box)

Switches the preamplifier on or off.

Remote: ESP:RANG3:INP:GAIN:STATe ON (Spectrum Emission Mask)

Remote: LIST:RANG3:INP:GAIN:STATe ON (Spurious Emissions)

Sweep Points (Sweep List dialog box, Spurious Emissions)

Sets the number of sweep points per range. For details on possible values refer to the Sweep

Points softkey of the sweep menu.

Remote: LIST:RANG3:POIN 601

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.108 E-11

Stop after Sweep (Sweep List dialog box, Spurious Emissions)

Configures the sweep behavior.

On The R&S FSL stops after one range is swept and continues only if you confirm (a message

box is displayed).

Off The R&S FSL sweeps all ranges in one go.

Remote: LIST:RANG1:BRE ON

Transd. Factor (Sweep List dialog box)

Sets a transducer for the specified range. You can only choose a transducer that fulfills the

following conditions:

–The transducer overlaps or equals the span of the range.

– The x–axis is linear.

–The unit is dB.

Remote: ESP:RANG1:TRAN 'test' (Spectrum Emission Mask)

Remote: LIST:RANG1:TRAN 'test' (Spurious Emissions)

Limit Check 1 to 4 (Sweep List dialog box)

Sets the type of limit check for all ranges. Possible states are:

Absolute Checks only the absolute limits defined.

Relative Checks only the relative limits. Relative limits are defined as relative

to the measured power in the reference range.

Abs and

Rel

Combines the absolute and relative limit. The limit check fails when

both limits are violated.

Abs or Rel Combines the absolute and relative limit. The limit check fails when

one of the limits is violated.

The limit state affects the availability of all limit settings (Abs Limit Start,Abs Limit Stop,Rel

Limit Start,Rel Limit Stop).

Dependent on the number of active power classes (see Edit Power Classes dialog box), the

number of limits that can be set varies. Up to four limits are possible. The sweep list is extended

accordingly.

Remote: ESP:RANG3:LIM:STAT AND (Spectrum Emission Mask)

Remote: LIST:RANG3:LIM:STAT ON (Spurious Emissions)

Remote: CALC:LIM3:FAIL?

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.109 E-11

Abs Limit Start (Sweep List dialog box)

Sets an absolute limit value at the start frequency of the range [dBm].

This parameter is only available if the limit check is set accordingly (see Limit Check 1 to 4

parameter).

Dependent on the number of active power classes (see Edit Power Classes dialog box), the

number of limits that can be set varies. Up to four limits are possible. The sweep list is extended

accordingly.

Remote: ESP:RANG1:LIM:ABS:STAR 10 (Spectrum Emission Mask)

Remote: LIST:RANG1:LIM:STAR 10 (Spurious Emissions)

Abs Limit Stop (Sweep List dialog box)

Sets an absolute limit value at the stop frequency of the range [dBm].

This parameter is only available if the limit check is set accordingly (see Limit Check 1 to 4

parameter).

Dependent on the number of active power classes (see Edit Power Classes dialog box), the

number of limits that can be set varies. Up to four limits are possible. The sweep list is extended

accordingly.

Remote: ESP:RANG1:LIM:ABS:STOP 20 (Spectrum Emission Mask)

Remote: LIST:RANG1:LIM:STOP 20 (Spurious Emissions)

Rel Limit Start (Sweep List dialog box, Spectrum Emission Mask)

Sets a relative limit value at the start frequency of the range [dBc].

This parameter is only available if the limit check is set accordingly (see Limit Check 1 to 4

parameter).

Dependent on the number of active power classes (see Edit Power Classes dialog box), the

number of limits that can be set varies. Up to four limits are possible. The sweep list is extended

accordingly.

Remote: ESP:RANG3:LIM:REL:STAR –20

Rel Limit Stop (Sweep List dialog box, Spectrum Emission Mask)

Sets a relative limit value at the stop frequency of the range [dBc].

This parameter is only available if the limit check is set accordingly (see Limit Check 1 to 4

parameter).

Dependent on the number of active power classes (see Edit Power Classes dialog box), the

number of limits that can be set varies. Up to four limits are possible. The sweep list is extended

accordingly.

Remote: ESP:RANG3:LIM:REL:STOP 20

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.110 E-11

Edit Sweep List/Close Sweep List

Opens/ closes the Sweep List dialog box. Closing the dialog box updates the measurement

results.

For further details refer to "Ranges and range settings" on page 4.81.

This softkey is available from firmware version 1.80.

Insert before Range

Inserts a new range to the left of the currently focussed range. The range numbers of the

currently focused range and all higher ranges are increased accordingly. The maximum number

of ranges is 20.

For further details refer to "Ranges and range settings" on page 4.81.

This softkey is available from firmware version 1.80.

Remote: ESP:RANG3:INS BEF (Spectrum Emission Mask)

Insert after Range

Inserts a new range to the right of the currently focused range. The range numbers of all higher

ranges are increased accordingly. The maximum number of ranges is 20.

For further details refer to "Ranges and range settings" on page 4.81.

This softkey is available from firmware version 1.80.

Remote: ESP:RANG1:INS AFT (Spectrum Emission Mask)

Delete Range

Deletes the currently focused range, if possible. The range numbers are updated accordingly.

For further details refer to "Ranges and range settings" on page 4.81.

This softkey is available from firmware version 1.80.

Remote: ESP:RANG4:DEL (Spectrum Emission Mask)

Remote: LIST:RANG4:DEL (Spurious Emissions)

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.111 E-11

Edit Reference Range

Opens the Reference Range dialog box to edit the additional settings used for SEM

measurements.

–Peak Power

Measures the highest peak within the reference range.

–Channel Power

Measures the channel power within the reference range (integral bandwidth method).

If the Channel Power reference power type is activated, the dialog box is extended to define

additional settings:

–Tx Bandwidth

Defines the bandwidth used for measuring the channel power:

minimum span



value



span of reference range

–RRC Filter State

Activates or deactivates the use of an RRC filter.

–RRC Filter Settings

Sets the alpha value of the RRC filter. This pane is only available if the RRC filter is activated.

For further details refer to "Ranges and range settings" on page 4.81.

This softkey is available from firmware version 1.80.

Remote: ESP:RTYP PEAK

Remote: ESP:BWID 1MHZ

Remote: ESP:FILT OFF

Remote: ESP:FILT:ALPH 0.5

List Evaluation

Opens a submenu to edit the list evaluation settings.

This softkey is available from firmware version 1.80.

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.112 E-11

List Evaluation On/Off

Activates or deactivates the list evaluation.

This softkey is available from firmware version 1.80.

Remote: CALC:ESP:PSE:AUTO OFF (Spectrum Emission Mask)

Remote: CALC:PSE:AUTO OFF (Spurious Emissions)

Remote: TRAC? LIST

List Full Screen

Switches between split screen and full screen.

deactivated split screen (diagram and list)

activated list in full screen

This softkey is available from firmware version 1.80.

Remote: DISP:WIND2:SIZE LARG

Margin

Opens an edit dialog box to enter the margin used for the limit check/peak search.

This softkey is available from firmware version 1.80.

Remote: CALC:ESP:PSE:MARG 100 (Spectrum Emission Mask)

Remote: CALC:PEAK:MARG 100 (Spurious Emissions)

Show Peaks

In the diagram, marks all peaks with blue squares that have been listed during an active list

evaluation.

This softkey is available from firmware version 1.80.

Remote: CALC:ESP:PSE:PSH ON (Spectrum Emission Mask)

Remote: CALC:PSE:PSH ON (Spurious Emissions)

List Up/List Down

Scrolls through the evaluation list if the number of found peaks exceeds the number of rows

shown in the evaluation list table.

These softkeys are available from firmware version 1.80.

Save Evaluation List

Opens the ASCII File Export Name dialog box to save the result in ASCII format to a specified

file and directory. For further details refer also to the ASCII File Export softkey.

This softkey is available from firmware version 1.80.

Remote: MMEM:STOR:LIST 'test'

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.113 E-11

ASCII File Export

An example of an output file is given in "ASCII file export format (Spectrum Emission Mask)" on

page 4.88. For further details refer also to the ASCII File Export softkey in the trace menu of the

base unit.

This softkey is available from firmware version 1.80.

Remote: MMEM:STOR:LIST 'test'

Decim Sep

For details refer to the Decim Sep softkey in the trace menu of the base unit.

This softkey is available from firmware version 1.80.

Edit Power Classes

Opens a dialog box to modify the power class settings.

The dialog box contains the following elements:

–Used Power Classes

Choose the power classes to be used from this dropdown menu. It is only possible to select either

one of the defined power classes or all of the defined power classes together.

Only power classes for which limits are defined are available for selection.

–PMin / PMax

Defines the level limits for each power class. The range always starts at -200 dBm (-INF) and

always stops at 200 dBm (+INF). These fields cannot be modified. If more than one Power Class is

defined, the value of PMin must equal the value of PMax of the last Power Class and vice versa.

Power Measurements – MEAS Key R&S FSL

1300.2519.12 4.114 E-11

–Sweep List

Opens the sweep list dialog box. For details see the Sweep List dialog box.

–Add / Remove

Activates or deactivates power classes to be defined. Up to four power classes can be defined.

The number of active power classes affect the availability of the items of the Used Power

Classes dropdown menu.

This softkey is available from firmware version 1.90.

Remote: CALC:LIM:ESP:PCL ON

Remote: CALC:LIM:ESP:PCL MIN <numeric_value>

Remote: CALC:LIM:ESP:PCL:MAX <numeric_value>

Remote: CALC:LIM:ESP:PCL:COUN <numeric_value>

Remote: CALC:LIM:ESP:PCL:LIM ABS

Load Standard

Opens a dialog box to select an XML file which includes the desired standard specification. For

details on the provided XML files refer to "Provided XML files for the Spectrum Emission Mask

measurement" on page 4.82.

This softkey is available from firmware version 1.80.

Remote: ESP:PRES 'WCDMA\3GPP\DL\PowerClass_31_39.xml'

Save As Standard

Opens the Save As Standard dialog box, in which the currently used SEM settings and

parameters can be saved and exported into an *.xml file. Enter the name of the file in the file

name field. For details on the structure and contents of the XML file refer to "Format description

of Spectrum Emission Mask XML files" on page 4.83.

This softkey is available from firmware version 1.90.

Remote: SENS:ESP:STOR "<file name>"

Restore Standard Files

Copies the XML files from the C:\R_S\instr\sem_backup folder to the C:\R_S\instr\sem_std

folder. Files of the same name are overwritten.

This softkey is available from firmware version 1.80.

Remote: ESP:PRES:REST

R&S FSL Power Measurements – MEAS Key

1300.2519.12 4.115 E-11

Meas Start/Stop

Aborts/restarts the current measurement and displays the status:

Start The measurement is currently running.

Stop The measurement has been stopped, or, in single sweep mode, the end of the sweep

has been reached.

This softkey is available from firmware version 1.80.

Remote: ABOR

Remote: INIT:ESP (Spectrum Emission Mask)

Remote: INIT:SPUR (Spurious Emissions)

Remote: INIT:CONM (Spurious Emissions)

Spurious Emissions

Opens a submenu to configure the Spurious Emissions measurement.

The Spurious Emissions measurement defines a measurement that monitors unwanted RF

products outside the assigned frequency band generated by an amplifier. The spurious

emissions are usually measured across a wide frequency range. The Spurious Emissions

measurement allows a flexible definition of all parameters.

This softkey is available from firmware version 1.80.

Remote: SWE:MODE LIST

Adjust X–Axis

Adjusts the frequency axis of measurement diagram automatically so that the start frequency

matches the start frequency of the first sweep range, and the stop frequency of the last sweep

range.

This softkey is available from firmware version 1.80.

Power Measurements – MEAS Key R&S FSL

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Details On/Off

Configures the list contents.

On Displays the whole list contents.

Off Displays only the highest peaks (one peak per range).

This softkey is available from firmware version 1.80.

Peaks per Range

Opens an edit dialog box to enter the number of peaks per range that are stored in the list. Once

the selected number of peaks has been reached, the peak search is stopped in the current

range and continued in the next range. The maximum value is 50.

This softkey is available from firmware version 1.80.

Remote: CALC:PSE:SUBR 10

Harmonic Distortion

Opens a submenu to determine the settings for harmonics measurement and activates the

harmonic distortion measurement. With this measurement it is possible to measure easily the

harmonics e.g. from a VCO. In addition the THD (total harmonic distortion) is calculated in %

and dB.

With span > 0 Hz, an automatic search for the first harmonic is carried out within the set

frequency range. Also the level is adjusted. In zero span, the center frequency is unchanged.

In the upper pane, the zero span sweeps on all harmonics are shown, separated by display

lines. This provides a very good overview about the measurement. In the lower pane, the mean

RMS results are displayed in numerical values. The THD values are displayed in the marker

field.

This softkey is available from firmware version 1.10.

Remote: CALC:MARK:FUNC:HARM:STAT ON

Remote: CALC:MARK:FUNC:HARM:DIST? TOT

Remote: CALC:MARK:FUNC:HARM:LIST?

Harmonic On/Off

Activates/deactivates the harmonic distortion measurement.

This softkey is available from firmware version 1.10.

Remote: CALC:MARK:FUNC:HARM:STAT ON

No. of Harmonics

Sets the number of harmonics that shall be measured. The range is from 1 to 26.

This softkey is available from firmware version 1.10.

Remote: CALC:MARK:FUNC:HARM:NHAR 2

R&S FSL Power Measurements – MEAS Key

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Harmonic Sweep Time

For details refer to the Sweeptime Manual softkey in the bandwidth menu.

This softkey is available from firmware version 1.10.

Harmonic RBW Auto

Enables/disables the automatic adjustment of the resolution bandwidth. The automatic

adjustment is carried out according to:

RBWn = RBW1* n

If RBWnis not available, the next higher value is used.

This softkey is available from firmware version 1.10.

Remote: CALC:MARK:FUNC:HARM:BAND:AUTO OFF

Adjust Settings

Activates the frequency search in the frequency range that was set before starting the harmonic

measurement (if harmonic measurement was with span > 0) and adjusts the level.

This softkey is available from firmware version 1.10.

Remote: CALC:MARK:FUNC:HARM:PRES

Full Size Diagram (span > 0)

Displays the diagram in full screen size.

Remote: DISP:SIZE LARG|SMAL

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1300.2519.12 4.118 E-11

Using Limit Lines and Display Lines – LINES Key

The LINES key is used to configure limit and display lines.

To open the lines menu

Press the LINES key.

The lines menu and the Select Limit Line dialog box are displayed. For details on the Select Limit

Line dialog box refer to "To select a limit line" on page 4.119.

Menu and softkey description

–"Softkeys of the lines menu" on page 4.123

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"Display Lines" on page 4.122

–"Limit Lines" on page 4.123

Task

–To work with display lines

–To select a limit line

–To create a new limit line

–To edit an existing limit line

–To create a new limit line based upon an existing limit line

–To activate/deactivate a limit line

R&S FSL Using Limit Lines and Display Lines – LINES Key

1300.2519.12 4.119 E-11

To work with display lines

Initial situation: The line is switched on (softkey with highlighted background) or off (softkey without

highlighted background), for example the Display Line 1.

1. Press the Display Lines softkey.

2. Press the Display Line 1 softkey for the first time.

An edit dialog box is opened to enter the position of the display line (by rotary knob, step keys or

numerical entry). If the line was switched off, it is switched on. If it was switched on, it remains

switched on.

3. If another softkey is pressed, the edit dialog box for the Display Line 1 softkey is closed, but the

line remains switched on (softkey with highlighted background).

4. Press the Display Line 1 softkey for the second time.

The edit dialog box for the display line will be opened again.

5. Press the Display Line 1 softkey again.

The line is switched off (softkey without highlighted background).

To select a limit line

1. To display the Select Limit Line dialog box, press the LINES key or go to the main limit line menu.

All limit lines, saved in the default directory, and all subdirectories are displayed. For each limit line,

the following information is given:

Unit unit of the y–axis

Traces selected traces to check

Show limit line displayed in the measurement diagram or hidden

Compatible compatibility of the limit line to the current measurement settings

Using Limit Lines and Display Lines – LINES Key R&S FSL

1300.2519.12 4.120 E-11

2. To display only the limit lines that are compatible, activate the Show compatible option. For details

oncompatibility refer to "Limit Lines" on page 4.123.

3. To navigate into a subdirectory, use the Show Directory and Hide Directory buttons.

To create a new limit line

1. Press the New softkey to define a new limit line.

The Edit Limit Line dialog box is displayed. For more details on limit lines refer also to "Limit Lines"

on page 4.123.

2. Press the Edit Name softkey and enter a name, if you want to save the limit line in the main

directory. To save the limit line in an existing subdirectory, enter the relative path. A new

subdirectory can only be created using the FILE key (for details refer to section "Instrument

Functions – Basic Settings", "Saving and Recalling Settings Files – FILE Key".

3. To change the span setting, set the focus in the X–Axis field and change the unit via the rotary

knob: Hz for span > 0 Hz or sfor zero span.

4. To change between absolute and relative scale mode for the x–axis, set the focus on the abs or rel

option next to the X–Axis field and press the CHECKMARK key. Relative scaling is always

suitable, if masks for bursts are to be defined in zero span, or if masks for modulated signals are

required for span > 0 Hz.

absolute: The frequencies or times are interpreted as absolute physical units.

relative: In the data point table, the frequencies are referred to the currently set center

frequency. In the zero span mode, the left boundary of the diagram constitutes the

reference.

5. To change the scaling of the y–axis, set the focus in the Y–Axis field and change the unit using the

rotary knob.

6. To change between absolute and relative units for the y–axis, set the focus on the abs or rel option

next to the Y–Axis field and press the CHECKMARK key.

absolute: The limit values refer to absolute levels or voltages.

relative: The limit values refer to the reference level (Ref Level). Limit values with the unit dB

are always relative values.

7. To define the limit line as upper or lower limit line, set the focus on the Upper or Lower option and

press the CHECKMARK key.

8. To change between linear or logarithmic scale of the x–axis, set the focus on the lin or log option

and press the CHECKMARK key.

9. If the scaling of the y–axis is relative, you can define an absolute threshold value that works as a

lower limit for the relative limit values (see figure below). Set the focus in the Threshold field and

enter a value.

The function is especially useful for mobile radio applications provided the limit values are defined

in relation to the carrier power as long as they are above an absolute limit value.

R&S FSL Using Limit Lines and Display Lines – LINES Key

1300.2519.12 4.121 E-11

RBW 300 Hz

VBW 3 kHz

SWT 100 ms

Marker [T1]

-28.4 dBm

200.0100 MHz

10 kHz/

Ref -20 dBm Att 10 dB

Center 200 MHz Span 100 kHz

relative limit line

absolute threshold

resulting limit

10. To define a signal–level distance to the limit line, press the Edit Margin softkey and enter a value.

If the limit line is defined as an upper limit, the margin means that the level is below the limit line. If

the limit line is defined as a lower limit, the margin means that the level is above the limit line.

11. To enter a comment, press the Edit Comment and enter a comment, e.g. a description of the

application.

12. To enter a new data point:

–Press the Insert Value Above softkey.

–Enter the new x and y value in the successive displayed edit dialog boxes.

13. To change a data point:

–Set the focus on the x and y value to be changed and press the Value softkey.

–Enter the new x or y value in the displayed edit dialog box.

14. To delete a data point, select the corresponding entry and press the Delete Value softkey.

15. To shift the complete limit line parallel in the horizontal direction, select the Shift x button and enter

a x shift value.

16. To shift the complete limit line parallel in the vertical direction, select the Shift y button and and

enter an y shift value.

17. Press the Save Limit Line softkey.

If an existing name is used, a message box is displayed. You have to confirm before the limit line is

overwritten.

To edit an existing limit line

1. In the Select Limit Line dialog box, select the limit line you want to alter. For details see also "To

select a limit line" on page 4.119.

2. Press the Edit softkey.

3. Edit the data as described in "To select a limit line" on page 4.119.

4. Save the limit line (Save Limit Line softkey).

To create a new limit line based upon an existing limit line

1. In the Select Limit Line dialog box, select the limit line you want to use as a basis for a new limit

line. For details see also "To select a limit line" on page 4.119.

2. Press the Copy to softkey to transfer the data of the limit line into the Edit Limit Line dialog box.

3. Press the Edit Name softkey and enter a new name.

Using Limit Lines and Display Lines – LINES Key R&S FSL

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4. To shift the complete limit line parallel in the horizontal direction, select the Shift x button and enter

an x shift value. In this manner, a new limit line can be easily generated based upon an existing

limit line which has been shifted horizontally.

5. To shift the complete limit line parallel in the vertical direction, select the Shift y button and enter a

yshift value. In this manner, a new limit line can be easily generated based upon an existing limit

line which has been shifted in Y direction

6. If required, edit the data as described in "To select a limit line" on page 4.119.

7. Save the limit line (Save Limit Line softkey).

To activate/deactivate a limit line

Prerequisites:

•The x– and y–units of limit line and current measurement setting have to be compatible. For details

refer to "Limit Lines" on page 4.123.

•The limit line has to consist of 2 or more data points.

1. In the Select Limit Line dialog box, select the limit line you want to activate/deactivate. For details

see also "To select a limit line" on page 4.119.

2. To activate or deactivate a limit line for a trace, press the Select Traces to check softkey and

select or deselect the trace(s) to which this limit line applies.

3. To deactivate the limit line for all traces, press the Deselect All softkey.

Display Lines

Display lines help to evaluate a trace – as do markers. The function of a display line is comparable to

that of a ruler that can be shifted on the trace in order to mark absolute values. They are exclusively

used to optically mark relevant frequencies or points in time (span = 0) as well as constant level values.

It is not possible to check automatically whether the points are below or above the marked level values.

The softkeys for setting and switching the display lines on/off work like triple switches. For details see

"To work with display lines" on page 4.119.

Two different types of display lines are provided:

•Two horizontal level lines for marking levels – Display Line 1 and 2

The level lines are continuous horizontal lines across the entire width of a diagram and can be

shifted in y direction.

•Two vertical frequency or time lines for marking frequencies or points in time – Frequency/Time

Line 1 and 2

The frequency or time lines are continuous vertical lines across the entire height of the diagram and

can be shifted in x direction.

Each line is identified by one of the following abbreviations:

•D1: Display Line 1

•D2: Display Line 2

•F1: Frequency Line 1

•F2: Frequency Line 2

•T1: Time Line 1

•T2: Time Line 2

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Limit Lines

Limit lines are used to define amplitude curves or spectral distribution boundaries on the display screen

which are not to be exceeded. They indicate, for example, the upper limits for interference radiation or

spurious waves which are allowed from a device under test (DUT). For transmission of information in

TDMA systems (e.g. GSM), the amplitude of the bursts in a timeslot must adhere to a curve that falls

within a specified tolerance band. The lower and upper limits may each be specified by a limit line.

Then, the amplitude curve can be controlled either visually or automatically for any violations of the

upper or lower limits (GO/NOGO test).

The instrument supports limit lines with a maximum of 50 data points. 8 of the limit lines stored in the

instrument can be activated simultaneously. The number of limit lines stored in the instrument is only

limited by the capacity of the flash disk used. For details see also "To select a limit line" on page 4.119.

Limit lines are compatible with the current measurement settings, if the following applies:

•The x unit of the limit line has to be identical to the current setting.

•The y unit of the limit line has to be identical to the current setting with the exception of dB based

units; all dB based units are compatible with each other.

At the time of entry, the R&S FSL immediately checks that all limit lines are in accordance with the

following guidelines:

•The frequencies/times for each data point must be entered in ascending order, however, for any

single frequency/time, two data points may be entered (vertical segment of a limit line).

•The data points are allocated in order of ascending frequency/time. Gaps are not allowed. If gaps

are desired, two separate limit lines must be defined and then both enabled.

•The entered frequencies/times need not necessarily be selectable in R&S FSL. A limit line may also

exceed the specified frequency or time range. The minimum frequency for a data point is –200

GHz, the maximum frequency is 200 GHz. For the time range representation, negative times may

also be entered. The allowed range is –1000 s to +1000 s.

Softkeys of the lines menu

The following table shows all softkeys available in the lines menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Command

Select Traces to check

Deselect All

New Edit Name

Edit Comment

Edit Margin

Value

Insert Value Above

Delete Value

Save Limit Line

Edit same contents as

New Limit Line menu

Copy to same contents as

New Limit Line menu

Delete

Using Limit Lines and Display Lines – LINES Key R&S FSL

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Display Lines Display Line 1

Display Line 2

Frequency Line 1

Frequency Line 2

Time Line 1

Time Line 2

Select Traces to check

Opens the Select Traces to Check dialog box to activate the selected limit line for a trace. One

limit line can be activated for several traces simultaneously. For details see also "To

activate/deactivate a limit line"on page 4.122 .

This softkey is available from firmware version 1.10.

Remote: CALC:LIM2:TRAC 3

Remote: CALC:LIM:STAT ON

Deselect All

Deactivates the selected limit line for all assigned traces. For details see also "To

activate/deactivate a limit line"on page 4.122 .

This softkey is available from firmware version 1.10.

Remote: CALC:LIM:STAT OFF

New

Opens the Edit Limit Line dialog box and a submenu to define a new limit line. For details see

also "Limit Lines" on page 4.123 and "To select a limit line" on page 4.119.

This softkey is available from firmware version 1.10.

Edit Name

Sets the focus on the Name field to enter or change the limit line name. A maximum of 8

characters is permitted for each name. All names must be compatible with the Windows XP

conventions for file names. The limit line data are stored under this name. The instrument stores

all limit lines with LIM as extension.

This softkey is available from firmware version 1.10.

Remote: CALC:LIM3:NAME "GSM1

Edit Comment

Sets the focus on the Comment field to enter or change a comment for the limit line. The text

must not exceed 40 characters.

This softkey is available from firmware version 1.10.

Remote: CALC:LIM5:COMM 'Upper limit for spectrum'

R&S FSL Using Limit Lines and Display Lines – LINES Key

1300.2519.12 4.125 E-11

Edit Margin

Sets the focus on the Margin field to enter or change a margin for the limit line. The default

setting is 0 dB (i.e. no margin).

This softkey is available from firmware version 1.10.

Value

Opens an edit dialog box to change an existing x or y value, depending on the selected column.

The softkey is only available if an existing value is selected.

The desired data points are entered in ascending order (two repeated frequencies/time values

are permitted).

This softkey is available from firmware version 1.10.

Remote: CALC:LIM3:CONT:DATA 1MHz,3MHz,30MHz

Remote: CALC:LIM3:UPP:DATA –10,0,0

Remote: CALC:LIM3:LOW:DATA –30,–40,–40

Insert Value Above

Creates an empty line above the selected data point to enter a new data point. This softkey

corresponds to the Insert button in the dialog box.

It is also possible to add a data point at the end of the list, if the focus is set below the last entry

line of the list.

The data points are entered in ascending order (two repeated frequencies/time values are

permitted). If the entered values are not in accordance with the ascending order rule, an error

message is displayed and the values are discarded.

This softkey is available from firmware version 1.10.

Delete Value

Deletes the selected data point (x and y value). All succeeding data points are shifted up

accordingly. This softkey corresponds to the Delete button in the dialog box.

The softkey is only available if an existing value is selected.

This softkey is available from firmware version 1.10.

Save Limit Line

Saves the currently edited limit line under the name defined in the Name field.

This softkey is available from firmware version 1.10.

Using Limit Lines and Display Lines – LINES Key R&S FSL

1300.2519.12 4.126 E-11

Edit

Opens a submenu to edit limit lines. For details see also "Limit Lines" on page 4.123 and "To

edit an existing limit line" on page 4.121.

This softkey is available from firmware version 1.10.

Remote: For details refer to chapter "Remote Control – Commands", section "Definition of the limit

line".

Copy to

Copies the data of the selected limit line and displays it in the Edit Limit Line dialog box. If the

limit line is edited and saved under a new name, a new limit line can be easily generated by

parallel translation or editing of an existing limit line.

For details see also "Limit Lines" on page 4.123 and "To create a new limit line based upon an

existing limit line" on page 4.121.

This softkey is available from firmware version 1.10.

Remote: CALC:LIM3:COPY 2

Delete

Deletes the selected limit line.

This softkey is available from firmware version 1.10.

Remote: CALC:LIM3:DEL

Display Lines

Opens a submenu to enable, disable and set display lines. Which softkeys are available

depends on the display mode (frequency or time range). For details see also "Display Lines" on

page 4.122 and "To work with display lines" on page 4.119.

Display Line 1 and Display Line 2

Enable or disable the level lines 1/2 and open an edit dialog box to enter the position of the

lines. For details see also "Display Lines" on page 4.122 and "To work with display lines" on

page 4.119.

Remote: CALC:DLIN:STAT ON

Remote: CALC:DLIN –20dBm

Frequency Line 1 and Frequency Line 2 (span > 0)

Enable or disable the frequency lines 1/2 and open an edit dialog box to enter the position of the

lines. For details see also "Display Lines" on page 4.122 and "To work with display lines" on

page 4.119.

Remote: CALC:FLIN:STAT ON

Remote: CALC:FLIN 120MHz

R&S FSL Using Limit Lines and Display Lines – LINES Key

1300.2519.12 4.127 E-11

Time Line 1 and Time Line 2 (zero span)

Enable or disable the time lines 1/2 and open an edit dialog box to enter the position of the lines.

For details see also "Display Lines" on page 4.122 and "To work with display lines" on page

4.119.

Remote: CALC:TLIN:STAT ON

Remote: CALC:TLIN 10ms

Using Limit Lines and Display Lines – LINES Key R&S FSL

1300.2519.12 4.128 E-11

Measurement Modes

This section describes the provided measurement modes, the change of measurement modes and the

access to the menus of all active measurement modes. For details refer to the following sections:

•"Measurement Mode Selection – MODE Key" on page 4.129

•"Measurement Mode Menus – MENU Key" on page 4.131

R&S FSL Measurement Mode Selection – MODE Key

1300.2519.12 4.129 E-11

Measurement Mode Selection – MODE Key

The MODE key provides a quick access to the menu of the current measurement mode and a fast

change of the measurement mode. You can choose from the following measurement modes:

•Spectrum Analyzer mode

•Analog Demodulation mode (Analog Demodulation option, K7)

•Bluetooth mode (Bluetooth Measurements option, K8)

•Cable TV Analyzer mode (Cable TV Measurements option, K20)

•Noise mode (Noise Figure Measurements option, K30)

•3G FDD BTS mode (3GPP Base Station Measurements option, K72)

•CDMA2000 BTS Analyzer mode (CDMA2000 Base Station Measurements option, K82)

•1xEV-DO BTS Analyzer mode (1xEV-DO Base Station Measurements option, K84)

•WLAN mode (WLAN TX Measurements option, K91/K91n)

•WiMAX mode (WiMAX IEEE 802.16 OFDM, OFDMA Measurements option, K92/K93)

To change the measurement mode

1. Press the MODE key.

The menu of the current measurement mode is displayed and the Measurement Modes dialog box

is opened.

2. To activate another mode, select the corresponding option and press the CHECKMARK key. More

than one measurement mode can be activated simultaneously.

3. To deactivate an activated mode, select the corresponding option and press the CHECKMARK

key.

Spectrum Analyzer mode

In the Spectrum Analyzer mode the functions provided correspond to those of a conventional

spectrum analyzer. The analyzer measures the frequency spectrum of the test signal over the selected

frequency range with the selected resolution and sweep time, or, for a fixed frequency, displays the

waveform of the video signal. This mode is set in the initial configuration.

Analog Demodulation mode (Analog Demodulation option, K7)

The Analog Demodulation mode requires an instrument equipped with the corresponding optional

software. This mode provides measurement functions for demodulating AM, FM, or PM signals. For

details refer to "Analog Demodulation (Option K7)" on page 4.140.

Bluetooth mode (Bluetooth Measurements option, K8)

The Bluetooth mode requires an instrument equipped with the corresponding optional software. This

mode provides measurements to test the conformity of signal sources to the Bluetooth RF Test

Specifications. For details refer to "Bluetooth Measurements (Option K8)" on page 4.158.

Measurement Mode Selection – MODE Key R&S FSL

1300.2519.12 4.130 E-11

Cable TV Analyzer mode (Cable TV Measurements option, K20)

The Cable TV Analyzer mode requires an instrument equipped with the corresponding optional

software. This mode provides ready–made measurements for analog and digital TV signals where most

of the parameters are set automatically. For details refer to "Cable TV Measurements (Option K20)" on

page 4.203.

Noise mode (Noise Figure Measurements option, K30)

The Noise mode requires an instrument equipped with the corresponding optional software. This mode

provides accurate and flexible noise measurement functions. For details refer to "Noise Figure

Measurements Option (K30)" on page 4.247.

3G FDD BTS mode (3GPP Base Station Measurements option, K72)

The 3G FDD BTS mode requires an instrument equipped with the corresponding optional software.

This mode provides test measurements for WCDMA downlink signals (base station signals) according

to the test specification. For details refer to "3GPP Base Station Measurements (Option K72)" on page

4.271.

CDMA2000 BTS Analyzer mode (CDMA2000 Base Station Measurements option,

K82)

The CDMA2000 BTS Analyzer mode requires an instrument equipped with the corresponding optional

software. This mode provides test measurements on forward link signals (base station) according to the

3GPP2 Standard (Third Generation Partnership Project 2). For details refer to "CDMA2000 BTS

Analyzer (Option K82)"on page 4.295.

1xEV-DO BTS Analyzer mode (1xEV-DO Base Station Measurements option, K84)

The 1xEV-DO BTS Analyzer mode requires an instrument equipped with the corresponding optional

software. This mode provides test measurements on forward link signals (base station) according to the

3GPP2 Standard (Third Generation Partnership Project 2). For details refer to "1xEV-DO BTS Analyzer

(Option K84)" on page 4.356.

WLAN mode (WLAN TX Measurements option, K91/K91n)

The WLAN mode requires an instrument equipped with the corresponding optional software. This mode

provides Wireless LAN TX measurement functions according to IEEE 802.11 a, b, g, j and n standards.

For details refer to "WLAN TX Measurements (Option K91 / K91n)" on page 4.409.

WiMAX mode (WiMAX IEEE 802.16 OFDM, OFDMA Measurements option, K92/K93)

The WiMAX mode requires an instrument equipped with the WiMAX IEEE 802.16 OFDM, OFDMA

Measurements option (R&S FSL–K93). This mode provides WiMAX and WiBro measurement functions

according to IEEE standards 802.16–2004 OFDM and 802.16e–2005 OFDMA/WiBro. It includes the

WiMAX 802.16 OFDM Measurements option (R&S FSL–K92). For details refer to "WiMAX, WiBro

Measurements (Options K92/K93)" on page 4.441.

R&S FSL Measurement Mode Menus – MENU Key

1300.2519.12 4.131 E-11

Measurement Mode Menus – MENU Key

The MENU key provides a quick access to the menu of the current measurement mode. For details on

measurement modes refer to "Measurement Mode Selection – MODE Key" on page 4.129.

To access the main menu of an active measurement mode

Press the MENU key.

The menu of the current measurement mode is displayed.

If the tracking generator, the power meter, and the spectrogram are available in the current

measurement mode, softkeys for these functions are also provided In the Spectrum Analyzer

mode with active acoustic monitoring, the softkey Marker Demod Volume to control the volume

control for acoustic monitoring is displayed.

Menu and softkey description

–"Optional softkeys of the menu menu" on page 4.131

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Optional softkeys of the menu menu

Apart from the softkeys of the current measurement mode, the following optional softkeys are available

in the menu menu. It is possible that the basic unit does not provide all these softkeys. If a softkey is

only available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Menu / Command

Tracking Generator

Power Meter

Spectrogram

Marker Demod Volume

Tracking Generator (models 13, 16 and 28)

Displays the menu of the Tracking Generator measurement mode. For details refer to

"Tracking Generator (Models 13, 16 and 28)" on page 4.134.

Power Meter (Power Sensor Support option, K9)

Displays the menu of the Power Meter measurement mode. For details refer to "Power Meter

(Option K9)" on page 4.186.

Measurement Mode Menus – MENU Key R&S FSL

1300.2519.12 4.132 E-11

Spectrogram (Spectrogram Measurement option, K14)

Displays the menu of the Spectrogram Measurement option. For details refer to "Spectrogram

Measurement (Option K14)" on page 4.191.

Marker Demod Volume (Spectrum Analyzer mode)

Opens a dialog box to regulate the volume for acoustic monitoring.

R&S FSL Measurement Mode Menus – MENU Key

1300.2519.12 4.133 E-11

Models and Options

This section describes models and firmware options that are not included in the basic unit configuration.

If hardware options are controlled via the firmware, the provided softkeys are described in the

corresponding menu section. The information, with which special option or model these softkeys are

supplied, is delivered in the corresponding softkey description.

Alist of all available hardware and firmware options is provided on CD-ROM. To check the options your

instrument provides, refer to the Quick Start Guide, chapter 2 "Preparing for Use". For details on

models and firmware options refer to the following sections:

•"Tracking Generator (Models 13, 16 and 28)" on page 4.134

•"Analog Demodulation (Option K7)" on page 4.140

•"Bluetooth Measurements (Option K8)" on page 4.158

•"Power Meter (Option K9)" on page 4.186

•"Spectrogram Measurement (Option K14)" on page 4.191

•"Cable TV Measurements (Option K20)" on page 4.203

•"Noise Figure Measurements Option (K30)" on page 4.247

•"3GPP Base Station Measurements (Option K72)" on page 4.271

•"CDMA2000 BTS Analyzer (Option K82)" on page 4.295

•"1xEV-DO BTS Analyzer (Option K84)" on page 4.356

•"WLAN TX Measurements (Option K91 / K91n)" on page 4.409

•"WiMAX, WiBro Measurements (Options K92/K93)" on page 4.441

Tracking Generator (Models 13, 16 and 28) R&S FSL

1300.2519.12 4.134 E-11

Tracking Generator (Models 13, 16 and 28)

During operation the tracking generator emits a signal exactly at the input frequency of the R&S FSL.

The tracking generator can be used in all measurement modes. Acquisition of test setup calibration

values (see Source Cal softkey) and normalization using these correction values (see Normalize

softkey) is only possible in the tracking generator measurement mode. For details on measurement

modes refer to "Measurement Mode Selection – MODE Key" on page 4.129.

FFT filters (for details see "To choose the appropriate filter type" on page 4.19) are not available if the

tracking generator is active.

For measurements with running tracking generator it is recommended to set the start frequency to 3 x

resolution bandwidth in order to meet the data sheet accuracy.

Note: The RF characteristics of some DUTs are especially sensitive concerning the input VSWR. In

such cases insertion of 10–20 dB attenuation between the DUT and the tracking generator

output is recommended.

To open the tracking generator menu

1. Press the MENU key.

2. Press the Tracking Generator softkey.

The tracking generator menu is displayed.

Menu and softkey description

–"Softkeys of the tracking generator menu" on page 4.137

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"Transmission measurement" on page 4.135

–"Reflection measurement" on page 4.135

–"Calibration mechanism" on page 4.136

Tasks

–To calibrate for transmission and reflection measurement

R&S FSL Tracking Generator (Models 13, 16 and 28)

1300.2519.12 4.135 E-11

To calibrate for transmission and reflection measurement

Prerequisite: The instrument is in tracking generator measurement mode (for details refer to

"Measurement Mode Selection – MODE Key" on page 4.129).

1. Press the Source Power softkey to enter the generator output level.

If the tracking generator is off, it is switched on.

2. To enter a constant level offset for the tracking generator, press the Power Offset softkey.

3. Press the Source Cal softkey to open the submenu for calibration.

4. To record a reference trace for transmission measurement, press the Cal Trans softkey.

The recording of the reference trace and the completion of the calibration sweep are indicated

by message boxes.

5. To record a reference trace for reflection measurement, press the Cal Refl Short or Cal Refl Open

softkey.

The recording of the reference trace and the completion of the calibration sweep are indicated

by message boxes.

6. Press the Normalize softkey to switch on the normalization.

7. Press the Ref Value Position softkey to display the reference line.

8. Press the Ref Value softkey to enter a value to shift the reference line.

9. Press the Recall softkey to restore the settings used for source calibration.

Transmission measurement

This measurement will yield the transmission characteristics of a two–port network. The built–in tracking

generator serves as a signal source. It is connected to the input connector of the DUT. The input of the

R&S FSL is fed from the output of the DUT. A calibration can be carried out to compensate for the

effects of the test setup (e.g. frequency response of connecting cables).

DUT

GEN OUTPUT RF INPUT

Fig. 4-8: Test setup for transmission measurement

Reflection measurement

Scalar reflection measurements can be carried out by means of a reflection–coefficient measurement

bridge.

DUT

GEN OUTPUT RF INPUT

Bridge

Fig. 4-9: Test setup for reflection measurement

Tracking Generator (Models 13, 16 and 28) R&S FSL

1300.2519.12 4.136 E-11

Calibration mechanism

Calibration means a calculation of the difference between the currently measured power and a

reference curve, independent of the selected type of measurement (transmission/reflection). The

hardware settings used for measuring the reference curve are included in the reference dataset.

Even with normalization switched on, the device settings can be changed in a wide area without

stopping the normalization. This reduces the necessity to carry out a new normalization to a minimum.

For this purpose the reference dataset (trace with 501 measured values) is stored internally as a table

of 501 points (frequency/level).

Differences in level settings between the reference curve and the current device settings are taken into

account automatically. If the span is reduced, a linear interpolation of the intermediate values is applied.

If the span increases, the values at the left or right border of the reference dataset are extrapolated to

the current start or stop frequency, i.e. the reference dataset is extended by constant values.

An enhancement label is used to mark the different levels of measurement accuracy. This

enhancement label is displayed at the right diagram border if normalization is switched on and a

deviation from the reference setting occurs. Three accuracy levels are defined:

Table 4-8: Measurement accuracy levels

Accuracy Enhancement label Reason/Limitation

high NOR no difference between reference setting and measurement

medium APX (approximation) change of the following settings:

coupling (RBW, VBW, SWT)

reference level, RF attenuation

start or stop frequency

output level of tracking generator

detector (max. peak, min. peak, sample, etc.)

change of frequency:

max. 501 points within the set sweep limits (corresponds to a doubling of the span)

–Aborted normalization more than 500 extrapolated points within the current sweep limits (in case of span

doubling)

Note: At a reference level of –10 dBm and at a tracking generator output level of the same value the

R&S FSL operates without overrange reserve, i.e. the R&S FSL is in danger of being

overloaded if a signal is applied whose amplitude is higher than the reference line. In this case,

either the message OVLD for overload or IFOVL for exceeded display range (clipping of the

trace at the upper diagram border = overrange) is displayed in the status line.

Overloading can be avoided as follows:

•Reducing the output level of the tracking generator (Source Power softkey in the tracking

generator menu)

•Increasing the reference level (Ref Level softkey in the amplitude menu)

R&S FSL Tracking Generator (Models 13, 16 and 28)

1300.2519.12 4.137 E-11

Softkeys of the tracking generator menu

The following table shows all softkeys available in the tracking generator menu. It is possible that your

instrument configuration does not provide all softkeys. If a softkey is only available with a special option,

model or (measurement) mode, this information is delivered in the corresponding softkey description.

For the description of the other main softkeys refer to "Optional softkeys of the menu menu" on page

4.131.

Menu / Command Command

Source On/Off

Source Power

Power Offset

Source Cal Cal Trans

Cal Refl Short

Cal Refl Open

Normalize

Ref Value Position

Ref Value

Recall

Source On/Off

Switches the tracking generator on or off. Default setting is off.

If the tracking generator is switched off, the corresponding hardware settings and the

normalization are discarded. To switch off the tracking generator but keep the hardware settings

and the normalization, enter –400 dBm into the edit dialog box displayed by pressing the

Source Power softkey.

Remote: OUTP:STAT ON

Source Power

Opens an edit dialog box to enter a tracking generator output power. The default output power is

–20 dBm. The range is specified in the data sheet. Additionally, the value –400 dBm is available

to switch off the tracking generator but keep the hardware settings.

If the tracking generator is off, it is automatically switched on if an output power value is entered.

For details on switching on or off refer to the Source On/Off softkey.

Remote: SOUR:POW –20dBm

Tracking Generator (Models 13, 16 and 28) R&S FSL

1300.2519.12 4.138 E-11

Power Offset

Opens an edit dialog box to enter a constant level offset for the tracking generator. Values from

–200 dB to +200 dB in 1 dB steps are allowed. The default setting is 0 dB. Offsets are indicated

by the enhancement label LVL.

With this offset for example attenuators or amplifiers at the output connector of the tracking

generator can be taken into account for the displayed output power values on screen or during

data entry. Positive offsets apply to an amplifier and negative offsets to an attenuator

subsequent to the tracking generator.

Remote: SOUR:POW:OFFS –10dB

Source Cal

Opens a submenu to configure calibration for transmission and reflection measurement. For

details on the test setups see "Transmission measurement" on page 4.135 and "Reflection

measurement" on page 4.135.

Cal Trans

Starts a sweep that records a reference trace. This trace is used to calculate the difference for

the normalized values.

Remote: CORR:METH TRAN

Cal Refl Short

Starts a sweep as reference trace for short–circuit calibration.

If both calibrations (open circuit, short circuit) are carried out, the calibration curve is calculated

by averaging the two measurements and stored in the memory. The order of the two calibration

measurements is free.

Remote: CORR:METH REFL

Cal Refl Open

Starts a sweep as reference trace the open–circuit calibration.

If both calibrations (open circuit, short circuit) are carried out, the calibration curve is calculated

by averaging the two measurements and stored in the memory. The order of the two calibration

measurements is free.

Remote: CORR:COLL OPEN

Normalize

Switches the normalization on or off. The softkey is only available if the memory contains a

reference trace. For details on normalization see "Calibration mechanism" on page 4.136.

Remote: CORR ON

R&S FSL Tracking Generator (Models 13, 16 and 28)

1300.2519.12 4.139 E-11

Ref Value Position

Switches the reference line on or off. The reference line marks the reference position at which

the normalization result (calculated difference with a reference trace) is displayed. For details on

the reference line see "Calibration mechanism" on page 4.136.

Remote: DISP:WIND:TRAC:Y:RPOS 10PCT

Ref Value

Opens an edit dialog box to enter a position value that shifts the reference line vertically. By

default the reference line corresponds to a difference of 0 dB between the currently measured

trace and the reference trace.

If, e.g. after a source calibration, a 10 dB attenuation is inserted into the signal path between

DUT and R&S FSL input, the measurement trace will be moved by 10 dB down. Entering a

reference value of –10 dB will shift the reference line also by 10 dB down and place the

measurement trace on the reference line. The deviation from the nominal power level can be

displayed with higher resolution (e.g. 1 dB/div). The power is still displayed in absolute values.

Remote: DISP:WIND:TRAC:Y:RVAL –10dB

Recall

Restores the settings that were used during source calibration. This can be useful if device

settings were changed after calibration (e.g. center frequency, frequency deviation, reference

level, etc).

Remote: CORR:REC

Analog Demodulation (Option K7) R&S FSL

1300.2519.12 4.140 E-11

Analog Demodulation (Option K7)

The digital signal processing in the R&S FSL, used in the analyzer mode for digital IF filters, is also

ideally suited for demodulating AM, FM, or PM signals. The firmware option R&S FSL–K7 provides the

necessary measurement functions.

The R&S FSL is equipped with a demodulator that is capable of performing AM, FM, and PM

demodulation at a time. Additionally maximum, minimum and average or current values can be

obtained parallelly over a selected number of measurements.

By sampling (digitization) already at the IF and digital down–conversion to the baseband (I/Q), the

demodulator achieves maximum accuracy and temperature stability. There is no evidence of typical

errors of an analog down–conversion and demodulation like AM to FM conversion and vice versa,

deviation error, frequency response or frequency drift at DC coupling.

This option is available from firmware version 1.10.

To open the analog demodulation menu

If the Analog Demodulation mode is not the active measurement mode, press the MODE key and

activate the Analog Demodulation option.

If the Analog Demodulation mode is already active, press the MENU key.

The analog demodulation menu is displayed. If the tracking generator (models 13, 16 and 28) or the

power meter (option Power Sensor Support, K9) is available, softkeys for these functions are also

provided.

Menu and softkey description

–"Softkeys of the analog demodulation menu" on page 4.144

–"Softkeys of the frequency menu (Analog Demodulation mode)" on page 4.150

–"Softkeys of the span menu (Analog Demodulation mode)" on page 4.152

–"Softkeys of the amplitude menu (Analog Demodulation mode)" on page 4.153

–"Softkeys of the bandwidth menu (Analog Demodulation mode)" on page 4.155

–"Softkeys of the sweep menu (Analog Demodulation mode)" on page 4.155

–"Softkeys of the trigger menu (Analog Demodulation mode)" on page 4.156

Apart from the power measurement menu that is not available in the Analog Demodulation mode, all

other menus are provided as described for the base unit. For details refer to the corresponding menu

descriptions.

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"Circuit description – block diagrams" on page 4.141

–"Demodulation bandwidth" on page 4.142

–"AF trigger" on page 4.142

–"Stability of measurement results" on page 4.142

–"Sample rate, measurement time and trigger offset" on page 4.143

R&S FSL Analog Demodulation (Option K7)

1300.2519.12 4.141 E-11

Circuit description – block diagrams

The software demodulator runs on the main processor of the analyzer. The demodulation process is

shown in Fig. 4-10: Block diagram of software demodulator. All calculations are performed

simultaneously with the same I/Q data set. Magnitude (= amplitude) and phase of the complex I/Q pairs

are determined. The frequency result is obtained from the differential phase.

For details on the analyzer signal processing refer to chapter "Remote Control – Commands", section

"TRACe:IQ Subsystem".

Fig. 4-10: Block diagram of software demodulator

The AM DC, FM DC and PM DC raw data of the demodulators is fed into the Trace Arithmetic block

that combines consecutive data sets. Possible trace modes are: Clear Write, Max Hold, Min Hold and

Average (for details refer to section "Trace mode overview" on page 4.40). The output data of the Trace

Arithmetic block can be read via remote control.

The collected measured values are evaluated by the selected detector (for details refer to chapter

"Instrument Functions", section "Detector overview". The result is displayed on the screen and can be

read out via remote control.

Analog Demodulation (Option K7) R&S FSL

1300.2519.12 4.142 E-11

In addition, important parameters are calculated:

•Acounter determines the modulation frequency for AM, FM, and PM.

•average power = carrier power (RF power)

•average frequency = carrier frequency offset (FM)

•The modulation depth or the frequency or phase deviation is displayed.

•AC coupling is possible with FM and PM display. The deviations are determined from the trace

data. +Peak, –Peak, ½ Peak–Peak and RMS are displayed.

Demodulation bandwidth

The demodulation bandwidth is not the 3 dB bandwidth but the useful bandwidth which is distortion–free

with regard to phase and amplitude.

Therefore the following formulas apply:

•AM: demodulation bandwidth



2 x modulation frequency

•FM: demodulation bandwidth



2 x (frequency deviation + modulation frequency)

•PM: demodulation bandwidth



2 x modulation frequency x (1 + phase deviation)

Note: If the center frequency of the analyzer is not set exactly to the signal frequency, the demodulation

bandwidth must be selected larger by the carrier offset, in addition to the requirement described

above. This also applies if FM or PM AC coupling has been selected.

In general, the demodulation bandwidth should be as narrow as possible to improve the S/N ratio. The

residual FM caused by noise floor and phase noise increases dramatically with the bandwidth,

especially with FM.

AF trigger

The analog demodulation option allows triggering to the demodulated signal. The display is stable if a

minimum of five modulation periods are within the recording time.

Triggering is always DC–coupled. Therefore triggering is possible directly to the point where a specific

carrier level, phase or frequency is exceeded or not attained.

Stability of measurement results

Despite amplitude and frequency modulation, the display of carrier power and carrier frequency offset is

stable.

This is achieved by a digital filter which sufficiently suppresses the modulation, provided, however, that

the measurement time is



3 x 1 / modulation frequency, i.e. that at least three periods of the AF signal

are recorded.

The mean carrier power for calculating the AM is also calculated with a digital filter that returns stable

results after a measurement time of



3 x 1 / modulation frequency, i.e. at least three cycles of the AF

signal must be recorded before a stable AM can be shown.

R&S FSL Analog Demodulation (Option K7)

1300.2519.12 4.143 E-11

Sample rate, measurement time and trigger offset

Depending on the sample rate, the maximum demodulation bandwidths listed in the table can be

obtained during the measurement. The permissible value range of the measurement time and trigger

offset depends on the selected demodulation bandwidth. If the AF filter or the AF trigger are not active,

the measurement time enlarges by 20%.

Demod.

bandwidth

Sample rate Measurement time Trigger offset

Min. Max. with

AF filter or

AF trigger

active

Max. with

AF filter and

AF trigger

deactive

Min. Max.

18 MHz 32 MHz 31.25 ns 12.5 ms 15 ms –12.5 ms 507.9 ms

10 MHz 32 MHz 31.25 ns 12.5 ms 15 ms –12.5 ms 507.9 ms

8MHz 16 MHz 62.5 ns 25 ms 30 ms –25 ms 1.015 s

5MHz 8 MHz 125 ns 50 ms 60 ms –50 ms 2.031 s

3MHz 4 MHz 250 ns 100 ms 120 ms –100 ms 4.063 s

1.6 MHz 2 MHz 500 ns 200 ms 240 ms –200 ms 8.126 s

800 kHz 1 MHz 1µs400 ms 480 ms –400 ms 16.25 s

400 kHz 500 kHz 2µs800 ms 960 ms –800 ms 32.50 s

200 kHz 250 kHz 4µs1.6 s 1.92 s –1.6 s 65.00 s

100 kHz 125 kHz 8µs3.2 s 3.84 s –3.2 s 130.0 s

50 kHz 62.5 kHz 16 µs6.4 s 7.68 s –6.4 s 260.0 s

25 kHz 31.25 kHz 32 µs12.8 s 15.36 s –12.8 s 520.0 s

12.5 kHz 15.625 kHz 64 µs25.6 s 30.72 s –25.6 s 1040 s

6.4 kHz 7,8125 kHz 128 µs51.2 s 61.44 s –51.2 s 2080 s

3.2 kHz 3,90625 kHz 256 µs102.4 s 122.88 s –102.4 s 4160 s

1.6 kHz 1,953125 kHz 512 µs204.8 s 245.76 s –204.8 s 8321 s

800 Hz 976,5625 Hz 1.024 ms 409.6 s 491.52 s –409.6 s 16643 s

400 Hz 488,28125 Hz 2.048 ms 819.2 s 983.04 s –819.2 s 33287 s

200 Hz 244,140625 Hz 4.096 ms 1638.4 s 1966.08 s –1638.4 s 66574 s

100 Hz 122,0703125 Hz 8.192 ms 3276.8 s 3932.16 s –3276.8 s 133148 s

Analog Demodulation (Option K7) R&S FSL

1300.2519.12 4.144 E-11

Softkeys of the analog demodulation menu

The following table shows all softkeys available in the analog demodulation menu. It is possible that

your instrument configuration does not provide all softkeys. If a softkey is only available with a special

option, model or (measurement) mode, this information is delivered in the corresponding softkey

description.

Menu / Command Submenu / Command Command

Modulation AM/FM/PM

Result Display AF Time Domain

AF Spectrum

RF Time Domain

RF Spectrum

Select Trace

Diagram Full Size

Demod BW

Meas Time

AF Range Dev per Division/dB per Division

Reference Position

Reference Value

Deviation Lin/Log

Demod Settings AF Coupling AC/DC

AF Filter Low Pass AF Filter

High Pass AF Filter

Deemphasis

Zero Phase Reference Point

Phase Wrap On/Off

Phase Unit Rad/Deg

More 

Zoom

Modulation AM/FM/PM

Selects the display of demodulated AM, FM, or PM signal. In single sweep mode, the data is

determined from the current I/Q data set, i.e. a change to AM/FM/PM does not trigger a new

measurement.

If FM is selected, the average value of the demodulated signal is mapped depending on the AF

Coupling AC/DC softkey setting.

Remote: CALC:FEED 'XTIM:FM'

R&S FSL Analog Demodulation (Option K7)

1300.2519.12 4.145 E-11

Result Display

Opens a submenu to select the measurement result to be displayed. The RF or AF signal in the

zero span or the RF or AF frequency spectrum determined via FFT can be selected for display.

In order to display the measurement results, the screen is divided in two halves. In the upper

half, the measurement results are displayed as a trace. In the lower half the results of additional

evaluation functions are shown.

All displays are determined from the I/Q data set recorded for the measurement. In single sweep

mode, the single data set recorded can be evaluated in all displays simply by switching the

result display.

AF Time Domain

Selects the AF display in zero span, calculated from the AM, FM, or PM signal.

Remote: CALC:FEED 'XTIM:FM'

AF Spectrum

Selects the display of the AF spectrum. The AF spectrum can be calculated from the AM, FM, or

PM signal in zero span.

Remote: CALC:FEED 'XTIM:FM:AFSP'

RF Time Domain

Selects the display of the RF signal in zero span. In contrast to normal analyzer operation, the

level values are determined from the recorded I/Q data set as root–mean–square values.

The softkey is not available if the RF spectrum display is selected.

Remote: CALC:FEED 'XTIM:RFP'

RF Spectrum

Selects the display of the RF signal in span > 0. In contrast to normal spectrum analyzer

operation, the measured values are determined using FFT from the recorded I/Q data set.

Remote: CALC:FEED 'XTIM:SPECTRUM'

Select Trace

Opens an edit dialog box to enter the number of the trace for which the data is to be displayed in

the lower half of the screen. Only activated traces can be selected.

Diagram Full Size

Switches the diagram to full screen size.

Remote: DISP:SIZE LARG

Analog Demodulation (Option K7) R&S FSL

1300.2519.12 4.146 E-11

Demod BW

Opens an edit dialog box to enter the demodulation bandwidth of the analog demodulation. The

demodulation bandwidth determines the sampling rate for recording the signal to be analyzed.

For details on the relation between demodulation bandwidth and sampling rate refer to "Sample

rate, measurement time and trigger offset" on page 4.143.

Remote: BAND:DEM 1MHz

Meas Time

Opens an editor for entering the measurement time of the analog demodulation. For details on

the measurement time values refer to "Sample rate, measurement time and trigger offset" on

page 4.143.

Remote: ADEM:MTIM 62.5US

Remote: SWE:TIME 10s

AF Range

Opens a submenu for determining the diagram scaling for AF displays.

The range for RF displays is set via the amplitude menu. For details refer to "Setting the Level

Display and Configuring the RF Input – AMPT Key" on page 4.13.

Dev per Division

Opens an edit dialog box to set the modulation depth or the phase or frequency deviation per

division:

AM display: 0.0001% to 1000%

FM display: 1 Hz/div to 1 MHz/div

PM display: 0.0001 rad/div to 1000 rad/div

The softkey is not available if logarithmic display is set (Deviation Lin/Log softkey).

Remote: DISP:WIND:TRAC:Y:PDIV 50kHz

dB per Division

Opens an edit dialog box to set the modulation depth or the FM or PM deviation to be displayed

in the range 0.1 dB/div to 20 dB/div.

The softkey is not available if linear display is set (Deviation Lin/Log softkey).

Remote: DISP:TRAC:Y:PDIV 5DB

R&S FSL Analog Demodulation (Option K7)

1300.2519.12 4.147 E-11

Reference Position

Determines the position of the reference line for the modulation depth or the phase or frequency

deviation on the y–axis of the diagram. By default, this line is set to 0.

The position is entered as a percentage of the diagram height with 100 % corresponding to the

upper diagram border. The default setting is 50 % (diagram center) for the display of the AM,

FM, or PM signal, and 100% (upper diagram border) for the AF spectrum display of the AM, FM,

or PM signal.

Remote: DISP:TRAC:Y:RPOS 50PCT

Reference Value

Determines the modulation depth or the frequency or phase deviation at the reference line of the

y–axis. The reference value is set separately for each display of the AM, FM, and PM signal and

the AF spectrum of the AM, FM, and PM signal.

–AM/FM/PM signal display

The trace display takes individual frequency/phase offsets into account (in contrast, the AF

Coupling AC/DC softkey permits automatic correction by the average frequency/phase offset

of the signal, and can therefore not be activated simultaneously).

Possible values: 0 and

10000% (AM), 0 and

10 MHz (FM), 0 and

10000 rad (PM).

–AF spectrum display of the AM/FM/PM signal

In the default setting, the reference value defines the modulation depth or the FM/PM deviation

at the upper diagram border.

Possible values: 0 and 10000% (AM), 0 and 10 MHz (FM), 0 and 10000 rad (PM).

Remote: DISP:TRAC:Y:RVAL 0HZ

Deviation Lin/Log

Switches between logarithmic and linear display of the modulation depth or the frequency or

phase deviation.

Remote: DISP:TRAC:Y:SPAC LOG

Demod Settings

Opens a submenu for the demodulation settings.

AF Coupling AC/DC

Controls the automatic correction of the frequency offset and phase offset of the input signal:

–FM signal display

If DC is selected, the absolute frequency is displayed, i.e. an input signal with an offset relative

to the center frequency is not displayed symmetrically with respect to the zero line.

If AC is selected, the frequency offset is automatically corrected, i.e. the trace is always

symmetric with respect to the zero line.

–PM signal display

Analog Demodulation (Option K7) R&S FSL

1300.2519.12 4.148 E-11

If DC is selected, the phase runs according to the existing frequency offset. In addition, the DC

signal contains a phase offset of



If AC is selected, the frequency offset and phase offset are automatically corrected, i.e. the

trace is always symmetric with respect to the zero line.

The softkey is not available with the AF spectrum display of the FM or PM signal.

Remote: ADEM:AF:COUP DC

AF Filter

Opens a submenu to select the appropriate filters. The bandwidth of the demodulated signal can

be reduced by high pass or low pass filters and also a de–emphasis can be switched on. The

selected filters are used for AM, FM and PM demodulation in common. Individual settings are

not possible.

Low Pass AF Filter

Opens the Low Pass AF Filter dialog box to select the filter type. Relative and absolute low

pass filter are available.

–Relative low pass filters:

The filters (3 dB) can be selected in % of the demodulation bandwidth. The filters are designed

as 5th–order Butterworth filter (30 dB/octave) and active for all demodulation bandwidths.

–Absolute low pass filters:

The filter are indicated by the 3 dB cutoff frequency. The 3 kHz and 15 kHz filters are designed

as 5th–order Butterworth filter (30 dB/octave). The 150 kHz filter is designed as 8th–order

Butterworth filter (48 dB/octave).

The absolute low pass filters are active in the following demodulation bandwidth range:

3kHz: 6.4 kHz



demodulation bandwidth



4MHz

15 kHz: 50 kHz



demodulation bandwidth



16 MHz

150 kHz: 400 kHz



demodulation bandwidth



16 MHz

Remote: FILT:LPAS ON

Remote: FILT:LPAS:FREQ 150kHz

Remote: FILT:LPAS:FREQ 25PCT

High Pass AF Filter

Opens the High Pass AF Filter dialog box to switch on a high pass filter with the given limit to

separate the DC component. The filters are indicated by the 3 dB cutoff frequency. The filters

are designed as 2nd–order Butterworth filter (12 dB/octave).

The high pass filters are active in the following demodulation bandwidth range:

50 Hz: 200 Hz



demodulation bandwidth



4MHz

300 Hz: 800 Hz



demodulation bandwidth



16 MHz

Remote: FILT:HPAS ON

Remote: FILT:HPAS:FREQ 300Hz

R&S FSL Analog Demodulation (Option K7)

1300.2519.12 4.149 E-11

Deemphasis

Opens the Deemphasis dialog box to switch on a deemphasis with the given time constant.

The deemphasis is active in the following demodulation bandwidth range:

25 Ms: 25 kHz



demodulation bandwidth



18 MHz

50 Ms: 6.4 kHz



demodulation bandwidth



18 MHz

75 Ms: 6.4 kHz



demodulation bandwidth



18 MHz

750 Ms: 800 Hz



demodulation bandwidth



4MHz

The following table shows the required demodulation bandwidth for an error less than 0.5 dB up

to a maximum AF frequency.

deemphasis 25 Ms50 Ms75 Ms750 Ms

max. AF frequency 25 kHz 12 kHz 8 kHz 800 Hz

required demodulation bandwidth



200 kHz



100 kHz



50 kHz



6.4 kHz

For higher AF frequencies the demodulation bandwidth must be increased.

Remote: FILT:DEMP ON

Remote: FILT:DEMP:TCON 750us

Zero Phase Reference Point

Defines the position at which the phase of the PM–demodulated signal is set to 0 rad. The entry

is made with respect to time. In the default setting, the first measured value is set to 0 rad.

This softkey is only available in the PM display with DC coupling.

Remote: ADEM:PM:RPO 500us

Phase Wrap On/Off

Activates/deactivates the phase wrap.

On The phase will be displayed in the range ±180° (



). For example, if the phase

exceeds +180°, 360° is subtracted from the phase value, with the display thus

showing >–180°.

Off The phase will not be wrapped.

This softkey in available in the PM signal displays.

Remote: CALC:FORM PHAS

Phase Unit Rad/Deg

Sets the phase unit to rad or deg for displaying PM signals.

Remote: UNIT:ANGL RAD

Analog Demodulation (Option K7) R&S FSL

1300.2519.12 4.150 E-11

Zoom

Activates or deactivates the zoom function. The zoom function is not available if the number of

measurement points falls below 501.

activated: A 1–to–1 allocation is selected, i.e. each measurement point corresponds to a

measured value. The start of the zoom window can be determined in the

associated field by entering the time.

deactivated: If more measured values than measurement points are available, several

measured values are combined in one measurement point according to the

method of the selected trace detector. For details on detectors refer to

"Detector overview" on page 4.42.

Remote: ADEM:ZOOM ON

Remote: ADEM:ZOOM:STARt 30US

Softkeys of the frequency menu (Analog Demodulation mode)

The following table shows all softkeys available in the frequency menu in Analog Demodulation mode

(FREQ key). It is possible that your instrument configuration does not provide all softkeys. If a softkey is

only available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Menu / Command Command

Center

CF Stepsize 0.1*Span/0.1*Demod BW

0.5*Span/0.5*Demod BW

x*Span/x*Demod BW

=Center

Manual

AF Center

AF Start

AF Stop

Center

For details refer to the Center softkey in the frequency menu of the base unit.

CF Stepsize

For details refer to the CF Stepsize softkey in the frequency menu of the base unit.

0.1*Span (RF Spectrum)

For details refer to the 0.1*Span softkey in the frequency menu of the base unit.

R&S FSL Analog Demodulation (Option K7)

1300.2519.12 4.151 E-11

0.1*Demod BW (AF/RF Time Domain, AF Spectrum)

For details see 0.1*RBW softkey in the frequency menu of the base unit.

0.5*Span (RF Spectrum)

For details refer to the 0.5*Span softkey in the frequency menu of the base unit.

0.5*Demod BW (AF/RF Time Domain, AF Spectrum)

For details see 0.5*RBW softkey in the frequency menu of the base unit.

x*Span (RF Spectrum)

For details refer to the x*Span softkey in the frequency menu of the base unit.

x*Demod BW (AF/RF Time Domain, AF Spectrum)

For details see x*RBW softkey in the frequency menu of the base unit.

=Center

For details refer to the =Center softkey in the frequency menu of the base unit.

Manual

For details refer to the Manual softkey in the frequency menu of the base unit.

AF Center (AF Spectrum)

Opens an edit box to enter the center frequency within the AF spectrum.

Remote: ADEM:AF:CENT 1MHZ

AF Start

Opens an edit box to define the start frequency within the AF spectrum.

Remote: ADEM:AF:STAR 0HZ

AF Stop

Opens an edit box to define the stop frequency within the AF spectrum.

The maximum AF stop frequency corresponds to half the demodulation bandwidth.

Remote: ADEM:AF:STOP 2MHZ

Analog Demodulation (Option K7) R&S FSL

1300.2519.12 4.152 E-11

Softkeys of the span menu (Analog Demodulation mode)

The following table shows all softkeys available in the span menu in Analog Demodulation mode

(SPAN key). It is possible that your instrument configuration does not provide all softkeys. If a softkey is

only available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Command

Span Manual/AF Span Manual

Demod Bandwidth

Full Span/AF Full Span

Span Manual (RF Spectrum)

If the RF spectrum display is active, values between the sampling rate/200 and the

demodulation bandwidth/2 are allowed.

For further details refer to the Span Manual softkey in the span menu of the base unit.

Remote: ADEM:SPEC:SPAN:ZOOM 5 MHz

AF Span Manual (AF Spectrum)

Opens an edit dialog box to enter the frequency range for the AF spectrum display. Values

between the sampling rate/1000 and the demodulation bandwidth/2 are allowed.

Remote: ADEM:AF:SPAN 2.5 MHz

Demod Bandwidth

For details see Demod BW softkey in the analog demodulation menu.

Full Span (RF Spectrum)

If the RF spectrum display is active, the full frequency range corresponds to the demodulation

bandwidth.

For further details refer to the Full Span softkey in the span menu of the base unit.

Remote: ADEM:SPEC:SPAN:ZOOM MAX

AF Full Span (AF Spectrum)

Sets the span to the maximum frequency range for the AF spectrum display. The maximum

frequency range corresponds to the demodulation bandwidth.

Remote: ADEM:AF:SPAN:FULL

R&S FSL Analog Demodulation (Option K7)

1300.2519.12 4.153 E-11

Softkeys of the amplitude menu (Analog Demodulation mode)

The following table shows all softkeys available in the amplitude menu in Analog Demodulation mode

(AMPT key). It is possible that your instrument configuration does not provide all softkeys. If a softkey is

only available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Menu / Command Command

Ref Level

Range Log/Range Linear

AF Range Dev per Division/dB per Division

Reference Position

Reference Value

Deviation Lin/Log

Preamp On/Off

RF Atten Manual

RF Atten Auto

More 

Ref Level Offset

Ref Level Position

Grid Abs / Rel

Unit

Input 50 L/75 L

Ref Level

For details refer to the Ref Level softkey in the amplitude menu of the base unit.

Range Log (RF result display)

This softkey is only available for the RF result display. For the RF result display, the AF Range

softkey is used.

For details refer to the Range Log softkey in the amplitude menu of the base unit.

Range Linear (RF result display)

This softkey is only available for the RF result display. For the RF result display, the AF Range

softkey is used.

For details refer to the Range Linear softkey in the amplitude menu of the base unit.

AF Range (AF result display)

For details refer to the AF Range softkey in the analog demodulation menu.

Analog Demodulation (Option K7) R&S FSL

1300.2519.12 4.154 E-11

Dev per Division

For details refer to the Dev per Division softkey in the analog demodulation menu.

dB per Division

For details refer to the dB per Division softkey in the analog demodulation menu.

Reference Position

For details refer to the Reference Position softkey in the analog demodulation menu.

Reference Value

For details refer to the Reference Value softkey in the analog demodulation menu.

Deviation Lin/Log

For details refer to the Deviation Lin/Log softkey in the analog demodulation menu.

Preamp On/Off (option RF Preamplifier, B22)

For details refer to the Preamp On/Off softkey in the amplitude menu of the base unit.

RF Atten Manual

For details refer to the RF Atten Manual softkey in the amplitude menu of the base unit.

RF Atten Auto

For details refer to the RF Atten Auto softkey in the amplitude menu of the base unit.

Ref Level Offset

For details refer to the Ref Level Offset softkey in the amplitude menu of the base unit.

Ref Level Position

For details refer to the Ref Level Position softkey in the amplitude menu of the base unit.

Grid Abs / Rel (not available with Range Linear)

For details refer to the Grid Abs / Rel softkey in the amplitude menu of the base unit.

R&S FSL Analog Demodulation (Option K7)

1300.2519.12 4.155 E-11

Unit (PM AF result display)

For details refer to the Unit softkey in the amplitude menu of the base unit.

Input 50 D/75 D

For details refer to the Input 50 D/75 Dsoftkey in the amplitude menu of the base unit.

Softkeys of the bandwidth menu (Analog Demodulation mode)

The following table shows all softkeys available in the bandwidth menu in Analog Demodulation mode

(BW key). It is possible that your instrument configuration does not provide all softkeys. If a softkey is

only available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Command

Res BW

Demod BW

Meas Time

Res BW (span > 0)

Opens an edit dialog box to enter a value for the resolution bandwidth. The range is specified in

the data sheet.

Remote: ADEM:SPEC:BAND 10 kHz

Demod BW

For details refer to the Demod BW softkey in the in the analog demodulation menu.

Meas Time

For details refer to the Meas Time softkey in the in the analog demodulation menu.

Softkeys of the sweep menu (Analog Demodulation mode)

The following table shows all softkeys available in the sweep menu in Analog Demodulation mode

(SWEEP key). It is possible that your instrument configuration does not provide all softkeys. If a softkey

is only available with a special option, model or (measurement) mode, this information is delivered in

the corresponding softkey description.

Command

Continuous Sweep

Single Sweep

Continue Sgl Sweep

Meas Time

Sweep Count

Analog Demodulation (Option K7) R&S FSL

1300.2519.12 4.156 E-11

Continuous Sweep

For details refer to the Continuous Sweep softkey in the in the sweep menu of the base unit.

Single Sweep

For details refer to the Single Sweep softkey in the in the sweep menu of the base unit.

Continue Sgl Sweep

For details refer to the Continue Single Sweep softkey in the in the sweep menu of the base

unit.

Meas Time

For details refer to the Meas Time softkey in the in the analog demodulation menu.

Sweep Count

For details refer to the Sweep Count softkey in the in the sweep menu of the base unit.

Softkeys of the trigger menu (Analog Demodulation mode)

The following table shows all softkeys available in the trigger menu in Analog Demodulation mode

(TRIG key). It is possible that your instrument configuration does not provide all softkeys. If a softkey is

only available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Command

Trigger Source

Trigger Level

Trigger Polarity Pos/Neg

Trigger Offset

Trigger Source

Opens the Trigger dialog box to select the trigger mode. Additional to the trigger modes

described in section "Trigger mode overview"on page 4.31, the following trigger modes are

available:

Selected option Specified threshold

AM (Offline) modulation depth of the AM signal

FM (Offline) frequency of the FM signal

PM (Offline) phase of the PM signal

RF (Offline) level of the RF signal

R&S FSL Analog Demodulation (Option K7)

1300.2519.12 4.157 E-11

In Analog Demodulation mode, the next measurement is triggered if the selected input signal

exceeds the threshold specified using the Trg / Gate Level softkey. A periodic signal modulated

onto the carrier frequency can be displayed in this way. It is recommended that the measurement

time covers at least five periods of the audio signal.

For further details refer to the Trg / Gate Source softkey in the trigger menu.

Remote: TRIG:SOUR IMM | IFP | EXT | FM | PM | AM | RF (Free Run, IF Power,

Extern,FM (Offline), PM (Offline), AM (Offline), RF (Offline))

Trigger Level

For details refer to the Trg / Gate Level softkey in the in the trigger menu of the base unit.

Trigger Polarity Pos/Neg

For details refer to the Trg / Gate Polarity Pos/Neg softkey in the in the trigger menu of the

base unit.

Trigger Offset

For details on the relation between demodulation bandwidth (option Analog Demodulation,

R&S FSL–K7) and trigger offset refer to "Sample rate, measurement time and trigger offset" on

page 4.143.

For details refer to the Trigger Offset softkey in the in the trigger menu of the base unit.

Bluetooth Measurements (Option K8) R&S FSL

1300.2519.12 4.158 E-11

Bluetooth Measurements (Option K8)

This option provides measurements to test the conformity of signal sources to the Bluetooth RF Test

Specification (Bluetooth SIG). For background information on Bluetooth measurements refer to chapter

"Advanced Measurement Examples".

This option is available from firmware version 1.30.

To open the Bluetooth menu

If the Bluetooth mode is not the active measurement mode, press the MODE key and activate the

Bluetooth option.

If the Bluetooth mode is already active, press the MENU key.

The Bluetooth menu is displayed. .

Menu and softkey description

–"Softkeys of the Bluetooth menu" on page 4.167

–"Softkeys of the frequency menu (Bluetooth mode)" on page 4.172

–"Softkeys of the amplitude menu (Bluetooth mode)" on page 4.173

–"Softkeys of the bandwidth menu (Bluetooth mode)" on page 4.175

–"Softkeys of the sweep menu (Bluetooth mode)" on page 4.177

–"Softkeys of the trigger menu (Bluetooth mode)" on page 4.180

–"Softkeys of the measurement menu (Bluetooth mode)" on page 4.181

The span menu is not available in the Bluetooth mode. All other menus are provided as described for

the base unit. For details refer to the corresponding menu descriptions.

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"Position of a Bluetooth burst" on page 4.160

–"Labels used in the measurement displays" on page 4.161

Tasks

–To adapt the settings to the characteristics of the DUT

R&S FSL Bluetooth Measurements (Option K8)

1300.2519.12 4.159 E-11

Measurements overview

The Bluetooth Measurements option provides the following measurement types:

–"Output Power" on page 4.161

–"Adjacent Channel Power" on page 4.162

–"Modulation Characteristics" on page 4.162

–"Initial Carrier Frequency Tolerance" on page 4.163

–"Carrier Frequency Drift" on page 4.164

–"Relative Transmit Power (EDR)" on page 4.164

–"In–band Spurious Emissions (EDR)" on page 4.165

–"Carrier Frequency Stability and Modulation Accuracy (EDR)" on page 4.166

–"Differential Phase Encoding (EDR)" on page 4.166

The basic parameter settings are described in section "To adapt the settings to the characteristics of the

DUT" on page 4.159.The settings that can be configured individually for each measurement are the

following:

•RBW (the IF bandwidth set up for modulation measurements is valid for all measurements)

•VBW

•RBW auto mode

•VBW auto mode

•trace mode

•detector

•sweep count

•sweep time auto mode

•sweep time

They are available in the corresponding menus as soon as the corresponding measurement is selected.

Changes to these settings are always related to the selected measurement. The settings defined in the

RF Test Specification can thus be modified individually for development or production. By using the

start recall function, the individual configuration of the various tests can be preserved over a preset.

To adapt the settings to the characteristics of the DUT

1. Set the spectrum analyzer to its default state.

–Press PRESET.

The R&S FSL is set to its default state.

2. Select the Bluetooth operating mode.

–Press MODE key.

–In the Measurement Modes dialog box, select Bluetooth.

The Bluetooth mode is activated and the main menu of the option is displayed.

3. Select the transmit channel.

–Press Channel softkey and enter the desired channel number.

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4. Select the packet length.

–Press Packet Type softkey.

The list of available packet type is displayed.

–Select the desired packet length and confirm the selection with ENTER.

5. Select the power class of the DUT.

–Press Power Class softkey and enter the power class.

6. Configure the sync settings (LAP).

–Press Find Sync softkey.

The submenu menu for configuration of the sync information is displayed.

–Press LAP softkey and enter the lower address part of the Bluetooth device address of the

DUT. The sync word used for the sync search will be calculated.

7. Select a measurement.

–Press the MEAS key and select the desired measurement in the softkey menu.

–Configure measurement time, measurement control and the number of measurement cycles by

pressing the corresponding softkeys. For further information refer to section "Softkeys of the

measurement menu (Bluetooth mode)" on page 4.181.

Further information

This section provides background information on measurements and displayed information.

Position of a Bluetooth burst

The RF Test Specification allows different methods to determine the position of a Bluetooth burst:

•The burst is defined by the p0 bit and the automatically determined packet length (Find Sync On).

•The burst is defined by the two 3dB points (Find Sync Off and Find Burst On). The search of the

3dB points is defined in the RF Test Specification as the alternative method compared with the p0

bit method.

Burst length

(=packet length)

with FIND SYNC ON

Burst length

with FIND SYNC OFF

3dB

Fig. 4-11 Definition of a Bluetooth burst

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Labels used in the measurement displays

•Enhancement label TDF

Offset values, set with the Antenna Gain softkey that are larger or smaller than 0 dB will activate the

enhancement label TDF at the right diagram border.

Measurements

In this section, every measurement type is introduced by a short description.

Output Power measurement

The Output Power measurement (Output Power softkey) determines the maximum and average output

power during a burst of the equipment under test (EUT). For this purpose a complete packet is recorded

in the zero span.

Fig. 4-12 Output power measurement

The peak value is determined from the complete contents of the measurement curve, whereas the

average power is calculated from an area of at least 20% to 80% of the burst.

During the Output Power measurement the Bluetooth demodulator is active in order to determine the

sync word within the signal, which is later–on used as the trigger basis. The Bluetooth demodulator is

placed in a signal path without video filter. This is why the video filter cannot be activated with the

Output Power measurement.

The EUT (equipment under test) must keep the following limits according to the RF Test Specification:

•PAV < 100 mW (20 dBm) EIRP

•PPK < 200 mW (23 dBm) EIRP

•If the EUT is conforming to power class 1: PAV > 1 mW (0 dBm)

•If the EUT is conforming to power class 2: 0.25 mW (–6 dBm) < PAV < 2.5 mW ( 4 dBm)

•If the EUT is conforming to power class 3: PAV < 1 mW (0 dBm)

Aviolation of these limits is marked on the screen in red color.

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Adjacent Channel Power measurement

The measurement of the TX Output Spectrum – Adjacent Channel Power measurement (TX Spec ACP

softkey) measures the power of all adjacent channels.

Fig. 4-13 TX Spectrum ACP measurement

The following limits are given by the RF Test Specification:

•PTX (f)



–20 dBm for |M–N| = 2

•PTX (f)



–40 dBm for |M–N|



with M = Transmit channel of the equipment under test, N = adjacent channel to be measured

Aviolation of these limits will be marked by red color and an asterisk (*).

Modulation Characteristics measurement

The measurement of the modulation characteristics (Modulation Char softkey) determines the

maximum frequency deviation of all 8 bit sequences of the payload.

Additionally the average value of the maximum frequency deviation of a packet will be calculated. For

this purpose the equipment under test is configured in a way that packets with bit pattern "11110000"

and "10101010" are transmitted alternately. According to the RF Test Specification this sequence has

to be repeated 10 times.

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Fig. 4-14 Modulation Characteristics measurement

Initial Carrier Frequency Tolerance measurement

The measurement of the Initial Carrier Frequency Tolerance (Init Carr Freq Tol softkey) determines the

carrier offset of the four preamble bits. According to the RF Test Specification the calculation of the

carrier offset is performed from the middle of the first preamble bit to the middle of the bit following the

preamble.

With Clear/Write trace mode and single sweep operation the selected number of sweeps will be

processed and according to the RF Test Specification the results of all sweeps will be compared with

the defined tolerance. If a different trace mode is selected, the analyzer can alternatively combine

several traces and determine the measurement results from the resulting trace.

Fig. 4-15 Initial Carrier Frequency Tolerance measurement

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Carrier Frequency Drift measurement

The measurement of the Carrier Frequency Drift (Carr Freq Drift softkey) determines the maximum

frequency drift between the average value of the preamble bits and any 10 bit group of the payload.

Additionally the maximum drift rate between all 10 bit groups in the payload is determined every 50µs.

With Clear/Write trace mode and single sweep operation the selected number of sweeps will be

processed and according to the RF Test Specification the results of all sweeps will be compared with

the defined tolerance. If a different trace mode is selected, the analyzer can alternatively combine

several traces and determine the measurement results from the resulting trace.

Fig. 4-16 Carrier Frequency Drift measurement

Relative Transmit Power (EDR) measurement

The measurement of the Relative Transmit Power (Rel TX Power softkey) is an enhanced data rate

measurement (EDR). It determines the average transmission power of the GFSK and DPSK modulated

parts of the signal and calculates the ratio of those values.

The measurement results must conform to the requirement:

•(PGFSK – 4dB) < PDPSK < (PGFSK + 1dB)

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Fig. 4-17 Relative Transmit Power (EDR) measurement

In–band Spurious Emissions (EDR) measurement

The measurement of the In–band Spurious Emissions (Spurious Emissions softkey) is an enhanced

data rate measurement (EDR). It verifies whether the level of unwanted signals within the used

frequency band lies below the required level. The analyzer records the signal only in those parts of the

signal in which the device transmits DPSK–modulated data.

The signal must meet the following conditions:

•PTX (f)



–20 dBm for |M–N| = 2

•PTX (f)



–40 dBm for |M–N|



with M = transmit channel of the equipment under test, N = adjacent channel to be measured

•The adjacent channel power between 1 MHz and 1.5 MHz from the carrier (Adj500kHz Low/Upp)

shall be at least 26 dB below the maximum power of the carrier (TX Channel (Ref)).

Fig. 4-18 In–band Spurious Emissions (EDR) measurement

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Carrier Frequency Stability and Modulation Accuracy (EDR) measurement

The measurement of the Carrier Frequency Stability and Modulation Accuracy (Carr Freq Stability

softkey) is an enhanced data rate measurement (EDR). It verifies that the modulation accuracy and the

frequency stability are working within the required limits. According to the RF Test Specification, the

software records 200 blocks, each with a length of 50 Msfor the evaluation. The number of blocks to be

recorded can be changed by the softkey Block Count.

Fig. 4-19 Carrier Frequency Stability and Modulation Accuracy (EDR) measurement

Differential Phase Encoding (EDR) measurement

The measurement of the Differential Phase Encoding (Diff Phase softkey) is an enhanced data rate

measurement (EDR). It checks in the time range of the DPSK modulation whether the device modulates

the data correctly.

Fig. 4-20 Differential Phase Encoding (EDR) measurement

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Softkeys of the Bluetooth menu

This menu provides the softkeys for the basic settings, which are common to all tests. The following

table shows all softkeys available in the Bluetooth menu. It is possible that your instrument configuration

does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Command

Channel

Packet Type

Packet Bytes SCO

Power Class

Antenna Gain

Find Sync Find Sync On/Off

LAP

Sync Offset

Find Burst On/Off

Burst Offset

Search Len Auto

Search Len Manual

More 

Select Trace

Points / Symbol

Channel

Opens an edit dialog box to enter the transmission channel number. From the number of the

channel the center frequency is calculated in accordance to the RF Test Specification. The

default setting is channel number 0.

Setting the channel number is in principle equal to changing the center frequency. The major

difference is that the center frequency is not limited to available frequency band values, i.e.

values outside the frequency band and between the discrete channels can be selected (see also

Center softkey in the frequency menu).

Remote: CONF:BTO:CHAN 20

Packet Type

Opens a dialog box to select the number of occupied slots in the sent packet. The AUTO value

is identical to 5Slot Packet.The default value is packet type 1Slot Packet.

The number of occupied slots is used for the automatic calculation of the sweep time

(Sweeptime Auto softkey) and the search length of the sync word (Search Len Auto softkey).

The actually transmitted packet type is determined automatically by the Bluetooth demodulator

(which means that the selected packet type need not necessarily correspond to the really

transmitted packet type; it will only affect the settings for sweep time and search length as

described above).

Remote: CONF:BTO:PTYP DH5

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Packet Bytes SCO

Opens an edit dialog box to set the number of payload bytes that are transmitted in a packet.

For SCO packets, the payload length must be adjusted because those packets have no payload

header.

Remote: CONF:BTO:PBSC 50

Power Class (Output Power)

Opens an edit dialog box to set one the Bluetooth power classes (1 to 3). The selection of the

power class determines the limits. The default setting is power class 1 (100 mW).

Remote: CONF:BTO:PCL 3

Antenna Gain

Opens an edit dialog box to enter a level offset in order to take the gain of an antenna into

account for displaying power values. The default setting is 0 dB (see also Labels used in the

measurement displays).

Remote: CORR:EGA:INP 10DB

Find Sync

Opens a submenu to set the signal processing functions of the analyzer in order to determine

the position of the first preamble bit p0 by correlation with the sync word. For this purpose a

sufficient record length of the FM demodulated signal is necessary.

For further information refer to "Position of a Bluetooth burst" on page 4.160.

Find Sync On/Off

Activates or deactivates the search of the sync word. The default setting is activated.

The results of the modulation measurements Modulation Characteristics,Initial Carrier

Frequency Tolerance,Carrier Frequency Drift can only be calculated if the softkey is activated.

The measurement of the Output Power can be performed with either this softkey or the Find

Burst On/Off softkey activated. If both softkeys are activated, the search area for the sync word

will be limited to the area of the detected burst. If the Find Burst On/Off softkey is not activated

or no burst is identified, the total record length (search length) is investigated.

For further information refer to "Position of a Bluetooth burst" on page 4.160.

Remote: DDEM:SEAR:SYNC ON

R&S FSL Bluetooth Measurements (Option K8)

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LAP

Opens an edit dialog box to enter the lower 24 bit (Lower Address Part, LAP)of the Bluetooth

Device Address (BD_ADDR) of the equipment under test (EUT).

The LAP is used to calculate the 64–bit sync word. The sync word in return is used to determine

the start of a packet by correlation and to determine the position of the first preamble bit p0

using the method described in the RF Test Specification.

The values for the lower address part range from 000000h to FFFFFFh. The default setting is

0000000h.

Remote: DDEM:SEAR:SYNC:LAP #HA3F45B

Sync Offset

Opens an edit dialog box to define the number of bits to be displayed in front of the of the first

preamble bit p0. If the sync word is identified, but the selected measurement time cannot be

displayed due to the selected sync offset, the message SYNC OFFSET INVALID is displayed.

The value range depends on the search length and the upper limit of symbols (400001 points /

symbol). The default setting for the sync offset is 0.

This softkey is only available if the Find Sync On/Off softkey is activated.

Sync

Word

Sync Offset > 0

Sync Offset = 0

Sync Offset < 0

Search Length

Access

Code

Header Payload

Meas Time (User)

Remote: DDEM:SEAR:SYNC:OFFS 10

Find Burst On/Off (Output Power)

Activates the burst search if the Find Sync On/Off softkey is deactivated. Beside the

synchronization on the sync word, the Output Power measurement can perform a burst search

to evaluate the signal according to the standard.

If the Find Sync On/Off softkey is not activated and no burst is identified, the message BURST

NOT FOUND is displayed, and the corresponding bit in the STATus:QUEStionable:SYNC

For further information refer to "Position of a Bluetooth burst" on page 4.160.

Remote: DDEM:SEAR:PULS OFF

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Burst Offset

Opens an edit dialog box to define the time to be displayed before the identified burst. The

values range from –10 ms to + 10 ms, with negative values moving the burst to the left, positive

values to the right. The default setting for the burst offset is 0.

If the burst is identified, but the selected measurement time cannot be displayed due to the

selected burst offset, the message BURST OFFSET INVALID is displayed.

This softkey is only available if the Find Sync On/Off softkey is deactivated and the Find Burst

On/Off softkey is activated.

Access

Code

Meas Time (User)

Burst Offset > 0

Burst Offset = 0

Burst Offset < 0

Search Length

Burst

Header Payload

Meas Time (User)

Trigger (optional)

Remote: DDEM:SEAR:PULS:OFFS 1MS

Search Len Auto

Activates or deactivates the automatic selection of the search length for the search of the sync

word or the burst, depending on the selected packet type. The automatic search length is

determined as follows:

Trigger free run:

search length = 3 * packet length + | sync offset or burst offset |

All other trigger modes:

search length = 1 * packet length + 1 Slot + | sync offset or burst offset |

If the selected measurement time is higher than the packet length, the following difference is

added to the search length:

measurement time – packet length

In the default setting, the automatic calculation of the search length is activated.

Remote: DDEM:SEAR:TIME:AUTO OFF

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Search Len Manual

Opens an edit dialog box to enter the search length used for determining the sync word or the

burst. The unit of the search length is seconds; the values range from 100 µsto (400001 / points

per symbol) µs. The default setting is 1825 µs.

The selected number of points / symbol and the maximum search length is listed in the table

below.

Points per symbol Max. search length

(number of slots)

2104.4

452.2

826.1

16 13.1

32 6.5

For information on the correlation of trigger and record length refer to the Search Len Auto

softkey.

Remote: DDEM:SEAR:TIME 100US

Select Trace

Opens an edit dialog box to select the measurement curve whose numeric results will be

displayed in the lower half of the screen. The default curve selected is trace 1.

Remote: CONF:BTO:TRAC2:SEL

Points / Symbol

(Output Power, TX Spec ACP, Modulation Char, Init Carr Freq Tol, Carr Freq Drift)

Opens an edit dialog box to change the number of measurement samples per symbol. For Basic

Rate measurements, the possible values are 2, 4, 8, 16, 32. The default value is 4. For EDR

measurements, the default value is set and cannot be changed.

The RF Test Specification requests an oversampling factor of at least 4. With this oversampling

factor a 5Slot Packet corresponds to 12500 measurement samples (= 2500 samples / slot).

Remote: CONF:BTO:PRAT 16

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Softkeys of the frequency menu (Bluetooth mode)

The following table shows all softkeys available in the frequency menu in Bluetooth mode (FREQ key).

It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Menu / Command Command

Center

CF–Stepsize 0.1*Chan Spacing

=Chan Spacing

Center

Opens an edit dialog box to change the center frequency.

If the frequency channel has been set via the Channel softkey, a change of the center

frequency is possible, but the relation to the frequency channel will be lost, which means that the

value range for the center frequency is not limited to frequencies within valid frequency

channels.

The return to the fixed relation between center frequency and Bluetooth frequency channels is

performed when Channel softkey is pressed or when another measurement is selected. The

center frequency will be rounded to the nearest frequency channel.

Remote: FREQ:CENT 100MHz

CF–Stepsize

Opens a submenu to set the step size of the center frequency.

0.1*Chan Spacing

Sets the step size of the center frequency to 1/10 of the channel spacing.

=Chan Spacing

Sets the step size of the center frequency to the size of the channel spacing.

R&S FSL Bluetooth Measurements (Option K8)

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Softkeys of the amplitude menu (Bluetooth mode)

The following table shows all softkeys available in the amplitude menu in Bluetooth mode (AMPT key).

It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Menu / Command Command

Ref Level

Range Range

Reference Position

Reference Value

Zoom

Range Log

Range Linear

RF Atten Manual

RF Atten Auto

More 

Ref Level Offset

Ref Level Position

Input 50 L/75 L

Ref Level

The maximum input power of the A/D converter (defined by this value) must be equal or higher

than the maximum power of the signal under test.

For details refer to the Ref Level softkey in the amplitude menu of the base unit.

Range (Modulation Char, Init Carr Freq Tol, Carr Freq Drift)

Opens a submenu for scaling the x– and y–axis.

Range (Modulation Char, Init Carr Freq Tol, Carr Freq Drift)

Opens an edit dialog box to enter the range for the frequency deviation.

Remote: DISP:TRAC:Y 110dB

Reference Position (Modulation Char, Init Carr Freq Tol, Carr Freq Drift)

Opens an edit dialog box to enter the position of the reference line for the frequency deviation on

the y–axis of the diagram. The unit is % of the diagram height, with 100% corresponding to the

upper diagram border.

Remote: DISP:WIND:TRAC:Y:RPOS 50PCT

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Reference Value (Modulation Char, Init Carr Freq Tol, Carr Freq Drift)

Opens an edit dialog box to enter the FM deviation at the reference line on the y–axis. This

allows individual frequency offsets to be taken into account for the display of the measurement

curves. The valid value range is 0 to

1MHz; the default setting is 0 Hz.

Remote: DISP:TRAC:Y:RVAL 0

Range Log

(Output Power, TX Spec ACP, Rel TX Power, Spurious Emissions, Carr Freq Stability, Diff Phase)

For details refer to the Range Log softkey in the amplitude menu of the base unit.

Range Linear

(Output Power, TX Spec ACP, Rel TX Power, Spurious Emissions, Carr Freq Stability, Diff Phase)

For details refer to the Range Linear softkey in the amplitude menu of the base unit.

RF Atten Manual

For details refer to the RF Atten Manual softkey in the amplitude menu of the base unit.

RF Atten Auto

For details refer to the RF Atten Auto softkey in the amplitude menu of the base unit.

Ref Level Offset

For details refer to the Ref Level Offset softkey in the amplitude menu of the base unit.

Ref Level Position

For details refer to the Ref Level Position softkey in the amplitude menu of the base unit.

Input 50 D/75 D

For details refer to the Input 50 D/75 Dsoftkey in the amplitude menu of the base unit.

R&S FSL Bluetooth Measurements (Option K8)

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Softkeys of the bandwidth menu (Bluetooth mode)

The following table shows all softkeys available in the bandwidth menu in Bluetooth mode (BW key). It

is possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Meas Time Manual

Meas Time Auto

Sweeptime Manual

Sweeptime Auto

Res BW Manual

Res BW Auto

Video BW Manual

Video BW Auto

Filter Type

Meas Filter

Meas Time Manual

(Output Power, Modulation Char, Init Carr Freq Tol, Carr Freq Drift, Rel TX Power, Carr Freq

Stability, Diff Phase)

Opens an edit dialog box to enter the measurement time. The valid value range is 1 µsto

(400001 / points per symbol) µs.

Remote: CONF:BTO:SWE:TIME 10MS

Meas Time Auto

(Output Power, Modulation Char, Init Carr Freq Tol, Carr Freq Drift, Rel TX Power, Carr Freq

Stability, Diff Phase)

Activates the automatic calculation of the measurement time. The automatic sweep time

corresponds to the settings defined in the RF Test Specification. By default, the automatic

sweep time calculation is activated.

Remote: CONF:BTO:SWE:TIME:AUTO ON

Sweeptime Manual (TX Spec ACP)

Opens an edit dialog box to enter the sweep time. The valid value range is 10 µs(minimum

measurement time for one channel) to 16000 s. The default setting is 79 s.

Remote: CONF:BTO:SWE:TIME 10MS

Sweeptime Auto (TX Spec ACP)

Activates the automatic calculation of the sweep time. The automatic sweep time corresponds to

the settings defined in the RF Test Specification. By default, it is activated.

Remote: CONF:BTO:SWE:TIME:AUTO ON

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Res BW Manual (Output Power, Rel TX Power)

Opens an edit dialog box to enter the resolution bandwidth. The values range from 1 MHz to 3

MHz. The default value is 3 MHz.

Remote: CONF:BTO:BAND 1KHZ

Res BW Auto (Output Power, TX Spec ACP, Rel TX Power, Spurious Emissions)

Sets the bandwidth according to the values defined in the RF Test Specification.

Remote: CONF:BTO:BAND:AUTO ON

Video BW Manual (TX Spec ACP)

The default value is 300 kHz, according to the values defined in the RF Test Specification.

For further details refer to the Video BW Manual softkey in the bandwidth menu of the base

unit.

Remote: CONF:BTO:BAND:VID 100HZ

Video BW Auto (TX Spec ACP, Spurious Emissions)

Sets the video bandwidth according to the values defined in the RF Test Specification. In the In–

band Spurious Emissions measurement, the video bandwidth is always adjusted automatically.

Therefore the softkey is activated by default and its state cannot be changed.

Remote: CONF:BTO:BAND:VID:AUTO ON

Filter Type (Output Power, TX Spec ACP, Spurious Emissions, Rel TX Power)

Opens the Filter Type dialog box to select the filter type. For the measurements Output Power

and Rel TX Power, a Gaussian or a channel filter can be selected. For the measurements TX

Spec ACP and Spurious Emissions, the filter type is a Gaussian filter.

Remote: BAND:TYPE NORM

Meas Filter (Modulation Char, Init Carr Freq Tol, Carr Freq Drift)

Activates or deactivates a filter that limits the bandwidth for the modulation measurements.

Since the RF Test Specification Rev 2.0.E.3 it is required to use this filter and therefore it is

activated by default.

The filter is flat within 1.04 MHz (ripple: only 0.02 dB) and has steep slopes outside this area.

The filter has the following characteristics:

– passband ripple up to

550 kHz < 0.5 dB (peak to peak)

–minimum attenuation in the transition band

650 kHz:



3dB

1MHz:



14 dB

2MHz:



44 dB

Remote: DDEM:FILT:MEAS BTO

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Softkeys of the sweep menu (Bluetooth mode)

The following table shows all softkeys available in the sweep menu in Bluetooth mode (SWEEP key).

In the Bluetooth mode, the sweep menu is used for direct entry into the measurement menu of the

currently selected measurement. It is possible that your instrument configuration does not provide all

softkeys. If a softkey is only available with a special option, model or (measurement) mode, this

information is delivered in the corresponding softkey description.

Command

Start Test

Continue Test

Continuous Sweep

Single Sweep

Meas Time Manual

Meas Time Auto

Sweeptime Manual

Sweeptime Auto

Block Count

Adjust Gate

Sweep Count

Power Avg Start

Power Avg Stop

Zoom

No. of ACP Chan

Channel List Start

More 

Gate Delay

Gate Length

GFSK Start

GFSK Stop

DPSK Start

DPSK Stop

Start Test (Modulation Char)

Initiates a new measurement. All frequency deviation values obtained earlier are discarded.

The bit pattern in the payload is detected automatically. The frequency deviation of a packet is

determined according to the procedure defined in the RF Test Specification.

Remote: INIT;*WAI

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Continue Test (Modulation Char)

Measures the frequency deviation of further packets after the bit pattern has been changed at

the EUT, just like the Start Test softkey did for the first bit pattern type. The results of the

preceding measurement are preserved and are taken into account for the new measurements.

Remote: INIT:CONM;*WAI

Continuous Sweep

Selects the continuous measurement operation. This is the default setting of the instrument.

Remote: INIT:CONT ON;*WAI

Single Sweep

(Output Power, TX Spec ACP, Init Carr Freq Tol, Carr Freq Drift, Rel TX Power, Spurious

Emissions, Carr Freq Stability, Diff Phase)

Selects the single measurement operation and starts a measurement cycle.

Remote: INIT:CONT OFF;*WAI

Block Count (Carr Freq Stability)

Opens an edit dialog box to enter the number of blocks to be measured. Every block has the

length of 50 Ms. The default value is 200 blocks.

This softkey is only available in single sweep operation.

Remote: CONF:BTO:CFST:BCO 1000

Adjust Gate (Spurious Emissions)

Adjusts the gate settings according to the pre–measurement results.

Remote: CONF:BTO:IBS:GATE:AUTO ONCE

Sweep Count

(Output Power, TX Spec ACP, Modulation Char, Init Carr Freq Tol, Carr Freq Drift, Rel TX Power,

Spurious Emissions, Diff Phase)

Opens an edit dialog box to enter the number of sweeps to be initiated by Single Sweep

softkey. The valid value range is 0 to 32767.

Remote: CONF:BTO:SWE:COUN 20

Power Avg Start (Output Power)

Opens an edit dialog box to enter the start position of the evaluation area for the average burst

power. The values range from 0 to 100%, the default setting is 20%.

For further information refer to "Position of a Bluetooth burst" on page 4.160.

Remote: CONF:BTO:POW:AVER:STAR 10PCT

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Power Avg Stop (Output Power)

Opens an edit dialog box to enter the stop position of the evaluation area for the average burst

power. The values range from 0 to 100%, the default setting is 80%.

For further information refer to "Position of a Bluetooth burst" on page 4.160.

Remote: CONF:BTO:POW:AVER:STAR 90PCT

Zoom (Modulation Char, Init Carr Freq Tol, Carr Freq Drift)

Activates or deactivates the zoom function. Opens an edit dialog box to enter the zoom start

position. The valid value range for the zoom start position is 0 to (measurement time – 500 /

sampling rate). The default setting for the zoom function is 0s (off).

With active zoom function, an area of only 501 samples is displayed.

Remote: ADEM:ZOOM ON

Remote: ADEM:ZOOM:STAR 500us

No. of ACP Chan (TX Spec ACP, Spurious Emissions)

Opens an edit dialog box to enter the number of adjacent channels, for which the power is to be

measured. The values range from 0 to 78. A minimum value of 3 is recommended. The default

setting is 78 (all channels).

As with the ACP measurement of the basic instrument firmware this value refers to the number

of adjacent channels on one side of the TX channel. This means that with a selected value of 10

the analyzer will measure in total 21 channels (10 lower channels + TX channel + 10 upper

channels).

The frequency range required for the measurement is set up automatically. The center

frequency will also be adapted automatically dependent on the selected TX channel.

The measurement of the adjacent channels is limited to the available Bluetooth frequency band,

which means that at maximum 79 channels (23 channels in France) will be measured.

Remote: CONF:BTO:ACLR:ACP 10 (TX Spec ACP)

Remote: CONF:BTO:IBS:ACP 20 (Spurious Emissions)

Channel List Start (TX Spec ACP, Spurious Emissions)

Opens an edit dialog box to enter the channel with which the result display table starts. Because

of the multiplicity of the measurements results not all channels can be displayed simultaneously.

Gate Delay (Spurious Emissions)

Opens an edit dialog box to enter the time between trigger event and start of the DPSK packet.

That is the measurement start time.

Remote: SWE:EGAT:HOLD 100us

Bluetooth Measurements (Option K8) R&S FSL

1300.2519.12 4.180 E-11

Gate Length (Spurious Emissions)

Opens an edit dialog box to enter the sweep time in seconds. Usually, this is the length of the

DPSK section.

Remote: SWE:EGAT:LENG 10ms

GFSK Start (Rel TX Power)

Opens an edit dialog box to enter the start time for the power measurement of the GFSK

sections of the packet. The default value is 10%.

The abbreviation GFSK stands for Gaussian Frequency Shift Keying.

Remote: CONF:BTO:RTP:GAV:STAR 20

GFSK Stop (Rel TX Power)

Opens an edit dialog box to enter the stop time for the power measurement of the GFSK

sections of the packet. The default value is 90%.

The abbreviation GFSK stands for Gaussian Frequency Shift Keying.

Remote: CONF:BTO:RTP:GAV:STOP 80

DPSK Start (Rel TX Power)

Opens an edit dialog box to enter the start time for the power measurement of the DPSK

sections of the packet. The default value is 10%.

The abbreviation DPSK stands for Differential Phase Shift Keying.

Remote: CONF:BTO:RTP:DAV:STAR 20

DPSK Stop (Rel TX Power)

Opens an edit dialog box to enter the stop time for the power measurement of the DPSK

sections of the packet. The default value is 90%.

The abbreviation DPSK stands for Differential Phase Shift Keying.

Remote: CONF:BTO:RTP:DAV:STOP 80

Softkeys of the trigger menu (Bluetooth mode)

The following table shows all softkeys available in the trigger menu in Bluetooth mode (FREQ key). It

is possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Trigger Source

Trg/Gate Level

Trigger Polarity

Trigger Offset

R&S FSL Bluetooth Measurements (Option K8)

1300.2519.12 4.181 E-11

Trigger Source

Opens the Trigger dialog box to select one of the following trigger sources: Free Run,External,

IF Power.

For further details refer to the Trg / Gate Source softkey in the trigger menu of the base unit.

Trg/Gate Level

Opens an edit dialog box to enter the trigger / gate level. This softkey is not available, if the

trigger source Free Run is selected.

For further details refer to the Trg / Gate Level softkey in the trigger menu of the base unit.

Trigger Polarity

For details refer to the Trg / Gate Polarity Pos/Neg softkey in the trigger menu of the base unit.

Trigger Offset

For details refer to the Trigger Offset softkey in the trigger menu of the base unit.

Softkeys of the measurement menu (Bluetooth mode)

The following table shows all softkeys available in the measurement menu in Bluetooth mode (MEAS

key). It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

In the Bluetooth mode, the sweep menu is used for direct entry into the measurement menu of the

currently selected measurement. Therefore only the softkeys to select a measurement are described in

this section. All other softkeys are linked to the description in section Softkeys of the sweep menu

(Bluetooth mode) or Softkeys of the bandwidth menu (Bluetooth mode).

Menu / Command Submenu / Command Command

Output Power Continuous Sweep

Single Sweep

Meas Time Manual

Meas Time Auto

Sweep Count

Power Avg Start

Power Avg Stop

TX Spec ACP Continuous Sweep

Single Sweep

Sweeptime Manual

Sweeptime Auto

Sweep Count

No. of ACP Chan

Bluetooth Measurements (Option K8) R&S FSL

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Menu / Command Submenu / Command Command

Channel List Start

Modulation Char Start Test

Continue Test

Continuous Sweep

Meas Time Manual

Meas Time Auto

Sweep Count

Zoom

Init Carr Freq Tol Continuous Sweep

Single Sweep

Meas Time Manual

Meas Time Auto

Sweep Count

Zoom

Carr Freq Drift see contents of the Init

Carr Freq Tol submenu

EDR Rel TX Power Continuous Sweep

Single Sweep

Meas Time Manual

Meas Time Auto

Sweep Count

More 

GFSK Start

GFSK Stop

DPSK Start

DPSK Stop

Spurious Emissions Continuous Sweep

Single Sweep

Adjust Gate

Sweep Count

No. of ACP Chan

Channel List Start

More 

Gate Delay

Gate Length

Carr Freq Stability Continuous Sweep

Single Sweep

Meas Time Manual

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Menu / Command Submenu / Command Command

Meas Time Auto

Block Count

Diff Phase Continuous Sweep

Single Sweep

Meas Time Manual

Meas Time Auto

Sweep Count

Output Power

Opens a submenu to configure the Output Power measurement. For further details refer to

"Output Power measurement" on page 4.161.

Remote: CONF:BTO:MEAS OPOW

Remote: CALC:BTO:OPOW?

Remote: CALC:BTO:OPOW:AVER? MAX

TX Spec ACP

Opens a submenu to configure the TX Spec ACP measurement. For further details refer to

"Adjacent Channel Power measurement" on page 4.162.

Remote: CONF:BTO:MEAS ACLR

Remote: CALC:BTO:ACLR?

Remote: CALC:BTO:ACLR:EXC?

Modulation Char

Opens a submenu to configure the Modulation Char measurement. For further details refer to

"Modulation Characteristics measurement" on page 4.162.

Remote: CONF:BTO:MEAS MCH

Remote: CALC:BTO:MCH:DF1:AVER? MIN

Remote: CALC:BTO:MCH:DF1:MAX? MIN

Remote: CALC:BTO:MCH:DF2:PERC?

Remote: CALC:BTO:MCH:RAT? MIN

Init Carr Freq Tol

Opens a submenu to configure the Init Carr Freq Tol measurement. For further details refer to

"Initial Carrier Frequency Tolerance measurement" on page 4.163.

Remote: CONF:BTO:MEAS IFCT

Remote: CALC:BTO:ICFT? AVER

Bluetooth Measurements (Option K8) R&S FSL

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Carr Freq Drift

Opens a submenu to configure the Carr Freq Drift measurement. For further details refer to

"Carrier Frequency Drift measurement" on page 4.164.

Remote: CONF:BTO:MEAS CFDR

Remote: CALC:BTO:CFDR?

Remote: CALC:BTO:CFDR:RATE?

EDR

Opens a submenu with all available enhanced data rate measurements.

Rel TX Power

Opens a submenu to configure the Rel TX Power measurement. For further details refer to

"Relative Transmit Power (EDR) measurement" on page 4.164.

Remote: CONF:BTO:MEAS RTP

Remote: CALC:BTO:RTP? MIN

Remote: CALC:BTO:RTP:GFSK? MIN

Remote: CALC:BTO:RTP:RAT? MIN

Spurious Emissions

Opens a submenu to configure the Spurious Emissions measurement. For further details refer to

"In–band Spurious Emissions (EDR) measurement" on page 4.165.

Remote: CONF:BTO:MEAS IBS

Remote: CALC:BTO:IBS?

Remote: CALC:BTO:IBS:EXC?

Remote: CALC:BTO:IBS:HADJ? LOW

Carr Freq Stability

Opens a submenu to configure the Carr Freq Stability measurement. For further details refer to

"Carrier Frequency Stability and Modulation Accuracy (EDR) measurement" on page 4.166.

Remote: CONF:BTO:MEAS CFST

Remote: CALC:BTO:CFST:FERR? MIN

Remote: CALC:BTO:CFST:FERR:BLOC? AVER

Remote: CALC:BTO:CFST:FERR:INIT? MAX

Remote: CALC:BTO:CFST:DEVM? AVER

Remote: CALC:BTO:CFST:DEVM:PEAK?

Remote: CALC:BTO:CFST:DEVM:D99Pct?

Remote: CALC:BTO:CFST:COUNt?

R&S FSL Bluetooth Measurements (Option K8)

1300.2519.12 4.185 E-11

Diff Phase

Opens a submenu to configure the Diff Phase measurement. For further details refer to

"Differential Phase Encoding (EDR) measurement" on page 4.166.

Remote: CONF:BTO:MEAS DPEN

Remote: CALC:BTO:DPEN:NERR?

Remote: CALC:BTO:DPEN?

Remote: CALC:BTO:DPEN:BER?

Power Meter (Option K9) R&S FSL

1300.2519.12 4.186 E-11

Power Meter (Option K9)

For precise power measurement a power sensor is connected to the instrument via the front panel

(USB connector) or the rear panel (power sensor, option R&S FSL–B5). The Power Sensor Support

firmware option provides the power measurement functions for this test setup (see Fig. 4-21: Power

sensor support – standard test setup). Both manual operation and remote control are supported. The

functions of this firmware option are described in this section. For details on the connectors and

compatible power sensors refer to the Quick Start Guide, chapter 1, "Front and Rear Panel".

Fig. 4-21: Power sensor support – standard test setup

To open the power meter menu

1. Press the MENU key.

2. Press the Power Meter softkey.

The power meter menu is displayed.

Menu and softkey description

–"Softkeys of the power meter menu" on page 4.187

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Tasks

–To zero the power meter

–To use the power meter

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1300.2519.12 4.187 E-11

To zero the power meter

1. Press the Zero softkey.

Adialog box is displayed that prompts you to disconnect all signals from the input of the power

sensor.

2. Disconnect all signals from the input of the power sensor and press ENTER to continue.

3. Wait until zeroing is complete.

Acorresponding message is displayed.

To use the power meter

1. Press the Frequency Coupling softkey to select the coupling option.

2. If you have selected the Manual coupling option, press the Frequency Manual softkey to enter the

frequency of the signal which power you want to measure.

3. Press the Unit/Scale softkey to set the unit for the power result display.

4. If you have selected dB or % as units (relative display), define a reference value:

–To set the currently measured power as a reference value, press the Meas–>Ref softkey.

–To enter a reference value, press the Reference Value softkey.

5. Press the Meas Time/Average softkey to select the measurement time. For recommendations refer

to the Meas Time/Average softkey description.

Softkeys of the power meter menu

The following table shows all softkeys available in the power meter menu. It is possible that your

instrument configuration does not provide all softkeys. If a softkey is only available with a special option,

model or (measurement) mode, this information is delivered in the corresponding softkey description.

For the description of the other main softkeys refer to "Optional softkeys of the menu menu" on page

4.131.

Command

Power Meter On/Off

Frequency Manual

Frequency Coupling

Unit/Scale

Zero

Meas Time/Average

More 

Meas–>Ref

Reference Value

Use Ref Lev Offset

Number of Readings

Ext Power Trigger

Trigger Level

Power Meter (Option K9) R&S FSL

1300.2519.12 4.188 E-11

Power Meter On/Off

Switches the power measurement on or off.

Remote: PMET ON

Frequency Manual

Opens an edit dialog box to enter the frequency of the signal to be measured. The power sensor

has a memory with frequency–dependent correction factors. This allows extreme accuracy for

signals of a known frequency.

Remote: PMET:FREQ 1GHZ

Frequency Coupling

Opens the Frequency Coupling dialog box to select the coupling option. The frequency can be

coupled automatically to the center frequency of the instrument or to the frequency of marker 1,

or manually to a set frequency (see Frequency Manual softkey).

Remote: PMET:FREQ:LINK CENT

Unit/Scale

Opens the Unit/Scale dialog box to select the unit with which the measured power is to be

displayed.

If dB or % is selected, the display is relative to a reference value that is defined with either the

Meas–>Ref softkey or the Reference Value softkey.

Remote: UNIT:PMET:POW DBM

Remote: UNIT:PMET:POW:RAT DB

Zero

Starts zeroing of the power sensor. For details on the zeroing process refer to "To zero the

power meter" on page 4.187.

Remote: CAL:PMET:ZERO:AUTO ONCE;*WAI

Meas Time/Average

Opens the Meas Time dialog box to select the measurement time or to switch to manual

averaging mode. In general, results are more precise with longer measurement times. The

following settings are recommended for different signal types to obtain stable and precise

results:

Short Stationary signals with high power (> –40dBm), because they require only a

short measurement time and short measurement time provides the highest

repetition rates.

Normal Signals with lower power or of modulated signals

Long Signals at the lower end of the measurement range (<–50 dBm) or

signals with lower power to minimize the influence of noise.

Manual Switches to manual averaging mode. The average count is set with the

Number of Readings softkey.

This parameter is available from firmware version 1.70.

R&S FSL Power Meter (Option K9)

1300.2519.12 4.189 E-11

Remote: PMET:MTIM SHOR

Remote: PMET:MTIM:AVER ON

Meas–>Ref

Sets the currently measured power as a reference value for the relative display. The reference

value can also be set manually via the Reference Value softkey.

Remote: CALC:PMET:REL:AUTO ONCE

Reference Value

Opens an edit dialog box to enter a reference value for relative measurements in the unit dBm.

Remote: CALC:PMET:REL –30DBM

Use Ref Lev Offset

If activated, takes the reference level offset set for the analyzer (Ref Level Offset softkey) into

account for the measured power. If deactivated, takes no offset into account.

This softkey is available from firmware version 1.50.

Remote: PMET:ROFF OFF

Number of Readings

Opens an edit dialog box to enter the number of readings (averagings) to be performed after a

single sweep has been started. This softkey is only available if manual averaging is selected

(Meas Time/Average softkey).

The values for the average count range from 0 to 256 in binary steps (1, 2, 4, 8,…). For average

count = 0 or 1, one reading is performed. The averaging and sweep count of the trace menu are

independent from this setting.

Results become more stable with extended average, particularly if signals with low power are

measured. This setting can be used to minimize the influence of noise in the power meter

measurement.

This softkey is available from firmware version 1.70.

Remote: PMET:MTIM:AVER:COUN 8

Ext Power Trigger

Activates the creation of a trigger signal in the power sensor. When pressing the softkey, the

following softkeys of the power meter menu become unavailable: Unit/Scale, Reference Value,

Use Ref Lev Offset and Number of Readings.

Pressing the softkey causes the transmission of the following remote commands to the power

sensor:

*RST

SENS:AVER:STAT OFF

TRIG:MAST:STAT ON

TRIG:SOUR INT

TRIG:SLOP POS

TRIG:DTIM 100e-6

INIT:CONT ON

Power Meter (Option K9) R&S FSL

1300.2519.12 4.190 E-11

This softkey is only available in conjunction with a NRP-Z81 power sensor.

This softkey is available from firmware version 1.90.

Remote: SENS:PMET:TRIG ON

Trigger Level

Opens an edit dialog box to enter the trigger level.

This softkey is only available in conjunction with a NRP-Z81 power sensor.

This softkey is available from firmware version 1.90.

Remote: SENS:PMET:TRIG:LEV -10 dBm

R&S FSL Spectrogram Measurement (Option K14)

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Spectrogram Measurement (Option K14)

The Spectrogram Measurement option provides a graphical view of frequency and amplitude changes

over a time interval. For display details refer to "Spectrogram view" on page 4.192.

Not all measurement types can be displayed in the Spectrogram view. If the Spectrogram Measurement

option is active and a measurement cannot be displayed in form of a spectrogram, the softkey of the

corresponding measurement is disabled.

If the Spectrogram view is active, all parameter settings set in the Spectrum Analyzer mode are kept,

and vice versa.

This option is available from firmware version 1.60.

To open the spectrogram menu

1. Press the MENU key.

2. Press the Spectrogram softkey.

The spectrogram menu is displayed.

Menu and softkey description

–"Softkeys of the spectrogram menu" on page 4.194

–"Softkeys of the sweep menu (Spectrogram view)" on page 4.195

–"Softkeys of the marker menu (Spectrogram view)" on page 4.197

–"Softkeys of the marker–> menu (Spectrogram view)" on page 4.197

All other menus are provided as described for the base unit. For details refer to the corresponding menu

descriptions.

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

– "Spectrogram view" on page 4.192

–"Markers and marker values" on page 4.193

–"Maximum number of frames" on page 4.193

Spectrogram Measurement (Option K14) R&S FSL

1300.2519.12 4.192 E-11

Spectrogram view

The Spectrogram view is divided into two panes: the spectrum analyzer result display (upper pane) and

the spectrogram result display (lower pane).

•spectrum analyzer result display

As in Spectrum Analyzer mode, all traces are displayed and available. For trace 1, the View and

Blank trace modes are not available.

During the measurement, always the current trace is displayed.

If no measurement is running, the trace to be displayed is selected via:

–the Select Frame softkey

–the edit dialog box for markers and delta markers (MKR key, Marker 1/2/3/4 softkeys or MKR–

>key, Select 1 2 3 4



softkey)

The selected trace is displayed with its corresponding, activated markers (D2 in the example). The

position of the markers activated for other traces is only displayed in the marker field (M1 in the

example).

•spectrogram result display

In a Cartesian diagram, the chronological power distribution (y–axis) over a frequency or time range

(x–axis) is displayed. The different levels are displayed in different colors.

Only the data of trace 1 is displayed in the spectrogram. The result display is build up by horizontal

lines so–called frames, each representing a trace. The frames are sorted in chronological order:

Starting from the current trace (frame 0) at the y–axis value zero, the last trace (frame –1), the trace

before the last trace (frame –2), and so on, are displayed with increasing y–axis value. The

maximum number of frames to be recorded is defined by the History Depth softkey.

Aframe consists of a maximum of 501 measurement points. If more measured values than

measurement points are available (set via the Sweep Points softkey), several measured values are

combined in one measurement point using the selected detector (Auto Peak detector not available,

for details on detectors refer to "Detector overview"on page 4.42).

Fig. 4-22 Spectrogram (example)

R&S FSL Spectrogram Measurement (Option K14)

1300.2519.12 4.193 E-11

Acolor map below the spectrogram shows the level and color assignment: the minimum level on

the left (–101.0 dBm in the example), the maximum level on the right (–1.0 dBm in the example).

The used colors are defined via the Color softkey. The level and color assignment is derived

automatically from the levels.

Below the right corner of the spectrogram, the frame number is displayed (# 0 in the example). If

the time stamp is activated, the time stamp instead of the frame number is displayed (for details

refer to the Time Stamp On/Off softkey).

The position of a marker (rhomb symbol) is displayed in the spectrogram result display only if the

marker is located in the visible area. If the marker is located outside the visible area, only its values

are displayed in the marker field.

Markers and marker values

In the spectrum analyzer result display, the marker information of all activated markers is displayed in

the marker field. Additional to the marker values of the base unit (for details see "Using Markers and

Delta Markers – MKR Key" on page 4.53), the frame number is given (# 0 in the example).

In the spectrogram result display, in maximum 4 markers and delta markers can be activated for

different frames at the same time. To assign a marker to a frame, the edit marker dialog box is

extended. Additionally to the marker value, the frame number must be defined.

When the marker edit dialog box is opened, the Marker 1 field is in edit mode. To change to the frame

number field, use the FIELD RIGHT key.

If a marker is activated when the measurement is halted (Continuous Sweep Start/Stop softkey), the

marker is set and visible in both result displays (provided that it is located in the visible area of the

spectrogram result display). If the marker value or the frame number is altered, the new position is

reflected in both result displays.

Maximum number of frames

The following table shows the correlation between the number of measurement points and the

maximum number of frames stored in the history buffer:

Measurement points Max. number of frames



501 20,000

1,001 12,488

2,001 6,247

4,001 3,124

8,001 1,562

16,001 781

32,001 391

Spectrogram Measurement (Option K14) R&S FSL

1300.2519.12 4.194 E-11

Softkeys of the spectrogram menu

The following table shows all softkeys available in the spectrogram menu (MENU key). It is possible

that your instrument configuration does not provide all softkeys. If a softkey is only available with a

special option, model or (measurement) mode, this information is delivered in the corresponding softkey

description.

For the description of the other main softkeys refer to "Optional softkeys of the menu menu" on page

4.131.

Command

Spectrogram On/Off

History Depth

Color

Maximize Size

Time Stamp On/Off

Spectrogram On/Off

Activates or deactivates the Spectrogram Measurement option.

Remote: CALC:SPEC ON

History Depth

Opens an edit dialog box to enter the number of frames to be stored in the history buffer. The

maximum number of frames depends on the number of sweep points (Sweep Points softkey)

and is determined according to "Maximum number of frames" on page 4.193.

If the history buffer is full, the oldest frame results are overwritten by the new ones.

Remote: CALC:SPEC:HDEP 1000

Color

Opens the Frame Color dialog box to select the frame color setting.

Color RGB colors

Radar black – green – white

Grayscale black and white

Remote: CALC:SPEC:COL RAD

Maximize Size

Changes the screen layout.

Activated Enlarges the spectrogram result display and scales down the spectrum

analyzer result display.

Deactivated Divides the screen in two equally sized panes.

Remote: CALC:SPEC:SIZE LARG

R&S FSL Spectrogram Measurement (Option K14)

1300.2519.12 4.195 E-11

Time Stamp On/Off

Defines the displayed item in the right lower corner.

On The time stamp (system time of the sweep start) is displayed instead of the frame

number.

Off The frame number is displayed.

Remote: CALC:SPEC:TST ON

Softkeys of the sweep menu (Spectrogram view)

The following table shows all softkeys available in the sweep menu of the Spectrogram Measurement

option (SWEEP key). It is possible that your instrument configuration does not provide all softkeys. If a

softkey is only available with a special option, model or (measurement) mode, this information is

delivered in the corresponding softkey description.

Command

Continuous Sweep Start/Stop

Single Sweep

Select Frame

Sweeptime Manual

Sweeptime Auto

Sweep Count

More 

Sweep Points

Continue Frame On/Off

Frame Count

Spectrogram Clear

Continuous Sweep Start/Stop

Stops or continues the measurement in continuous sweep mode. The trace averaging is

determined by the sweep count value (for details refer to the Sweep Count softkey in the trace

menu of the base unit).

Continuous Sweep Start The measurement is stopped. Press the softkey to continue the

measurement.

Continuous Sweep Stop The measurement is running. Press the softkey to stop the

measurement.

Remote: INIT:CONT ON

Single Sweep

For details refer to the Single Sweep softkey in the sweep menu of the base unit.

Spectrogram Measurement (Option K14) R&S FSL

1300.2519.12 4.196 E-11

Select Frame

Opens an edit dialog box to select the frame if no measurement is running. If the active marker

value is altered, the value of the selected frame is updated accordingly.

During a measurement, the value is fixed to 0 and this softkey is not available.

Remote: CALC:SPEC:FRAM:SEL –10

Sweeptime Manual

For details refer to the Sweeptime Manual softkey in the sweep menu of the base unit.

Sweeptime Auto

For details refer to the Sweeptime Auto softkey in the sweep menu of the base unit.

Sweep Count

For details refer to the Sweep Count softkey in the sweep menu of the base unit.

Sweep Points

For details refer to the Sweep Points softkey in the sweep menu of the base unit.

Continue Frame On/Off

Determines whether the results of the last measurement are deleted before starting a new

measurement.

On Repeats the single sweep measurement without deleting the spectrogram results of

the last measurement. One of the following trace modes is to be used: Max Hold,Min

Hold,Average.

Off Deletes the last measurement results before performing a single sweep

measurement.

This softkey takes effect in single sweep mode only.

Remote: CALC:SPEC:CONT ON

Frame Count

Opens an edit dialog box to enter the number of frames to be recorded in a single sweep

measurement, whereas the Sweep Count entry determines how many sweeps are combined

according to the selected trace mode (Max Hold or Min Hold)in one trace (frame). The

maximum number of frames is determined according to "Maximum number of frames" on page

4.193.

This softkey takes effect in single sweep mode only.

Remote: CALC:SPEC:FRAM:COUN 200

R&S FSL Spectrogram Measurement (Option K14)

1300.2519.12 4.197 E-11

Spectrogram Clear

Deletes the spectrogram result display and the history buffer.

Remote: CALC:SPEC:CLE

Softkeys of the marker menu (Spectrogram view)

Additional to the functionality of the base unit (for details refer to "Softkeys of the marker menu" on page

4.57), the edit dialog box for markers and delta markers is extended. For details refer to "Markers and

marker values" on page 4.193.

Softkeys of the marker–> menu (Spectrogram view)

The following table shows all softkeys available in the marker–> menu of the Spectrogram

Measurement option (MKR–> key). It is possible that your instrument configuration does not provide all

softkeys. If a softkey is only available with a special option, model or (measurement) mode, this

information is delivered in the corresponding softkey description.

Menu / Command Command

Select 1 2 3 4



Peak

Next Peak

Search Mode Next Peak X Search < abs >

Next Peak Y Search up/abs/dn

Next Min X Search < abs >

Next Min Y Search up/abs/dn

Marker Search Type

Select Search Area

Center =Mkr Freq

Ref Lvl =Mkr Lvl

More 

Select 1 2 3 4



Min

Next Min

Search Mode identical to Search Mode menu

above

Search Limits Left Limit

Right Limit

Threshold

Search Lim Off

Peak Excursion

Exclude LO

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Select 1 2 3 4



The edit dialog box for markers and delta markers is extended as described in "Markers and

marker values" on page 4.193.

For further details refer to the Select 1 2 3 4



softkey in the marker–> menu of the base unit.

Remote: CALC:MARK2:SPEC:FRAM –20

Remote: CALC:DELT3:SPEC:FRAM –50

Peak

Sets the active marker/delta marker to the highest maximum according to the selected search

type (Marker Search Type softkey).

Remote: CALC:MARK:MAX (in x direction)

Remote: CALC:DELT:MAX (in x direction)

Remote: CALC:MARK:SPEC:Y:MAX (y direction)

Remote: CALC:DELT4:SPEC:Y:MAX (y direction)

Remote: CALC:MARK2:SPEC:XY:MAX (xy direction)

Remote: CALC:DELT2:SPEC:XY:MAX (xy direction)

Next Peak

Sets the active marker/delta marker to the next maximum according to the mode selected using

the Search Mode softkey. For the XY Search (Marker Search Type softkey), this softkey is not

available.

Remote: for search in x direction see Next Peak X Search < abs > softkey

Remote: for search in y direction see Next Peak Y Search up/abs/dn softkey

Search Mode

Displays a submenu to define the search mode for the Next Peak and Next Min softkeys.

Next Peak X Search < abs >

Selects the mode of the Next Peak softkey, if the X Search is selected (Marker Search Type

softkey). Three settings are available:

<Sets the active marker/delta marker to the next maximum left to the marker of the

selected frame.

abs Sets the active marker/delta marker to the next lower maximum of the selected

frame.

>Sets the active marker/delta marker to the next maximum right to the marker of the

selected frame.

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Remote: CALC:MARK2:MAX:LEFT (<)

Remote: CALC:DELT:MAX:LEFT (<)

Remote: CALC:MARK:MAX:RIGH (>)

Remote: CALC:DELT:MAX:RIGH (>)

Remote: CALC:MARK2:MAX:NEXT (abs)

Remote: CALC:DELT2:MAX:NEXT (abs)

Next Peak Y Search up/abs/dn

Selects the mode of the Next Peak softkey, if the Y Search is selected (Marker Search Type

softkey). Three settings are available:

up Sets the active marker/delta marker to the next maximum above the current marker

position (constant x–axis value).

abs Sets the active marker/delta marker to the next lower maximum in y–axis direction

(constant x–axis value).

dn Sets the active marker/delta marker to the next maximum below the current marker

position (constant x–axis value).

Remote: CALC:MARK2:SPEC:Y:MAX:ABOV (up)

Remote: CALC:DELT2:SPEC:Y:MAX:ABOV (up)

Remote: CALC:MARK:SPEC:Y:MAX:NEXT (abs)

Remote: CALC:DELT4:SPEC:Y:MAX:NEXT (abs)

Remote: CALC:MARK3:SPEC:Y:MAX:BEL (dn)

Remote: CALC:DELT3:SPEC:Y:MAX:BEL (dn)

Next Min X Search < abs >

Selects the mode of the Next Min softkey, if the X Search is selected (Marker Search Type

softkey). Three settings are available:

<Sets the active marker/delta marker to the next minimum left to the marker of the

selected frame.

abs Sets the active marker/delta marker to the next higher minimum of the selected

frame.

>Sets the active marker/delta marker to the next minimum right to the marker of the

selected frame.

Remote: CALC:MARK2:MIN:LEFT (<)

Remote: CALC:DELT:MIN:LEFT (<)

Remote: CALC:MARK:MIN:RIGH (>)

Remote: CALC:DELT:MIN:RIGH (>)

Remote: CALC:MARK2:MIN:NEXT (abs)

Remote: CALC:DELT2:MIN:NEXT (abs)

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Next Min Y Search up/abs/dn

Selects the mode of the Next Min softkey, if the Y Search is selected (Marker Search Type

softkey). Three settings are available:

up Sets the active marker/delta marker to the next minimum above the current marker

position (constant x–axis value).

abs Sets the active marker/delta marker to the next higher minimum in y–axis direction

(constant x–axis value).

dn Sets the active marker/delta marker to the next minimum below the current marker

position (constant x–axis value).

Remote: CALC:MARK2:SPEC:Y:MIN:ABOV (up)

Remote: CALC:DELT2:SPEC:Y:MIN:ABOV (up)

Remote: CALC:MARK:SPEC:Y:MIN:NEXT (abs)

Remote: CALC:DELT4:SPEC:Y:MIN:NEXT (abs)

Remote: CALC:MARK3:SPEC:Y:MIN:BEL (dn)

Remote: CALC:DELT3:SPEC:Y:MIN:BEL (dn)

Marker Search Type

Displays the Marker Search Type dialog box to select the search direction:

XSearch The selected frame is searched for peaks (Next Peak X Search < abs >

softkey) or minima (Next Min X Search < abs > softkey).

YSearch The frames are searched with constant x–axis value for peaks (Next Peak Y

Search up/abs/dn softkey) or minima (Next Min Y Search up/abs/dn

softkey).

XY Search All frames are searched in x and y–axis direction for peaks or minima. Only

the absolute search mode is available.

Select Search Area

Displays the Marker Search Area dialog box to select the search area:

Visible The search takes only place in the area displayed in the Spectrogram view.

Memory The search takes place in the whole data range stored in the history buffer.

Remote: CALC:MARK2:SPEC:SAR MEM

Remote: CALC:DELT2:SPEC:SAR MEM

Center =Mkr Freq (span > 0)

For details refer to the Center =Mkr Freq softkey in the marker–> menu of the base unit.

Ref Lvl =Mkr Lvl

For details refer to the Ref Lvl =Mkr Lvl softkey in the marker–> menu of the base unit.

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Min

Sets the active marker/delta marker to the highest minimum according to the selected search

type (Marker Search Type softkey).

For further details refer to the Min softkey in the marker–> menu of the base unit.

Remote: CALC:MARK:MIN (in x direction)

Remote: CALC:DELT:MIN (in x direction)

Remote: CALC:MARK:SPEC:Y:MIN (y direction)

Remote: CALC:DELT4:SPEC:Y:MIN (y direction)

Remote: CALC:MARK3:SPEC:XY:MIN (xy direction)

Remote: CALC:DELT3:SPEC:XY:MIN (xy direction)

Next Min

Sets the active marker/delta marker to the next minimum according to the mode selected using

the Search Mode softkey. For the XY Search (Marker Search Type softkey), this softkey is not

available.

Remote: for search in x direction see Next Min X Search < abs > softkey

Remote: for search in y direction see Next Min Y Search up/abs/dn softkey

Search Limits

For details refer to the Search Limits softkey in the marker–> menu of the base unit.

Left Limit

For details refer to the Left Limit softkey in the marker–> menu of the base unit.

Right Limit

For details refer to the Right Limit softkey in the marker–> menu of the base unit.

Threshold

For details refer to the Threshold softkey in the marker–> menu of the base unit.

Search Lim Off

For details refer to the Search Lim Off softkey in the marker–> menu of the base unit.

Peak Excursion

For details refer to the Peak Excursion softkey in the marker–> menu of the base unit.

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Exclude LO

For details refer to the Exclude LO softkey in the marker–> menu of the base unit.

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Cable TV Measurements (Option K20)

The Cable TV Measurements option provides ready–made measurements for analog and digital TV

signals where most of the parameters are set automatically. Thus the measurements can be carried out

fast and with a minimum of effort.

Averaging can be applied to the measurement results. If the results are presented in a table, only the

values in the table are averaged, not the trace itself. For details refer to "Setting Traces – TRACE Key"

on page 4.39. Measurement specific settings as signal levels, limits etc. are saved using the save /

recall function described in section "Instrument Functions – Basic Settings", "Instrument Setup and

Interface Configuration – SETUP Key".

This option is available from firmware version 1.30.

To open the Cable TV Analyzer menu

If the Cable TV Analyzer mode is not the active measurement mode, press the MODE key and

activate the Cable TV Analyzer option.

If the Cable TV Analyzer mode is already active, press the MENU key.

The Cable TV Analyzer menu is displayed. .

Menu and softkey description

–"Softkeys of the Cable TV Analyzer menu" on page 4.223

–"Softkeys of the frequency menu (Cable TV Analyzer mode)" on page 4.226

–"Softkeys of the amplitude menu (Cable TV Analyzer mode)" on page 4.228

–"Softkeys of the trace menu (Cable TV Analyzer mode)" on page 4.229

–"Softkeys of the measurement menu (Cable TV Analyzer mode)" on page 4.230

The bandwidth, span, trigger and lines menus are not available in the Cable TV Analyzer mode. All

other menus are provided as described for the base unit. For details refer to the corresponding menu

descriptions.

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

– "Information in the status bar" on page 4.209

–"Channel tables" on page 4.210

–"Modulation standards" on page 4.210

–"Signal level" on page 4.211

–"Attenuation adjustment" on page 4.211

–"Labels used in the measurement displays" on page 4.212

–"Short list of cable TV terms and abbreviations" on page 4.213

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Tasks

–"To edit a channel table" on page 4.205

–"To create a channel table" on page 4.206

–"To copy a channel table" on page 4.206

–"To create a new modulation standard" on page 4.207

–"To edit a modulation standard" on page 4.208

–"To copy a modulation standard" on page 4.208

–"To perform a measurement using a channel table" on page 4.208

–"To perform a measurement without a channel table" on page 4.209

Measurements overview

All measurements can be performed with or without using a channel table (see also "To perform a

measurement using a channel table" on page 4.208 and "To perform a measurement without a channel

table" on page 4.209). In this section, the measurements are performed using a channel table. For

every measurement type, a short introduction is given. For a more detailed description on every

measurement type refer to chapter "Advanced Measurement Examples".

The measurements are divided into three groups:

analog TV Using an analog modulation standard, the measurement of one single channel is

performed.

digital TV Using a digital modulation standard, the measurement of one single channel is

performed.

TV analyzer Measurements on the entire TV network, i.e. several or all channels, are

performed.

For detailed information on the softkeys provided for each measurement type, refer to "Softkeys of the

measurement menu (Cable TV Analyzer mode)" on page 4.230.

The following measurement types are provided:

•analog TV measurements:

–"Spectrum" on page 4.213

–"Carriers" on page 4.214

–"C/N" on page 4.214

–"CSO" on page 4.215

–"CTB" on page 4.216

–"Video Scope" on page 4.217

–"Vision Modulation" on page 4.217

–"Hum" on page 4.218

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•digital TV measurements:

–"Spectrum" on page 4.218

–"Overview" on page 4.219

–"Constellation Diagram (Modulation Analysis)" on page 4.219

–"Modulation Errors (Modulation Analysis)" on page 4.220

–"Echo Pattern (Channel Analysis)" on page 4.220

–"Channel Power" on page 4.221

–"APD" on page 4.221

–"CCDF" on page 4.222

•TV analyzer measurement:

–"Tilt" on page 4.222

To edit a channel table

1. Press the Channel Setup softkey.

The Channel Tables dialog box is displayed.

If a measurement is running, the channel table used in the measurement (so–called active channel

table) is the channel table in focus. For further details refer also to "Channel tables" on page 4.210.

2. In the Channel Tables dialog box, focus the channel table you want to edit.

3. Press the Edit softkey.

The Channel Table dialog box and the edit submenu is displayed. Each line in the channel table

represents one channel.

The channels are displayed as they are entered and are not sorted automatically. If you prefer the

entries ordered with respect to their channel number, enter the channels accordingly.

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4. In the Name and Description field, edit the name and the description for the channel table via the

keypad.

If the name of a channel table is changed, the channel table with the old name is not overwritten but

retained, and a new channel table is created additionally.

In the title bar, *(unsaved changes) is displayed.

5. To edit an existing channel:

–In the No. and Comment column, edit the channel number and a comment for the channel via

the keypad.

–In the Modulation Standard column, open the list of all available modulation standards via the

ENTER key and select a modulation standard from the list. If you want to create, edit or view a

modulation standard, press the Modulation Options softkey. For further information refer to

"To create a new modulation standard" on page 4.207.

–In the RF MHz column, set an RF value. The RF represents the characteristic frequency of a

channel. Its interpretation depends on the modulation standard, e.g. for analog TV. For detailed

information refer to the RF softkey on page 4.226.

If the modulation standard is changed from an analog to a digital one, the RF frequency is

changed automatically. Therefore it is recommended to proceed in the described order, i.e. to

set the modulation standard first.

–In the Width MHz column, set a width value.

6. To create a new channel:

–Set the focus on a channel and press the Copy Channel softkey.

–Change the entries of the channel as desired.

7. To delete a channel, press the Delete Channel softkey.

8. To leave the whole channel table without saving the changes, press the Discard Changes softkey.

9. To save your changes, press the Save Changes softkey.

If the channel table contains invalid entries, an error message is displayed and saving is denied.

To create a channel table

1. In the Channel Setup submenu, press the New softkey to create a new channel table. For further

details refer also to "Channel tables" on page 4.210.

2. Continue as described in "To edit a channel table" on page 4.205, step 4.

To copy a channel table

1. Press the Channel Setup softkey.For further details refer also to "Channel tables" on page 4.210.

2. In the Channel Tables dialog box, focus the channel table you want to copy.

3. Press the Copy softkey.

4. Continue as described in "To edit a channel table" on page 4.205, step 4.

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To create a new modulation standard

1.In the Channel Setup submenu, press the Edit,New,or Copy softkey.

2. In the Modulation Options submenu, press the New softkey.

The Modulation Standard Options dialog box is displayed. As soon as you change entries, in the

title bar, *(unsaved changes) is displayed.

3. Enter a name for the modulation standard. It is recommended to include the TV standard in the

name, e.g. XY_DVB–C 16QAM.

If a modulation standard with the entered name already exists, the name is not accepted and a

message box is displayed. The input field remains editable.

4. Select the Signal Type.Depending on this setting, the fields and entries of the New Modulation

Standard dialog box are configured. Therefore it is recommended to proceed in the described

order.

5. For the Analog TV signal type, define the following parameters:

TV standard, sound system, group delay, color system, bar line, quiet line, sideband position. The

entries that can be selected may depend on the setting of the previous parameter.

For every parameter a default value is set. Change this setting if necessary.

6. For the Digital TV signal type, define the following parameters:

TV standard, constellation, symbol rate, roll–off, sideband position. The entries that can be selected

may depend on the setting of the previous parameter.

7. Press the previous key twice to go back to the Channel Table dialog box.

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8. Press the Save Changes softkey to save the changes.

The new modulation standard can be used for any channel.

9. To discard the changes, press the Discard Changes softkey.

To edit a modulation standard

1. In the Channel Setup – Edit / New / Copy submenu, press the Modulation Options softkey.

In the Modulation Standards dialog box, all modulation standards defined for this channel table

are displayed.

2. In the Modulation Standards dialog box, set the focus on the modulation standard you want to

edit.

3. Press the Edit softkey.

The Modulation Standard Options dialog box is displayed.

4. For further instructions see "To create a new modulation standard" on page 4.207.

To copy a modulation standard

1. Press the Channel Setup softkey.

2. In the Channel Tables dialog box, focus the channel table that contains the modulation standard

you want to copy.

3. Press the Copy softkey (for further details see "To create a channel table" on page 4.206).

4. Enter a name for the copied channel table.

5. If you want to alter the channel table, continue as described in "To edit a channel table" on page

4.205, step 4.

6. If you want to alter the modulation standard, press the Modulation Options softkey and then the

Edit softkey (for further details see "To create a new modulation standard" on page 4.207).

To perform a measurement using a channel table

1. Press the Channel Setup softkey.

The Channel Tables dialog box is displayed.

2. Select the channel table you want to use for the measurement and press the ENTER key or the

Activate softkey.

If no adequate channel table is available, you can edit or create a channel table, or perform the

measurement without a channel table (For details refer to "To edit a channel table" on page 4.205,

"To create a channel table" on page 4.206 or "To perform a measurement without a channel table"

on page 4.209).

3. Press the MEAS key.

4. In the measurement menu, press the softkey for the measurement you want to perform.

5. Set up the measurement as described for every measurement type in section "Measurements" on

page 4.204.

6. Press the RUN key to start the measurement.

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To perform a measurement without a channel table

1.Press the Channel Setup softkey.

The Channel Tables dialog box is displayed.

2. Select no channel table <none > and press the ENTER key or the Activate softkey.

3. Press the MEAS key.

4. In the measurement menu, press the Analog TV or Digital TV softkey.

5. Press the softkey for the measurement you want to perform.

6. Press the Analog TV Settings or Digital TV Settings softkey to setup the modulation parameters.

The Analog TV Settings or Digital TV Settings dialog box is displayed.

7. Enter the parameters for the measurement.

–analog TV: for details refer to the Analog TV Settings softkey in the analog TV measurement

menu.

–digital TV: for details refer to the Digital TV Settings softkey in the digital TV measurement

menu.

8. Press the Adjust Attenuation softkey to set the signal level appropriately.

9. Press the RUN key to start the measurement.

Information in the status bar

The status bar provides valuable information for working with the application. The information is

supplied context–sensitively and always refers to the graphical user interface element in focus. The

following types of information are displayed:

•possible range for a parameter

•description what to do

•hints

•warnings

•information on synchronization

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Channel tables

Channel tables are lists of channels, as they occur in a cable TV network. They provide a quick access

to the channels to be analyzed. Depending on its designation, a channel table can contain all channels

of a cable TV network or it can be restricted to a subset of all available channels, e.g. to all digital DVB–

Cchannels of the cable TV network.

In the Channel Tables dialog box, all available channel tables are sorted in alphabetic order. The name

of a channel table displayed in the list corresponds to the file name of the channel table, excluding the

file extension (*.cht).

The first list entry is <none >.If this entry is selected, no channel table is used. This can be useful for

measurements where no appropriate channel table is available, or if the Cable TV Measurements

option (K20) is used in a R&D laboratory. The Tilt measurement is not possible if no channel table is

used. For a step–by–step instruction refer to "To perform a measurement without a channel table" on

page 4.209.

Some channel tables are provided with the option. In these channel tables, all modulation standards are

set to <unused > (for further details refer to "Modulation standards" on page 4.210). Based on this set,

you can customize your own channel tables. Use the Restore Default Tables softkey to restore the

provided channel tables.

Modulation standards

Amodulation standard is a set of parameters defining the modulation properties of a TV signal (as used

in a TV channel). The signal type is the characteristic parameter of this set. Modulation standards are

defined for every channel table individually. As a maximum, 40 modulation standards can be created

per channel table. If, in a channel table, the modulation standard of a channel is set to <unused >,no

modulation standard is defined for this channel and therefore no measurements can be performed for

this channel.

If no channel table <none > is activated, a default modulation standard can be edited and changed via

the Analog TV Settings or Digital TV Settings softkey, but these changes are not saved permanently.

Pressing the PRESET key restores the default settings.

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Signal level

The signal level represents the expected RMS (digital TV) or peak (analog TV) channel power. This

power is only valid for one single channel, which is the current measurement channel. The signal level

is not identical to the level of the signal fed into the R&S FSL's RF input. This signal may consist of

many TV channels and hence have a much higher total power than the current channel to be

investigated.

In most measurements the signal level determines the upper horizontal display line. The signal level

value is related to the reference level by a constant offset. The reference level value is the maximum

value the AD converter can handle without distortion of the measured value. The signal level can either

be entered via the Signal Lvl key or by using the auto scale function (e.g. Auto Range softkey in the

Tilt measurement).

Attenuation adjustment

To get valid measurement results it is very important to set the R&S FSL's hardware, i.e. the attenuator

and the preamplifier, in a reasonable way. This can either be done manually or by relying on the Adjust

Attenuation softkey. Apart from the hardware setting, the displayed grid depends on the signal level of

the signal present in the current measurement channel.

Preamplifier IF Stages...

RF Overload

Detector

IF Overload

Detector

Attenuator ADC

RF Input

Fig. 4-23 R&S FSL hardware overview (only relevant parts for attenuation adjustment)

Fig. 4-23 shows the R&S FSL's hardware. It only comprises blocks that effect the level settings

described in this section. The signal from the device under test, e.g. a single cable TV transmitter or a

test point of a cable TV network with many channels, is plugged into the R&S FSL's RF input. The level

of the signal is reduced by the electronic attenuator or increased by the preamplifier (option B22

required). Then the signal is fed into the first mixer.

The level of this signal is typically referred to as mixer level. The mixer level is a very crucial parameter.

If the mixer level is too high the mixer will be overloaded. As a result, non–linear effects are produced,

e.g. intermodulation products, and the intermodulation products (e.g. CTB or CSO) of the device under

test can not be distinguished from those of the R&S FSL's mixer. To reveal this, the R&S FSL's

hardware has two overload detectors. The RF overload detector reports a mixer overload and the IF

overload detector indicates an overload of the analog to digital converter (ADC). The combination of the

results of both detectors control the overload message OVL displayed on the R&S FSL's screen.

Increasing the attenuation reduces the signal to noise ratio but also reduces the mixer's non–linear

effects. For cable TV measurements such as CTB,CSO,CCDF,and APD that measure non–linearities,

it is recommended to chose a higher attenuation than for other measurements.

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Attenuator setting Preamplifier setting

30 dB off

25 dB off

20 dB off

15 dB off

10 dB off

5dB off

0dB off

15 dB on

10 dB on

5dB on

0dB on

To adjust the attenuation manually, refer to the table above that lists reasonable combinations of

attenuator and preamplifier settings. The maximum total attenuation is achieved with the setting of the

first line. If you want to set the R&S FSL hardware manually you should start with the maximum

attenuation and then reduce the total attenuation until an overload will be reported (OVL displayed on

the screen). Depending on the intended measurement, you should then choose an attenuation of about

one or two steps higher than the setting that caused an overload. Be aware, that the manual attenuator

and the preamplifier setting is kept for all measurements. For further details refer to the RF Atten

Manual and Preamp On/Off softkeys.

Alternatively, you can automatically adjust the attenuator and the preamplifier using the Adjust

Attenuation softkey. The Cable TV Measurements option sets the optimum values for the

measurement. If you change to another measurement, these values may be altered automatically in

order to find the optimum setting (e.g. low noise or low distortion) for the chosen measurement.

Labels used in the measurement displays

Positions of special values are marked as vertical lines in the measurement display.

Label Description

VC Vision Carrier

SC1 Sound Carrier 1

SC2 Sound Carrier 2

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Short list of cable TV terms and abbreviations

Term or abbreviation Description

Amplitude Modulation

Analog modulation technique where the carrier amplitude contains the

information.

bar line see VITS

DVB–C

Digital Video Broadcasting for Cable Systems

DVB–C uses single carrier QAM as modulation technique.

DVB–T

Digital Video Broadcasting Terrestrial

DVB–T uses OFDM as modulation technique.

NTSC

National Television System Committee

Technique for transmitting color information in analog TV systems. NTSC is

for example adopted by the USA, Canada and Japan.

OFDM

Orthogonal Frequency Division Multiplexing

Digital multicarrier modulation technique. OFDM is used in terrestrial TV

networks, e.g. DVB–T systems.

PAL

Phase Alternation Line

Technique for transmitting color information in analog TV systems used in

many European countries.

QAM

Quadrature Amplitude Modulation

Digital modulation technique, where both phase and amplitude carry

information.

SECAM

Système en Couleur avec Mémoire

Technique for transmitting color information in analog TV systems. SECAM

is adopted by France, countries of the Eastern block and most Arabic

countries.

VITS

Vertical Interval Test Signal

Line of a TV picture where a special test signal is transmitted. VITS lines

are used for in–service measurements (cf. Quiet Line, Bar Line). These

lines are invisible, i.e. they are located before the first or after the last visible

line of the TV picture.

Measurements

In this section, every measurement type is introduced by a short description and by a basic step–by–

step instruction. Also a list with all parameters that can be altered is presented.

Spectrum – analog TV

This measurement gives an overview of the active measurement channel. The spectrum is displayed as

afull screen trace. The following parameters can be set:

Parameter

channel number

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the Spectrum softkey.

4. To adjust the input attenuator, press the Adjust Attenuation softkey.

5. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 4.214 E-11

Carriers – analog TV

This measurement determines the carrier powers (vision carrier, one or two sound carriers) and their

frequencies in analog TV channels and compares them against limits. The sound carrier power

frequencies are displayed relative to the measured vision carrier power frequency. The following

parameters can be set:

Parameter

channel number

limits

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the Carriers softkey.

4. To change the limits, press the Edit Table softkey.

5. To adjust the input attenuator, press the Adjust Attenuation softkey.

6. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

C/N – analog TV

This measurement determines the carrier–to–noise ratio. The measurement consists of two sub–

measurements: reference power measurement and noise measurement. The following parameters can

be set:

Parameter

reference power

measurement method

(In–Service, Off–Service, Quiet Line)

measurement frequencies

(CF, Span)

noise reference bandwidth

noise floor correction

limits

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the C/N softkey.

4. To change the setting of the reference power:

–Press the Reference Power softkey.

–Press the Reference Channel,Same as Meas Channel,or Manual Reference Power softkey

and, if necessary, enter a value.

R&S FSL Cable TV Measurements (Option K20)

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5. To configure the measurement, press the C/N Setup softkey.

The C/N Setup dialog box is displayed.

–Under Measurement Method,activate one of the options. For details refer to the C/N Setup

softkey in the measurement menu.

–Only for In–Service and Off–Service measurement method: Under Measurement

Frequencies,enter the center frequencies and span values. Set the span values relative to the

vision carrier of the current measurement.

–In the Noise Reference Bandwidth field, enter a number in order to change the default value.

–If the DUT's noise is close to the noise of the spectrum analyzer, activate the Noise Floor

Correction option.

6. To change the limits, press the Edit Table softkey.

7. To activate the carrier measurement with the next sweep, press the Meas Carrier softkey.

Prerequisite is, that in the C/N Setup dialog box under Measurement Methods the Off–Service

option is selected.

8. To adjust the input attenuator, press the Adjust Attenuation softkey.

9. Press the RUN key.

10. Only for In–Service and Off–Service measurement method: To measure in the next frequency

span defined via the C/N setup, press the Next Meas Frequency softkey.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

CSO – analog TV

This measurement determines the carrier–to–second order beat ratio (CSO). The measurement

consists of two sub–measurements: reference power measurement and beat measurement of second

order intermodulation products. The following parameters can be set:

Parameter

reference power

measurement method

(Off–Service, Quiet Line)

measurement frequencies

(CF, Span)

noise floor correction

limits

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the CSO softkey.

4. To change the setting of the reference power:

–Press the Reference Power softkey.

–Press the Reference Channel,Same as Meas Channel,or Manual Reference Power softkey

and, if necessary, enter a value.

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5. To configure the measurement, press the CSO Setup softkey.

The CSO Setup dialog box is displayed.

–Under Measurement Method,activate one of the options. For details refer to the CSO Setup

softkey in the measurement menu.

–Only for Off–Service measurement method: Under Measurement Frequencies,enter the

center frequencies and span values.

–If the DUT's noise is close to the noise of the spectrum analyzer, activate the Noise Floor

Correction option.

6. To change the limits, press the Edit Table softkey.

7. To activate the carrier measurement with the next sweep, press the Meas Carrier softkey.

Prerequisite is, that in the CSO Setup dialog box under Measurement Methods the Off–Service

option is selected.

8. To adjust the input attenuator, press the Adjust Attenuation softkey.

9. Press the RUN key.

10. Only for Off–Service measurement method: To measure in the next frequency span defined via the

C/N setup, press the Next Meas Frequency softkey.

For a more detailed description of this measurement type refer chapter "Advanced Measurement

Examples".

CTB – analog TV

This measurement determines the carrier–to–composite triple beat ratio (CTB). The measurement

consists of two sub–measurements: reference power measurement and beat measurement of third

order intermodulation products. The following parameters can be set:

Parameter

reference power

measurement frequencies

(CF, Span)

noise floor correction

limits

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the CTB softkey.

4. To change the setting of the reference power:

–Press the Reference Power softkey.

–Press the Reference Channel,Same as Meas Channel,or Manual Reference Power softkey

and, if necessary, enter a value.

5. To configure the measurement, press the CTB Setup softkey.

The CTB Setup dialog box is displayed.

–Under Measurement Frequencies,enter the center frequencies and span values.

–If the DUT's noise is close to the noise of the spectrum analyzer, activate the Noise Floor

Correction option.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 4.217 E-11

6. To change the limits, press the Edit Table softkey.

7. To adjust the input attenuator, press the Adjust Attenuation softkey.

8. Press the RUN key.

9. To measure in the next frequency span defined via the C/N setup, press the Next Meas Frequency

softkey.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Video Scope – analog TV

This measurement determines the luminance signal as a function of the time. The following parameters

can be set:

Parameter

channel number

field

line

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the Video Scope softkey.

4. For the TV standard Min combination with another color system than PAL,press the Field 1/2

softkey to select field 1 or 2.

5. Press the Line softkey to enter the line number.

6. To change the sweep time, press the Sweeptime Manual softkey and enter a value.

7. To define a trigger offset, press the Trigger Offset softkey and enter a value.

8. To adjust the input attenuator, press the Adjust Attenuation softkey.

9. Press the RUN key.

Note: The y–axis of the diagram is scaled in Volt for all TV standards except M. If the selected TV

standard is M, the y–axis of the diagram is scaled in IRE.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Vision Modulation – analog TV

This measurement determines the residual picture carrier and the modulation depth. The following

parameters can be set:

Parameter

channel number

limits

The basic procedure is the following:

1. Press the MEAS key.

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1300.2519.12 4.218 E-11

2. Press the Analog TV softkey.

3. Press the Vision Modulation softkey.

4. To change the limits, press the Edit Table softkey.

5. To adjust the input attenuator, press the Adjust Attenuation softkey.

6. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Hum – analog TV

This measurement determines the hum values. The hum is a not–wanted amplitude modulation with a

modulating frequency below 1 KHz and typically equal to the power line frequency or its harmonics. The

following parameters can be set:

Parameter

channel number

limits

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Analog TV softkey.

3. Press the Hum softkey.

4. To adjust the range of the y–axis, press the Auto Range softkey.

5. To change the limits, press the Edit Table softkey.

6. To adjust the input attenuator, press the Adjust Attenuation softkey.

7. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Spectrum – digital TV

This measurement gives an overview of the active measurement channel. The spectrum is displayed as

afull screen trace. The following parameters can be set:

Parameter

channel number

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the Spectrum softkey.

4. To adjust the input attenuator, press the Adjust Attenuation softkey.

5. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 4.219 E-11

Overview – digital TV

This measurement determines the modulation accuracy of digitally modulated single carrier cable TV

signals. The measurement results are displayed in a table: MER (rms) for the root mean square of the

modulation error rate, MER (peak) for the peak of the modulation error rate, EVM (rms) for the root

mean square of the error vector magnitude, EVM (peak) for the peak of the error vector magnitude,

Carrier Frequency Offset,and Symbol Rate Offset.Less important result parameters are displayed

in the result table of the Modulation Errors (Modulation Analysis) – digital TV measurement. The

following parameters can be set:

Parameter

channel number

limits

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the Overview softkey.

4. To magnify one parameter, press the Zoom softkey and activate the parameter. To go back to the

default setting, activate None.

5. To change the limits, press the Edit Table softkey.

6. To adjust the input attenuator, press the Adjust Attenuation softkey.

7. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Constellation Diagram (Modulation Analysis) – digital TV

This measurement displays the constellation diagram. The following parameters can be set:

Parameter

channel number

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the Modulation Analysis softkey.

4. Press the Const Diagram softkey.

5. To zoom into one quadrant, press the Zoom softkey and activate the parameter. To go back to the

general view, activate None.

6. To display the constellation diagram unchanged, while the I/Q samples are collected in the

background, press the Freeze softkey. To switch back to the continual update the display, press the

Freeze softkey again.

7. To adjust the input attenuator, press the Adjust Attenuation softkey.

8. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 4.220 E-11

Modulation Errors (Modulation Analysis) – digital TV

This measurement determines the modulation accuracy. The measurement results are displayed in a

table: Amplitude Imbalance (amplification difference of I and Q signal caused by a non–ideal IQ

modulator in the transmitter), Quadrature Error (phase offset relative to the ideal phase difference

between the I and Q signal), Carrier Suppression,and Phase Jitter (root mean square of phase

error). The more important result parameters are displayed in the result table of the Overview – digital

TV measurement. The following parameters can be set:

Parameter

channel number

limits

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the Modulation Analysis softkey.

4. Press the Modulation Errors softkey.

5. To magnify one parameter, press the Zoom softkey and activate the parameter. To go back to the

default setting, activate None.

6. To change the limits, press the Edit Table softkey.

7. To adjust the input attenuator, press the Adjust Attenuation softkey.

8. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Echo Pattern (Channel Analysis) – digital TV

This measurement determines the magnitude of the channel impulse response with respect to the

corresponding time delay. The following parameters can be set:

Parameter

channel number

unit

velocity factor

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the Channel Analysis softkey.

4. Press the Echo Pattern softkey.

5. To change the unit from Msto km or miles:

–Press the Velocity Factor softkey to define the velocity of propagation for the unit conversion.

–Press the Unit softkey to select the unit.

6. To zoom onto the echo pattern, press the Zoom softkey.

7. To adjust the input attenuator, press the Adjust Attenuation softkey.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 4.221 E-11

8. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Channel Power – digital TV

This measurement determines the channel power of a digital TV channel. The following parameters can

be set:

Parameter

channel number

limits

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the Channel Power softkey.

4. To change the limits, press the Edit Table softkey.

5. To adjust the input attenuator, press the Adjust Attenuation softkey.

6. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

APD – digital TV

This measurement determines the amplitude probability density function (APD). The following

parameters can be set:

Parameter

channel number

x– and y–axis scaling

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the APD softkey.

4. To change the scaling parameters of the x– and y–axis:

–Press the Scaling softkey.

–Press the corresponding softkey to change the parameters: x–Axis Signal Lvl,x–Axis Range,

y–Axis Max Value,y–Axis Min Value,Default Settings.

5. To adjust the input attenuator, press the Adjust Attenuation softkey.

6. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 4.222 E-11

CCDF – digital TV

This measurement determines the complementary cumulative distribution function (CCDF) of the

complex base band signal. The following parameters can be set:

Parameter

channel number

power exceeding probability

x– and y–axis scaling

The basic procedure is the following:

1. Press the MEAS key.

2. Press the Digital TV softkey.

3. Press the CCDF softkey.

4. To determine the power exceeded with a given probability, press the Percent Marker softkey.

5. To change the scaling parameters of the x– and y–axis:

–Press the Scaling softkey.

–Press the corresponding softkey to change the parameters: x–Axis Signal L,x–Axis Range,

y–Axis Max Value,y–Axis Min Value,Default Settings.

6. To adjust the input attenuator, press the Adjust Attenuation softkey.

7. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Tilt – TV analyzer

This measurement determines the frequency response of the cable TV network by measuring the

channel power of every channel. The whole measurement sequence can take some time, depending on

the number of channels. The following parameters can be set:

Parameter

span

modulation standard

The basic procedure is the following:

1. Select the appropriate channel table and activate it (for details refer to "To perform a measurement

using a channel table" on page 4.208).

2. Press the MEAS key.

3. Press the TV Analyzer softkey.

4. Press the Tilt softkey.

5. To restrict the channels to be measured, press the Tilt Setup softkey:

The Tilt Setup dialog box is displayed.

–To limit the frequency range, under Span,enter a start and stop frequency.

–To select only channels of certain modulation standards for the measurement, under

Modulation Standards,activate the modulation standards to be included in the measurement.

6. To adjust the range of the y–axis, press the Auto Range softkey.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 4.223 E-11

7. Press the RUN key.

For a more detailed description of this measurement type refer to chapter "Advanced Measurement

Examples".

Softkeys of the Cable TV Analyzer menu

The following table shows all softkeys available in the Cable TV Analyzer menu. It is possible that your

instrument configuration does not provide all softkeys. If a softkey is only available with a special option,

model or (measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Submenu / Command Submenu / Command Command

Channel Setup Activate

New Copy Channel

Delete Channel

Modulation Options New

Delete

Edit

Save Changes

Discard Changes

Copy same contents as New

Delete

Edit same contents as New

Restore Default Tables

Adjust Attenuation

Channel Setup

Opens the Channel Tables dialog box with all available channel tables listed, and displays a

submenu to activate, create, edit, copy, and delete channel tables and modulation standards.

For further information on channel tables refer to "Channel tables" on page 4.210 and

"Modulation standards" on page 4.210.

Activate

Activates the channel table in focus. Alternatively to this softkey, the rotary knob or the ENTER

key can be pressed.

Activating a channel table is synonymous to loading the selected channel table and discarding

the previously active channel table. As a prerequisite, the channel table must have at least one

channel with a digital or analog modulation standard. Otherwise the channel table cannot be

loaded and an error message is displayed. If no appropriate channel table exists, select

<none > for no channel table.

Remote: CONF:TV:CTAB:SEL 'TV–ITALY'

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 4.224 E-11

New

Creates a new channel table and opens the Channel Table dialog box with the according

submenu to edit the channel table.

It is recommended to use long names in order to distinguish the channel tables from each other

easily.

For further details refer to "To create a channel table" on page 4.206.

Copy Channel

Copies the channel in focus.

Delete Channel

Deletes the channel in focus. If the channel table consists only of one channel, this channel can

not be deleted.

Modulation Options

Opens the Modulation Standards dialog box with all available modulation standards of the

channel table listed, and displays a submenu to create, edit, and delete a modulation standard.

For further information on modulation standards refer to "Modulation standards" on page 4.210,

"To create a new modulation standard" on page 4.207, and "To copy a modulation standard" on

page 4.208.

New

Opens the Modulation Standard Options dialog box to define a new modulation standard for

the channel table.

For further information on modulation standards refer to "Modulation standards" on page 4.210

and "To create a new modulation standard" on page 4.207.

Remote: DDEM:SBAN NORM

Remote: DDEM:SRAT 1000000

Remote: DDEM:FILT:ALPH R018

Remote: TV:MST:NAME 'TEST'

Remote: TV:MST:STYP DTV

Remote: TV:MST:FILT:GDEL FLAT

Remote: SET:TV:STAN DK

Remote: SET:TV:STAN:AUD FM65MONO

Remote: SET:TV:STAN:COL SEC

Delete

Deletes the modulation standard focused in the Modulation Standards dialog box.

R&S FSL Cable TV Measurements (Option K20)

1300.2519.12 4.225 E-11

Edit

Opens the Modulation Standard Options dialog box for the modulation standard in focus.

Alternatively to this softkey, the rotary knob or the ENTER key can be pressed.

For details refer to "Modulation standards" on page 4.210 and "To create a new modulation

standard" on page 4.207.

Remote: DDEM:SBAN NORM

Remote: DDEM:SRAT 1000000

Remote: DDEM:FILT:ALPH R018

Remote: TV:MST:NAME 'TEST'

Remote: TV:MST:STYP DTV

Remote: TV:MST:FILT:GDEL FLAT

Remote: SET:TV:STAN DK

Remote: SET:TV:STAN:AUD FM65MONO

Remote: SET:TV:STAN:COL SEC

Save Changes

Saves all changes in channels and modulation standards, if the channel table passes the

compliance check. For further details refer to "To edit a channel table" on page 4.205.

Discard Changes

After confirmation, discards all changes in channels and modulation standards made for the

current channel table. Reloads and displays the original channel table.

Copy

Copies the channel table in focus and opens the Channel Table dialog box with the according

submenu to edit the channel table. If you enter a name that is already in use you are prompted

to enter another one.

For further details refer to "To create a channel table" on page 4.206.

Delete

Deletes the channel table in focus. If the channel table in focus is also the active channel table,

no channel table <none > will be activated.

Edit

Opens the Channel Table dialog box for the channel table in focus and displays a submenu for

editing this channel table. For details refer to "To edit a channel table" on page 4.205.

Restore Default Tables

Restores the default set of channel tables and the channel table examples.

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1300.2519.12 4.226 E-11

Adjust Attenuation

Adjusts the input attenuator. For details on the adjustment procedure refer to "Attenuation

adjustment" on page 4.211.

Remote: POW:ACH:PRES:RLEV

Softkeys of the frequency menu (Cable TV Analyzer mode)

The following table shows all softkeys available in the frequency menu in Cable TV Analyzer mode

(FREQ key). It is possible that your instrument configuration does not provide all softkeys. If a softkey is

only available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Menu / Command Command

Channel

RF Stepsize Manual

Channel Width

Frequency Abs/Rel

Opens an edit dialog box to enter the RF frequency. The interpretation of the RF frequency

depends on the signal type (analog TV or digital TV) to measure:

Signal type RF

<unused > center frequency

analog TV vision carrier frequency

digital TV center frequency

If the modulation standard or the active measurement channel is changed, the RF is

automatically adapted.

If no channel table <none > is activated, the interpretation of the RF frequency depends on the

active measurement.

Remote: FREQ:RF 10MHZ

R&S FSL Cable TV Measurements (Option K20)

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Channel

Displays the active channel table to select a particular measurement channel. The active

channel is highlighted.

All channels can be selected, except those with modulation standard <unused >.Incompatible

channels are marked accordingly; for example an analog TV channel inside a digital TV

measurement. If an incompatible channel is selected, the current measurement is aborted, and

the spectrum measurement will become the active measurement. If no channel table <none >

is activated, this softkey is not available.

If you perform a measurement over all possible channels, use the Channel No softkey of the

measurement menu to change from one channel to the next channel of the channel table

quickly.

Remote: FREQ:CHAN 3

RF Stepsize

Opens a submenu to set the RF step size. If no channel table <none > is activated, this softkey

is not available.

Remote: FREQ:CENT:STEP 120MHz

Manual

For details refer to the Manual softkey in the frequency menu of the base unit.

Channel Width

Takes the channel width of the current measurement channel as RF step size once.

If no channel table <none > is activated, this softkey is not available.

Frequency Abs/Rel

Sets the labeling of the frequency axis.

If absolute labeling is selected, the absolute frequencies are displayed, and all markers are

absolute.

If relative labeling is selected, the reference is set to 0 Hz. The reference depends on the signal

type:

Signal type Reference

<unused > center frequency

analog TV vision carrier frequency

digital TV center frequency

This softkey is not available in the Tilt measurement.

Remote: SWE:SPAC ABS

Cable TV Measurements (Option K20) R&S FSL

1300.2519.12 4.228 E-11

Softkeys of the amplitude menu (Cable TV Analyzer mode)

The following table shows all softkeys available in the amplitude menu in Cable TV Analyzer mode

(AMPT key). It is possible that your instrument configuration does not provide all softkeys. If a softkey is

only available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Command

Signal Lvl

Range Log

Range Linear

Preamp On/Off

Signal Lvl Position

RF Atten Manual

More 

Signal Lvl Offset

Signal Lvl Position

Grid Abs/Rel

Unit

Input 50 L/75 L

Signal Lvl

Opens an edit dialog box to enter the expected RMS (digital TV) or peak (analog TV) input

power of the signal. This parameter is channel–specific and is set, in a cable network with

multiple channels, only for the signal of interest. However, mostly channels with the same signal

type have the same signal level.

Remote: DISP:TRAC:Y:RLEV –60dBm

Range Log

For details refer to the Range Log softkey in the amplitude menu of the base unit.

Range Linear

For details refer to the Range Linear softkey in the amplitude menu of the base unit.

Preamp On/Off

For details refer to the Preamp On/Off softkey in the amplitude menu of the base unit.

Signal Lvl Position

For details refer to the Ref Level Position softkey in the amplitude menu of the base unit.

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RF Atten Manual

Opens an edit dialog box to enter the attenuation. For details see also "Attenuation adjustment"

on page 4.211.

Signal Lvl Offset

For details refer to the Ref Level Offset softkey in the amplitude menu of the base unit.

Grid Abs/Rel

For details refer to the Grid Abs / Rel softkey in the amplitude menu of the base unit.

Unit

Opens a list containing all allowed units to select the appropriate unit. These units are used for

scaling diagrams or input/output of parameters and limits.

The variety of the absolute units depends on the selected measurement, as relative unit dB is

used.

The units are selected according to the state of the Range Log and Range Linear softkeys. For

voltage units, the input impedance (Input 50 D/75 Dsoftkey) is used for the conversion.

Remote: CALC:UNIT:POW DBM

Input 50 D/75 D

For details refer to the Input 50 D/75 Dsoftkey in the amplitude menu of the base unit.

Typically, cable TV networks have an impedance of 75 L(set the softkey to 75 L). For precise

(level) measurements an adapter of the RAZ type (= 25 Lin series to the input impedance of the

instrument) should always be used.

Softkeys of the trace menu (Cable TV Analyzer mode)

In the Cable TV Analyzer mode, 4 traces are available. In the measurements listed below, averaging is

not carried out over the measurement points (trace) but over the values listed in the result table.

Therefore instead of a trace mode a result mode is selected via the Result Mode softkey.

•Carriers

•C/N, CSO, CTB

•Vision Modulation

•Hum

•Overview

•Modulation Errors

•Channel Power

•Tilt

Apart from these differences, the trace menu works as described in "Setting Traces – TRACE Key" on

page 4.39.

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1300.2519.12 4.230 E-11

Softkeys of the measurement menu (Cable TV Analyzer mode)

The following table shows all softkeys available in the measurement menu in Cable TV Analyzer mode

(MEAS key). It is possible that your instrument configuration does not provide all softkeys. If a softkey is

only available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Menu /

Command

Submenu /

Command

Submenu / Command Command

Analog TV Spectrum Channel No

Adjust Attenuation

Carriers Channel No

Edit Table

Adjust Attenuation

C/N Channel No

Reference Power Reference Channel

Same as Meas

Channel

Manual Reference

Power

C/N Setup Insert Line

Delete Line

Next Meas Frequency

Edit Table

Meas Carrier

Adjust Attenuation

CSO Channel No

Reference Power same contents as in

C/N submenu

CSO Setup same contents as in

C/N Setup submenu

Next Meas Frequency

Edit Table

Meas Carrier

Adjust Attenuation

CTB Channel No

Reference Power same contents as in

C/N submenu

CTB Setup same contents as in

C/N Setup submenu

Next Meas Frequency

Edit Table

Meas Carrier

Adjust Attenuation

Analog TV Settings

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Menu /

Command

Submenu /

Command

Submenu / Command Command

More 

Video Scope Channel No

Line

Field 1/2

Sweeptime Manual

Trigger Offset

Adjust Attenuation

Vision Modulation Channel No

Edit Table

Adjust Attenuation

Hum Channel No

Auto Range

Edit Table

Adjust Attenuation

Analog TV Settings

Digital TV Spectrum Channel No

Shoulder Atten On/Off

Adjust Attenuation

Overview Channel No

Zoom

Edit Table

Adjust Attenuation

Modulation Analysis Const Diagram Channel No

Zoom

Freeze

Adjust Attenuation

Modulation Errors Channel No

Zoom

Edit Table

Adjust Attenuation

Channel Analysis Echo Pattern Channel No

Unit

Zoom

Velocity Factor

Adjust Attenuation

Digital TV Settings

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Menu /

Command

Submenu /

Command

Submenu / Command Command

More 

Channel Power Channel No

Edit Table

Adjust Attenuation

APD Channel No

Scaling x–Axis Signal Lvl

x–Axis Range

y–Axis Max Value

y–Axis Min Value

Default Settings

Adjust Attenuation

CCDF Channel No

Percent Marker

Scaling same contents as in

APD submenu

Adjust Attenuation

Digital TV Settings

TV Analyzer Tilt Tilt Setup

Auto Range

Adjust Attenuation

Analog TV

Opens a submenu with all available analog TV measurements. Every measurement type

provides its own submenu to set the parameters. Additionally the Analog TV Settings softkey

gives access to the modulation standard information.

This softkey is only available if the active channel table has at least one channel with an analog

TV modulation standard, or if no channel table <none > is activated.

If a digital TV channel is in use when pressing this softkey, automatically the first analog channel

of the active channel table is selected.

For further details refer also to section "Measurements"on page 4.204.

Spectrum

Opens a submenu to measure an analog TV spectrum.

For further information refer to "Spectrum – analog TV" on page 4.213.

Remote: CONF:ATV:MEAS ASP

Remote: TRAC? TRACE1

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Channel No

Opens an edit dialog box to select the measurement channel. Select the previous or next

channel via the rotary knob or the arrow keys, or enter the channel number.

Only compatible channels can be selected, entries of incompatible channel are skipped.

Incompatible channels are channels of a different signal type or channels with the modulation

standard <unused >.

If you want to select a particular channel, use the Channel softkey in the frequency menu. If

channel table < none > is selected, use the RF softkey in the frequency menu for frequency

input.

Remote: FREQ:CHAN 3

Shoulder Atten On/Off

Activates or deactivates the shoulder measurement in accordance to ETSI TR 101290 standard.

If activated, the results (upper and lower shoulder attenuation) are displayed as a list below the

spectrum.

This softkey is available from firmware version 1.50.

Remote: CALC:DTV:RES? SAL

Remote: CALC:DTV:RES? SAUP

Remote: CONF:DTV:MEAS:SATT OFF

Carriers

Opens a submenu to measure the carriers powers.

For further information refer to "Carriers – analog TV" on page 4.214.

Remote: CONF:ATV:MEAS CARR

Remote: CONF:ATV:RES:CARR? ALL

Edit Table

Activates the edit mode to change the limits within the result table. To edit a field, press the

ENTER key. For all available parameters, the limit fields contain default values. If a field is

empty, the corresponding limit can not be set for the measurement.

For the following measurements, the unit for the upper and lower limits differs. The unit is set in

the last table column. Only the limits carrying the set unit are displayed in the table. To display

the other limts, change the unit first.

Measurement Parameter Unit lower limits Unit upper limit

Hum dB %

Overview, Modulation Errors MER (rms) dB %

MER (peak) dB %

EVM (rms) dB %

EVM (peak) dB %

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Remote: CALCulate:ATV:LIMit Subsystem, CALCulate:ATV:LIMit:RESult Subsystem,

CALCulate:ATV:RESult Subsystem for analog TV

Remote: CALCulate:DTV:LIMit Subsystem, CALCulate:DTV:LIMit:RESult Subsystem,

CALCulate:DTV:RESult Subsystem for digital TV

Meas Carrier

Switches the carrier or noise measurement on or off.

activate

Starts a new carrier measurement with the next sweep.

deactiv

ated

Starts a new noise measurement with the next sweep.

This softkey is only available in the Off–Service measurement method (setup dialog box).

Remote: CONF:ATV:CN:MEAS NOIS

Remote: CONF:ATV:CSO:MEAS NOIS

Remote: CONF:ATV:CTB:MEAS NOIS

C/N

Opens a submenu to measure the carrier–to–noise ratio.

For further information refer to "C/N – analog TV" on page 4.214.

Remote: CONF:ATV:MEAS CN

Remote: CALC:ATV:RES:CN? ALL

Reference Power

Opens a submenu to select the reference power method. The state of this submenu is not part

of the measurement parameter set. If you switch from one measurement to another, the settings

of this submenu are unchanged.

The set reference power method is indicated on the softkey:

(Meas Ch) Reference Channel softkey

(same) Same as Meas Channel softkey

<value> Manual Reference Power softkey

Remote: ATV:CN:POW:REF:MODE RCH

Remote: ATV:CSO:POW:REF:MODE RCH

Remote: ATV:CTB:POW:REF:MODE RCH

Reference Channel

Displays the active channel table to select a particular measurement channel. For further details

refer to the Channel softkey in the frequency menu.

Remote: ATV:CN:POW:REF:CHAN:MAN 5

Remote: ATV:CSO:POW:REF:CHAN:MAN 6

Remote: ATV:CTB:POW:REF:CHAN:MAN 5

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Same as Meas Channel

Sets the active measurement channel as reference channel. If the active measurement channel

is changed, e.g. via the Channel No softkey, the reference channel is also changed

automatically. This is the default setting.

Remote: ATV:CN:POW:REF:MODE MCH

Remote: ATV:CSO:POW:REF:MODE MCH

Remote: ATV:CTB:POW:REF:MODE MCH

Manual Reference Power

Opens an edit dialog box to enter the reference power. The unit is set via the Unit softkey in the

amplitude menu.

Remote: ATV:CN:POW:REF:MAN 10

Remote: ATV:CSO:POW:REF:MAN 20

Remote: ATV:CTB:POW:REF:MAN 10

C/N Setup

Opens the C/N Setup dialog box to configure the following:

–Measurement Method

In–Service:While an analog TV signal is present, a gap between two consecutive channels,

where only noise exists, is used to determine the noise power. A noise marker is placed there,

and the noise power is determined.

Off–Service:The current measurement channel has to be switched off. An according message

prompts you to do so. In this channel, a noise marker is placed, and the noise power is

determined.

Quiet Line:While an analog TV signal is present, the carrier–to–noise ratio is measured using

the so–called "Quiet Line''. The measurement is fully automated.

–Measurement Frequencies

The table contains center frequencies (CF) and span values. The center frequency values are

relative to the vision carrier frequency. One parameter set defines a frequency span and is

used in one measurement. Only selected parameter sets are used in the measurements. If no

parameter set is selected at all, the measurement is performed over all listed parameter sets.

For the Quiet Line measurement method, the table remains empty. For the other measurement

methods, the table must contain at least one parameter set.

–Noise Reference Bandwidth

The entered value is multiplied with the measured noise power density to determine the noise

power value.

–Noise Floor Correction

This option activates or deactivates the noise correction factor measurement. By default, the

option is deactivated. In the noise correction factor measurement, the noise of the R&S FSL is

determined. Therefore you are prompted to remove the cable from the R&S FSL's RF input

when activating the option.

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Remote: ATV:CN:MEAS:MODE OSER (Measurement Method)

Remote: ATV:CN:TABL1:MFR 1,1000,1000 (Measurement Frequencies)

Remote: ATV:CN:BWID 7MHZ (Noise Reference Bandwidth)

Remote: ATV:CN:POW:NCOR ON (Noise Floor Correction)

Insert Line

Inserts a line in the Measurement Frequencies table to add a parameter set. This softkey is

only active, if the focus is on the Measurement Frequencies table.

Delete Line

Deletes the focused line in the Measurement Frequencies table. This softkey is only active, if

the focus is on the Measurement Frequencies table.

Next Meas Frequency

Switches from one frequency span to the next according to the parameter sets (center

frequency, span) defined under Measurement Frequencies in the setup dialog box. Only

activated entries are considered.

Remote: ATV:CN:CFR:NEXT

Remote: ATV:CSO:CFR:NEXT

Remote: ATV:CTB:CFR:NEXT

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CSO

Opens a submenu to measure the carrier–to–second order beat ratio (CSO).

For further information refer to "CSO – analog TV" on page 4.215.

Remote: CONF:ATV:MEAS CSO

Remote: CALC:ATV:RES:CSO? ALL

CSO Setup

Opens the CSO Setup dialog box to configure the following:

–Measurement Method

Off–Service:The current measurement channel has to be switched off. An according message

prompts you to do so. In this channel, a noise marker is placed, and the noise power is

determined.

Quiet Line:While an analog TV signal is present, the carrier–to–second order beat ratio is

measured using the so–called "Quiet Line''. The measurement is fully automated.

–Measurement Frequencies

The table contains center frequencies (CF) and span values. The center frequency values are

relative to the vision carrier frequency. One parameter set defines a frequency span and is

used in one measurement. Only selected parameter sets are used in the measurements. If no

parameter set is selected at all, the measurement is performed over all listed parameter sets.

For the Quiet Line measurement method, the table remains empty.

–Noise Floor Correction

This option activates or deactivates the noise correction factor measurement. By default, the

option is deactivated. In the noise correction factor measurement, the noise of the R&S FSL is

determined. Therefore you are prompted to remove the cable from the R&S FSL's RF input

when activating the option.

Remote: ATV:CSO:MEAS:MODE QLIN (Measurement Method)

Remote: ATV:CSO:TABL2:MFR 1,–2000,2000 (Measurement Frequencies)

Remote: ATV:CSO:POW:NCOR ON (Noise Floor Correction)

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CTB

Opens a submenu to measure the carrier–to–composite triple beat ratio (CTB). The

measurement always takes place off–service with current measurement channel has to be

switched off. An according message prompts you to do so. In this channel, a noise marker is

placed, and the noise power is determined.

For further information refer to "CTB – analog TV" on page 4.216.

Remote: CONF:ATV:MEAS CTB

Remote: CALC:ATV:RES:CTB? ALL

CTB Setup

Opens the CTB Setup dialog box to configure the following:

–Measurement Frequencies

The table contains center frequencies (CF) and span values. The center frequency values are

relative to the vision carrier frequency. One parameter set defines a frequency span and is

used in one measurement. Only selected parameter sets are used in the measurements. If no

parameter set is selected at all, the measurement is performed over all listed parameter sets.

–Noise Floor Correction

This option activates or deactivates the noise correction factor measurement. By default, the

option is deactivated. In the noise correction factor measurement, the noise of the R&S FSL is

determined. Therefore you are prompted to remove the cable from the R&S FSL's RF input

when activating the option.

Remote: ATV:CTB:TABL1:MFR 1,100,10000 (Measurement Frequencies)

Remote: ATV:CTB:POW:NCOR ON (Noise Floor Correction)

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Analog TV Settings

Opens the Analog TV Settings dialog box to modify the modulation standard parameters. The

displayed parameters are derived from the modulation standard referenced in the active channel

table. If no channel table <none > is activated, the default modulation standard is used (for

details see also "Modulation standards" on page 4.210).

For the modulation standard, the changes made via this softkey are only kept as long as a

measurement channel with the same modulation standard is selected. If a measurement

channel with a different modulation standard is selected, or the PRESET key is pressed, the

changes are lost.

If no channel table <none > is activated, the changes of the default modulation standard are

kept as long as the PRESET key is not pressed.

Remote: SET:TV:STAN DK (TV Standard)

Remote: SET:TV:STAN:AUD FM65MONO (Sound System)

Remote: TV:MST:FILT:GDEL FLAT (Group Delay)

Remote: SET:TV:STAN:COL SEC (Color System)

Remote: TRIG:VID:BLIN 16,TRIG:VID:BFI 2,TRIG:VID:BLIN:TYPE CCIR17 (Bar Line)

Remote: TRIG:VID:QLIN 20,TRIG:VID:QFI 2 (Quiet Line)

Remote: DDEM:SBAN NORM (Sideband Position)

Video Scope

Opens a submenu to measure the luminance signal. For this measurement, the TRACE key is

not available.

For further information refer to "Video Scope – analog TV" on page 4.217.

Remote: CONF:ATV:MEAS VSC

Remote: TRAC? TRACE1

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Line

Opens an edit dialog box to set the line number of the TV picture. The numbering conventions

depend on the following conditions:

TV standard Color system Field number Line numbering



M– – 1, 2, …, 625



MPAL – 1, 2, …, 525



MNTSC 1 1, 2, …, 263



MNTSC 2 1, 2, …, 262

Remote: TRIG:VID:LINE 17

Field 1/2

Selects the active field. Field 1 is the default state. This softkey is only available for the TV

standard Min combination with another color system than PAL.

For details on numbering conventions of TV picture lines refer to the Line softkey.

Remote: TRIG:VID:FIEL 2

Sweeptime Manual

Opens an edit dialog box to enter the total sweep time. Possible values are 25, 50 and 100 Ms.

The set value is indicated on the softkey.

Remote: SWE:TIME 10s

Trigger Offset

Opens an edit dialog box to enter a value for the trigger offset. The set value is indicated on the

softkey.

Remote: TRIG:HOLD 500us

Vision Modulation

Opens a submenu to measure the residual picture carrier and the modulation depth.

For further information refer to "Vision Modulation – analog TV" on page 4.217.

Remote: CONF:ATV:MEAS VMOD

Remote: CALC:ATV:RES:VMOD? ALL

Hum

Opens a submenu to measure the hum.

For further information refer to "Hum – analog TV" on page 4.218.

Remote: CONF:ATV:MEAS HUM

Remote: CALC:ATV:RES:HUM?

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Auto Range

Automatically adjusts the x– and y–axis once. Alternatively the range of the y–axis can be

changed via the Range Log softkey or the Range Linear softkey in the amplitude menu.

Remote: DISP:TRAC:Y:AUTO ON

Digital TV

Opens a submenu with all available digital TV measurements. Every measurement type

provides its own submenu to set the parameters. Additionally the Digital TV Settings softkey

gives access to the modulation standard information.

This softkey is only available if the active channel table has at least one channel with a digital TV

modulation standard, or if no channel table <none > is activated.

If an analog TV channel is in use when pressing this softkey, automatically the first digital

channel of the active channel table is selected.

For further details refer also to section "Measurements"on page 4.204.

Spectrum

Opens a submenu to measure a digital TV spectrum.

For further information refer to "Spectrum – digital TV" on page 4.218.

Remote: CONF:DTV:MEAS DSP

Remote: TRAC? TRACE1

Overview

Opens a submenu to measure the modulation accuracy.

For further information refer to "Overview – digital TV" on page 4.219.

Remote: CONF:DTV:MEAS OVER

Remote: CALC:DTV:RES? ALL

Zoom

Opens the Select Result Parameter dialog box to set the zoom:

None The whole result table is displayed (default setting).

[parameter] The selected parameter is displayed separately in the upper pane.

Remote: DISP:ZOOM:OVER MERP

Remote: DISP:ZOOM:MERR MERP

Modulation Analysis

Opens a submenu to select one of the following modulation measurements:

–Const Diagram

–Modulation Errors

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Const Diagram

Opens a submenu to display the constellation diagram. For further information refer to

"Constellation Diagram (Modulation Analysis) – digital TV" on page 4.219.

Remote: CONF:DTV:MEAS CONS

Remote: TRAC? TRACE1

Zoom

Opens the Select Constellation Zoom Mode dialog box to set the zoom:

<none > The whole constellation diagram is displayed (default setting).

Quadrant 1/2/3/4 The selected quadrant is displayed. A pictogram shows the

quadrant position.

Remote: DISP:ZOOM:QUAD 1

Freeze

Sets the display mode. If activated, the constellation diagram is displayed unchanged, while the

I/Q samples are collected in the background. If deactivated, the constellation diagram is

displayed on basis of the current I/Q samples and, in continuous sweep mode, is updated with

every measurement.

If a new zoom mode (see Zoom softkey) is selected, this softkey is automatically set to off.

Remote: DISP:TRAC1:MODE:FRE ON

Modulation Errors

Opens a submenu to measure the modulation accuracy.

For further information refer to "Modulation Errors (Modulation Analysis) – digital TV" on page

4.220.

Remote: CONF:DTV:MEAS MERR

Remote: CALC:DTV:RES? ALL

Channel Analysis

Opens a submenu to select a measurement for checking the transmission performance of a

channel:

–Echo Pattern

Echo Pattern

Opens a submenu to measure the magnitude of channel impulse response with respect to the

corresponding time delay.

For further information refer to "Echo Pattern (Channel Analysis) – digital TV" on page 4.220.

Remote: CONF:DTV:MEAS EPAT

Remote: TRAC? TRACE1

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Unit

Opens the Unit dialog box to select the unit: s, m.

Remote: CALC:DTV:UNIT:POW:EPAT M

Zoom

Opens an edit dialog box to zoom onto the echo pattern measurement, around 0 Ms. The zoom

factor can vary from 1 to 20.

Remote: DISP:ZOOM:EPAT 2

Remote: DISP:ZOOM:EPAT:STAT ON

Velocity Factor

Opens an edit dialog box to enter the velocity of propagation of the signal in the transmission

channel (e.g. cable), relative to speed of light.

The velocity factor is used to convert the impulse response results from seconds into meter,

when changing the unit via the Unit softkey.

Remote: CORR:RVEL 2

Digital TV Settings

Opens the Digital TV Settings dialog box to modify the modulation standard and equalizer

parameters. For details on the modulation standard parameters, refer also to "Modulation

standards" on page 4.210 and "To create a new modulation standard" on page 4.207.

Under Equalizer,the following equalizer parameters can be modified:

–Activating or deactivating the equalizer: If the Activate option is activated, the equalizer is

switched on and filters the signal.

–Activating or deactivating the Freeze Equalizer option: If activated the equalizer coefficients

remain unchanged. If deactivated the equalizer taps are changed with every measurement.

–Pressing the Reset button sets all equalizer parameters to their default values.

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Remote: SET:TV:STAN DK (TV Standard)

Remote: SOURce:DM:FORM QAM128 (Constellation)

Remote: DDEM:SRAT 1000000 (Symbol Rate)

Remote: DDEM:FILT:ALPH R018 (Roll–Off)

Remote: DDEM:SBAN NORM (Sideband Position)

Remote: DDEM:EQU OFF (Activate Equalizer)

Remote: DDEM:EQU:FRE ON (Freeze Equalizer)

Remote: DDEM:EQU:RES (Reset Equalizer)

Channel Power

Opens a submenu to measure the channel power of a digital TV signal.

For further information refer to "Channel Power – digital TV" on page 4.221.

APD

Opens a submenu to measure the amplitude probability density function (APD) of a digital TV

signal sampled in the complex base band.

For further information refer to "APD – digital TV" on page 4.221.

Remote: CONF:DTV:MEAS APD

Remote: TRAC? TRACE1

Scaling

For details refer to the Scaling softkey in the power measurement menu of the base unit.

x–Axis Signal Lvl

For details refer to the x–Axis Ref Level softkey in the power measurement menu of the base

unit.

x–Axis Range

For details refer to the x–Axis Range softkey in the power measurement menu of the base unit.

y–Axis Max Value

For details refer to the y–Axis Max Value softkey in the power measurement menu of the base

unit.

y–Axis Min Value

For details refer to the y–Axis Min Value softkey in the power measurement menu of the base

unit.

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Default Settings

For details refer to the Default Settings softkey in the power measurement menu of the base

unit.

CCDF

Opens a submenu to measure the complementary cumulative distribution function (CCDF) of the

amplitude of a digital TV signal sampled in the complex base band.

For further information refer to "CCDF – digital TV" on page 4.222.

Remote: CONF:DTV:MEAS CCDF

Remote: TRAC? TRACE1

Percent Marker

For details refer to the Percent Marker softkey in the power measurement menu of the base

unit.

TV Analyzer

Opens a submenu with all available measurements that can be applied to a set of channels or

all channels of the entire TV network (channel table). In these measurements, both analog and

digital TV channels can be measured together. This softkey is only available if a channel table is

selected.

Every measurement type provides its own submenu to set the parameters. For each

measurement, a channel table must be selected. The choice of no channel table <none > is not

permitted.

For further details refer also to section "Measurements" on page 4.204.

Tilt

Opens a submenu to measure the frequency response of the cable TV system. Each channel is

measured using the information stored in the modulation standard. Channels with the

modulation standard <unused > are not measured.

For further information refer to "Tilt – TV analyzer" on page 4.222.

Remote: CONF:TV:MEAS TILT

Remote: TRAC? TRACE1

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Tilt Setup

Opens the Tilt Setup dialog box to define a filter for the Tilt measurement. The following

parameters can be defined for the measurement:

Span full span or a limited frequency range

Modulation Standards channels with certain modulation standards (select one or

several) or no restriction (select all)

Remote: FREQ:SPAN:FULL,FREQ:STAR 20MHz,FREQ:STOP 2000MHz (Span)

Remote: TV:TILT:MST:CDIS 'Analog TV',TV:TILT:MST:CEN 'Analog TV' (Modulation

Standards)

Auto Range

Automatically adjusts the x– and y–axis once. Alternatively the range of the y–axis can be

changed via the Range Log softkey or the Range Linear softkey in the amplitude menu of the

base unit.

Remote: DISP:TRAC:Y:AUTO ON

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Noise Figure Measurements Option (K30)

The Noise Figure Measurements option provides noise figure measurements. Using this option, the

noise figure of a Device Under Test, e.g. low–noise FET amplifier circuits, with noise figures of less than

1dB can be measured. This option is available from firmware version 1.50.

To open the noise figure measurements menu

If the Noise mode is not the active measurement mode, press the MODE key and activate the

Noise option.

If the Noise mode is already active, press the MENU key or the MEAS key.

The noise figure measurements menu is displayed. .

Menu and softkey description

–"Softkeys of the noise figure measurements menu (Noise mode)" on page 4.252

–"Softkeys of the sweep menu (Noise mode)" on page 4.265

–"Softkeys of the trace menu (Noise mode)" on page 4.266

–"Softkeys of the marker menu (Noise mode)" on page 4.267

–"Softkeys of the marker–> menu (Noise mode)" on page 4.268

–"Softkeys of the lines menu (Noise mode)" on page 4.268

The span and trigger menus are not available in the Noise mode. All other menus are provided as

described for the base unit. For details refer to the corresponding menu descriptions.

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"Measurement modes of the noise figure measurement" on page 4.248

–"Calibration" on page 4.248

–"Measurement forms" on page 4.249

–"Measurement settings" on page 4.249

–"Result displays" on page 4.250

–"Status bar information" on page 4.252

Tasks

–To edit tables

–To work with limit lines

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To edit tables

1. Select the table header using the rotary knob or arrow keys and press rotary knob or the ENTER

key to enter into the edit mode.

2. Focus the field you want to edit using the arrow keys or the rotary knob.

3. Enter the values (for details refer to the Quick Start Guide, chapter 4, "Basic Operations").

4. To insert a new row above the currently selected row, press the Insert softkey.

5. To delete the currently selected row, press the Delete softkey.

6. Only available for the Frequency Table:

To update the table according to the Frequency Settings,press the Build Tbl softkey.

7. Press the Exit softkey to leave the edit mode.

To work with limit lines

1. Press the LINES key.

The Limit Lines dialog box is displayed. It contains information on name, limit, status, and a

comment.

2. To activate limit lines, select the limit line you want to activate and press the Enable/Disable

softkey.

3. To define a new limit line, press the New softkey and enter the limit line characteristics.

4. To modify a limit line, select the limit line you want to edit and press the Edit softkey.

5. To save a limit line, press the Exit softkey.

If data are missing or if some data are invalid, an error message is displayed.

6. To delete a limit line, select the limit line you want to edit and press the Delete softkey.

Further information

This section provides background information on measurements and displayed information.

Measurement modes of the noise figure measurement

Noise measurements are performed on many different types of device under test (DUT). The type of

DUT to be measured determines the test setup and also how the frequency list is to be generated. To

support these different types of DUT, two different noise figure measurement types are available:

•Direct measurement

•Frequency–converting measurement

–Fixed LO, IF = RF + LO

–Fixed LO, IF = abs(RF – LO)

The setup for the different measurement types is described with the Schematic softkey. The

measurement mode is set in the Frequency Settings dialog box, Mode field.

Calibration

The calibration measures the noise introduced to a signal by the spectrum analyzer itself to

compensate it in measurements on a device under test. This compensation is called 2nd stage

correction, because the spectrum analyzer is the second stage of the test setup, the DUT being the first

stage.

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If the second stage correction is activated (Measurement Settings dialog box, 2nd Stage Correction

option), a separate calibration measurement is performed before the main measurement (for details on

the measurement setup refer to chapter "Advanced Measurement Examples"). The data measured in

the calibration measurement are used for compensation in the main measurement.

It is strongly recommended to perform calibration before running measurements (Cal softkey). It is

possible to run measurements in an uncalibrated status, but the measurement results will not be

corrected for any noise introduced by the spectrum analyzer itself.

If the list of receive frequencies (RF) is changed, at which the measurements are performed, calibration

is necessary again to ensure that calibration data are available for every measurement step. For details

on frequency settings refer to the Freq Settings softkey.

Measurement forms

Two forms of measurements are possible:

•frequency list measurement

Ameasurement is performed at each of the frequencies listed in the frequency list (Freq Settings

softkey). The noise figure of the DUT across a user–specified range of frequencies is measured. In

single sweep mode, each frequency point is measured once and complete. In continuous sweep

mode, one frequency point after the other is measured in turn until the measurement is aborted.

•fixed frequency measurement

Acontinuous measurement is performed at the single frequency currently selected in the

Frequency List Results.This individual frequency from the frequency list measurement is

investigated in more detail, for example to see the effect of dynamic changes to the noise figure of

the DUT at a particular frequency (see also Fix Freq softkey).

Measurement settings

The overall measurement settings used to obtain the current measurement results are displayed below

the title bar (see Fig. 4-24). The following settings are listed:

Setting Defined in

RBW Measurement Settings dialog box, RBW field

Average Measurement Settings dialog box, Average field

RF Attenuation Measurement Settings dialog box, RF Attenuation field

Auto Ref Level Measurement Settings dialog box, Automatic Ref Level field

2nd Stage Corr Measurement Settings dialog box, 2nd Stage Correction field

Image Rej Frequency Settings dialog box, Image Rej field

Fig. 4-24 Measurement settings for the noise figure measurement (example)

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Result displays

The result displays consist of two panes:

•Current Value pane

In the title bar of this pane, the current measurement mode of the noise figure measurement (on the

left) and the calibration status of the noise figure measurement (on the right, if the second stage

correction is switched on) are displayed.

Below, the settings and measurement results for the currently selected measurement point in the

frequency list are displayed:

Parameter Description

RF Receive frequency at the DUT at which the current values were measured (Hz).

LO Local oscillator frequency (Hz), only displayed for frequency–converting measurements

IF Intermediate frequency (Hz), only displayed for frequency–converting measurements

ENR ENR value (dB), refers to the receive frequency (RF)

Loss In Loss at the input of the DUT (dB), refers to the receive frequency (RF)

Loss Out Loss at the output of the DUT (dB)

frequency–converting measurements: refers to the intermediate frequency (IF)

direct measurements: refers to the receive frequency (RF)

NF Noise figure measured (dB)

Noise Temp Noise temperature (K), derived from measured noise figure

Gain Gain measured (dB)

Fig. 4-25 Current Value pane (example)

•Frequency List Result or graph (frequency list results only)

The measurement results are represented according to the measurement form (see "Measurement

forms").

•frequency list results

The measurement results for all frequencies defined in the Frequency Table are displayed in form

of a graph (see Fig. Graphical result display (example)) or a table (Frequency List Results,see

Fig.Tabular result display (example)), depending on the currently selected result display (see

Display List/Graph softkey). The measurement results are updated as the measurement is in

progress. Under Current Value,the details of the currently selected frequency in the Frequency

List Results are displayed.

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Fig. 4-26 Graphical result display (example)

Fig. 4-27 Tabular result display (example)

•fixed frequency results

Under Current Value,the measurement results for the fixed frequency are displayed and

continuously updated. The Frequency List Results do not change – these are the results of the

last frequency list measurement.

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Status bar information

The status bar displays the following information:

•parameter values

If a parameter in a settings dialog box is selected, the minimum and maximum values for the

selected parameter are displayed.

If a Boolean or an enumarated parameter in a dialog box is selected, the minimum and maximum

values are displayed as N/A for not applicable.

•measurement status

During the measurement, the current measurement status along with detailed information about the

progress is displayed.

•error messages (with red background)

•warning messages (with yellow background)

Softkeys of the noise figure measurements menu (Noise mode)

The following table shows all softkeys available in the noise figure measurements menu. It is possible

that your instrument configuration does not provide all softkeys. If a softkey is only available with a

special option, model or (measurement) mode, this information is delivered in the corresponding softkey

description.

Command

Freq Settings

Display List/Graph

Display Settings

ENR Settings

Loss Settings

Meas Settings

Schematic

Table edit mode

Build Tbl

Exit

Insert

Delete

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Freq Settings

Opens the Frequency Settings dialog box. Alternatively, this dialog box is opened by pressing

the FREQ key (with focus on the Start Freq field).

The Frequency Settings dialog box contains the following elements:

Frequency Settings Start Freq

Stop Freq

Step Freq

Mode

Fixed LO

Image Rej

Frequency Table

Under Frequency Settings,the frequency settings and the measurement mode are set.

Under Frequency Table,the individual measurement steps are listed that will be performed

exactly in the order of the table. They are generated from the start frequency, the stop

frequency, and the step size on basis of the selected mode. If the start frequency is smaller than

the stop frequency, the RF values are generated into a list of ascending frequencies. If the start

frequency is larger, the list is descending. Not more than 100 measurement steps are possible.

If the gap between start and stop frequency is too large, increase the step frequency.

Depending on the measurement type, the Frequency Table contains the following columns:

Measurement type Column Description

Direct measurement

Frequency–converting measurement

RF receive frequency, generated from the Start Freq,the Stop

Freq,and the Step Freq field entries

Frequency–converting measurement LO constant LO frequency, defined via the Fixed LO field

IF IF frequency, calculated according to the Mode field

Image image frequency, shows whether image frequency filters are

required and for which frequency range the image rejection

of the DUT is needed (Image Rej field)

It is possible to customize the Frequency Table by editing, deleting, and inserting measurement

steps. This might be useful in order to insert extra measurement steps near to a specific

frequency of interest in order to get more detailed results. If the start, stop, or step frequency is

changed, the Frequency Table is generated afresh and all manual modifications are

overwritten. To customize this table, proceed according to "To edit tables" on page 4.248.

Remote: FREQ:LIST:DATA 550MHz,300MHz,900MHz (Frequency Table)

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Start Freq

Specifies the start frequency. This is the first receive frequency (RF) entry in the Frequency

Table and the Frequency List Results (result display).

If the start frequency is changed, the Frequency Table is updated accordingly.

Remote: FREQ:STAR 500MHZ

Stop Freq

Specifies the stop frequency. This is the last receive frequency (RF) entry in the Frequency

Table and the Frequency List Results (result display).

If the stop frequency is changed, the Frequency Table is updated accordingly.

Remote: FREQ:STOP 700MHZ

Step Freq

Specifies the step size between the single measurement steps. If the step frequency is larger

than the difference between the start frequency and the stop frequency, the Frequency Table

and the Frequency List Results (result display) just contain the start and stop frequency.

If the step frequency is changed, the Frequency Table is updated accordingly.

Remote: FREQ:STEP 10MHZ

Mode

Specifies the measurement mode. For details on modes refer to "Measurement modes of the

noise figure measurement" on page 4.248.

If the mode is changed, the Frequency Table is updated accordingly.

Remote: SENS:CONF:MODE:DUT DOWN

Fixed LO

Specifies the fixed local oscillator frequency. This field is only available if a frequency–converting

measurement mode is selected (Mode field). For details on modes refer to Measurement modes

of the noise figure measurement.

If the fixed LO is changed, the Frequency Table is updated accordingly.

Remote: SENS:CONF:MODE:SYST:LOSC:FREQ 1MHZ

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Image Rej

Specifies the suppression applied to the second sideband. This field is only available if a

frequency–converting measurement mode is selected. For details on modes refer to

"Measurement modes of the noise figure measurement" on page 4.248.

The value entered is applied across the complete frequency range. A value of 999.99 dB

corresponds to the generally used single–sideband measurement (SSB), where the second

sideband does not noticeably affect the measurement result. This is the default value. A value of

0dB corresponds to the double–sideband measurement (DSB), where both sidebands are

converted to the same extent.

Remote: CORR:IREJ 100

Display List/Graph

Configures the result display. The measurement results are displayed either in form of a list of

measurement points or as a graphical trace. For further details refer to "Result displays" on page

4.250.

Remote: DISP:TABL ON

Display Settings

Opens the Graphic dialog box to modify the graphical results display.

Under Results Settings,the settings that affect the overall results display are defined. Under

Noise Trace Settings,the settings related to the graphical display of noise results are defined.

Under Gain Trace Settings,the settings related to the graphical display of gain results are

defined.

The Graphic dialog box contains the following elements:

Results Settings Combined Trace Display

Noise Trace Settings Y–Axis

Automatic Scaling

Min Y–Axis NF

Min Y–Axis Temp

Max Y–Axis NF

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Max Y–Axis Temp

Symbols

Gain Trace Settings Y–Axis

Automatic Scaling

Min Y–Axis

Max Y–Axis

Symbols

Noise and Gain X–Axis Settings X–Axis

Combined Trace Display

Activates or deactivates the combined trace display of noise and gain results.

On The noise and gain traces are displayed in the same trace display in different colors.

Off The noise and gain traces are displayed in different trace displays.

Remote: DISP:FORM SING

Y–Axis

Specifies the type of noise result that is to be displayed graphically:

–Noise Figure

–Noise Temperature

–Off (no noise results are displayed graphically)

Remote: DISP:DATA:TRAC1 NFIG|TEFF

Remote: DISP:TRAC OFF

Automatic Scaling

Activates or deactivates the automatic scaling of the Y–axis.

On The y–axis is scaled automatically. The automatic scaling algorithm provides the

optimal display of the complete range of results.

Off The automatic scaling of the y–axis is switched off, and the scale has to be specified

manually:

for noise results via the Min Y–Axis NF/Min Y–Axis Temp/Max Y–Axis NF/Max Y–

Axis Temp fields,

for gain results via the Min Y–Axis/Max Y–Axis fields.

Remote: DISP:TRAC:Y:AUTO ON

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Min Y–Axis NF/Max Y–Axis NF

Specifies the minimum/maximum noise figure result that can be displayed graphically. It is only

possible to enter a value, if the automatic scaling is deactivated (see Automatic Scaling

option), and the y–axis is set to Noise Figure (see Y–Axis field).

Remote: DISP:TRAC:Y:BOTT –30

Remote: DISP:TRAC:Y:TOP 30

Min Y–Axis Temp/Max Y–Axis Temp

Specifies the minimum/maximum noise temperature result that can be displayed graphically. It is

only possible to enter a value, if the automatic scaling is deactivated (see Automatic Scaling

option), and the y–axis is set to Noise Figure (see Y–Axis field).

Remote: DISP:TRAC:Y:BOTT –30

Remote: DISP:TRAC:Y:TOP 30

Symbols

Activates or deactivates the symbol representation. If activated, each measured value is marked

by a symbol. This helps to distinguish result types in a monochrome printout.

Remote: DISP:TRAC:SYMB ON

Y–Axis

Activates or deactivates the graphical display of gain results.

Remote: DISP:TRAC2 OFF

Min Y–Axis/Max Y–Axis

Specifies the minimum/maximum gain result that can be displayed graphically. It is only possible

to enter a value, if the automatic scaling is deactivated (see Automatic Scaling option), and the

y–axis is activated (see Y–Axis field).

Remote: DISP:TRAC2:Y:BOTT 1

Remote: DISP:TRAC2:Y:TOP 10

X–Axis

Specifies the scaling of the x–axis. This parameter is only editable in a frequency–converting

measurement mode.

Remote: DISP:TRAC:X IF

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ENR Settings

Opens the ENR dialog box.

The abbreviation ENR stands for excess noise ratio. Correct ENR values for the noise source

are essential to perform accurate measurements. They are used to calculate the effective noise

temperature of the noise source that in turn is used for calculation of measurement results.

Under ENR Settings,the default ENR value is 15 dB as a constant value that is valid for all

frequencies.

Under ENR Table,the frequency–dependent ENR values are listed. The list can contain up to

100 RF/ENR pairs. The order of the RF values in the list is not important. To modify this table,

proceed as described in "To edit tables" on page 4.248. ENR tables can be saved and recalled at

any time via the FILE key (for details refer to the section "Saving and Recalling Settings Files –

FILE Key"). Additionally to the data saved by the basic unit, all data entered in the ENR Settings

dialog box are saved.

The ENR Settings dialog box contains the following elements:

ENR Settings Selection

ENR Constant

Room Temperature

ENR Table

Remote: CORR:ENR:MEAS:TABL:DATA 1MHZ,10,2MHZ,12 (ENR Table)

Selection

Defines the used ENR values.

Constant The value specified in the ENR Constant field is used for all frequencies. The

entries of the ENR Table are ignored.

Table The entries of the ENR Table provide the basis for the ENR values. Between

these values the R&S FSL uses interpolated values.

Remote: CORR:ENR:MODE SPOT

ENR Constant

Specifies the constant ENR value of the noise source that is used throughout the entire

frequency range. This parameter is only editable if, in the Selection list, Constant is selected.

Remote: CORR:ENR:SPOT 30

Room Temperature

Specifies the current room temperature as an absolute value in Kelvin. This value is used in the

calculation of the noise results.

Remote: CORR:TEMP 291.50

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Loss Settings

Opens the LOSS dialog box to take additional losses due to cables or attenuators into account

that are not considered in the calibration.

Under Loss Input Settings,the additional loss between the noise source and the DUT is

defined. Under Loss Output Settings,the additional loss between the DUT and the analyzer is

defined.

Under Loss Input Table or Loss Output Table,the list can contain up to 100 RF/ENR pairs.

The order of the RF values in the list is not important. To modify this table, proceed as described

in "To edit tables" on page 4.248.Loss tables can be saved and recalled at any time via the FILE

key (for details refer to the section "Saving and Recalling Settings Files – FILE Key").

Additionally to the data saved by the basic unit, all loss input & output data entered in the Loss

Settings dialog box are saved.

The Loss Settings dialog box contains the following elements:

Loss Input Settings Selection

Loss Input Constant

Loss Input Table

Loss Output Settings Selection

Loss Output Constant

Loss Output Table

Remote: CORR:LOSS:INP:TABL 1MHz,10,2MHz,12 (Loss Input Table)

Remote: CORR:LOSS:OUTP:TABL 1MHz,10,2MHz,12 (Loss Output Table)

Selection

Defines the used Loss values.

Constant The values specified in the Loss Input Constant/Loss Output Constant fields

are used for all frequencies. The entries of the Loss Input/Output Table are

ignored.

Table The entries of the Loss Input/Output Table provide the basis for the Loss

values. Between these values the R&S FSL uses interpolated values.

Remote: CORR:LOSS:INP:MODE SPOT

Remote: CORR:LOSS:OUTP:MODE SPOT

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Loss Input Constant/Loss Output Constant

Specifies the constant loss value that is used across the entire frequency range. This parameter

is only editable if, in the Selection list, Constant is selected.

Remote: CORR:LOSS:INP:SPOT 10

Remote: CORR:LOSS:OUTP:SPOT 10

Meas Settings

Opens the Measurement Settings dialog box to modify all settings related to the overall

measurement.

Alternatively, the Measurement Settings dialog box is opened as follows:

–AMPT key, with focus on the RF Attenuation field

–BW key, with focus on the RBW field

Under Calibration,the second stage correction can be activated or deactivated. For details

refer also to "Calibration" on page 4.248.

Under Analyzer Settings,the general settings for the spectrum analyzer concerning the level,

attenuation and bandwidth of the signal to be measured are defined.

The Measurement Settings dialog box contains the following elements:

Calibration 2nd Stage Correction

Analyzer Settings RBW

Sweep Time

Settling Time

Average

RF Attenuation

Automatic Ref Level

Ref Level

Range

Preamplifier

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2nd Stage Correction

Activates or deactivates the second stage correction.

On The calibration data recorded via the Cal softkey are used to correct the measurement

results. The calibration data are stored independent of the state of the option.

Off No correction is applied to the measurement results.

For details refer also to "Calibration" on page 4.248.

Remote: CORR ON

RBW

Specifies the resolution bandwidth for the measurement.

Alarge value improves the averaging of the display considerably, reduces the influence of

external sources of interference, and permits the fastest measurement time possible.

Alow value should only be used across a very small frequency range. For measurements at low

frequencies, the RBW must be reduced to prevent the LO frequency of the analyzer from

invalidating the measurement. At receive frequencies of 100 kHz, the RBW must not exceed 10

kHz.

Remote: BAND 1MHz

Sweep Time

Specifies the time one complete measurement sweep takes. Two sweeps are performed for

each measurement step (once with noise source on, once with noise source off).

For narrow bandwidths, the sweep time should be increased in order to give accurate

measurement results.

Remote: SWE:TIME 10s

Settling Time

Specifies the time the DUT takes to settle after a noise source has been turned on or off.

Most noise sources generate an interfering DC component in addition to the noise spectrum. If

the noise source is switched on or off, low–frequency DUTs may require this settling time for

coupling capacitors to be charged or discharged.

Remote: SYST:CONF:DUT:STIM 1000MS

Average

Specifies the number of measurement sweeps over which the average is taken to produce the

displayed measurement results.

The higher the number of sweeps, the more accurate the measurement results, but the

measurement time is significantly longer.

An average value of 1 means that each displayed result is produced from one measurement

sweep. This is sufficient for most cases.

Remote: SWE:COUN 10

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RF Attenuation

Specifies the attenuation that is applied to the received RF signal.

To obtain a low noise figure for the analyzer and hence more accurate noise measurements,

0dB should be set. For high DUT power levels or critical matching, a higher setting is also

possible. A setting of 10 dB will give a much better VSWR (voltage standing wave ratio) of the

analyzer, but will result in a worse noise figure of the analyzer.

Remote: INP:ATT 30 DB

Automatic Ref Level

Activates or deactivates the automatic reference level setting.

Off Specify a reference level manually (see Ref Level softkey).

On The reference level is measured automatically. The total measurement time increases.

The automatic reference level measurement is performed as follows:

–2nd stage correction activated:

At the beginning of the calibration measurement, several measurements are performed at the

first frequency test point and the reference level is calculated from these results taking into

account the maximum gain of the DUT (see Range softkey).

–2nd stage correction deactivated:

At the beginning of the main measurement, several measurements are performed at the first

frequency test point and the reference level is calculated from these results. The range setting

is not significant.

Remote: DISP:TRAC:Y:RLEV:AUTO ON

Ref Level

Specifies the reference level. It is only possible to enter a reference level manually, if the

automatic reference level is deactivated (see Automatic Ref Level softkey).

The reference level should be about 5 to 15 dB above the noise display that occurs with the

DUT connected and the noise source activated.

Even for DUTs with a high–ripple frequency response it can be useful to enter the reference

level manually, because an automatic reference level setting may not always result in optimal

settings.

Remote: DISP:TRAC:Y:RLEV 0

Range

Specifies the maximum gain expected from the DUT.

If the 2nd Stage Correction is activated, this value is used to calculate the automatic reference

level to ensure that the expected power of the measured signal will be within the optimum

operating range of the spectrum analyzer (see Automatic Ref Level softkey).

To ensure accurate measurement results, the range should not exceed the actual gain of the

DUT by more than a margin of 10 dB.

Remote: SYST:CONF:DUT:GAIN 10

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Preamplifier

Activates or deactivates the preamplifier of the R&S FSL.

Remote: INP:GAIN:STAT ON

Schematic

Displays the schematic diagram of the test setup for the selected measurement type and the

specified frequency ranges. If the frequency ranges are changed, the schematic diagram is

updated accordingly.

– Direct measurement

The direct measurement mode is designed for DUTs without frequency–conversion, e.g.

amplifiers.

The schematic display for the direct measurement mode is shown in Fig. 4-28. The upper part

of the figure shows the setup for calibration. The lower part of the figure shows the test setup

for the measurement.

Fig. 4-28 Schematic diagram for direct measurements

–Frequency–converting measurement

The frequency–converting measurement mode is designed for frequency–converting DUTs that

have a fixed Local Oscillator (LO) frequency, for example, satellite converters with a fixed LO

frequency. .

The schematic display for the frequency–converting measurement mode is shown in Fig. 4-29.

The upper part of the figure shows the setup for calibration. The lower part of the figure shows

the test setup for the measurement.

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Fig. 4-29 Schematic diagram for frequency converting measurements

Build Tbl

Updates the table according to the Frequency Settings (Freq Settings softkey).

Exit

Exits the edit mode of a table.

Insert

Inserts a row above the currently selected row and sets the focus on the first field of the new

row.

This softkey is only available if the Frequency Table contains less than 100 measurement

steps.

Delete

Deletes the currently selected row. This action requires no confirmation.

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Softkeys of the sweep menu (Noise mode)

The following table shows all softkeys available in the sweep menu in Noise mode (SWEEP key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Sweep Single/Cont

Cal

Fix Freq

Sweep Single/Cont

Selects the sweep mode.

Single single sweep mode

Cont continuous sweep mode

If a measurement is started while another measurement is in progress, the first measurement

will be aborted and the new measurement started immediately.

For further details refer to "Measurement forms" on page 4.249.

Remote: CONF:LIST:CONT

Remote: CONF:LIST:SING

Cal

Performs a calibration. The calibration status of the noise figure measurement is displayed in the

title bar. For further details refer to "Calibration" on page 4.248.

This softkey is only available, if the 2nd Stage Correction option in the Measurement Settings

dialog box is activated.

Remote: CONF:CORR

Fix Freq

Starts a fixed frequency measurement for the frequency that is currently selected in the

Frequency List Results.For further details refer to "Measurement forms" on page 4.249 and

"Result displays" on page 4.250.

This softkey is only available after a frequency list measurement has been completed and the

measurement results are displayed in list form (Display List/Graph softkey).

Remote: CONF:SING

Remote: FREQ 10MHz

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Softkeys of the trace menu (Noise mode)

Using the trace memory facility, you can save graphical display results (max. 3 trace sets) for

comparison with subsequent measurements. This facility is recommended in order to compare and to

document the effects of small changes on the DUT.

The following table shows all softkeys available in the trace menu in Noise mode (TRACE key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Display Graph/List

ASCII File Export

Decim Sep

More 

Data –> Mem1

Data –> Mem2

Data –> Mem3

Data On/Off

Mem1 On/Off

Mem2 On/Off

Mem3 On/Off

Display Graph/List

For details refer to the Display List/Graph softkey in the noise figure measurements menu.

ASCII File Export

For details refer to the ASCII File Export softkey in the trace menu of the base unit.

Decim Sep

For details refer to the Decim Sep softkey in the trace menu of the base unit.

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Data –> Mem1/Data –> Mem2/Data –> Mem3

Saves the current trace results to trace memory <n>. If a trace memory <n> contains data, the

corresponding softkey has a green background. The content of the trace memory <n> is

displayed via the Mem1 On/Off/Mem2 On/Off/Mem3 On/Off softkeys.

If data is transferred to a trace memory that already contains trace data, the new trace data

overwrite the current trace data in the memory.

Remote: CONF:ARR:MEM2 ONCE

Remote: FETC:ARR:MEM2:NOIS:FIG?

Remote: FETC:ARR:MEM2:NOIS:GAIN?

Remote: FETC:ARR:MEM2:NOIS:TEMP?

Data On/Off

Switches the display of the current measurement results on or off. The display of trace memory

results is not affected if this softkey is pressed. If a new frequency list measurement is started,

the display of the current result trace is switched on automatically.

Remote: DISP:CURR:DATA OFF

Mem1 On/Off / Mem2 On/Off / Mem3 On/Off

Switches the display of trace memory <n> on or off. This softkey is not available if no data is

held in the selected trace memory.

Remote: DISP:ARR:MEM2 ON

Softkeys of the marker menu (Noise mode)

The following table shows all softkeys available in the marker menu in Noise mode (MKR key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Marker 1

Marker to Trace

All Marker Off

Marker 1

Activates marker 1 and opens an edit dialog box to enter a value for marker 1 to be set to.

Pressing the softkey again deactivates the marker 1. This softkey is only available if

measurement results are displayed.

This softkey is available from firmware version 1.60.

Remote: CALC:MARK ON

Remote: CALC:MARK:X 550 MHZ

Remote: CALC:MARK:Y?

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Marker to Trace

Opens a dialog box to select the trace (noise figure or gain), on which the marker is to be

placed. This softkey is only available if measurement results are displayed.

This softkey is available from firmware version 1.60.

Remote: CALC:MARK:TRAC GAIN

All Marker Off

Switches off the active marker. This softkey is only available if measurement results are

displayed.

This softkey is available from firmware version 1.60.

Remote: CALC:MARK:AOFF

Softkeys of the marker–> menu (Noise mode)

The following table shows all softkeys available in the marker–> menu in Noise mode (MKR–> key). It

is possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Peak

Min

Peak

Activates marker 1 and sets it to the highest maximum of the trace.

This softkey is available from firmware version 1.60.

Remote: CALC:MARK:MAX

Min

Activates marker 1 and sets it to the minimum of the selected trace.

This softkey is available from firmware version 1.60.

Remote: CALC:MARK:MIN

Softkeys of the lines menu (Noise mode)

The following table shows all softkeys available in the lines menu in Noise mode (LINES key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Menu / Command Command

New Exit

Insert

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Menu / Command Command

Delete

Edit same contents as

New menu

Enable/Disable

Delete

New

Displays the Limit Line dialog box in edit mode with all fields necessary to define a new limit

line. For further details see "To work with limit lines" on page 4.248.

In the edit mode, the Limit Line dialog box contains the following elements:

Name

Limit

Comment

Frequency

Limit

Name

Specifies the name of the limit line to uniquely identify every limit line. Any combination of

alphanumeric characters is allowed. If the entered name already exists, an error message is

displayed with the request to alter the name.

Remote: CALC:LIM1:NAME FM1

Limit

Specifies the result type (noise or gain) and the limit type (upper or lower) for the limit line.

Remote: CALC:LIM2:TRAC NFIG

Comment

Specifies a description for the limit line. Any combination of alphanumeric characters is allowed.

Remote: CALC:LIM5:COMM 'Upper limit for spectrum'

Frequency

Specifies the receive frequencies.

Remote: CALC:LIM2:CONT 1MHz,30MHz,100MHz,300MHz,1GHz

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Limit

Specifies the limits for the receive frequencies.

Remote: CALC:LIM2:LOW –30,–40,–10,–40,–30 (lower limit line)

Remote: CALC:LIM2:UPP –10,0,0,–10,–5 (upper limit line)

Exit

Exits the edit mode of a table.

Insert

Inserts a row above the currently selected row and sets the focus on the first field of the new

row.

Delete

Deletes the currently selected row. This action requires no confirmation.

Edit

Displays the Limit Line dialog box in edit mode with all data of the selected limit line. For further

details refer to the New softkey.

Enable/Disable

Enables or disables the selected limit line. Limit checking is only performed for activated limit

lines. Only one limit line of each type can be active at a given time.

Remote: CALC:LIM:STAT ON

Remote: CALC:LIM4:LOW:STAT ON

Remote: CALC:LIM4:UPP:STAT ON

Delete

Deletes the selected limit line.

Remote: CALC:LIM1:DEL

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3GPP Base Station Measurements (Option K72)

The R&S FSL equipped with the 3GPP Base Station Measurements option performs code domain

power measurements on downlink signals according to the 3GPP standard (Third Generation

Partnership Project, FDD mode). Signals that meet the conditions for channel configuration of 3GPP

standard test models 1 to 5 can be measured, including HSDPA and HSUPA signals (test model 5). In

addition to the code domain power measurements specified by the 3GPP standard, the 3GPP Base

Station Measurements option offers measurements with predefined settings in the frequency domain,

e.g. power measurements.

This option is available from firmware version 1.60.

To open the settings menu

If the 3G FDD BTS mode is not the active measurement mode, press the MODE key and activate

the 3G FDD BTS option.

If the 3G FDD BTS mode is already active, press the MENU key.

The settings menu is displayed. .

Menu and softkey description

–"Softkeys of the settings menu (3G FDD BTS mode)" on page 4.275

–"Softkeys of the frequency menu (3G FDD BTS mode)" on page 4.279

–"Softkeys of the amplitude menu (3G FDD BTS mode)" on page 4.280

–"Softkeys of the trigger menu (3G FDD BTS mode)" on page 4.281

–"Softkeys of the marker menu (3G FDD BTS mode)" on page 4.281

–"Softkeys of the marker–> menu (3G FDD BTS mode)" on page 4.282

–"Softkeys of the measurement menu (3G FDD BTS mode)" on page 4.283

The span, bandwidth, and lines menus are not available in the 3G FDD BTS mode. All other menus are

provided as described for the base unit. For details refer to the corresponding menu descriptions.

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information

–"Short list of abbreviations" on page 4.273

–"Channels of the Code Domain Channel Table and their usage" on page 4.273

–"Marker values" on page 4.274

Measurements and result displays

The 3GPP Base Station Measurements option provides the following test measurement types and

result displays:

•code domain power measurements

–Code Domain Power Diagram (see Code Dom Power Diagram softkey)

–Code Domain Channel Table (see Code Dom Channel Table softkey)

–Code Domain Result Summary (see Code Dom Result Summary softkey)

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The code domain power measurements are performed as specified by the 3GPP standards. A

signal section of approx. 20 ms is recorded for analysis and then searched through to find the start

of a 3GPP FDD frame. If a frame start is found in the signal, the code domain power analysis is

performed for a complete frame starting from slot 0. The different result displays are calculated from

the recorded IQ data set. Therefore it is not necessary to start a new measurement in order to

change the result display. Common settings for these measurements are performed via the settings

menu (MENU key). For details refer to "Softkeys of the settings menu (3G FDD BTS mode)" on

page 4.275.

The measurement settings are listed below the title bar:

Parameter in example Description

CF 3.0 GHz center frequency

Result Summary Code Domain Result Summary result display

Att 0 dB attenuation

Ref –20.0 dBm reference level

Channel 0.256 channel number and spreading code

CPICH Slot 0 common pilot channel slot number

Chan Slot 0 channel slot number

•RF measurements

–Signal Channel Power (see Power softkey)

–Adjacent–Channel Power (see ACP softkey)

–Spectrum Emission Mask (see Spectrum Emission Mask softkey)

All these measurements are accessed via the MEAS key (measurement menu). Some parameters are

set automatically according to the 3GPP standard. A list of these parameters is given with each

measurement type. A set of parameters is passed on from the 3GPP Base Station Measurements

option to the base unit and vice versa in order to provide a quick swap (see the following table).

Transferred parameters

center frequency

reference level

attenuation

reference level offset

center frequency step size

trigger source

trigger offset

For a detailed description refer also to chapter "Advanced Measurement Examples".

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Short list of abbreviations

Term or abbreviation Description

BTS base transmission station

CPICH common pilot channel

DPCH dedicated physical channel, data channel

FDD frequency division duplexing

PCCPCH primary common control physical channel

PICH paging indication channel.

SCH synchronization channel, divided into P–SCH (primary synchronization channel) and

S–SCH (secondary synchronization channel)

Channels of the Code Domain Channel Table and their usage

The channel assignment table contains the following (data) channels:

•CPICH

The common pilot channel is used to synchronize the signal in the case of CPICH synchronization.

It is expected at code class 8 and code number 0.

•PSCH

The primary synchronization channel is used to synchronize the signal in the case of SCH

synchronization. It is a non–orthogonal channel. Only the power of this channel is determined.

•SSCH

The secondary synchronization channel is a non–orthogonal channel. Only the power of this

channel is determined.

•PCCPCH

The primary common control physical channel is used to synchronize the signal in the case of SCH

synchronization. It is expected at code class 8 and code number 1.

•SCCPCH

The secondary common control physical channel is a QPSK–modulated channel without any pilot

symbols. In the 3GPP test models, this channel can be found in code class 8 and code number 3.

However, the code class and code number need not to be fixed and can vary. For this reason, the

following rules are used to indicate SCCPCH.

HSDPA/HSUPA On/Off softkey set to Off

–Only one QPSK–modulated channel without pilot symbols is detected and displayed as the

SCCPCH. Any further QPSK–modulated channels without pilot symbols are not detected as

active channels.

–If the signal contains more than one channel without pilot symbols, the channel that is received

in the highest code class and with the lowest code number is displayed as the SCCPCH. It is

expected that only one channel of this type is included in the received signal. According to this

assumption, this channel is probably the SCCPCH.

HSDPA/HSUPA On/Off softkey set to On

–All QPSK–modulated channels without pilot symbols are detected. If one of these channels is

received at code class 8 and code number 3, it is displayed as the SCCPCH. QPSK–modulated

channels without pilot symbols and a code class higher than or equal to 7 are marked with the

channel type CHAN. QPSK–modulated channels without pilot symbols and a code class lower

than 7 are marked with channel type HSPDSCH.

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•PICH

The paging indication channel is expected at code class 8 and code number 16.

•DPCH

The dedicated physical channel is a data channel that contains pilot symbols. The displayed

channel type is DPCH. The status is inactive (channel is not active), active (channel is active and

all pilot symbols are correct), or pilotf (channel is active but it contains incorrect pilot symbols).

•HS–PDSCH (HSDPA)

The high speed physical downlink shared channel does not contain any pilot symbols. It is a

channel type that is expected in code classes equal to or higher than 7: HSPDSCH(QPSK)_

(QPSK–modulated slot of an HS–PDSCH channel), HSPDSCH(16QAM)_ (16QAM–modulated slot

of an HS–PDSCH channel), HSPDSCH(NONE)_ (slot without power of an HS–PDSCH channel).

The modulation type of these channels can be varied depending on the selected slot. The status is

inactive (channel is not active) or active (channel is active and all pilot symbols are correct).

•HS–SSCH (HSDPA)

The high speed shared control channel does not contain any pilot symbols. It is a channel type that

is expected in code classes equal to or higher than 7. The modulation type should always be

QPSK. The channel does not contain any pilot symbols. The status is inactive (channel is not

active) or active (channel is active and all pilot symbols are correct).

•CHAN

Any arbitrary channel that does not carry a valid pilot symbol sequence is displayed as an arbitrary

channel. It is not possible to decide which channel type is transmitted. The only prerequisite is that

the channel carries symbols of a sufficient signal to noise ratio.

–Chan Type: CHAN (QPSK–modulated channel without any pilot symbols)

–Status: inactive if the channel is not active; active if the channel is active

•E–HICH

Enhanced HARQ hybrid acknowledgement indicator channel

Carries hybrid ARQ ACK/NACK

•E–RGCH

Enhanced relative grant channel

Carries relative grant allocation for a UE

•E–AGCH

Enhanced absolute grant channel

Carries absolute grant allocation for a UE

Marker values

Additional to the marker values of the base unit, displayed in the marker field (for details see "Using

Markers and Delta Markers – MKR Key" on page 4.53), the symbol rate of the channel (for unassigned

codes 7.5 ksps, see example) is given.

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Softkeys of the settings menu (3G FDD BTS mode)

The following table shows all softkeys available in the main menu of the 3GPP Base Station

Measurements option (MENU key). It is possible that your instrument configuration does not provide all

softkeys. If a softkey is only available with a special option, model or (measurement) mode, this

information is delivered in the corresponding softkey description.

Menu / Command Command

Select Channel

Select CPICH Slot

Code Power Abs/Rel

Power Ref TOT/CPICH

Scrambling Code Scrambling Code

Scrambling Code Autosearch

Show List

Format Hex/Dec

Adjust Ref Level

More 

Invert Q On/Off

Normalize On/Off

Antenna Diversity On/Off

Antenna Number 1/2

Inactive Channel Threshold

HSDPA/HSUPA On/Off

Sync Type CPICH/SCH

Select Channel

Opens an edit dialog box to enter the channel number and spreading factor, separated by a

decimal point. The chosen channel is marked red in the Code Domain Power Diagram and this

channel is used for channel–based evaluations in the Code Domain Result Summary.

Example:

entry 5.128

Channel 5 is marked at spreading factor 128 (30 ksps), if the channel is active; otherwise code

20 at spreading factor 512 is selected.

Remote: CDP:CODE 30

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Select CPICH Slot

Opens an edit dialog box to enter the slot number. The chosen slot is evaluated in the Code

Domain Power Diagram and is used for slot–based evaluations in the Code Domain Result

Summary.

The slot number is defined on the basis of the CPICH (i.e. calculated in steps of 2560 chips

starting from the beginning of the frame). The desired slot of the selected channel is converted

according to its timing offset.

Example:

Slot 0 of the CPICH is set. The selected channel has a timing offset of 2816 chips, i.e. slot 0 of

the channel is delayed by 2816 chips with respect to the frame start. Slot 0 of the CPICH

therefore corresponds to slot 14 of the last frame of the channel.

Remote: CDP:SLOT 3

Code Power Abs/Rel (Code Domain Power Diagram)

Sets the scaling of the result display.

Abs absolute power in dB

Rel power relative to the reference chosen via the Power Ref TOT/CPICH softkey in

dBm (default setting)

Remote: CALC:FEED 'XPOW:CDP'

Power Ref TOT/CPICH (Code Domain Power Diagram)

Sets the power reference for the relative power displays (see also Code Power Abs/Rel

softkey):

TOT total power

CPICH power of the common pilot channel (default setting)

In contrast to the variable total power, the power of the CPICH is the same

in all slots so that it can form the constant reference for the display.

Remote: CDP:PREF TOT

Scrambling Code

Opens the scrambling code menu.

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Scrambling Code

Opens an edit dialog box to enter the scrambling code. The scrambling codes are used to

distinguish between different base stations. Each base station has its own scrambling code. The

scrambling code range in hexadecimal format is [0x0 … 0x5FFF]

The scrambling codes are divided into 512 sets, each consisting of a primary scrambling code

and 15 secondary scrambling codes.

The range of the primary scrambling codes is described by n=16*i

with k=0, i



[0 ... 511] = [0 ... 1FF].

The range of the secondary scrambling codes is described by j=16*i+k,

with k



[1 ... 15] = [1 ... F].

Example:

To enter the primary scrambling code number '1', the digits '10' need to be entered. (i = 1, k = 0).

The entered scrambling code has to coincide with that of the signal. Otherwise, a code domain

power measurement of the signal is not possible.

Remote: CDP:LCOD #H2

Scrambling Code Autosearch

Searches automatically the scrambling code that leads to the highest signal power and stores it

as new scrambling code for further measurements. All scrambling codes of the recorded signal

are taken into account. As a prerequisite, the center frequency and level settings have to be

correct.

The scrambling code search automatically determines the primary scrambling code number. The

secondary scrambling code number is expected to be 0. Other scrambling codes can not be

detected. Therefore, the range for detection is 0x0000 –0x1FF0h, where the last digit is always

Remote: CDP:LCOD:SEAR

Show List

Displays a result list of the automatic search sequence containing the highest power values

calculated and the corresponding scrambling codes. The power shown is a coarse value for the

CPICH power.

This softkey is only available after a scrambling code auto search has been performed (see

Scrambling Code Autosearch softkey).

Remote: CDP:LCOD:SEAR:LIST?

Format Hex/Dec

Selects the display format of the scrambling codes:

Hex hexadecimal

Dec decimal

The default setting is hexadecimal.

Remote: CDP:LCOD #H2

Remote: CDP:LCOD:DVAL 3

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Adjust Ref Level

Adjusts the reference level to the measured channel power. This ensures that the settings of the

RF attenuation and the reference level are optimally adjusted to the signal level without

overloading the R&S FSL or limiting the dynamic range by an S/N ratio that is too small.

Remote: CDP:LEV:ADJ

Invert Q On/Off

Switches the Q inversion on or off:

ON The sign of the Q–component of the signal is inverted.

OFF The sign of the Q–component of the signal remains unchanged (default setting).

Remote: CDP:QINV ON

Normalize On/Off

Activates and deactivates the elimination of the I/Q offset.

Remote: CDP:NORM ON

Antenna Diversity On/Off

Activates or deactivates the antenna diversity mode for the code domain power analysis. The

default setting of this softkey is OFF.The diversity antennas are selected via the Antenna

Number 1/2 softkey.

Remote: CDP:ANT 1

Antenna Number 1/2

Switches between antenna set 1 or 2. The default setting of this softkey is 1.This softkey is only

available if the Antenna Diversity On/Off softkey is activated.

Remote: CDP:ANT 1

Inactive Channel Threshold

Opens an edit dialog box to set the minimum power theshold for a single channel (channel

power compared to total signal power). Only channels with a signal power above this value are

recognized as active channels. Channels with a signal power below this value are considered to

be not active (irrespective of whether they contain pilot symbols or not).

The default value is –60 dB.

Remote: CDP:ICTR –10dB

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HSDPA/HSUPA On/Off

Activates or deactivates the HSUPA/DPA channel detection and the display of the HSUPA/DPA

channels in the channel table.

ON The high speed channels can be detected (default settings).

The modulation type (QPSK /16QAM) is detected.

OFF The high speed channel can not be detected.

Pilot symbols are detected.

Remote: CDP:HSDP OFF

Sync Type CPICH/SCH

Defines the synchronization. The default setting of this softkey is CPICH.

CPICH Asynchronization to the CPICH control channel is performed. As a prerequisite,

the CPICH control channel must be present in the signal.

SCH Asynchronization without assuming the presence of a CPICH channel is

performed.

While this setting can also be used with other channel configurations, but the

probability of synchronization failure increases with the number of data channels.

Remote: CDP:STYP SCH

Softkeys of the frequency menu (3G FDD BTS mode)

The following table shows all softkeys available in the frequency menu in 3G FDD BTS mode. It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Center

Stepsize Manual

Frequency Offset

Center

For details refer to the Center softkey in the frequency menu of the base unit.

Stepsize Manual

For details refer to the Manual softkey in the frequency menu of the base unit.

Frequency Offset

For details refer to the Frequency Offset softkey in the frequency menu of the base unit.

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Softkeys of the amplitude menu (3G FDD BTS mode)

The following table shows all softkeys available in the amplitude menu in 3G FDD BTS mode. It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Ref Level

Adjust Ref Level

Ref Level Offset

dB per Division

Reference Position

RF Atten Manual

RF Atten Auto

Ref Level

For details refer to the Ref Level softkey in the amplitude menu of the base unit.

Adjust Ref Level

For details refer to the Adjust Ref Level softkey in the settings menu.

Ref Level Offset

For details refer to the Ref Level Offset softkey in the amplitude menu of the base unit.

dB per Division

Opens an edit dialog box to set the scaling of the y–axis in dB.

Remote: DISP:TRAC:Y:PDIV +10dB

Reference Position

For details refer to the Ref Level Position softkey in the amplitude menu of the base unit.

RF Atten Manual

For details refer to the RF Atten Manual softkey in the amplitude menu of the base unit.

RF Atten Auto

For details refer to the RF Atten Auto softkey in the amplitude menu of the base unit.

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Softkeys of the trigger menu (3G FDD BTS mode)

The following table shows all softkeys available in the trigger menu in 3G FDD BTS mode. It is possible

that your instrument configuration does not provide all softkeys. If a softkey is only available with a

special option, model or (measurement) mode, this information is delivered in the corresponding softkey

description.

Command

Trigger Source

Trigger Polarity Pos/Neg

Trigger Offset

Trigger Source

Opens the Trigger Source dialog box. In the 3GPP Base Station Measurements option, only

the following trigger sources are available:

–Free Run,External,IF Power

For further details refer to the Trg / Gate Source softkey in the trigger menu of the base unit.

Trigger Polarity Pos/Neg

For details refer to the Trg / Gate Polarity Pos/Neg softkey in the trigger menu of the base unit.

Trigger Offset

For details refer to the Trigger Offset softkey in the trigger menu of the base unit.

Softkeys of the marker menu (3G FDD BTS mode)

The following table shows all softkeys available in the marker menu in 3G FDD BTS mode. It is possible

that your instrument configuration does not provide all softkeys. If a softkey is only available with a

special option, model or (measurement) mode, this information is delivered in the corresponding softkey

description.

Command

Marker 1

Marker 2

Marker 3

Marker 4

Marker Norm/Delta

Marker Zoom

All Marker Off

Marker 1/Marker 2/Marker 3/Marker 4/Marker Norm/Delta

For details refer to the Marker 1,Marker 2,Marker 3,Marker 4,Marker Norm/Delta softkeys in

the trigger menu of the base unit.

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Marker Zoom

Opens an edit dialog box to set the number of channels.

All Marker Off

For details refer to the All Marker Off softkey in the trigger menu of the base unit.

Softkeys of the marker–> menu (3G FDD BTS mode)

The following table shows all softkeys available in the marker–> menu in 3G FDD BTS mode. It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Select 1 2 3 4



Peak

Next Peak

Next Peak Mode < abs >

CPICH

PCCPCH

More 

Select 1 2 3 4



Min

Next Min

Next Min Mode < abs >

CPICH

PCCPCH

Select 1 2 3 4



For further details refer to the Select 1 2 3 4



softkey in the marker–> menu of the base unit.

Peak

For further details refer to the Peak softkey in the marker–> menu of the base unit.

Next Peak

For further details refer to the Next Peak softkey in the marker–> menu of the base unit.

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Next Peak Mode < abs >

For further details refer to the Next Peak Mode < abs > softkey in the marker–> menu of the

base unit.

CPICH

Sets the active marker/delta marker on the common pilot channel (code number 0 for spreading

factor 256; corresponds to displayed code numbers 0 and 1 of the x–axis).

Remote: CALC:MARK1:FUNC:CPIC

Remote: CALC:MARK1:Y?

Remote: CALC:DELT1:FUNC:CPIC

Remote: CALC:DELT1:Y?

PCCPCH

Sets the active marker/delta marker on the primary common control physical channel (code

number 1 for spreading factor 256; corresponds to displayed code numbers 2 and 3 of the x–

axis).

Remote: CALC:MARK1:FUNC:PCCP

Remote: CALC:MARK1:Y?

Remote: CALC:DELT1:FUNC:PCCP

Remote: CALC:DELT1:Y?

Min

For further details refer to the Min softkey in the marker–> menu of the base unit.

Next Min

For further details refer to the Next Min softkey in the marker–> menu of the base unit.

Next Min Mode < abs >

For further details refer to the Next Min Mode < abs > softkey in the marker–> menu of the base

unit.

Softkeys of the measurement menu (3G FDD BTS mode)

The following table shows all softkeys available in the measurement menu in 3G FDD BTS mode. It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Menu / Command Submenu / Command Submenu / Command Command

Auto Level&Code

Code Dom Channel Table

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Menu / Command Submenu / Command Submenu / Command Command

Code Dom Power Diagram

Code Dom Result Summary Select Channel

Result Summary Normal

Result Summary Extended

Power CP / ACP Config #of TX Chan

#of Adj Chan

Channel Settings Channel Bandwidth

Channel Spacing

Chan Pwr/Hz

ACP Ref Settings

Adjust Ref Lvl

Adjust Settings

Limit Checking Limit Chk On/Off

Edit ACP Limit

Power Mode Clear/Write

Max Hold

Select Trace

Adjust Settings

Sweep Time

Fast ACP On/Off

ACP Abs/Rel

Adjust Ref Lvl

ACP same contents as Power

Spectrum Emission Mask Limit Line Auto

Limit Line Manual

Limit Line User 

Restore Std Lines

30kHz/1MHz Transition

Adjust Ref Level

Auto Level&Code

Starts a sequence performing the following steps:

–Auto adjust the reference level.

–Search and select scrambling code with the highest power.

– Start measurement.

–Select Code Domain Result Summary result display.

Remote: CDP:ASEQ

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Code Dom Channel Table

Selects the Code Domain Channel Table result display. This channel assignment table can

contain up to 512 entries, corresponding to the 512 codes that can be assigned within the class

of spreading factor 512. For detailed description of the channels refer to "Channels of the Code

Domain Channel Table and their usage" on page 4.273.

In the upper part of the Code Domain Channel Table, all channels that have to be present in the

signal to be analyzed are listed. In the lower part of the table, all data channels contained in the

signal are listed. A data channel is any channel that does not have a predefined channel number

and symbol rate.

The channels are listed in descending order according to symbol rates and, within a symbol rate,

in ascending order according to the channel numbers. Therefore, the unassigned codes are

always to be found at the end of the table.

The following parameters of these channels are determined by the code domain power

measurement:

–Chan Type

type of channel (active channels only)

If the modulation type of a channel can vary (HS–PDSCH), the value of the measured

modulation type is appended to the channel type. Data channels without a type fully recognized

are characterized as CHAN.

–SymRate [ksps]

symbol rate at which the channel is transmitted (7.5 ksps to 960 ksps).

–Chan

number of the channel spreading code (0 to [spreading factor–1]).

–Status

Unassigned codes are considered to be inactive. A data channel is considered to be active if

the required pilot symbols (see 3GPP specification, exception: PICH) are to be found at the end

of each slot. In addition, the channel should have minimum power (see Inactive Channel

Threshold softkey).

–PilotL [Bits]

number of pilot bits of the channel

–PwrAbs [dBm]/ PwrRel [dB]

3GPP Base Station Measurements (Option K72) R&S FSL

1300.2519.12 4.286 E-11

indication of the absolute and relative channel power (referenced to the CPICH or the total

power of the signal)

–TOffs [Chips]

timing offset = offset between the start of the first slot of the channel and the start of the

analyzed 3GPP FDD frame

Remote: CALC:FEED 'XTIM:CDP:ERR:CTAB'

Remote: TRAC? CTAB

Code Dom Power Diagram

Selects the Code Domain Power Diagram result display. Common settings for code domain power

measurements are performed via the settings menu (MENU key). For details refer to "Softkeys of

the settings menu (3G FDD BTS mode)" on page 4.275.

This result display shows the power of all occupied code channels in a bar graph. The x–axis is

scaled for the highest code class or the highest spreading factor (512). Code channels with a lower

spreading factor occupy correspondingly more channels of the highest code class. The power of a

code channel is always measured according to its symbol rate. Unused code channels are

assumed to belong to the highest code class and displayed accordingly. The displayed power of an

unused code channel therefore corresponds to the power of a channel with the spreading factor

512 at the respective code position.

The measured power always refers to one slot. The time reference for the start of a slot is the

CIPCH slot. If the signal contains channels with timing offsets, the start of a slot of the channel may

be different from the CPICH slot start. This leads to the power of the bar graphs normally being

averaged over two adjacent slots in such cases. The power shown in the bar graphs thus does not

necessarily correspond to the slot power of the channel the bar graph belongs to.

Detected channels are displayed in yellow color.

The codes where no channel could be detected (non–active channels) are displayed in blue

color. These channel should be checked for their pilot symbols.

The channel that is adjusted via the Select Channel softkey is marked red. If it is an assigned

channel, the entire channel is marked red. If it is an unassigned code, only the entered code is

marked.

R&S FSL 3GPP Base Station Measurements (Option K72)

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If the HSDPA/HSUPA On/Off softkey is activated, the detection of channels does not depend on

pilot sequences. An active channel merely has to exceed the minimum power (see Inactive

Channel Threshold softkey). Therefore channels of the type HS–PDSCH are recognized as

active (see also Code Dom Channel Table softkey).

Remote: CALC:FEED 'XPOW:CDP'

Remote: TRAC? TRACE1

Code Dom Result Summary

Opens a submenu to display the Result Summary.

Result Summary Normal

Selects the mormal Code Domain Result Summary result display.

This result display shows the most important measurement results in one table with big letters.

Via the Result Summary Extended softkey you can switch to the extended Code Dom Result

Summary result display.

–Total Power

total signal power (average power of total evaluated 3GPP FDD frame).

–Carrier Frequency Error

frequency error relative to the center frequency of the R&S FSL

The absolute frequency error is the sum of the R&S FSL and DUT frequency error. The

specified value is averaged via one slot; the frequency offset of the selected slot applies (via

Select CPICH Slot softkey). The maximum frequency error that can be compensated is

specified in the table below as a function of the sync mode. Transmitter and receiver should be

synchronized as far as possible (see chapter 2).

Sync Type Antenna diversity Max. Freq. Offset

CPICH X 5.0 kHz

SCH OFF 1.6 kHz

SCH ANT 1 330 Hz

SCH ANT 2 330 Hz

–Composite EVM

difference between the test signal and the ideal reference signal

–Peak Code Domain Error

projection of the difference between the test signal and the ideal reference signal onto the

selected spreading factor

–No of Active Channels

number of active channels detected in the signal (Both the detected data channels and the

control channels are considered active channels.)

Remote: CALC:FEED 'XTIM:CDP:ERR:SUMM'

Remote: CALC:MARK:FUNC:WCDP:RES? CDP

Remote: TRAC? TRACE1

3GPP Base Station Measurements (Option K72) R&S FSL

1300.2519.12 4.288 E-11

Result Summary Extended

Extends the number of results shown in the normal Code Dom Result Summary result display

(Result Summary Normal softkey) by the results listed below.

This result display consists of two panes. The Global Results (upper pane) contains the results

for the total signal. The Channel Results (lower pane) lists the measurement results of the

selected channel (marked red in the Code Domain Power Diagram).

–Chip Rate Error

chip rate error in ppm

As a result of a high chip rate error, symbol errors arise and the code domain power

measurement is possibly not synchronized to the 3GPP FDD signal. The result is valid even if

synchronization of the R&S FSL and signal failed.

–Trigger to Frame

time difference between the beginning of the recorded signal section to the start of the analyzed

3GPP FDD frame

In the case of triggered data collection, this difference is identical with the time difference of

frame trigger (+ trigger offset) – frame start. If synchronization of the R&S FSL and W–CDMA

signal fails, the Trigger to Frame value is not significant.

–IQ Offset

DC offset of signals in %

–IQ Imbalance

I/Q imbalance of signal in %

–CPICH Slot No

number of the CPICH slot at which the measurement is performed (selected via the Select

CPICH Slot softkey).

–CPICH Power

power of the common pilot channel

–Symbol Rate

symbol rate at which the channel is transmitted

–RHO

quality parameter for every slot

–Channel Code

number of the spreading code of the selected channel

–Timing Offset

offset between the start of the first slot in the channel and the start of the analyzed 3GPP FDD

frame

–No of Pilot Bits

number of pilot bits of the selected channel

–Channel Slot No

channel slot number, obtained by combining the value of the Select CPICH Slot softkey and

the channel's timing offset

–Channel Power Rel / Abs

channel power, relative (see Power Ref TOT/CPICH softkey) and absolute.

R&S FSL 3GPP Base Station Measurements (Option K72)

1300.2519.12 4.289 E-11

–Symbol EVM

Peak (%Pk) or average (%rms) of the results of the error vector magnitude

–Modulation Type

modulation type of an HSDPA channel (QPSK or 16QAM modulation)

Remote: CDP:RSUM EXT

Power

Activates the measurement of the 3GPP FDD signal channel power and opens a submenu. This

measurement is identical to the ACP measurement (see ACP softkey), the default settings are in

accordance with the 3GPP specifications:

Parameter Default setting

CP / ACP Standard W–CDMA 3GPP FWD

#of Adj Chan 0 (all adjacent channels deactivated)

The R&S FSL measures the unweighted RF signal power in a bandwidth of

22.0|84.3)1(5 =+=



MHzMHzfBW

The power is measured in zero span using a digital channel filter of 5 MHz in bandwidth.

According to the 3GPP standard, the measurement bandwidth (5 MHz) is slightly larger than the

minimum required bandwidth of 4.7 MHz.

Remote: CONF:WCDP:MEAS POW

Remote: CALC:MARK:FUNC:POW:RES? CPOW

Remote: TRAC? TRACE1

CP / ACP Config

For further details refer to the CP / ACP Config softkey in the power measurement menu of the

base unit.

3GPP Base Station Measurements (Option K72) R&S FSL

1300.2519.12 4.290 E-11

#of TX Chan

For further details refer to the #of TX Chan softkey in the power measurement menu of the

base unit.

#of Adj Chan

For further details refer to the #of Adj Chan softkey in the power measurement menu of the

base unit.

Channel Settings

For further details refer to the Channel Settings softkey in the power measurement menu of the

base unit.

Channel Bandwidth

For further details refer to the Channel Bandwidth softkey in the power measurement menu of

the base unit.

Channel Spacing

For further details refer to the Channel Spacing softkey in the power measurement menu of the

base unit.

Chan Pwr/Hz

For further details refer to the Chan Pwr/Hz softkey in the power measurement menu of the

base unit.

ACP Ref Settings

For further details refer to the ACP Ref Settings softkey in the power measurement menu of the

base unit.

Limit Checking

For further details refer to the Limit Checking softkey in the power measurement menu of the

base unit.

Limit Chk On/Off

For further details refer to the Limit Chk On/Off softkey in the power measurement menu of the

base unit.

R&S FSL 3GPP Base Station Measurements (Option K72)

1300.2519.12 4.291 E-11

Edit ACP Limit

For further details refer to the Edit ACP Limit softkey in the power measurement menu of the

base unit.

Power Mode

For further details refer to the Power Mode softkey in the power measurement menu of the base

unit.

Clear/Write

For further details refer to the Clear/Write softkey in the power measurement menu of the base

unit.

Max Hold

For further details refer to the Max Hold softkey in the power measurement menu of the base

unit.

Select Trace

For further details refer to the Select Trace softkey in the power measurement menu of the base

unit.

Adjust Settings

For further details refer to the Adjust Settings softkey in the power measurement menu of the

base unit.

Sweep Time

For further details refer to the Sweep Time softkey in the power measurement menu of the base

unit.

Fast ACP On/Off

For further details refer to the Fast ACP On/Off softkey in the power measurement menu of the

base unit.

ACP Abs/Rel

For further details refer to the ACP Abs/Rel softkey in the power measurement menu of the

base unit.

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Adjust Ref Lvl

For further details refer to the Adjust Ref Level softkey in the power measurement menu of the

base unit.

ACP

Activates the Adjacent–Channel Power measurement and opens a submenu for configuration.

This measurement is identical to the ACP measurement of the base unit (see CP, ACP, MC–

ACP softkey in the measurement menu of the base unit), but the default settings are in

accordance with the 3GPP specifications:

Parameter Default setting

CP / ACP Standard W–CDMA 3GPP FWD

#of Adj Chan 2

The R&S FSL measures the channel power and the relative power of the adjacent

channels/alternate channels. The results are displayed below the screen.

Remote: CONF:WCDP:MEAS ALCR

Remote: CALC:MARK:FUNC:POWer:RES? ACP

Spectrum Emission Mask

Activates the Spectrum Emission Mask measurement and opens a submenu. This measurement

compares the signal power in defined carrier offset ranges with the maximum values specified

by 3GPP.

The following default settings are used in accordance with the 3GPP specifications:

Parameter Default setting

CP / ACP Standard W–CDMA 3GPP REV

#of Adj Chan 0

Span 25.5 MHz

BW 50 ms

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1300.2519.12 4.293 E-11

Additional to the graphical result display, the peak list displays the peaks of the frequency

ranges specified by the 3GPP specification. The table contains the following information:

Tx Power power of the transmission channel

Tx Bandwidth bandwidth used to measure the Tx power

Range upper and lower frequency of the evaluated range relative to the center frequency

RBW bandwidth used to measure the evaluated range

Frequency exact frequency where the peak was detected

Level absolute level of the peak

Pwr Rel peak level relative to the Tx power

Delta level relative to the limit.

Positive Values show that the peak exceeds the limit from the specification. The values

Level, Pwr Rel and Delta therefore change their color to red and an asterisk appears beside

the Delta values.

Remote: CONF:WCDP:MEAS ESP

Remote: TRAC? TRACE1

Limit Line Auto

If activated, sets the limit line automatically according to the power determined in the useful

channel. If the measurement is carried out in continuous sweep mode and the channel power

changes from sweep to sweep, this can result in the limit line being continuously redrawn. This

softkey is activated by default.

If deactivated, the limit line settings are defined via the Limit Line Manual softkey.

Remote: CALC:LIM:ESP:MODE AUTO

Limit Line Manual

Opens the Manual Power dialog box to select one of the following predefined limit lines

according to the expected power range:



43 dBm

39 dBm



P < 43 dBm

3GPP Base Station Measurements (Option K72) R&S FSL

1300.2519.12 4.294 E-11

31 dBm



P < 39 dBm

P<31 dBm

The power at the different frequency offsets is compared with the selected limit line.

Remote: CALC:LIM:ESP:MODE MAN

Remote: CALC:LIM:ESP:VAL 39

Limit Line User

Opens the lines menu of the base unit and switches to the standard limit line handling of the

base unit. For details refer to section "Softkeys of the lines menu" on page 4.123 of the base

unit.

Remote: CALC:LIM:ESP:MODE USER

Restore Std Lines

Restores the limit lines defined according to the standard to their factory–set values.

Remote: CALC:LIM:ESP:REST

30kHz/1MHz Transition

Defines the offset frequency at which the resolution bandwidth is changed in the range from 30

kHz to 1 MHz. The default value is 4.0 MHz.

Remote: CALC:LIM:ESP:TRAN 5MHZ

Adjust Ref Level

Adjusts the reference level to the total signal power measured. This softkey becomes active

after the occupied bandwidth has been measured in the first sweep and therefore the total signal

power is known.

This ensures that the signal path is not overdriven and that the dynamic range is not limited by a

reference level that is too low.

Remote: POW:ACH:PRES:RLEV

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.295 E-11

CDMA2000 BTS Analyzer (Option K82)

The R&S FSL equipped with the CDMA2000 BTS Analyzer option performs Code Domain

measurements on forward link signals according to the 3GPP2 Standard (Third Generation Partnership

Project 2). The "Recommended Minimum Performance Standard for CDMA2000 Spread Spectrum

Base Stations", C.S0010–C version 2.0 dated March 2006, is taken as a basis. This Standard has been

approved by the following authority with the specified designation:

•TIA: TIA-97-F-1

•TTA: TTAT.3G-C-S0010-C v2.0

When the CDMA2000 specification is mentioned in the document, these standards are meant.

The CDMA2000 BTS Analyzer option supports the radio configurations 1 to 5, i.e. all radio

configurations with a single carrier (1X) are supported. Accordingly, IS95A/B signals conforming to radio

configurations 1&2 can be measured with the CDMA2000 BTS Analyzer option. In addition to the

measurements called for by the CDMA2000 standard in the code domain, the CDMA2000 BTS

Analyzer option features measurements in the spectral range such as channel power, adjacent channel

power, occupied bandwidth and spectrum emission mask with predefined settings.

This option is available from firmware version 1.90.

To open the CDMA2000 BTS Analyzer

If the CDMA2000 BTS Analyzer mode is not the active measurement mode, press the MODE key

and activate the CDMA2000 BTS Analyzer option.

If the CDMA2000 BTS Analyzer mode is already active, press the MENU key.

The Code Domain Analyzer menu is displayed. .

Menu and softkey description

–"Softkeys of the Code Domain Analyzer menu (CDMA2000 BTS Analyzer mode)" on page 4.307

–"Softkeys of the frequency menu (CDMA2000 BTS Analyzer mode)" on page 4.335

–"Softkeys of the span menu (CDMA2000 BTS Analyzer mode)" on page 4.336

–"Softkeys of the amplitude menu (CDMA2000 BTS Analyzer mode)" on page 4.337

–"Softkeys of the bandwidth menu (CDMA2000 BTS Analyzer mode)" on page 4.339

–"Softkeys of the sweep menu (CDMA2000 BTS Analyzer mode)" on page 4.340

–"Softkeys of the trigger menu (CDMA2000 BTS Analyzer mode)" on page 4.341

–"Softkeys of the trace menu (CDMA2000 BTS Analyzer mode)" on page 4.341

–"Softkeys of the marker menu (CDMA2000 BTS Analyzer mode)" on page 4.343

–"Softkeys of the marker–> menu (CDMA2000 BTS Analyzer mode)" on page 4.344

–"Softkeys of the measurement menu (CDMA2000 BTS Analyzer mode)" on page 4.345

The lines menu is not available in the CDMA2000 BTS Analyzer mode.

The span menu is not available for code domain measurements and signal power measurements. For

details refer to the corresponding menu descriptions of the base unit ("Setting the Frequency Span –

SPAN Key".

The bandwidth menu is not available for code domain measurements and CCDF measurements. For

details refer to the corresponding menu descriptions of the base unit ("Setting the Bandwidths and

Sweep Time – BW Key").

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.296 E-11

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System" in the Quick Start Guide.

Further information

–"Predefined Channel Tables" on page 4.303

–"Relationship between channel type and modulation type" on page 4.305

–"Short list of terms and abbreviations" on page 4.306

–"Hadamard and BitReverse Code Tables" on page 4.353

Tasks

–"To edit a channel table" on page 4.297

–"To create a channel table" on page 4.297

–"To copy a channel table" on page 4.297

Measurements and result display

The CDMA2000 BTS Analyzer option provides the following test measurement types and result

displays. All measurements and result displays are accessed via the MEAS key (measurement

menu)."Code Domain Analysis" on page 4.298

–"Signal Channel Power" on page 4.300

–"Adjacent Channel Power" on page 4.300

–"Spectrum Emission Mask" on page 4.301

–"Occupied Bandwidth" on page 4.301

–"Complementary Cumulative Distribution Function" on page 4.302

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.297 E-11

To edit a channel table

1. Enter the Channel Table Settings menu and the corresponding dialog box is displayed.

2. Select the channel table to be edited by marking the check box.

3. Press the Edit softkey and the Edit Channel Table dialog box is displayed.

Each row in the table represents one channel. Channels are displayed as entered and not sorted

automatically. To sort the channels use the Sort softkey (for details on how sorting is done see the

Sort softkey).

4. Enter a name and a description of the channel table in the Name and Description field.

5. Add and delete channels by using the corresponding softkeys.

6. To edit an existing channel put the focus on the parameter to be changed.

–Choose a channel type from the dropdown menu (opens with the ENTER key) in the Channel

Type column. No channel types other than the ones found in the list can be chosen.

–Assign a channel number in the Walsh Ch.SF column. Note that some channel types have

predefined values and can not be edited.

–Choose a radio configuration in the Radio Configuration column.

–Activate or deactivate a channel in State column.

–The columns Symbol Rate/ ksps,Power/ dB and Domain Conflict can not be edited. The

values are calculated automatically.

For further details also refer to the Edit channel table dialog box.

To create a channel table

1. Enter the Channel Table Settings menu and the corresponding dialog box is displayed.

2. Press the New softkey and a new channel table by the name 'ChannelTable' will be added. The

new channel table contains no channels by default.

For further details refer to the New softkey as well as "To edit a channel table"on page 4.297.

To copy a channel table

1. Enter the Channel Table Settings menu and the corresponding dialog box is displayed.

2. Select the channel table to be copied by marking the check box.

3. Press the Copy softkey and the channel table in focus is copied. The copy is named

'Copy of <SourceChannelTableName>. Except the name, all elements of the channel table in focus

are copied.

For further details refer to the Copy softkey as well as "To edit a channel table" on page

4.297.Measurements and result display

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Measurements and result display

The CDMA2000 BTS Analyzer option provides the following test measurement types and result

displays. All measurements and result displays are accessed via the MEAS key (measurement

menu)."Code Domain Analysis" on page 4.298

–"Signal Channel Power" on page 4.300

–"Adjacent Channel Power" on page 4.300

–"Spectrum Emission Mask" on page 4.301

–"Occupied Bandwidth" on page 4.301

–"Complementary Cumulative Distribution Function" on page 4.302

Code Domain Analysis

The Code Domain Analyzer performs measurements in the code domain. The following

measurement types and corresponding result displays are available:

Softkey Definition

Code Domain Power Code Domain Power result display in relative or absolute scaling

Channel Table Channel occupancy table

Power vs PCG Power of the selected channel versus all PCGs

Result Summary Results in tabular form

Code Domain Error Code Domain Error Power result display

Composite EVM Averaged error between the test signal and the ideal reference signal

Peak Code Domain Error Projection of the maximum error between the test signal and the reference signal

Channel Constell Channel Constellation result display

EVM vs Symbol Error Vector Magnitude result display

Composite Constell Composite Constellation result display

Power vs Symbol Power of the selected channel and of the selected PCG versus all symbols

Channel Bitstream Display of decided bits

In the Code Domain Analyzer, the results are displayed in either one screen or in two screens (see

Screen Size Full/Split softkey). Any result can be displayed in either screen. On top of the

measurement screens the following settings and measurement results (so called result displays)

are displayed (with the respective default settings):

Frequency: 2.4020 Ghz Ref. Level: -20.00 dBm Ref. Lvl Offset: 0.0 dB

Power Ref: PICH Count: 0 Attenuation: 0 dB

PCG: 0 Channel: 0.64 Symbol Rate: 19.2 ksps

The result displays are defined in the following way:

Parameter Defined in

Frequency Frontend Settings dialog box, Center field

Power Ref Result Settings dialog box, Power Reference field

PCG Result Settings dialog box, Power Control Group field

Ref. Level Frontend Settings dialog box, Ref. Level field

Count SWEEP menu, Sweep Count softkey

Attenuation Frontend Settings dialog box, RF Attenuation Auto field

R&S FSL CDMA2000 BTS Analyzer (Option K82)

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Parameter Defined in

Ref. Lvl Offset Frontend Settings dialog box, Ref. Level Offset field

Channel Result Settings dialog box, Channel (Code) Number field

Symbol Rate Automatically calculated (see Add Channel softkey)

In the default setting after the preset, the analyzer is in Spectrum Analyzer mode (for details see

"Initializing the Configuration – PRESET Key"on page 4.3). The settings of the Code Domain

Analyzer are not active until the CDMA2000 BTS Analyzer mode is activated (see "To open the

CDMA2000 BTS Analyzer" on page 4.295)

Table 4-9: Initial configuration of the Code Domain Analyzer

Parameter Setting

digital standard CDMA2000

sweep continuous

channel table auto search

trigger source free run

trigger offset 0 s

PN offset 0 chips

inactive channel threshold –60 dB

channel (code) number 0

power control group 0

capture length 3 PCGs (where PCG stands for Power Control Group)

code order Hadamard

antenna diversity OFF

In order to provide a quick swap from the base unit to the CDMA2000 BTS Analyzer option, some

parameters are passed on.

Transferred parameter

Reference level

Ref Level Offset

Center Frequency

Attenuation

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.300 E-11

Signal Channel Power

The Power measurement analyses the RF signal power of a single channel with 1.2288 MHz

bandwidth over a single trace. The displayed results are based on the root mean square.

The configuration is according to the CDMA2000 requirements.

Beneath the measurement screen the bandwidth and the associated channel power are

displayed. The other screen elements match that of the screen of the Spectrum Analyzer mode.

The default settings are in accordance with the 3GPP2 specifications.

Setting Default value

Frequency Span 2 MHz

ACP Standard CDMA2000 MC1

Number of adjacent channels 0

Adjacent Channel Power On

In order to provide a quick swap from the base unit to the CDMA2000 BTS Analyzer option,

some parameters are passed on.

Transferred parameter

Reference Level

Ref Level Offset

RBW

VBW

#of Samples

Refer also to the Power softkey in the measurement menu.

Adjacent Channel Power

The Adjacent Channel Power measurement analyses the power of the TX channel and the

power of adjacent and alternate channels on the left and right side of the TX channel. The

number of TX channels and adjacent channels can be modified as well as the band class.

Beneath the measurement screen the bandwidth and power of the TX channel and the

bandwidth, spacing and power of the adjacent and alternate channels are displayed.

The default settings are in accordance with the 3GPP2 specifications.

Setting Default value

Adjacent Channel Power On

ACP Standard CDMA2000 MC1

Number of adjacent channels 2

In order to provide a quick swap from the base unit to the CDMA2000 BTS Analyzer option,

some parameters are passed on.

Transferred parameter

Reference Level

Ref Level Offset

RBW

VBW

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.301 E-11

Transferred parameter

#of Adjacent Channels

Sweep Time

Span

Fast ACP Mode

For details on the softkeys of the Adjacent Channel Power measurement refer to the Adjacent

Channel Power softkey in the measurement menu.

Spectrum Emission Mask (see Spectrum Emission Mask softkey)

The default settings of the Spectrum Emission Mask measurement are listed in the table below.

Setting Default value

Frequency Span 8 MHz

Sweep Time 100 ms

Detector RMS

In order to provide a quick swap from the base unit to the CDMA2000 BTS Analyzer option,

some parameters are passed on.

Transferred Parameter

Reference Level

Ref Level Offset

Center Frequency

Frequency Offset

Trigger settings

For details on the softkeys of the Spectrum Emission Mask measurement refer to the

Spectrum Emission Mask softkey in the measurement menu.

Occupied Bandwidth

The Occupied Bandwidth measurement determines the bandwidth in which the signal power

can be found. By default the bandwidth is displayed in which 99% of the signal is found. The

percentage of the signal power included in the measurement can be modified.

In the top right corner of the screen, the bandwidth and frequency markers are displayed.

The default settings of the Occupied Bandwidth measurement are listed in the table below.

Setting Default value

Occupied Bandwidth ON

Frequency Span 4.2 MHz

Sweep Time 100 ms

RBW 30 kHz

VBW 300 kHz

Detector RMS

In order to provide a quick swap from the base unit to the CDMA2000 BTS Analyzer option,

some parameters are passed on.

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Transferred parameter

Reference Level

Ref Level Offset

RBW

VBW

Sweep Time

Span

For details on the softkeys of the Occupied Bandwidth measurement see Occupied

Bandwidth in the measurement menu.

Complementary Cumulative Distribution Function (CCDF)

The CCDF measurement displays the CCDF and the Crest factor. The CCDF shows

distribution of the signal amplitudes. For the measurement, a signal section of settable length is

recorded continuously in a zero span. The measurement is useful to determine errors of linear

amplifiers.

The Crest factor is defined as the difference of the peak power and the mean power.

Beneath the measurement screen a table containing the number of included samples, mean

and peak power and the Crest factor is displayed.

The default settings of the CCDF measurement are listed in the table below.

Setting Default value

CCDF ON

RBW 10 MHz

Detector Sample

In order to provide a quick swap from the base unit to the CDMA2000 BTS Analyzer option,

some parameters are passed on.

Transferred parameter

Reference Level

Ref Level Offset

RBW

#of Samples

For details on the softkeys of the CCDF measurement see CCDF in the measurement menu.

In a transition from the base unit to the CDMA2000 BTS Analyzer option, external trigger sources are

preserved, all other trigger sources are switched to the Free Run trigger mode. Additional trigger

settings are preserved.

For a detailed description refer also to chapter "Advanced Measurement Examples".

R&S FSL CDMA2000 BTS Analyzer (Option K82)

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Predefined Channel Tables

Predefined channel tables offer access to a quick configuration for the channel search. The CDMA2000

BTS Analyzer option provides the following set of channel tables compliant with the CDMA2000

specification:

•RECENT

This channel table always appears first in the list. It contains the channels that were automatically

created during the last measurement with Auto Search channels activated (for details refer to

Channel Table Settings).

•MPC_RC1 (Base Station Main Path 6 Channels Radio Configuration 1)

Channel table with F-PICH/F-SYNC/F-PCH and 6 data channels (see Table 4-10).

•MPC_RC4 (Base Station Main Path 6 Channels Radio Configuration 4)

Channel table with F-PICH/F-SYNC/F-PCH and 6 data channels (see Table 4-11).

•TDC_RC4 (Base Station Transmit Diversity Path 6 Channels Radio Configuration 4)

Channel table with F-PICH/F-SYNC/F-PCH and 6 data channels (see Table 4-12).

In addition to the compliant channel tables, the following channel tables are defined:

•BPC_RC4 (Base Station Both Paths 6 Channels Radio Configuration 4)

Channel table with F-PICH/F-TDPICH/F-SYNC/F-PCH and 6 data channels (see Table 4-13).

–The standard does not specify a channel number for the data channels. If you wish to use

channels other than those in the predefined channel tables, you may copy the original tables

and adapt the channels in the copy. For details refer to the step-by-step instructions "To edit a

channel table", "To create a channel table"and "To copy a channel table".

Table 4-10: Base station channel table for main branch in radio configuration 1

Channel type Number of

channels

Radio

configuration

Code channel

(Walsh Code.SF)

F-PICH 1 – 0.64

F-SYNC 1 – 32.64

F-PCH 1 – 1.64

CHAN 6 1

9.64

10.64

11.64

15.64

17.64

25.64

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Table 4-11: Base station channel table for main branch in radio configuration 4

Channel type Number of

channels

Radio

configuration

Code channel

(Walsh Code.SF)

F-PICH 1 – 0.64

F-SYNC 1 – 32.64

F-PCH 1 – 1.64

CHAN 6 4

9.128

10.128

11.128

15.128

17.128

25.128

Table 4-12: Base station channel table for antenna 2 in radio configuration 4

Channel type Number of

channels

Radio

configuration

Code channel

(Walsh Code.SF)

F-TDPICH 1 – 16.128

F-SYNC 1 – 32.64

F-PCH 1 – 1.64

CHAN 6 4

9.128

10.128

11.128

15.128

17.128

25.128

Table 4-13: Base station test model for aggregate signal in radio configuration 4

Channel type Number of

channels

Radio

configuration

Code channel

(Walsh Code.SF)

F-PICH 1 – 0.64

F-TDPICH 1 – 16.128

F-SYNC 1 – 32.64

F-PCH 1 – 1.64

CHAN 6 4

9.128

10.128

11.128

15.128

17.128

25.128

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Relationship between channel type and modulation type

Channel type Channel Modulation

F-PICH Pilot channel BPSK

F-SYNC Synchronisation channel BPSK

F-PCH Paging channel BPSK

F-TDPICH Transmit diversity pilot channel BPSK

F-APICH Auxiliary pilot channel BPSK

F-ATDPICH Auxiliary transmit diversity channel BPSK

F-BCH Broadcast channel QPSK

F-CPCCH Common power control channel QPSK

F-CACH Common assignment channel QPSK

F-CCCH Common control channel QPSK

F-PDCCH Packet data control channel QPSK

F-PDCH Packet data channel QPSK, 8PSK or 16QAM

CHAN Data channel radio configuration 1-2 BPSK

CHAN Data channel radio configuration 3-5 QPSK

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Short list of terms and abbreviations

For a more comprehensive glossary refer to the CDMA2000 standard.

Term or abbreviation Description

APICH auxiliary pilot channel

ATDPCH auxiliary transmit diversity pilot channel

BCH broadcast channel.

CACH common assignment channel

CCCH common control channel

CDEP code domain error power

CDP code domain power

Composite EVM In accordance with the 3GPP2 specifications, determines the square root of the squared

error between the real and the imaginary parts of the test signal and an ideally generated

reference signal (EVM referred to the total signal) in a composite EVM measurement.

CPCCH common power control channel

Crest factor ratio of peak to average value of the signal

Inactive Channel Threshold Minimum power that a single channel must have compared with the total signal to be

recognized as an active channel.

MC1 multi–carrier1 (one carrier system 1X).

MC2 multi–carrier3 (three carrier system 3X).

OTD orthogonal transmit diversity, two antennas used

PCG power control group: name in CDMA2000 system for 1536 chips or 1.25 ms interval;

transmitter power is constant during a power control group

PCH paging channel

PDCH packet data channel

PDCCH packet data control channel

PICH pilot channel 0.64

RC radio configuration; definition of sampling rate, permissible data rates, modulation types

and use of special channels, and transmit diversity

SF spreading factor

SYNC synchronisation channel 32.64

TD transmit diversity, two antennas used

TDPICH transmit diversity pilot channel 16.128

x.y Walsh code x.y, with code number x and spreading factor y of the channel

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Softkeys of the Code Domain Analyzer menu (CDMA2000 BTS Analyzer mode)

"The following table shows all softkeys available in the main menu of the CDMA2000 BTS Analyzer

option (MENU key). It is possible that your instrument configuration does not provide all softkeys. If a

softkey is only available with a special option, model or (measurement) mode, this information is

delivered in the corresponding softkey description.

Note: Most of the settings of the Code Domain Analyzer can be changed in two ways. One way is to

use the softkeys like in the base unit and previous options, i.e. by pressing the softkeys and by

entering the desired parameters directly in the corresponding fields. The softkey automatically

sets the focus on the desired field.

The other way is to use the dialog boxes, in which most of the settings of the Code Domain

Analyzer can be changed. To change a parameter via the dialog boxes, select the parameter to

be modified with the rotary knob or the cursor keys and press the ENTER key to edit the field

(the blue solid frame becomes a blue dotted frame). Make the desired changes in the field. To

confirm the changes press the ENTER key a second time.

Menu / Command Submenu / Command Submenu / Command Command

Settings Settings Overview

Frontend Settings

IQ Capture Settings

Demod Settings

Channel Table Settings New

Copy

Delete

Edit Add Channel

Delete Channel

Meas

Sort

Save

Cancel

Reload

Restore Default Tables

Result Settings

Screen Focus A/B

Screen Size Full/Split

Select Meas Code Domain Power

Channel Table

Power vs PCG

Result Summary

Screen Focus A/B

Select Ch/PCG

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Menu / Command Submenu / Command Submenu / Command Command

More 

Code Domain Error

Composite EVM

Peak Code Domain Error

Channel Constell

Screen Focus A/B

Select Ch/PCG

More 

EVM vs Symbol

Composite Constell

Power vs Symbol

Channel Bitstream

Screen Focus A/B

Select Ch/PCG

Adjust Ref Level

Settings

Opens a submenu to configure the Code Domain Analyzer result displays with the following

softkeys:

–Settings Overview

–Frontend Settings

–IQ Capture Settings

–Demod Settings

–Channel Table Settings

–Result Settings

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Settings Overview

This softkey opens the Settings Overview dialog box that visualizes the data flow of the Code

Domain Analyzer and summarizes all of the current settings. In addition, the current settings can

be changed via the Settings Overview dialog box.

To change the settings, either use the rotary knob or the cursor keys to change the focus to any

other block or press one of the following softkeys:

–Frontend Settings

–IQ Capture Settings

–Demod Settings

–Channel Table Settings

–Result Settings

When using the rotary knob or the cursor keys, press the ENTER key to open the corresponding

dialog box. The Settings Overview dialog box always remains open while settings are modified.

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Frontend Settings

Opens the Frontend Settings dialog box.

In the Frontend Settings dialog box, the following parameters can be modified:

Center

Ref. Level

Ref. Level Offset

RF Attenuation Manual

RF Attenuation Auto

Preamplifier

Center (Frontend Settings dialog box)

For details refer to the Center softkey in the frequency menu of the base unit.

Ref. Level (Frontend Settings dialog box)

For details refer to the Ref Level softkey in the amplitude menu of the base unit.

Ref. Level Offset (Frontend Settings dialog box)

For details refer to the Ref Level Offset softkey in the amplitude menu of the base unit.

RF Attenuation Manual (Frontend Settings dialog box)

For details refer to the RF Atten Manual softkey in the amplitude menu of the base unit.

RF Attenuation Auto (Frontend Settings dialog box)

For details refer to the RF Atten Auto softkey in the amplitude menu of the base unit.

Preamplifier (Frontend Settings dialog box)

For details refer to the Preamp On/Off softkey in the amplitude menu of the base unit.

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IQ Capture Settings

Opens the IQ Capture Settings dialog box.

In the IQ Capture Settings dialog box, the following parameters can be modified:

Capture Length

Swap IQ

Trigger Source

Trigger Polarity

Trigger Offset

Capture Length (IQ Capture Settings dialog box)

Defines the number of power control groups (PCG) that are to be analyzed. The input value is

always in multiples of the PCGs. The maximum capture length value is 64. The default value is

Remote: CDP:IQL 12

Swap IQ (IQ Capture Settings dialog box)

If activated, inverts the sign of the Q-component of the signal. The default setting is OFF.

Remote: CDP:QINV ON

Trigger Source (IQ Capture Settings dialog box)

Selects one of the trigger modes: Free Run or External. Other trigger modes are not available.

The default setting is Free Run. If External trigger mode has been set, the enhancement label

TRG is displayed. For details on the trigger modes refer to Trigger mode overview on page 4.31.

Remote: TRIG:SOUR EXT

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Trigger Polarity (IQ Capture Settings dialog box)

Sets the polarity of the trigger source.

Depending on the required polarity of the edge, the trigger polarity can be set to either positive

or negative. The default setting is Pos.The setting only has an effect if the trigger source is

external.

Remote: TRIG:SLOP POS

Remote: SWE:EGAT:POL POS

Trigger Offset (IQ Capture Settings dialog box)

For details refer to the Trigger Offset softkey in the trigger menu of the base unit.

Demod Settings

Opens the Demodulation Settings dialog box:

In the Demodulation Settings dialog box, the following parameters can be modified:

Base SF

Antenna Diversity

Multi Carrier

Time/Phase Estimation

PN Offset

Base SF (Demod Settings dialog box)

Specifies the base spreading factor. If the base spreading factor of 64 is used for channels of

spreading factor 128 (code class 7), an alias power is displayed in the Code Domain Power and

Code Domain Error Power diagrams.

Remote: CDP:SFAC 64

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Antenna Diversity (Demod Settings dialog box)

Activates or deactivates the orthogonal transmit diversity (two-antenna system) and defines the

antenna for which the results will be displayed.

Antenna 1 The signal of antenna 1 is fed in.

The pilot channel (F-PICH) with channel number 0 and spreading factor 64

(0.64) is required.

If a channel table is used in the measurement (see Channel Table), it

must contain the pilot channel (F-PICH), but must not contain the transmit

diversity pilot channel (F-TDPICH).

As reference for the code power (Power Reference), PICH is used.

Antenna 2 The signal of antenna 2 is fed in.

The transmit diversity pilot channel (F-TDPICH) with channel number 16

and spreading factor 128 (16.128) is required.

If a channel table is used in the measurement (see Channel Table), it

must contain the transmit diversity pilot channel (F-TDPICH), but must not

contain the pilot channel (F-PICH).

As reference for the code power (Power Reference), F-TDPICH is used.

Off The aggregate signal from both antennas is fed in.

The pilot channels of both antennas are required.

If a channel table is used in the measurement (see Channel Table), it

must contain both the transmit diversity pilot channel (F-TDPICH) and the

pilot channel (F-PICH).

As reference for the code power (Power Reference), F-PICH is used.

Remote: CDP:ANT OFF

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Multi Carrier (Demod Settings dialog box)

Activates or deactivates the Multi Carrier mode. The mode improves the processing of multi

carrier signals. It allows the measurement on one carrier out of a multi carrier signal. This is

done by activating a low pass filter and by using a special algorithm for signal detection on multi

carrier signals.

Note that the low pass filter affects the measured signal quality (e.g. EVM and RHO) compared

to a measurement without a filter. The algorithm used for signal detection slightly increases the

calculation time.

The frequency response of the low pass filter is shown below.

00.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1

-70

-60

-50

-40

-30

-20

-10

Frequency response of low pass filter (Multi Carrier = On)

Frequency in MHz

|H(f)| in dB

Remote: CONF:CDP:MCAR ON

Time/Phase Estimation (Demod Settings dialog box)

Actives or deactivates the timing and phase offset calculation of the channels as to the pilot

channel. If deactivated or more than 50 active channels are in the signal, the calculation does

not take place and dashes instead of values are displayed as results.

Remote: CDP:TPM ON

PN Offset (Demod Settings dialog box)

Specifies the PN (Pseudo Noise) offset of the base station, which is used to distinguish the base

stations within a CDMA2000 system.

The PN offset determines the offset in the circulating PN sequence in multiples of 64 chips with

reference to the event second clock trigger.

Although the parameter is always available, it only has a function in External trigger mode.

Remote: CDP:PNOF 0...511

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Channel Table Settings

Opens the Channel Table Settings dialog box and the corresponding submenu.

Predefined channel tables are a way to customize measurements. The RECENT channel table

contains the last configuration used before switching from Auto Search to Predefined. The

BPC_RC4, MPC_RC1, MPC_RC4 and TDC_RC4 channel tables are included in the option per

default and are configured according to the standard. For details on the predefined channel

tables refer to Predefined Channel Tables on page 4.303. In addition, new channel tables can

be created and saved to be used in measurements. For details refer to the step by step

instructions on how To edit a channel table on page 4.297, To create a channel table on page

4.297 and To copy a channel table on page 4.297.

In the Channel Table Settings dialog box, the following parameters can be modified:

Channel Table

Inactive Channel Threshold

Channel Table Name

Channel Table (Channel Table Settings dialog box)

Defines the channel table used in the measurement.

Auto Search Searches the whole code domain (all permissible symbol rates and

channel numbers) for active channels.

The automatic search provides an overview of the channels contained in

the signal. If channels are not detected as being active, change the

threshold (see Inactive Channel Threshold)or select the Predefined

channel search type.

Predefined Performs the Code Domain Analyzer measurement on the basis of the

active predefined channel table (see Channel Table Name). All

channels of a channel table are assumed to be active. For details see

also Predefined Channel Tables on page 4.303.

Remote: CONF:CDP:CTAB[:STAT] ON

Remote: CONF:CDP:CTAB:SEL "MPC_RC4"

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Inactive Channel Threshold (Channel Table Settings dialog box)

Defines the minimum power which a single channel must have compared to the total signal in

order to be regarded as an active channel. Channels below the specified threshold are regarded

as "inactive". The parameter is only available in the Auto Search mode of the Channel Table

Settings dialog box.

The default value is -60 dB. With this value all channels with signals such as the CDMA2000 test

models are located by the Code Domain Power analysis. Decrease the Inactive Channel

Threshold value, if not all channels contained in the signal are detected.

Remote: CDP:ICTR –100 dB ... 0 dB

Channel Table Name (Channel Table Settings dialog box)

In this field a list of the available channel tables is shown. To activate a predefined channel

table, select the corresponding check box by using the cursor keys and pressing the ENTER

key. The selected channel table is then used as the basis for future measurements (until another

is chosen or Auto Search is activated).

An active channel table must completely describe the supplied signal, also in regard to the

transmit diversity (see Antenna Diversity).

Using the softkeys, customized channel tables can be defined or existing channel tables can be

modified. For details refer to the step-by-step instructions To edit a channel table on page 4.297,

To copy a channel table on page 4.297 and To create a channel table on page 4.297.

Remote: CONF:CDP:CTAB:CAT?

New

Creates a new channel table name that can be seen in the dialog box from then on. The name

will be automatically set to 'ChannelTable'. By default, the resulting channel table is completely

empty (i.e. it contains no channel at all). Also see the section on how To create a channel table

on page 4.297.

Remote: CONF:CDP:CTAB:NAME "NEW_TAB"

Copy

Copies the selected table. All elements of the selected channel table are copied, except the

name which is set to 'Copy of <SourceChannelTableName>'. Also see the section on how To

copy a channel table on page 4.297.

Remote: CONF:CDP:CTAB:COPY "CTAB2"

Delete

Deletes the selected channel table. The currently active channel table cannot be deleted.

Remote: CONF:CDP:CTAB:DEL "CTAB2"

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Edit

Opens the Edit Channel Table dialog box and the corresponding softkey menu.

The dialog box contains the following items (grey fields can not be modified):

Item Description

Name Enter the name of the selected channel table, which will be

saved under <name>.xml. Note that the old channel table

file is not deleted. The name is case sensitive and may not

contain spaces. It must be a valid MS Windows file name.

Description Further information about the channel table can be entered

Channel Type Select one of the channel types from the dropdown menu

Walsh Ch.SF Enter the Channel Number (Ch) and Spreading Factor (SF).

For some channel types the possible values are limited or

preset (e.g. F-PICH, F-TDPICH and F-PDCH).

Symbol Rate/ksps Display of the symbol rate

RC The Radio Configuration (RC) can be customized for only

two channel types. For the F-PDCH the values can be

10(QPSK), 10(8PSK) and 10(16QAM). For CHAN channels

the Radio Configuration can either be 1-2 or 3-5.

Power/dB Contains the measured relative code domain power. The

unit is dB. The fields are filled with values after pressing the

Meas softkey.

State Indicates whether a channel is active or inactive

DomainConflict A red bullet is shown if there's a conflict of any sort between

two or more channels (e.g. two conflicting channel codes)

Changes are never saved automatically. For that reason every time a change is made, the text

'*(unsaved changes)' appears in the title bar.

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The corresponding softkey menu contains the following items:

Add Channel

Delete Channel

Meas

Sort

Save

Cancel

Reload

Remote: CONF:CDP:CTAB:NAME "NEW_TAB"

Add Channel

Inserts a new channel below the one selected. The default values for a new channel are:

ChannelType CHAN

Walsh Ch.SF 1.64

SymbolRate 19.2 ksps (automatically calculated)

RadioConfiguration 3-5

Power 0 dB (automatically calculated)

State Off

DomainConflict No (automatically calculated)

To change the channel type use the dropdown menu that opens when selecting / highlighting

the Channel Type field that should be changed and pressing the ENTER key. The radio

configuration settings are changed in the same way.

To change the channel number type another channel number in the form

'ChannelNumber.SpreadingFactor' or simply the code number (see Channel (Code) Number

for details) in the respective field and confirm the change with the ENTER key.

To activate or deactivate a channel, simply select the field and confirm with the ENTER key.

The R&S FSL automatically checks for conflicts between two active channels.

Remote: CONF:CDP:CTAB:DATA "0…13, 2…7, 0…127, 0…30, 0, 0, 0 | 1"

Delete Channel

Deletes the selected channel without further notice.

Meas

Initiates a measurement in Automatic Channel Search mode. The measurement results are

applied to the active channel table. The active channel table is overwritten without further notice.

The softkey is only available if the Auto Search mode is selected in the Channel Table

Settings dialog box.

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Sort

Sorts the table according to the following rules.

First off, active channels are separated from inactive channels. Within these categories sorting is

then done first by the channel type (special channels like F-PICH or F-SYNC first, then data

channels) and next by the spreading factor in ascending order. Last, the sorting is done by the

code number, also in ascending order.

Save

Saves the table under its specified name in the xml-format. If you edit a channel table and want

to keep the original channel table, change the name of the edited channel table before saving it.

Cancel

Closes the Edit dialog box and returns to the Channel Table Settings dialog box. Changes

applied to the channel table are lost.

Reload

Reloads the original content of the copied channel table.

Restore Default Tables

Restores the predefined channel tables (see Predefined Channel Tables on page 4.303) to their

factory–set values. Existing channel tables with the same name as default channel tables are

replaced by this action. In this way, you can undo unintentional overwriting.

Remote: CONF:CDP:CTAB:REST

Result Settings

Opens the Result Settings dialog box.

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The Result Settings dialog box contains the following parameters:

Power Control Group

Channel (Code) Number

Code Order

Code Power

Power Reference

Normalize

Power Control Group (Result Settings dialog box)

In some measurements it is possible to highlight the data of a specific PCG (Power Control

Group). Select the PCG (Power Control Group) on which to put the focus on in this field. The

range of the value depends on the Capture Length defined in the IQ Capture Settings dialog

box. The range is (0 to Capture Length-1).

The defined value is valid for any measurement which takes PCGs into account (for further

information see also the Select Ch/PCG softkey). The selected PCG is highlighted in red on the

screen (as opposed to the others which are displayed in yellow).

Remote: CDP:SLOT 0 ...(IQ_CAPTURE_LENGTH–1)

Channel (Code) Number (Result Settings dialog box)

The entry in this field corresponds to a specific code to be examined. The valid range is from 0

to BSF-1. The base spreading factor (BSF) is either 64 or 128 depending on the setting of the

Base SF field and can not be edited via this field. The selected channel will be marked red in the

Channel Table. In the Code Domain Power display and the Code Domain Error Power display,

all codes belonging to this channel will be marked red.

The defined value is valid for any measurement that takes a selected channel into account (for

further information see also the Select Ch/PCG softkey).

The rotary knob behavior depends on the result display and the graphic display. In the case of

the Code Domain Power and Code Domain Error result displays, the rotary knob behavior

depends on the code order (refer to Code Order)The adjacent channel is always selected with

the rotary knob. In the channel table, the rotary knob is used to scroll through the list.

Remote: CDP:CODE 0...(BASE SF–1)

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Code Order (Result Settings dialog box)

Selects the channel sorting for the Code Domain Power and Code Domain Error result

displays.

Bit-Reverse order The channels with concentrated codes are next to one another,

since the code numbers are sorted in bit–reversed order. Thus in the

Code Domain Power result display, the total power of a

concentrated code channel is displayed.

Example (for base spreading factor of 64):

0.64, 32.64, 16.64, 48.64, 8.64, 40.64, ... , 15.64, 47.64,

31.64, 63.64

Hadamard order The codes are sorted in ascending order in the result display.

Example (for base spreading factor of 64):

0.64, 1.64, 2.64, ... , 63.64.

For each code, the power is displayed in this code. If there is a code

channel in the signal that covers several codes, the individual power

of the codes is displayed.

For details refer to Hadamard and BitReverse Code Tables on page 4.353.

Remote: CDP:ORD HAD

Code Power (Result Settings dialog box)

Selects the y-axis scaling for the Code Domain Power result display.

Absolute scaling dBm

Relative scaling dB

The reference is determined via the Power Reference.

Remote: CALC:FEED "XPOW:CDP[:ABS]"

Remote: CALC:FEED "XPOW:CDP:RAT"

Power Reference (Result Settings dialog box)

Determines the reference power for the relative power result displays (Code Domain Power,

Power vs PCG).

Pilot Channel The reference power is the power of the pilot channel. Which

pilot channel is used as reference depends on the antenna

diversity (for details see Antenna Diversity).

This is the default setting.

Total Power The reference power is the total power of the signal referred per

power control group (PCG) to the corresponding PCG.

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By default, the power of the channels is referred to the power of the pilot channel (code number

0). The power of the pilot channel is identical over all PCGs and hence can be used as a

constant reference for the result display. In contrast, the total power can vary from PCG to PCG

due to the possibility of a power level change in the different code channels.

In the Power vs PCG result display, with enabled power control and reference to the total power

of the signal, the power control of the selected channel is not necessarily reflected.

Example (theoretical):

There is just one data channel in the signal and its power is controlled.

The power is referred to the total power of the signal (which consists only of the contribution

from this one data channel).

In the Power vs. PCG diagram, a straight line is displayed instead of the expected power

staircase.

For relative result displays, the reference value Total Power is therefore only meaningful if the

signal does not contain power control. For signals with enabled power control, use the Pilot

Channel setting, since the pilot channel is not subject to power control under any

circumstances.

Remote: CDP:PREF TOT

Normalize (Result Settings dialog box)

If activated, this parameter eliminates the DC offset from the signal. By default, the parameter is

deactivated.

Remote: CDP:NORM ON

Screen Focus A/B

Sets the focus on the selected screen. Changes apply only to the focused screen. There are no

restrictions to the display of measurement results, i.e. you can display every result display in

either or both screens.

Remote: DISP:SEL

Screen Size Full/Split

Displays the result display in full screen size, or splits the screen to display two result displays.

To change settings in split screen display, set the focus on the designated result display via the

Screen Focus A/B softkey.

Remote: DISP:FORM SING

Select Meas

Opens a submenu to select one of the measurements and result displays of the Code Domain

Analyzer:

–Code Domain Power on page 4.323

–Channel Table on page 4.324

–Power vs PCG on page 4.325

–Result Summary on page 4.326

–Code Domain Error on page 4.328

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–Composite EVM on page 4.329

–Peak Code Domain Error on page 4.330

–Channel Constell on page 4.331

–EVM vs Symbol on page 4.332

–Composite Constell on page 4.332

–Power vs Symbol on page 4.333

–Channel Bitstream on page 4.334

For details on screen layout and default settings refer to the measurement description of the

Code Domain Analysis on page 4.298.

Code Domain Power

Selects the Code Domain Power (CDP) result display with relative scaling.

In this result display, the total signal is taken into account over a single power control group. The

power of the different channels is determined and plotted in a diagram. In this diagram, the x–

axis represents the channel (code) number, which corresponds to the base spreading factor.

The y–axis is a logarithmic level axis that shows the power of each channel. To configure this

result display, use the Result Settings dialog box (Settings softkey menu, Result Settings

softkey).

The Code Domain Power result display supports two sort orders (for details refer to Code Order).

Fig. 4-30: CDP measurement (result displayed in Hadamard code order)

Fig. 4-31: CDP measurement (result displayed in Bit Reverse code order for the same signal)

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.324 E-11

Active and inactive channels are defined via the Channel Table Settings dialog box (Settings

softkey menu, Channel Table Settings softkey). The power values of the active and

unassigned channels are shown in different colors. In addition, codes with alias power can

occur. These codes obtain power components originating either from a spreading factor higher

than the base spreading factor or from the own and/or another antenna as a result of transmit

diversity.

The following colors are defined:

–Red: selected channel (Channel (Code) Number)

–Yellow: active channel

– Cyan: inactive channel

–Light blue: alias power of higher spreading factor

–Magenta: alias power as a result of transmit diversity

Note: If codes with alias power are displayed, set the highest base spreading factor using the Base

SF.

It is not recommended to select more detailed result displays (such as Channel Constell)for

unassigned codes, since the results are not valid.

Remote: CALC1:FEED "XPOW:CDP:RAT" (relative code power)

Remote: CALC1:FEED "XPOW:CDP" (absolute code power)

Channel Table

Selects the Channel Table result display.

The Channel Table result display may contain up to 128 entries, corresponding to the highest

base spreading factor of 128. The total signal is taken into account over a single power control

group. You can set the number of PCGs by the Capture Length.

In the Channel Table result display, the channels are sorted according to channel type, i.e.

special channels like F-PICH, F-SYNC etc. first, then data channels (CHAN) and last inactive

channels (always shown as '---').

Within a group, channels are sorted according to the spreading factor and then according to

code number, also in ascending order. Within the code number, first active, then inactive

channels are listed. The selected channel (Channel (Code) Number)is marked in red. Active

and inactive data channels are defined via the Channel Table Settings dialog box (Settings

softkey menu, Channel Table Settings softkey).

Fig. 4-32: Channel Table result display

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.325 E-11

For the Code Domain Power measurement, the following parameters are determined for the

channels:

–Channel Type

Shows type of channel ('---' for inactive channels)

–Walsh Chan.SF

Channel number including the spreading factor (in the form <Channel>.<SF>).

–Symb Rate/ksps

Symbol rate with which the channel is transmitted (9.6 ksps to 307.2 ksps).

–RC

Radio configuration.

–State

Status display. Unassigned codes are identified as inactive channels.

–Pwr dBm/Pwr dB

Specification of the absolute (dBm) and relative (dB) (referred to the F-PICH or the total power

of signal) power of the channel

–TOffs/ns and Ph Offs/mrad

Timing/phase offset between this channel and the pilot channel (enabled via the Demod

Settings softkey, Time/Phase Estimation).

If enabled, the maximum value of the timing/phase offset is displayed together with the

associated channel in the last two lines. Since the timing/phase offset values of each active

channel can be either negative or positive, the absolute values are compared and the maximum

is displayed with the original sign.

Remote: CALC1:FEED "XTIM:CDP:ERR:CTAB"

Power vs PCG

Selects the Power versus Power Control Group (PCG) result display.

In this result display, the power of the selected channel is averaged for each measured PCG and

referred to the pilot power of the PCG. Therefore the unit of the y–axis is dB (relative to the Pilot

Channel). For measurements in which Antenna Diversity is inactive (OFF) or set to 'Antenna 1',

the F-PICH channel is used as reference, while the F-TDPICH channel is used for measurements in

which Antenna Diversity is set to 'Antenna 2'.

Note: For signals with enabled power control, use the default reference power setting. For details

refer to Power Reference.

The result display consists of the number of the PCGs in the measurement and their respective

power value. You can set the number of PCGs by means of the Capture Length.Subsequently,

the Power vs. PCG result display takes one code channel into account over the entire period of

observation. The selected PCG (Power Control Group)is marked in red.

Note: For a power–regulated signal, to correctly detect the start of a power control group, the external

trigger must be used.

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.326 E-11

Fig. 4-33: Power vs PCG for an occupied channel with power control

Remote: CALC2:FEED "XTIM:CDP:PVSL"

Result Summary

Selects the numeric result display of many measurement results. Note the effects of the Trace

Mode softkey differ from other measurements. The Min Hold and Max Hold values are already

given in the Min and Max columns of the Result Summary table. When in Average trace mode,

the Current column is renamed to Average and the corresponding values are displayed. The

current values are displayed in the Current column, when the View trace mode is activated.

The result display is subdivided as follows:

–Global Results

–PCG

–Channel

Fig. 4-34: Result summary

Remote: CALC2:FEED "XTIM:CDP:ERR:SUMM"

Remote: CALC:MARK:FUNC:CDP:RES?

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.327 E-11

Global Results

Under Global Results,the measurement results that concern the total signal (that is, all

channels) for the entire period of observation (that is, all PCGs) are displayed:

–Carrier Frequency Error

Specifies the frequency error referred to the set center frequency of the R&S FSL. The absolute

frequency error is the sum of the frequency error of the R&S FSL and that of the device under

test. Frequency differences between the transmitter and receiver of more than 1.0 kHz impair

synchronization of the Code Domain Power measurement. If at all possible, the transmitter and

the receiver should be synchronized (refer to chapter "Advanced Measurement Examples").

The frequency error is available in the units both Hz and ppm referred to the carrier frequency.

The value of the Carrier Frequency Error in ppm is only displayed in full screen mode.

–Chip Rate Error

Specifies the chip rate error (1.2288 Mcps) in ppm. A large chip rate error results in symbol

errors and, consequently, possibly in the Code Domain Power measurement not being able to

perform synchronization. This measurement result is also valid if the R&S FSL could not

synchronize to the CDMA2000 signal.

–Trigger to Frame

Reflects the time offset from the beginning of the recorded signal section to the start of the first

PCG. In case of triggered data recording, this corresponds to the timing offset:

frame trigger (+ trigger offset) – start of first PCG

If it was not possible to synchronize the R&S FSL to the CDMA2000 signal, this measurement

result is meaningless. If the Free Run trigger mode is selected, dashes are displayed.

The Trigger to Frame value is only displayed in full screen mode.

–Active Channels

Specifies the number of active channels found in the signal. Detected data channels as well as

special channels are regarded as active. With transmit diversity, the result applies to the

selected antenna (refer to Antenna Diversity). No value is displayed in both the Min and Max

columns.

PCG

Under PCG,the measurement results that concern the total signal (that is, all channels) for the

selected power control group (Capture Length)are displayed:

–Total Power

Shows the total power of the signal.

–Pilot Power

Shows the power of the pilot channel. If antenna 2 is selected, the power of the F-TDPICH is

displayed, in all other cases that of the F-PICH (for details refer to Antenna Diversity).

The value for the Pilot Power is only displayed in full screen mode.

–RHO

Shows the quality parameter RHO. According to the CDMA2000 standard, RHO is the

normalized, correlated power between the measured and the ideally generated reference

signal. When RHO is measured, the CDMA2000 standard requires that only the pilot channel

be supplied.

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.328 E-11

–Composite EVM

The composite EVM is the difference between the test signal and the ideal reference signal

(refer to the Composite EVM softkey).

–IQ Imbalance / Offset

Shows the IQ imbalance and the DC offset of the signal in %.

The values for IQ Imbalance and IQ Offset are only displayed in full screen mode.

Channel

Under Channel,the measurement results of the selected channel and the selected PCG are

displayed:

–Power

Shows the channel power of the selected channel and PCG. The result depends on the

selected Code Power and the Power Reference)and absolute channel power.

–EVM

Shows the peak or mean value of the EVM measurement result (refer to the EVM vs Symbol

softkey).

The value of the EVM is only displayed in full screen mode.

–Modulation

Displays the modulation type of the channel and PCG: BPSK, QPSK, 8PSK, or 16QAM. No

values are displayed in the Min and Max columns.

–Timing Offset

Shows the timing offset between the selected channel and the pilot channel (enabled via the

Demod Settings softkey, Time/Phase Estimation).

The Timing Offset is only displayed in full screen mode.

–Phase Offset

Shows the phase offset between the selected channel and the pilot channel (enabled via the

Demod Settings softkey, Time/Phase Estimation).

The Phase Offset is only displayed in full screen mode.

Select Ch/PCG

This softkey allows to select a specific PCG (Power Control Group) and/ or channel for the

measurement. The key has three different states. Pressing the softkey once, opens a standard

dialog box in which the channel number can be entered. Pressing it for the second time, a

specific PCG can be entered. On the third hit, the softkey becomes unselected.

For details on the effects of the Select Ch/PCG softkey, refer to Channel (Code) Number and

Power Control Group

The following result displays take results for a PCG into account:

–Code Domain Power on page 4.323

–Code Domain Error on page 4.329

–Channel Table on page 4.324

–Power vs Symbol on page 4.333

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.329 E-11

–Composite Constell on page 4.333

–Result Summary on page 4.326

–Channel Bitstream on page 4.334

–Channel Constell on page 4.332

–EVM vs Symbol on page 4.332

The following result displays take results for a channel into account:

–Power vs PCG on page 4.325

–Power vs Symbol on page 4.333

–Result Summary on page 4.326

–Channel Bitstream on page 4.334

–Channel Constell on page 4.332

–EVM vs Symbol on page 4.332

Remote: CDP:SLOT 0 ...(IQ_CAPTURE_LENGTH–1) (PCG selection)

Remote: CDP:CODE 0...(BASE SF–1) (Channel and Code selection)

Code Domain Error

Selects the Code Domain Error Power (CDEP) result display.

This result display shows the difference in power between measured and ideally generated

reference signals for each code in dB. Since it is an error power, active and inactive channels

can be rated jointly at a glance. The total signal is taken into account over a single power control

group. The error power in the different codes is determined and plotted in a diagram. In this

diagram, the x–axis represents the channel (code) number, which corresponds to the base

spreading factor. The y–axis is a logarithmic level axis that shows the power of each channel. To

configure this result display, use the Result Settings dialog box (Settings softkey menu, Result

Settings softkey).

The Code Domain Error Power result display supports two sort orders, Hadamard and Bit-Reverse

(for details refer to Code Order).

Fig. 4-35: Code Domain Error Power (results shown in Hadamard code order)

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.330 E-11

Fig. 4-36: Code Domain Error Power (results for the same signal shown in Bit Reverse code order)

Active and inactive channels are defined via the Channel Table Settings dialog box (Settings

softkey menu, Channel Table Settings softkey). The power values of the active and inactive

channels take on different colors. In addition, codes with alias power can occur. These codes

obtain power components originating either from a spreading factor higher than the base

spreading factor or from the own and/or another antenna as a result of transmit diversity.

The following colors are defined:

–Red: selected channel (Channel (Code) Number)

–Yellow: active channel

– Cyan: inactive

–Light blue: alias power of higher spreading factor

–Magenta: alias power as a result of transmit diversity

Note: If codes with alias power are displayed, set the highest base spreading factor using the Base

SF.

It is not recommended to select more detailed result displays (such as Channel Constell)for

unassigned codes, since the results are not valid.

Remote: CALC1:FEED "XPOW:CDEP"

Composite EVM

Selects the result display of the error vector magnitude (EVM) over the total signal (modulation

accuracy).

In this result display, the square root is determined from the error square between the real and

imaginary parts of the test signal and an ideally generated reference signal (EVM referred to the

total signal).

The result display consists of a composite EVM measured value for each power control group

(PCG). You can set the number of PCGs by the Capture Length. Subsequently, the Composite

EVM result display takes the whole signal into account over the entire period of observation. The

selected PCG (Power Control Group)is marked in red.

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.331 E-11

Only the channels detected as being active are used to generate the ideal reference signal. If a

channel is not detected as being active, e.g. on account of low power, the difference between

the test signal and the reference signal and the composite EVM is therefore very large (see Fig.

4-37). Distortions also occur if unassigned codes are wrongly given the status of "active

channel". To obtain reliable measurement results, select an adequate channel threshold via the

Inactive Channel Threshold field.

Fig. 4-37: Composite EVM display for the case of all the channels contained in the signal being

detected as active.

Remote: CALC1:FEED "XTIM:CDP:MACC"

Peak Code Domain Error

Selects the Peak Code Domain Error result display.

In this result display, the error between the test signal and the ideally generated reference signal

is projected to the base spreading factor. The unit of the y–axis is dB. The base spreading factor

is selected by the Base SF.

The result display consists of the numeric value per PCG for the peak code domain error. You

can set the number of PCGs by the Capture Length.Subsequently, the Peak Code Domain

Error result display takes the whole signal into account over the entire period of observation. The

selected PCG (Power Control Group)is marked in red.

Only the channels detected as being active are used to generate the ideal reference signal. If a

channel is not detected as being active, e.g. on account of low power, the difference between

the test signal and the reference signal is very large. The result display therefore shows a peak

code domain error that is too high (see Fig. 4-38). Distortions also occur if unassigned codes are

wrongly given the status of "active channel". To obtain reliable measurement results, select an

adequate channel threshold via the Inactive Channel Threshold field.

Fig. 4-38: Peak code domain error for the case of all the channels contained in the signal being

detected as active

Remote: CALC:FEED "XTIM:CDP:ERR:PCD"

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.332 E-11

Channel Constell

Selects the Channel Constellation result display.

The measurement provides information about the channel constellation at symbol level. It shows

the constellation of the modulated signals of the selected channel and PCG (see Select

Ch/PCG). Supported modulation schemes are BPSK, QPSK, 8PSK and 16QAM. In CDMA2000

the modulation scheme depends on the channel type. Inactive channels can be measured, but

the result is meaningless since these channels do not contain data.

The BPSK constellation points are displayed on the x-axis, while the constellation points of

QPSK and 16QAM are located on neither axis.

Fig. 4-39: Channel constellation diagram

Remote: CALC:FEED "XTIM:CDP:SYMB:CONS"

EVM vs Symbol

Selects the Symbol Error Vector Magnitude result display.

The result display provides information on the EVM for the selected channel and the selected

PCGs on symbol level. The number of symbols is in the range from 6 to 384 and can be

calculated like this:

Number of symbols = Number of chips in one PCG / ChannelSF / K, with

Number of chips in one PCG = 1536

Channel SF = 4, 8, 16, 32, 64 or 128

K = 1 for Antenna Diversity = OFF

K = 2 for Antenna Diversity



OFF

This calculation thus takes into account the results of a channel for a power control group. The

result is given in %. Inactive channels can be measured, but the result is meaningless since

these channels do not contain data. To set the channel and the PCG, use the Select Ch/PCG

softkey.

Fig. 4-40: Error vector magnitude on symbol level

Remote: CALC2:FEED "XTIM:CDP:SYMB:EVM"

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.333 E-11

Composite Constell

Selects the Composite Constellation result display.

The measurement provides information about the constellation points at chip level. The total

signal is taken into account over the selected PCG. Therefore it is not possible to select a

specific channel number. For each of the 1536 chips, a constellation point is displayed in the

diagram.

Fig. 4-41: Composite constellation diagram

Remote: CALC:FEED "XTIM:CDP:COMP:CONS"

Power vs Symbol

Selects the Power versus Symbol result display.

In this result display, the absolute power in dBm at every symbol number is calculated for the

selected channel and the selected PCGs. This calculation thus takes into account the results of

achannel for a specific PCG. To set the channel and the PCG, use the Select Ch/PCG softkey.

Fig. 4-42: Power of a channel on symbol level

Remote: CALC:FEED "XTIM:CDP:PVSY"

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.334 E-11

Channel Bitstream

Selects the Bitstream result display.

The result display provides information on the demodulated bits for the selected channel and the

selected PCGs. This calculation thus takes into account the results of a channel for a specific

PCG. All bits that are part of inactive channels are marked as being invalid by means of dashes.

For 16QAM modulation '----' is displayed, for 8PSK modulation '---', for QPSK '--' and for BPSK '-

'. To set the channel and the PCG, use the Select Ch/PCG softkey.

Acertain symbol can be selected by using the MKR key. By enetering a number, the marker will

jump to the selected symbol. If there are more symbols than the screen is capable of displaying,

the marker can also be used to scroll inside the list.

Depending on the spreading factor (symbol rate) of the channel, a minimum of 12 and a

maximum of 384 symbols can be contained in a power control group. In case of an active

transmit diversity (Antenna Diversity)the values redeuce to the half. Depending on the

modulation type, a symbol consists of the following bits:

–BPSK: 1 bit (only the I–component is assigned)

–QPSK: 2 bits (I–component followed by the Q–component)

–8PSK: 3 bits

–16QAM: 4 bits

In accordance with the radio configuration and the channel type, there are BPSK and QPSK

modulated channels in the CDMA2000 system. For details refer to Relationship between

channel type and modulation type on page 4.305.

The order is shown in the following figure:

Fig. 4-43: Phasor diagram for QPSK, BPSK, 8PSK and 16QAM including bit values

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.335 E-11

Fig. 4-44: Demodulated bits of a channel for one PCG

Remote: CALC:FEED "XTIM:CDP:BSTR"

Adjust Ref Level

Adjusts the reference level to the measured channel power. This ensures that the settings of the

RF attenuation and reference level are optimally adjusted to the signal level without overloading

the R&S FSL or limiting the dynamic range by a too small S/N ratio.

Current measurements are aborted when pressing the softkey and resumed after the automatic

level detection is finished.

For further details refer also to the Adjust Ref Level softkey in the measurement menu of the

base unit.

Remote: CDP:LEV:ADJ

Softkeys of the frequency menu (CDMA2000 BTS Analyzer mode)

The following table shows all softkeys available in the frequency menu in CDMA2000 BTS Analyzer

mode. It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Command

Center

Start

Stop

CF-Stepsize 

Center

For details refer to the Center softkey in the frequency menu of the base unit.

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.336 E-11

Start

Opens an edit dialog box to define the start frequency. For further details refer to the Start

softkey in the frequency menu of the base unit.

Note that the softkey is unavailable for Code Domain and CCDF measurements.

Remote: FREQ:STAR 800 MHz

Stop

Opens an edit dialog box to define the stop frequency. For further details refer to the Stop

softkey in the frequency menu of the base unit.

Note that the softkey is unavailable for Code Domain and CCDF measurements.

Remote: FREQ:STOP 1.500 MHz

CF-Stepsize

For details including the submenu refer to the CF Stepsize softkey in the frequency menu of the

base unit.

Softkeys of the span menu (CDMA2000 BTS Analyzer mode)

The following table shows all softkeys available in the span menu in CDMA2000 BTS Analyzer mode.

It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

Note that the span menu is not available for code domain measurements and the signal power

measurement.

Command

Span Manual

Sweeptime Manual

Start

Stop

Full Span

Last Span

Span Manual

For details refer to the Span Manual softkey in the span menu of the base unit.

Sweeptime Manual

For details refer to the Sweeptime Manual softkey in the bandwidth menu of the base unit.

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.337 E-11

Start

For details refer to the Start softkey in the span menu of the base unit.

Stop

For details refer to the Stop softkey in the span menu of the base unit.

Full Span

For details refer to the Full Span softkey in the span menu of the base unit.

Last Span

For details refer to the Last Span softkey in the span menu of the base unit.

Softkeys of the amplitude menu (CDMA2000 BTS Analyzer mode)

The following table shows all softkeys available in the amplitude menu in CDMA2000 BTS Analyzer

mode. It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

Menu / Command Command

Ref Level

Adjust Ref Level

Ref Level Offset

Preamp On/Off

Scaling Auto Scale Once

y-Axis Maximum

y-Axis Minimum

RF Atten Manual

RF Atten Auto

Ref Level

For details refer to the Ref Level softkey in the amplitude menu of the base unit.

Adjust Ref Level

For details refer to the Adjust Ref Level softkey in the Code Domain Analyzer menu.

Ref Level Offset

For details refer to the Ref Level Offset softkey in the amplitude menu of the base unit.

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.338 E-11

Preamp On/Off

For details refer to the Preamp On/Off softkey in the amplitude menu of the base unit.

Note that this softkey is only available if the hardware option RF Preamplifier B22 is installed.

Scaling

Opens a submenu with the following softkeys:

Auto Scale Once

y-Axis Maximum

y-Axis Minimum

This submenu is only available for code domain measurements.

Auto Scale Once

Automatically scales the y-axis of the grid of the selected screen with respect to the measured

data.

The softkey is available for the following measurements: Code Domain Power, Code Domain

Error, Composite EVM. Peak Code Domain Error, Peak Code Domain Error vs PCG, Power vs

PCG, EVM vs Symbol and Power vs Symbol.

Remote: DISP:TRAC:Y:AUTO ONCE

y-Axis Maximum

Opens a dialog box to set the maximum value for the y-axis of the grid of the selected screen.

The softkey is available for the following measurements: Code Domain Power, Code Domain

Error, Composite EVM. Peak Code Domain Error, Peak Code Domain Error vs PCG, Power vs

PCG, EVM vs Symbol and Power vs Symbol.

Remote: DISP:TRAC:Y:MAX -40

y-Axis Minimum

Opens a dialog box to set the minimum value for the y-axis of the grid of the selected screen.

The softkey is available for the following measurements: Code Domain Power, Code Domain

Error, Composite EVM. Peak Code Domain Error, Peak Code Domain Error vs PCG, Power vs

PCG, EVM vs Symbol and Power vs Symbol.

Remote: :DISP:TRAC:Y:MIN 50

RF Atten Manual

For details refer to the RF Atten Manual softkey in the amplitude menu of the base unit.

RF Atten Auto

For details refer to the RF Atten Auto softkey in the amplitude menu of the base unit.

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.339 E-11

Softkeys of the bandwidth menu (CDMA2000 BTS Analyzer mode)

The following table shows all softkeys available in the bandwidth menu in CDMA2000 BTS Analyzer

mode. It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

Note that the softkeys of the bandwidth menu are not available for code domain measurements and are

inactive for the CCDF measurement.

Command

Res BW Manual

Res BW Auto

Video BW Manual

Video BW Auto

Sweeptime Manual

Sweeptime Auto

Filter Type

Res BW Manual

For details refer to the Res BW Manual softkey in the bandwidth menu of the base unit.

Res BW Auto

For details refer to the Res BW Auto softkey in the bandwidth menu of the base unit.

Video BW Manual

For details refer to the Video BW Manual softkey in the bandwidth menu of the base unit.

Video BW Auto

For details refer to the Video BW Auto softkey in the bandwidth menu of the base unit.

Sweeptime Manual

For details refer to the Sweeptime Manual softkey in the bandwidth menu of the base unit.

Sweeptime Auto

For details refer to the Sweeptime Auto softkey in the bandwidth menu of the base unit.

Filter Type

For details refer to the Filter Type softkey in the bandwidth menu of the base unit.

CDMA2000 BTS Analyzer (Option K82) R&S FSL

1300.2519.12 4.340 E-11

Softkeys of the sweep menu (CDMA2000 BTS Analyzer mode)

The following table shows all softkeys available in the sweep menu in CDMA2000 BTS Analyzer mode.

It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

Command

Continuous Sweep

Single Sweep

Continue Single Sweep

Sweeptime Manual

Sweeptime Auto

Sweep Count

Sweep Points

Continuous Sweep

For details refer to the Continuous Sweep softkey in the sweep menu of the base unit.

Single Sweep

For details refer to the Single Sweep softkey in the sweep menu of the base unit.

Continue Single Sweep

For details refer to the Continue Single Sweep softkey in the sweep menu of the base unit.

Sweeptime Manual

For details refer to the Sweeptime Manual softkey in the sweep menu of the base unit.

The softkey is not available for code domain and the CCDF measurements.

Sweeptime Auto

For details refer to the Sweeptime Auto softkey in the sweep menu of the base unit.

The softkey is not available for code domain and the CCDF measurements.

Sweep Count

For details refer to the Sweep Count softkey in the sweep menu of the base unit.

Sweep Points

For details refer to the Sweep Points softkey in the sweep menu of the base unit.

R&S FSL CDMA2000 BTS Analyzer (Option K82)

1300.2519.12 4.341 E-11

Softkeys of the trigger menu (CDMA2000 BTS Analyzer mode)

The following table shows all softkeys available in the trigger menu in CDMA2000 BTS Analyzer mode.

It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

Command

Trigger Source

Trigger Polarity Pos/Neg

Trigger Offset

Trigger Source

For details refer to the Trigger Source softkey of the IQ Capture Settings dialog box.

Trigger Polarity Pos/Neg

For details refer to the Trigger Polarity softkey of the IQ Capture Settings dialog box.

Trigger Offset

For details refer to the Trigger Offset softkey in the trigger menu of the base unit.

Softkeys of the trace menu (CDMA2000 BTS Analyzer mode)

The following table shows all softkeys available in the trace menu in CDMA2000 BTS Analyzer mode.

It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

Command

Trace Mode

Screen Focus A/B

Screen Size Full/Split

Scaling

Sweep Count

Trace Mode

Opens a dialog box, in which the trace mode can be selected. For details on the various trace

modes refer to the Trace mode overview on page 4.40.

Note that the Blank trace mode is not available for the code domain measurements. Also note

that the Trace Mode softkey is not available for the Result Summary measurement. This is

because in this measurement the minimum, mean and maximum values are already supported

(see Result Summary).

Remote: DISP:TRAC:MODE AVER

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Screen Focus A/B

For details refer to the Screen Focus A/B softkey in the Code Domain Analyzer root menu

(main menu).

Screen Size Full/Split

For details refer to the Screen Size Full/Split softkey in the Code Domain Analyzer root menu

(main menu).

Scaling

For details refer to the Scaling softkey in the amplitude menu.

Auto Scale Once (Scaling menu)

For details refer to the Auto Scale Once softkey in the amplitude menu.

y-Axis Maximum (Scaling menu)

For details refer to the y-Axis Maximum softkey in the amplitude menu.

y-Axis Minimum (Scaling menu)

For details refer to the y-Axis Minimum softkey in the amplitude menu.

Sweep Count

For details refer to the Sweep Count softkey in the sweep menu of the base unit.

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Softkeys of the marker menu (CDMA2000 BTS Analyzer mode)

The following table shows all softkeys available in the marker menu in CDMA2000 BTS Analyzer

mode. It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

The softkeys of the marker menu are not available for the Result Summary, Channel Table and CCDF

measurements.

Command

Marker 1

Marker 2

Marker 3

Marker 4

Marker Norm/Delta

All Marker Off

Percent Marker

Marker 1/Marker 2/Marker 3/Marker 4Marker Norm/Delta

The Marker <no> softkey activates the corresponding marker and opens an edit dialog box to

enter a value for the marker to be set to. Pressing the softkey again deactivates the selected

marker. If two screens are active in the Code Domain Analyzer, each of the screens has its own

set of markers.

Marker 1 is always the reference marker for relative measurements. If activated, markers 2 to 4

are delta markers that refer to marker 1. These markers can be converted into markers with

absolute value display by means of the Marker Norm/Delta softkey. If marker 1 is the active

marker, pressing the Marker Norm/Delta softkey switches on an additional delta marker.

For the Channel Bitstream measurement only one marker (Marker 1) is available. It can be used

for scrolling and to display the number and value of a bit.

Remote: CALC:MARK ON

Remote: CALC:MARK:X <value>

Remote: CALC:MARK:Y?

Remote: CALC:DELT ON

Remote: CALC:DELT:X <value>

Remote: CALC:DELT:X:REL?

Remote: CALC:DELT:Y?

All Marker Off

For details refer to the All Marker Off softkey in the marker menu of the base unit.

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Percent Marker

"Opens an edit dialog box to enter a probability value and to position marker 1. Thus, the power

which is exceeded with a given probability can be determined very easily. If marker 1 is

deactivated, it will be switched on automatically.

This softkey is only available for the CCDF measurement.

Remote: CALC:MARK:Y:PERC 0…100%

Softkeys of the marker–> menu (CDMA2000 BTS Analyzer mode)

The following table shows all softkeys available in the marker–> menu in CDMA2000 BTS Analyzer

mode. It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

The softkeys of the marker-> menu are not available for the Result Summary, Channel Table and

CCDF measurements.

Command

Select 1 2 3 4



Peak

Next Peak

Next Peak Mode < abs>

F-PICH

F-TDPICH

More 

Select 1 2 3 4



Min

Next Min

Next Min Mode < abs>

Select 1 2 3 4



Selects the normal marker or the delta markers, activates the marker and opens an edit dialog

box to enter a value for the marker to be set to.



stands for delta marker 1.

Since the Channel Bitstream measurements supports only one marker, this softkey is not

available for that measurement.

Remote: CALC:MARK1 ON

Remote: CALC:MARK1:X <value>

Remote: CALC:MARK1:Y?

Peak

For details refer to the Peak softkey in the MKR-> menu of the base unit.

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Next Peak

For details refer to the Next Peak softkey in the MKR-> menu of the base unit.

Next Peak Mode < abs>

For details refer to the Next Peak Mode < abs > softkey in the MKR-> menu of the base unit.

F-PICH

Sets the marker to the F-PICH channel. The softkey is only available if the x-axis of the active

screen is a code axis.

Remote: CALC:MARK:FUNC:PICH

F-TDPICH

Sets the marker to the F-TDPICH channel. The softkey is only available if the x-axis of the active

screen is a code axis.

Remote: CALC:MARK:FUNC:TDP

Min

For details refer to the Min softkey in the MKR-> menu of the base unit.

Next Min

For details refer to the Next Min softkey in the MKR-> menu of the base unit.

Next Min Mode < abs>

For details refer to the Next Min Mode < abs > softkey in the MKR-> menu of the base unit.

Softkeys of the measurement menu (CDMA2000 BTS Analyzer mode)

The following table shows all softkeys available in the measurement menu in CDMA2000 BTS

Analyzer mode. It is possible that your instrument configuration does not provide all softkeys. If a

softkey is only available with a special option, model or (measurement) mode, this information is

delivered in the corresponding softkey description.

Menu / Command Submenu / Command

Code Domain Analyzer 

Power

Adjacent Channel Power ACP Config 

Sweep Time

Fast ACP On/Off

ACP Abs/Rel

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Menu / Command Submenu / Command

Adjust Ref Level

Spectrum Emission Mask Edit Sweep List

List Evaluation

Edit Reference Range

Edit Power Classes

Bandclass

Load Standard

Save As Standard

Meas Start/Stop

Restore FSL K82 Files

Occupied Bandwidth %Power Bandwidth

Adjust Ref Level

Adjust Settings

CCDF Percent Marker

Res BW

#of Samples

Scaling

Adjust Settings

Code Domain Analyzer

AActivates the Code Domain Analyzer and opens the Code Domain Analyzer menu. Select the

desired result display via this menu. For details refer to Softkeys of the Code Domain Analyzer

menu (CDMA2000 BTS Analyzer mode) on page 4.307.

For details on the measurements in the code domain, initial configuration and screen layout refer

to the description of the Code Domain Analysis on page 4.298.

Remote: CONF:CDP:MEAS CDP

Power

Activates the Signal Channel Power measurement, in which the power of a single channel is

determined.

For details on screen layout and default values see the description of the Signal Channel Power

on page 4.300.

Remote: CONF:CDP:MEAS POW

Remote: CALC:MARK:FUNC:POW:RES? CPOW (result query)

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Adjacent Channel Power

Activates the Adjacent Channel Power measurement.

In this measurement the power of the carrier and its adjacent and alternate channels is determined.

For details on screen layout and default values see the description of the Adjacent Channel Power

on page 4.300.

Also opens the Adjacent Channel Power submenu containing the following softkeys:

Bandclass

ACP Config

Sweep Time

Fast ACP On/Off

ACP Abs/Rel

Adjust Ref Level

Remote: CONF:CDP:MEAS ACLR

Remote: CALC:MARK:FUNC:POW:RES? ACP (result query)

Bandclass (Adjacent Channel Power submenu)

softkey:Band Class (K82)"Opens a dialog box to select the bandclass. The following

bandclasses are available:

Band Class 0 800 MHz Cellular Band

Band Class 1 1.9 GHz PCS Band

Band Class 2 TACS Band

Band Class 3 JTACS Band

Band Class 4 Korean PCS Band

Band Class 5 450 MHz NMT Band

Band Class 6 2 GHz IMT-2000 Band

Band Class 7 700 MHz Band

Band Class 8 1800 MHz Band

Band Class 9 900 MHz Band

Band Class 10 Secondary 800 MHz

Band Class 11 400 MHz European PAMR Band

Band Class 12 800 MHz PAMR Band

Band Class 13 2.5 GHz IMT-2000 Extension Band

Band Class 14 US PCS 1.9 GHz Band

Band Class 15 AWS Band

Band Class 16 US 2.5 GHz Band

Band Class 17 US 2.5 GHz Forward Link Only Band

Remote: CONF:CDP:BCL <value>

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ACP Config (Adjacent Channel Power submenu)

For details on the softkey and submenus refer to the CP / ACP Config softkey in the Adjacent

Channel Power submenu of the base unit.

Sweep Time (Adjacent Channel Power submenu)

For details refer to the Sweep Time softkey in the Adjacent Channel Power submenu of the

base unit.

Fast ACP On/Off (Adjacent Channel Power submenu)

For details refer to the Fast ACP On/Off softkey in the Adjacent Channel Power submenu of the

base unit.

ACP Abs/Rel (Adjacent Channel Power submenu)

For details refer to the ACP Abs/Rel softkey in the Adjacent Channel Power submenu of the

base unit.

Adjust Ref Level (Adjacent Channel Power submenu)

For details refer to the Adjust Ref Level softkey in the Code Domain Analyzer menu.

Spectrum Emission Mask

Performs a comparison of the signal power in different carrier offset ranges with the maximum

values specified in the CDMA2000 specification. With the exception of a few softkeys this

measurement is identical to the Spectrum Emission Mask measurement of the base unit (refer to

Spectrum Emission Mask on page 4.104).

For details on screen layout and default values see the description of the Spectrum Emission

Mask on page 4.301.

Also opens the Spectrum Emission Mask submenu containing the following softkeys:

Edit Sweep List

List Evaluation

Edit Reference Range

Edit Power Classes

Bandclass

Load Standard

Save As Standard

Meas Start/Stop

Restore FSL K82 Files

Remote: CONF:CDP:MEAS ESP

Remote: CALC:LIM:FAIL?

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Edit Sweep List

For details on the Edit Sweep List softkey and its submenu refer to the Edit Sweep List softkey

in the Spectrum Emission Mask submenu of the base unit.

List Evaluation

For details on the List Evaluation softkey and its submenu refer to the List Evaluation softkey in

the Spectrum Emission Mask submenu of the base unit.

Edit Reference Range

Opens the Reference Range dialog box. For details refer to the Edit Reference Range softkey

in the Spectrum Emission Mask submenu of the base unit.

Edit Power Classes

Opens the Power Classes dialog box. For details refer to the Edit Power Classes softkey in the

Spectrum Emission Mask submenu of the base unit.

Bandclass

Opens a dialog box, to select a specific bandclass.

Alist of the supported bandclasses can be found in the description of the Bandclass softkey in

the ACP measurement menu.

The settings for each bandclass are provided in *.xml files that are located in the directory

C:\R_S\INSTR\sem_std\cdma2000\dl.The files themselves are named C2K_DL_BC01.XML

(bandclass 1) to C2K_DL_BC17.XML (bandclass 17). By selecting one of the bandclasses from

the dialog box, the correct file will be loaded automatically. The file can also be loaded manually

(see Load Standard softkey).

Remote: CONF:CDP:BCL <value>

Load Standard

Opens the Load Standard dialog box, in which the *.xml file to be imported can be selected. If a

file is imported, the SEM settings specified in the file will be used. All previous SEM settings will

be lost.

Remote: ESP:PRES "<file name>"

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Save As Standard

Opens the Save As Standard dialog box, in which the currently used SEM settings and

parameters can be saved and exported into an *.xml file. Enter the name of the file in the file

name field.

It is also possible to save the settings under one of the default bandclass file names (see

Bandclass softkey). When overwriting one of the default files, the customized settings will be

linked to the corresponding bandclass while the default settings are lost.

To restore the default bandclass settings press the Restore FSL K82 Files softkey.

Remote: ESP:STOR "<file name>"

Meas Start/Stop

For details on the Meas Start/Stop softkey refer to the Meas Start/Stop softkey in the Spectrum

Emission Mask submenu of the base unit.

Restore FSL K82 Files

"softkey:Restore FSL K82 Files (K82)"Restores all default files of the K82 option into the

C:\R_S\INSTR\SYSTEM_ROOT_RW\sem_std\cdma2000\dl directory. If changes have been

applied to the files, these will be lost.

Remote: ESP:PRES:REST

Occupied Bandwidth

Activates measurement of the bandwidth assigned to the signal.

For details on screen layout and default values see the description of the Occupied Bandwidth

on page 4.301.

Also opens the Occupied Bandwidth submenu containing the following softkeys:

%Power Bandwidth

Channel Bandwidth

Adjust Ref Level

Adjust Settings

Remote: CONF:CDP:MEAS OBAN

Remote: CALC:MARK:FUNC:POW:RES? OBAN (result query)

%Power Bandwidth

For details refer to the %Power Bandwidth softkey in the OBW submenu of the base unit.

Channel Bandwidth

For details refer to the Channel Bandwidth softkey in the ACP Config submenu of the base

unit.

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Adjust Ref Level

For details refer to the Adjust Ref Level softkey in the Code Domain Analyzer menu.

Adjust Settings

Automatically optimizes all instrument settings for the selected channel configuration (channel

bandwidth, channel spacing) within a specific frequency range (channel bandwidth). The

adjustment is carried out only once. If necessary, the instrument settings can be changed later.

Remote: POW:ACH:PRES OBW

CCDF

Starts the measurement of the Complementary Cumulative Distribution Function and the Crest

factor.

For details on screen layout and default values see the description of the Complementary

Cumulative Distribution Function on page 4.302.

Also opens the CCDF submenu containing the following softkeys:

Percent Marker

Res BW

#of Samples

Scaling

More 

Adjust Settings

Remote: CONF:CDP:MEAS CCDF

Percent Marker

For details refer to the Percent Marker softkey in the CCDF submenu of the base unit.

Res BW

For details refer to the Res BW softkey in the CCDF submenu of the base unit.

#of Samples

For details refer to the #of Samples softkey in the CCDF submenu of the base unit.

Scaling

For details refer to the Scaling softkey and the corresponding submenu in the CCDF submenu

of the base unit.

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Adjust Settings

Automatically optimizes all instrument settings for the selected channel configuration (channel

bandwidth, channel spacing) within a specific frequency range (channel bandwidth). The

adjustment is carried out only once. If necessary, the instrument settings can be changed later.

Remote: CALC:STAT:SCAL:AUTO ONCE

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Hadamard and BitReverse Code Tables

The following tables show the code sequences with Hadamard and BitReverse orders for the Code

Domain Power and Code Domain Error Power result displays.

As an example, the corresponding cells for channel 8.32 (channel number 8 for spreading factor 32) are

marked to show where the different codes of this channel are located.

Table 4-14: Code table for base spreading factor 64

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Table 4-15: Code table for base spreading factor 128 (part 1)

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Table 4-16: Code table for base spreading factor 128 (part 1)

1xEV-DO BTS Analyzer (Option K84) R&S FSL

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1xEV-DO BTS Analyzer (Option K84)

The R&S FSL equipped with the 1xEV-DO BTS Analyzer option performs Code Domain measurements

on forward link signals according to the 3GPP2 Standard (Third Generation Partnership Project 2) high

rate packet data. The standard, which was defined for packet-oriented data communications, is

generally referred to as 1xEV-DO (First EVolution Data Only).

This option is available from firmware version 2.00

To open the 1xEV-DO BTS Analyzer

If the 1xEV-DO BTS Analyzer mode is not the active measurement mode, press the MODE key

and activate the 1xEV-DO BTS Analyzer option.

If the 1xEV-DO BTS Analyzer mode is already active, press the MENU key.

The Code Domain Analyzer menu is displayed.

Further Information

–Measurements and result display

–Channel Type Characteristics

–Predefined Channel Tables

Menu and softkey description

–"Softkeys of the Code Domain Analyzer Menu (1xEV-DO BTS Analyzer mode)" on page 4.365

–"Softkeys of the frequency menu (1xEV-DO BTS Analyzer mode)" on page 4.390

–"Softkeys of the span menu (1xEV-DO BTS Analyzer mode)" on page 4.391

–"Softkeys of the amplitude menu (1xEV-DO BTS Analyzer mode)" on page 4.392

–"Softkeys of the bandwidth menu (1xEV-DO BTS Analyzer mode)"on page 4.394

–"Softkeys of the sweep menu (1xEV-DO BTS Analyzer mode)" on page 4.395

–"Softkeys of the trigger menu (1xEV-DO BTS Analyzer mode)" on page 4.396

–"Softkeys of the trace menu (1xEV-DO BTS Analyzer mode)" on page 4.396

–"Softkeys of the marker menu (1xEV-DO BTS Analyzer mode)" on page 4.397

–"Softkeys of the marker–> menu (1xEV-DO BTS Analyzer mode)" on page 4.399

–"Softkeys of the measurement menu (1xEV-DO BTS Analyzer mode)" on page 4.400

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Measurements and result display

The 1xEV-DO BTS Analyzer option provides the following test measurement types and result displays.

All measurements and result displays are accessed via the MEAS key (measurement menu).

–"Code Domain Analysis" on page 4.357

–"Signal Channel Power" on page 4.358

–"Adjacent Channel Power" on page 4.359

–"Spectrum Emission Mask" on page 4.360

–"Occupied Bandwidth" on page 4.360

–"Complementary Cumulative Distribution Function (CCDF)" on page 4.361

–"Power vs Time" on page 4.362

Code Domain Analysis

The Code Domain Analyzer performs measurements in the code domain. The following

measurement types and corresponding result displays are available:

Softkey Definition

Code Domain Power Code Domain Power result display

General Results General results in tabular form

Channel Results Results for a specific channel in tabular form

Power vs Chip Power of the selected channel versus all chips

Power vs Symbol Power of the selected channel and of the selected slot versus all symbols

Composite EVM Averaged error between the test signal and the ideal reference signal

Channel Table Channel occupancy table

Bitstream Display of decided bits

Peak Code Domain Error Projection of the maximum error between the test signal and the reference signal

Code Domain Error Code Domain Error Power result display

Symbol Constellation Symbol constellation result display

EVM vs Symbol Error Vector Magnitude result display

Composite Constellation Composite constellation result display

In the Code Domain Analyzer, the results are displayed in either one screen or in two screens (see

Screen Size Split/Full softkey). Any result can be displayed in either screen. On top of the

measurement screens the following settings and measurement results (so called result displays)

are displayed (with the respective default settings):

Frequency: 3.000 Ghz Ref. Level: -20.00 dBm Ref. Lvl Offset: 0.0 dB

Code Power: REL Count: 0 RF Attenuation: 0 dB

Slot: 0 of 3 Code: 0.32 Channel Type: PILOT

In the default setting after the preset, the analyzer is in Spectrum Analyzer mode (for details see

"Initializing the Configuration – PRESET Key"on page 4.3). The settings of the Code Domain

Analyzer are not active until the 1xEV-DO BTS Analyzer mode is activate (see "To open the 1xEV-

DO BTS Analyzer"on page 4.356)

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Parameter Setting

Digital standard 1xEV-DO, Revision 0

Sweep Continuous

Channel table Auto Search

Trigger source Free Run

Trigger offset 0 s

PN offset 0 chips

Inactive channel threshold -40 dB

Channel type PILOT

Code number 0

Slot 0

Capture length 3 slots

In order to provide a quick swap from the base unit to the 1xEV-DO BTS Analyzer option, some

parameters are passed on.

Transferred

parameter

Reference level

Ref Level Offset

Attenuation

Center Frequency

Frequency offset

Signal Channel Power

The Power measurement analyses the RF signal power of a single channel with 1.2288 MHz

bandwidth over a single trace. The displayed results are based on the root mean square.

The configuration is according to the 1xEV-DO0 requirements.

Beneath the measurement screen the bandwidth and the associated channel power are displayed.

The other screen elements match that of the screen of the Spectrum Analyzer mode.

The default settings are in accordance with the 3GPP2 specifications.

Setting Default value

Frequency Span 2 MHz

ACP Standard 1xEV-DO0 MC1

Number of adjacent channels 0

Adjacent Channel Power On

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In order to provide a quick swap from the base unit to the 1xEV-DO0 BTS Analyzer option, some

parameters are passed on.

Transferred parameter

Reference Level

Ref Level Offset

RBW

VBW

#of Samples

Refer also to the Power softkey in the measurement menu.

Adjacent Channel Power

The Adjacent Channel Power measurement analyses the power of the TX channel and the power of

adjacent and alternate channels on the left and right side of the TX channel. The number of TX

channels and adjacent channels can be modified as well as the band class.

Beneath the measurement screen the bandwidth and power of the TX channel and the bandwidth,

spacing and power of the adjacent and alternate channels are displayed.

The default settings are in accordance with the 3GPP2 specifications.

Setting Default value

Adjacent Channel Power On

ACP Standard 1xEV-DO0 MC1

Number of adjacent channels 2

In order to provide a quick swap from the base unit to the 1xEV-DO BTS Analyzer option, some

parameters are passed on.

Transferred parameter

Reference Level

Ref Level Offset

RBW

VBW

#of Adjacent Channels

Sweep Time

Span

Fast ACP Mode

For details on the softkeys of the Adjacent Channel Power measurement refer to the Adjacent

Channel Power softkey in the measurement menu.

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Spectrum Emission Mask

The Spectrum Emission Mask measurement shows the quality of the measured signal by

comparing the power values in the frequency range near the carrier against a spectral mask that is

defined by the 3GPP2 specifications. The limits depend on the selected bandclass. In this way, the

performance of the DUT can be tested and the emissions and their distance to the limit be

identified.

Note that the 3GPP2 standard does not distinguish between spurious and spectral emissions.

Beneath the measurement screen a table showing the peak list. In the peak list the values for the

worst spectral emissions are displayed including their frequency and power.

The default settings of the Spectrum Emission Mask measurement are listed in the table below.

Setting Default value

Frequency Span 8 MHz

Sweep Time 100 ms

Detector RMS

In order to provide a quick swap from the base unit to the 1xEV-DO BTS Analyzer option, some

parameters are passed on.

Transferred Parameter

Reference Level

Ref Level Offset

Center Frequency

Frequency Offset

Trigger settings

For details on the softkeys of the Spectrum Emission Mask measurement refer to the Spectrum

Emission Mask softkey in the measurement menu.

Occupied Bandwidth

The Occupied Bandwidth measurement determines the bandwidth in which the signal power can be

found. By default the bandwidth is displayed in which 99% of the signal is found. The percentage of

the signal power included in the measurement can be modified.

In the top right corner of the screen, the bandwidth and frequency markers are displayed.

The default settings of the Occupied Bandwidth measurement are listed in the table below.

Setting Default value

Occupied Bandwidth ON

Frequency Span 4.2 MHz

Sweep Time 100 ms

RBW 30 kHz

VBW 300 kHz

Detector RMS

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In order to provide a quick swap from the base unit to the 1xEV-DO BTS Analyzer option, some

parameters are passed on.

Transferred parameter

Reference Level

Ref Level Offset

RBW

VBW

Sweep Time

Span

For details on the softkeys of the Occupied Bandwidth measurement see Occupied Bandwidth in

the measurement menu.

Complementary Cumulative Distribution Function (CCDF)

The CCDF measurement displays the CCDF and the Crest factor. The CCDF shows distribution of

the signal amplitudes. For the measurement, a signal section of settable length is recorded

continuously in a zero span. The measurement is useful to determine errors of linear amplifiers.

The Crest factor is defined as the difference of the peak power and the mean power.

Beneath the measurement screen a table containing the number of included samples, mean and

peak power and the Crest factor is displayed.

The default settings of the CCDF measurement are listed in the table below.

Setting Default value

CCDF ON

RBW 10 MHz

Detector Sample

In order to provide a quick swap from the base unit to the 1xEV-DO BTS Analyzer option, some

parameters are passed on.

Transferred parameter

Reference Level

Ref Level Offset

RBW

#of Samples

For details on the softkeys of the CCDF measurement see CCDF in the measurement menu.

In a transition from the base unit to the 1xEV-DO BTS Analyzer option, external trigger sources are

preserved, all other trigger sources are switched to the Free Run trigger mode. Additional trigger

settings are preserved.

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Power vs Time

The Power vs Time measurement examines a specified number of half slots. Up to 36 half slots can

be captured and processed simultaneously. That means that for a standard measurement of 100

half slots only three data captures are necessary. After the capturing of the data theR&S FSL

averages the measured values and compares the results to the emission envelope mask. You can

define the emission envelope mask in the corresponding submenu.

Setting Default value

Frequency Span 0 (Zero Span)

Sweep Time 833.38 Ms

RBW 3 MHz

VBW 10 MHz

Detector RMS

Trace Mode Average

In order to provide a quick swap from the base unit to the 1xEV-DO0 BTS Analyzer option, some

parameters are passed on.

Transferred Parameter

Reference Level

Ref Level Offset

Center Frequency

Frequency Offset

Trigger settings

For details on the softkeys of the Power vs Time measurement see Power vs Time in the

measurement menu.

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

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Channel Type Characteristics

The following table shows the relationship between symbol rate, spreading factor, number of symbols,

number of bits, number of chips and the channel type.

Bits per Slot and Code Channel

Type

Spreading

Factor

Symbol Rate Modulation Type Chips per Slot Symbols per

Slot and Code

Mapping I or Q Mapping Complex

PILOT 32 38.4 ksps BPSK-I or BPSK-Q 96*2=192 6 6 12

MAC Rev. 0 64

Rev. A 128

19.2 ksps

9.6 ksps

BPSK-I or BPSK-Q 64*4=256 4

PREAMBLE

Rev. 0 32

Rev. A 64

38.4 ksps

19.2 ksps

BPSK-I or BPSK-Q

Preamble length

64:

128:

256:

512:

1024:

64:

128:

256:

512:

1024:

DATA 16 76.8 ksps QPSK, 8-PSK,

16QAM

Mapping always Complex

Modulation Type

400*4

-PreambleChips

=DataNettoChips

QPSK 8-PSK 16QAM

1600-0 = 1600

1600-64 = 1536

1600-128 = 1472

1600-256 = 1344

1600-512 = 1088

1600-1024=576

100

200

192

184

168

136

300

288

276

252

204

104

400

384

368

336

272

144

Predefined Channel Tables

Predefined channel tables offer access to a quick configuration for the channel search. The 1xEV-DO

BTS Analyzer option provides the following set of channel tables compliant with the 1xEV-DO

specification:

•DPQPSK:

Channel table with channel types PILOT/MAC/PREAMBLE/DATA with modulation type QPSK in

channel type DATA and the following listed active codes in channel types.

•DO8PSK:

Channel table with channel types PILOT/MAC/PREAMBLE/DATA with modulation type 8–PSK in

channel type DATA and the following listed active codes in channel types.

•DO16QAM:

Channel table with channel types PILOT/MAC/PREAMBLE/DATA with modulation type 16–QAM in

channel type DATA and the following listed active codes in channel types.

•DO_IDLE:

Channel table with channel types PILOT/MAC – known as IDLE slot, since it does not contain any

active channels in the DATA channel type.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.364 E-11

Tabelle 4-17: Base station channel table DOQPSK with QPSK modulation in DATA area

Channel Type Number of

Channels

Code Channel (Walsh

Code.SF)

Mosulation /

Mapping

Pilot 1 0.32 BPSK-I

Mac 5 2.64 (RA)

3.64

4.64

34.64

35.64

BPSK-I

BPSK-Q

Preamble (64 chips long) 1 3,32 BPSK-I

Data 16 0.16

1.16

2.16

...

13.16

14.16

15.16

QPSK

Tabelle 4-18: Base station channel table DO8PSK with 8-PSK modulation in DATA area

Channel Type Number of Channels Code Channel (Walsh

Code.SF)

Mosulation /

Mapping

Pilot 1 0.32 BPSK-I

Mac 5 2.64 (RA)

3.64

4.64

34.64

35.64

BPSK-I

BPSK-Q

Preamble (64 chips long) 1 3,32 BPSK-I

Data 16 0.16

1.16

2.16

...

13.16

14.16

15.16

8-PSK

Tabelle 4-19: Base station channel table DO16QAM with 16QAM modulation in DATA area

Channel Type Number of Channels Code Channel (Walsh

Code.SF)

Mosulation /

Mapping

Pilot 1 0.32 BPSK-I

Mac 5 2.64 (RA)

3.64

4.64

34.64

35.64

BPSK-I

BPSK-Q

Preamble (64 chips long) 1 3,32 BPSK-I

Data 16 0.16

1.16

2.16

...

13.16

14.16

15.16

16-QAM

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.365 E-11

Tabelle 4-20: Base station test model DO_IDLE for idle slot configuration

Channel Type Number of Channels Code Channel (Walsh

Code.SF)

Mosulation /

Mapping

Pilot 1 0.32 BPSK-I

Mac 5 2.64 (RA) BPSK-I

Softkeys of the Code Domain Analyzer Menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the main menu of the 1xEV-DO BTS Analyzer option

(MENU key). It is possible that your instrument configuration does not provide all softkeys. If a softkey is

only available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Menu / Command Menu / Command Command

Settings Settings Overview

Frontend Settings

IQ Capture Settings

Demod Settings

Channel Table Settings New Add Channel

Delete Channel

Meas

Sort

Save

Cancel

Reload

Copy Same as New

Delete

Edit Same as New

Restore Default Tables

Result Settings

Screen Focus A/B

Screen Size Split/Full

Select Meas

Chan Type

Select Code/Slot

Adjust Ref Level

1xEV-DO BTS Analyzer (Option K84) R&S FSL

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Settings

Opens a submenu to configure the Code Domain Analyzer result displays with the following

softkeys:

–Frontend Settings

–IQ Capture Settings

–Demod Settings

–Channel Table Settings

–Result Settings

Settings Overview

This softkey opens the Settings Overview dialog box that visualizes the data flow of the Code

Domain Analyzer and summarizes all of the current settings. In addition, the current settings can

be changed via the Settings Overview dialog box.

To change the settings, either use the rotary knob or the cursor keys to change the focus to any

other block or press one of the following softkeys:

–Frontend Settings

–IQ Capture Settings

–Demod Settings

–Channel Table Settings

–Result Settings

When using the rotary knob or the cursor keys, press the ENTER key to open the corresponding

dialog box. The Settings Overview dialog box always remains open while settings are modified.

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

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Frontend Settings

Opens the Frontend Settings dialog box and corresponding softkey submenu.

In the Frontend Settings dialog box, the following parameters can be modified:

Center

Ref Level

Ref Level Offset

RF Atten Manual

RF Atten Auto

Preamp On Off

Center

For details refer to the Center softkey in the frequency menu of the base unit.

Ref Level

For details refer to the Ref Level softkey in the amplitude menu of the base unit.

Ref Level Offset

For details refer to the Ref Level Offset softkey in the amplitude menu of the base unit.

RF Atten Manual

For details refer to the RF Atten Manual softkey in the amplitude menu of the base unit.

RF Atten Auto

For details refer to the RF Atten Auto softkey in the amplitude menu of the base unit.

Preamp On Off

For details refer to the Preamp On/Off softkey in the amplitude menu of the base unit.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

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IQ Capture Settings

Opens the IQ Capture Settings dialog box and corresponding softkey submenu.

In the IQ Capture Settings dialog box, the following parameters can be modified:

Capture Length

Swap IQ On Off

Trigger Source

Trigger Polarity

Trigger Offset

Capture Length

Enter the number of slots to be analyzed in the range from 2 to 12. The capture length is always

amultiple of the slot. The default setting is 3 slots.

Remote: CDP:IQL 12

Swap IQ On Off

To invert the sign of the Q-component of the signal activate the Swap IQ check box. The default

setting is OFF.

Remote: CDP:QINV ON

Trigger Source

Availbale trigger modes are Free Run and External. For more details on trigger modes refer to

"Trigger mode overview"on page 4.31. The default setting is Free Run.

Remote: TRIG:SOUR EXT

Trigger Polarity

Set the polarity of the trigger source. The sweep starts either after a positive or negative edge of

the trigger signal. The default setting is Positive.

Trigger Polarity available only for an External trigger source.

Remote: TRIG:SLOP POS

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.369 E-11

Trigger Offset

For details refer to the Trigger Offset softkey in the trigger menu of the base unit.

Demod Settings

Opens the Demod Settings dialog box and corresponding softkey submenu.

In the Demod dialog box, the following parameters can be modified:

Revision 0 A

Multi Carrier On Off

Time Phase Estimation On Off

PN Offset

Revision 0 A

Specifies the characteristics of the signal you want to analyze. Select whether to analyze a

signal of Revision 0 or Revision A. For details on the characteristics of the revisions of the 1xEV-

DO standard refer to Channel Type Characteristics.

In revision A the number of active users increases. That means that the spreading factor

(number of orthogonal codes) doubles for channel types MAC and PREAMBLE.

The amount of returned trace data in the MAC and PREAMBLE channels is different for

Revision 0 and A, depending on the channel type and selected evaluation (see table above).

The R&S FSL detects all the channels on a per slot basis. Therefore the R&S FSL recognizes

changes in the channel configuration and modulation over the recorded slots.

In revision A the following modulation types are added within some of the MAC channels:

–ON/OFF keying ACK on the I branch (OOKA-I),

–ON/OFF keying ACK on the Q branch (OOKA-Q),

–ON/OFF keying NACK on the I branch (OOKN-I) and the

–ON/OFF keying NACK on the Q branch (OOKN-Q)

1xEV-DO BTS Analyzer (Option K84) R&S FSL

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If the 2 bits within an ON/OFF keying modulation are identical, the modulation is not possible to

berecognized as an ON/OFF keying modulation. If both bits are containing ‘1’ information (ON)

the modulation is identical to a BPSK and will be recognized as BPSK. If both bits are containing

‘0’ information (OFF) there is no power within that code and slot and therefore no modulation is

detected. Is the evaluation set to MAPPING COMPLEX the separate I and Q branch detection

within the result summary is not any longer selected and the modulation type will be a 2BPSK

with the coding number 5 via remote.

Remote: CONF:CDP:REV 0

Multi Carrier On Off

Activates or deactivates the Multi Carrier mode. The mode improves the processing of multi

carrier signals. It allows the measurement on one carrier out of a multi carrier signal. This is

done by activating a low pass filter and by using a special algorithm for signal detection on multi

carrier signals.

Note that the low pass filter affects the measured signal quality (e.g. EVM and RHO) compared

to a measurement without a filter. The algorithm used for signal detection slightly increases the

calculation time.

The frequency response of the low pass filter is shown below.

00.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1

-70

-60

-50

-40

-30

-20

-10

Frequency response of low pass filter (Multi Carrier = On)

Frequency in MHz

|H(f)| in dB

Remote: CONF:CDP:MCAR ON

Time Phase Estimation On Off

Actives or deactivates the timing and phase offset calculation of the channels as to the pilot

channel. If deactivated or more than 50 active channels are in the signal, the calculation does

not take place and dashes instead of values are displayed as results.

Remote: CDP:TPM ON

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.371 E-11

PN Offset

Set the PN (Pseudo Noise) offset. The PN offset is used to distinguish the individual base

stations in a 1xEV-DO network.

The PN offset determines the offset in the circulating PN sequence in multiples of 64 chips with

reference to the event second clock trigger.

Although the parameter is always available, it only has a function in External trigger mode.

Remote: CDP:PNOF 512

Channel Table Settings

Opens the Demod Settings dialog box and corresponding softkey submenu. The dialog box

also displays the available predefined channel tables.

Predefined channel tables are a way to customize measurements. The RECENT channel table

contains the last configuration used before switching from Auto Search to Predefined. The

DO16QAM, DO8PSK, DO_IDLE and DOQPSK channel tables are included in the option per

default and are configured according to the standard. For details on the predefined channel

tables refer to Predefined Channel Tables on page 4.303. In addition, you can create new

channel tables to be used in measurements. For details refer to the New softkey.

In the Demod dialog box, the following parameters can be modified:

Channel Table

Inactive Channel Threshold

Available Channel Tables

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.372 E-11

The softkey menu contains the following softkeys:

New

Copy

Delete

Edit

Restore Default Tables

Channel Table

Define whether to use a predefined channel table or an automatically generated channel table in

the measurements.

Auto Search Searches the whole code domain (all permissible symbol rates and

channel numbers) for active channels.

The automatic search provides an overview of the channels contained in

the signal. If channels are not detected as being active, change the

threshold (see Inactive Channel Threshold)or select the Predefined

channel search type.

Predefined Performs the Code Domain Analyzer measurement on the basis of the

active predefined channel table (see Channel Table Name). All

channels of a channel table are assumed to be active. For details see

Predefined Channel Tables on page 4.303.

Remote: CONF:CDP:CTAB[:STAT] ON

Remote: CONF:CDP:CTAB:SEL "DOQPSK"

Inactive Channel Threshold

Defines the minimum power which a single channel must have compared to the total signal in

order to be regarded as an active channel Channels below the specified threshold are regarded

as "inactive". The parameter is only available in the Auto Search mode of the Channel Table

Settings dialog box. .

The default value is -40 dB. With this value all channels with signals such as the 1xEV-DO test

models are located by the Code Domain Power analysis. Decrease the Inactive Channel

Threshold value, if not all channels contained in the signal are detected.

Remote: CDP:ICTR -40

Available Channel Tables

This field shows the available channel tables. To activate a predefined channel table, select the

corresponding check box by using the cursor keys and pressing the ENTER key. The selected

channel table provides a basis for future measurements (until another is chosen or Auto Search

is activated).

Using the softkeys, customized channel tables can be defined or existing channel tables can be

modified.

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.373 E-11

New

Creates a new channel table name that can be seen in the dialog box from then on. The name

will be automatically set to 'ChannelTable'. By default, the resulting channel table is completely

empty (i.e. it contains no channel at all).

The submenu contains the following items:

Add Channel

Delete Channel

Meas

Sort

Save

Cancel

Reload

Remote: CONF:CDP:CTAB:NAME "NEW_TAB"

Add Channel

Inserts a new channel below the one selected. The default values for a new channel are:

ChannelType MAC

Walsh Ch.SF 2.64

SymbolRate 19.2 ksps (automatically calculated)

Modulation BPSK-I

Power 0 dB (automatically calculated)

State Off

DomainConflict No (automatically calculated)

To change the channel type use the dropdown menu that opens when selecting / highlighting

the Channel Type field that should be changed and pressing the ENTER key. The radio

configuration settings are changed in the same way.

To change the channel number type another channel number in the form

'ChannelNumber.SpreadingFactor' or simply the code number (see Select Code Slot for

details) in the respective field and confirm the change with the ENTER key.

To activate or deactivate a channel, simply select the field and confirm with the ENTER key.

The R&S FSL automatically checks for conflicts between two active channels.

Remote: CONF:CDP:CTAB:DATA "0…13, 2…7, 0…127, 0…30, 0, 0, 0 | 1"

Delete Channel

Deletes the selected channel without further notice.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.374 E-11

Meas

Initiates a measurement in Automatic Channel Search mode. The measurement results are

applied to the active channel table. The active channel table is overwritten without further notice.

The softkey is only available if the Auto Search mode is selected in the Channel Table

Settings dialog box.

Sort

Sorts the table according to the following rules.

First off, active channels are separated from inactive channels. Within these categories sorting is

then done first by the channel type and next by the spreading factor in ascending order. Last,

the sorting is done by the code number, also in ascending order.

Save

Saves the table under its specified name in the xml-format. If you edit a channel table and want

to keep the original channel table, change the name of the edited channel table before saving it.

Cancel

Closes the Edit dialog box and returns to the Channel Table Settings dialog box. Changes

applied to the channel table are lost.

Reload

Reloads the original content of the copied channel table.

Copy

Copies the selected table. All elements of the selected channel table are copied, except the

name which is set to 'Copy of <SourceChannelTableName>'.

The submenu is the same as that of the New softkey.

Remote: CONF:CDP:CTAB:COPY "CTAB2"

Delete

Deletes the selected channel table. The currently active channel table cannot be deleted.

Remote: CONF:CDP:CTAB:DEL "CTAB2"

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.375 E-11

Edit

Opens the Edit Channel Table dialog box and the corresponding softkey menu.

The dialog box contains the following items (grey fields can not be modified):

Item Description

Name Enter the name of the selected channel table, which will be

saved under <name>.xml. Note that the old channel table

file is not deleted. The name is case sensitive and may not

contain spaces. It must be a valid MS Windows file name.

Description Further information about the channel table can be entered

Channel Type Select one of the channel types from the dropdown menu

Walsh Ch.SF Enter the Channel Number (Ch) and Spreading Factor (SF).

For some channel types the possible values are limited or

preset (e.g. F-PICH, F-TDPICH and F-PDCH).

Symbol Rate/ksps Display of the symbol rate

RC The Radio Configuration (RC) can be customized for only

two channel types. For the F-PDCH the values can be

10(QPSK), 10(8PSK) and 10(16QAM). For CHAN channels

the Radio Configuration can either be 1-2 or 3-5.

Power/dB Contains the measured relative code domain power. The

unit is dB. The fields are filled with values after pressing the

Meas softkey.

State Indicates whether a channel is active or inactive

DomainConflict A red bullet is shown if there's a conflict of any sort between

two or more channels (e.g. two conflicting channel codes)

Changes are never saved automatically. For that reason every time a change is made, the text

'*(unsaved changes)' appears in the title bar.

The corresponding softkey menu contains the same items as the New softkey.

Remote: CONF:CDP:CTAB:NAME "NEW_TAB"

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.376 E-11

Restore Default Tables

Restores the predefined channel tables (see Predefined Channel Tables on page 4.303) to their

factory–set values. Existing channel tables with the same name as default channel tables are

replaced by this action. In this way, you can undo unintentional overwriting.

Remote: CONF:CDP:CTAB:REST

Result Settings

Opens the Result Settings dialog box.

The Result Settings dialog box contains the following parameters:

Select Code Slot

Channel Type

Mapping

Mapping Auto

Code Dom Overview

CDP Average

Code Power

Normalize

Select Code Slot

This softkey toggles between code selection and slot selection.

If the focus is on Code Selection, select a code number. Enter the code as a decimal. The range

depends on the specified channel type. For channel type PILOT and PREAMBLE values

between 0 and 31 are valid. For channel type MAC the range is between 0 and 63 and for DATA

only 63 is valid.

The following measurements take results for a Code into account: Power vs Symbol,Channel

Results,Bitstream,Symbol Constellation,EVM vs Symbol.In the following result displays, the

selcted code is highlighted in red:Code Domain Power, Channel Table, Code Domain Error.

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.377 E-11

If the focus is on Slot selection, select a slot. Enter the number as a decimal. The range of the

values is from 0 to (Capture Length -1). Refer to Capture Length for further details.

The following measurements take results for a Slot into account: Code Domain Power,Code

Domain Error,Channel Table,Power vs Chip,Power vs Symbol,Composite Constellation,

General Results,Channel Results,Bitstream,Symbol Constellation,EVM vs Symbol.In the

Composite EVM and Peak Code Domain Error the selected slot is highlighted in red.

Remote: CDP:CODE 0...(CAPTURE LENGTH -1)

Remote: CDP:CODE 0...31 | 63

Channel Type

Select one of the following channel types for the measurement:

Also opens a softkey submenu conatining the following items:

Pilot

MAC

Preamble

Data

For further details on the characteristics of the channel types refer to Channel Type

Characteristics on page 4.363.

Remote: CDP:CTYP PIL

Pilot

Selects the Pilot channel type.

Remote: CDP:CTYP PIL

MAC

Selects the MAC channel type.

Remote: CDP:CTYP MAC

Preamble

Selects the Preamble channel type.

Remote: CDP:CTYP PRE

Data

Selects the Data channel type.

Remote: CDP:CTYP DATA

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.378 E-11

Mapping

The mapping mode determines whether the complex signal, the I or the Q branch is analyzed in

the measurement.

Use manual mapping to obtain the option of examining any channel type as either a complex

signal or in the I and Q branch. This setting is valid for any channel type. Also refer to Mapping

Auto.

Remote: CDP:MMOD COMPL | I | Q

Mapping Auto

Automatically sets the type of mapping to be used in the measurement according to the

following table:

Channel type Mapping

Pilot I or Q

MAC I or Q

Preamble I or Q

Data Complex

Remote: CDP:MMOD AUTO

Code Dom Overview

Activate the Overview mode and screen A displays the I branch and screen B the Q branch of

the signal.

This softkey is only available for Code Domain Power and Code Domain Error Power

measurements. When active, the Mapping and Mapping Auto softkeys are not available.

Remote: CDP:OVER ON

CDP Average

Activate CDP average and the Code Domain Analysis is averaged over all slots. For channel

type Data and Preamble this calculation assumes that preambles of different length do not occur

in the slots. If active, ALL is displayed in the Slot field above the measurement screen.

This softkey is only available for Code Domain Analysis and is required by the 1xEV-DO

standard.

Remote: CDP:AVER ON

Code Power

Selects for the Code Domain Power measurement whether the y–values are displayed as an

absolute (dBm) or relative (dB). In Relative mode the reference is the total power of the channel

type.

Remote: CALC:FEED "XPOW:CDP"

Remote: CALC:FEED "XPOW:CDP:RAT"

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.379 E-11

Normalize

Eliminates the DC offset from the signal.

The default setting of the parameter is OFF.

Remote: CDP:NORM OFF

Screen Focus A/B

Sets the focus on the selected screen. Changes apply only to the focused screen. There are no

restrictions to the display of measurement results, i.e. you can display every result display in

either or both screens.

Remote: DISP:WIND1:SSEL

Screen Size Split/Full

Displays the result display in full screen size, or splits the screen to display two result displays.

To change settings in split screen display, set the focus on the designated result display via the

Screen Focus A/B softkey.

Remote: DISP:FORM SING

Select Meas

Opens a dialog box to select one of the measurements and result displays of the Code Domain

Analyzer:

–Code Domain Power

–General Results

–Channel Results

–Power vs Chip

–Power vs Symbol

–Composite EVM

–Channel Table

–Bitstream

–Peak Code Domain Error

–Code Domain Error

–Symbol Constellation

–EVM vs Symbol

–Composite Constellation

For details on screen layout and default settings refer to the measurement description of the

Measurements and result display.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

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Code Domain Power

Selects the Code Domain Power (CDP) result display. By default the display is set to relative

scaling.

In this result display, the total signal for one channel type is taken into account over a single slot.

The R&S FSL determines the power of the different codes and plots them in a diagram. In this

diagram, the x–axis represents the code. The y–axis is a logarithmic level axis that shows the

power of each code (either in absolute or relative values - see Code Power). To configure this

result display, use the Result Settings dialog box (Settings softkey menu, Result Settings

softkey).

The number of codes on the x axis depends on the channel type (see Channel Type). Select

the slot to be analyzed with Select Code Slot.

Activate CDP Average to perform a measurement over all slots. The CDP Average analysis is

required by the standard. In case of Data and Preamble channel types the standard assumes

that preambles of different lengths do not occur in the slots.

The power values of the assigned and unassigned codes are displayed in different colors:

–Yellow: assigned code

– Cyan: unassigned code

For details on the inactive channel threshhold refer to Inactive Channel Threshold.

Set the mapping with Mapping.There is also an auto mapping function available (see Mapping

Auto). It causes complex mapping to be analyzed separately for the Data channel type and

mapping for the I or Q branch to be analyzed separately for the other channel types. In the latter

case the I/Q selection can be set by means of the SELECT I/Q softkey. For a separate analysis

of the I and Q branch, activate Code Dom Overview mode. Screen A displays the I branch and

screen B the Q branch of the signal.

Another option for obtaining an overview of the CDP is to enable complex mapping (see

Mapping). The code domain power is then constantly displayed as a complex analysis on

screen A for the selected channel type.

In case of an analysis of the Data channel, the results of complex analysis are approximately 3

dB higher than the results of a separate I or Q analysis. This is because 50% of the power

values are distributed to I and Q, respectively, for the complex modulation types of the DATA

channel type.

Remote: CALC:FEED "XPOW:CDP:RAT"

Remote: CALC:FEED "XPOW:CDP"

Remote: CDP:OVER ON

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.381 E-11

General Results

Under General Results, the measurement results that concern the total signal or the entire

period of observation are displayed. The upper part of the result display shows the global

results, i.e. results for all channels:

–Carrier Frequency Error (absolute and relative)

Shows the frequency error referred to the center frequency. The absolute frequency error is the

sum of the frequency error of the analyzer and that of the device under test.

Differences of more than 4.0 kHz between transmitter and receiver frequency impair the

synchronization of the CDP measurement. If at all possible, the transmitter and the receiver

should be synchronized.

The unit of the frequency error is either Hz or ppm referred to the carrier frequency.

–Chip Rate Error

Shows the chip rate error (1.2288 Mcps) in ppm. A large chip rate error results in symbol errors

and, consequently, in possible synchronization errors for CDP measurements.

This measurement result is also valid if the analyzer was not able to synchronize onto the 1xEV–

DO signal.

–Trigger to Frame

This measurement result reproduces the timing offset from the beginning of the acquired signal

section until the start of the first slot. In case of triggered data acquisition, this corresponds to the

timing offset frame to trigger (+ trigger offset) until the start of the first slot. If the analyzer was

not able to synchronize onto the 1xEV–DO signal, the value of Trg to Frame is not meaningful.

For the Free Run trigger mode, dashes (–––) are displayed.

–RHO Pilot

Shows the quality parameter RHO for the pilot channel. According to the standard, RHO is

measured over all slots.

–RHO ov -1/2

Shows the quality parameter RHO for all chips and over all slots. According to the standard, the

averaging limit is on the half slot limit.

–RHO MAC

Shows the quality parameter RHO for the MAC channel

–RHO DATA

Shows the quality parameter RHO for the Data channel

The bottom part of General Results shows results specific to the selected slot:

–Power PILOT

Shows the absolute power of the Pilot channel in dBm.

–Power MAC

Shows the absolute power of the MAC channel in dBm.

–Power DATA

Shows the absolute power of the Pilot channel in dBm.

–Power PREAMBLE

Shows the absolute power of the Preamble channel in dBm.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

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–Composite EVM

The composite EVM value is the difference between the test signal and ideal reference signal

(also see Composite EVM).

–Max. Pwr DATA

Shows the maximum power of the Data channel. This is the highest value of the I- and Q-branch

of the Data channel.

–Min. Pwr. DATA

Shows the minimum power of the Data channel. This is the smallest value of the I- and Q-

branch of the Data channel.

–Data Mode Type

Shows the modulation type of the Data channel.

–Act. MAC Chs

Shows the number of active MAC channels.

–Act. DATA Chs

Shows the number of active Data channels.

–Preamble Length

Shows the length of the preamble in chips. If no preamble is present in the slot, this value is 0.

–RHO

Shows the quality parameter RHO calculated over a slot.

–Max. inact. Pwr MAC

Shows the maximum power of inactive MAC channels. This is the highest inactive channel from

the I- and Q-branch of the MAC channels.

Remote: CALC:FEED "XTIM:CDP:ERR:SUMM"

Remote: CALC:MARK:FUNC:POW:RES?

Channel Results

Under Channel Results, the measurement results that concern a specific channel are displayed.

The upper part of the result display shows common results for the selected channel:

–Power

Shows the total power of the selected channel type.

–IQ Imbalance

Shows the IQ imbalance of the signal in percent.

–Pk CDE (SF xx/IQ)

The Peak Code Domain Error measurement specifies a projection of the difference between test

signal and ideal reference signal to the spreading factor that belongs to the channel type. This

spreading factor is shown in brackets.

–IQ Offset

Shows the DC offset of the signal in percent.

The bottom part of the result display shows results specific to the selected channel type and the

selected slot:

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.383 E-11

–Symbol Rate

Shows the symbol rate with which the channel is transmitted.

–Channel.SF

Shows the code number and its associated spreading factor.

–Symbol EVM

Shows the peak and the mean values of the Error Vector Magnitude measurement (also see

EVM vs Symbol).

–Timing Offset

Shows the timing offset between the selected channel and the first active channel in the channel

type (also see Time Phase Estimation On Off).

–Phase Offset

Shows the phase offset between the selected channel and the first active channel in the channel

type (also see Time Phase Estimation On Off).

–Channel Pwr Rel

Shows the relative channel power (referred to the total power of the channel type).

–Channel Pwr Abs

Shows the absolute channel power (referred to the total power of the channel type).

–Modulation Type

Shows the modulation type of the channel.

Remote: CALC:FEED "XTIM:CDP:ERR:SUMM"

Remote: CALC:MARK:FUNC:POW:RES?

Power vs Chip

Selects the Power vs Chip result display.

This result display shows the chip powers for the selected slot. Thus, there are 2048 power

values in one trace. This analysis accordingly takes the total signal for the duration of one slot

into account.

Select the slot to be analyzed with Select Code Slot.

Due to the symmetric structure of the 1xEV-DO forward link signal, it is easy to identify which

channel types in the slot have power.

Remote: CALC2:FEED "XTIM:CDP:PVCH"

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.384 E-11

Power vs Symbol

Selects the Power versus Symbol result display.

This result display shows the power of each symbol for the selected code (see Select Code

Slot)and the Channel Type.

The result display shows the absolute power at each symbol time for a selected code of a

specific channel and the selected slot. It thus takes results of a code of the selected channel

type into account.

The number of symbols on the x axis is between 2 and 100.

Remote: CALC2:FEED "XTIM:CDP:PVSY"

Composite EVM

Selects the result display of the error vector magnitude (EVM) over the total signal (modulation

accuracy).

In this result display, the square root is determined from the error square between the real and

imaginary parts of the test signal and an ideally generated reference signal (EVM referred to the

total signal).

The result display consists of a composite EVM measured value for each slot. You can set the

number of slots by the Capture Length.Subsequently, the Composite EVM result display takes

the whole signal into account over the entire period of observation. The selected slot is marked

in red.

Only the channels detected as being active are used to generate the ideal reference signal. If a

channel is not detected as being active, e.g. on account of low power, the difference between

the test signal and the reference signal and the composite EVM is therefore very large.

Distortions also occur if unassigned codes are wrongly given the status of "active channel". To

obtain reliable measurement results, select an adequate channel threshold via the Inactive

Channel Threshold field.

Remote: CALC2:FEED "XTIM:CDP:MACC"

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.385 E-11

Channel Table

Selects the Channel Occupancy Table analysis.

In this result display all active channels are displayed. Therefore the channel table can contain

up to 146 entries: one entry for Pilot and Preamble channel each, 16 entries for the Data

channel and 128 entries for the MAC channel (64 on the I and Q branch respectively). The

Channel Table result display takes into account the total signal over one slot. Select the slot to

be analyzed in the Select Code Slot field.

The channels are listed in the following order: first the Pilot channel, then the MAC and

Preamble channels and the Data channel last. Within the channel types, the channels are sorted

by ascending code number.

The R&S FSL determines the following parameters for the channels:

–Channel Type

Shows the channel type of the active channel. Possible values are Pilot, MAC and Data. For the

Preamble channel, the length in chips is similarly specified, thus resulting in the following options

for the Preamble channel type: PRE64, PRE128, PRE256, PRE512 or PRE1024.

–CHAN.SF

Channel number including the spreading factor (in the form <Channel>.<SF>).

–Symb Rate

Symbol rate with which the channel is transmitted.

–Modulation / Mapping

Shows the modulation type of the channel. For Data channels possible values are QPSK, 8-PSK

and 16 QAM. For all other channel types possible values are either BPSK-I or BPSK-Q.

–Pwr Abs / Pwr Rel

Specification of the absolute and relative power (referred to the total power in the channel type)

of the channel.

–TOffs

Shows the timing offset between the current channel and the first active channel. It can be

enabled by means of Time Phase Estimation On Off.

–Ph Offs

Phase offset between this channel and the first active channel. It can be enabled by means of

Time Phase Estimation On Off.

Remote: CALC:FEED "XTIM:CDP:ERR:CTAB"

Bitstream

Selects the Bitstream result display.

The result display provides information on the demodulated bits for the selected channel type

and the selected code. It thus takes into account results of a code in the selected channel type

for one slot.

Depending on the symbol rate of the channel type, the number of chips of the channel type, and

the modulation type, a minimum of 4 and a maximum of 400 bits can be contained in a slot

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.386 E-11

Depending on the modulation type, a symbol consists of the following bits:

–BPSK: 1 bit (only the I or the Q component is assigned; in case of complex mapping a 2BPSK

modulation is displayed with both the I and Q components)

–QPSK: 2 bits (I–component followed by the Q–component)

–8PSK: 3 bits

–16QAM: 4 bits

Depending on the channel type, the following modulation types are available:

Pilot: BPSK-I

MAC: BPSK-I / BPSK-Q

Preamble: BPSK-I

Data: QPSK / 8-PSK / 16QAM

All bits that are part of unassigned codes are marked as being invalid by means of dashes. For

16QAM modulation '----' is displayed, for 8PSK modulation '---', for QPSK '--' and for BPSK '-'. To

set the channel and the slot, use the Select Code Slot softkey.

Acertain symbol can be selected by using the MKR key. By enetering a number, the marker will

jump to the selected symbol. If there are more symbols than the screen is capable of displaying,

the marker can also be used to scroll inside the list.

Remote: CALC:FEED "XTIM:CDP:BSTR"

Peak Code Domain Error

Selects the Peak Code Domain Error result display.

In this result display, the error between the test signal and the ideally generated reference signal

is projected to the base spreading factor. The unit of the y–axis is dB. You can not specify the

spreading factor; it is automatically set by the channel type.

The result display consists of the numeric value per slot for the peak code domain error. You

can set the number of slots in the Capture Length field. Subsequently, the Peak Code Domain

Error result display takes the whole signal (i.e. all channel types) into account over the entire

period of observation. The selected slot is marked in red.

Only the channels detected as being active are used to generate the ideal reference signal. If a

channel is not detected as being active, e.g. on account of low power, the difference between

the test signal and the reference signal is very large. The result display therefore shows a peak

code domain error that is too high for all slots. Distortions also occur if unassigned codes are

wrongly given the status of "active channel". To obtain reliable measurement results, select an

adequate channel threshold via the Inactive Channel Threshold field.

Remote: CALC:FEED "XTIM:CDP:ERR:PCD"

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.387 E-11

Code Domain Error

Selects the Code Domain Error Power (CDEP) result display.

This result display shows the difference in power between measured and ideally generated

reference signals for each code in dB. Since it is an error power, active and inactive channels

can be rated jointly at a glance. The total signal is taken into account over a single slot. The

error power is determined and plotted in a diagram. In this diagram, the x–axis represents the

code number, which depends on the channel type. The y–axis is a logarithmic level axis that

shows the power of each code. To configure this result display, use the Result Settings dialog

box (Settings softkey menu, Result Settings softkey).

The power values of the assigned and unassigned codes are displayed in different colors:

–Yellow: assigned code

– Cyan: unassigned code

Remote: CALC:FEED "XTIM:CDP"

Symbol Constellation

Selects the Symbol Constellation result display.

The measurement shows the constellation of the modulated signals of the selected code against

the channel type and slot (see Select Code Slot and Channel Type). Supported modulation

schemes are BPSK, QPSK, 8PSK and 16QAM. Unassigned codes can be measured, but the

result is meaningless since these do not contain data.

The BPSK constellation points are displayed on the x-axis, while the constellation points of

QPSK and 16QAM are located on neither axis.

Remote: CALC:FEED "XTIM:CDP:SYMB:CONS"

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.388 E-11

EVM vs Symbol

Selects the Symbol Error Vector Magnitude result display.

The result display provides information on the EVM for the selected channel type and the

selected code on symbol level. The number of symbols is in the range from 2 to 100.

Evaluation of the symbol error vector magnitude for unassigned codes is possible, but the

results are not valid.

Remote: CALC:FEED "XTIM:CDP:SYMB:EVM"

Composite Constellation

Selects the Composite Constellation result display.

The measurement provides information about the constellation points at chip level. The total

signal is taken into account over the selected slot. Therefore it is not possible to select a specific

code. For each chip, a constellation point is displayed in the diagram. The number of displayed

chip is dependent on the channel type and, in case of Preamble and Data channels, on the

length of the preamble. The number of chips lies between 64 and 1600 chips.

Remote: CALC:FEED "XTIM:CDP:COMP:CONS"

Chan Type

Opens submenu containing the following softkeys:

Command

Screen Focus A/B

Select Meas

Chan Type Pilot Mac

Chan Type Preamble Data

Code Dom Overview

Mapping Auto

Mapping Complex I Q

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.389 E-11

Screen Focus A/B

For details refer to Screen Focus A/B.

Select Meas

For details refer to Select Meas.

Chan Type Pilot Mac

Select either the Pilot or Mac channel type.

For further details on the characteristics of the channel types refer to Channel Type

Characteristics on page 4.363.

Remote: CDP:CTYP MAC | PIL

Chan Type Preamble Data

Select either the Preamble or Data channel type.

For further details on the characteristics of the channel types refer to Channel Type

Characteristics on page 4.363.

Remote: CDP:CTYP PRE | DATA

Code Dom Overview

For details refer to Code Dom Overview.

Mapping Auto

For details refer to Mapping Auto.

Mapping Complex I Q

For details refer to Mapping.

Select Code/Slot

For details refer to Select Code Slot.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.390 E-11

Adjust Ref Level

Adjusts the reference level to the measured channel power. This ensures that the settings of the

RF attenuation and reference level are optimally adjusted to the signal level without overloading

the R&S FSL or limiting the dynamic range by a too small S/N ratio.

Current measurements are aborted when pressing the softkey and resumed after the automatic

level detection is finished.

For further details refer also to the Adjust Ref Level softkey in the measurement menu of the

base unit.

Remote: CDP:LEV:ADJ

Softkeys of the frequency menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the frequency menu in 1xEV-DO BTS Analyzer

mode. It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Command

Center

Start

Stop

CF-Stepsize 

Center

For details refer to the Center softkey in the frequency menu of the base unit.

Start

Opens an edit dialog box to define the start frequency. For further details refer to the Start

softkey in the frequency menu of the base unit.

Note that the softkey is unavailable for Code Domain and CCDF measurements.

Remote: FREQ:STAR 800 MHz

Stop

Opens an edit dialog box to define the stop frequency. For further details refer to the Stop

softkey in the frequency menu of the base unit.

Note that the softkey is unavailable for Code Domain and CCDF measurements.

Remote: FREQ:STOP 1.500 MHz

CF-Stepsize

For details including the submenu refer to the CF Stepsize softkey in the frequency menu of the

base unit.

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.391 E-11

Softkeys of the span menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the span menu in 1xEV-DO BTS Analyzer mode. It

is possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or measurement mode, this information is delivered in the corresponding

softkey description.

Note that the span menu is not available for code domain measurements and the signal power

measurement.

Command

Span Manual

Sweeptime Manual

Start

Stop

Full Span

Last Span

Span Manual

For details refer to the Span Manual softkey in the span menu of the base unit.

Sweeptime Manual

For details refer to the Sweeptime Manual softkey in the bandwidth menu of the base unit.

Start

For details refer to the Start softkey in the span menu of the base unit.

Stop

For details refer to the Stop softkey in the span menu of the base unit.

Full Span

For details refer to the Full Span softkey in the span menu of the base unit.

Last Span

For details refer to the Last Span softkey in the span menu of the base unit.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.392 E-11

Softkeys of the amplitude menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the amplitude menu in 1xEV-DO BTS Analyzer

mode. It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

Menu / Command Command

Ref Level

Adjust Ref Level

Ref Level Offset

Preamp On/Off

Scaling Auto Scale Once

y-Axis Maximum

y-Axis Minimum

RF Atten Manual

RF Atten Auto

Ref Level

For details refer to the Ref Level softkey in the amplitude menu of the base unit.

Adjust Ref Level

For details refer to the Adjust Ref Level softkey in the Code Domain Analyzer menu.

Ref Level Offset

For details refer to the Ref Level Offset softkey in the amplitude menu of the base unit.

Preamp On/Off

For details refer to the Preamp On/Off softkey in the amplitude menu of the base unit.

Note that this softkey is only available if the hardware option RF Preamplifier B22 is installed.

Scaling

Opens a submenu with the following softkeys:

Auto Scale Once

y-Axis Maximum

y-Axis Minimum

This submenu is only available for code domain measurements.

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.393 E-11

Auto Scale Once

Automatically scales the y-axis of the grid of the selected screen with respect to the measured

data.

The softkey is available for the following measurements: Code Domain Power, Code Domain

Error, Composite EVM. Peak Code Domain Error, Peak Code Domain Error vs PCG, Power vs

PCG, EVM vs Symbol and Power vs Symbol.

Remote: DISP:TRAC:Y:AUTO ONCE

y-Axis Maximum

Opens a dialog box to set the maximum value for the y-axis of the grid of the selected screen.

The softkey is available for the following measurements: Code Domain Power, Code Domain

Error, Composite EVM. Peak Code Domain Error, Peak Code Domain Error vs PCG, Power vs

PCG, EVM vs Symbol and Power vs Symbol.

Remote: DISP:TRAC:Y:MAX -40

y-Axis Minimum

Opens a dialog box to set the minimum value for the y-axis of the grid of the selected screen.

The softkey is available for the following measurements: Code Domain Power, Code Domain

Error, Composite EVM. Peak Code Domain Error, Peak Code Domain Error vs PCG, Power vs

PCG, EVM vs Symbol and Power vs Symbol.

Remote: DISP:TRAC:Y:MIN 50

RF Atten Manual

For details refer to the RF Atten Manual softkey in the amplitude menu of the base unit.

RF Atten Auto

For details refer to the RF Atten Auto softkey in the amplitude menu of the base unit.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.394 E-11

Softkeys of the bandwidth menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the bandwidth menu in 1xEV-DO BTS Analyzer

mode. It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

Note that the softkeys of the bandwidth menu are not available for code domain measurements and are

inactive for the CCDF measurement.

Command

Res BW Manual

Res BW Auto

Video BW Manual

Video BW Auto

Sweeptime Manual

Sweeptime Auto

Filter Type

Res BW Manual

For details refer to the Res BW Manual softkey in the bandwidth menu of the base unit.

Res BW Auto

For details refer to the Res BW Auto softkey in the bandwidth menu of the base unit.

Video BW Manual

For details refer to the Video BW Manual softkey in the bandwidth menu of the base unit.

Video BW Auto

For details refer to the Video BW Auto softkey in the bandwidth menu of the base unit.

Sweeptime Manual

For details refer to the Sweeptime Manual softkey in the bandwidth menu of the base unit.

Sweeptime Auto

For details refer to the Sweeptime Auto softkey in the bandwidth menu of the base unit.

Filter Type

For details refer to the Filter Type softkey in the bandwidth menu of the base unit.

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.395 E-11

Softkeys of the sweep menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the sweep menu in 1xEV-DO BTS Analyzer mode. It

is possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or measurement mode, this information is delivered in the corresponding

softkey description.

Command

Continuous Sweep

Single Sweep

Sweeptime Manual

Sweeptime Auto

Sweep Count

Sweep Points

Continuous Sweep

For details refer to the Continuous Sweep softkey in the sweep menu of the base unit.

Single Sweep

For details refer to the Single Sweep softkey in the sweep menu of the base unit.

Continue Single Sweep

For details refer to the Continue Single Sweep softkey in the sweep menu of the base unit.

Sweeptime Manual

For details refer to the Sweeptime Manual softkey in the sweep menu of the base unit.

The softkey is not available for code domain and the CCDF measurements.

Sweeptime Auto

For details refer to the Sweeptime Auto softkey in the sweep menu of the base unit.

The softkey is not available for code domain and the CCDF measurements.

Sweep Count

For details refer to the Sweep Count softkey in the sweep menu of the base unit.

Sweep Points

For details refer to the Sweep Points softkey in the sweep menu of the base unit.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.396 E-11

Softkeys of the trigger menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the trigger menu in 1xEV-DO BTS Analyzer mode. It

is possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or measurement mode, this information is delivered in the corresponding

softkey description.

Command

Trigger Source

Trigger Polarity Pos/Neg

Trigger Offset

Trigger Source

For details refer to the Trigger Source softkey of the IQ Capture Settings dialog box.

Trigger Polarity Pos/Neg

For details refer to the Trigger Polarity softkey of the IQ Capture Settings dialog box.

Trigger Offset

For details refer to the Trigger Offset softkey in the trigger menu of the base unit.

Softkeys of the trace menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the trace menu in 1xEV-DO BTS Analyzer mode. It

is possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or measurement mode, this information is delivered in the corresponding

softkey description.

Command

Trace Mode

Screen Focus A/B

Screen Size Full/Split

Scaling Auto Scale Once

y-Axis Maximum

y-Axis Minimum

Sweep Count

Trace Mode

Opens a dialog box, in which the trace mode can be selected. For details on the various trace

modes refer to the Trace mode overview on page 4.40.

Note that the Blank trace mode is not available for the code domain measurements.

Remote: DISP:TRAC:MODE AVER

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.397 E-11

Screen Focus A/B

For details refer to the Screen Focus A/B softkey in the Code Domain Analyzer root menu.

Screen Size Full/Split

For details refer to the Screen Size Split/Full softkey in the Code Domain Analyzer root menu.

Scaling

For details refer to the Scaling softkey in the amplitude menu.

Auto Scale Once

For details refer to the Auto Scale Once softkey in the amplitude menu.

y-Axis Maximum

For details refer to the y-Axis Maximum softkey in the amplitude menu.

y-Axis Minimum

For details refer to the y-Axis Minimum softkey in the amplitude menu.

Sweep Count

For details refer to the Sweep Count softkey in the sweep menu of the base unit.

Softkeys of the marker menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the marker menu in 1xEV-DO BTS Analyzer mode.

It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

The softkeys of the marker menu are not available for the Result Summary, Channel Table and CCDF

measurements.

Command

Marker 1

Marker 2

Marker 3

Marker 4

Marker Norm/Delta

All Marker Off

Percent Marker

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.398 E-11

Marker 1/Marker 2/Marker 3/Marker 4/Marker Norm/Delta

The Marker <no> softkey activates the corresponding marker and opens an edit dialog box to

enter a value for the marker to be set to. Pressing the softkey again deactivates the selected

marker. If two screens are active in the Code Domain Analyzer, each of the screens has its own

set of markers.

Marker 1 is always the reference marker for relative measurements. If activated, markers 2 to 4

are delta markers that refer to marker 1. These markers can be converted into markers with

absolute value display by means of the Marker Norm/Delta softkey. If marker 1 is the active

marker, pressing the Marker Norm/Delta softkey switches on an additional delta marker.

For the Channel Bitstream measurement only one marker (Marker 1) is available. It can be used

for scrolling and to display the number and value of a bit.

Remote: CALC:MARK ON

Remote: CALC:MARK:X <value>

Remote: CALC:MARK:Y?

Remote: CALC:DELT ON

Remote: CALC:DELT:X <value>

Remote: CALC:DELT:X:REL?

Remote: CALC:DELT:Y?

All Marker Off

For details refer to the All Marker Off softkey in the marker menu of the base unit.

Percent Marker

"Opens an edit dialog box to enter a probability value and to position marker 1. Thus, the power

which is exceeded with a given probability can be determined very easily. If marker 1 is

deactivated, it will be switched on automatically.

This softkey is only available for the CCDF measurement.

Remote: CALC:MARK:Y:PERC 0…100%

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.399 E-11

Softkeys of the marker–> menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the marker–> menu in 1xEV-DO BTS Analyzer

mode. It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or measurement mode, this information is delivered in the

corresponding softkey description.

The softkeys of the marker-> menu are not available for the Result Summary, Channel Table and

CCDF measurements.

Command

Select 1 2 3 4



Peak

Next Peak

Next Peak Mode < abs>

Min

Next Min

Next Min Mode < abs>

Select 1 2 3 4



Selects the normal marker or the delta markers, activates the marker and opens an edit dialog

box to enter a value for the marker to be set to.



stands for delta marker 1.

Since the Channel Bitstream measurements supports only one marker, this softkey is not

available for that measurement.

Remote: CALC:MARK1 ON

Remote: CALC:MARK1:X <value>

Remote: CALC:MARK1:Y?

Peak

For details refer to the Peak softkey in the MKR-> menu of the base unit.

Next Peak

For details refer to the Next Peak softkey in the MKR-> menu of the base unit.

Next Peak Mode < abs>

For details refer to the Next Peak Mode < abs > softkey in the MKR-> menu of the base unit.

Min

For details refer to the Min softkey in the MKR-> menu of the base unit.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.400 E-11

Next Min

For details refer to the Next Min softkey in the MKR-> menu of the base unit.

Next Min Mode < abs>

For details refer to the Next Min Mode < abs > softkey in the MKR-> menu of the base unit.

Softkeys of the measurement menu (1xEV-DO BTS Analyzer mode)

The following table shows all softkeys available in the measurement menu in 1xEV-DO BTS Analyzer

mode. It is possible that your instrument configuration does not provide all softkeys. If a softkey is only

available with a special option, model or (measurement) mode, this information is delivered in the

corresponding softkey description.

Menu / Command Submenu / Command

Code Domain Analyzer

Power

Adjacent Channel Power Bandclass

ACP Config

Sweep Time

Fast ACP On/Off

ACP Abs/Rel

Adjust Ref Level

Spectrum Emission Mask Edit Sweep List

List Evaluation

Edit Reference Range

Edit Power Classes

Bandclass

XML Import

XML Export

Meas Start/Stop

Restore Default Files

Occupied Bandwidth %Power Bandwidth

Channel Bandwidth

Adjust Ref Level

Adjust Settings

CCDF Percent Marker

Res BW

#of Samples

Scaling

Adjust Settings

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.401 E-11

Code Domain Analyzer

AActivates the Code Domain Analyzer and opens the Code Domain Analyzer menu. Select the

desired result display via this menu. For details refer to Softkeys of the Code Domain Analyzer

Menu (1xEV-DO BTS Analyzer mode).

For details on the measurements in the code domain, initial configuration and screen layout refer

to the description of the Code Domain Analysis.

Remote: CONF:CDP:MEAS CDP

Power

Activates the Signal Channel Power measurement, in which the power of a single channel is

determined.

For details on screen layout and default values see the description of the Signal Channel Power.

Remote: CONF:CDP:MEAS POW

Remote: CALC:MARK:FUNC:POW:RES? CPOW (result query)

Adjacent Channel Power

Activates the Adjacent Channel Power measurement.

In this measurement the power of the carrier and its adjacent and alternate channels is determined.

For details on screen layout and default values see the description of the Adjacent Channel Power.

Also opens the Adjacent Channel Power submenu containing the following softkeys:

Command

Bandclass

ACP Config

Sweep Time

Fast ACP On/Off

ACP Abs/Rel

Adjust Ref Level

Remote: CONF:CDP:MEAS ACLR

Remote: CALC:MARK:FUNC:POW:RES? ACP (result query)

Bandclass

softkey:Band Class (K84)"Opens a dialog box to select the bandclass. The following

bandclasses are available:

Band Class 0 800 MHz Cellular Band

Band Class 1 1.9 GHz PCS Band

Band Class 2 TACS Band

Band Class 3 JTACS Band

Band Class 4 Korean PCS Band

Band Class 5 450 MHz NMT Band

Band Class 6 2 GHz IMT-2000 Band

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.402 E-11

Band Class 7 700 MHz Band

Band Class 8 1800 MHz Band

Band Class 9 900 MHz Band

Band Class 10 Secondary 800 MHz

Band Class 11 400 MHz European PAMR Band

Band Class 12 800 MHz PAMR Band

Band Class 13 2.5 GHz IMT-2000 Extension Band

Band Class 14 US PCS 1.9 GHz Band

Band Class 15 AWS Band

Band Class 16 US 2.5 GHz Band

Band Class 17 US 2.5 GHz Forward Link Only Band

Remote: CONF:CDP:BCL <value>

ACP Config

For details on the softkey and submenus refer to the CP / ACP Config softkey in the Adjacent

Channel Power submenu of the base unit.

Sweep Time

For details refer to the Sweep Time softkey in the Adjacent Channel Power submenu of the

base unit.

Fast ACP On/Off

For details refer to the Fast ACP On/Off softkey in the Adjacent Channel Power submenu of the

base unit.

ACP Abs/Rel

For details refer to the ACP Abs/Rel softkey in the Adjacent Channel Power submenu of the

base unit.

Adjust Ref Level

For details refer to the Adjust Ref Level softkey in the Code Domain Analyzer menu.

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.403 E-11

Spectrum Emission Mask

Performs a comparison of the signal power in different carrier offset ranges with the maximum

values specified in the 1xEV-DO specification. With the exception of a few softkeys this

measurement is identical to the Spectrum Emission Mask measurement of the base unit.

For details on screen layout and default values see the description of the Spectrum Emission

Mask.

Also opens the Spectrum Emission Mask submenu containing the following softkeys:

Edit Sweep List

List Evaluation

Edit Reference Range

Edit Power Classes

Bandclass

XML Import

XML Export

Meas Start/Stop

Restore Default Files

Remote: CONF:CDP:MEAS ESP

Remote: CALC:LIM:FAIL?

Edit Sweep List

For details on the Edit Sweep List softkey and its submenu refer to the Edit Sweep List softkey

in the Spectrum Emission Mask submenu of the base unit.

List Evaluation

For details on the List Evaluation softkey and its submenu refer to the List Evaluation softkey in

the Spectrum Emission Mask submenu of the base unit.

Edit Reference Range

Opens the Reference Range dialog box. For details refer to the Edit Reference Range softkey

in the Spectrum Emission Mask submenu of the base unit.

Edit Power Classes

Opens the Power Classes dialog box. For details refer to the Edit Power Classes softkey in the

Spectrum Emission Mask submenu of the base unit.

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.404 E-11

Bandclass

Opens a dialog box, to select a specific bandclass.

Alist of the supported bandclasses can be found in the description of the Bandclass softkey in

the ACP measurement menu.

The settings for each bandclass are provided in *.xml files that are located in the directory

C:\R_S\INSTR\sem_std\EVDO\dl.The files themselves are named C2K_DL_BC01.XML

(bandclass 1) to C2K_DL_BC17.XML (bandclass 17). By selecting one of the bandclasses from

the dialog box, the correct file will be loaded automatically. The file can also be loaded manually

(see XML Import softkey).

Remote: CONF:CDP:BCL <value>

XML Import

Opens the XML Import dialog box, in which the *.xml file to be imported can be selected. If a file

is imported, the SEM settings specified in the file will be used. All previous SEM settings will be

lost.

Remote: ESP:PRES "<file name>"

XML Export

Opens the XML Export dialog box, in which the currently used SEM settings and parameters

can be saved and exported into an *.xml file. Enter the name of the file in the file name field.

It is also possible to save the settings under one of the default bandclass file names (see

Bandclass softkey). When overwriting one of the default files, the customized settings will be

linked to the corresponding bandclass while the default settings are lost.

To restore the default bandclass settings press the Restore Default Files softkey.

Remote: ESP:STOR "<file name>"

Meas Start/Stop

For details on the Meas Start/Stop softkey refer to the Meas Start/Stop softkey in the Spectrum

Emission Mask submenu of the base unit.

Restore Default Files

"softkey:Restore FSL K84 Files (K84)"Restores all default files of the K84 option into the

C:\R_S\INSTR\sem_std\1EVDO\dl directory. If changes have been applied to the files, these will

be lost.

Remote: ESP:PRES:REST

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.405 E-11

Occupied Bandwidth

Activates measurement of the bandwidth assigned to the signal.

For details on screen layout and default values see the description of the Occupied Bandwidth.

Also opens the Occupied Bandwidth submenu containing the following softkeys:

%Power Bandwidth

Channel Bandwidth

Adjust Ref Level

Adjust Settings

Remote: CONF:CDP:MEAS OBAN

Remote: CALC:MARK:FUNC:POW:RES? OBAN (result query)

%Power Bandwidth

For details refer to the %Power Bandwidth softkey in the OBW submenu of the base unit.

Channel Bandwidth

For details refer to the Channel Bandwidth softkey in the ACP Config submenu of the base

unit.

Adjust Ref Level

For details refer to the Adjust Ref Level softkey in the Code Domain Analyzer menu.

Adjust Settings

Automatically optimizes all instrument settings for the selected channel configuration (channel

bandwidth, channel spacing) within a specific frequency range (channel bandwidth). The

adjustment is carried out only once. If necessary, the instrument settings can be changed later.

Remote: POW:ACH:PRES OBW

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.406 E-11

CCDF

Starts the measurement of the Complementary Cumulative Distribution Function and the Crest

factor.

For details on screen layout and default values see the description of the Complementary

Cumulative Distribution Function (CCDF).

Also opens the CCDF submenu containing the following softkeys:

Percent Marker

Res BW

#of Samples

Scaling

Adjust Settings

Percent Marker

Remote: CONF:CDP:MEAS CCDF

Percent Marker

For details refer to the Percent Marker softkey in the CCDF submenu of the base unit.

Res BW

For details refer to the Res BW softkey in the CCDF submenu of the base unit.

#of Samples

For details refer to the #of Samples softkey in the CCDF submenu of the base unit.

Scaling

For details refer to the Scaling softkey and the corresponding submenu in the CCDF submenu

of the base unit.

Adjust Settings

Automatically optimizes all instrument settings for the selected channel configuration (channel

bandwidth, channel spacing) within a specific frequency range (channel bandwidth). The

adjustment is carried out only once. If necessary, the instrument settings can be changed later.

Remote: CALC:STAT:SCAL:AUTO ONCE

R&S FSL 1xEV-DO BTS Analyzer (Option K84)

1300.2519.12 4.407 E-11

Power vs Time

Starts the measurement of the Power vs Time. This measurement is required by the standard

for the Emission Envelope Mask.

For details on screen layout and default values see the description of the Power vs Time.

Also opens the PvT submenu containing the following softkeys:

Command

No of HalfSlots

RF:Slot Full Idle

Burst Fit On Off

Reference Mean Pwr

Reference Manual

Set Mean To Manual

Restart On Fail

Restore STD Lines

Remote: CONF:CDP:MEAS PVT

No of HalfSlots

Change the number of halfslots for averaging. The default value is 100.

Remote: SWE:COUN <numeric value>

RF:Slot Full Idle

Defines the expected signal. Set it to either FULL or IDLE mode. The limit lines and the borders

for calculating the mean power are set. The lower and upper limit line are called DOPVTFL/

DOPVTFU for FULL and DOPVTIL/ DOPVTIU for IDLE mode. It is possible to change these

lines with the standard limit line editor.

Remote: CONF:CDP:RFS FULL

Burst Fit On Off

Activate an automatic burst alignment to the center of the diagram. If active the burst fit

algorithm searches the maximum and minimum gradient, between them the maximum peak is

determined, and from this point the 7 dB down points are searched. If these are within plausible

ranges the burst is centered in the screen, otherwise nothing will happen. The default setting is

OFF.

The softkey is only available if the RF:Slot is set to idle mode (see RF:Slot Full Idle).

Remote: CONF:CDP:PVT:BURS ON

1xEV-DO BTS Analyzer (Option K84) R&S FSL

1300.2519.12 4.408 E-11

Reference Mean Pwr

The standard asks for the sequence to first measure the FULL slot with the limit line relative to

the mean power of the averaged time response. Therefore you should activate the Reference

Mean Power for Full slot measurements.

In this mode the mean power is calculated and the limit lines are relative to that mean power.

This value should be used also as the reference for the IDLE slot measurement.

Remote: CALC:LIM:PVT:REF AUTO

Reference Manual

Select the reference value for the limits manually (also see Reference Mean Pwr and Set Mean

To Manual).

Remote: CALC:LIM:PVT:REF MANUAL

Remote: CALC:LIM:PVT:RVAL <numeric value>

Set Mean To Manual

Pressing the softkey leads to the usage of the current mean power value of the averaged time

response as the fixed reference value for the limit lines. The mode is switched to Reference

Manual. Now the IDLE slot can be selected and the measurement sequence can be finished.

(also see Reference Mean Pwr and Reference Manual).

Remote: CALC:LIM:PVT:REF ONCE

Restart On Fail

Evaluates the limit line over all results at the end of a single sweep. The sweep restarts if the

result is FAIL. On a PASS or MARGIN result, the sweep ends.

This softkey is only available in single sweep mode.

Remote: CONF:CDP:PVT:FRES ON

Restore STD Lines

Restores the limit lines defined in the standard to the state they were in when the device was

supplied. In this way unintended overwriting of the standard lines can be undone.

Remote: CALC:LIM:PVT:REST

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.409 E-11

WLAN TX Measurements (Option K91 / K91n)

The WLAN TX Measurements option extends the functionality of the R&S FSL spectrum analyzer to

enable Wireless LAN TX measurements according to IEEE standards 802.11 a, b, g, j and n.

TX measurement of wireless LAN Device Under Test (DUT) according to the standards specified for the

device can be performed:

•Modulation formats:

–IEEE 802.11a, j, g (OFDM): BPSK, QPSK, 16QAM, 64QAM

–IEEE 802.11b, g (single carrier): DBPSK, DQPSK, CCK (5.5 & 11 Mbps), PBCC (5.5, 11 & 22

Mbps)

–IEEE 802.11n (OFDM): BPSK (6.5 & 7.2 Mbps), QPSK (13, 14.4, 19.5 & 21.7 Mbps), 16QAM

(26, 28.9, 39 & 43.3 Mbps), 64QAM (52, 57.8, 58.5, 65 & 72.2 Mbps)

•Modulation measurements:

–Constellation diagram

–Constellation diagram per OFDM carrier

–I/Q offset and I/Q imbalance

–Carrier and symbol frequency errors

–Modulation error (EVM) per OFDM carrier or symbol

–Amplitude response and group–delay distortion (spectral flatness)

•Amplitude statistics (CCDF) and crest factor

•Transmit spectrum mask

•FFT, also over a selected part of the signal, e.g. preamble

•Payload bit information

•Capture time selectable up to 15 ms (dependent on selected standard), multiple sweeps possible

for large number of bursts (10922).

The option R&S FSL-K91 is available from firmware version 1.20.

The option R&S FSL-K91n is available from firmware version 1.90.

To open the WLAN menu

If the WLAN mode is not the active measurement mode, press the MODE key and activate the

WLAN option.

If the WLAN mode is already active, press the MENU or MEAS key.

The WLAN menu is displayed. .

To exit the WLAN measurement mode, select another option. For details refer also to section

"Measurement Mode Selection – MODE Key" on page 4.129.

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.410 E-11

Menu and softkey description

–"Softkeys of the WLAN menu" on page 4.414

–"Softkeys of the sweep menu (WLAN mode)" on page 4.436

–"Softkeys of the marker menu (WLAN mode)" on page 4.437

–"Softkeys of the marker–> menu (WLAN mode)" on page 4.438

–"Softkeys of the lines menu (WLAN mode)" on page 4.439

–"Softkeys of the trace menu (WLAN mode)" on page 4.439

The file, setup, and print menus are provided as described for the base unit. For details refer to the

corresponding menu descriptions. The span and bandwidth menus are not available in the WLAN

mode.

The FREQ,AMPT,and TRIG keys open the General Settings or the Demod Settings dialog box. For

details refer to the Settings General/Demod softkey description (WLAN menu).

To display help to a softkey, press the HELP key and then the softkey for which you want to display

help. To close the help window, press the ESC key. For further information refer to section "How to use

the Help System".

Further information topics

–"Measurements and result displays" on page 4.410

–"Rise / fall time measurement" on page 4.413

–"Title bar information" on page 4.414

–"Status bar information" on page 4.414

Measurements and result displays

The WLAN option provides two main measurement types:

•IQ measurements (based on captured IQ data)

–Power vs Time (see PVT softkey)

–EVM vs Symbol, EVM vs Carrier (see EVM vs Symbol/Carrier softkey)

–Phase vs Preamble, Frequency vs Preamble (see Error Frequency/Phase softkey)

–Spectrum Flatness (see Spectrum Flatness softkey)

–Spectrum FFT (see Spectrum FFT softkey)

–Constellation vs Symbol, Constellation vs Carrier (see Constell vs Symbol/Carrier softkey)

–Conditional Cumulative Distribution Function (see CCDF softkey)

–Bit Stream (see Bitstream softkey)

–Signal Field (see Signal Field softkey)

•frequency sweep measurements

–Spectrum mask (see Spectrum Mask or Spectrum IEEE/ETSI softkeys)

–Spectrum ACP/ACPR (see Spectrum ACPR or ACP Rel/Abs softkey)

The measurement result display is divided into two panes:

•Measurement settings

•Result displays

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.411 E-11

The results can be displayed in form of a list or a graph (see also Display List/Graph softkey).

–"Result summary list" on page 4.411

–"Result display graph" on page 4.412

Measurement settings

The overall measurement settings used to obtain the current measurement results are displayed below

the title bar (see Fig. 4-45). The following settings are listed:

Setting Description Restrictions

Frequency The frequency of the measured input signal.

Preamble Type The type of preamble of analyzed bursts.

Ref Level The reference level used for the input signal. IEEE 802.11b, g (Single Carrier)

only

Modulation Shows the active setting selected in the Demod Settings

dialog box: Demodulator or PSDU Modulation to Analyze.

External Att The attenuation (positive values) or gain (negative values)

applied to the signal externally (i.e. before the RF or IQ

connector of the spectrum analyzer), e.g.:

External Att = 10 dB means that before the RF connector of

the R&S FSL a 10 dB attenuator is used

External Att = –20 dB means that before the RF connector of

the R&S FSL a amplifier with 20 dB gain is used

PSDU Data Length Shows the minimum and maximum number of data bytes that

aburst may have if it is to be considered in results analysis.

IEEE 802.11b, g (Single Carrier)

only

Fig. 4-45 Measurement settings (example)

Result summary list

The result summary list shows the overall measurement results and provides limit checking for result

values in accordance with the selected standard. Result values which are within the limit as specified by

the standard are displayed in green. Result values which are outside of the limits specified by the

standard are displayed in red with a '*' to the left. Results which have no limits specified by the standard

are displayed in white. Limit values are displayed in white (not bold) and can be modified, if focused, via

the keypad. To reset the limit values to the values specified in the standard, use the lines menu (LINES

key).

The results displayed in this list are for the entire measurement. If a specific number of bursts have

been requested which requires more than one sweep, the result summary list is updated at the end of

each sweep. The number of bursts measured and the number of bursts requested are displayed to

show the progress through the measurement. The Min / Mean / Max columns show the minimum, mean

or maximum values of the burst results.

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.412 E-11

Fig. 4-46 Result summary list (example)

Result display graph

Additionally to the selected graphical result display, the Magnitude Capture Buffer display is provided

for all IQ measurements. The different result displays are described with the corresponding softkey.

The Magnitude Capture Buffer display shows the complete range of captured data for the last sweep.

All analyzed bursts are identified with a green bar at the bottom of the Magnitude Capture Buffer

display. If, in the Demod Settings dialog box, the Signal Field Content option is activated only bursts

that match the required criteria are marked with a green bar.

Fig. 4-47 Magnitude capture buffer results (example)

•IQ measurements

All IQ measurements process the same signal data and as such all IQ measurement results are

available after a single IQ measurement execution.

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.413 E-11

IQ measurements can be run in split screen mode (allowing both the Magnitude Capture Buffer

display and the selected IQ measurement results to be displayed simultaneously) or in full screen

mode (with either the Magnitude Capture Buffer display or the selected IQ measurement results

displayed).

•frequency sweep measurements

The frequency sweep measurements use different signal data to IQ measurements and as such it is

not possible to run an IQ measurement and then view the results in the frequency sweep

measurements and vice–versa. Also because each of the frequency sweep measurements uses

different settings to obtain signal data it is not possible to run a frequency sweep measurement and

view the results of another frequency sweep measurement.

All frequency sweep measurements are run in full screen mode.

Further information

This section provides background information on measurements and displayed information. For details

on signal processing refer to chapter "Advanced Measurement Examples", section "Measurement

Examples of the WLAN TX Measurements Option (K91/K91n)".

Rise / fall time measurement

The rise/fall time is calculated according to the following algorithm:

•Apply a moving average filter over the burst power (adjustable average length)

•If Ref Pow Max is set: Search maximum power Pmax over the whole burst. Set Pref=Pmax

•If Ref Pow Mean is set: Calculate mean power Pmean of the whole burst. Set Pref=Pmean

•Rise time

–Search the first crossing of 0.5xPref from the left.

–Search backwards for the 10% crossing 0.1xPref and note t10.

–Search forward for the 90% crossing 0.9xPref and note t90.

–Return Trise=t90–t10.

•Fall time

–Search the first crossing of 0.5xPref from the right.

–search forwards for the 10% crossing 0.1xPref and note t10.

–search backwards for the 90% crossing 0.9xPref and note t90.

–Return Tfall=t10–t90.

Since the single carrier modes of 802.11b, g use linear modulation formats like BPSK or QPSK, the

transmit signal power varies between symbol sampling times. These power variations are determined

by the transmit filter, which is not defined in the standard. The R&S FSL–K91 allows fine tuning of the

PVT measurements on signals with high crest factors by an adjustable moving average filter and two

different reference power settings.

The reference power equals the 100% setting for the rise / fall time calculation. Either the maximum

burst power or the mean burst power can be chosen as reference power. Using the mean burst power,

rarely power peaks within the burst does not influence the rise / fall time measurement.

The moving average filter smoothes the power trace and thus eliminates the modulation. While a long

average length leads to more stable measurement results, it naturally increases the rise / fall times

compared to no averaging.

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.414 E-11

Title bar information

The title bar displays the following information:

•wireless LAN standard applicable to the current measurement (in the middle)

Status bar information

The status bar displays the following information:

•parameter values

If a parameter in a settings dialog box is selected, the minimum and maximum values for the

selected parameter are displayed.

If a Boolean parameter in a dialog box is selected, the minimum and maximum values are displayed

as N/A for not applicable.

•measurement status

During the measurement, the current measurement status along with detailed information about the

progress is displayed.

•error messages (with red background)

•warning messages (with yellow background)

Softkeys of the WLAN menu

The following table shows all softkeys available in the WLAN menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Command

Settings General/Demod

Display List/Graph

PVT Settings General/Demod

Display List/Graph

Full Burst

Rising & Falling

Ramp Up/Down/Up & Down

Ref Pow Max/Mean

Average Length

More 

Gating Settings On/Off

Import

Export

R&S Support

EVM Constell Settings General/Demod

Display List/Graph

EVM vs Symbol/Carrier

Error Frequency/Phase

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.415 E-11

Menu / Command Command

Constell vs Symbol/Carrier

Carrier Selection

More 

Gating Settings On/Off

Import

Export

Y–Axis/Div

R&S Support

Spectrum Settings General/Demod

Display List/Graph

Spectrum Flatness

Spectrum Mask / Spectrum IEEE/ETSI

Spectrum FFT

Spectrum ACPR / Spectrum ACP / ACP Rel/Abs

More 

same contents as PVT side menu

Statistics Settings General/Demod

Display List/Graph

CCDF

Bitstream

Signal Field / PLCP Header

More 

same contents as PVT side menu

Settings General/Demod

Opens the General Settings or the Demod Settings dialog box. Screenshots of the dialog

boxes are provided in chapter "Advanced Measurement Examples", section "Measurement

Examples of the WLAN TX Measurements Option (K91/K91n)".

Alternatively, the General Settings dialog box is opened as follows:

–FREQ key, with focus on the Frequency field

–AMPT key, with focus on the Signal Level (RF) field

–TRIG key, with focus on the Trigger Mode field

In the General Settings dialog box, all settings related to the overall measurement can be

modified. The right pane with the advanced settings is only displayed if the Advanced Settings

option is activated. The General Settings dialog box contains the following elements:

Signal Characteristics Standard

Frequency

Channel No

Level Settings Signal Level

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.416 E-11

Auto Lvl

Ext Att

Data Capture Settings Capture Time

Burst Count

Analyze Bursts

Sweep Count

Trigger Settings Trigger Mode

Trigger Offset

Power Level

Auto Lvl

IQ Settings Swap IQ

Advanced Settings Auto Level Time

Ref Level

Attenuation

Sample Rate

In the Demod Settings dialog box, the settings associated with the signal modulation can be

modified. The settings under Burst to Analyze specify the characteristics of the bursts to be

considered in the measurement results. Only the bursts which meet the criteria specified in this

group will be included in measurement analysis if the Use Header Content option is activated.

The tracking settings allow various errors in measurement results to be compensated for.

The Demod Settings dialog box contains the following elements. If an element is only available

for certain standards, the corresponding standards are listed.

Burst to Analyze Signal Field Content

Use Header Content

Burst Type

Preamble Type

Auto Demodulation

Analyze PSDU Mod

Demodulator

Auto Guard

Guard Interval

PPDU Frame Format

Equal Burst Length

Data Symbols

Min Data Symbols

Max Data Symbols

Channel Estimation

Payload Length

Min Payload Length

Max Payload Length

Tracking Phase

Timing

Level

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.417 E-11

Standard (General Settings dialog box)

Displays a list of all installed standards to select the wireless LAN standard. This is necessary to

ensure that the measurements are performed according to the specified standard with the

correct limit values and limit lines.

Remote: CONF:STAN 0

Frequency (General Settings dialog box)

Specifies the center frequency of the signal to be measured. If the frequency is modified, the

Channel No field is updated accordingly.

Remote: FREQ:CENT 100MHz

Channel No (General Settings dialog box)

Specifies the channel to be measured. If the Channel No field is modified, the frequency is

updated accordingly.

Remote: CONF:CHAN 9

Signal Level (General Settings dialog box)

Specifies the expected mean level of the RF input signal. If an automatic level detection

measurement has been executed the signal level (RF) is updated.

For all standards other than IEEE 802.11b & g (Single Carrier), the reference level is set 10 dB

higher than the signal level (RF) because of the expected crest factor of the signal. For

standards IEEE 802.11b & g (Single Carrier), the reference level is set to the signal level (RF).

Remote: CONF:POW:EXP:RF 9

Auto Lvl (General Settings dialog box)

Activates or deactivates the automatic setting of the reference level for measurements.

On The reference level is measured automatically at the start of each measurement

sweep. This ensures that the reference level is always set at the optimal level for

obtaining accurate results but will result in slightly increased measurement times. For

details about automatic level detection refer to chapter "Advanced Measurement

Examples".

Off The reference level is defined manually in the Signal Level field.

Remote: CONF:POW:AUTO 1

Remote: CONF:POW:AUTO:SWE:TIME 200MS

Ext Att (General Settings dialog box)

Specifies the external attenuation or gain applied to the RF signal. A positive value indicates

attenuation, a negative value indicates gain. All displayed power level values are shifted by this

value.

Remote: INP:ATT 30dB

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.418 E-11

Capture Time (General Settings dialog box)

Specifies the time (and therefore the amount of data) to be captured in a single measurement

sweep.

Remote: SWE:TIME 10ms

Burst Count (General Settings dialog box)

Activates or deactivates a specified number of bursts for capture and analysis.

On The data analysis is performed over a number of consecutive sweeps until the

required number of bursts has been captured and analyzed.

Off The data analysis is performed on a single measurement sweep.

Remote: BURS:COUN:STAT ON

Analyze Bursts (General Settings dialog box)

Specifies the number of bursts to be measured, if the Burst Count option is activated.

Remote: BURS:COUN 16

Sweep Count (General Settings dialog box)

Specifies the number of sweeps to be performed for Spectrum ACP/ACPR and Spectrum Mask

measurements.

Remote: SWEep:COUNt 64

Trigger Mode (General Settings dialog box)

Sets the source of the trigger for the measurement sweep.

Free Run The measurement sweep starts immediately.

External Triggering via a TTL signal at the input connector EXT TRIGGER/GATE

IN on the rear panel.

Power The measurement sweep starts when the signal power meets or exceeds

the specified power trigger level. This trigger mode is not available for

Spectrum Mask measurements in ETSI standard. If it is set and then the

Spectrum Mask measurement in ETSI standard is selected, it automatically

changes to Free Run.

Remote: TRIG:MODE IMM

Trigger Offset (General Settings dialog box)

Specifies the time offset between the trigger signal and the start of the sweep. A negative value

indicates a pre–trigger. This field is not available in the Free Run trigger mode.

Remote: TRIG:HOLD 500us

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.419 E-11

Power Level (General Settings dialog box)

Specifies the trigger level if the Power trigger mode is set.

Remote: TRIG:LEV:POW 10 DBM

Auto Lvl (General Settings dialog box)

Activates or deactivates the automatic measurement of the power trigger level.

On The power trigger level is measured automatically at the start of each measurement

sweep. This ensures that the power trigger level is always set at the optimal level for

obtaining accurate results but will result in a slightly increased measurement times.

Off The power trigger level is defined manually in the Power Level field.

Remote: TRIG:LEV:POW:AUTO ON

Swap IQ (General Settings dialog box)

Activates or deactivates the inverted I/Q modulation.

On I and Q signals are interchanged.

Off Normal I/Q modulation.

Remote: SWAP ON

Auto Level Time (General Settings dialog box)

Specifies the sweep time used for the automatic level measurements.

Remote: CONF:POW:AUTO:SWE:TIME 200MS

Ref Level (General Settings dialog box)

Specifies the reference level to use for measurements. If the reference level is modified, the

signal level is updated accordingly (depending on the currently selected standard and

measurement type). This field is only editable if the Auto Lvl is deactivated.

Remote: DISP:TRAC:Y:RLEV?

Attenuation (General Settings dialog box)

Specifies the settings for the attenuator. This field is only editable if the Auto Lvl option is

deactivated. If the Auto Lvl option is activated, the RF attenuator setting is coupled to the

reference level setting.

Remote: INP:ATT 30dB

Sample Rate (General Settings dialog box)

Specifies the sample rate used for IQ measurements.

Remote: TRACE:IQ:SRAT 20000

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.420 E-11

Signal Field Content (Demod Settings dialog box, IEEE 802.11a, g (OFDM), j and n)

Activates or deactivates the decoding of the captured burst data.

On Only the bursts are included in the results analysis whose modulation format specified

in the signal symbol field matches the modulation format specified in the Analyze

PSDU Mod field.

Off The data is demodulated according to the modulation scheme specified in the

Demodulator field. If any of the analyzed data has a modulation different to that

specified the results will be of limited use.

Remote: DEM:FORM:SIGS ON

Use Header Content (Demod Settings dialog box, IEEE 802.11b, g – Single Carrier)

Activates or deactivates the PLCP header field decoding of the captured burst data.

On Only the bursts are included in the results analysis whose modulation format specified

in the signal symbol field matches the modulation format specified in the Analyze

PSDU Mod field.

Off The data is demodulated according to the modulation scheme specified in the

Demodulator field. If any of the analyzed data has a modulation different to that

specified the results will be of limited use.

Remote: DEM:FORM:AUT ON

Burst Type (Demod Settings dialog box, IEEE 802.11a, g (OFDM, Single Carrier), j and n)

Specifies the type of burst to be included in measurement analysis. Only one burst type can be

selected for the measurement results. The following burst types are supported:

Direct Link Burst IEEE 802.11a, j, n

OFDM IEEE 802.11g

Long DSSS–OFDM IEEE 802.11g

Short DSSS–OFDM IEEE 802.11g

Long PLCP IEEE 802.11g

Short PLCP IEEE 802.11g

Remote: DEM:FORM:BAN:BTYPe 'DIRECT'

Preamble Type (Demod Settings dialog box, IEEE 802.11b)

Specifies the type of burst which should be included in measurement analysis. The following

burst types are supported: Short PLCP, Long PLCP.

Remote: DEM:FORM:BAN:BTYPe 'SHORT'

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.421 E-11

Auto Demodulation

Activates or deactivates the automatic detection of the modulation. If activated, the modulation

applied to the input data is determined from the modulation type of the first complete burst within

the captured data. This option automatically activates the Signal Field Content option.

Remote: DEM:FORM:AUT ON

Analyze PSDU Mod

Specifies the modulation of the bursts to be analyzed. Only bursts using the selected modulation

are considered in measurement analysis. This option is only available if the Signal Field

Content or the Use Header Content option is activated.

Remote: DEM:FORM:AUT ON

Demodulator

Specifies the modulation to be applied to the measured data. If the captured data uses a

different modulation scheme than specified by this field the results will be of limited use. This

field is only available if the Signal Field Content or the Use Header Content option is

deactivated.

Remote: DEM:FORM:BAN 'QAM16'

PPDU Frame Format (Demod Settings dialog box, IEEE 802.11n)

PPDU Frame Format specifies the type of PHY Protocol Data Unit (PPDU) which should be

included in measurement analysis. The following PPDU formats are supported:

–Mixed 20 MHz

–Green Field 20 MHz

Remote: DEM:FORM:BAN:BTYP 'MM20'

Auto Guard (Demod Settings dialog box, IEEE 802.11n)

Specifies whether the Guard interval of the measured data should be automatically detected or

not. When Auto Guard Interval is set to ON then the Guard Interval is detected from the input

signal .

When Use Auto Guard Interval is set to OFF then guard interval of the input signal can be

specified with the Guard Interval parameter.

Remote: CONF:WLAN:GTIM:AUTO ON

Guard Interval (Demod Settings dialog box, IEEE 802.11n)

Specifies the guard interval of the input signal.

When Auto Guard Interval is set to ON then Guard Interval is read only and display the detected

guard interval.

Remote: CONF:WLAN:GTIM SHOR

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.422 E-11

Equal Burst Length (Demod Settings dialog box)

Activates or deactivates the burst selection for measurement analysis according to the range or

specific number of data symbols/bytes.

Standard State Description

IEEE 802.11a, j, n On Only bursts with exactly the number of symbols specified in the

Data Symbols field are considered for measurement analysis.

Off Only bursts within the range of data symbols specified by the

Min Data Symbols and Max Data Symbols fields are

considered for measurement analysis.

IEEE 802.11b, g

(Single Carrier)

On Only bursts with exactly the number of data bytes or duration

specified in the Payload Length field are considered for

measurement analysis.

Off Only bursts within the range of data bytes or duration specified

by the Min Payload Length and Max Payload Length fields

are considered for measurement analysis.

IEEE 802.11g

(OFDM)

On Only bursts with exactly the number of data symbols or

duration specified in the Payload Length field are considered

for measurement analysis.

Off Only bursts within the range of data symbols or duration

specified by the Min Payload Length and Max Payload

Length fields are considered for measurement analysis.

Remote: DEM:FORM:BAN:SYMB:EQU ON

Remote: DEM:FORM:BAN:DBYTes:EQU ON

Remote: DEM:BAN:DUR:EQU ON (PVT)

Data Symbols (Demod Settings dialog box, IEEE 802.11a, j, n)

Specifies the number of data symbols of a burst to be considered in measurement analysis. This

field is only available if the Equal Burst Length option is activated.

Remote: DEM:FORM:BAN:SYMB:MIN 16

Min Data Symbols (Demod Settings dialog box, IEEE 802.11a, j, n)

Specifies the minimum number of data symbols of a burst to be considered in measurement

analysis. This field is only available if the Equal Burst Length option is deactivated.

Remote: DEM:FORM:BAN:SYMB:MIN 16

Max Data Symbols (Demod Settings dialog box, IEEE 802.11a, j, n)

Specifies the maximum number of data symbols of a burst to be considered in measurement

analysis. This field is only available if the Equal Burst Length option is deactivated.

Remote: DEM:FORM:BAN:SYMB:MAX 1300

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.423 E-11

Channel Estimation (Demod Settings dialog box, IEEE 802.11a, g (OFDM), j, n)

Specifies how accurately the EVM results are calculated.

Preamble The channel estimation is performed in the preamble as required in the

standard.

Payload The channel estimation is performed in the payload.

Remote: DEM:CEST ON

Payload Length (Demod Settings dialog box, IEEE 802.11b, g)

Specifies the number of symbols, bytes or duration of a burst to be considered in measurement

analysis. This field is only available if the Equal Burst Length option is activated.

Remote: DEM:FORM:BAN:DBYTes:MIN 16

Remote: DEM:BAN:DUR:MIN 45

Min Payload Length (Demod Settings dialog box, IEEE 802.11b, g)

Specifies the minimum number of symbols, bytes or duration of a burst to be considered in

measurement analysis. This field is only available if the Equal Burst Length option is

deactivated.

Remote: DEM:FORM:BAN:DBYTes:MIN 16

Remote: DEM:BAN:DUR:MIN 45

Max Payload Length (Demod Settings dialog box, IEEE 802.11b, g)

Specifies the maximum number of symbols, bytes or duration of a burst to be considered in

measurement analysis. This field is only available if the Equal Burst Length option is

deactivated.

Remote: DEM:FORM:BAN:DBYTes:MAX 1300

Remote: DEM:BAN:DUR:MAX 1300

Phase (Demod Settings dialog box)

Activates or deactivates the compensation for phase error. If activated, the measurement results

are compensated for phase error on a per–symbol basis.

Remote: TRAC:PHAS 1

Timing (Demod Settings dialog box)

Activates or deactivates the compensation for timing error. If activated, the measurement results

are compensated for timing error on a per–symbol basis.

Remote: TRAC:TIME ON

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.424 E-11

Level (Demod Settings dialog box)

Activates or deactivates the compensation for level error. If activated, the measurement results

are compensated for level error on a per–symbol basis.

Remote: TRAC:LEV ON

Display List/Graph

Configures the result display. The measurement results are displayed either in form of a list of

measurement points or as a graphical trace.

Remote: DISP:WIND1:TABL ON

Remote: for result queries see chapter "Remote Control – Commands", section FETCh Subsystem

PVT

Opens the PVT submenu to select the Power vs Time measurement results.

The PVT result displays show the minimum, average and maximum levels measured over the

full range of the measured input data, or over complete bursts displayed within the gating lines if

gating is switched on. The results are displayed as a single burst. Using screen B in full screen

provides additional power information during this measurement.

For IEEE 802.11b and g (single carrier), the PVT results are displayed as percentage values of

the reference power. The reference can be set to either the max or mean power of the burst. For

both rising and falling edges two time lines are displayed, which mark the points 10% and 90%

of the reference power. The time between these two points is compared against the limits

specified for the rising and falling edges.

For further details see also "Rise / fall time measurement" on page 4.413.

Remote: CONF:BURS:PVT

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.425 E-11

Full Burst (IEEE 802.11a, g, j – OFDM and n)

Displays the PVT results in a single graph with all burst data being displayed.

For further details refer to the PVT softkey.

Remote: CONF:BURS:PVT:SEL FULL

Rising & Falling (IEEE 802.11a, g, j – OFDM and n)

Displays the PVT results in two separate graphs, the left hand side showing the rising edge and

the right hand side showing the falling edge.

Remote: CONF:BURS:PVT:SEL EDGE

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.426 E-11

Ramp Up/Down/Up & Down (IEEE 802.11b, g – Single Carrier)

Sets the display of the rising/falling edge graph:

Up Displays the rising edge graph.

Down Displays the falling edge graph.

Up & Down Displays the rising and falling edge graph.

For further details refer to the PVT softkey.

Remote: CONF:BURS:PVT:SEL RISE

Ref Pow Max/Mean (IEEE 802.11b, g – Single Carrier)

Sets the reference for the rise and fall time calculation to the maximum or mean burst power.

For further details refer to the PVT softkey.

Remote: CONF:BURS:PVT:RPOW MEAN

Average Length (IEEE 802.11b, g – Single Carrier)

Opens an edit dialog box to enter the number of samples in order to adjust the length of the

smoothing filter.

For further details refer to the PVT softkey.

Remote: CONF:BURS:PVT:AVER 31

Gating Settings On/Off

Activates or deactivates gating, or opens the Gate Settings dialog box to specify range of

captured data used in results calculation.

On Uses only the specified range of captured data in results calculation. In the

Magnitude Capture Buffer trace, two vertical lines mark the specified range.

Off Uses all the captured data in results calculation.

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.427 E-11

In the Gate Settings dialog box, the following parameters are set:

Delay Start point of captured data to be used in results calculation, i.e.

the delay from the start of the captured data in time or samples. If

the delay is specified in time, the number of samples is updated

accordingly, and vice versa.

Length Amount of captured data to be used in results calculation. If the

length is specified in time, the number of samples is updated

accordingly, and vice versa.

Link Gate and Mark If activated, the position of the marker and the gate lines are

linked. The marker is positioned half way between gate start and

end. The marker position alters when the gate is modified, and

the gate lines move with the marker when the marker position is

altered.

The gate settings are defined for following measurements: PVT, Spectrum FFT, CCDF,

Spectrum Mask, Spectrum ACPR.

If a frequency sweep measurement is active (Spectrum Mask and Spectrum ACP) the result

display is switched to the Magnitude Capture Buffer display in order to allow the gate to be set

the correct part of the sweep.

Remote: SWE:EGAT ON

Remote: SWE:EGAT:HOLD 125us, SWE:EGAT:HOLD:SAMP 2500 (Delay)

Remote: SWE:EGAT:LENG 20ms,SWE:EGAT:LENG:SAMP 200000 (Length)

Remote: SWE:EGAT:LINK ON (Link Gate and Mark)

Import

Opens the Choose the file to import dialog box.

Select the IQ data file you want to import and press ENTER.The extension of data files is *.iqw.

Remote: MMEM:LOAD:IQ:STAT

Export

Opens the Choose the file to export dialog box.

Enter the path and the name of the IQ data file you want to export and press ENTER.The

extension of data files is *.iqw. If the file cannot be created or there is no valid IQ data to export

an error message is displayed.

Remote: MMEM:STOR:IQ:STAT

R&S Support

Creates files that help identifying the current problem. They are stored under

C:\R_S\Instr\user\Support. If you contact the Rohde&Schwarz support to get help for a certain

problem, send these files to the support in order to identify and solve the problem faster.

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.428 E-11

Y–Axis/Div

Opens a dialog box to modify the y–axis settings:

Auto Scaling If activated, the scaling of the y–axis is calculated automatically.

Per Division Specifies the scaling to be used if Auto Scaling is deactivated.

Unit Specifies the y–axis unit. With the unit is dB, Auto Scaling is always

activated.

Remote: DISP:WIND2:TRAC:Y:SCAL:AUTO ON

Remote: DISP:WIND2:TRAC:Y:SCAL:DPIV 2

EVM Constell

Opens a submenu to select the error vector magnitude (EVM) or the constellation result

displays.

EVM vs Symbol/Carrier

Selects the EVM vs Symbol or EVM vs Carrier result displays.

–EVM vs Symbol

This result display shows the EVM measured over the full range of the measured input data.

The results are displayed on a per–symbol basis, with blue vertical lines marking the

boundaries of each burst. Note that burst boundary lines are only displayed if the number of

analyzed bursts is less than 250.

For IEEE 802.11a, j, g, n (OFDM) the minimum, average, and maximum traces are displayed.

For IEEE 802.11b, g (Single Carrier) two EVM traces are displayed. The trace labeled with VEC

ERR IEEE shows the error vector magnitude as defined in the IEEE 802.11b, g standards. For the

trace labeled with EVM a commonly used EVM definition is applied, which is the square root of the

momentary error power normalized by the averaged reference power.

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.429 E-11

–EVM vs Carrier (IEEE 802.11a, g, j, n – OFDM)

This result display shows all EVM values recorded on a per–carrier basis over the full set of

measured data. An average trace is also displayed.

Remote: CONF:BURS:EVM:ESYM (EVM vs Symbol)

Remote: CONF:BURS:EVM:ECAR (EVM vs Carrier)

Error Frequency/Phase

Selects the Rel. Frequency Error vs Preamble or the Phase Error vs Preamble result displays.

These result displays show the error values recorded over the preamble part of the burst. A

minimum, average and maximum trace are displayed. The results display either relative

frequency error or phase error.

Remote: CONF:BURS:PRE

Remote: CONF:BURS:PRE:SEL FREQ (Frequency Error vs Preamble)

Remote: CONF:BURS:PRE:SEL PHAS (Phase Error vs Preamble)

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.430 E-11

Constell vs Symbol/Carrier

Selects the Constallation vs Symbol or the Constellation vs Carrier result displays.

–Constellation vs Symbol (all standards)

This result display shows the in–phase and quadrature phase results over the full range of the

measured input data. The ideal points for the selected modulations scheme are displayed for

reference purposes.

The amount of data displayed in the Constellation result display can be reduced by selecting

the carrier or carriers for which data is to be displayed (Carrier Selection softkey).

–Constellation vs Carrier (IEEE 802.11a, g, j, n – OFDM)

This result display shows the in–phase and quadrature phase results over the full range of the

measured input data plotted on a per–carrier basis. The magnitude of the in–phase and

quadrature part is shown on the y–axis, both are displayed as separate traces (I–> trace 1, Q–>

trace 2).

Remote: CONF:BURS:CONS:CSYM (Constellation vs Symbol)

Remote: CONF:BURS:CONS:CCAR (Constellation vs Carrier)

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.431 E-11

Carrier Selection (IEEE 802.11a, g, j, n – OFDM)

Opens a dialog box to select the carrier for data display. Either a specific carrier number, pilots

only or all carriers can be selected.

Remote: CONF:BURS:CONS:CARR:SEL –26

Spectrum

Opens a submenu for frequency measurements.

Spectrum Flatness (IEEE 802.11a, g, j, n – OFDM)

Sets the Spectrum Flatness result display.

This result display shows the spectrum flatness and group delay values recorded on a per–

carrier basis over the full set of measured data. An average trace is also displayed for each of

the result types. An upper and lower limit line representing the limits specified for the selected

standard are displayed and an overall pass/fail status is displayed for the obtained (average)

results against these limit lines.

Remote: CONF:BURS:SPEC:FLAT

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.432 E-11

Spectrum Mask (IEEE 802.11b, g – Single Carrier),

Spectrum IEEE/ETSI (IEEE 802.11a, g, j, n – OFDM)

Sets the Spectrum Mask result display.

This result display shows power against frequency. The span of the results is 100 MHz for IEEE

and 500 MHz for ETSI around the specified measurement frequency. A limit line representing

the spectrum mask specified for the selected standard is displayed and an overall pass/fail

status is displayed for the obtained results against this limit line. The number of sweeps is set in

the General Settings dialog box, Sweep Count field. If the measurement is performed over

multiple sweeps both a max hold trace and an average trace are displayed.

Remote: CONF:BURS:SPEC:MASK

Remote: CONF:BURS:SPEC:MASK:SEL ETSI

Spectrum FFT

Sets the Spectrum FFT result display.

This result display shows the Power vs Frequency results obtained from a FFT performed over

the range of data in the Magnitude Capture Buffer which lies within the gate lines.

Remote: CONF:BURS:SPEC:FFT

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.433 E-11

Spectrum ACPR (IEEE 802.11a, g, n, OFDM Turbo Mode)

Spectrum ACP (IEEE 802.11b)

ACP Rel/Abs (IEEE 802.11j)

Sets the ACP (Adjacent Channel Power) result display.

This result display is similar to the Spectrum Mask measurement, and provides information

about leakage into adjacent channels. The results show the absolute or relative power

measured in the three nearest channels either side of the measured channel. This measurement

is the same as the adjacent channel power measurement provided by the spectrum analyzer.

The number of sweeps is set in the General Settings dialog box, Sweep Count field. If the

measurement is performed over multiple sweeps both a max hold trace and an average trace

are displayed.

Remote: CONF:BURS:SPEC:ACPR

Remote: CALC:MARK:FUNC:POW:RES? (result query)

Remote: CALC:MARK:FUNC:POW:RES:MAXH? (result query)

Statistics

Opens a submenu to display statistics measurement results.

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.434 E-11

CCDF

Sets the CCDF result display.

This result display shows the probability of an amplitude within the gating lines exceeding the

mean power measured between the gating lines. The x–axis displays power relative to the

measured mean power.

Remote: CONF:BURS:STAT:CCDF

Bitstream

Sets the Bitstream result display. This result display shows the demodulated data stream.

–IEEE 802.11a, j, g, n (OFDM):

The results are grouped by symbol and carrier.

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.435 E-11

–IEEE 802.11b or g (Single Carrier)

The results are grouped by burst.

Remote: CONF:BURS:STAT:BSTR

Signal Field (IEEE 802.11a, g, j, n – OFDM),

PLCP Header (IEEE 802.11b, g – Single Carrier)

Sets the Signal Field result display or the PLCP Header result display, depending on the

selected standard.

Signal Field

This result display shows the decoded data from the signal field of the burst. Therefore it is only

available, if, in the Demod Settings dialog box, the Signal Field Content option is activated.

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.436 E-11

PLCP Header

This result display shows the decoded data from the PLCP header of the burst. The following

details are listed:

Column header Description Example

Burst number of the decoded burst

Acolored block indicates that the burst was successfully

decoded.

Burst 1

Signal signal field

The decoded data rate is shown below.

00010100

2MBits/s

Service service field

The currently used bits are highlighted. The text below explains

the decoded meaning of these bits.

00000000

––/––/––

PSDU Length length field

The decoded time to transmit the PSDU is shown below.

0000000001111000

120 Ms

CRC CRC field

The result is displayed below (OK for passed or Failed).

1110100111001110

Remote: CONF:BURS:STAT:SFIeld

Softkeys of the sweep menu (WLAN mode)

The following table shows all softkeys available in the sweep menu in WLAN mode (SWEEP key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Meas Single/Cont

Auto Level

Refresh

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.437 E-11

Meas Single/Cont

Selects the sweep mode.

Single single sweep mode

Cont continuous sweep mode

Remote: INIT:CONT OFF (single sweep mode)

Remote: INIT:CONT ON (continuous sweep mode)

Auto Level

Starts an automatic level detection measurement. If this softkey is pressed while a measurement

is running, the current measurement is aborted and the automatic level detection measurement

is started. If the aborted measurement was a continuous measurement it is resumed after the

automatic level detection is completed.

Remote: CONF:POW:AUTO ON

Refresh

Updates the current measurement results with respect to the current gate settings. This softkey

is only available if the measurement results are effected by the gate settings (Spectrum FFT,

PVT and CCDF) and if the gate settings are modified after a measurement result has been

obtained.

Softkeys of the marker menu (WLAN mode)

The following table shows all softkeys available in the marker menu in WLAN mode (MKR key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description. Close all settings dialog boxes before opening the marker menu.

Command

Marker 1

Unzoom

Marker Zoom

Marker Off

Marker 1

Opens a dialog box to adjust the marker. The contents of the dialog box depends on the type of

graph the marker is adjusted to. After every change, the marker position in the trace and the

marker information are updated.

Remote: CALC:MARK ON

Remote: CALC:MARK:X 2ms

Remote: CALC2:MARK:Y –2

Remote: CALC:MARK:SYMB 2

Remote: CALC:MARK:CARR –7

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.438 E-11

Unzoom

Cancels the marker zoom.

Remote: CALC:MARK:FUNC:ZOOM 1

Marker Zoom

Opens an edit dialog box to select the magnification factor for the zoom. The zoom facility is

provided for the following result displays: Magnitude Capture Buffer, PVT, Constellation vs

Symbol, Constellation vs Carrier. The maximum magnification depends on the type of result

display.

Remote: CALC:MARK:FUNC:ZOOM 3

Marker Off

Switches off all makers in the active result display.

Remote: CALC:MARK:AOFF

Softkeys of the marker–> menu (WLAN mode)

The following table shows all softkeys available in the marker–> menu in WLAN mode (MKR–> key). It

is possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Peak

Min

MKR –> Trace

Peak (Spectrum Flatness result display)

Sets the marker to the peak value of the assigned trace.

Remote: CALC:MARK:MAX

Min (Spectrum Flatness result display)

Sets the marker to the minimum value of the assigned trace.

Remote: CALC:MARK:MIN

MKR –> Trace

Opens an edit dialog box to enter the number of the trace, on which the marker is to be placed.

This softkey is available for all result displays with more than one trace.

Remote: CALC:MARK:TRAC 2

R&S FSL WLAN TX Measurements (Option K91 / K91n)

1300.2519.12 4.439 E-11

Softkeys of the lines menu (WLAN mode)

The following table shows all softkeys available in the lines menu in WLAN mode (LINES key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

This menu is only available if the results are displayed in form of a list (for details see Result summary

list and Display List/Graph softkey).

Command

Default Current

Default All

Default Current

Resets all limits for the current modulation scheme to the values specified in the selected

standard.

Remote: see CALCulate:LIMit Subsystem

Default All

Resets all limits for all modulation schemes to the values specified in the selected standard.

Remote: see CALCulate:LIMit Subsystem

Softkeys of the trace menu (WLAN mode)

The following table shows all softkeys available in the trace menu in WLAN mode (TRACE key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Display List/Graph

Screen A/B

Screen Full/Split

Display List/Graph

For details refer to the Display List/Graph softkey in the WLAN menu.

Screen A/B

Selects the active screen for IQ measurement results in split and full screen mode. Only the

markers of an active screen can be controlled.

Remote: DISP:WIND1:SSEL

WLAN TX Measurements (Option K91 / K91n) R&S FSL

1300.2519.12 4.440 E-11

Screen Full/Split

Changes the display between split and full screen for IQ measurement results. Frequency

sweep measurement results are always displayed in full screen.

Remote: DISP:FORM SING

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.441 E-11

WiMAX, WiBro Measurements (Options K92/K93)

The WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K93) extends the

functionality of the R&S FSL to enable WiMAX IEEE 802.16e, WiBro Measurements according to the

IEEE standards listed below. It includes the functionality of the WiMAX 802.16 OFDM Measurements

option (R&S FSL–K92). Accordingly both options are described together in this section, differentiated by

the corresponding standards:WiMAX 802.16 OFDM Measurements (R&S FSL–K92/K93)

–IEEE 802.16–2004/Cor 1–2005 OFDM physical layer mode

The short forms IEEE 802.16–2004 OFDM is used in this section to reference this standard.

The corresponding remote control mode is OFDM.

•WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K93)

–IEEE 802.16–2004/Cor 1–2005, IEEE 802.16e–2005 OFDMA physical layer mode

The short form IEEE 802.16e–2005 OFDMA is used in this section to reference this standard.

The corresponding remote control mode is OFDMA.

–IEEE 802.16–2004/Cor 1–2005, IEEE 802.16e–2005 based WiBro

The short form IEEE 802.16e–2005 WiBro is used in this section to reference this standard.

The corresponding remote control mode is WiBro.

The options are available from firmware version 1.40 (R&S FSL–K92) and 1.50 (R&S FSL–K93).

TX measurements of a WiMAX Device Under Test (DUT) according to the standards specified for the device

are performed:

•Modulation formats

–IEEE 802.16–2004: BPSK (IEEE 802.16–2004 OFDM), QPSK, 16QAM, 64QAM

•Modulation measurements

–Constellation diagram

–Constellation diagram per OFDM carrier

–I/Q offset and I/Q imbalance

–Carrier and symbol frequency errors

–Modulation error (EVM) per OFDM carrier or symbol

–Amplitude response and group–delay distortion (spectral flatness)

•Amplitude statistics (CCDF) and crest factor

•Frequency and Phase error vs Symbol

•Transmit spectrum mask

•Adjacent Channel Power (absolute and relative)

•FFT, also over a selected part of the signal, e.g. preamble

•Payload bit information

•Capture time selectable up to 50 ms, multiple sweeps possible for large number of bursts

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.442 E-11

To open the measurement menu

If the WiMAX mode is not the active measurement mode, press the MODE key and activate the

WiMAX option.

If the WiMAX mode is already active, press the MENU or MEAS key.

The measurement menu is displayed. .

To exit the WiMAX measurement mode, select another option. For details refer also to section

"Measurement Mode Selection – MODE Key" on page 4.129.

Menu and softkey description

–"Softkeys of the WiMAX menu (WiMAX mode)" on page 4.448

–"Softkeys of the sweep menu (WiMAX mode)" on page 4.486

–"Softkeys of the marker menu (WiMAX mode)" on page 4.487

–"Softkeys of the marker–> menu (WiMAX mode)" on page 4.488

–"Softkeys of the lines menu (WiMAX mode)" on page 4.488

–"Softkeys of the trace menu (WiMAX mode)" on page 4.489

The file, setup, and print menus are provided as described for the base unit. For details refer to the

corresponding menu descriptions. The span and bandwidth menus are not available in the WiMAX

mode.

The FREQ,AMPT and TRIG keys open the General Settings or the Demod Settings dialog box. For

details refer to the Settings General/Demod softkey description (measurement menu).

Further information topics

–"Measurements and result displays" on page 4.442

–"Current restrictions to the IEEE 802.16e–2005 OFDMA/WiBro signal to be analyzed" on page

4.443

–"Title bar information" on page 4.448

–"Status bar information" on page 4.448

Tasks topics

–"To transfer the current R&S SMU WiMAX setting via LAN" on page 4.447

Measurements and result displays

The WiMAX IEEE 802.16 OFDM, OFDMA Measurements option provides two main measurement

types:

•IQ measurements (based on captured IQ data)

–Power vs Time (see PVT softkey)

–EVM vs Symbol, EVM vs Carrier (see EVM vs Symbol/Carrier softkey)

–Phase vs Preamble, Frequency vs Preamble (see Error Frequency/Phase softkey)

–Spectrum Flatness (see Spectrum Flat./Diff./Group Delay softkey)

–Spectrum Group Delay (see Spectrum Flat./Diff./Group Delay softkey)

–Spectrum Flatness Adjacent Carrier Power Difference (see Spectrum Flat./Diff./Group Delay

softkey)

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.443 E-11

–Spectrum FFT (see Spectrum FFT softkey)

–Constellation vs Symbol (see Constell vs Symbol/Carrier softkey)

–Constellation vs Carrier (IEEE 802.16–2004 OFDM only, see Constell vs Symbol/Carrier

softkey)

–Conditional Cumulative Distribution Function (see CCDF softkey)

–Bit Stream (see Bitstream softkey)

•frequency sweep measurements

–Spectrum Mask (see Spectrum IEEE/ETSI softkey)

–Spectrum ACP/ACPR (see ACPR Abs/Rel softkey)

For current restrictions refer to Current restrictions to the IEEE 802.16e–2005 OFDMA/WiBro signal to

be analyzed.

The measurement result display is divided into two panes:

•Measurement settings

•Result displays

The results can be displayed in form of a list or a graph (see also Display List/Graph softkey).

–Result summary list

–Result display graph

Current restrictions to the IEEE 802.16e–2005 OFDMA/WiBro signal to be analyzed

•standard

–IEEE 16–2004/Cor1–2005, IEEE 802.16e–2005, OFDMA Physical Layer Mode, 1 October

2004/28 February 2006

–IEEE 16–2004/Cor1–2005, IEEE 802.16e–2005 based WiBro

•FFT sizes

The FFT sizes 128, 512, 1024 and 2048 are supported.

•subframes

–Either a DL subframe or a UL subframe can be analyzed at one point in time.

–One DL–PUSC zone per DL subframe is supported.

–One DL–FUSC zone immediately following the first mandatory DL–PUSC zone is supported

(DL subframe).

–One UL–PUSC zone per UL subframe is supported.

–The subframes have to be separated by sufficient power off gaps.

•segments

The first mandatory DL–PUSC zone must contain exclusively one segment. The assignment of

subchannel groups to this segment is not restricted.

•symbols

The signal to be analyzed must contain at least two OFDMA data symbols. More OFDMA data

symbols will improve the accuracy of the measurement results.

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1300.2519.12 4.444 E-11

•burst

Each OFDMA symbol of a zone must contain at least one active burst, i.e. each OFDMA symbol of

the zone must comprise subchannels belonging to an active burst. The zone/segment must be

covered by active bursts, i.e. no gaps at the beginning, mid or end of the zone/segment are

allowed.

•UL subframes

In case of UL subframe analysis, the frame number must be constant for the signal to be analyzed.

Measurement settings

The overall measurement settings used to obtain the current measurement results are displayed below

the title bar (see Fig. 4-48). The following settings are listed:

Setting Description Standard restrictions

Frequency The frequency of the measured input signal.

Burst Type The type of burst being analyzed IEEE 802.16–2004 OFDM only

Zone/Seg The zone and segment being analyzed IEEE 802.16e–2005 OFDMA/WiBro only

Signal Level The expected mean signal level for the input signal.

Modulation Shows the active setting selected in the Demod

Settings dialog box, Demodulator list.

If the Mod. Detection field is set to ALL,ALL is

displayed.

IEEE 802.16–2004 OFDM only

Shows the active setting selected in the Demod

Settings dialog box, Demodulator list.

If the Modulation Analysis Scope field is set to ALL,

ALL is displayed.

IEEE 802.16e–2005 OFDMA/WiBro only

External Att The attenuation (positive values) or gain (negative

values) applied to the signal externally (i.e. before the

RF or IQ connector of the spectrum analyzer), e.g.:

External Att = 10 dB means that before the RF

connector of the R&S FSL a 10 dB attenuator is used

External Att = –20 dB means that before the RF

connector of the R&S FSL a amplifier with 20 dB gain

is used.

Data Symbols Shows the minimum and maximum number of data

symbols that a burst may have to be considered in

results analysis .

IEEE 802.16–2004 OFDM only

Zone Offset/Length A combined display of the offset and length of the

analyzed zone

IEEE 802.16e–2005 OFDMA/WiBro only

Fig. 4-48 Measurement settings for IEEE 802.16–2004 OFDM (example)

Fig. 4-49 Measurement settings for IEEE 802.16e–2005 OFDMA/WiBro (example)

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1300.2519.12 4.445 E-11

Result summary list

If the results are displayed in tabular form (Display Graph/List softkey), the result summary list is

displayed. It shows the overall measurement results and provides limit checking for result values in

accordance with the selected standard. Result values which are within the limit as specified by the

standard are displayed in green. Result values which are outside of the limits specified by the standard

are displayed in red with a '*' to the left. Results which have no limits specified by the standard are

displayed in white. Limit values are displayed in white (not bold) and can be modified, when focused,

via the keypad. Limits are modified for the currently selected modulation scheme. Each modulation

scheme may have its own set of user defined limits. To reset the limit values to the values specified in

the standard, use the lines menu (LINES key).

•IEEE 802.16–2004 OFDM

The results displayed in this list are for the entire measurement. If a specific number of bursts have

been requested which requires more than one sweep, the result summary list is updated at the end

of each sweep. The number of bursts measured and the number of bursts requested are displayed

to show the progress through the measurement. The Min / Mean / Max columns show the minimum,

mean or maximum values of the burst results.

Fig. 4-50 Result summary list for IEEE 802.16–2004 OFDM (example)

•IEEE 802.16e–2005 OFDMA, WiBro

For these measurement results, the minimum, mean, and maximum is taken over the analyzed

zones of the current capture buffer content.

Two lists are available:

–Result Summary of Analyzed Subframes (list 1)

–Result Summary of Analyzed Zone / Segment (list 2)

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.446 E-11

Fig. 4-51 Result summary list 1 for IEEE 802.16e–2005 OFDMA/WiBro (example)

Fig. 4-52 Result summary list 2 for IEEE 802.16e–2005 OFDMA/WiBro (example)

For details regarding how the results are calculated refer to chapter "Advanced Measurement

Examples".

Result display graph

•IQ measurements

If the results are displayed in graphical form (Display Graph/List softkey), additionally to the

selected graphical result display, the Magnitude Capture Buffer (power profile) display is provided

for all IQ measurements. The different result displays are described with the corresponding softkey.

The Magnitude Capture Buffer display shows the complete range of captured data for the last

sweep. All analyzed bursts are identified with a green bar at the bottom of the Magnitude Capture

Buffer display. Only those bursts match the required criteria. The gate delay line (GD)and gate

length line (GL)are displayed in red color.

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.447 E-11

Fig. 4-53 Magnitude capture buffer results (example)

All IQ measurements process the same signal data and as such all IQ measurement results are

available after a single IQ measurement execution.

IQ measurements can be run in split screen mode (allowing both the Magnitude Capture Buffer

display and the selected IQ measurement results to be displayed simultaneously) or in full screen

mode (with either the Magnitude Capture Buffer display or the selected IQ measurement results

displayed).

When measuring OFDMA or WiBro measurements, the time from the start of the capture buffer to

the start of the first frame is also displayed in the Magnitude Capture buffer. This time is marked

with a vertical blue line, with the result displayed at the top of the graph.

•frequency sweep measurements

The frequency sweep measurements use different signal data to IQ measurements and as such it is

not possible to run an IQ measurement and then view the results in the frequency sweep

measurements and vice–versa. Also because each of the frequency sweep measurements uses

different settings to obtain signal data it is not possible to run a frequency sweep measurement and

view the results of another frequency sweep measurement.

All frequency sweep measurements are run in full screen mode.

Further information

This section provides background information on measurements and displayed information. For details

on signal processing refer to chapter "Advanced Measurement Examples", section "WiMAX, WiBro

Measurements (Options K92/K93)".

To transfer the current R&S SMU WiMAX setting via LAN

Prerequisite:

•The Windows Firewall of the R&S SMU is switched off.

1. Press the Settings General/Demod softkey to open the General Settings dialog box.

2. Under Signal Characteristics in the Standard list, select the IEEE 802.16e–2005 OFDMA or IEEE

802.16e–2005 WiBro standard.

3. Under Setup in the SMU Address field, specify the TCP/IP address of the R&S SMU.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.448 E-11

4. Press the More softkey to change into the side menu.

5. Press the File Manager softkey to open the File Manager.

6. Under Folders,select the SMU entry.

7. Under Files,select the Current SMU WiMAX Settings entry using the RIGHTARRROW key.

8. Press the Recall softkey.

The selected WiMAX setting file is transferred from the R&S ´SMU to the R&S FSL.

Title bar information

The title bar displays the following information:

•standard applicable to the current measurement

Status bar information

The status bar displays the following information:

•parameter values

If a parameter in a settings dialog box is selected, the minimum and maximum values for the

selected parameter are displayed.

If a Boolean parameter in a dialog box is selected, the minimum and maximum values are displayed

as N/A for not applicable.

•measurement status

During the measurement, the current measurement status along with detailed information about the

progress is displayed.

•error messages (with red background), for details refer to chapter "Error Messages".

•warning messages (with blue background), for details refer to chapter "Error Messages".

Softkeys of the WiMAX menu (WiMAX mode)

The following table shows all softkeys available in the WiMAX menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Command

Settings General/Demod

Display Graph/List

PVT Settings General/Demod

Display Graph/List

Full Burst

Start End

Burst Selection

Full Subframe

Rising/Falling

More 

Gating Settings On/Off

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1300.2519.12 4.449 E-11

Menu / Command Command

Import

Export

R&S Support

EVM Constell Settings General/Demod

EVM vs Symbol/Carrier

Error Frequency/Phase

Constell vs Symbol/Carrier

Carrier Selection

Constell Selection

More 

Gating Settings On/Off

Import

Export

Y–Axis/Div

R&S Support

Spectrum Settings General/Demod

Display Graph/List

Spectrum Flat./Diff./Group Delay

Spectrum IEEE/ETSI

Spectrum Mask

Spectrum FFT

ACPR Abs/Rel

More 

Gating Settings On/Off

SEM Settings

ACP Settings

Import

Export

R&S Support

Statistics Settings General/Demod

Display Graph/List

CCDF

Bitstream

Burst Summary

Bit Selection

More 

Gating Settings On/Off

Import

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.450 E-11

Menu / Command Command

Export

R&S Support

File Manager For the available File Manager

softkeys, see the description of the File

Manager softkey.

Settings General/Demod

Opens the General Settings dialog box or the Demod Settings dialog box. Screenshots of the

dialog boxes are provided in chapter "Advanced Measurement Examples", section

"Measurement Examples of the WiMAX IEEE 802.16 OFDM, OFDMA Measurements option

(K93)".

Alternatively, the General Settings dialog box is opened as follows:

–FREQ key, with focus on the Frequency field

–AMPT key, with focus on the Signal Level (RF) field

–TRIG key, with focus on the Trigger Mode list

In the General Settings dialog box, all settings related to the overall measurement are modified.

The right pane with the advanced settings is only displayed, if the Advanced Settings option is

activated. The General Settings dialog box contains the following elements:

Pane Field/List Standard Restrictions

Signal Characteristics Standard

Frequency

Channel No IEEE 802.16–2004 OFDM

Frequency Band

FFT Size NFFT IEEE 802.16e–2005 OFDMA/WiBro

Channel BW

Sample Rate

G = Tg/Tb

Level Settings Signal Level

Auto Lev

Ext Att

Data Capture Settings Capture Time

Burst Count

Analyze Bursts

Sweep Time

Sweep Count

Trigger Settings Trigger Mode

Trigger Offset

Power Level

Auto Lvl

Input Settings Advanced Auto Level Time

Ref Level

Attenuation

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.451 E-11

Pane Field/List Standard Restrictions

IQ Settings Swap IQ

Result Settings RSSI, CINR avg.

List Results Unit IEEE 802.16–2004 OFDM

Setup SMU Address IEEE 802.16e–2005 OFDMA/WiBro

Inthe Demod Settings dialog box, the settings associated with the signal modulation are

modified. The content of the Demod Settings dialog box depends on the selected standard:

–IEEE 802.16–2004 OFDM

The settings under Burst to Analyze specify the characteristics of the bursts to be considered

in the measurement results. Only the bursts which meet the criteria specified in this group will

be included in measurement analysis. The settings under Tracking allow various errors in

measurement results to be compensated for.

–IEEE 802.16e–2005 OFDMA/WiBro

The Demod Settings dialog box contains the three tabs. Use the left/right arrow keys to

navigate between the tabs.

On the Demod Settings tab, the channel estimation range is set. The settings under Bursts to

Analyze specify the characteristics of the bursts to be considered in the measurement results.

The settings under Tracking allow various errors in measurement results to be compensated

for.

On the Frame Global tab, the common settings associated with the frame to be analyzed can

be modified.

On the Frame Config tab, the settings associated with the frame configuration can be modified.

The Zone/Segment List and the Burst List are displayed. The content of the selected list is

graphically displayed under The content of the selected list is graphically displayed under the

Zone/Segment Map and the Burst Map respectively. To edit Frame Config tab, softkeys are

available (see the table below).

The Demod Settings dialog box contains the following elements:

Tab/Pane Field/List or Softkey Standard Restrictions

Demod Settings

Burst to Analyze Burst Type IEEE 802.16–2004 OFDM

Link Mode IEEE 802.16–2004 OFDM

Use FCH Content IEEE 802.16–2004 OFDM

Mod. Detection IEEE 802.16–2004 OFDM

Demodulator IEEE 802.16–2004 OFDM

Subchannelization IEEE 802.16–2004 OFDM

Index IEEE 802.16–2004 OFDM

UL Phys. Modifier IEEE 802.16–2004 OFDM

Equal Burst Length IEEE 802.16–2004 OFDM

Data Symbols IEEE 802.16–2004 OFDM

Min Data Symbols IEEE 802.16–2004 OFDM

Max Data Symbols IEEE 802.16–2004 OFDM

Channel Estimation IEEE 802.16–2004 OFDM

Tracking Phase IEEE 802.16–2004 OFDM

Timing IEEE 802.16–2004 OFDM

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.452 E-11

Tab/Pane Field/List or Softkey Standard Restrictions

Level IEEE 802.16–2004 OFDM

Demod Settings

Channel Estimation Range Downlink (DL) IEEE 802.16e–2005 OFDMA/WiBro

Uplink (UL) IEEE 802.16e–2005 OFDMA/WiBro

Bursts To Analyze Modulation Analysis Scope IEEE 802.16e–2005 OFDMA/WiBro

Demodulator IEEE 802.16e–2005 OFDMA/WiBro

Tracking Settings Phase IEEE 802.16e–2005 OFDMA/WiBro

Timing IEEE 802.16e–2005 OFDMA/WiBro

Pilots for Tracking DL IEEE 802.16e–2005 OFDMA/WiBro

Pilots for Tracking UL IEEE 802.16e–2005 OFDMA/WiBro

Advanced FFT start offset rel to CP center IEEE 802.16e–2005 OFDMA/WiBro

Frame Global

Frame File Name IEEE 802.16e–2005 OFDMA/WiBro

IDCell IEEE 802.16e–2005 OFDMA/WiBro

DL Subframe Preamble Mode IEEE 802.16e–2005 OFDMA/WiBro

Preamble Index

Used Subchannel Bitmap

UL Subframe Frame Number IEEE 802.16e–2005 OFDMA/WiBro

Allocated Subchannel Bitmap IEEE 802.16e–2005 OFDMA/WiBro

Frame Config

List Zone/Burst IEEE 802.16e–2005 OFDMA/WiBro

Copy Zone/Burst IEEE 802.16e–2005 OFDMA/WiBro

Insert Zone/Burst IEEE 802.16e–2005 OFDMA/WiBro

New Zone/Burst IEEE 802.16e–2005 OFDMA/WiBro

New Segment IEEE 802.16e–2005 OFDMA/WiBro

Delete Zone/Burst IEEE 802.16e–2005 OFDMA/WiBro

File Manager IEEE 802.16e–2005 OFDMA/WiBro

Standard (General Settings dialog box)

Displays a list of all installed standards to select the WiMAX/WiBro standard:

Standard Installed with Option

IEEE 802.16–2004 OFDM R&S FSL–K92/K93

IEEE 802.16e–2005 OFDMA R&S FSL–K93 only

IEEE 802.16e–2005 WiBro R&S FSL–K93 only

All available entries represent a list of default settings in accordance to the specified standard.

This ensures that the measurements are performed according to the specified standard with the

correct limit values and limit lines.

Remote: CONF:STAN 0

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1300.2519.12 4.453 E-11

Frequency (General Settings dialog box)

Specifies the center frequency of the signal to be measured. If the frequency is modified, the

Channel No field is updated accordingly.

Remote: FREQ:CENT 100MHz

Channel No (General Settings dialog box, IEEE 802.16–2004 OFDM)

Specifies the channel to be measured. If the field entry is modified, the center frequency is

derived according to the section in the standard mentioned below and updated.

–For the Licensed Bands {ETSI, MMDS, WCS}:

Channel numbers are supported according to IEEE Std 802.16–2004 "8.3.10.2 Transmitter

channel bandwidth and RF carrier frequencies''. For the target frequency bands see IEEE Std

802.16–2004 "B.1 Targeted frequency bands''.

–For the License Exempt Bands {U–NII, CEPT}:

Channel numbers are supported according to IEEE Std 802.16–2004 "8.5.1 Channelization''.

Remote: CONF:CHAN 9

Frequency Band (General Settings dialog box)

Specifies the relationship between the Channel BW and the Sample Rate parameters.

Remote: CONF:WIM:FBAN ETSI

FFT Size NFFT (General Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Specifies the maximum number of carriers supported by the signal to be measured.

Remote: CONF:WIM:NFFT FFT2048

Channel BW (General Settings dialog box)

Specifies the bandwidth of the channel to be measured.

Remote: BAND:CHAN 7MHZ

Sample Rate (General Settings dialog box)

Specifies the sample rate used for IQ measurements.

Remote: TRACE:IQ:SRAT 2000000

G = Tg/Tb(General Settings dialog box)

Specifies the guard time ratio.

Remote: CONF:WIM:IGR 16

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1300.2519.12 4.454 E-11

Signal Level (General Settings dialog box)

Specifies the expected level of the RF input signal. If an automatic level detection measurement

has been executed, the signal level (RF) is updated.

Remote: CONF:POW:EXP:RF –20

Auto Lev (General Settings dialog box)

Activates or deactivates the automatic setting of the reference level for measurements.

On The reference level is measured automatically at the start of each measurement

sweep. This ensures that the reference level is always set at the optimal level for

obtaining accurate results but will result in slightly increased measurement times. For

details about level detection refer to chapter "Advanced Measurement Examples".

Off The reference level is defined manually in the Signal Level field.

Remote: CONF:POW:AUTO ON

Remote: CONF:POW:AUTO:SWE:TIME 200MS

Ext Att (General Settings dialog box)

Specifies the external attenuation or gain applied to the RF signal. A positive value indicates

attenuation, a negative value indicates gain. All displayed power level values are shifted by this

value.

Remote: DISP:TRAC:Y:RLEV:OFFS 10

Capture Time (General Settings dialog box)

Specifies the time (and therefore the amount of data) to be captured in a single measurement

sweep.

Remote: SWE:TIME 10ms

Burst Count (General Settings dialog box)

Activates or deactivates a specified number of bursts for capture and analysis.

On The data analysis is performed over a number of consecutive sweeps until the

required number of bursts has been captured and analyzed.

Off The data analysis is performed on a single measurement sweep.

Remote: BURS:COUN:STAT ON

Analyze Bursts (General Settings dialog box)

Specifies the number of bursts to be measured, if the Burst Count option is activated.

If the number of bursts of the specified type is not contained in a single measurement sweep,

the measurement sweeps continue until the requested number of bursts have been captured.

Remote: BURS:COUN 16

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1300.2519.12 4.455 E-11

Sweep Time (General Settings dialog box)

Specifies the sweep time for the Spectrum Mask and Spectrum ACP/ACPR measurements:

–If the Auto option is activated, the sweep time is calculated automatically.

–If the Auto option is deactivated, specify the sweep time.

Remote: SWE:ACPR:TIME 1S

Remote: SWE:ACPR:TIME:AUTO OFF

Sweep Count (General Settings dialog box)

Specifies the number of sweeps to be performed for Spectrum ACP/ACPR and Spectrum Mask

measurements.

Remote: SWE:COUNt 64

Trigger Mode (General Settings dialog box)

Sets the trigger source for the measurement sweep.

Free Run The measurement sweep starts immediately.

External The measurement sweep starts if the external trigger signal meets or

exceeds the external trigger level (a fixed value that cannot be altered) at

the input connector EXT TRIGGER/GATE IN on the rear panel.

Power The measurement sweep starts if the signal power meets or exceeds the

specified power trigger level.

Remote: TRIG:MODE IMM

Trigger Offset (General Settings dialog box)

Specifies the time offset between the trigger signal and the start of the sweep. A negative value

indicates a pre–trigger. This field is not available in the Free Run trigger mode.

Remote: TRIG:HOLD 500us

Power Level (General Settings dialog box)

Specifies the trigger level if the Power trigger mode is set (see Trigger Mode field).

Remote: TRIG:LEV:POW 10 DBM

Auto Lvl (General Settings dialog box)

Activates or deactivates the automatic measurement of the power trigger level if the Power

trigger mode is set (see Trigger Mode field).

On The power trigger level is measured automatically at the start of each measurement

sweep. This ensures that the power trigger level is always set at the optimal level for

obtaining accurate results but will result in a slightly increased measurement times.

Off The power trigger level is defined manually in the Power Level field.

Remote: TRIG:LEV:POW:AUTO ON

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.456 E-11

Auto Level Time (General Settings dialog box)

Specifies the sweep time used for the automatic level measurements.

Remote: CONF:POW:AUTO:SWE:TIME 200MS

Ref Level (General Settings dialog box)

Specifies the reference level used for measurements. If the reference level is modified, the

signal level is updated accordingly (depending on the currently selected standard and

measurement type). This field is only editable if the Auto Lev option is deactivated.

Remote: DISP:TRAC:Y:RLEV?

Attenuation (General Settings dialog box)

Specifies the settings for the attenuator. This field is only editable if the Auto Lev option is

deactivated. If the Auto Lev option is activated, the RF attenuator setting is coupled to the

reference level setting.

Remote: INP:ATT 30dB

Swap IQ (General Settings dialog box)

Activates or deactivates the inverted I/Q modulation.

On I and Q signals are interchanged.

Off Normal I/Q modulation.

Remote: SWAP ON

RSSI, CINR avg. (General Settings dialog box)

Specifies the mean and standard deviation for the RSSI and CINR results (see IEEE Std

802.16–2004 "8.3.9.2 RSSI mean and standard deviation'', "8.3.9.3 CINR mean and standard

deviation'').

Remote: CONF:WIM:AVER 0.1

List Results Unit (General Settings dialog box, IEEE 802.16–2004 OFDM)

Specifies the units for the results in the results summary table.

Remote: UNIT:TABL DB

SMU Address (General Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Specifies the TCP/IP address of an external R&S SMU signal generator connected via TCP/IP.

This enables the R&S FSL to download the frame zone setup directly.

Remote: SYST:COMM:TCP:ADDR 192.168.1.1

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.457 E-11

Burst Type (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Specifies the type of burst to be included in measurement analysis. Only one burst type can be

selected for the measurement results. The OFDM burst type is supported.

Link Mode (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Specifies the link mode of bursts that are to be included in measurement analysis. The following

link mode types are supported:

UL Up Link

DL Down Link

Remote: CONF:WIM:LMOD UL

Use FCH Content (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Activates or deactivates the decoding of the captured burst data FCH field.

OFF This is the default setting and cannot be altered currently.

ON Only the bursts with a modulation format matching the format specified in the

Demodulator list are included in the results analysis.

Mod. Detection (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Specifies the demodulation of the signal. The following values are supported:

None No modulation detection is performed. The signal will be analyzed according

to the Demodulator setting. Therefore the Demodulator setting must match

with the modulation format of the subframe. This setting excludes the analysis

of multiple modulation formats in a subframe.

First

Symbol

The first data symbol specifies the modulation format, i.e. the signal will be

analyzed according to the modulation format of the first data symbol. This

setting supports multiple modulation formats in a subframe.

If First Symbol is selected, the Demodulator setting is disabled and is

automatically updated with the modulation scheme detected in the first

symbol.

User Only bursts matching the setting in the Demodulator list are analyzed. This

setting supports multiple modulation formats in a subframe.

All All bursts individual payload modulations are analyzed accordingly. This

setting is useful to get an overview of the signal content.

Remote: DEM:FORM:AUTO FIRS

Demodulator (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Defines the modulation format for signal analysis if the Mod. Detection is set to None or User

(see Mod. Detection field).

The measurement application does not distinguish between different coding rates for the same

modulation format. If the signal to be analyzed contains the profiles (modulation format A, coding

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.458 E-11

rate B) and (modulation format C, coding rate D), the signal to be analyzed must hold the

following condition in order to produce correct measurement results:

[A == C



B== D]

Remote: DEM:FORM:BAN '16QAM1/2

Subchannelization (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Activates or deactivates the subchannelization, if the Up Link mode is set (see Link Mode

field). If activated, the subchannel index of uplink bursts is analyzed, defined by the Index field.

Remote: SUBC:STAT ON

Index (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Defines the subchannelization index of uplink bursts to be analyzed. Subchannelization index 16

is the default subchannel with full occupation.

Remote: SUBC 12

UL Phys. Modifier (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Specifies a common UL physical modifier for all uplink bursts.

Remote: SUBC:ULPH 1

Equal Burst Length (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Activates or deactivates the burst selection for measurement analysis according to the range or

specific number of data symbols/bytes.

On Only bursts with exactly the number of symbols specified in the

Data Symbols field are considered for measurement analysis.

Off Only bursts within the range of data symbols specified by the

Min Data Symbols and Max Data Symbols fields are

considered for measurement analysis.

Remote: DEM:FORM:BAN:SYMB:EQU ON

Data Symbols (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Specifies the number of symbols that a burst must have to be considered for measurement

analysis. This field is only available if the Equal Burst Length option is activated.

Remote: DEM:FORM:BAN:SYMB:MIN 16

Min Data Symbols (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Specifies the minimum number of data symbols that a burst must have to be considered in

measurement analysis. This field is only available if the Equal Burst Length option is

deactivated.

Remote: DEM:FORM:BAN:SYMB:MIN 16

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.459 E-11

Max Data Symbols (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Specifies the maximum number of data symbols that a burst must have to be considered in

measurement analysis. This field is only available if the Equal Burst Length option is

deactivated.

Remote: DEM:FORM:BAN:SYMB:MAX 1300

Channel Estimation (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Specifies how accurately the EVM results are calculated.

Preamble The channel estimation is performed in the preamble as required in the

standard.

Payload The channel estimation is performed in the payload.

Remote: DEM:CEST ON

Phase (Demod Settings dialog box)

Activates or deactivates the compensation for the phase error. If activated, the measurement

results are compensated for phase error on a per–symbol basis.

Remote: TRAC:PHAS ON

Timing (Demod Settings dialog box)

Activates or deactivates the compensation for the timing error. If activated, the measurement

results are compensated for timing error on a per–symbol basis.

Remote: TRAC:TIME ON

Level (Demod Settings dialog box, IEEE 802.16–2004 OFDM)

Activates or deactivates the compensation for the level error. If activated, the measurement

results are compensated for level error on a per–symbol basis.

Remote: TRAC:LEV ON

Downlink (DL) (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Specifies how channel estimation is performed for downlink signals.

Preamble Only The channel estimation is performed in the preamble only.

Preamble and Payload The channel estimation is performed in the preamble and in the

payload (payload comprises pilots and data).

Payload Only The channel estimation is performed in the payload only.

Remote: DEM:CEST PREAMPAYL

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.460 E-11

Uplink (UL) (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Displays the channel estimation performed for uplink signals.

This field is for information purposes only as channel estimation for uplink signals are always

performed in payload only (payload comprises pilots and data).

Modulation Analysis Scope (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Displays the modulation formats to be analyzed.

This field is for information purposes only as all detected modulation schemes are analyzed.

Demodulator (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Displays the modulation scheme detected in the analyzed signal. For signals using multiple

modulation schemes, the modulation scheme with the highest data rate is displayed. The field

also indicates the limits that are applied to the EVM results in the table or results.

This field is for information purposes only.

Remote: DEM:FORM:BAN?

Pilots for Tracking DL (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Specifies how, for downlink signals, the pilot sequence is determined for tracking purposes.

According to Standard The pilot sequence is computed according to the standard.

Detected The pilot sequence uses the values detected in the signal.

Remote: TRAC:PIL DET

Pilots for Tracking UL (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Displays how, for uplink signals, the pilot sequence is determined for tracking purposes.

This field is for information purposes only as tracking is performed according to the selected

standard.

FFT start offset rel to CP center (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Adds an offset to the FFT starting point determined by the application.

The setting range is from –100% to +100% of the cyclic prefix (CP) length. In the case of 0%,

the optimal FFT starting point, determined by the application, is used. This is the default setting.

Remote: FFT:OFF 0

File Name (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Displays the name of the loaded *.WIMAX settings file. If no file is loaded the '….' is displayed.

This field is for information purposes only.

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.461 E-11

IDCell (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Specifies the downlink IDCell number and affects the definition of the preamble sequence (in

conjunction with the used segments according to the Used Subchannel Bitmap setting), the

pilot sequence of the first zone and the subchannel definition of the first zone.

Remote: CONF:WIM:DLSF:IDC 0

Preamble Mode (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Specifies how the preamble index is calculated.

Auto The preamble index is automatically calculated according to the IDCell and Used

Subchannel Bitmap parameters.

User The preamble index can be specified manually, i.e. the preamble pattern is chosen

according to the standard using the Preamble Index parameter.

Remote: CONF:WIM:DLSF:PRE:MODE AUTO

Preamble Index (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Specifies the preamble pattern (according to the standard) to be used, if the Preamble Mode

parameter is set to User.

Remote: CONF:WIM:DLSF:PRE:IND 31

Used Subchannel Bitmap (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Assigns subchannel groups to segments, see [802.16e–2005], page 360, table 268a

"Subchannel index of the six subchannel groups". This table defines how many subchannels are

available for the Burst List (Frame Config tab) belonging to the corresponding segment of a

DL–PUSC zone (with Use All Subchannels being false). In the burst list – corresponding to the

segment – this selection controls the height of the white area in the burst map.

Remote: CONF:WIM:DLSF:SEGM1 63

Frame Number (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Specifies the number of the frame to be analyzed. For UL subframe analysis, the frame number

must be constant for the signal to be analyzed.

Remote: CONF:WIM:ULSF:FRAM 0

Allocated Subchannel Bitmap (Demod Settings dialog box, IEEE 802.16e–2005 OFDMA/WiBro)

Specifies the subchannels to be analyzed.

This parameter is for information purposes only as all subchannels are used in the UL subframe.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.462 E-11

List Zone/Burst (IEEE 802.16e–2005 OFDMA/WiBro)

Sets the focus on the Zone/Segment List or the Burst List to enter and modify data. To insert,

copy, and delete rows, use the softkeys available with the Frame Config tab.

The content of the selected list is graphically displayed under the Zone/Segment Map and the

Burst Map respectively.

The Zone/Segment List contains the following columns:

Column Description

ID Provides a unique ID for the zone. This parameter is read only. If there are any errors in the

zone/segment configuration, the background is displayed in red color.

Bursts Pressing the rotary knob or the ENTER key with focus on this field changes the focus to the

Burst List and displays the Burst Map.

Analyze Defines the zone/segment to be analyzed. Only one zone/segment can be selected for analysis

at any given time.

Zone Defines the zone type. The following types are supported: DL–PUSC, DL–FUSC, UL–PUSC

Segment Defines the segment for a DL–PUSC zone.

For DL–FUSC zones, this parameter has no effect.

Length Defines the length in OFDMA symbols of the zone.

The zone length must be a multiple of the symbol numbers per slot. If this is not the case, an

error message is displayed in the status bar and the measurement does not start.

Offset Defines the offset in OFDMA symbols from the start of the subframe.

The first DL–PUSC zone starts with 1. The first UL–PUSC zone starts with 0.

PermBase Specifies the permbase that is required for the calculation of the subchannel – physical carrier

assignment permutation.

PRBS_ID Specifies the permbase ID that is required for the calculation of the pilot sequence.

Fig. 4-54 Definition of the Zone Offset [green arrow] and the Zone Length [violet arrow] parameters

from the Zone/Segment List

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.463 E-11

The Burst List contains the following parameters, depending on the zone selection:

Column Description Zone

restrictions

ID Provides a unique ID for the burst. This parameter is read only. The background

color of this parameter reflects the modulation of the burst. If there are any errors in

the burst configuration then the background of this item will be red.

Modulation Defines the modulation format of the burst. In the Burst Map,identical modulation

formats are displays in the same color.

No. of Subch. Defines the number of logical subchannels occupied by the burst. DL_FUSC,

DL_PUSC

No. of Symb. Defines the number of OFDMA symbols occupied by the burst.

It must be a multiple of the symbol numbers per slot. If this is not the case, an error

message is displayed in the status bar and the measurement does not start.

DL_FUSC,

DL_PUSC

Duration

[Slots]

Specifies the unit of time for the allocating bandwidth. UL_PUSC

Auto If selected, the Offset Subch. and the Offset Symb. parameters are set

automatically.

UL_PUSC

Offset Subch. Defines the offset in logical subchannels from subchannel 0.

Offset Symb. Defines the offset in OFDMA symbols. It must be a multiple of the number of

symbols per slot. If this is not the case, an error message is displayed in the status

bar and the measurement does not start.

The start of the zone defines symbol 0.

Power[dB] Defines the boosting factor of the burst.

Burst Type Defines the burst type from the protocol layer perspective. DL_FUSC,

DL_PUSC

Fig. 4-55 Definition of the Burst Offset [green arrows] and the Burst Length [violet arrows]

parameters from the Burst List

The Zone/Segment Map and the Burst Map display panes are located at the bottom of the

Frame Config tab. They display a graphical view of the selected Zone/Segment List.

–Zone/Segment Map

Displays a graphical view of the selected Zone/Segment List.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.464 E-11

–Burst Map

Displays a graphical view of the selected Burst List.The background color of each burst in the

diagram match the modulation format of the burst. Any burst that is incorrectly configured is

displayed with a red background. The measurement does only start if the frame definition is

correct.

Example:

The Burst Map with burst 1 exceeds the available amount of logical subchannels. The area

causing the problem is highlighted red.

The configuration is corrected by doing one of the following:

a) Reducing the number of subchannels for burst 1 in the Burst List.

b) Assigning more subchannels to the zone/segment to which burst 1 belongs.

c) Increasing NFFT.

Remote: CONFigure:WIMax:ZONE<1…26>...,for details see CONFigure Subsystem

(WiMAX/WiBro, K93)

Copy Zone/Burst (IEEE 802.16e–2005 OFDMA/WiBro)

Copies the selected zone or burst to the clipboard.

Insert Zone/Burst (IEEE 802.16e–2005 OFDMA/WiBro)

Pastes the zone or burst below the focused zone or burst.

New Zone/Burst (IEEE 802.16e–2005 OFDMA/WiBro)

Inserts a new zone or burst below the focused zone or burst.

Remote: CONF:WIM:ZONE1:CONT ON,DLFUSC,0,10,0,0,0 (zone)

Remote: CONF:WIM:ZONE1:BURS1:CONT QAM16_1_2,1D2,5,10,20,0,0,0, DATA (burst)

New Segment (IEEE 802.16e–2005 OFDMA/WiBro)

Inserts a new segment below the focused zone/segment. This softkey is only available, if the

focus is on the Zone/Segment List.

Delete Zone/Burst (IEEE 802.16e–2005 OFDMA/WiBro)

Deletes the focused zone or burst.

Remote: CONF:WIM:ZONE1:DEL (zone)

Remote: CONF:WIM:ZONE1:BURS1:DEL (burst)

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.465 E-11

Display Graph/List

Configures the result display. The measurement results are displayed either in form of a list of

measurement points or as a graphical trace.

For details on the result displays refer to "Result summary list" on page 4.445 and "Result

display graph" on page 4.446.

Remote: DISP:TABL OFF

Remote: for result queries see section FETCh Subsystem

PVT

Opens the PVT submenu to select the Power vs Time measurement results.

The PVT result displays show the measured input data over the full range or over complete

bursts, displayed within the gating lines if gating is switched on. The results are displayed as a

single burst. If the gate start or gate length are altered then the results can be updated to reflect

these changes by pressing the Refresh softkey in the sweep menu.

Remote: CONF:BURS:PVT

Full Burst (IEEE 802.16–2004 OFDM)

Displays the PVT results in a single graph with all burst data being displayed (Display Graph

selected), or in a list (Display List selected).

For further details refer to the PVT softkey.

Remote: CONF:BURS:PVT:SEL FULL

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.466 E-11

Start End (IEEE 802.16–2004 OFDM)

Displays the results in two separate graphs, the left hand side showing the start and the right

hand side showing the end of a burst (Display Graph selected), or in a list (Display List

selected).

Remote: CONF:BURS:PVT:SEL EDGE

Burst Selection (IEEE 802.16–2004 OFDM)

Opens an edit dialog box to select a burst by entering its number.

Remote: CONF:BURS:PVT:BURS 1

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.467 E-11

Full Subframe (IEEE 802.16e–2005 OFDMA/WiBro)

Displays the results in a single graph with the minimum, mean, and maximum power profile of

the subframe that contains the zone selected to be analyzed (Display Graph selected), or in

two lists (Display List 1/2 selected).

Remote: CONF:BURS:PVT:SEL FULL

Rising/Falling (IEEE 802.16e–2005 OFDMA/WiBro)

Displays the results in two separate graphs: the minimum, mean, and maximum power profile of

rising (on the left hand) respective falling (on the right hand) edge of the subframe that contains

the zone selected to be analyzed (Display Graph selected), or in two lists (Display List 1/2

selected).

Remote: CONF:BURS:PVT:SEL EDGE

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.468 E-11

Gating Settings On/Off (Spectrum Mask, Spectrum FFT, Spectrum ACPR, CCDF)

Activates or deactivates gating, or opens the Gate Settings dialog box to specify range of

captured data used in results calculation.

On Uses only the specified range of captured data in results calculation. In the

Magnitude Capture Buffer trace, two vertical lines mark the specified range.

Off Uses all the captured data in results calculation.

In the Gate Settings dialog box, the following parameters are set:

Delay Start point of captured data to be used in results calculation, i.e.

the delay from the start of the captured data in time or samples.

If the delay is specified in time, the number of samples is

updated accordingly, and vice versa.

Length Amount of captured data to be used in results calculation. If the

length is specified in time, the number of samples is updated

accordingly, and vice versa.

Link Gate and Marker If activated, the position of the marker and the gate lines are

linked. The marker is positioned half way between gate start and

end. The marker position alters if the gate is modified, and the

gate lines move with the marker if the marker position is altered.

The gate settings are defined for following measurements: Spectrum FFT, CCDF, Spectrum

Mask, Spectrum ACPR.

If a frequency sweep measurement is active (Spectrum Mask and Spectrum ACP), the result

display is switched to the Magnitude Capture Buffer display in order to help defining the gate

settings correctly.

Remote: SWE:EGAT ON

Remote: SWE:EGAT:HOLD 125us,SWE:EGAT:HOLD:SAMP 2500 (Delay)

Remote: SWE:EGAT:LENG 100ms,SWE:EGAT:LENG:SAMP 2000000 (Length)

Remote: SWE:EGAT:LINK ON (Link Gate and Mark)

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.469 E-11

SEM Settings (IEEE 802.16e–2005 WiBro)

Opens the Spectrum Emission Mask Settings dialog box to configure the Spectrum Emission

Mask measurement.

SEM according to Specifies how the Spectrum Emission Mask settings and limits are

applied:

TTA Standard – as specified in the standard.

User – as specified in the selected XML file

File Name Specifies the XML file name

Link Direction Sets the link direction:

UL – uplink, DL – downlink

Power Class Sets the power class:

Auto – automatic selection

(–INF, 23) dBm,(23, INF) dBm – power class values for uplink

(–INF, 29) dBm,(29, 40) dBm,(40, INF) dBm – power class values

for downlink

The other parameters are set by default.

The SEM Configuration shows the settings and limits applied over specified frequency ranges

around the TX channel. The settings displayed are dependent on the selected Link Direction

and Power Class.

This softkey is available from firmware version 1.60.

Remote: POW:SEM:TTA STANDARD (SEM according to)

Remote: POW:SEM:MOD UL (Link Direction)

Remote: POW:SEM:CLAS 0 (Power Class)

Import

Opens the Choose iqw file to import dialog box.

Enter the path and the name of the IQ data file you want to import. Focus the Select button and

press ENTER to load the specified IQ data file. The Select button becomes active only, if the

entered name matches a file name in the selected directory.

Remote: MMEM:LOAD:IQ:STAT 1,'C:\R_S\Instr\user\data.iqw'

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.470 E-11

Export

Opens the Choose iqw file to export dialog box.

Enter the path and the name of the IQ data file you want to export. Press ENTER to write the IQ

data into the specified file. If the file cannot be created or there is no valid IQ data to export an

error message is displayed.

Remote: MMEM:STOR:IQ:STAT 1,'C:\R_S\Instr\user\data.iqw'

R&S Support

Creates files that help identifying the current problem. The files are stored under

C:\R_S\Instr\user\Support. If you contact the Rohde&Schwarz support to get help for a certain

problem, send these files to the support in order to identify and solve the problem faster.

EVM Constell

Opens a submenu to select the error vector magnitude (EVM) or the constellation result

displays.

EVM vs Symbol/Carrier

Selects the EVM vs Symbol or EVM vs Carrier result displays.

–EVM vs Symbol (IEEE 802.16–2004 OFDM)

This result display shows the EVM measured over the full range of the measured input data.

The results are displayed on a per–symbol basis, with blue vertical lines marking the

boundaries of each burst. Note that burst boundary lines are only displayed if the number of

analyzed bursts is less than 250. The minimum, average, and maximum traces are displayed.

For the trace labeled with EVM a commonly used EVM definition is applied, which is the square

root of the momentary error power normalized by the averaged reference power. For details of

this measurements please refer to chapter 2.

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.471 E-11

–EVM vs Symbol (IEEE 802.16e–2005 OFDMA/WiBro)

This result display shows all EVM values versus the symbols of the analyzed zone. If the

capture buffer contains more than one analyzed zones, the corresponding result graphs will be

appended. The minimum, mean, and maximum statistics is performed over carriers.

–EVM vs Carrier (IEEE 802.16–2004 OFDM)

This result display shows all EVM values recorded on a per–carrier basis over the full set of

measured data. The minimum, average and maximum traces are displayed.

–EVM vs Carrier (IEEE 802.16e–2005 OFDMA/WiBro)

This result display shows all EVM values versus the physical carriers. The minimum, mean, and

maximum statistics is performed over the symbols of all analyzed zones in the capture buffer.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.472 E-11

Remote: CONF:BURS:EVM:ESYM (EVM vs Symbol)

Remote: CONF:BURS:EVM:ECAR (EVM vs Carrier)

Error Frequency/Phase (IEEE 802.16–2004 OFDM)

Selects the Frequency Error vs Preamble or the Phase Error vs Preamble result displays.

These result displays show the error values recorded over the preamble part of the burst. A

minimum, average and maximum trace are displayed. The results display either relative

frequency error or phase error.

Using the Y–Axis/Div softkey, the scaling of the y–axis can be modified to allow the results to

be scaled to an optimum level.

Remote: CONF:BURS:PRE

Remote: CONF:BURS:PRE:SEL FREQ (Frequency Error vs Preamble)

Remote: CONF:BURS:PRE:SEL PHAS (Phase Error vs Preamble)

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.473 E-11

Constell vs Symbol/Carrier

Selects the Constellation vs Symbol or the Constellation vs Carrier result displays.

–Constellation vs Symbol (IEEE 802.16–2004 OFDM)

This result display shows the in–phase and quadrature phase results over the full range of the

measured input data. The ideal points for the selected modulations scheme are displayed for

reference purposes.

The amount of data displayed in the Constellation result display can be reduced by selecting

the carrier or carriers for which data is to be displayed (Carrier Selection softkey).

–Constellation vs Symbol (IEEE 802.16e–2005 OFDMA/WiBro)

This result display shows the complex constellation diagram of the modulation symbols. The

modulation symbols belong to the bursts of the analyzed zone. The different modulation

formats are displayed in unique colors. The same color assignment is used in the Bitstream

result display.

The amount of data displayed in the Constellation result display can be reduced via the

Constell Selection softkey.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.474 E-11

–Constellation vs Carrier (IEEE 802.16–2004 OFDM)

This result display shows the in–phase and quadrature phase results over the full range of the

measured input data plotted on a per–carrier basis. The magnitude of the in–phase and

quadrature part is shown on the y–axis, both are displayed as separate traces (I–> trace 1, Q–>

trace 2).

Remote: CONF:BURS:CONS:CSYM (Constellation vs Symbol)

Remote: CONF:BURS:CONS:CCAR (Constellation vs Carrier)

Carrier Selection (IEEE 802.16–2004 OFDM)

Opens a dialog box to select the carrier for data display. Either a specific carrier number, pilots

only or all carriers can be selected.

Remote: CONF:BURS:CONS:CARR:SEL –26

Constell Selection (IEEE 802.16e–2005 OFDMA/WiBro)

Opens a dialog box for filtering the displayed results. The results may be filtered by any

combination of modulation, burst, symbol, or carrier. If the constellation selection parameters are

changed, the result display is updated accordingly.

Remote: CONF:BURS:CONS:SYMB:SEL 1 (symbol)

Remote: CONF:BURS:CONS:FORM:SEL QPSK (modulation)

Remote: CONF:BURS:CONS:BURS:SEL 1 (burst)

Y–Axis/Div (EVM vs Symbol/Carrier, Error Frequency/Phase)

Opens a dialog box to modify the y–axis settings:

Auto Scaling If activated, the scaling of the y–axis is calculated automatically.

Per Division Specifies the scaling to be used if Auto Scaling is deactivated.

Unit Specifies the y–axis unit.

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.475 E-11

This softkey is only available for the above mentioned measurements if trace data are displayed.

Remote: DISP:WIND2:TRAC1:Y:AUTO ON (Auto Scaling)

Remote: DISP:WIND2:TRAC1:Y:PDIV 2 (Per Division)

Remote: UNIT:EVM PCT (Unit – EVM vs Symbol/Carrier)

Remote: UNIT:PRE HZ (Unit – Error Frequency/Phase)

Spectrum

Opens a submenu for frequency measurements.

Spectrum Flat./Diff./Group Delay

Sets the Spectrum Flatness result displays in graphical form (Display Graph selected), or in

tabular form (Display List 1/2 selected).

–Spectrum Flatness and Spectrum Flatness Group Delay (IEEE 802.16–2004 OFDM)

These result displays show either the Spectrum Flatness or the Group Delay values recorded

on a per–carrier basis over the full set of measured data. A minimum, average and maximum

trace are displayed for each of the result types. If the Spectrum Flatness result display is

selected an upper and lower limit line representing the limits specified for the selected standard

are displayed. An overall pass/fail status is displayed for the obtained (average) results against

these limit lines.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.476 E-11

–Spectrum Flatness and Spectrum Flatness Group Delay (IEEE 802.16e–2005 OFDMA/WiBro)

This result display shows the average energy of the constellations for the physical carriers. The

limit lines are displayed according to the requirements of the standard. The minimum, mean,

and maximum statistics is performed over the analyzed zones in the capture buffer.

–Spectrum Flatness Difference (IEEE 802.16–2004 OFDM)

This result display shows the adjacent carrier power difference of the preamble part of the

burst. A minimum, average and maximum trace are displayed.

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.477 E-11

–Spectrum Flatness Difference (IEEE 802.16e–2005 OFDMA/WiBro)

This result display shows the absolute difference of adjacent carriers. The limit lines are

displayed according to the requirements of the standard. The minimum, mean, and maximum

statistics is performed over the analyzed zones in the capture buffer.

Remote: CONF:BURS:SPEC:FLAT

Remote: CONF:BURS:SPEC:FLAT:SEL FLAT (Spectrum Flatness)

Remote: CONF:BURS:SPEC:FLAT:SEL GRD (Spectrum Flatness Group Delay)

Remote: CONF:BURS:SPEC:FLAT:SEL DIFF (Spectrum Flatness Difference)

Spectrum IEEE/ETSI (IEEE 802.16–2004 OFDM, IEEE 802.16e–2005 OFDMA) /

Spectrum Mask (IEEE 802.16e–2005 WiBro)

Sets the Spectrum (Emission) Mask result display. For the IEEE 802.16–2004 OFDM, IEEE

802.16e–2005 OFDMA standards, the result is displayed in graphical form (Display Graph

selected), or in tabular form (Display List 1/2 selected). For the IEEE 802.16e–2005 WiBro

standard, graph and table are displayed combined.

This result display shows power against frequency. A limit line representing the spectrum mask

specified for the selected standard is displayed and an overall pass/fail status is displayed for

the obtained results against this limit line.

For the IEEE 802.16–2004 OFDM, IEEE 802.16e–2005 OFDMA standards, the span of the

results is related to the specified sample rate.

For the IEEE 802.16e–2005 WiBro standard, the table contains the results for each of the

individual frequency ranges. On the trace, the highest power value is marked for each of the

specified frequency ranges with a marker.

The number of sweeps is set in the General Settings dialog box, Sweep Count field. If the

measurement is performed over multiple sweeps both a max hold trace and an average trace

are displayed. For the IEEE 802.16e–2005 WiBro standard, the Spectrum Emission Mask

measurement is configured via the SEM Settings softkey.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.478 E-11

–Spectrum IEEE (IEEE 802.16–2004 OFDM)

–Spectrum IEEE (IEEE 802.16e–2005 OFDMA)

–Spectrum ETSI (IEEE 802.16–2004 OFDM)

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.479 E-11

–Spectrum ETSI (IEEE 802.16e–2005 OFDMA)

–IEEE 802.16e–2005 WiBro

Remote: CONF:BURS:SPEC:MASK

Remote: CONF:BURS:SPEC:MASK:SEL IEEE

Remote: CONF:BURS:SPEC:MASK:SEL ETSI

Spectrum FFT

Sets the Spectrum FFT result display in graphical form (Display Graph selected), or in tabular

form (Display List 1/2 selected).

This result display shows the Power vs Frequency results obtained from a FFT performed over

the range of data in the Magnitude Capture Buffer which lies within the gate lines. If the gate

start or gate length are altered then the results can be updated to reflect these changes by

pressing the Refresh softkey in the sweep menu.

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.480 E-11

–IEEE 802.16–2004 OFDM

–IEEE 802.16e–2005 OFDMA/WiBro

Remote: CONF:BURS:SPEC:FFT

ACPR Abs/Rel

Sets the ACPR (Adjacent Channel Power Relative) result display in graphical form (Display

Graph selected), or in tabular form (Display List 1/2 selected).

This result display is similar to the Spectrum Mask measurement, and provides information

about leakage into adjacent channels. The results show the relative power measured in the

three nearest channels either side of the measured channel. This measurement is the same as

the adjacent channel power measurement provided by the spectrum analyzer.

The number of sweeps is set in the General Settings dialog box, Sweep Count field. If the

measurement is performed over multiple sweeps both a max hold trace and an average trace

are displayed.

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.481 E-11

–IEEE 802.16–2004 OFDM

–IEEE 802.16e–2005 OFDMA/WiBro

Remote: CONF:BURS:SPEC:ACPR

Remote: CONF:BURS:SPEC:ACPR:SEL ABS

Remote: CALC2:MARK:FUNC:POW:RES? (result query)

Remote: CALC2:MARK:FUNC:POW:RES:MAXH? (result query)

ACP Settings

Opens the ACP Settings dialog box to configure the ACPR result display. By default, the ACP

settings are derived from the General Settings dialog box, Channel BW field.

Pane Field Description

Channels No. of Channels Specifies the number of channels adjacent to the transmit

channel to be measured.

If set to 0, only the transmit channel is measured.

TX/ACP Channel BW TX Specifies the bandwidth of the transmit channel to be measured

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.482 E-11

Pane Field Description

by the ACP measurement.

Adjacent,

Alternate 1,

Alternate 2,

Alternate 3,

Alternate 4

Specifies the bandwidth of the first to fifth channel before and

after the transmit channel to be measured.

ACP Channel Spacing Adjacent,

Alternate 1,

Alternate 2,

Alternate 3,

Alternate 4

Specifies the spacing of the first to fifth channel before and

after the transmit channel to be measured.

Remote: POW:ACH:ACP 3 (No. of Channels)

Remote: POW:ACH:BAND 30kHz (TX)

Remote: POW:ACH:SPAC 33kHz(Adjacent/TX)

Remote: POW:ACH:SPAC:ALT1 100kHz (Alternate 1 to 4/TX)

Remote: POW:ACH:BAND:ACH 30kHz (Adjacent)

Remote: POW:ACH:BAND:ALT2 30kHz (Alternate 1 to 4)

Statistics

Opens a submenu to display statistics measurement results.

CCDF

Sets the CCDF result display in graphical form (Display Graph selected), or in tabular form

(Display List 1/2 selected).

This result display shows the probability of an amplitude within the gating lines exceeding the

mean power measured between the gating lines. The x–axis displays power relative to the

measured mean power.

If the gate start or gate length are altered then the results can be updated to reflect these

changes by pressing the Refresh softkey in the sweep menu.

–IEEE 802.16–2004 OFDM

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.483 E-11

–IEEE 802.16e–2005 OFDMA/WiBro

Remote: CONF:BURS:STAT:CCDF

Bitstream

Sets the Bitstream result display in graphical form (Display Graph selected), or in tabular form

(Display List 1/2 selected).

–IEEE 802.16–2004 OFDM

This result display shows the demodulated data stream. These results are grouped by burst

and symbol. If no dialog boxes are displayed, the results can be scrolled through using the

cursor keys or rotary knob.

–IEEE 802.16e–2005 OFDMA/WiBro

This result display shows the modulation symbols of the bursts from the analyzed zone. The

different modulation formats are displayed in unique colors. The same color assignment is used

in the Constellation vs Symbol result display. The modulation symbols define bit sequences.

The mapping is defined in the standard. Signals with erroneous pilot sequences (i.e where the

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.484 E-11

detected pilot sequence does not match that according to the standard) are highlighted with a

red background.

The amount of data displayed in the Bitstream result display can be reduced via the Bit

Selection softkey.

Remote: CONF:BURS:STAT:BSTR

Burst Summary

This result display shows the summary data for the analyzed bursts. If no dialog boxes are

displayed, the results can be scrolled through using the cursor keys or rotary knob.

–IEEE 802.16–2004 OFDM

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.485 E-11

–IEEE 802.16e–2005 OFDMA/WiBro

This result display provides information about the bursts from the analyzed zone, i.e.

modulation of the burst, power boosting information, EVM of the burst. Each analyzed zone will

produce a set of burst results.

Remote: CONF:BURS:STAT:BSUM

Bit Selection (IEEE 802.16e–2005 OFDMA/WiBro)

Opens a dialog box for filtering the displayed results. The results may be filtered by any

combination of modulation, symbol or burst. If the bit selection parameters are changed, the

result display is updated accordingly.

This softkey is only available if the Bitstream measurement (Bitstream softkey) is selected.

Remote: CONF:BURS:BSTR:SYMB:SEL 1 (symbol)

Remote: CONF:BURS:BSTR:FORM:SEL QPSK (modulation)

Remote: CONF:BURS:BSTR:BURS:SEL 1 (burst)

File Manager (IEEE 802.16e–2005 OFDMA/WiBro)

Opens the File Manager dialog box. The File Manager provides the possibility to transfer

WiMAX settings from an R&S SMU signal generator via LAN. For step–by–step instructions see

"To transfer the current R&S SMU WiMAX setting via LAN" on page 4.447. The File Manager

also offers some general file management support.

The File Manager writes into the directory C:\R_S\Instr\user\WMAN and its subdirectories or a

USB memory stick only.

Under File Types,filter the displayed files by selecting:

All (*.*) All file types are displayed. Use this selection to perform general file

management tasks.

SMU WiMax Only files with the extension WiMAX are displayed.

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1300.2519.12 4.486 E-11

Depending on the focus, the following softkeys are provided:

–Recall

–New Folder

–Copy

–Paste

–Rename

–Delete File

For further information refer to section "Instrument Functions – Basic Settings", "Saving and

Recalling Settings Files – FILE Key".

Softkeys of the sweep menu (WiMAX mode)

The following table shows all softkeys available in the sweep menu in WiMAX mode (SWEEP key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Run Single/Cont

Auto Level

Refresh

Run Single/Cont

Selects the sweep mode.

Single single sweep mode

Cont continuous sweep mode

Asingle measurement will complete once the requested number of bursts have been obtained

or a single sweep has been completed, depending on the measurement settings. If a

measurement is completed in continuous mode, a new measurement will be started.

If a measurement is started while another measurement is in progress, the first measurement

will be aborted and the new measurement started immediately.

Remote: INIT:CONT OFF (single sweep mode)

Remote: INIT:CONT ON (continuous sweep mode)

Auto Level

Starts an automatic level detection measurement. After the automatic level detection has been

completed, the trace is displayed in the Magnitude Capture Buffer display.

If this softkey is pressed while a measurement is running, the current measurement is aborted

and the automatic level detection measurement is started. If the aborted measurement was a

continuous measurement, it is resumed after the automatic level detection is completed.

Remote: CONF:POW:AUTO ON

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.487 E-11

Refresh

Updates the current measurement results with respect to the current gate settings. This softkey

is only available if the measurement results are effected by the gate settings (Spectrum FFT,

CCDF, Spectrum Mask, Spectrum ACPR) and if the gate settings are modified after a

measurement result has been obtained.

Remote: INIT:REFR

Softkeys of the marker menu (WiMAX mode)

The following table shows all softkeys available in the marker menu in WiMAX mode (MKR key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description. Close all settings dialog boxes before opening the marker menu.

Command

Marker 1

Unzoom

Marker Zoom

Marker Off

Marker 1

Opens a dialog box to adjust the marker. The contents of the dialog box depends on the type of

graph the marker is adjusted to. After every change, the marker position in the trace and the

marker information are updated.

Remote: CALC1:MARK1 ON

Remote: CALC:MARK:X 2ms

Remote: CALC:MARK:Y?

Remote: CALC2:MARK:SYMB 2

Remote: CALC2:MARK:CARR –7

Unzoom

Cancels the marker zoom.

Remote: CALC:MARK:FUNC:ZOOM 1

Marker Zoom (Magnitude Capture Buffer, PVT, Constellation vs Symbol, Constellation vs

Carrier)

Opens an edit dialog box to select the magnification factor for the zoom. The maximum

magnification depends on the type of result display.

Remote: CALC:MARK:FUNC:ZOOM 4

WiMAX, WiBro Measurements (Options K92/K93) R&S FSL

1300.2519.12 4.488 E-11

Marker Off

Switches off all makers in the active result display.

Remote: CALC2:MARK:AOFF

Softkeys of the marker–> menu (WiMAX mode)

The following table shows all softkeys available in the marker–> menu in WiMAX mode (MKR–> key). It

is possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

MKR –> Trace

Opens an edit dialog box to enter the number of the trace, on which the marker is to be placed.

This softkey is available for all result displays with more than one trace.

Remote: CALC2:MARK:TRAC 2

Softkeys of the lines menu (WiMAX mode)

The following table shows all softkeys available in the lines menu in WiMAX mode (LINES key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

This menu is only available if the results are displayed in form of a list (for details see Result summary

list and Display Graph/List softkey).

Command

Default Current

Default All

Default Current

Resets all limits for the current modulation scheme to the values specified in the selected

standard.

Remote: see CALCulate:LIMit Subsystem

Default All

Resets all limits for all modulation schemes to the values specified in the selected standard.

Remote: see CALCulate:LIMit Subsystem

R&S FSL WiMAX, WiBro Measurements (Options K92/K93)

1300.2519.12 4.489 E-11

Softkeys of the trace menu (WiMAX mode)

The following table shows all softkeys available in the trace menu in WiMAX mode (TRACE key). It is

possible that your instrument configuration does not provide all softkeys. If a softkey is only available

with a special option, model or (measurement) mode, this information is delivered in the corresponding

softkey description.

Command

Display List/Graph

Screen Focus A/B

Screen Size Full/Split

Display List/Graph

For details refer to the Display Graph/List softkey in the WiMAX menu.

Screen Focus A/B

Selects the active screen for IQ measurement results in split and full screen mode. Only the

markers of an active screen can be controlled.

Remote: DISP:WIND1:SSEL

Screen Size Full/Split

Changes the display between split and full screen for IQ measurement results. Frequency

sweep measurement results are always displayed in full screen.

Remote: DISP:FORM SING

Instrument Functions - Basic Settings R&S FSL

1300.2519.12 4.490 E-11

Instrument Functions - Basic Settings

Inthis section, all basic settings functions of the R&S FSL and their application are explained in detail.

The analyzer functions are described in section "Instrument Functions - Analyzer".

For every key a table is provided in which all submenus and corresponding commands are listed. The

description of the submenus and commands follows the order of the table. The commands for the

optional remote control (if any) are indicated for each softkey. The description includes the following:

•"General Settings, Printout and Instrument Settings" on page 4.491

This section provides information on how to prepare measurements and process their results:

setting the instrument, managing and retrieving data, returning to manual operation, and printout.

More basic information on operation is given in the Quick Start Guide. The front and the rear view of the

instrument together with a table of all available keys and a short description are provided in chapter

"Front and Rear Panel". Chapter "Preparing for Use" informs how to start working with the instrument

for the first time. A brief introduction on handling the instrument is given in chapter "Basic Operations".

This includes also the description of the keys for basic operations like switching the instrument on and

off or starting a measurement.

R&S FSL Instrument Setup and Interface Configuration - SETUP Key

1300.2519.12 4.491 E-11

General Settings, Printout and Instrument Settings

After putting the instrument into operation and becoming familiar with the handling of the instrument (for

details see Quick Start Guide), the preparations for measurements can start. In this section the general

settings of the instrument, the data management and the processing of measurement results are

described. This includes the following topics and keys:

•"Instrument Setup and Interface Configuration - SETUP Key" on page 4.492

•"Saving and Recalling Settings Files - FILE Key" on page 4.510

•"Manual Operation - Local Menu" on page 4.519

•"Measurement Documentation - PRINT Key" on page 4.520

Instrument Setup and Interface Configuration - SETUP Key R&S FSL

1300.2519.12 4.492 E-11

Instrument Setup and Interface Configuration - SETUP Key

The SETUP key is used to set or display the default settings of the instrument: reference frequency,

noise source, level correction values, date, time, LAN interface, firmware update and enabling of

options, information about instrument configuration and service support functions. For further details

refer also to the Quick Start Guide, chapter 2 "Preparing for Use".

To open the setup menu

Press the SETUP key.

The setup menu is displayed.

Menu and softkey description

–"Softkeys of the setup menu" on page 4.492

To display help to a softkey, press the HELP key and then softkey for which you want to display help.

To close the help window, press the ESC key. For further information refer to section "How to use the

Help System".

Softkeys of the setup menu

The following table shows all softkeys available in the setup menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

Menu Command Submenu / Command Submenu / Command Command

Reference Int/Ext

Transducer Active On/Off

Edit Insert Line

Delete Line

Edit Name

Edit Unit

Edit Value

Interpolation Lin/Log

Save Factor

New same contents as Edit menu

Copy to same contents as Edit menu

Delete

Ref Level Adjust Man/Auto

Show Directory

IF Output

Noise Src On/Off

Alignment Self Align

Show Align Results

Corr Data On/Off

General Setup Configure Network

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1300.2519.12 4.493 E-11

Menu Command Submenu / Command Submenu / Command Command

Network Address Computer Name

IP Address

Subnet Mask

DHCP On/Off

LXI LAN Status On/Off

Info

Password

Description

LAN Reset

GPIB GPIB Address

ID String Factory

ID String User

GPIB Language

Display Update On/Off

More 

GPIB Terminator LFEOI/EOI

*IDN Format Leg./New

I/O Logging On/Off

Time+Date

Meas Display Screen Title

Time+Date On/Off

Logo On/Off

Annotation On/Off

Screen Colors Select Screen Color

Set

Color On/Off

Select Object

Predefined Colors

User Defined Colors

Set to Default

Print Colors Select Print Color Set

Color On/Off

Select Object

Predefined Colors

User Defined Colors

Set to Default

Display Pwr Save On/Off

Monitor Int/Ext

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1300.2519.12 4.494 E-11

Menu Command Submenu / Command Submenu / Command Command

Soft Frontpanel

More 

Firmware Update Firmware Update

Option Licenses Install Option

Shutdown Off/Standby

System Info Hardware Info

Versions+Options

System Messages

Clear All Messages

Service Input RF/Cal/TG

Comb Frequency

Reset Password

Selftest

Selftest Results

Password

Service Function

Reference Int/Ext

Switches between the internal and external reference signal source. The default setting is

internal reference. It is important, that the external reference signal is deactivated when

switching from external to internal reference to avoid interactions.

If the reference signal is missing when switching to external reference, the message EXREF is

displayed to indicate that no synchronization is performed.

The R&S FSL can use the internal reference source or an external reference source as

frequency standard from which all internal oscillators are derived. A 10 MHz crystal oscillator is

used as internal reference source. In the external reference setting, all internal oscillators of the

R&S FSL are synchronized to the external reference frequency (also 10 MHz). For details on

connectors refer to the Quick Start Guide, chapter 1 "Front and Rear Panel".

Remote: ROSC:SOUR INT

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1300.2519.12 4.495 E-11

Transducer

Opens the Select Transducer dialog box and a submenu to activate or deactivate defined

transducer factors, to generate new transducer factors or to edit existing ones.

In the Select Transducer dialog box, a transducer factor can be edited, deleted or copied, if

selected, using the corresponding softkeys. The default directory, in which the transducer factors

are saved, is displayed (C:\R_S\INSTR\TRD; the extension of transducer factor files is *.TDF).

Subdirectories can be added or deleted via the file manager. They are displayed or hidden using

the arrow keys or the Show Directory softkey / Hide Directory button.

Two different directory views are possible: If the Show all option is activated, all transducer

factors in the directory are displayed. If the Show compatible option is activated, only the

compatible transducer factors in the directory are displayed.

For details on transducer factors refer to chapter "Advanced Measurement Examples".

This softkey is available from firmware version 1.10.

Remote: CORR:TRAN:SEL FACTOR1

Active On/Off

Activates or deactivates the selected transducer factor. A maximum of 10 transducer factors can

be activated at the same time. If an additional transducer factor is activated, its unit compatibility

is checked. If one factor has a different unit than dB, all the other activated factors must have the

unit dB.

This softkey is available from firmware version 1.10.

Remote: CORR:TRAN:SEL <name>

Remote: CORR:TRAN ON

Edit

Opens the Edit Transducer dialog box with the data of the selected factor. During editing, a

transducer factor remains stored in the background until the factor is saved using the Save

Factor softkey.

This softkey is available from firmware version 1.10.

Remote: Comment: CORR:TRAN:COMM <string>

Insert Line

Inserts an empty line above the selected reference value to enter a new reference value. When

entering a new reference value in the line, the ascending order of frequencies must be taken into

consideration, however.

This softkey is available from firmware version 1.10.

Delete Line

Deletes the selected reference value (complete line). The reference values that follow move one

line up.

This softkey is available from firmware version 1.10.

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Edit Name

Sets the focus on the Name field to enter a file name. The extension is added automatically.

This softkey is available from firmware version 1.10.

Remote: CORR:TRAN:SEL <name>

Edit Unit

Sets the focus on the Unit field to select the unit.

This softkey is available from firmware version 1.10.

Remote: CORR:TRAN:UNIT <string>

Edit Value

Sets the focus to enter positions and values as frequency/level pairs. The entered data are also

displayed graphically. Using the Shift x or Shift y button, all entered values can be shifted in x

or y direction.

This softkey is available from firmware version 1.10.

Remote: CORR:TRAN:DATA <freq>,<level>

Interpolation Lin/Log

Sets the scaling of the x-axis to linear or logarithmic.

This softkey is available from firmware version 1.10.

Remote: CORR:TRAN:SCAL LIN|LOG

Save Factor

Saves the changed factor to a file on the internal flash disk. If a transducer factor with the same

name already exists, a confirmation query is displayed. If the new factor is active, the new

values are immediately applied.

This softkey is available from firmware version 1.10.

Remote: In remote control, the save operation is performed automatically after the definition of the

reference values.

New

Opens the Edit Transducer dialog box to enter data for a new factor.

This softkey is available from firmware version 1.10.

Copy to

Opens the Edit Transducer dialog box to copy the selected factor.

This softkey is available from firmware version 1.10.

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Delete

Deletes the selected factor after confirmation.

This softkey is available from firmware version 1.10.

Remote: CORR:TRAN DEL

Ref Level Adjust Man/Auto

Activates or deactivates the automatic adjustment of the reference level to the selected

transducer factor.

Auto Activates the automatic adjustment.

Man Deactivates the automatic adjustment. Adjust the reference level via the amplitude

menu.

If a transducer factor is used (active), the trace is moved by a calculated shift. However, an

upward shift reduces the dynamic range for the displayed values. With this softkey set to Auto,

the original dynamic range is restored by also shifting the reference level by the maximum value

of the transducer factor.

This softkey is available from firmware version 1.10.

Remote: CORR:TRAN:ADJ:RLEV ON

Show Directory

Displays the subdirectory of the selected directory.

This softkey is available from firmware version 1.10.

IF Output (option Additional Interfaces, B5 only)

Opens the IF Output Source dialog box to select the output of the IF/VIDEO OUT connector: IF,

Video 200 mV,or Video 1 V.

Note: The AF output available at the frontpanel can only be used if the IF output source is set to

video.

For further details refer to the Quick Start Guide, chapter 1 "Front and Rear Panel".

Remote: OUTP IF VID

Noise Src On/Off (option Additional Interfaces, B5 only)

Switches the supply voltage for an external noise source on or off. For details on connectors

refer to the Quick Start Guide, chapter 1 "Front and Rear Panel" .

Remote: DIAG:SERV:NSO ON

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Alignment

Opens a submenu with the available functions for recording, displaying and activating the data

for self alignment.

The correction data and characteristics required for the alignment are determined by comparison

of the results at different settings with the known characteristics of the high-precision calibration

signal source at 65.83 MHz. The correction data are stored as a file on flash disk and can be

displayed using the Show Align Results softkey.

Self Align

Starts the recording of correction data of the instrument. If the correction data acquisition has

failed or if the correction values are deactivated, a corresponding message is displayed in the

status field.

As long as the self alignment data is collected the procedure can be cancelled using the Abort

button.

Remote: *CAL?

Show Align Results

Opens a dialog box that displays the correction data of the alignment:

–date and time of last correction data record

–overall results of correction data record

–list of found correction values according to function/module

The results are classified as follows:

PASSED calibration successful without any restrictions

CHECK deviation of correction value larger than expected, correction could

however be performed

FAILED deviations of correction value too large, no correction was possible. The

found correction data are not applicable.

As long as the self alignment data is collected the procedure can be cancelled using the Abort

button.

Remote: CAL:RES?

Remote: CAL:ABOR

Corr Data On/Off

Activates and deactivates the alignment data, e.g. for service purposes the correction data can

be deactivated.

Remote: CAL:STAT ON

General Setup

Opens a submenu for all general settings such as IP address and LAN settings, date and time,

remote control (optional) and MEAS display.

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Configure Network

Opens the Network Connections dialog box to change the LAN settings. For details refer to the

Quick Start Guide, chapter 2 "Preparing for Use" and appendix B "LAN Interface".

Network Address

Opens a submenu to configure the internet protocol properties and the computer name.

Computer Name

Opens an edit dialog box to enter the computer name via the keypad. The naming conventions

of Windows apply. If too many characters and/or numbers are entered, in the status line, an

according message is displayed. For step-by-step instructions refer to the Quick Start Guide,

appendix B "LAN Interface".

IP Address

Opens an edit dialog box to enter the IP address via the keypad. The TCP/IP protocol is

preinstalled with the IP address 10.0.0.10. If the DHCP server is available (DHCP On), the

dialog box entry is read-only.

The IP address consists of four number blocks separated by dots. Each block contains 3

numbers in maximum (e.g. 100.100.100.100), but also one or two numbers are allowed in a

block (as an example see the preinstalled address). For step-by-step instructions refer to the

Quick Start Guide, chapter 2 "Preparing for Use".

Subnet Mask

Opens an edit dialog box to enter the subnet mask via the keypad. The TCP/IP protocol is

preinstalled with the subnet mask 255.255.255.0. If the DHCP server is available (DHCP On),

the dialog box entry is read-only.

The subnet mask consists of four number blocks separated by dots. Each block contains 3

numbers in maximum (e.g. 100.100.100.100), but also one or two numbers are allowed in a

block (as an example see the preinstalled address). For step-by-step instructions refer to the

Quick Start Guide, chapter 2 "Preparing for Use".

DHCP On/Off

Switches between DHCP server available (On) or not available (Off). If a DHCP server is

available in the network, the IP address and subnet mask of the instrument are obtained

automatically from the DHCP server. For further details refer to the Quick Start Guide, chapter 2

"Preparing for Use".

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LXI

Opens the LXI submenu containing the following softkeys:

LAN Status On/Off

Info

Password

Description

LAN Reset

LAN Status On/Off

Activates the LAN status bar that shows the current status of the LAN connection.

Depending on the status of the connection, the LXI logo in the LAN Status Indicator window

assumes the following states:

Red No connection is established

Green A connection is established

Blinking The device has not been identified

This softkey is availbale from firmware version 1.90.

Info

Shows the current parameter of LXI class C. The R&S FSL displays the current version, class

and various computer parameter like computer name or IP adress.

While active, the dialog is not updated.

This softkey is availbale from firmware version 1.90.

Remote: SYST:LXI:INF?

Password

Shows the currently set password. You can also change the current password using this softkey.

The password is needed to change settings via the web browser (e.g. IP parameter). An empty

password is not valid, i.e. you must enter a password.

By default, the password is LxiWebIfc.

This softkey is availbale from firmware version 1.90.

Remote: SYST:LXI:PASS <string>

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Description

Opens a dialog box to view or change the LXI instrument description. This description is used on

some of the LXI web sites.

By default, the description is 'Spectrum Analyzer/FSL/Serial #'

This softkey is availbale from firmware version 1.90.

Remote: SYST:LXI:MDES <string>

LAN Reset

Resets the LAN configuration to a state required by the LXI standard. For example, the TCP/IP

mode is set to DHCP and Dynamic DNS and ICMP Ping are enabled. In addition, the R&S FSL

sets the password and the instrument description to their initial states (see Password and

Description softkeys).

This softkey is availbale from firmware version 1.90.

Remote: SYST:LXI:LANR

GPIB (option GPIB Interface, B10 only)

Opens a submenu to set the parameters of the remote control interface.

GPIB Address (option GPIB Interface, B10 only)

Opens an edit dialog box to enter the GPIB address. Values from 0 to 30 are allowed. The

default address is 20.

If, e.g. after a firmware update, the R&S FSL does not maintain the GPIB address after reboot,

the shutdown file needs to be recreated. Perform the following steps:

–Set the GPIB address.

–Create a shutdown file by switching the R&S FSL in the standby mode:

Press the ON/STANDBY key on the front panel and wait until the yellow LED is on. With the

battery pack option, use a USB keyboard and terminate the R&S FSL firmware with ALT+F4 to

create the shutdown file.

If the shutdown file was created once, the R&S FSL boots with exactly those settings after a reboot

with the main switch on the rear panel. During a firmware update or cold boot for service reasons

the shutdown file is deleted, and the setup is necessary once again.

Remote: SYST:COMM:GPIB:ADDR 20

ID String Factory (option GPIB Interface, B10 only)

Selects the default response to the *IDN? query.

ID String User (option GPIB Interface, B10 only)

Opens an edit dialog box to enter a user-defined response to the *IDN? query. Max. 36

characters are allowed.

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GPIB Language (option GPIB Interface, B10 only)

Only the remote control language SCPI is available for the R&S FSL and is set by default.

Remote: SYST:LANG 'SCPI'

Display Update On/Off

Defines whether the instrument display is switched off when changing from manual operation to

remote control. In remote control mode, this softkey is displayed in the local menu (for details

refer to section "Manual Operation - Local Menu" on page 4.519).

Remote: SYST:DISP:UPD ON

GPIB Terminator LFEOI/EOI (option GPIB Interface, B10 only)

Changes the GPIB receive terminator.

According to the standard the terminator in ASCII is <LF> and/or <EOI>. For binary data

transfers (e.g. trace data) from the control computer to the instrument, the binary code used for

<LF> might be included in the binary data block, and therefore should not be interpreted as a

terminator in this particular case. This can be avoided by changing the receive terminator to EOI.

Remote: SYST:COMM:GPIB:RTER EOI

*IDN Format Leg./New

Defines the response format to the *IDN? remote command. This function is intended for re-use

of existing control programs together with the R&S FSL.

Leg. Legacy format, compatible to the R&S FSP/FSU/FSQ family

New R&S FSL format

Remote: SYST:FORM:IDEN LEG

I/O Logging On/Off (option GPIB Interface, B10 only)

Activates or deactivates the SCPI error log function. All remote control commands received by the

R&S FSL are recorded in the following log file:

C:\R_S\instr\ScpiLogging\ScpiLog.txt

Logging the commands may be extremely useful for debug purposes, e.g. in order to find misspelled

keywords in control programs.

Time+Date

Opens an edit dialog box to enter time and date for the internal real time clock. For details refer

to the Quick Start Guide, chapter 2 "Preparing for Use".

Remote: SYST:TIME 12,30

Remote: SYST:DATE 2004,10,01

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Meas Display

Opens a submenu to configure the display and the print colors.

This softkey is available from firmware version 1.10.

Screen Title

Activates/deactivates the display of a diagram title (if available) and opens an edit dialog box to

enter a new title for the active diagram. Max. 20 characters are allowed.

This softkey is available from firmware version 1.10.

Remote: DISP:TEXT 'Noise Meas'

Remote: DISP:TEXT:STATe ON

Time+Date On/Off

Activates/deactivates the display of date and time above the diagram.

This softkey is available from firmware version 1.10.

Remote: DISP:TIME OFF

Logo On/Off

Activates/deactivates the display of the Rohde & Schwarz company logo in the upper left corner.

This softkey is available from firmware version 1.10.

Remote: DISP:LOGO ON

Annotation On/Off

Activates/deactivates the display of the frequency information. For example to protect

confidential data it can be useful to hide the frequency information.

This softkey is available from firmware version 1.10.

Remote: DISP:ANN:FREQ ON

Screen Colors

Opens a submenu to configure the screen colors. For details on screen colors refer to the Quick

Start Guide, chapter 2 "Preparing for Use".

This softkey is available from firmware version 1.10.

Remote: DISP:CMAP2:HSL 0.3,0.8,1.0

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Select Screen Color Set

Opens the Select Screen Color Set dialog box to select default or user defined color settings.

Ifone of the default settings is selected (Default Colors 1/2), the default settings for brightness,

color tint and color saturation for all display screen elements are restored. The default color

schemes provide optimum visibility of all picture elements at an angle of vision from above or

below. Default setting is Default Colors 1.

If User Defined Colors is selected, a user-defined color set can be defined. For step-by-step

instruction refer to the Quick Start Guide, chapter 2 "Preparing for Use".

This softkey is available from firmware version 1.10.

Remote: DISP:CMAP:DEF2

Color On/Off

Switches from color display to black-and-white display and back. The default setting is color

display.

This softkey is available from firmware version 1.10.

Select Object

Opens the Color Setup dialog box to select the color settings for a selected object.

The Selected Object list is displayed to select the object. For setting the color the predefined

colors are displayed.

This softkey is available from firmware version 1.10.

Remote: DISP:CMAP2:HSL 0.3,0.8,1.0 (screen colors)

Remote: HCOP:CMAP2:HSL 0.3,0.8,1.0 (print colors)

Predefined Colors

In the Color Setup dialog box, displays the Predefined Colors (alternative to the Predefined

Colors button). This softkey is only available if, in the Select Color Set dialog box, the User

Defined Colors option is selected or the Color Setup dialog box is displayed. For further details

refer to the Quick Start Guide, chapter 2 "Preparing for Use".

This softkey is available from firmware version 1.10.

Remote: DISP:CMAP2:PDEF GRE (screen colors)

Remote: HCOP:CMAP2:PDEF GRE (print colors)

User Defined Colors

In the Color Setup dialog box, displays the User Defined Colors (alternative to the User

Defined Colors button). This softkey is only available if, in the Select Color Set dialog box, the

User Defined Colors option is selected or the Color Setup dialog box is displayed. For further

details refer to the Quick Start Guide, chapter 2 "Preparing for Use".

This softkey is available from firmware version 1.10.

Remote: DISP:CMAP2:HSL 0.3,0.8,1.0 (screen colors)

Remote: HCOP:CMAP2:HSL 0.3,0.8,1.0 (print colors)

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Set to Default

Opens the Set to Default dialog box to select one of the factory default color settings.

This softkey is available from firmware version 1.10.

Remote: DISP:CMAP:DEF2 (screen colors)

Remote: HCOP:CMAP:DEF2 (print colors)

Print Colors

Opens a submenu to select the colors for the printout. To facilitate color selection, the selected

color combination is displayed when the menu is entered. The previous colors are restored

when the menu is exited.

This softkey is available from firmware version 1.10.

Select Print Color Set

Opens the Select Print Color Set dialog box to select the color settings for printout.

Screen Colors (Print) Selects the current screen colors for the printout. The

background is always printed in white and the grid in

black.

Screen Colors (Hardcopy) Selects the current screen colors without any changes for

ahardcopy. The output format is set via the Device

Setup softkey in the print menu.

Optimized Colors Selects an optimized color setting for the printout to

improve the visibility of the colors (default setting). Trace

1is blue, trace 2 black, trace 3 green, and the markers

are turquoise. The background is always printed in white

and the grid in black.

User Defined Colors Enables the softkeys to define colors for the printout.

This softkey is available from firmware version 1.10.

Remote: HCOP:CMAP:DEF1

Color On/Off

Switches from color printout to black-and-white printout and back. All colored areas are printed

in white and all colored lines in black. This improves the contrast. The default setting is color

printout, provided that the selected printer can produce color printouts.

This softkey is available from firmware version 1.10.

Remote: HCOP:DEV:COL ON

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Display Pwr Save On/Off

Switches the power-save mode for the display on/off and opens an edit dialog box to enter the

time for the power-save function to respond. After the elapse of this time the display is

completely switched off, i.e. including backlighting. This mode is recommended when the

instrument is exclusively operated in remote control.

For details on the power-save mode for the display refer to the Quick Start Guide, chapter 2

"Preparing for Use".

This softkey is available from firmware version 1.10.

Remote: DISP:PSAV ON

Remote: DISP:PSAV:HOLD 15

Monitor Int/Ext

Switches from the internal instrument monitor to an external monitor and vice versa. The softkey

is only effective, if an external monitor is connected. For further details refer to the Quick Start

Guide, chapter 2 "Preparing for Use".

This softkey is available from firmware version 1.80.

Soft Frontpanel

Activates or deactivates the display of the instrument emulation.

deactivated Only the measurement screen is displayed. This is the setting for working at

the R&S FSL.

activated Additionally to the measurement screen, the whole front panel is displayed.

This is the setting for working at a computer with XP Remote Desktop or at

an external monitor.

Alternatively to this softkey, you can use the F6 key.

Remote: SYST:DISP:FPAN ON

Firmware Update

Opens a submenu to install firmware versions. The installation of a new firmware version can be

performed via USB or LAN interface. For details on installation refer to the Quick Start Guide,

chapter 3 "Firmware Update and Installation of Firmware Options".

Firmware Update

Opens the Firmware Update dialog box. The update path is changed by entering the new path

or via the Browse button. The installation is started via the Execute button. For details on

installation refer to the Quick Start Guide, chapter 3 "Firmware Update and Installation of

Firmware Options".

Remote: SYST:FIRM:UPD 'D:\FW_UPDATE'

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Option Licenses

Opens a submenu to install options. For details on options refer to the Quick Start Guide,

chapter 3 "Firmware Update and Installation of Firmware Options".

Install Option

Opens an edit dialog box to enter the license key for the option that you want to install.

Amessage box open if an option is about to expire or has already expired (in which case all

functions (including remote control) are unavailable until the R&S FSL is rebooted). For more

information about the option in question refer to the System Info softkey in the setup menu.

Shutdown Off/Standby

Configures the shutdown behavior of the R&S FSL when switched off via the ON/STANDBY key

on the front panel.

Off If activated, the R&S FSL is shutdown completely when switched off via the

ON/STANDBY key on the front panel. When switched on the next time, the

R&S FSL will completely reboot.

To prevent the instrument from overheating, the fan remains active.

Standby If activated, the R&S FSL goes into the standby mode when switched off via the

ON/STANDBY key on the front panel. When switched on the next time, the boot

time is shorter. This is the default setting.

This softkey is available from firmware version 1.80.

System Info

Opens a submenu to display detailed information on module data, device statistics and system

messages.

Hardware Info

Opens a dialog box that displays hardware information, e.g. on the frontend and motherboard.

Every listed component is described by its serial number, order number, model information,

hardware code, and hardware revision.

Remote: DIAG:SERV:HWIN?

Versions+Options

Opens a dialog box that displays a list of hardware and firmware information, e.g. the firmware

version, the image version, BIOS version, data sheet version of the basic device, installed

options (hardware and firmware options).

For details on options refer to the Quick Start Guide, chapter 2 "Checking the Furnished Items".

Remote: *IDN?

Remote: *OPT?

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System Messages

Opens the System Messages dialog box that displays the generated system messages in the

order of their occurrence. The most recent messages are placed at the top of the list. Messages

that have occurred since the last display of system messages menu are marked with an asterisk

'*'. The following information is available:

No device-specific error code

Message brief description of the message

Component hardware messages: name of the affected module

software messages: name of the affected software

Date/Time date and time of the occurrence of the message

If the number of error messages exceeds the capacity of the error buffer, Message buffer

overflow is displayed. To delete messages see Clear All Messages softkey.

Remote: SYST:ERR:LIST?

Clear All Messages

Deletes all system messages. The softkey is only available if the System Messages dialog box

is displayed.

Remote: SYST:ERR:CLE:ALL?

Service

Opens a submenu that contains additional functions for maintenance and/or trouble shooting.

NOTICE Risk of incorrect operation

The service functions are not necessary for normal measurement operation.

However, incorrect use can affect correct operation and / or data integrity of the

R&S FSL. Therefore, many of the functions can only be used after entering a

password. They are described in the instrument service manual.

Input RF/Cal/TG

Selects the input for measurement.

RF Switches the input of the R&S FSL to the input connector (normal position). This is

the default setting.

Cal Switches the RF input of the R&S FSL to the internal calibration source (65.83 MHz)

and activates the data entry of the output level of the calibration source. Possible

values are 0 dB and -30 dB.

TG Switches the RF input of the R&S FSL to the tracking generator output. Only the

models 13, 16 and 28 offer this setting.

Remote: DIAG:SERV:INP RF|CAL|TG

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Comb Frequency

Opens a dialog box to set the comb generator frequency for the internal calibration:

Comb/1 65.8333 MHz / 1

Comb/64 65.8333 MHz / 64

Comb/65 65.8333 MHz / 65

Remote: Sine: DIAG:SERV:INP:PULS OFF

Remote: Comb: DIAG:SERV:INP:PULS ON

Remote: Comb: DIAG:SERV:INP:PRAT COMB64

Reset Password

Deactivates all set passwords.

Remote: SYST:PASS:RES

Selftest

Initiates the self test of the instrument modules to identify a defective module in case of failure .

All modules are checked consecutively and the test result is displayed.

Remote: *TST?

Selftest Results

Opens the Selftest Result dialog box that contains the test results. In case of failure a short

description of the failed test, the defective module, the associated value range and the

corresponding test results are indicated.

Remote: DIAG:SERV:STE:RES?

Password

Opens an edit dialog box to enter the password. This ensures that the service functions are only

used by authorized personnel.

Remote: SYST:PASS "Password"

Service Function

Opens the Service Function dialog box to start special service functions. For further information

refer to the service manual.

Remote: DIAG:SERV:SFUNC <value>,<value>...

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Saving and Recalling Settings Files - FILE Key

The FILE key is used to store and load instrument settings and to manage stored files.

The file menu includes functions for storing (Save softkey) instrument settings such as instrument

configurations (measurement/display settings, etc) and measurement results on permanent storage

media, or to load (Recall softkey) stored data back onto the instrument.

Functions for management of storage media (File Manager softkey) include among others functions for

listing, copying, and deleting/renaming files.

The R&S FSL is capable of internally storing complete instrument settings with instrument

configurations and measurement data in the form of settings files. The respective data are stored on the

internal flash disk or, if selected, on a memory stick or network drive. The mass media are assigned to

the volume names as follows:

Drive Designation Comment

Coperating system, firmware and stored

instrument settings

for customer data

AUSB floppy drive if connected

DUSB memory stick or USB CD-ROM if connected

E...Z additional USB mass storage devices or

mounted LAN volumes

if connected

To open the file menu

Press the FILE key.

The file menu is displayed.

Menu and softkey description

–"Softkeys of the file menu" on page 4.512

To display help to a softkey, press the HELP key and then softkey for which you want to display help.

To close the help window, press the ESC key. For further information refer to section "How to use the

Help System".

Further information

–"Navigation in the dialog boxes for saving and loading settings files" on page 4.511

–"Navigation in the file manager" on page 4.511

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Navigation in the dialog boxes for saving and loading settings files

The Save and Recall dialog boxes are used to save and recall settings files. For both dialog boxes, the

same navigation principle applies. Press the Save or Recall softkey to open the corresponding dialog

box.

•Path field

To change the directory, press the Select Path softkey.

To select a folder, use the rotary knob or the UPARROW and DNARROW keys. To open a

subfolder, press the RIGHTARROW key. To close subfolders, press the LEFTARROW key. To

confirm the selection, press the rotary knob or the ENTER key.

•Files list

If the Recall or Startup Recall dialog box is opened, the focus is on the Files list. To set the focus

on the Files list, press the Select File softkey.

To select a folder, use the rotary knob or the UPARROW and DNARROW keys. To open a

subfolder, press the ENTER key. To select a file, use the rotary knob or the UPARROW and

DNARROW keys. To load the selected file, press the rotary knob or the ENTER key. To delete the

selected file, press the softkey.

•File Name field

If the Save dialog box is opened, the focus is on the File Name field. To set the focus on File Name

field, press the Edit File Name softkey. Enter the name in the File Name field. The extension of the

data name is ignored (for details on entering the name, see Quick Start Guide, chapter 4 "Basic

Operations").

•Comment field

To enter a comment, press the Edit Comment softkey (for details on entering the name, see Quick

Start Guide, chapter 4 "Basic Operations").

•Items saved in the settings file

–To select a special item, set the focus on the entry using the arrow keys or the rotary knob. To

confirm the selection, press the CHECKMARK key. To deselect the item, press the

CHECKMARK key again.

Navigation in the file manager

•To change from one subfolder to another, use the ENTER key.

•To change to the next higher directory, select the dots "..".

•To change into a subfolder, use the RIGHTARROW and LEFTARROW keys.

•To select a file or a folder, use the UPARROW and DNARROW keys.

•To confirm the selection of a file or folder, press the ENTER key.

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Softkeys of the file menu

The following table shows all softkeys available in the file menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Submenu / Command Command

Save Save File

Select Path

Select File

Edit File Name

Edit Comment

Select Items Select Items

Enable all Items

Disable all Items

Delete File

Recall Recall File

Select Path

Select File

Edit File Name

Select Items Select Items

Enable all Items

Disable all Items

Delete File

Startup Recall

Startup Recall Setup

File Manager Edit Path

New Folder

Copy

Rename

Cut

Paste

More 

Delete

Sort Mode Name

Date

Extension

Size

File Lists 1/2

Current File List 1/2

Network Drive Map Network Drive

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Menu / Command Submenu / Command Command

Disconnect Network Drive

Export

Import

Hardcopy

Save

Opens the Save dialog box to define and store the settings file. To navigate in the dialog box

and define/enter data, use the corresponding softkeys. For details see also "Navigation in the

dialog boxes for saving and loading settings files" on page 4.511.

Path Directory in which the settings file is stored. The default path for user

settings files is C:\r_s\instr\user

Files List of settings files already stored

File Name Name of settings file

Comment Comment regarding the settings file

[Items] Selection of items to be saved in the settings file

Save File / Recall File

Saves the settings file with the defined file name (Save dialog box), or recalls the selected

settings file (Recall dialog box). If the file name already exists, upon saving, a message is

displayed. Selecting Yes overwrites the existing file, selecting No aborts the saving process.

For details on the file name conventions refer to the Edit File Name softkey description.

This softkey is available from firmware version 1.70.

Remote: MMEM:STOR:STAT 1,'Save'

Remote: MMEM:STOR:STAT:NEXT

Remote: MMEM:LOAD:STAT 1,'C:\R_S\Instr\user\TEST01'

Select Path

Opens the directory list to select the drive and folder for the settings file to be stored or loaded.

The default path is C:\r_s\instr\user. For details see also "Navigation in the dialog boxes for

saving and loading settings files" on page 4.511.

Select File

Sets the focus on the Files list. For details see also "Navigation in the dialog boxes for saving

and loading settings files" on page 4.511.

Remote: MMEM:CAT? 'C:\R_S\Instr\user\*.DFL'

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Edit File Name

Sets the focus on the File Name field.

Inthe Save dialog box, the field already contains a suggestion for a new name: the file name

used in the last saving process is counted up to the next unused name. For example, if the

name last used was "test_004", the new name "test_005" is suggested, but only if this name is

not in use. If the name "test_005" is already in use, the next free name is suggested, e.g.

"test_006". You can change the suggested name to any name conform to the following naming

conventions.

The name of a settings file consists of a base name followed by an underscore and three

numbers, e.g. limit_lines_005. In the example, the base name is "limit_lines". The base name

can contain characters, numbers and underscores. The file extension is added automatically.

This softkey is available from firmware version 1.70.

Edit Comment

Sets the focus on the Comment field to enter a comment for the settings file. Max. 60

characters are allowed. For details see also "Navigation in the dialog boxes for saving and

loading settings files" on page 4.511.

Select Items

Displays the softkey submenu for selecting the items to be stored or loaded.

Select Items

Sets the focus on the items list. For details see also "Navigation in the dialog boxes for saving

and loading settings files" on page 4.511.

In the Save dialog box, all items that can be saved are displayed. The number of displayed

items depends on the installed options, as for some options additional items can be stored.

In the Recall dialog box, the items saved in the selected file are displayed.

Remote: MMEM:SEL:HWS ON

Remote: MMEM:SEL:LIN:ALL ON

Remote: MMEM:SEL:TRAC ON

Remote: MMEM:SEL:TRAN:ALL ON

Enable all Items

Selects all items for saving or loading.

This softkey is available from firmware version 1.70.

Remote: MMEM:SEL:ALL

R&S FSL Saving and Recalling Settings Files - FILE Key

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Disable all Items

Selects none of the items for saving or loading.

This softkey is available from firmware version 1.70.

Remote: MMEM:SEL:NONE

Delete File

Deletes the selected settings file.

Remote: MMEM:CLE:STAT 1,'TEST'

Recall

Opens the Recall dialog box to load a settings file. To navigate in the dialog box, use the

corresponding softkeys. For details see also "Navigation in the dialog boxes for saving and

loading settings files" on page 4.511.

Path Directory from which the settings file is loaded. The default path for

user settings files is C:\r_s\instr\user

Files List of stored settings files

File Name Name of settings file

Comment Comment of the settings file

[Items] Items saved in the settings file

Startup Recall

Activates or deactivates the startup recall function. If activated, the settings stored in the file

selected via the Startup Recall Setup softkey are loaded when booting or for preset. If

deactivated, the default settings are loaded.

This softkey is available from firmware version 1.10.

Remote: MMEM:LOAD:AUTO 1,'C:\R_S\Instr\user\TEST'

Startup Recall Setup

Opens the Startup Recall dialog box to select the settings file for the startup recall function (see

also Startup Recall softkey).

This softkey is available from firmware version 1.10.

Remote: MMEM:LOAD:AUTO 1,'C:\R_S\Instr\user\TEST'

Saving and Recalling Settings Files - FILE Key R&S FSL

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File Manager

Opens the File Manager dialog box and a submenu to manage mass storage media and files. In

the upper left corner, the current drive is displayed. Below the folders and subfolders of the

current directory are displayed. For details on navigation see also "Navigation in the file

manager" on page 4.511.

The following tasks can be performed:

–to copy files from flash disk to other media

–to copy files into another directory

–to rename and delete files

Edit Path

For details see Select Path softkey.

Remote: MMEM:MSIS "D:"

Remote: MMEM:CDIR "C:\R_S\Instr\user"

New Folder

Creates a new folder and opens an edit dialog box to enter name and path (absolute or relative

to the current directory) of the new folder.

Remote: MMEM:MDIR "C:\R_S\Instr\user\TEST"

Copy

Copies the selected item to the clipboard. The item can be copied later using the Paste softkey.

For details on navigation see also "Navigation in the file manager" on page 4.511.

Remote: MMEM:COPY "C:\R_S\Instr\user\set.cfg","E:"

Rename

Opens an edit dialog box to enter a new file or folder name:. For details on navigation see also

"Navigation in the file manager" on page 4.511.

Remote: MMEM:MOVE "test02.cfg","set2.cfg"

Cut

Copies the selected file to the clipboard. If the file is later copied to a different directory using the

Paste softkey, it is deleted in the current directory. For details on navigation see also

"Navigation in the file manager" on page 4.511.

Paste

Copies a file from the clipboard to the currently selected directory. For details on navigation see

also "Navigation in the file manager" on page 4.511.

R&S FSL Saving and Recalling Settings Files - FILE Key

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Delete

Deletes the selected item after confirmation. For details on navigation see also "Navigation in

the file manager" on page 4.511.

Remote: MMEM:DEL "test01.hcp"

Remote: MMEM:RDIR "C:\R_S\Instr\user\TEST"

Sort Mode

Opens a submenu to select the sorting mode for the displayed files. The entry for the next higher

directory level ("..") and the folders are always located at the top of the list.

Name

Sorts the displayed files in alphabetical order of the file names.

Date

Sorts the displayed files in respect to the date.

Extension

Sorts the displayed files in respect to the extension.

Size

Sorts the displayed files in respect to the size.

File Lists 1/2

Splits the screen to copy files from one directory to the other. The focus between the two panes

is switched using the FIELD RIGHT and FIELD LEFT keys.

Current File List 1/2

Changes the focus to the selected file list.

Network Drive

Opens the Map Network Drive dialog box. For further information refer to the Quick Start

Guide.

This softkey is available from firmware version 1.70.

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Map Network Drive

Sets the focus on the Drive list. For further information refer to the Quick Start Guide.

This softkey is available from firmware version 1.70.

Remote: MMEM:NETW:MAP 'T:','\\server\folder'

Remote: MMEM:NETW:USED ON

Remote: MMEM:NETW:UNUS?

Disconnect Network Drive

Opens the Disconnect Network Drivedialog box. In the Drive list, select the drive you want to

disconnect and confirm with OK.

This softkey is available from firmware version 1.70.

Remote: MMEM:NETW:DISC 'T:'

Export

Opens a submenu to configure exports of trace data. For details see ASCII File Export softkey

in the trace menu.

ASCII File Export

Decim Sep

Import

This function is currently not available in spectrum analyzer mode.

Hardcopy

Opens the print menu. For details on submenus and softkeys refer to Measurement

Documentation - PRINT Key.

R&S FSL Manual Operation - Local Menu

1300.2519.12 4.519 E-11

Manual Operation - Local Menu

When switched on, the instrument is always in the manual measurement mode and can be operated via

the front panel. As soon as the instrument receives a remote command, it is switched to the remote

control mode.

In remote control mode, all keys of the instrument except the PRESET key are disabled. The LOCAL

softkey and the Display Update On/Off softkey are displayed. Depending on the setting of the Display

Update On/Off softkey, the diagrams, traces and display fields are displayed or hidden. For further

details on the Display Update On/Off softkey refer to section "Instrument Setup and Interface

Configuration - SETUP Key".

For details on remote control refer to chapter 5 "Remote Control - Basics".

The change to manual operation consists of:

•Enabling the Front Panel Keys

Returning to manual mode enables all inactive keys. The main softkey menu of the current mode is

displayed.

•Displaying the measurement diagrams again.

The diagrams, traces and display fields are displayed again.

•Generating the OPERATION COMPLETE message

If, at the time of pressing the LOCAL softkey, the synchronization mechanism via *OPC, *OPC? or

*WAI is active, the currently running measurement procedure is aborted and synchronization is

achieved by setting the corresponding bits in the registers of the status reporting system.

•Setting Bit 6 (User Request) of the Event Status Register

With a corresponding configuration of the status reporting system, this bit immediately causes the

generation of a service request (SRQ) to inform the control software that the user wishes to return

to front panel control. For example this can be used to interrupt the control program and to correct

instrument settings manually. This bit is set each time the LOCAL softkey is pressed.

To return to manual operation

Press the LOCAL softkey.

The instrument switches from remote to manual operation, but only if the local lockout function has

not been activated in the remote control mode.

Measurement Documentation - PRINT Key R&S FSL

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Measurement Documentation - PRINT Key

The PRINT key is used to select and configure the printer and to customize the screen printout. For

detailed information on printer selection and installation refer to the Quick Start Guide.

To open the print menu

Press the PRINT key.

The print menu is displayed.

Menu and softkey description

–"Softkeys of the print menu" on page 4.520

To display help to a softkey, press the HELP key and then softkey for which you want to display help.

To close the help window, press the ESC key. For further information refer to section "How to use the

Help System".

Softkeys of the print menu

The following table shows all softkeys available in the print menu. It is possible that your instrument

configuration does not provide all softkeys. If a softkey is only available with a special option, model or

(measurement) mode, this information is delivered in the corresponding softkey description.

Menu / Command Submenu / Command

Print Screen

Device Setup

Device 1/2

Colors Select Print Color Set

Color On/Off

Select Object

Predefined Colors

User Defined Colors

Set to Default

Comment

Install Printer

Print Screen

Starts to printout all test results displayed on the screen: diagrams, traces, markers, marker lists,

limit lines etc. Comments, title, date, and time are included at the bottom margin of the printout.

All displayed items belonging to the instrument software (softkeys, tables, dialog boxes) are not

printed out. The date and time can be excluded from the printout via the Device Setup softkey.

The output is defined via the Device Setup softkey. If the output is saved in a file, the file name

used in the last saving process is counted up to the next unused name. If you use a file name

that already exists, upon saving, a message is displayed. Selecting Yes overwrites the existing

file, selecting No aborts the saving process. For further details on the file name and an example,

refer to the file menu, Edit File Name softkey.

R&S FSL Measurement Documentation - PRINT Key

1300.2519.12 4.521 E-11

Path Directory in which the file is stored. The default path is

C:\r_s\instr\user

Files List of the existing files in the same format

File Name Name of the file

Remote: HCOP:ITEM:ALL

Remote: HCOP

Remote: HCOP:NEXT

Device Setup

Opens the Hardcopy Setup dialog box to define the output: image file, clipboard, or the printer.

The dialog box consists of two tabs which are selected via the Device 1/2 softkey. For further

information refer to the Quick Start Guide.

Remote: HCOP:DEV:LANG GDI

Remote: SYST:COMM:PRIN:ENUM:FIRS?

Remote: SYST:COMM:PRIN:ENUM:NEXT?

Remote: SYST:COMM:PRIN:SEL <Printer>

Remote: HCOP:PAGE:ORI PORT

Remote: HCOP:DEST "SYST:COMM:PRIN"

Remote: HCOP:TDST:STAT?

Remote: HCOP:TDST:STAT OFF

Device 1/2

Selects the tab of the device in the Device Setup dialog box. The analyzer is able to manage

two print settings independently of each other. For each device the print setting is displayed on

the corresponding tab of the Device Setup dialog box (Device Setup softkey). For further

information refer to the Quick Start Guide.

Colors

For details see Print Colors softkey of the setup menu.

This softkey is available from firmware version 1.10.

Select Print Color Set

For details see Select Print Color Set softkey of the setup menu.

This softkey is available from firmware version 1.10.

Color On/Off

For details see Color On/Off softkey of the setup menu.

This softkey is available from firmware version 1.10.

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1300.2519.12 4.522 E-11

Select Object

For details see Select Object softkey of the setup menu.

This softkey is available from firmware version 1.10.

Predefined Colors

For details see Predefined Colors softkey of the setup menu.

This softkey is available from firmware version 1.10.

User Defined Colors

For details see User Defined Colors softkey of the setup menu.

This softkey is available from firmware version 1.10.

Set to Default

For details see Set to Default softkey of the setup menu.

This softkey is available from firmware version 1.10.

Comment

Opens dialog box to enter a comment. Max. 120 characters are allowed. 60 characters fit in one

line. In the first line, at any point a manual line-feed can be forced by entering "@".

Date and time are inserted automatically. The comment is printed below the diagram area, but

not displayed on the screen. If a comment should not be printed, it must be deleted.

For details on the alphanumeric entries refer to the Quick Start Guide, chapter 4 "Basic

Operations".

This softkey is available from firmware version 1.10.

Install Printer

Opens the Printers and Faxes window to install a new printer. All printers that are already

installed are displayed. For details refer to the Quick Start Guide, appendix A, "Printer Interface".

R&S FSL Introduction

1300.2519.12 I-5.1 E-11

Contents of Chapter 5

5Remote Control – Basics.................................................................................... 5.1

Introduction.......................................................................................................................................5.1

Getting Started..................................................................................................................................5.3

Setting the Remote Control (IP/GPIB) Address .............................................................................5.3

Starting Remote Control ..................................................................................................................5.4

Returning to Manual Operation.......................................................................................................5.4

SCPI Command Structure and Syntax ...........................................................................................5.5

Structure of a Command..........................................................................................................5.5

Structure of a Command Line ..................................................................................................5.7

Responses to Queries..............................................................................................................5.8

Parameters...............................................................................................................................5.8

Overview of Syntax Elements ................................................................................................5.10

Instrument Model and Command Processing .............................................................................5.11

Command Sequence and Command Synchronization ..........................................................5.13

Status Reporting System...............................................................................................................5.14

Structure of an SCPI Status Register.....................................................................................5.14

Overview of the Status Registers ...........................................................................................5.16

Status Byte (STB) and Service Request Enable Register (SRE)...........................................5.17

IST Flag and Parallel Poll Enable Register (PPE)..................................................................5.18

Event Status Register (ESR) and Event Status Enable Register (ESE) ................................5.18

STATus:OPERation Register.......................................................................................5.19

STATus:QUEStionable Register..................................................................................5.19

STATus:QUEStionable:ACPLimit Register..................................................................5.20

STATus:QUEStionable:FREQuency Register .............................................................5.21

STATus:QUEStionable:LIMit Register .........................................................................5.22

STATus:QUEStionable:LMARgin Register ..................................................................5.22

STATus:QUEStionable:POWer Register.....................................................................5.23

STATus:QUEStionable:SYNC Register.......................................................................5.24

Application of the Status Reporting Systems .........................................................................5.25

Service Request...........................................................................................................5.25

Serial Poll.....................................................................................................................5.25

Parallel Poll ..................................................................................................................5.25

Query by Means of Commands ...................................................................................5.26

Error Queue Query.......................................................................................................5.26

Reset Values of the Status Reporting System .......................................................................5.27

Interfaces and Protocols................................................................................................................5.28

LAN Interface .........................................................................................................................5.28

VXI Basics....................................................................................................................5.28

VXI–11 Interface Messages.........................................................................................5.30

RSIB Protocol Basics...................................................................................................5.30

RSIB Interface Functions .............................................................................................5.31

GPIB Interface (Option R&S FSL–B10) .................................................................................5.33

GPIB Basics.................................................................................................................5.33

GPIB Interface Functions.............................................................................................5.34

GPIB Interface Messages ............................................................................................5.34

Instrument Messages...................................................................................................5.36

Introduction R&S FSL

1300.2519.12 I-5.2 E-11

Noise Figure Measurements (K30) – Status Reporting System.................................................5.37

STATus:OPERation Register.................................................................................................5.37

STATus:QUEStionable Register ............................................................................................5.38

STATus:QUEStionable:CORRection Register.......................................................................5.38

Error Reporting.......................................................................................................................5.38

3GPP Base Station Measurements (K72) – Status Reporting System ......................................5.39

STATus:QUEStionable:SYNC Register .................................................................................5.39

CDMA2000 (K82) and 1xEV-DO (K84) BTS Analyzer – Status Reporting System....................5.40

STATus:QUEstionable:SYNC Register..................................................................................5.40

WLAN TX Measurements (K91/K91n) – Status Reporting System............................................5.41

STATus:OPERation Register.................................................................................................5.41

STATus:QUEStionable:LIMit Register ...................................................................................5.42

STATus:QUEStionable:SYNC Register .................................................................................5.43

Error Reporting.......................................................................................................................5.43

WiMAX, WiBro Measurements (K92/K93) – Status Reporting System......................................5.44

STATus:OPERation Register.................................................................................................5.44

STATus:QUEStionable:LIMit Register ...................................................................................5.45

STATus:QUEStionable:SYNC Register .................................................................................5.45

Error Reporting.......................................................................................................................5.46

R&S FSL Introduction

1300.2519.12 5.1 E-11

5Remote Control – Basics

This chapter assumes basic knowledge of programming and operation of the controller. It provides the

following:

•Instructions on how to put the R&S FSL into operation via remote control.

•Ageneral introduction to remote control of programmable instruments. This includes the description

of the command structure and syntax according to the SCPI standard, the description of command

execution and of the status registers.

•Diagrams and tables describing the status registers used in the R&S FSL.

•Adescription of the interfaces and protocols used for remote control.

In chapter "Instrument Functions" of this manual and in the Online Help, the remote control commands

available for an instrument function are listed after each function description. In the Online Help, these

remote control commands are linked to their description, provided in the manual in chapter "Remote

Control – Commands". Program examples for the R&S FSL are given in chapter 7 "Remote Control –

Programming Examples".

Introduction

The instrument is equipped with the following interfaces for remote control:

-LAN interface: The protocol is based on TCP/IP and supports the VXI–11 standard.

-Option GPIB Interface, R&S FSL–B10: GPIB interface according to standard IEC 625/IEEE 488

The connectors are located at the rear of the instrument and permit a connection to a controller for

remote control via a local area network (LAN) or directly (option GPIB Interface, R&S FSL–B10).

SCPI (Standard Commands for Programmable Instruments) commands – messages – are used for

remote control. Commands that are not taken from the SCPI standard follow the SCPI syntax rules. The

instrument supports the SCPI version 1999. The SCPI standard is based on standard IEEE 488.2 and

aims at the standardization of device–specific commands, error handling and the status registers. The

tutorial "Automatic Measurement Control – A tutorial on SCPI and IEEE 488.2" from John M. Pieper

(R&S order number 0002.3536.00) offers detailed information on concepts and definitions of SCPI.

The requirements that the SCPI standard places on command syntax, error handling and configuration

of the status registers are explained in detail in the following sections. Tables provide a fast overview of

the bit assignment in the status registers. The tables are supplemented by a comprehensive description

of the status registers.

VISA is a standardized software interface library providing input and output functions to communicate

with instruments. The I/O channel (LAN, GPIB…) is selected at initialization time by means of a

channel–specific resource string. For more information about VISA refer to its user documentation.

The programming examples for remote control are all written in Microsoft®VISUAL BASIC®.Access to

the VISA functions require the declaration of the functions and constants prior to their use in the project.

This can be accomplished either by adding the modules VISA32.BAS and VPPTYPE.BAS or a

reference to the VISA32.DLL to the project.

Introduction R&S FSL

1300.2519.12 5.2 E-11

The modules visa32.bas and vpptype.bas can be found in the <VXIpnpPath>\WinNT\include (typically

C:\VXIpnp\WinNt\include).

Note: Manual operation is designed for maximum possible operating convenience. In contrast, the

priority of remote control is the "predictability" of the device status. Therefore, control programs

should always define an initial device status (e.g. with the command *RST) and then implement

the required settings.

To make remote control operation more comfortable and faster, you can use IVI drivers. They bundle

remote control commands, reduce the I/O to the instrument by status caching, check status and

parameters and offer simulation modes.

R&S FSL Getting Started

1300.2519.12 5.3 E-11

Getting Started

The short and simple operating sequence below shows how to put the instrument into operation and

quickly set its basic functions. The remote control address, which is factory–set to 10.0.0.10, subnet

mask 255.255.255.0 for LAN operation and 20 for operation via GPIB, is used. If you want to change the

IP address, see "Setting the Remote Control (IP/GPIB) Address".

To prepare for remote control

1. Connect the instrument to the LAN or directly to the GPIB controller (option GPIB Interface,

R&S FSL–B10).

For details refer to the Quick Start Guide, appendix B.

2. Switch on the instruments.

3. Write and start the following program on the controller:

status = viOpenDefaultRM(defaultRM) 'Open default resource manager

Cmd = "*RST;*CLS"

status = viWrite(vi, Cmd, Len(Cmd),

retCount)

'Reset instrument and clear status

registers

Cmd = "FREQ:CENT 100MHz"

status = viWrite(vi, Cmd, Len(Cmd),

retCount)

'Set center frequency to 100 MHz

Cmd = "FREQ:SPAN 10MHz"

status = viWrite(vi, Cmd, Len(Cmd),

retCount)

'Set span to 10 MHz

Cmd = "DISP:TRAC:Y:RLEV –10dBm"

status = viWrite(vi, Cmd, Len(Cmd),

retCount)

'Set reference level to –10 dBm

The instrument now performs a sweep in the frequency range of 95 MHz to 105 MHz.

Setting the Remote Control (IP/GPIB) Address

In order to operate the instrument via remote control, it must be addressed using the set IP or GPIB

address. The remote control address is factory–set (for details refer to "Getting Started"), but it can be

changed, if it does not fit in the network environment.

To change the GPIB address via R&S FSL

For details see Quick Start Guide, chapter 2 "Preparing for Use".

To change the GPIB address via GPIB

status = viOpenDefaultRM(defaultRM) 'Open default resource manager

status = viOpen(defaultRM, "GPIB:20::INSTR", 0,

5000, vi) 'Open connection to instrument

with old address

Cmd = "SYST:COMM:GPIB:ADDR 18"

status = viWrite(vi, Cmd, Len(Cmd), retCount) 'Set instrument to new address

status = viClose(vi)

status = viOpen(defaultRM, "GPIB:18::INSTR", 0,

5000, vi)

'Close old connection and reopen

with new address

To change the IP address via R&S FSL

For details see Quick Start Guide, chapter 2 "Preparing for Use".

Starting Remote Control R&S FSL

1300.2519.12 5.4 E-11

Starting Remote Control

Onpower–on, the instrument is always in the manual operating state ("local" state) and can be operated

via the front panel.

To start remote control

Send an addressed command from a controller to the instrument.

The instrument is switched to remote control ("remote" state). Operation via the front panel is

disabled. Only the Local softkey is displayed to return to manual operation. The instrument remains

in the remote state until it is reset to the manual state via the instrument or via remote control

interfaces. Switching from manual operation to remote control and vice versa does not affect the

other instrument settings.

During program execution, send the SYSTem:DISPlay:UPDate ON command to activate the

display of results.

The changes in the device settings and the recorded measurement curves are displayed on the

instrument screen.

To obtain optimum performance during remote control, send the SYSTem:DISPlay:UPDate OFF

command to hide the display of results and diagrams again (default setting in remote control).

To prevent unintentional return to manual operation, disable the keys of the R&S FSL by the

universal command LLO.

Then the transition to manual mode is only possible via remote control.

This function is only available for the GPIB interface.

To enable the keys of the R&S FSL again, switch the instrument to local mode, i.e. deactivate the

REN line of the remote control interface.

Note: If the instrument is exclusively operated in remote control, it is recommended to switch on the

power–save mode for the display. For more details on this mode refer to the Quick Start Guide.

Returning to Manual Operation

Before the transition, command processing must be completed. If command processing is not

completed, it is not possible to return to manual operation and the instrument will switch back to remote

control immediately.

To return to manual operation via R&S FSL

Press the Local softkey or the Preset key.

To return to manual operation via GPIB

...

status = viGpibControlREN(vi,

VI_GPIB_REN_ADDRESS_GTL)

'Set instrument to manual

operation

...

R&S FSL SCPI Command Structure and Syntax

1300.2519.12 5.5 E-11

SCPI Command Structure and Syntax

SCPI (Standard Commands for Programmable Instruments) describes a standard command set for

programming instruments, irrespective of the type of instrument or manufacturer. The goal of the SCPI

consortium is to standardize the device–specific commands to a large extent. For this purpose, a model

was developed which defines the same functions inside a device or for different devices. Command

systems were generated which are assigned to these functions. Thus it is possible to address the same

functions with identical commands. The command systems are of a hierarchical structure.

SCPI is based on standard IEEE 488.2, i.e. it uses the same syntactic basic elements as well as the

common commands defined in this standard. Part of the syntax of the device responses is defined with

greater restrictions than in standard IEEE 488.2 (see section "Responses to Queries").

Structure of a Command

The commands consist of a so–called header and, in most cases, one or more parameters. Header and

parameter are separated by a "white space" (ASCII code 0 to 9, 11 to 32 decimal, e.g. blank). The

headers may consist of several key words. Queries are formed by directly appending a question mark to

the header.

Note: Not all commands used in the following examples are implemented in the instrument.

Common commands

Common commands consist of a header preceded by an asterisk "*" and one or several parameters, if

any.

Examples: *RST RESET, resets the device

*ESE 253 EVENT STATUS ENABLE, sets the bits of the event status enable

*ESR? EVENT STATUS QUERY, queries the contents of the event status

Device–specific commands

•Hierarchy

Device–specific commands are of hierarchical structure (see Fig. 5–1). The different levels are

represented by combined headers. Headers of the highest level (root level) have only one key word.

This key word denotes a complete command system.

Example: SENSe

This key word denotes the SENSe command system.

For commands of lower levels, the complete path has to be specified, starting on the left with the

highest level, the individual key words being separated by a colon ":".

Example: SENSe:FREQuency:SPAN 10MHZ

This command lies in the third level of the SENSe system. It sets the frequency span.

SCPI Command Structure and Syntax R&S FSL

1300.2519.12 5.6 E-11

SENSe

BANDwidth FUNCtion FREQuency

STOP CENTer SPAN OFFSet

STARt

DETector

Fig. 5–1 Tree structure the SCPI command systems using the SENSe system as example

•Multiple key words

Some key words occur in several levels within one command system. Their effect depends on the

structure of the command, i.e. at which position in the header of a command they are inserted.

Example: SOURce:FM:POLarity NORMal

This command contains key word POLarity in the third command level. It defines the polarity

between modulator and modulation signal.

Example: SOURce:FM:EXTernal:POLarity NORMal

This command contains key word POLarity in the fourth command level. It defines the polarity

between modulation voltage and the resulting direction of the modulation only for the external signal

source indicated.

•Optional key words

Some command systems permit certain key words to be inserted into the header or omitted. These

key words are marked by square brackets in the description. The full command length must be

recognized by the instrument for reasons of compatibility with the SCPI standard. Some commands

are considerably shortened by these optional key words.

Example: [SENSe]:BANDwidth[:RESolution]:AUTO

This command couples the resolution bandwidth of the instrument to other parameters. The

following command has the same effect: BANDwidth:AUTO

Note: An optional key word must not be omitted if its effect is specified in detail by a numeric suffix.

•Long and short form

The key words feature a long form and a short form. Either the short form or the long form can be

entered, other abbreviations are not permitted.

Example: STATus:QUEStionable:ENABle 1= STAT:QUES:ENAB 1

Note: Upper–case and lower–case notation only serves to distinguish the two forms in the manual, the

instrument itself does not distinguish upper–case and lower–case letters.

•Parameter

The parameter must be separated from the header by a "white space". If several parameters are

specified in a command, they are separated by a comma ",". A few queries permit the parameters

MINimum, MAXimum and DEFault to be entered. For a description of the types of parameter, refer

to section "Parameters".

Example: SENSe:FREQuency:STOP? MAXimum, Response: 3.5E9

This query requests the maximal value for the stop frequency.

R&S FSL SCPI Command Structure and Syntax

1300.2519.12 5.7 E-11

•Numeric suffix

If a device features several functions or features of the same kind, e.g. inputs, the desired function

can be selected by a suffix added to the command. Entries without suffix are interpreted like entries

with the suffix 1. Optional keywords must be specified if they select a function with the suffix.

Example: SYSTem:COMMunicate:SERial2:BAUD 9600

This command sets the baud rate of a second serial interface.

Note: In case of remote control, suffix counting may differ from the numbers of the corresponding

selection used in manual operation. SCPI prescribes that suffix counting starts with 1. Suffix 1 is

the default state and used when no specific suffix is specified.

Some standards define a fixed numbering, starting with 0. With GSM, for instance, slots are

counted from 0 to 7. In the case of remote control, the slots are selected with the suffixes 1 to 8.

If the numbering differs in manual operation and remote control, it is indicated with the

respective command.

Structure of a Command Line

Acommand line may consist of one or several commands. It is terminated by an EOI signal together

with the last data byte.

Several commands in a command line must be separated by a semicolon ";". If the next command

belongs to a different command system, the semicolon is followed by a colon. A colon ":" at the

beginning of a command marks the root node of the command tree.

Example:

CALL InstrWrite(analyzer, "SENSe:FREQuency:CENTer 100MHz;:INPut:ATTenuation

10")

This command line contains two commands. The first one is part of the SENSe command system and is

used to determine the center frequency of the instrument. The second one is part of the INPut

command system and sets the input signal attenuation.

If the successive commands belong to the same system, having one or several levels in common, the

command line can be abbreviated. For that purpose, the second command after the semicolon starts

with the level that lies below the common levels (see also Fig. 5–1). The colon following the semicolon

must be omitted in this case.

Example:

CALL InstrWrite(analyzer, "SENSe:FREQuency:STARt 1E6;:SENSe:FREQuency:STOP

1E9")

This command line is represented in its full length and contains two commands separated from each

other by the semicolon. Both commands are part of the SENSe command system, subsystem

FREQuency, i.e. they have two common levels.

When abbreviating the command line, the second command begins with the level below

SENSe:FREQuency.The colon after the semicolon is omitted. The abbreviated form of the command

line reads as follows:

CALL InstrWrite(analyzer, "SENSe:FREQuency:STARt 1E6;STOP 1E9")

However, a new command line always begins with the complete path.

Example:

CALL InstrWrite(analyzer, "SENSe:FREQuency:STARt 1E6")

CALL InstrWrite(analyzer, "SENSe:FREQuency:STOP 1E9")

SCPI Command Structure and Syntax R&S FSL

1300.2519.12 5.8 E-11

Responses to Queries

Aquery is defined for each setting command unless explicitly specified otherwise. It is formed by adding

aquestion mark to the associated setting command. According to SCPI, the responses to queries are

partly subject to stricter rules than in standard IEEE 488.2.

•The requested parameter is transmitted without header.

Example: INPut:COUPling?,Response: DC

•Maximum values, minimum values and all further quantities, which are requested via a special text

parameter are returned as numerical values.

Example: SENSe:FREQuency:STOP? MAX,Response: 3.5E9

•Numerical values are output without a unit. Physical quantities are referred to the basic units or to

the units set using the Unit command.

Example: SENSe:FREQuency:CENTer?, Response: 1E6 (for 1 MHz)

•Truth values <Boolean values> are returned as 0(for OFF) and 1(for ON).

Example: SENSe:BANDwidth:AUTO?, Response: 1(for ON)

•Text (character data) is returned in a short form.

Example: SYSTem:COMMunicate:SERial:CONTrol:RTS?,Response STAN (for standard)

Parameters

Most commands require a parameter to be specified. The parameters must be separated from the

header by a "white space". Permissible parameters are numerical values, Boolean parameters, text,

character strings and block data. The type of parameter required for the respective command and the

permissible range of values are specified in the command description.

Numerical values

Numerical values can be entered in any form, i.e. with sign, decimal point and exponent. Values

exceeding the resolution of the instrument are rounded up or down. The mantissa may comprise up to

255 characters, the exponent must lie inside the value range –32000 to 32000. The exponent is

introduced by an "E" or "e". Entry of the exponent alone is not permissible. In the case of physical

quantities, the unit can be entered. Permissible unit prefixes are G (giga), MA (mega), MOHM and MHZ

are also permissible), K (kilo), M (milli), U (micro) and N (nano). It the unit is missing, the basic unit is

used.

Example: SENSe:FREQuency:STOP 1.5GHz = SENSe:FREQuency:STOP 1.5E9

Special numerical

The texts MINimum, MAXimum, DEFault, UP and DOWN are interpreted as valuesspecial numerical

values. In the case of a query, the numerical value is provided.

Example:

Setting command: SENSe:FREQuency:STOP MAXimum

Query: SENSe:FREQuency:STOP?,Response: 3.5E9

–MIN/MAX

MINimum and MAXimum denote the minimum and maximum value.

–DEF

DEFault denotes a preset value which has been stored in the EPROM. This value conforms to the

default setting, as it is called by the *RST command

R&S FSL SCPI Command Structure and Syntax

1300.2519.12 5.9 E-11

–UP/DOWN

UP, DOWN increases or reduces the numerical value by one step. The step width can be specified

via an allocated step command (see annex C, List of Commands) for each parameter which can be

set via UP, DOWN.

–INF/NINF

INFinity, Negative INFinity (NINF) Negative INFinity (NINF) represent the numerical values –9.9E37

or 9.9E37, respectively. INF and NINF are only sent as device reponses.

–NAN

Not A Number (NAN) represents the value 9.91E37. NAN is only sent as device response. This

value is not defined. Possible causes are the division of zero by zero, the subtraction of infinite from

infinite and the representation of missing values.

Boolean parameters

Boolean parameters represent two states. The ON state (logically true) is represented by ON or a

numerical value unequal to 0. The OFF state (logically untrue) is represented by OFF or the numerical

value 0. The numerical values are provided as response for query.

Example:

Setting command: DISPlay:WINDow:STATe ON

Query: DISPlay:WINDow:STATe?,Response: 1

Text

Text parameters observe the syntactic rules for key words, i.e. they can be entered using a short or long

form. Like any parameter, they have to be separated from the header by a white space. In the case of a

query, the short form of the text is provided.

Example:

Setting command: INPut:COUPling GROund

Query: INPut:COUPling?,Response: GRO

Strings

Strings must always be entered in quotation marks (' or ").

Example:

SYSTem:LANGuage "SCPI" or SYSTem:LANGuage 'SCPI'

Block data

Block data are a transmission format which is suitable for the transmission of large amounts of data. A

command using a block data parameter has the following structure:

Example:

HEADer:HEADer #45168xxxxxxxx

ASCII character # introduces the data block. The next number indicates how many of the following digits

describe the length of the data block. In the example the 4 following digits indicate the length to be 5168

bytes. The data bytes follow. During the transmission of these data bytes all end or other control signs

are ignored until all bytes are transmitted.

SCPI Command Structure and Syntax R&S FSL

1300.2519.12 5.10 E-11

Overview of Syntax Elements

The following survey offers an overview of the syntax elements.

:The colon separates the key words of a command. In a command line the separating

semicolon marks the uppermost command level.

;The semicolon separates two commands of a command line. It does not alter the path.

,The comma separates several parameters of a command.

?The question mark forms a query.

*The asterisk marks a common command.

"Quotation marks introduce a string and terminate it.

#The hash symbol # introduces binary, octal, hexadecimal and block data.

Binary: #B10110

Octal: #O7612

Hexa: #HF3A7

Block: #21312

A "white space" (ASCII–Code 0 to 9, 11 to 32 decimal, e.g. blank) separates header and

parameter.

R&S FSL Instrument Model and Command Processing

1300.2519.12 5.11 E-11

Instrument Model and Command Processing

The block diagram in Fig. 5–2 shows how SCPI commands are serviced in the instrument. The

individual components work independently and simultaneously. They communicate with each other by

means of so–called "messages".

IEC/IEEE bus

Ethernet

Input unit with

input buffer

Command

recognition

Instrument settings

data base

Instrument

hardware

Output unit with

output buffer

Status reporting

system

IEC/IEEE bus

Ethernet

Fig. 5–2 Instrument model in the case of remote control

Input unit

The input unit receives commands character by character from the controller and collects them in the

input buffer. The input unit sends a message to the command recognition as soon as the input buffer is

full or as soon as it receives a delimiter, <PROGRAM MESSAGE TERMINATOR>, as defined in IEEE

488.2, or the interface message DCL.

If the input buffer is full, the traffic is stopped and the data received up to then are processed.

Subsequently the traffic is continued. If, however, the buffer is not yet full when receiving the delimiter,

the input unit can already receive the next command during command recognition and execution. The

receipt of DCL clears the input buffer and immediately resets the command recognition.

Command recognition

The command recognition analyses the data received from the input unit. It proceeds in the order in

which it receives the data. Only DCL is serviced with priority, for example GET (Group Execute Trigger)

is only executed after the commands received before. Each recognized command is immediately

transferred to the internal instrument settings data base but not executed immediately.

The command recognition detects syntax errors in the commands and transfers them to the status

reporting system. The rest of a command line after a syntax error is analyzed further if possible and

serviced. After the syntax test, the value range of the parameter is checked, if required.

If the command recognition detects a delimiter, it passes the command to an execution unit that

performs the instrument settings. In the meantime, the command recognition is ready to process new

commands (overlapping execution). A DCL command is processed in the same way.

Instrument Model and Command Processing R&S FSL

1300.2519.12 5.12 E-11

Data base and instrument hardware

Here the expression "instrument hardware" denotes the part of the instrument fulfilling the actual

instrument function – signal generation, measurement etc. The controller is not included. The term

"data base" denotes a database that manages all the parameters and associated settings required for

setting the instrument hardware.

Setting commands lead to an alteration in the data set. The data set management enters the new

values (e.g. frequency) into the data set, however, only passes them on to the hardware when

requested by the command recognition. This only takes place at the end of a command line.

The data are checked for compatibility with the current instrument settings before they are transmitted to

the instrument hardware. If the execution is not possible, an "execution error" is signaled to the status

reporting system. The corresponding settings are discarded.

Before passing on the data to the hardware, the settling bit in the STATus:OPERation register is set

(refer to section "STATus:OPERation Register"). The hardware executes the settings and resets the bit

again as soon as the new state has settled. This fact can be used to synchronize command servicing.

Queries induce the data set management to send the desired data to the output unit.

Status reporting system

For detailed information refer to section "Status Reporting System".

Output unit

The output unit collects the information requested by the controller, which it receives from the data base

management. It processes it according to the SCPI rules and makes it available in the output buffer.

If the instrument is addressed as a talker without the output buffer containing data or awaiting data from

the data base management, the output unit sends error message "Query UNTERMINATED" to the

status reporting system. No data are sent on the GPIB or via the Ethernet, the controller waits until it has

reached its time limit. This behavior is specified by SCPI.

R&S FSL Instrument Model and Command Processing

1300.2519.12 5.13 E-11

Command Sequence and Command Synchronization

What has been said above makes clear that all commands can potentially be carried out overlapping. In

order to prevent an overlapping execution of commands, one of the commands *OPC, *OPC? or *WAI

must be used. All three commands cause a certain action only to be carried out after the hardware has

been set. By suitable programming, the controller can be forced to wait for the respective action to occur

(refer to Table 5–1).

Table 5–1 Synchronization using *OPC, *OPC? and *WAI

Command Action Programming the controller

*OPC Sets the Operation Complete bit in

the ESR after all previous

commands have been executed.

–Setting bit 0 in the ESE

–Setting bit 5 in the SRE

–Waiting for service request (SRQ)

*OPC? Stops command processing until 1

is returned. This is only the case

after the Operation Complete bit

has been set in the ESR. This bit

indicates that the previous setting

has been completed.

Sending *OPC? directly after the command

whose processing should be terminated before

other commands can be executed.

*WAI Stops further command processing

until all commands sent before

*WAI have been executed.

Sending *WAI directly after the command whose

processing should be terminated before other

commands are executed.

An example for command synchronization can be found in chapter 7 "Remote Control – Programming

Examples".

For a couple of commands the synchronization to the end of command execution is mandatory in order

to obtain the desired result. The affected commands require either more than one measurement in

order to accomplish the desired instrument setting (e.g. auto range functions), or they require a longer

period of time for execution. If a new command is received during execution of the corresponding

function this may either lead to either to an aborted measurement or to incorrect measurement data.

The following list includes the commands, for which a synchronization via *OPC, *OPC? or *WAI is

mandatory:

Table 5–2 Commands with mandatory synchronization (overlapping commands)

Command Purpose

INIT start measurement

INIT:CONM continue measurement

CALC:MARK:FUNC:ZOOM zoom frequency range around marker 1

CALC:STAT:SCAL:AUTO ONCE optimize level settings for signal statistic

measurement functions

[SENS:]POW:ACH:PRES:RLEV optimize level settings for adjacent channel

power measurements

Status Reporting System R&S FSL

1300.2519.12 5.14 E-11

Status Reporting System

The status reporting system (refer to Fig. 5–4)stores all information on the present operating state of

the instrument, and on errors which have occurred. This information is stored in the status registers and

in the error queue. The status registers and the error queue can be queried via GPIB or via the Ethernet.

The information is of a hierarchical structure. The register status byte (STB) defined in IEEE 488.2 and

its associated mask register service request enable (SRE) form the uppermost level. The STB receives

its information from the standard event status register (ESR) which is also defined in IEEE 488.2 with

the associated mask register standard event status enable (ESE) and registers STATus:OPERation and

STATus:QUEStionable which are defined by SCPI and contain detailed information on the instrument.

The IST flag ("Individual STatus") and the parallel poll enable register (PPE) allocated to it are also part

of the status reporting system. The IST flag, like the SRQ, combines the entire instrument status in a

single bit. The PPE fulfills the same function for the IST flag as the SRE for the service request.

The output buffer contains the messages the instrument returns to the controller. It is not part of the

status reporting system but determines the value of the MAV bit in the STB.

Structure of an SCPI Status Register

Each standard SCPI register consists of 5 parts which each have a width of 16 bits and have different

functions (refer to Fig. 5–3). The individual bits are independent of each other, i.e. each hardware status

is assigned a bit number that applies to all five parts. For example, bit 3 of the STATus:OPERation

bit) is set to zero for all parts. Thus the contents of the register parts can be processed by the controller

as positive integer.

15 14 13 12 PTRansition part 3 2 1 0

15 14 13 12 EVENt part 3 2 1 0

15 14 13 12 ENABle part 3 2 1 0

& & & & & & & & & & & & & & & &

to higher-order register

Sum bit

& = logical AN

=logical OR

of all bits

15 14 13 12 NTRansition part 3 2 1 0

15 14 13 12 CONDition part 3 2 1 0

Fig. 5–3 The status–register model

CONDition part

The CONDition part is directly written into by the hardware or the sum bit of the next lower register. Its

contents reflects the current instrument status. This register part can only be read, but not written into or

cleared. Its contents is not affected by reading.

R&S FSL Status Reporting System

1300.2519.12 5.15 E-11

PTRansition part

The Positive–TRansition part acts as an edge detector. When a bit of the CONDition part is changed

from 0 to 1, the associated PTR bit decides whether the EVENt bit is set to 1.

PTR bit =1: the EVENt bit is set.

PTR bit =0: the EVENt bit is not set.

This part can be written into and read at will. Its contents is not affected by reading.

NTRansition part

The Negative–TRansition part also acts as an edge detector. When a bit of the CONDition part is

changed from 1 to 0, the associated NTR bit decides whether the EVENt bit is set to 1.

NTR–Bit = 1: the EVENt bit is set.

NTR–Bit = 0: the EVENt bit is not set.

This part can be written into and read at will. Its contents is not affected by reading.

With these two edge register parts the user can define which state transition of the condition part (none,

0to 1, 1 to 0 or both) is stored in the EVENt part.

EVENt part

The EVENt part indicates whether an event has occurred since the last reading, it is the "memory" of the

condition part. It only indicates events passed on by the edge filters. It is permanently updated by the

instrument. This part can only be read by the user. Reading the register clears it. This part is often

equated with the entire register.

ENABle part

The ENABle part determines whether the associated EVENt bit contributes to the sum bit (see below).

Each bit of the EVENt part is ANDed with the associated ENABle bit (symbol '&'). The results of all

logical operations of this part are passed on to the sum bit via an OR function (symbol '+').

ENABle–Bit = 0: the associated EVENt bit does not contribute to the sum bit

ENABle–Bit = 1: if the associated EVENT bit is "1", the sum bit is set to "1" as well.

This part can be written into and read by the user at will. Its contents is not affected by reading.

Sum bit

As indicated above, the sum bit is obtained from the EVENt and ENABle part for each register. The

result is then entered into a bit of the CONDition part of the higher–order register.

The instrument automatically generates the sum bit for each register. Thus an event, e.g. a PLL that has

not locked, can lead to a service request throughout all levels of the hierarchy.

Note: The service request enable register SRE defined in IEEE 488.2 can be taken as ENABle part of

the STB if the STB is structured according to SCPI. By analogy, the ESE can be taken as the

ENABle part of the ESR.

Status Reporting System R&S FSL

1300.2519.12 5.16 E-11

Overview of the Status Registers

The following figure shows the status registers used by the R&S FSL base unit. The status registers

used by the R&S FSL options are described in separate sections at the end of this chapter.

SRE STB

PPE

ISTflag

&=logic AND

=logic OR

of all bits

ESE ESR

Error/event

queue

bla

Output

buffer

SRQ

RQS/MSS

ESB

MAV

Power o n

User Request

Command Error

Exec uti on Error

Device Dependent Error

Query Error

Request Control

Operation Complete

-&-

STATus:QUEStionabl e

TRANsducer break

LMARgin

LIMit

CALibration (= UNCAL)

FREQuency

TEMPerature

POW er

ACPLimit

LIMit 8 FAIL

LIMit 7 FAIL

LIMit 6 FAIL

LIMit 5 FAIL

LIMit 4 FAIL

LIMit 3 FAIL

LIMit 2 FAIL

LIMit 1 FAIL

STATus:QUEStionable:POWer

IF_OVerload

UNDerload

OVERload

STATus:QUEStionable: FREQuency

LO UNLocked

OVEN COLD

LMARgin 8 FAIL

LMARgin 7 FAIL

LMARgin 6 FAIL

LMARgin 5 FAIL

LMARgin 4 FAIL

LMARgin 3 FAIL

LMARgin 2 FAIL

LMARgin 1 FAIL

ST AT us: QUEStiona ble:LMARgin <1|2>

STATus:OPERation

not used

Scan results available

HCOPy in progress

CALibrating

STATus:QUEStionable:LI Mit <1|2>

-&-

STATus:QUEStionable:ACPLimit

not used

not used not used

SYNC

not used

CARRier overload

No carrier

SYNC not found

BURSt not found

STATus:QUEStionable:SYNC

EXTernalREFerence

BATTERY LOW

not used

ALT3 … 11 LOWer/UPPer FAIL

ALT2 LOWer FAIL

ALT2 UPPer FAIL

ALT1 LOWer FAIL

ALT1 UPPer FAIL

ADJ LOWer FAIL

ADJ UPPer FAIL

Fig. 5–4 Overview of the status registers (base unit)

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1300.2519.12 5.17 E-11

Status Byte (STB) and Service Request Enable Register

(SRE)

The STB is already defined in IEEE 488.2. It provides a rough overview of the instrument status by

collecting the pieces of information of the lower registers. It can thus be compared with the CONDition

part of an SCPI register and assumes the highest level within the SCPI hierarchy. A special feature is

that bit 6 acts as the sum bit of the remaining bits of the status byte.

The STATUS BYTE is read using the command "*STB?" or a serial poll.

The STB is linked to the SRE. The latter corresponds to the ENABle part of the SCPI registers in its

function. Each bit of the STB is assigned a bit in the SRE. Bit 6 of the SRE is ignored. If a bit is set in the

SRE and the associated bit in the STB changes from 0 to 1, a service request (SRQ) is generated on

the GPIB or via the Ethernet, which triggers an interrupt in the controller if this is appropriately

configured and can be further processed there.

The SRE can be set using the command "*SRE" and read using the command "*SRE?"

Table 5–3 Meaning of the bits used in the status byte

Bit No. Meaning

0...1 Not used

2Error Queue not empty

The bit is set when an entry is made in the error queue.

If this bit is enabled by the SRE, each entry of the error queue generates a service request.

Thus an error can be recognized and specified in greater detail by polling the error queue.

The poll provides an informative error message. This procedure is to be recommended

since it considerably reduces the problems involved with remote control.

3QUEStionable status sum bit

The bit is set if an EVENt bit is set in the QUEStionable: status register and the associated

ENABle bit is set to 1.

Aset bit indicates a questionable instrument status, which can be specified in greater

detail by polling the QUEStionable status register.

4MAV bit (message available)

The bit is set if a message is available in the output buffer which can be read. This bit can

be used to enable data to be automatically read from the instrument to the controller.

5ESB bit

Sum bit of the event status register. It is set if one of the bits in the event status register is

set and enabled in the event status enable register.

Setting of this bit indicates a serious error which can be specified in greater detail by

polling the event status register.

6MSS bit (master status summary bit)

The bit is set if the instrument triggers a service request. This is the case if one of the

other bits of this registers is set together with its mask bit in the service request enable

7OPERation status register sum bit

The bit is set if an EVENt bit is set in the OPERation status register and the associated

ENABle bit is set to 1.

Aset bit indicates that the instrument is just performing an action. The type of action can

be determined by polling the OPERation status register.

Status Reporting System R&S FSL

1300.2519.12 5.18 E-11

IST Flag and Parallel Poll Enable Register (PPE)

By analogy with the SRQ, the IST flag combines the entire status information in a single bit. It can be

read by means of a parallel poll (refer to section "Parallel Poll") or using the command *IST?.

The parallel poll enable register (PPE) determines which bits of the STB contribute to the IST flag. The

bits of the STB are ANDed with the corresponding bits of the PPE, with bit 6 being used as well in

contrast to the SRE. The IST flag results from the ORing of all results. The PPE can be set using

commands *PRE and read using command *PRE?.

Event Status Register (ESR) and Event Status Enable

The ESR is defined in IEEE 488.2. It can be compared with the EVENt part of a SCPI register. The

event status register can be read out using command *ESR?.

The ESE is the associated ENABle part. It can be set using the command *ESE and read using the

command *ESE?.

Table 5–4 Meaning of the bits in the event status register

Bit No. Meaning

0Operation Complete

This bit is set on receipt of the command *OPC exactly when all previous commands have

been executed.

1Not used

2Query Error

This bit is set if either the controller wants to read data from the instrument without having

sent a query, or if it does not fetch requested data and sends new instructions to the

instrument instead. The cause is often a query which is faulty and hence cannot be

executed.

3Device–dependent Error

This bit is set if a device–dependent error occurs. An error message with a number

between –300 and –399 or a positive error number, which denotes the error in greater

detail, is entered into the error queue.

4Execution Error

This bit is set if a received command is syntactically correct but cannot be performed for

other reasons. An error message with a number between –200 and –300, which denotes

the error in greater detail, is entered into the error queue.

5Command Error

This bit is set if a command is received, which is undefined or syntactically incorrect. An

error message with a number between –100 and –200, which denotes the error in greater

detail, is entered into the error queue.

6User Request

This bit is set on pressing the Local softkey.

7Power On (supply voltage on)

This bit is set on switching on the instrument.

R&S FSL Status Reporting System

1300.2519.12 5.19 E-11

STATus:OPERation Register

In the CONDition part, this register contains information on which actions the instrument is being

executing or, in the EVENt part, information on which actions the instrument has executed since the last

reading. It can be read using the commands STATus:OPERation:CONDition? or STATus

:OPERation[:EVENt]?.

Table 5–5 Meaning of the bits in the STATus:OPERation register

Bit No. Meaning

0CALibrating

This bit is set as long as the instrument is performing a calibration.

1to 7 Not used

8HardCOPy in progress

This bit is set while the instrument is printing a hardcopy.

9to 14 Not used

15 This bit is always 0

STATus:QUEStionable Register

This register contains information about indefinite states which may occur if the unit is operated without

meeting the specifications. It can be read using the commands STATus:QUEStionable:

CONDition? and STATus:QUEStionable[:EVENt]?.

Table 5–6 Meaning of bits in STATus:QUEStionable register

Bit No. Meaning

0to 1 These bits are not used

2BATTERY LOW

If the instrument is running without any external power supply and the charging level of the

internal battery is approximately lower than 5% this bit is set to indcate that the system will

be shut down automatically in approx. 5 minutes.

3POWer

This bit is set if a questionable power occurs (refer also to section

"STATus:QUEStionable:POWer Register")

4TEMPerature

This bit is set if a questionable temperature occurs.

5FREQuency

The bit is set if a frequency is questionable (refer to section

"STATus:QUEStionable:FREQuency Register")

6to 7 Not used

Status Reporting System R&S FSL

1300.2519.12 5.20 E-11

Bit No. Meaning

8CALibration

The bit is set if a measurement is performed unaligned (label UNCAL)

9LIMit (device–specific)

This bit is set if a limit value is violated (see also section "STATus:QUEStionable:LIMit

10 LMARgin (device–specific)

This bit is set if a margin is violated (see also section "STATus:QUEStionable:LMARgin

11 SYNC (device–dependent)

This bit is set if, in measurements or pre–measurements, synchronization to midamble

fails or no burst is found.

This bit is also set if, in pre–measurements mode, the result differs too strongly from the

expected value (see also "STATus:QUEStionable:SYNC Register").

12 ACPLimit (device–specific)

This bit is set if a limit for the adjacent channel power measurement is violated (see also

section "STATus:QUEStionable:ACPLimit Register")

13 to 14 Not used

15 This bit is always 0.

STATus:QUEStionable:ACPLimit Register

This register contains information about the observance of limits during adjacent power measurements.

It can be read using the commands 'STATus:QUEStionable:ACPLimit :CONDition?' and

'STATus:QUEStionable:ACPLimit[:EVENt]?'

Table 5–7 Meaning of bits in STATus:QUEStionable:ACPLimit register

Bit No. Meaning

0ADJ UPPer FAIL

This bit is set if the limit is exceeded in the upper adjacent channel

1ADJ LOWer FAIL

This bit is set if the limit is exceeded in the lower adjacent channel.

2ALT1 UPPer FAIL

This bit is set if the limit is exceeded in the upper 1st alternate channel.

3ALT1 LOWer FAIL

This bit is set if the limit is exceeded in the lower 1st alternate channel.

4ALT2 UPPer FAIL

This bit is set if the limit is exceeded in the upper 2nd alternate channel.

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Bit No. Meaning

5ALT2 LOWer FAIL

This bit is set if the limit is exceeded in the lower 2nd alternate channel.

6ALT3 … 11 LOWer/UPPer FAIL

This bit is set if the limit is exceeded in one off the lower or upper alternate channels

3 … 11

7to 14 Not used

15 This bit is always set to 0.

STATus:QUEStionable:FREQuency Register

This register contains information about the reference and local oscillator.

It can be read using the commands STATus:QUEStionable:FREQuency:CONDition? and

STATus :QUEStionable:FREQuency[:EVENt]?.

Table 5–8 Meaning of bits in STATus:QUEStionable:FREQuency register

Bit No. Meaning

0OVEN COLD

This bit is set if the reference oscillator has not yet attained its operating temperature.

OCXO is displayed.

1LO UNLocked

This bit is set if the local oscillator no longer locks. LOUNL is displayed.

2to 7 Not used

8EXTernalREFerence

Bit 8 indicates that the external reference oscillator is selected and no useable external

reference source is connected to the instrument. Therefore the synthesizer can not lock

and the frequency accuracy is not guaranteed.

9to 14 Not used

15 This bit is always 0.

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1300.2519.12 5.22 E-11

STATus:QUEStionable:LIMit Register

This register contains information about the observance of limit lines. It can be read using the

commands STATus:QUEStionable:LIMit:CONDition? and

STATus:QUEStionable:LIMit[:EVENt]?.

Table 5–9 Meaning of bits in STATus:QUEStionable:LIMit register

Bit No. Meaning

0LIMit 1 FAIL

This bit is set if limit line 1 is violated.

1LIMit 2 FAIL

This bit is set if limit line 2 is violated.

2LIMit 3 FAIL

This bit is set if limit line 3 is violated.

3LIMit 4 FAIL

This bit is set if limit line 4 is violated.

4LIMit 5 FAIL

This bit is set if limit line 5 is violated.

5LIMit 6 FAIL

This bit is set if limit line 6 is violated.

6LIMit 7 FAIL

This bit is set if limit line 7 is violated.

7LIMit 8 FAIL

This bit is set if limit line 8 is violated.

8to 14 Not used

15 This bit is always 0.

STATus:QUEStionable:LMARgin Register

This register contains information about the observance of limit margins. It can be read using the

commands STATus:QUEStionable:LMARgin:CONDition? and STATus

:QUEStionable:LMARgin[:EVENt]?.

Table 5–10 Meaning of bits in STATus:QUEStionable:LMARgin register

Bit No. Meaning

0LMARgin 1 FAIL

This bit is set if limit margin 1 is violated.

1LMARgin 2 FAIL

This bit is set if limit margin 2 is violated.

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Bit No. Meaning

2LMARgin 3 FAIL

This bit is set if limit margin 3 is violated.

3LMARgin 4 FAIL

This bit is set if limit margin 4 is violated.

4LMARgin 5 FAIL

This bit is set if limit margin 5 is violated.

5LMARgin 6 FAIL

This bit is set if limit margin 1 is violated.

6LMARgin 7 FAIL

This bit is set if limit margin 7 is violated.

7LMARgin 8 FAIL

This bit is set if limit margin 8 is violated.

8to 14 Not used

15 This bit is always 0.

STATus:QUEStionable:POWer Register

This register contains all information about possible overloads of the unit.

It can be read using the commands STATus:QUEStionable:POWer:CONDition? and STATus

:QUEStionable:POWer[:EVENt]?.

Table 5–11 Meaning of bits in STATus:QUEStionable:POWer register

Bit No. Meaning

0OVERload

This bit is set if the RF input is overloaded. OVLD is displayed.

1UNDerload

This bit is set if the RF input is underloaded. UNLD is displayed.

2IF_OVerload

This bit is set if the IF path is overloaded. IFOVL is displayed.

3to 14 Not used

15 This bit is always 0.

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STATus:QUEStionable:SYNC Register

This register contains information about sync and bursts not found, and about pre–measurement results

exceeding or falling short of expected values (for details on GSM power measurements refer to chapter

"Advanced Measurement Examples", and the Quick Start Guide, chapter 5, "Basic Measurement

Examples").

It can be read using the commands STATus:QUEStionable:SYNC:CONDition? and

STATus:QUEStionable:SYNC[:EVENt]?.

Table 5–12 Meaning of bits in STATus:QUEstionable:SYNC register

Bit No. Meaning

0BURSt not found

This bit is set if no burst is found in the measurements/pre–measurements for

phase/frequency error (PFE) or carrier power versus time (PVT). If a burst is found in

these measurements/pre–measurements, the bit is reset.

1SYNC not found

This bit is set if the synchronization sequence (training sequence) of the midamble is not

found in the measurements/pre–measurements for phase/frequency error (PFE) or carrier

power versus time (PVT). If the synchronization sequence (training sequence) of the

midamble is found in these measurements/pre–measurements, the bit is reset.

With option TV Trigger (B6), this bis is set in the free run trigger mode if the trigger does not

return data.

2No carrier

This bit is set if the level value determined in the pre–measurements for carrier power

versus time (PVT) and spectrum due to modulation is too low. The bit is reset at the

beginning of the pre–measurement.

3Carrier overload

This bit is set if the level value determined in the pre–measurements for carrier versus time

(PVT) and spectrum due to modulation is too high. The bit is reset at the beginning of the

pre–measurement.

4–14 Not used.

15 This bit is always 0.

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Application of the Status Reporting Systems

In order to be able to effectively use the status reporting system, the information contained there must

be transmitted to the controller and further processed there. There are several methods which are

represented in the following. For detailed program examples refer to chapter 7 "Remote Control –

Programming Examples".

Service Request

Under certain circumstances, the instrument can send a service request (SRQ) to the controller. Usually

this service request initiates an interrupt at the controller, to which the control program can react

appropriately. As evident from Fig. 5–4,an SRQ is always initiated if one or several of bits 2, 3, 4, 5 or 7

of the status byte are set and enabled in the SRE. Each of these bits combines the information of a

further register, the error queue or the output buffer. The ENABle parts of the status registers can be set

so that arbitrary bits in an arbitrary status register initiate an SRQ. In order to make use of the

possibilities of the service request effectively, all bits should be set to "1" in enable registers SRE and

ESE.

Example: Use of the command *OPC to generate an SRQ at the end of a sweep

1. CALL InstrWrite(analyzer, "*ESE 1") 'Set bit 0 in the ESE (Operation Complete)

2. CALL InstrWrite(analyzer, "*SRE 32") 'Set bit 5 in the SRE (ESB)?

After its settings have been completed, the instrument generates an SRQ.

The SRQ is the only possibility for the instrument to become active on its own. Each controller program

should set the instrument in a way that a service request is initiated in the case of malfunction. The

program should react appropriately to the service request. A detailed example for a service request

routine is to be found in chapter 7 "Remote Control – Programming Examples".

Serial Poll

In a serial poll, just as with command *STB,the status byte of an instrument is queried. However, the

query is realized via interface messages and is thus clearly faster. The serial–poll method has already

been defined in IEEE 488.1 and used to be the only standard possibility for different instruments to poll

the status byte. The method also works with instruments which do not adhere to SCPI or IEEE 488.2.

The VISUAL BASIC command for executing a serial poll is IBRSP().Serial poll is mainly used to obtain

afast overview of the state of several instruments connected to the controller.

Parallel Poll

In a parallel poll, the controller uses a single command to request up to eight instruments to transmit

one bit of information each on the data lines, i.e., to set the data line allocated to each instrument to a

logical "0" or "1". In addition to the SRE register, which determines the conditions under which an SRQ

is generated, there is a parallel poll enable register (PPE). This register is ANDed with the STB bit by bit,

considering bit 6 as well. The results are ORed, the result is possibly inverted and then sent as a

response to the parallel poll of the controller. The result can also be queried without parallel poll by

means of the command *IST?.

The instrument first has to be set for the parallel poll using the VISUAL BASIC command IBPPC().

This command allocates a data line to the instrument and determines whether the response is to be

inverted. The parallel poll itself is executed using IBRPP().

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The parallel poll method is mainly used to find out quickly which one of the instruments connected to the

controller has sent a service request. To this effect, SRE and PPE must be set to the same value.

Query by Means of Commands

Each part of any status register can be read by means of queries. The individual commands are listed in

the description of the STATus Subsystem. The returned value is always a number that represents the

bit pattern of the queried register. This number is evaluated by the controller program.

Queries are usually used after an SRQ in order to obtain more detailed information on the cause of the

SRQ.

Error Queue Query

Each error state in the instrument leads to an entry in the error queue. The entries of the error queue

are detailed plain–text error messages that can be displayed via manual operation using the setup menu

or queried via remote control using the command SYSTem:ERRor?.Each call of SYSTem:ERRor?

provides one entry from the error queue. If no error messages are stored there any more, the instrument

responds with 0, "No error".

The error queue should be queried after every SRQ in the controller program as the entries describe the

cause of an error more precisely than the status registers. Especially in the test phase of a controller

program the error queue should be queried regularly since faulty commands from the controller to the

instrument are recorded there as well.

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Reset Values of the Status Reporting System

Table 5–13 contains the different commands and events causing the status reporting system to be

reset. None of the commands, except *RST and SYSTem:PRESet,influences the functional instrument

settings. In particular, DCL does not change the instrument settings.

Table 5–13 Resetting the status reporting system

Event Switching on

supply voltage

DCL,SDC

Power–On–

Status–Clear

(Device

Clear,

Selected

Device

Clear)

*RST or

SYSTem:PRE

Set

STATus:PRE

Set

*CLS

Effect 0 1

Clear STB,ESR yes yes

Clear SRE,ESE yes    

Clear PPE yes    

Clear EVENt parts of

the registers

yes yes

Clear ENABle parts

of all OPERation and

QUEStionable

registers; Fill ENABle

parts of all other

registers with "1".

yes   yes 

Fill PTRansition parts

with "1";

Clear NTRansition

parts

yes   yes 

Clear error queue yes yes yes

Clear output buffer yes yes yes 1) 1) 1)

Clear command

processing and input

buffer

yes yes yes 

1) Every command being the first in a command line, i.e., immediately following a <PROGRAM

MESSAGE TERMINATOR> clears the output buffer.

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1300.2519.12 5.28 E-11

Interfaces and Protocols

The standard instrument is accessed via LAN in order to perform for remote control. Optional a GPIB

interface can be used for remote control, provided by option GPIB Interface, R&S FSL–B10.

LAN Interface

To be integrated in a LAN, the instrument is equipped with a LAN interface, consisting of a connector, a

network interface card and protocols (VXI–11 and RSIB). For details on the connector and its use refer

to the Quick Start Guide, chapter 1 "Front and Rear Panel".

Instrument access via VXI11 or RSIB is usually achieved from high level programming platforms by

using VISA as an intermediate abstraction layer. VISA encapsulates the low level VXI, RSIB or even

GPIB function calls and thus makes the transport interface transparent for the user. The necessary

VISA library is available as a separate product. For details contact your local R&S sales representative.

VXI Basics

The VXI–11 standard is based on the RPC protocol which in turn relies on TCP/IP as the

network/transport layer. The TCP/IP network protocol and the associated network services are

preconfigured. TCP/IP ensures connection–oriented communication, where the order of the exchanged

messages is adhered to and interrupted links are identified. With this protocol, messages cannot be lost.

Remote control of an instrument via a network is based on standardized protocols which follow the OSI

reference model (see Fig. below).

SCPI

XDR (VXI-11)

ONC-RPC

TCP / UDP

Ethernet/802.3

802.3/10BASE-T

Application

Presentation

Session

Transport

Network

Data Link

Physical

Fig. 5–5 Example for LAN remote control based on the OSI reference model

Based on TCP/UDP, messages between the controller and the instrument are exchanged via open

network computing (ONC) – remote procedure calls (RPC). With XDR (VXI–11), legal RPC messages

are known as VXI–11 standard. Based on this standard, messages are exchanged between the

controller and the instrument. The messages are identical with SCPI commands. They can be organized

in four groups:

•program messages (control command to the instrument)

•response messages (values returned by the instrument)

•service request (spontaneous queries of the instrument)

•low–level control messages (interface messages).

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1300.2519.12 5.29 E-11

AVXI–11 link between a controller and an instrument uses three channels: core, abort and interrupt

channel. Instrument control is mainly performed on the core channel (program, response and low–level

control messages). The abort channel is used for immediate abort of the core channel; the interrupt

channel transmits spontaneous service requests of the instrument. Link setup itself is very complex. For

more details refer to the VXI–11 specification.

Instrument Controller

Interrupt channel

(Service request)

Abort channel

(abort)

Core channel

(program, response,

control messages )

Fig. 5–6 VXI–11 channels between instrument and controller

The number of controllers that can address an instrument is practically unlimited in the network. In the

instrument, the individual controllers are clearly distinguished. This distinction continues up to the

application level in the controller, i.e. two applications on a computer are identified by the instrument as

two different controllers.

Instrument Controller

Controller

Fig. 5–7 Remote control via LAN from several controllers

The controllers can lock and unlock the instrument for exclusive access. This regulates access to the

instrument of several controllers.

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1300.2519.12 5.30 E-11

VXI–11 Interface Messages

On the Ethernet link, the interface messages are called low–level control messages. These messages

can be used to emulate interface messages of the GPIB.

Table 5–14 VXI–11 Interface Messages

Command Effect on the instrument

&ABO (Abort) Aborts the processing of the commands just received.

&DCL (Device Clear) Aborts the processing of the commands just received and

sets the command processing software to a defined initial

state. Does not change the instrument setting.

&GTL (Go to Local) Transition to the "Local" state (manual operation)

&GTR (Go to Remote) Transition to the "Remote" state (remote control)

&GET (Group Execute

Trigger)

Triggers a previously active device function (e.g. a sweep).

The effect of the command is the same as with that of a pulse

at the external trigger signal input.

&LLO (Local Lockout) Disables switchover from remote control to manual operation

by means of the front panel keys

&POL (Serial Poll) Starts a serial poll

&NREN (Not Remote Enable) Enables switchover from remote control to manual operation

by means of the front panel keys

RSIB Protocol Basics

The R&S defined RSIB protocol uses the TCP/IP protocol for communication with the instrument.

Remote control over RSIB is done on a message level basis using the SCPI command set of the

instrument. The RSIB protocol allows you to control the instrument not only via Visual C++– and Visual

Basic programs but also via the two Windows applications WinWord and Excel as well as via National

Instruments LabView, LabWindows/CVI and Agilent VEE. The control applications run on an external

computer in the network.

AUNIX operating system can be installed on an external computer in addition to a Windows operating

system. In this case, the control applications are created either in C or C++. The supported UNIX

operating systems include:

•Sun Solaris 2.6 Sparc Station

•Sun Solaris 2.6 Intel Platform

•Red Hat Linux 6.2 x86 Processors

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RSIB Interface Functions

The library functions are adapted to the interface functions of National Instruments for GPIB

programming. The functions supported by the libraries are listed in the following table.

Function Description

RSDLLibfind() Provides a handle for access to a device.

RSDLLibwrt() Sends a zero–terminated string to a device.

RSDLLilwrt() Sends a certain number of bytes to a device.

RSDLLibwrtf() Sends the contents of a file to a device.

RSDLLibrd() Reads data from a device into a string.

RSDLLilrd() Reads a certain number of bytes from a device.

RSDLLibrdf() Reads data from a device into a file.

RSDLLibtmo() Sets timeout for RSIB functions.

RSDLLibsre() Switches a device to the local or remote state.

RSDLLibloc() Temporarily switches a device to the local state.

RSDLLibeot() Enables/disables the END message for write operations.

RSDLLibrsp() Performs a serial poll and provides the status byte.

RSDLLibonl() Sets the device online/offline.

RSDLLTestSrq() Checks whether a device has generated an SRQ.

RSDLLWaitSrq() Waits until a device generates an SRQ.

RSDLLSwapBytes Swaps the byte sequence for binary numeric display (only required for

non–Intel platforms).

As with the National Instrument interface, the successful execution of a command can be checked by

means of the variables ibsta,iberr and ibcntl.For this purpose, all RSIB functions are assigned

references to these three variables.

Status word – ibsta

The status word ibsta provides information on the status of the RSIB interface. The following bits are

defined:

Bit

designation

Bit Hex code

Description

ERR 15 8000 Is set when an error has occurred on calling a function. If this

bit is set, iberr contains an error code that specifies the error

in greater detail.

TIMO 14 4000 Is set when a timeout has occurred on calling a function.

CMPL 80100 Is set if the response of the GPIB parser has been read out

completely. If a parser response is read out with the function

RSDLLilrd() and the length of the buffer is insufficient for

the answer, the bit will be cleared.

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Error variable – iberr

If the ERR bit (8000h) is set in the status word, iberr contains an error code which allows the error to

be specified in greater detail. Extra error codes are defined for the RSIB protocol, independent of the

National Instruments interface.

Error Error

code

Description

IBERR_CONNECT 2Setup of the connection to the measuring instrument has failed.

IBERR_NO_DEVICE 3 A function of the interface has been called with an illegal device

handle.

IBERR_MEM 4No empty memory available.

IBERR_TIMEOUT 5Timeout has occurred.

IBERR_BUSY 6The RSIB protocol is blocked by a function that is still running.

IBERR_FILE 7Error when reading or writing to a file.

IBERR_SEMA 8Error upon creating or assigning a semaphore (only under

UNIX).

Count variable – ibcntl

The variable ibcntl is updated with the number of transferred bytes each time a read or write function

is called.

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GPIB Interface (Option R&S FSL–B10)

The standard instrument is not equipped with an GPIB connector, but can be accessed via the LAN

interface for remote control. The option R&S FSL–B10 provides a GPIB interface. For details on the

connector and its use refer to the Quick Start Guide, chapter 1 "Front and Rear Panel".

GPIB Basics

The GPIB interface is described by the following characterisitics:

•8–bit parallel data transfer

•bi–directional data transfer

•three–line handshake

•high data transfer rate of max. 700 kbyte/s

•up to 15 instruments can be connected

•maximal length of the interconnecting cables 15 m (single connection, 2m)

•wired–OR connection if several instruments are connected in parallel.

Depending on the bus type the following bus lines are used:

•Data bus with 8 lines D0 to D7.

The transmission is bit–parallel and byte–serial in the ASCII/ISO code. D0 is the least significant bit,

D7 the most significant bit.

•Control bus with 5 lines

IFC (Interface Clear) active LOW resets the interfaces of the instruments connected to the

default setting.

ATN (Attention) active LOW signals the transmission of interface messages.

inactive HIGH signals the transmission of device messages.

SRQ (Service Request) active LOW enables the connected device to send a service request

to the controller.

REN (Remote Enable) active LOW permits switchover to remote control.

EOI (End or Identify) has two functions in connection with ATN:

ATN = HIGH

active LOW marks the end of data transmission.

ATN = LOW

active LOW triggers a parallel poll.

•Handshake bus with three lines

DAV (Data Valid) active LOW signals a valid data byte on the data bus.

NRFD (Not Ready For Data) active LOW signals that one of the connected devices is not ready

for data transfer.

NDAC (Not Data Accepted) active LOW signals that the instrument connected is accepting the

data on the data bus.

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GPIB Interface Functions

Instruments which can be remote controlled via the GPIB can be equipped with different interface

functions. Table 5–1 lists the interface functions appropriate for the instrument.

Table 5–1 Interface functions

Control character Interface function

SH1 Handshake source function (source handshake), full capability

AH1 Handshake sink function (acceptor handshake), full capability

L4 Listener function, full capability, unaddress if MTA.

T6 Talker function, full capability, ability to respond to serial poll,

unaddress if MLA

SR1 Service request function (Service Request), full capability

PP1 Parallel poll function, full capability

RL1 Remote/Local switch over function, full capability

DC1 Reset function (Device Clear), full capability

DT1 Trigger function (Device Trigger), full capability

C0 No controller function

GPIB Interface Messages

The messages transferred via the data lines of the GPIB can be divided into two groups: interface

messages and device messages

Interface messages are transferred on the data lines of the GPIB if the "ATN" control line is active

(LOW). They are used for communication between controller and instruments and can only be sent by

the controller which currently has control of the GPIB.

Universal Commands

The universal commands are encoded 10 – 1F hex. They affect all instruments connected to the bus

without addressing.

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Table 5–2 Universal Commands

Command QuickBASIC command Effect on the instrument

DCL (Device Clear) IBCMD (controller%,

CHR$(20))

Aborts the processing of the commands

just received and sets the command

processing software to a defined initial

state. Does not change the instrument

settings.

IFC (Interface Clear) IBSIC (controller%) Resets the interfaces to the default

setting.

LLO (Local Lockout) IBCMD (controller%,

CHR$(17))

The LOC/IEC ADDR key is disabled.

SPE (Serial Poll Enable) IBCMD (controller%,

CHR$(24))

Ready for serial poll.

SPD (Serial Poll Disable) IBCMD (controller%,

CHR$(25))

End of serial poll.

P P U ( P a r a l l e l P o l l

Unconfigure)

IBCMD (controller%,

CHR$(21))

End of the parallel–poll state.

Addressed Commands

The addressed commands are encoded 00 – 0F hex. They are only effective for instruments addressed

as listeners.

Table 5–3 Addressed Commands

Command QuickBASIC command Effect on the instrument

S D C ( S e l e c t e d D e v i c e

Clear)

IBCLR (device%) Aborts the processing of the commands

just received and sets the command

processing software to a defined initial

state. Does not change the instrument

setting.

GET (Group Execute

Trigger)

IBTRG (device%) Triggers a previously active device

function (e.g. a sweep). The effect of the

command is the same as with that of a

pulse at the external trigger signal input.

GTL (Go to Local) IBLOC (device%) Transition to the "Local" state (manual

operation).

P P C ( P a r a l l e l P o l l

Configure)

IBPPC (device%, data%) Configure instrument for parallel poll.

Additionally, the QuickBASIC command

executes PPE/PPD.

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Instrument Messages

For different interfaces, device messages are more or less alike. They are divided into two groups,

depending on the direction they are sent: commands and device responses.

Commands

Commands (program messages) are messages the controller sends to the instrument. They operate the

device functions and request information. The commands are subdivided according to two criteria:

•According to the effect they have on the instrument:

–Setting commands cause instrument settings such as a reset of the instrument or setting the

frequency.

–Queries cause data to be provided for remote control, e.g. for identification of the device or

polling a parameter value. Queries are formed by directly appending a question mark to the

header.

•According to their definition in standard:

–Common commands are exactly defined as to their function and notation in standard IEEE

488.2. They refer to functions such as management of the standardized status registers, reset

and self test.

–Device–specific commands refer to functions depending on the features of the instrument such

as frequency setting. A majority of these commands has also been standardized by the SCPI

committee. Device–specific extensions following the SCPI rules are permitted by the standard.

Device responses

Device responses (response messages and service request) are messages the instrument sends to the

controller after a query. They can contain measurement results, instrument settings and information on

the instrument status (refer to section "Responses to Queries").

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Noise Figure Measurements (K30) – Status Reporting

System

Additionally to the registers provided by the base system, the following registers are used or modified in

the Noise Figure Measurements option (K30):

•STATus:OPERation Register

Although this register is provided by the base system, the Noise Figure Measurements option

makes use of bits not used within the base system.

•STATus:QUEStionable Register

Although this register is provided by the base system, the Noise Figure Measurements option uses

different bits and definitions.

•STATus:QUEStionable:CORRection Register

This register is provided by the R&S FS–K30 option.

The following registers are provided by the base system and are not available from the Noise Figure

Measurements option (K30) command tree:

•STATus:QUEStionable:ACPLimit Register

•STATus:QUEStionable:LIMit Register

•STATus:QUEStionable:LMARgin Register

•STATus:QUEStionable:POWer Register

Detailed information on the status registers of the base system is given in section Status Reporting

System.In this section, only the new and altered status registers / bits for the Noise Figure

Measurements option (K30) are described.

This option is available from firmware version 1.50.

STATus:OPERation Register

Additionally to the bits assigned by the base system (for details refer to STATus:OPERation Register),

the bits no. 4 and 7 are defined:

Bit No Meaning

4MEASuring

A'1' in this bit position indicates that a measurement is in progress.

7CORRecting

Indicates that a user calibration is in progress.

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STATus:QUEStionable Register

Additionally to the bits assigned by the base system (for details refer to STATus:QUEStionable

Bit No Meaning

11 CORRection

This bit is set if a questionable correction data occurs (see also section

STATus:QUEStionable:CORRection Register).

STATus:QUEStionable:CORRection Register

This register comprises information about the correction state of noise measurements. It can be queried

by STATus:QUEStionable:CONDition? and STATus:QUEStionable[:EVENt]? commands.

Bit No Meaning

0NO CORRection

User calibration is required (i.e. not done, or setup changed). Will remain 1 until a user

calibration is done. Set to 1 at the start of a user calibration. It will go to 0 at the end of a

user calibration only if at least all points on one range have been calibrated. Initial value

is 1.

1These bits are not used

2UNCorrected measurement

Uncorrected measurement data (one or more points could not be corrected using

existing user calibration). Set to 0 at the start of each sweep/redisplay of result. Will

remain 0 until an attempt is made to correct a point and the calibration data does not

exist (the required range has not been calibrated).

If no calibration data exist, this bit will not be set when an attempt is made to make a

corrected measurement.

3to 14 These bits are not used

15 This bit is always 0

Error Reporting

Error reporting for the Noise Figure Measurements option is carried out using the Service Request

(SRQ) interrupt in the GPIB interface. When an error occurs a Service Request interrupt will be

generated. The master can then query the slave instrument for the error that triggered the interrupt

Errors are queried through the "SYSTem:ERRor'' command.

R&S FSL 3GPP Base Station Measurements (K72) – Status Reporting System

1300.2519.12 5.39 E-11

3GPP Base Station Measurements (K72) – Status

Reporting System

Additionally to the registers provided by the base system, the following registers are used or modified in

the 3GPP Base Station Measurements option (K72):

•STATus:QUEStionable:SYNC Register

Although this register is provided by the base system, the 3GPP Base Station Measurements option

(K72) uses different bits and definitions.

Detailed information on the status registers of the base system is given in section Status Reporting

System.In this section, only the new and altered status registers / bits for the 3GPP Base Station

Measurements option (K72) are described.

This option is available from firmware version 1.60.

STATus:QUEStionable:SYNC Register

This register contains information about failed synchronization and incorrect pilot symbols.

The bits can be queried with commands STATus:QUEStionable:SYNC:CONDition? and

STATus:QUEStionable:SYNC[:EVENt]?.

Bit No Meaning

0This bit is not used.

1K72/K74 Frame Sync failed

This bit is set when synchronization is not possible within the application.

Possible reasons:

•Incorrectly set frequency

•Incorrectly set level

•Incorrectly set scrambling code

•Incorrectly set values for Invert Q

•Invalid signal at input

2to 4 These bits are not used.

5K72/K74 Incorrect Pilot Symbol

This bit is set when one or more of the received pilot symbols are not equal to the

specified pilot symbols of the 3GPP standard.

Possible reasons:

•Incorrectly sent pilot symbols in the received frame.

•Low signal to noise ratio (SNR) of the WCDMA signal.

•One or more code channels have a significantly lower power level compared to the

total power. The incorrect pilots are detected in these channels because of low

channel SNR.

•One or more channels are sent with high power ramping. In slots with low relative

power to total power, the pilot symbols might be detected incorrectly (check the

signal quality by using the symbol constellation display).

6to 14 These bits are not used.

15 This bit is always 0.

CDMA2000 (K82) and 1xEV-DO (K84) BTS Analyzer – Status Reporting SystemR&S FSL

1300.2519.12 5.40 E-11

CDMA2000 (K82) and 1xEV-DO (K84) BTS Analyzer –

Status Reporting System

Additionally to the registers provided by the base system, the following register is used in the

CDMA2000 BTS Analyzer option (K82):

•STATus:QUEstionable:SYNC Register

Although this register is provided by the base system, the CDMA2000 BTS Analyzer option (K82)

uses different bits and definitions.

Detailed information on the status registers of the base system is given in section Status Reporting

System.In this section, only the new and altered status registers / bits for the CDMA2000 BTS Analyzer

option (K82) are described.

This option is available from firmware version 1.90.

STATus:QUEstionable:SYNC Register

This register contains information on the error situation in the code domain analysis of the CDMA2000

BTS Analyzer option.

The bits can be queried with commands STATus:QUEStionable:SYNC:CONDition? and

STATus:QUEStionable:SYNC[:EVENt]?.

Bit No Meaning

0This bit is not used.

1K82 Frame Sync failed

This bit is set when synchronization is not possible within the application.

Possible reasons:

•Incorrectly set frequency

•Incorrectly set level

•Incorrectly set PN Offset

•Incorrectly set values for Swap IQ

•Invalid signal at input

2to 14 These bits are not used.

15 This bit is always 0.

R&S FSL WLAN TX Measurements (K91/K91n) - Status Reporting System

1300.2519.12 5.41 E-11

WLAN TX Measurements (K91/K91n) – Status Reporting

System

Additionally to the registers provided by the base system, the following registers are used or modified in

the WLAN TX Measurements option (K91/K91n):

•STATus:OPERation Register

Although this register is provided by the base system, the WLAN TX Measurements option (K91)

makes use of bits not used within the base system.

•STATus:QUEStionable:LIMit Register,STATus:QUEStionable:SYNC Register

Although this register is provided by the base system, the WLAN TX Measurements option (K91)

uses different bits and definitions.

The following registers are provided by the base system and are not available from the WLAN TX

Measurements option (K91) command tree:

•STATus:QUEStionable:ACPLimit Register

•STATus:QUEStionable:LMARgin Register

Detailed information on the status registers of the base system is given in section Status Reporting

System.In this section, only the new and altered status registers / bits for the WLAN TX Measurements

option (K91) are described.

This option is available from firmware version 1.20.

STATus:OPERation Register

Additionally to the bits assigned by the base system (for details refer to STATus:OPERation Register),

bit no. 4 is defined:

Bit No Meaning

4MEASuring

This bit is set while a measurement is in progress.

WLAN TX Measurements (K91K91n) – Status Reporting System R&S FSL

1300.2519.12 5.42 E-11

STATus:QUEStionable:LIMit Register

This register comprises information about the observance of limit lines in the corresponding

measurement window (LIMit 1 corresponds to screen A, LIMit 2 to screen B). It can be queried with the

STATus:QUEStionable:LIMit<1|2>:CONDition? and

STATus:QUEStionable:LIMit<1|2>[:EVENt]? commands.

Note: No limit lines are displayed in screen A and therefore all bits in the LIMit1 register will always be

set to 0.

Bit No Meaning

0to 1 These bits are not used.

2LIMit FAIL

This bit is set if the ETSI Spectrum Mask limit line is violated.

3LIMit FAIL

This bit is set if the Spectrum Flatness (Upper) limit line is violated.

4LIMit FAIL

This bit is set if the Spectrum Flatness (Lower) limit line is violated.

5LIMit FAIL

This bit is set if the IEEE Spectrum Mask limit line is violated.

6LIMit FAIL

This bit is set if the PVT Rising Edge max limit is violated.

7LIMit FAIL

This bit is set if the PVT Rising Edge mean limit is violated.

8LIMit FAIL

This bit is set if the PVT Falling Edge max limit is violated.

9LIMit FAIL

This bit is set if the PVT Falling Edge mean limit is violated.

10 to 14 These bits are not used.

15 This bit is always 0.

R&S FSL WLAN TX Measurements (K91/K91n) – Status Reporting System

1300.2519.12 5.43 E-11

STATus:QUEStionable:SYNC Register

This register contains information about sync and bursts not found, and about pre–measurement results

exceeding or falling short of expected values.

The bits can be queried with commands "STATus:QUEStionable:SYNC:CONDition?" and

"STATus:QUEStionable:SYNC[:EVENt]?".

Bit No Meaning

0BURSt not found

This bit is set if an IQ measurement is performed and no bursts are detected.

1This bit is not used

2no bursts of REQuired type

This bit is set if an IQ measurement is performed and no bursts of the specified type are

detected.

3GATE length too small

This bit is set if gating is used in a measurement and the gate length is not set

sufficiently large enough.

4BURSt count too small

This bit is set if a PVT measurement is performed with gating active and there is not at

least 1 burst within the gate lines.

5auto level OVERload

This bit is set if a signal overload is detected when an auto–level measurement is

performed.

6auto level NoSIGnal

This bit is set if no signal is detected by the auto–level measurement.

7to 14 These bits are not used.

15 This bit is always 0.

Error Reporting

Error reporting for the WLAN TX Measurements option (K91) is carried out using the Service Request

(SRQ) interrupt in the GPIB interface. When an error occurs a Service Request interrupt will be

generated. The master can then query the slave instrument for the error that triggered the interrupt

errors are queried through the "SYSTem:ERRor'' command.

WiMAX, WiBro Measurements (K92/K93) – Status Reporting System R&S FSL

1300.2519.12 5.44 E-11

WiMAX, WiBro Measurements (K92/K93) – Status

Reporting System

Additionally to the registers provided by the base system, the following registers are used or modified in

the WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K93):

•STATus:OPERation Register

Although this register is provided by the base system, the WiMAX IEEE 802.16 OFDM, OFDMA

Measurements option (R&S FSL–K93) makes use of bits not used within the base system.

•STATus:QUEStionable:LIMit Register, STATus:QUEStionable:SYNC Register

Although these registers are provided by the base system, the WiMAX IEEE 802.16 OFDM,

OFDMA Measurements option (R&S FSL–K93) uses different bits and definitions.

The following registers are provided by the base system and are not available from the WiMAX IEEE

802.16 OFDM, OFDMA Measurements option (R&S FSL–K93) command tree:

•STATus:QUEStionable:ACPLimit Register

•STATus:QUEStionable:LMARgin Register

Detailed information on the status registers of the base system is given in section Status Reporting

System.In this section, only the new and altered status registers / bits for the WiMAX IEEE 802.16

OFDM, OFDMA Measurements option (R&S FSL–K93) are described.

The WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K93) includes the

functionality of the WiMAX 802.16 OFDM Measurements option (R&S FSL–K92). Accordingly both

options are described together in this section. The options are available from firmware version 1.40

(R&S FSL–K92) and 1.50 (R&S FSL–K93).

STATus:OPERation Register

Additionally to the bits assigned by the base system (for details refer to STATus:OPERation Register),

bit no. 4 is defined:

Bit No Meaning

4MEASuring

This bit is set while a measurement is in progress.

R&S FSL WiMAX, WiBro Measurements (K92/K93) – Status Reporting System

1300.2519.12 5.45 E-11

STATus:QUEStionable:LIMit Register

This register comprises information about the observance of limit lines in the corresponding

measurement window (LIMit 1 corresponds to screen A, LIMit 2 to screen B). It can be queried with the

STATus:QUEStionable:LIMit<1|2>:CONDition? and

STATus:QUEStionable:LIMit<1|2>[:EVENt]? commands.

Note: No limit lines are displayed in screen A and therefore all bits in the LIMit1 register will always be

set to 0.

Bit No Meaning

0to 1 These bits are not used.

2LIMit FAIL

This bit is set if the ETSI Spectrum Mask limit line is violated.

3LIMit FAIL

This bit is set if the IEEE Spectrum Mask limit line is violated.

4LIMit FAIL

This bit is set if the Spectrum Flatness (Upper) limit line is violated.

5LIMit FAIL

This bit is set if the Spectrum Flatness (Lower) limit line is violated.

6LIMit FAIL

This bit is set if the Spectrum Flatness Difference (Upper) limit line is violated.

7LIMit FAIL

This bit is set if the Spectrum Flatness Difference (Lower) limit line is violated.

8to 14 These bits are not used.

15 This bit is always 0.

STATus:QUEStionable:SYNC Register

This register contains information about sync and bursts not found, and about pre–measurement results

exceeding or falling short of expected values.

The bits can be queried with commands "STATus:QUEStionable:SYNC:CONDition?" and

"STATus:QUEStionable:SYNC[:EVENt]?".

Bit No Meaning

0BURSt not found

This bit is set if an IQ measurement is performed and no bursts are detected.

1This bit is not used.

2no bursts of REQuired type

This bit is set if an IQ measurement is performed and no bursts of the specified type are

detected.

3GATE length too small

This bit is set if gating is used in a measurement and the gate length is not set

sufficiently large enough.

4BURSt count too small

This bit is set if a PVT measurement is performed with gating active and there is not at

least 1 burst within the gate lines.

5auto level OVERload

This bit is set if a signal overload is detected when an auto–level measurement is

performed.

WiMAX, WiBro Measurements (K92/K93) – Status Reporting System R&S FSL

1300.2519.12 5.46 E-11

Bit No Meaning

6auto level NoSIGnal

This bit is set if no signal is detected by the auto–level measurement.

7to 14 These bits are not used.

15 This bit is always 0.

Error Reporting

Error reporting for the WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K92/K93)

is carried out using the Service Request (SRQ) interrupt in the GPIB interface. When an error occurs a

Service Request interrupt will be generated. The master can then query the slave instrument for the

error that triggered the interrupt errors are queried through the "SYSTem:ERRor'' command.

R&S FSL Notation

1300.2519.12 6.1 E-11

Contents of Chapter 6

6Remote Control – Commands...................................................................... 6.1

Notation .............................................................................................................................................6.2

Remote Commands of the Base Unit .............................................................................................6.5

Common Commands..................................................................................................................6.6

ABORt Subsystem....................................................................................................................6.10

CALCulate Subsystem..............................................................................................................6.11

CALibration Subsystem ..........................................................................................................6.120

DIAGnostic Subsystem...........................................................................................................6.122

DISPlay Subsystem ................................................................................................................6.126

FORMat Subsytem .................................................................................................................6.138

HCOPy Subsystem.................................................................................................................6.139

INITiate Subsystem ................................................................................................................6.146

INPut Subsystem ....................................................................................................................6.150

INSTrument Subsystem..........................................................................................................6.153

MMEMory Subsystem.............................................................................................................6.154

OUTPut Subsystem ................................................................................................................6.169

SENSe Subsystem .................................................................................................................6.172

SOURce Subsystem...............................................................................................................6.235

STATus Subsystem ................................................................................................................6.237

SYSTem Subsystem...............................................................................................................6.253

TRACe Subsystem .................................................................................................................6.263

TRIGger Subsystem ...............................................................................................................6.277

UNIT Subsystem.....................................................................................................................6.283

Remote Commands of the Analog Demodulation Option (K7)................................................6.284

CALCulate Subsystem (Analog Demodulation, K7) ...............................................................6.285

DISPlay Subsystem (Analog Demodulation, K7)....................................................................6.295

INSTrument Subsystem (Analog Demodulation, K7) .............................................................6.297

SENSe Subsystem (Analog Demodulation, K7).....................................................................6.298

TRACe Subsystem (Analog Demodulation, K7).....................................................................6.328

TRIGger Subsystem (Analog Demodulation, K7)...................................................................6.329

UNIT Subsystem (Analog Demodulation, K7) ........................................................................6.331

Remote Commands of the Bluetooth Measurements Option (K8)..........................................6.332

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) ..............................................................6.333

CALCulate:DELTamarker Subsystem (BLUETOOTH, K8) ....................................................6.353

CALCulate:MARKer Subsystem (BLUETOOTH, K8).............................................................6.354

CONFigure:BTOoth Subsystem (BLUETOOTH, K8) .............................................................6.355

DISPlay Subsystem (BLUETOOTH, K8) ................................................................................6.369

INSTrument Subsystem (BLUETOOTH, K8)..........................................................................6.370

SENSe Subsystem (BLUETOOTH, K8) .................................................................................6.371

Remote Commands of the Power Meter Option (K9)................................................................6.377

CALCulate Subsystem (Power Meter, K9) .............................................................................6.378

R&S FSL Notation

1300.2519.12 6.2 E-11

CALibration Subsystem (Power Meter, K9)............................................................................6.380

FETCh Subsystem (Power Meter, K9) ...................................................................................6.381

READ Subsystem (Power Meter, K9).....................................................................................6.382

SENSe Subsystem (Power Meter, K9)...................................................................................6.383

UNIT Subsystem (Power Meter, K9) ......................................................................................6.388

Remote Commands of the Spectrogram Measurement Option (K14) ....................................6.389

CALCulate Subsystem (SPECM, K14)...................................................................................6.390

INITiate Subsystem (SPECM, K14)........................................................................................6.407

MMEMory Subsystem (SPECM, K14)....................................................................................6.408

TRACe Subsystem (SPECM, K14) ........................................................................................6.409

Remote Commands of the Cable TV Measurements Option (K20) .........................................6.410

ABORt Subsystem (CATV, K20) ............................................................................................6.411

CALCulate Subsystem (CATV, K20) ......................................................................................6.412

CONFigure Subsystem (CATV, K20) .....................................................................................6.469

DISPlay Subsystem (CATV, K20) ..........................................................................................6.474

FORMat Subsystem (CATV, K20)..........................................................................................6.479

INITiate Subsystem (CATV, K20)...........................................................................................6.480

INPut Subsystem (CATV, K20)...............................................................................................6.481

INSTrument Subsystem (CATV, K20) ....................................................................................6.482

MMEMory Subsystem (CATV, K20) .......................................................................................6.483

SENSe Subsystem (CATV, K20)............................................................................................6.484

SETup:TV Subsystem (CATV, K20).......................................................................................6.509

SOURce Subsystem (CATV, K20) .........................................................................................6.511

STATus Subsystem (CATV, K20) ..........................................................................................6.512

TRACe Subsystem (CATV, K20)............................................................................................6.516

TRIGger Subsystem (CATV, K20)..........................................................................................6.517

UNIT Subsystem (CATV, K20) ...............................................................................................6.520

Remote Commands of the Noise Figure Measurements Option (K30)...................................6.521

ABORt Subsystem (Noise Figure, K30) .................................................................................6.522

CALCulate Subsystem (Noise Figure, K30) ...........................................................................6.523

CONFigure Subsystem (Noise Figure, K30) ..........................................................................6.532

DISPlay Subsystem (Noise Figure, K30)................................................................................6.534

FETCh Subsystem (Noise Figure, K30) .................................................................................6.541

INITiate Subsystem (Noise Figure, K30) ................................................................................6.545

INPut Subsystem (Noise Figure, K30)....................................................................................6.546

INSTrument Subsystem (Noise Figure, K30) .........................................................................6.547

SENSe Subsystem (Noise Figure, K30).................................................................................6.548

STATus Subsystem (Noise Figure, K30)................................................................................6.558

SYSTem Subsystem (Noise Figure, K30) ..............................................................................6.563

Remote Commands of the 3GPP Base Station Measurements Option (K72) ........................6.564

ABORt Subsystem (WCDMA, K72)........................................................................................6.565

CALCulate Subsystem (WCDMA, K72)..................................................................................6.566

CONFigure:WCDPower Subsystem (WCDMA, K72).............................................................6.576

DISPlay Subsystem (WCDMA, K72) ......................................................................................6.577

INITiate Subsystem (WCDMA, K72) ......................................................................................6.579

R&S FSL Notation

1300.2519.12 6.3 E-11

INPut Subsystem (WCDMA, K72) ..........................................................................................6.580

INSTrument Subsystem (WCDMA, K72)................................................................................6.581

SENSe Subsystem (WCDMA, K72) .......................................................................................6.582

STATus:QUEStionable Subsystem (WCDMA, K72) ..............................................................6.591

TRACe Subsystem (WCDMA, K72) .......................................................................................6.592

TRIGger Subsystem (WCDMA, K72) .....................................................................................6.595

Remote Commands of the CDMA2000 BTS Analyzer Option (K82)........................................6.596

CALCulate Subsystem (CDMA, K82).....................................................................................6.597

CONFigure Subsystem (CDMA, K82) ....................................................................................6.604

DISPlay Subsystem (CDMA, K82) .........................................................................................6.611

INSTrument Subsystem (CDMA, K82) ...................................................................................6.613

SENSe Subsystem (CDMA, K82)...........................................................................................6.614

TRACe Subsystem (CDMA, K82)...........................................................................................6.624

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) ...........................................6.633

CALCulate Subsystem (EVDO, K84) .....................................................................................6.634

CONFigure Subsystem (EVDO, K84).....................................................................................6.643

DISPlay Subsystem (EVDO, K84)..........................................................................................6.653

INSTrument Subsystem (EVDO, K84) ...................................................................................6.655

SENSe Subsystem (EVDO, K84) ...........................................................................................6.656

TRACe Subsystem (1xEV-DO, K84) ......................................................................................6.664

Remote Commands of the WLAN TX Measurements Option (K91 / K91n) ............................6.671

ABORt Subsystem (WLAN, K91 / K91n) ................................................................................6.672

CALCulate:BURSt Subsystem (WLAN, K91 / K91n)..............................................................6.673

CALCulate:LIMit Subsystem (WLAN, K91 / K91n).................................................................6.674

CALCulate:MARKer Subsystem (WLAN, K91 / K91n) ...........................................................6.691

CONFigure Subsystem (WLAN, K91 / K91n) .........................................................................6.698

DISPlay Subsystem (WLAN, K91 / K91n) ..............................................................................6.709

FETCh Subsystem (WLAN, K91 / K91n)................................................................................6.712

FORMat Subsystem (WLAN, K91 / K91n)..............................................................................6.721

INITiate Subsystem (WLAN, K91 / K91n)...............................................................................6.722

INPut Subsystem (WLAN, K91 / K91n) ..................................................................................6.723

INSTrument Subsystem (WLAN, K91 / K91n)........................................................................6.724

MMEMory Subsystem (WLAN, K91 / K91n)...........................................................................6.725

SENSe Subsystem (WLAN, K91 / K91n) ...............................................................................6.726

STATus Subsystem (WLAN, K91 / K91n) ..............................................................................6.741

TRACe Subsystem (WLAN, K91 / K91n) ...............................................................................6.745

TRIGger Subsystem (WLAN, K91 / K91n) .............................................................................6.751

UNIT Subsystem (WLAN, K91 / K91n)...................................................................................6.753

Remote Commands of the WiMAX, WiBro Measurements Option (K92/K93) ........................6.755

ABORt Subsystem (WiMAX, K92/K93) ..................................................................................6.757

CALCulate:BURSt Subsystem (WiMAX, K92/K93) ................................................................6.758

CALCulate:LIMit Subsystem (WiMAX, K92/K93) ...................................................................6.759

CALCulate:MARKer Subsystem (WiMAX, K92/K93) .............................................................6.775

CONFigure Subsystem (WiMAX, K92/K93) ...........................................................................6.783

DISPlay Subsystem (WiMAX, K92/K93).................................................................................6.811

R&S FSL Notation

1300.2519.12 6.4 E-11

FETCh Subsystem (WiMAX, K92/K93) ..................................................................................6.816

FORMat Subsystem (WiMAX, K92/K93) ................................................................................6.828

INITiate Subsystem (WiMAX, K92/K93) .................................................................................6.829

INPut Subsystem (WiMAX, K92/K93).....................................................................................6.830

INSTrument Subsystem (WiMAX, K92/K93) ..........................................................................6.831

MMEMory Subsystem (WiMAX, K92/K93) .............................................................................6.832

SENSe Subsystem (WiMAX, K92/K93)..................................................................................6.834

STATus Subsystem (WiMAX, K92/K93).................................................................................6.851

SYSTEM Subsystem (WiMAX, K92/K93)...............................................................................6.855

TRACe Subsystem (WiMAX, K92/K93)..................................................................................6.856

TRIGger Subsystem (WiMAX, K92/K93)................................................................................6.864

UNIT Subsystem (WiMAX, K92/K93) .....................................................................................6.867

R&S FSL Notation

1300.2519.12 6.1 E-11

6 Remote Control – Commands

This chapter describes all remote control commands for the analyzer functions, firmware options (see

list below) and the basic settings functions of the R&S FSL in detail. Commands that are used both for

analyzer functions and firmware options are described in the analyzer commands section. The mode

information is provided for each command.

Afew commands are implemented for reasons of compatibility with the R&S FSP family only. These

commands are not described in the R&S FSL documentation, because they have no effect.

Each subsystem starts with a list of commands, which provides quick access to all commands of the

subsystem. Be aware, that for one subsystem more than one SCPI command lists can exist, depending

on the functionality (analyzer and basic settings, options). For details on the notation refer to "Notation".

Remote commands of firmware and firmware options

–"Remote Commands of the Base Unit" on page 6.5

–"Remote Commands of the Analog Demodulation Option (K7)" on page 6.284

–"Remote Commands of the Bluetooth Measurements Option (K8)" on page 6.332

–"Remote Commands of the Power Meter Option (K9)" on page 6.377

–"Remote Commands of the Spectrogram Measurement Option (K14)" on page 6.389

–"Remote Commands of the Cable TV Measurements Option (K20)" on page 6.410

–"Remote Commands of the Noise Figure Measurements Option (K30)" on page 6.521

–"Remote Commands of the 3GPP Base Station Measurements Option (K72)" on page 6.564

–"Remote Commands of the CDMA2000 BTS Analyzer Option (K82)" on page 6.596

–"Remote Commands of the 1xEV-DO BTS Analyzer Option (K84)" on page 6.633

–"Remote Commands of the WLAN TX Measurements Option (K91 / K91n)" on page 6.671

–"Remote Commands of the WiMAX, WiBro Measurements Option (K92/K93)" on page 6.755

R&S FSL Notation

1300.2519.12 6.2 E-11

Notation

In the following sections, all commands implemented in the instrument are first listed and then

described in detail, arranged according to the command subsystems. The notation is adapted to the

SCPI standard. The SCPI conformity information is included in the individual description of the

commands.

•Individual Description

•Upper/Lower Case Notation

•Special Characters

•Description of Parameters

Individual Description

The individual description contains the complete notation of the command. An example for each

command, the *RST value and the SCPI information are included as well.

The options and operating modes for which a command can be used are indicated by the following

abbreviations:

Abbreviation Description

Aspectrum analysis

A–F spectrum analysis – span > 0 only (frequency mode)

A–T spectrum analysis – zero span only (time mode)

ADEMOD analog demodulation (option R&S FSL–K7)

BT Bluetooth measurements (option R&S FSL–K8)

CATV cable TV measurements (option R&S FSL–K20)

CDMA CDMA2000 Base Station measurements (option R&S FSL-K82)

NF noise figure measurements (option R&S FSL–K30)

OFDM WiMAX IEEE 802.16 OFDM measurements

(options R&S FSL–K92/K93)

OFDMA/WiBro WiMAX IEEE 802.16e OFDMA/WiBro measurements

(option R&S FSL–K93)

PSM power sensor measurements (option R&S FSL–K9)

SPECM spectrogram measurements (option R&S FSL–K14)

WCDMA 3GPP Base Station measurements (option R&S FSL–K72)

WLAN WLAN TX measurements (option R&S FSL–K91)

Note: The spectrum analysis (analyzer) mode is implemented in the basic unit. For the other modes,

the corresponding options are required.

Upper/Lower Case Notation

Upper/lower case letters are used to mark the long or short form of the key words of a command in the

description (see chapter 5 "Remote Control – Basics"). The instrument itself does not distinguish

between upper and lower case letters.

R&S FSL Notation

1300.2519.12 6.3 E-11

Special Characters

| A selection of key words with an identical effect exists for several commands. These

keywords are indicated in the same line; they are separated by a vertical stroke. Only one of

these keywords needs to be included in the header of the command. The effect of the

command is independent of which of the keywords is used.

Example:

SENSe:FREQuency:CW|:FIXed

The two following commands with identical meaning can be created. They set the

frequency of the fixed frequency signal to 1 kHz:

SENSe:FREQuency:CW 1E3

SENSe:FREQuency:FIXed 1E3

Avertical stroke in parameter indications marks alternative possibilities in the sense of "or".

The effect of the command is different, depending on which parameter is used.

Example: Selection of the parameters for the command

[SENSe<1|2>:]AVERage:TYPE VIDeo | LINear

If parameter SINGle is selected, full screen is displayed, in the case of SPLit, split screen

is displayed.

[] Key words in square brackets can be omitted when composing the header. The full

command length must be accepted by the instrument for reasons of compatibility with the

SCPI standards.

Parameters in square brackets can be incorporated optionally in the command or omitted as

well.

{} Parameters in braces can be incorporated optionally in the command, either not at all, once

or several times.

Description of Parameters

Due to the standardization, the parameter section of SCPI commands consists always of the same

syntactical elements. SCPI has therefore specified a series of definitions, which are used in the tables

of commands. In the tables, these established definitions are indicated in angled brackets (<...>) and

will be briefly explained in the following (see also chapter 5 "Remote Control – Basics", section

"Parameters").

This keyword refers to parameters which can adopt two states, "on" and "off". The "off" state may either

be indicated by the keyword OFF or by the numeric value 0, the "on" state is indicated by ON or any

numeric value other than zero. Parameter queries are always returned the numeric value 0 or 1.

<numeric_value> <num>

R&S FSL Notation

1300.2519.12 6.4 E-11

These keywords mark parameters which may be entered as numeric values or be set using specific

keywords (character data). The following keywords given below are permitted:

MAXimum:This keyword sets the parameter to the largest possible value.

MINimum: This keyword sets the parameter to the smallest possible value.

DEFault: This keyword is used to reset the parameter to its default value.

UP:This keyword increments the parameter value.

DOWN:This keyword decrements the parameter value.

The numeric values associated to MAXimum/MINimum/DEFault can be queried by adding the

corresponding keywords to the command. They must be entered following the quotation mark.

Example:

SENSe:FREQuency:CENTer? MAXimum

Returns the maximum possible numeric value of the center frequency as result.

This keyword is provided for commands the parameters of which consist of a binary data block.

R&S FSL Remote Commands of the Base Unit

1300.2519.12 6.5 E-11

Remote Commands of the Base Unit

In this section all remote control commands for base unit functions are described in detail.

Subsystems of the analyzer

–"Common Commands" on page 6.6

–"ABORt Subsystem" on page 6.10

–"CALCulate Subsystem" on page 6.11

–"CALibration Subsystem" on page 6.120

–"DIAGnostic Subsystem" on page 6.122

–"DISPlay Subsystem" on page 6.126

–"FORMat Subsytem" on page 6.138

–"HCOPy Subsystem" on page 6.139

– "INITiate Subsystem" on page 6.146

–"INPut Subsystem" on page 6.150

–"INSTrument Subsystem" on page 6.153

–"MMEMory Subsystem"on page 6.154

–"OUTPut Subsystem" on page 6.169

–"SENSe Subsystem" on page 6.172

–"SOURce Subsystem" on page 6.235

–"STATus Subsystem" on page 6.237

–"SYSTem Subsystem" on page 6.253

–"TRACe Subsystem" on page 6.263

–"TRIGger Subsystem" on page 6.277

–"UNIT Subsystem" on page 6.283

Common Commands R&S FSL

1300.2519.12 6.6 E-11

Common Commands

The common commands are taken from the IEEE 488.2 (IEC 625-2) standard. A particular command

has the same effect on different devices. The headers of these commands consist of an asterisk "*"

followed by three letters. Many common commands refer to the status reporting system which is

described in detail in chapter 5 "Remote Control - Basics".

Available Common Commands

–*CAL?

–*CLS

–*ESE

–*ESR?

–*IDN?

–*IST?

–*OPC

–*OPT?

–*PCB

–*PRE

–*PSC

–*RST

–*SRE

–*STB?

–*TRG

–*TST?

–*WAI

*CAL?

CALIBRATION QUERY initiates a calibration of the instrument and subsequently queries the

calibration status. Responses > 0 indicate errors.

*CLS

CLEAR STATUS sets the status byte (STB), the standard event register (ESR) and the EVENt

part of the QUEStionable and the OPERation register to zero. The command does not alter the

mask and transition parts of the registers. It clears the output buffer.

*ESE

EVENT STATUS ENABLE sets the event status enable register to the value indicated. The

query form *ESE? returns the contents of the event status enable register in decimal form.

Parameter

0to 255

R&S FSL Common Commands

1300.2519.12 6.7 E-11

*ESR?

STANDARD EVENT STATUS QUERY returns the contents of the event status register in

decimal form (0 to 255) and subsequently sets the register to zero.

Parameter

0to 255

*IDN?

IDENTIFICATION QUERY queries the instrument identification.

Return values (examples)

LEGacy format, example for R&S FSL6:

Rohde&Schwarz,FSL-6,100005/016,1.80

NEW format, example for R&S FSL6:

Rohde&Schwarz,FSL-6,1300.2502K16/100005,1.80

FSL-6 device name

100005/016 serial number/model

1300.2502K16/100005 part number/serial number

1.80 firmware version

*IST?

INDIVIDUAL STATUS QUERY returns the contents of the IST flag in decimal form. The IST flag

is the status bit which is sent during a parallel poll (see chapter 5 "Remote Control - Basics").

Parameter

0 | 1

*OPC

OPERATION COMPLETE sets bit 0 in the event status register after all preceding commands

have been executed. This bit can be used to initiate a service request (see chapter 5 "Remote

Control - Basics").

*OPT?

OPTION IDENTIFICATION QUERY queries the options included in the instrument and returns a

list of the options installed. The options are separated from each other by means of commas.

Parameter

B<number> hardware options

K<number> software options

For a list of all available options and their description refer to the CD-ROM.

Example

B4,B5,B6,B7,B8,B10,B22,B30,B31,K7,K9

Common Commands R&S FSL

1300.2519.12 6.8 E-11

*PCB

PASS CONTROL BACK indicates the controller address which the remote control is to be

returned to after termination of the triggered action.

Parameter

0to 30

*PRE

PARALLEL POLL REGISTER ENABLE sets the parallel poll enable register to the indicated

value. The query form *PRE? returns the contents of the parallel poll enable register in decimal

form.

Parameter

0to 255

*PSC

POWER ON STATUS CLEAR determines whether the contents of the ENABle registers are

preserved or reset during power-up.

The quer y form *PSC? reads out the contents of the po wer- on-status-clear flag. The response can

be 0 or 1.

Parameter

0Causes the contents of the status registers to be preserved. Thus a service

request can be generated when switching on the instrument, if the status

registers ESE and SRE are suitably configured.

1Resets the registers.

*RST

RESET sets the instrument to a defined default status. The command essentially corresponds

to pressing the PRESET key. The default settings are described in section "Remote Commands

of the Base Unit", "Initializing the Configuration - PRESET Key".

*SRE

SERVICE REQUEST ENABLE sets the service request enable register to the indicated value.

Bit 6 (MSS mask bit) remains 0. This command determines under which conditions a service

request is generated. The query form *SRE? reads the contents of the service request enable

Parameter

0to 255

*STB?

READ STATUS BYTE QUERY reads out the contents of the status byte in decimal form.

R&S FSL Common Commands

1300.2519.12 6.9 E-11

*TRG

TRIGGER initiates all actions in the currently active test screen expecting a trigger event. This

command corresponds to the INITiate:IMMediate command. For details refer to section

"Remote Commands of the Base Unit", "TRIGger Subsystem".

*TST?

SELF TEST QUERY initiates the self test of the instrument and outputs an error code in decimal

form.

Parameter

0 = no error

*WAI

WAIT-to-CONTINUE permits servicing of subsequent commands only after all preceding

commands have been executed and all signals have settled (see chapter 5 "Remote Control -

Basics", and *OPC command).

ABORt Subsystem R&S FSL

1300.2519.12 6.10 E-11

ABORt Subsystem

The ABORt subsystem contains the commands for aborting triggered actions. An action can be

triggered again immediately after being aborted. All commands trigger events, and therefore they have

no *RST value.

Commands of the ABORt Subsystem

–ABORt

ABORt

This command aborts a current measurement and resets the trigger system.

Example

ABOR;INIT:IMM

Characteristics

RST value: –

SCPI: conform

Mode

all

R&S FSL CALCulate Subsystem

1300.2519.12 6.11 E-11

CALCulate Subsystem

The CALCulate subsystem contains commands for converting instrument data, transforming and

carrying out corrections. These functions are carried out subsequent to data acquisition, i.e. following

the SENSe subsystem.

The following subsystems are included:

•"CALCulate:DELTamarker Subsystem" on page 6.12

•"CALCulate:DLINe Subsystem" on page 6.23

•"CALCulate:ESPectrum Subsystem" on page 6.24

•"CALCulate:FLINe Subsystem" on page 6.26

•"CALCulate:LIMit Subsystem" on page 6.27

•"CALCulate:MARKer Subsystem" on page 6.55

•"CALCulate:MATH Subsystem" on page 6.108

•"CALCulate:PSEarch|PEAKsearch Subsystem" on page 6.110

•"CALCulate:STATistics Subsystem" on page 6.112

•"CALCulate:THReshold Subsystem" on page 6.117

•"CALCulate:TLINe Subsystem" on page 6.118

•"CALCulate:UNIT Subsystem" on page 6.119

CALCulate Subsystem R&S FSL

1300.2519.12 6.12 E-11

CALCulate:DELTamarker Subsystem

The CALCulate:DELTamarker subsystem controls the delta marker functions of the instrument.

Commands of the CALCulate:DELTamarker Subsystem

–CALCulate<1|2>:DELTamarker<1...4>[:STATe]

–CALCulate<1|2>:DELTamarker<1...4>:AOFF

–CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed[:STATe]

–CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:MAXimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:X

–CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:Y

–CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:Y:OFFSet

–CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PNOise[:STATe]

–CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PNOise:RESult?

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum:NEXT

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt

–CALCulate<1|2>:DELTamarker<1...4>:MINimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT

–CALCulate<1|2>:DELTamarker<1...4>:MINimum:NEXT

–CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt

–CALCulate<1|2>:DELTamarker<1...4>:MODE

–CALCulate<1|2>:DELTamarker<1...4>:TRACe

–CALCulate<1|2>:DELTamarker<1...4>:X

–CALCulate<1|2>:DELTamarker<1...4>:X:RELative?

–CALCulate<1|2>:DELTamarker<1...4>:Y?

CALCulate<1|2>:DELTamarker<1...4>[:STATe]

This command switches on and off the delta marker when delta marker 1 is selected. The

corresponding marker becomes the delta marker when delta marker 2 to 4 is selected. If the

corresponding marker is not activated, it will be activated and positioned on the maximum of the

measurement curve.

If no numeric suffix with DELTamarker is indicated, delta marker 1 is selected automatically.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

Parameter

ON | OFF

Example

CALC:DELT3 ON

Switches marker 3 to delta marker mode.

R&S FSL CALCulate Subsystem

1300.2519.12 6.13 E-11

Characteristics

RST value: OFF

SCPI: device–specific

Mode

all

CALCulate<1|2>:DELTamarker<1...4>:AOFF

This command switches off all active delta markers.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

Example

CALC:DELT:AOFF

Switches off all delta markers.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, WCDMA

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed[:STATe]

This command switches the relative measurement to a fixed reference value on or off. Marker 1

will be activated previously and a peak search will be performed, if necessary. If marker 1 is

activated, its position becomes the reference point for the measurement. The reference point

can then be modified with the

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:X commands and

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:Y independently of

the position of marker 1 and of a trace. It applies to all delta markers as long as the function is

active.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:DELT:FUNC:FIX ON

Switches on the measurement with fixed reference value for all delta markers.

CALC:DELT:FUNC:FIX:RPO:X 128 MHZ

Sets the frequency reference to 128 MHz.

CALC:DELT:FUNC:FIX:RPO:Y 30 DBM

Sets the reference level to +30 dBm.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

CALCulate Subsystem R&S FSL

1300.2519.12 6.14 E-11

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:MAXimum[:PEAK]

This command sets the reference point level for all delta markers for a measurement with fixed

reference point (CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed[:STATe])to

the peak of the selected trace.

For phase–noise measurements

(CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PNOise[:STATe]), the command

defines a new reference point level for delta marker 2.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Parameter

<numeric_value>

Example

CALC:DELT:FUNC:FIX:RPO:MAX

Sets the reference point level for delta markers to the peak of the selected trace.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:X

This command defines a new frequency reference (span > 0) or time (span = 0) for all delta

markers for a measurement with fixed reference value

(CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed[:STATe]).

For phase–noise measurements

(CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PNOise[:STATe]), the command

defines a new frequency reference or time for delta marker 2.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

<numeric_value>

Example

CALC:DELT:FUNC:FIX:RPO:X 128MHz

Sets the frequency reference to 128 MHz.

Characteristics

RST value: – (CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed[:STATe] is

set to OFF)

SCPI: device–specific

Mode

R&S FSL CALCulate Subsystem

1300.2519.12 6.15 E-11

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:Y

This command defines a new reference point level for all delta markers for a measurement with

fixed reference point

(CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed[:STATe]).

For phase–noise measurements

(CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PNOise[:STATe]), the command

defines a new reference point level for delta marker 2.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

<numeric_value>

Example

CALC:DELT:FUNC:FIX:RPO:Y –10dBm

Sets the reference point level for delta markers to –10 dBm.

Characteristics

RST value: – (CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed[:STATe] is

set to OFF)

SCPI: device–specific

Mode

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:Y:OFFSet

This command defines an additional level offset for the measurement with fixed reference value

(CALCulate:DELTamarker:FUNCtion:FIXed:STATe ON). For this measurement, the

offset is included in the display of all delta markers.

For phase–noise measurements

(CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PNOise[:STATe]), the command

defines an additional level offset which is included in the display of delta marker 2.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

<numeric_value>

Example

CALC:DELT:FUNC:FIX:RPO:Y:OFFS 10dB

Sets the level offset for the measurement with fixed reference value or the phase–noise

measurement to 10 dB.

Characteristics

RST value: 0 dB

SCPI: device–specific

Mode

CALCulate Subsystem R&S FSL

1300.2519.12 6.16 E-11

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PNOise[:STATe]

This command switches on or off the phase–noise measurement with all active delta markers.

The correction values for the bandwidth and the log amplifier are taken into account in the

measurement.

Marker 1 will be activated, if necessary, and a peak search will be performed. If marker 1 is

activated, its position becomes the reference point for the measurement.

The reference point can then be modified with the

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:X and

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:Y commands

independently of the position of marker 1 and of a trace (the same commands used for the

measurement with fixed reference point).

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:DELT:FUNC:PNO ON

Switches on the phase–noise measurement with all delta markers.

CALC:DELT:FUNC:FIX:RPO:X 128 MHZ

Sets the frequency reference to 128 MHz.

CALC:DELT:FUNC:FIX:RPO:Y 30 DBM

Sets the reference level to +30 dBm

Characteristics

RST value: OFF

SCPI: device–specific

Mode

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PNOise:RESult?

This command queries the result of the phase–noise measurement. The measurement will be

switched on, if necessary.

The numeric suffixes <1|2> are irrelevant for this command.

This command is only a query and therefore has no *RST value.

Example

CALC:DELT:FUNC:PNO:RES?

Outputs the result of phase–noise measurement of the selected delta marker.

Characteristics

RST value: –

SCPI: device–specific

Mode

R&S FSL CALCulate Subsystem

1300.2519.12 6.17 E-11

CALCulate<1|2>:DELTamarker<1...4>:MAXimum[:PEAK]

This command positions the delta marker to the current maximum value on the measured curve.

If necessary, the corresponding delta marker will be activated first.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

CALC:DELT3:MAX

Sets delta marker 3 to the maximum value of the associated trace.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT

This command positions the delta marker to the next smaller maximum value to the left of the

current value (i.e. descending X values). The corresponding delta marker will be activated first,

if necessary.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

CALC:DELT:MAX:LEFT

Sets delta marker 1 to the next smaller maximum value to the left of the current value.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:NEXT

This command positions the delta marker to the next smaller maximum value on the measured

curve. The corresponding delta marker will be activated first, if necessary.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

CALC:DELT2:MAX:NEXT

Sets delta marker 2 to the next smaller maximum value.

CALCulate Subsystem R&S FSL

1300.2519.12 6.18 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt

This command positions the delta marker to the next smaller maximum value to the right of the

current value (i.e. ascending X values). The corresponding delta marker is activated first, if

necessary.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

CALC:DELT:MAX:RIGH

Sets delta marker 1 to the next smaller maximum value to the right of the current value.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:DELTamarker<1...4>:MINimum[:PEAK]

This command positions the delta marker to the current minimum value on the measured curve.

The corresponding delta marker will be activated first, if necessary.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

CALC:DELT3:MIN

Sets delta marker 3 to the minimum value of the associated trace.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

R&S FSL CALCulate Subsystem

1300.2519.12 6.19 E-11

CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT

This command positions the delta marker to the next higher minimum value to the left of the

current value (i.e. descending X values). The corresponding delta marker will be activated first,

if necessary.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

CALC:DELT:MIN:LEFT

Sets delta marker 1 to the next higher minimum to the left of the current value.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:DELTamarker<1...4>:MINimum:NEXT

This command positions the delta marker to the next higher minimum value of the measured

curve. The corresponding delta marker will be activated first, if necessary.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

CALC:DELT2:MIN:NEXT

Sets delta marker 2 to the next higher minimum value.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt

This command positions the delta marker to the next higher minimum value to the right of the

current value (i.e. ascending X values). The corresponding delta marker will be activated first, if

necessary.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

CALC:DELT:MIN:RIGH

Sets delta marker 1 to the next higher minimum value to the right of the current value.

CALCulate Subsystem R&S FSL

1300.2519.12 6.20 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:DELTamarker<1...4>:MODE

This command switches between relative and absolute frequency input of the delta marker (or

time with span = 0).

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ABSolute | RELative

Example

CALC:DELT:MODE ABS

Switches the frequency/time indication for all delta markers to absolute values.

CALC:DELT:MODE REL

Switches the frequency/time indication for all delta markers to relative to marker 1.

Characteristics

RST value: REL

SCPI: device–specific

Mode

all

CALCulate<1|2>:DELTamarker<1...4>:TRACe

This command assigns the selected delta marker to the indicated trace. The selected trace must

be active, i.e. its state must be different from "BLANK".

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

1to 6

Example

CALC:DELT3:TRAC 2

Assigns delta marker 3 to trace 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV

R&S FSL CALCulate Subsystem

1300.2519.12 6.21 E-11

CALCulate<1|2>:DELTamarker<1...4>:X

This command positions the selected delta marker to the indicated frequency (span > 0), time

(span = 0) or level (APD measurement = ON or CCDF measurement = ON). The input is in

absolute values or relative to marker 1 depending on the command

CALCulate<1|2>:DELTamarker<1...4>:MODE.If reference fixed measurement

(CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed[:STATe] is ON) is active,

relative values refer to the reference position are entered. The query always returns absolute

values.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0to MAX (frequency | sweep time)

Example

CALC:DELT:MOD REL

Switches the input for all delta markers to relative to marker 1.

CALC:DELT2:X 10.7MHz

Positions delta marker 2 10.7 MHz to the right of marker 1.

CALC:DELT:X?

Outputs the absolute frequency/time of delta marker 1.

CALC:DELT:X:REL?

Outputs the relative frequency/time/level of delta marker 1.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, WCDMA

CALCulate<1|2>:DELTamarker<1...4>:X:RELative?

This command queries the frequency (span > 0) or time (span = 0) of the selected delta marker

relative to marker 1 or to the reference position ( for

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed[:STATe] is ON). The

command activates the corresponding delta marker, if necessary.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT3:X:REL?

Outputs the frequency of delta marker 3 relative to marker 1 or relative to the reference position.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, WCDMA

CALCulate Subsystem R&S FSL

1300.2519.12 6.22 E-11

CALCulate<1|2>:DELTamarker<1...4>:Y?

This command queries the measured value of the selected delta marker. The corresponding

delta marker will be activated, if necessary. The output is always a relative value referred to

marker 1 or to the reference position (reference fixed active).

To obtain a correct query result, a complete sweep with synchronization to the sweep end must

be performed between the activation of the delta marker and the query of the y value. This is

only possible in single sweep mode.

Depending on the unit defined with CALCulate<1|2>:UNIT:POWer or on the activated

measuring functions, the query result is output in the units below:

Parameter or measuring functions Output unit

DBM | DBPW | DBUV | DBMV | DBUA dB (lin/log)

WATT | VOLT | AMPere dB (lin), % (log)

statistics function (APD or CCDF) on dimensionless output

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:DELT2 ON

Switches on delta marker 2.

INIT;*WAI

Starts a sweep and waits for its end.

CALC:DELT2:Y?

Outputs measurement value of delta marker 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, ADEMOD, BT, CATV, CDMA, EVDO, WCDMA

R&S FSL CALCulate Subsystem

1300.2519.12 6.23 E-11

CALCulate:DLINe Subsystem

The CALCulate:DLINe subsystem defines the position of the display lines.

Commands of the CALCulate:DLINe Subsystem

–CALCulate<1|2>:DLINe<1|2>

–CALCulate<1|2>:DLINe<1|2>:STATe

CALCulate<1|2>:DLINe<1|2>

This command defines the position of display line 1 or 2. These lines enable the user to mark

any levels in the diagram. The unit depends on the setting made with

CALCulate<1|2>:UNIT:POWer.

The numeric suffixes <1|2> at CALCulate are irrelevant for this command.

Parameter

MINimum to MAXimum (depending on current unit)

Example

CALC:DLIN –20dBm

Characteristics

*RST value: – (STATe to OFF)

SCPI: device–specific

Mode

CALCulate<1|2>:DLINe<1|2>:STATe

This command switches display line 1 or 2 (level lines) on or off.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:DLIN2:STAT OFF

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

CALCulate Subsystem R&S FSL

1300.2519.12 6.24 E-11

CALCulate:ESPectrum Subsystem

The CALCulate:ESPectrum subsystem contains the remote commands for Spectrum Emission Mask

(SEM) measurements. Both groups of commands (PSEarch and PEAKsearch) perform the same

functions.

Commands of the CALCulate:ESPectrum Subsystem

–CALCulate<1|2>:ESPectrum:PSEarch|:PEAKsearch:AUTO

–CALCulate<1|2>:ESPectrum:PSEarch|:PEAKsearch:MARGin

–CALCulate<1|2>:ESPectrum:PSEarch|:PEAKsearch:PSHow

CALCulate<1|2>:ESPectrum:PSEarch|:PEAKsearch:AUTO

This command activates or deactivates the list evaluation.

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

ON | OFF

Example

CALC:ESP:PSE:AUTO OFF

Deactivates the list evaluation.

Characteristics

RST value: ON

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate<1|2>:ESPectrum:PSEarch|:PEAKsearch:MARGin

This command sets the margin used for the limit check/peak search.

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

–200 to 200 dB

Example

CALC:ESP:PSE:MARG 100

Sets the margin to 100 dB.

Characteristics

RST value: 200 dB

SCPI: device–specific

Mode

A, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.25 E-11

CALCulate<1|2>:ESPectrum:PSEarch|:PEAKsearch:PSHow

This command marks all peaks with blue squares in the diagram.

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

ON | OFF

Example

CALC:ESP:PSE:PSH ON

Marks all peaks with blue squares.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate Subsystem R&S FSL

1300.2519.12 6.26 E-11

CALCulate:FLINe Subsystem

The CALCulate:FLINe subsystem defines the position of the frequency lines.

Commands of the CALCulate:FLINe Subsystem

–CALCulate<1|2>:FLINe<1|2>

–CALCulate<1|2>:FLINe<1|2>:STATe

CALCulate<1|2>:FLINe<1|2>

This command defines the position of the frequency lines that mark the frequencies.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0to fmax

Example

CALC:FLIN2 120MHz

Characteristics

*RST value: – (STATe to OFF)

SCPI: device–specific

Mode

A–F

CALCulate<1|2>:FLINe<1|2>:STATe

This command switches the frequency line on or off.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:FLIN2:STAT ON

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–F

R&S FSL CALCulate Subsystem

1300.2519.12 6.27 E-11

CALCulate:LIMit Subsystem

The CALCulate:LIMit subsystem contains commands for the limit lines and the corresponding limit

checks. Limit lines can be defined as upper or lower limit lines. The individual Y values of the limit lines

correspond to the values of the x–axis (CONTrol). The number of X and Y values must be identical. For

details on limit lines refer to chapter "Instrument Functions", section "Using Limit Lines and Display

Lines – LINES Key".

The following subsystems are included:

•"CALCulate:LIMit:ACPower Subsystem" on page 6.33

•"CALCulate:LIMit:CONTrol Subsystem" on page 6.41

•"CALCulate:LIMit:ESPectrum Subsystem" on page 6.44

•"CALCulate:LIMit:LOWer Subsystem" on page 6.47

•"CALCulate:LIMit:UPPer Subsystem" on page 6.51

Commands of the CALCulate:LIMit Subsystem

–CALCulate<1|2>:LIMit<1...8>:ACTive?

–CALCulate<1|2>:LIMit<1...8>:CLEar[:IMMediate]

–CALCulate<1|2>:LIMit<1...8>:COMMent

–CALCulate<1|2>:LIMit<1...8>:COPY

–CALCulate<1|2>:LIMit<1...8>:DELete

–CALCulate<1|2>:LIMit<1...8>:FAIL?

–CALCulate<1|2>:LIMit<1...8>:NAME

–CALCulate<1|2>:LIMit<1...8>:STATe

–CALCulate<1|2>:LIMit<1...8>:TRACe

–CALCulate<1|2>:LIMit<1...8>:UNIT

Further information

–Example (analyzer mode)

–Definition of the limit line

–Switching on and evaluating the line

Example (analyzer mode)

Definition and use of a new limit line 5 for trace 2 with the following features:

•upper limit line

•absolute x–axis with span > 0.

•5ref. values: 126 MHz/–40 dB, 127 MHz/–40 dB, 128 MHz/–20 dB, 129 MHz/–40 dB, 130 MHz/–40

•relative y–axis with unit dB

•absolute threshold value at –35 dBm

•no safety margin

CALCulate Subsystem R&S FSL

1300.2519.12 6.28 E-11

Definition of the limit line

1. Defining the name:

CALC:LIM5:NAME 'TEST1'

2. Entering the comment:

CALC:LIM5:COMM 'Upper limit line'

3. Associated trace:

CALC:LIM5:TRAC 2

4. Defining the x–axis range:

CALC:LIM5:CONT:DOM FREQ

5. Defining the x–axis scaling:

CALC:LIM5:CONT:MODE ABS

6. Defining the y–axis unit:

CALC:LIM5:UNIT DB

7. Defining the y–axis scaling:

CALC:LIM5:UPP:MODE REL

8. Defining the x–axis values:

CALC:LIM5:CONT 126MHZ, 127MHZ, 128MHZ, 129 MHZ, 130MHZ

9. Defining the y values:

CALC:LIM5:UPP –40, –40, –30, –40, –40

10. Defining the y threshold value:

CALC:LIM5:UPP:THR –35DBM

The definition of the safety margin and shifting in X and/or Y direction can take place as from here (see

commands below).

Switching on and evaluating the line

1. Switching on the line:

CALC:LIM5:UPP:STAT ON

2. Switching on the limit check:

CALC:LIM5:STAT ON

3. Starting a new measurement with synchronization:

INIT;*WAI

4. Querying the limit check result:

CALC:LIM5:FAIL?

R&S FSL CALCulate Subsystem

1300.2519.12 6.29 E-11

CALCulate<1|2>:LIMit<1...8>:ACTive?

This command queries the names of all active limit lines.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

This command is only a query and therefore has no *RST value.

This command is available from firmware version 1.60.

Example

CALC:LIM:ACT?

Queries the names of all active limit lines.

Return values

'3GBAA,3GBBA,3GBCR'

Returns the names of the active limit lines in alphabetical order, separated by commas.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:CLEar[:IMMediate]

This command deletes the result of the current limit check for all limit lines.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

This command is an event and therefore has no *RST value.

This command is available from firmware version 1.10.

Example

CALC:LIM:CLE

Deletes the result of the limit check.

Characteristics

*RST value: –

SCPI: conform

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate<1|2>:LIMit<1...8>:COMMent

This command defines a comment for the limit line selected (max. 40 characters).

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

<string>, max. 40 alphanumeric characters

Example

CALC:LIM5:COMM 'Upper limit for spectrum'

Defines the comment for limit line 5.

CALCulate Subsystem R&S FSL

1300.2519.12 6.30 E-11

Characteristics

*RST value: blank comment

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate<1|2>:LIMit<1...8>:COPY

This command copies one limit line onto another one

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.10.

Parameter

1to 8 number of the new limit line

<name> name of the new limit line given as a string

Example

CALC:LIM1:COPY 2

Copies limit line 1 to line 2.

CALC:LIM1:COPY 'FM2'

Copies limit line 1 to a new line named FM2.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate<1|2>:LIMit<1...8>:DELete

This command deletes the selected limit line.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.10.

Example

CALC:LIM1:DEL

Deletes limit line 1.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO, NF

R&S FSL CALCulate Subsystem

1300.2519.12 6.31 E-11

CALCulate<1|2>:LIMit<1...8>:FAIL?

This command queries the result of the limit check of the indicated limit line. It should be noted

that a complete sweep must have been performed to obtain a correct result. A synchronization

with *OPC,*OPC? or *WAI should therefore be provided. The result of the limit check is given

with 0 for PASS, 1 for FAIL, and 2 for MARGIN.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Return values

0for pass, 1 for fail

Example

INIT;*WAI

Starts a new sweep and waits for its end.

CALC:LIM3:FAIL?

Queries the result of the check for limit line 3.

Characteristics

*RST value: –

SCPI: conform

Mode

A, ADEMOD, NF, CDMA, EVDO, WLAN

CALCulate<1|2>:LIMit<1...8>:NAME

This command assigns a name to a limit line numbered 1 to 8. If it does not exist already, a limit

line with this name is created.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

Example

CALC:LIM1:NAME 'FM1'

Assigns the name FM1 to limit line 1.

Characteristics

*RST value: REM1 to REM8 for lines 1 to 8

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:STATe

This command switches on or off the limit check for the selected limit line.

The result of the limit check can be queried with CALCulate<1|2>:LIMit<1...8>:FAIL?.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

ON | OFF

CALCulate Subsystem R&S FSL

1300.2519.12 6.32 E-11

Example

CALC:LIM:STAT ON

Switches on the limit check for limit line 1.

Characteristics

*RST value: OFF

SCPI: conform

Mode

A, BT, ADEMOD, CDMA, EVDO, NF

CALCulate<1|2>:LIMit<1...8>:TRACe

This command assigns a limit line to a trace.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

1to 6

Example

CALC:LIM2:TRAC 3

Assigns limit line 2 to trace 3.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:UNIT

This command defines the unit of the selected limit line.

Upon selection of the unit DB the limit line is automatically switched to the relative mode. For

units different from DB the limit line is automatically switched to absolute mode.

The units DEG, RAD, S, HZ, PCT are not available in spectrum analyzer mode.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

DBM | DBPW | WATT | DBUV | DBMV | VOLT |DBUA | AMPere | DB | DEG | RAD | HZ | PCT

Example

CALC:LIM4:UNIT DBUV

Sets the unit of limit line 4 to dBµV.

Characteristics

*RST value: DBM

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.33 E-11

CALCulate:LIMit:ACPower Subsystem

The CALCulate:LIMit:ACPower subsystem defines the limit check for adjacent channel power measurement.

Commands of the CALCulate:LIMit:ACPower Subsystem

–CALCulate<1|2>:LIMit<1...8>:ACPower[:STATe]

–CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel[:RELative]

–CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel[:RELative]:STATe

–CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:ABSolute

–CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:ABSolute:STATe

–CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:RESult?

–CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>[:RELative]

–CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>[:RELative]:STATe

–CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>:ABSolute

–CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>:ABSolute:STATe

–CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>:RESult?

CALCulate<1|2>:LIMit<1...8>:ACPower[:STATe]

This command switches on and off the limit check for adjacent–channel power measurements.

The CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel[:RELative]:STATe or

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>[:RELative]:STATe

commands must be used in addition to specify whether the limit check is to be performed for the

upper/lower adjacent channel or for the alternate adjacent channels.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:LIM:ACP ON

Switches on the ACP limit check.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel[:RELative]

This command defines the relative limit of the upper/lower adjacent channel for adjacent–

channel power measurements. The reference value for the relative limit value is the measured

channel power.

It should be noted that the relative limit value has no effect on the limit check as soon as it is

below the absolute limit value defined with the

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:ABSolute command. This

mechanism allows automatic checking of the absolute basic values of adjacent–channel power

as defined in mobile radio standards.

CALCulate Subsystem R&S FSL

1300.2519.12 6.34 E-11

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

Parameter

first value: 0 to 100dB; limit for the upper (lower) adjacent channel

second value: 0 to 100dB; is ignored but must be indicated for reasons of compatibility with the

FSP family

Example

CALC:LIM:ACP:ACH 30DB, 30DB

Sets the relative limit value for the power in the lower and upper adjacent channel to 30 dB

below the channel power.

Characteristics

*RST value: 0 dB

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel[:RELative]:STATe

This command activates the limit check for the relative limit value of the adjacent channel when

adjacent–channel power measurement is performed. Before the command, the limit check must

be activated using CALCulate<1|2>:LIMit<1...8>:ACPower[:STATe].

The result can be queried with

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:RESult?.It should be noted that a

complete measurement must be performed between switching on the limit check and the result

query, since otherwise no correct results are available.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:LIM:ACP:ACH 30DB, 30DB

Sets the relative limit value for the power in the lower and upper adjacent channel to 30 dB

below the channel power.

CALC:LIM:ACP:ACH:ABS –35DBM, –35DBM

Sets the absolute limit value for the power in the lower and upper adjacent channel to –35 dBm.

CALC:LIM:ACP ON

Switches on globally the limit check for the channel/adjacent channel measurement.

CALC:LIM:ACP:ACH:STAT ON

Switches on the check of the relative limit values for adjacent channels.

CALC:LIM:ACP:ACH:ABS:STAT ON

Switches on the check of absolute limit values for the adjacent channels.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:LIM:ACP:ACH:RES?

Queries the limit check result in the adjacent channels.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.35 E-11

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:ABSolute

This command defines the absolute limit value for the lower/upper adjacent channel during

adjacent–channel power measurement (Adjacent Channel Power).

It should be noted that the absolute limit value has no effect on the limit check as soon as it is

below the relative limit value defined with

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel[:RELative].This mechanism

allows automatic checking of the absolute basic values of adjacent–channel power as defined in

mobile radio standards.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

Parameter

first value: –200DBM to 200DBM; limit for the lower and the upper adjacent channel

second value: –200 to 200DBM; is ignored but must be indicated for reasons of compatibility

with the FSP family

Example

CALC:LIM:ACP:ACH:ABS –35DBM, –35DBM

Sets the absolute limit value for the power in the lower and upper adjacent channel to –35 dBm.

Characteristics

*RST value: –200DBM

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:ABSolute:STATe

This command activates the limit check for the adjacent channel when adjacent–channel power

measurement (Adjacent Channel Power) is performed. Before the command, the limit check for

the channel/adjacent–channel measurement must be globally switched on using

CALCulate<1|2>:LIMit<1...8>:ACPower[:STATe].

The result can be queried with

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:RESult?.It should be noted that a

complete measurement must be performed between switching on the limit check and the result

query, since otherwise no correct results are available.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:LIM:ACP:ACH 30DB, 30DB

Sets the relative limit value for the power in the lower and upper adjacent channel to 30 dB

below the channel power.

CALC:LIM:ACP:ACH:ABS –35DBM, –35DBM

Sets the absolute limit value for the power in the lower and upper adjacent channel to –35 dBm.

CALC:LIM:ACP ON

Switches on globally the limit check for the channel/adjacent–channel measurement.

CALC:LIM:ACP:ACH:REL:STAT ON

Switches on the check of the relative limit values for adjacent channels.

CALC:LIM:ACP:ACH:ABS:STAT ON

Switches on the check of absolute limit values for the adjacent channels.

CALCulate Subsystem R&S FSL

1300.2519.12 6.36 E-11

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:LIM:ACP:ACH:RES?

Queries the limit check result in the adjacent channels.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:RESult?

This command queries the result of the limit check for the upper /lower adjacent channel when

adjacent channel power measurement is performed.

If the power measurement of the adjacent channel is switched off, the command produces a

query error.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

This command is a query and therefore has no *RST value.

Parameter

The result is returned in the form <result>, <result> where <result> = PASSED | FAILED, and

where the first returned value denotes the lower, the second denotes the upper adjacent

channel.

Example

CALC:LIM:ACP:ACH 30DB, 30DB

Sets the relative limit value for the power in the lower and upper adjacent channel to 30 dB

below the channel power.

CALC:LIM:ACP:ACH:ABS –35DBM, –35DBM

Sets the absolute limit value for the power in the lower and upper adjacent channel to –35 dB.

CALC:LIM:ACP ON

Switches on globally the limit check for the channel/adjacent channel measurement.

CALC:LIM:ACP:ACH:STAT ON

Switches on the limit check for the adjacent channels.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:LIM:ACP:ACH:RES?

Queries the limit check result in the adjacent channels.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, CDMA, EVDO, WLAN

R&S FSL CALCulate Subsystem

1300.2519.12 6.37 E-11

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>[:RELative]

This command defines the limit for the alternate adjacent channels for adjacent channel power

measurements. The reference value for the relative limit value is the measured channel power.

The numeric suffix after ALTernate denotes the alternate channel. The numeric suffixes <1|2>

with CALCulate and <1...8> with LIMit are irrelevant for this command.

It should be noted that the relative limit value has no effect on the limit check as soon as it is

below the absolute limit defined with

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>:ABSolute.This

mechanism allows automatic checking of the absolute basic values of adjacent–channel power

as defined in mobile radio standards.

Parameter

first value: 0 to 100dB; limit for the lower and the upper alternate adjacent channel

second value: 0 to 100dB; is ignored but must be indicated for reasons of compatibility with the

FSP family

Example

CALC:LIM:ACP:ALT2 30DB, 30DB

Sets the relative limit value for the power in the lower and upper second alternate adjacent

channel to 30 dB below the channel power.

Characteristics

*RST value: 0 DB

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>[:RELative]:STATe

This command activates the limit check for the alternate adjacent channels for adjacent channel

power measurements. Before the command, the limit check must be activated using

CALCulate<1|2>:LIMit<1...8>:ACPower[:STATe].

The numeric suffix after ALTernate denotes the alternate channel. The numeric suffixes <1|2>

with CALCulate and <1...8> with LIMit are irrelevant for this command.

The result can be queried with

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>:RESult?.It should be

noted that a complete measurement must be performed between switching on the limit check

and the result query, since otherwise no correct results are obtained.

Parameter

ON | OFF

Example

CALC:LIM:ACP:ALT2 30DB, 30DB

Sets the relative limit value for the power in the lower and upper second alternate adjacent

channel to 30 dB below the channel power.

CALC:LIM:ACP:ALT2:ABS –35DBM, –35DBM

Sets the absolute limit value for the power in the lower and upper second alternate adjacent

channel to –35 dBm.

CALC:LIM:ACP ON

Switches on globally the limit check for the channel/adjacent channel measurement.

CALCulate Subsystem R&S FSL

1300.2519.12 6.38 E-11

CALC:LIM:ACP:ALT2:STAT ON

Switches on the check of the relative limit values for the lower and upper second alternate

adjacent channel.

CALC:LIM:ACP:ALT2:ABS:STAT ON

Switches on the check of absolute limit values for the lower and upper second alternate

adjacent channel.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:LIM:ACP:ALT2:RES?

Queries the limit check result in the second alternate adjacent channels.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>:ABSolute

This command defines the absolute limit value for the lower/upper alternate adjacent–channel

power measurement (Adjacent Channel Power).

The numeric suffix after ALTernate denotes the alternate channel. The numeric suffixes <1|2>

with CALCulate and <1...8> with LIMit are irrelevant for this command.

It should be noted that the absolute limit value for the limit check has no effect as soon as it is

below the relative limit value defined with

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>[:RELative].This

mechanism allows automatic checking of the absolute basic values defined in mobile radio

standards for the power in adjacent channels.

Parameter

first value: –200DBM to 200DBM; limit for the lower and the upper alternate adjacent channel

second value: –200DBM to 200DBM; is ignored but must be indicated for reasons of

compatibility with the FSP family

Example

CALC:LIM:ACP:ALT2:ABS –35DBM, –35DBM

Sets the absolute limit value for the power in the lower and upper second alternate adjacent

channel to –35 dBm.

Characteristics

*RST value: –200DBM

SCPI: device–specific

Mode

A, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.39 E-11

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>:ABSolute:STATe

This command activates the limit check for the alternate adjacent channels for adjacent–

channel power measurement (Adjacent Channel Power).

Before the command, the limit check must be globally switched on for the channel/adjacent–

channel power with the CALCulate<1|2>:LIMit<1...8>:ACPower[:STATe] command.

The numeric suffix after ALTernate denotes the alternate channel. The numeric suffixes <1|2>

with CALCulate and <1...8> with LIMit are irrelevant for this command.

The result can be queried with

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>:RESult?.It should be

noted that a complete measurement must be performed between switching on the limit check

and the result query, since otherwise no correct results are available.

Parameter

ON | OFF

Example

CALC:LIM:ACP:ALT2 30DB, 30DB

Sets the relative limit value for the power in the lower and upper second alternate adjacent

channel to 30 dB below the channel power.

CALC:LIM:ACP:ALT2:ABS –35DBM, –35DBM

Sets the absolute limit value for the power in the lower and upper second alternate adjacent

channel to –35 dBm.

CALC:LIM:ACP ON

Switches on globally the limit check for the channel/adjacent channel measurement.

CALC:LIM:ACP:ALT2:STAT ON

Switches on the check of the relative limit values for the lower and upper second alternative

adjacent channels.

CALC:LIM:ACP:ALT2:ABS:STAT ON

Switches on the check of absolute limit values for the lower and upper second alternative

adjacent channels.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:LIM:ACP:ALT2:RES?

Queries the limit check result in the second alternate adjacent channels.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate Subsystem R&S FSL

1300.2519.12 6.40 E-11

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>:RESult?

This command queries the result of the limit check for the alternate adjacent channels for

adjacent channel power measurements.

The numeric suffix after ALTernate denotes the alternate channel. The numeric suffixes <1|2>

with CALCulate and <1...8> with LIMit are irrelevant for this command.

If the power measurement of the adjacent channel is switched off, the command produces a

query error.

This command is a query and therefore has no *RST value.

Parameter

The result is returned in the form <result>, <result> where <result> = PASSED | FAILED and

where the first (second) returned value denotes the lower (upper) alternate adjacent channel.

Example

CALC:LIM:ACP:ALT2 30DB, 30DB

Sets the relative limit value for the power in the lower and upper second alternate adjacent

channel to 30 dB below the channel power.

CALC:LIM:ACP:ALT2:ABS –35DBM, –35DBM

Sets the absolute limit value for the power in the lower and upper second alternate adjacent

channel to –35 dBm.

CALC:LIM:ACP ON

Switches on globally the limit check for the channel/adjacent channel measurement.

CALC:LIM:ACP:ALT2:STAT ON

Switches on the limit check for the lower and upper second adjacent channel.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:LIM:ACP:ALT2:RES?

Queries the limit check result in the second alternate adjacent channels.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, CDMA, EVDO, WLAN

R&S FSL CALCulate Subsystem

1300.2519.12 6.41 E-11

CALCulate:LIMit:CONTrol Subsystem

The CALCulate:LIMit:CONTrol subsystem defines the x–axis (CONTrol axis).

This subsystem is available from firmware version 1.10.

Commands of the CALCulate:LIMit:CONTrol Subsystem

–CALCulate<1|2>:LIMit<1...8>:CONTrol[:DATA]

–CALCulate<1|2>:LIMit<1...8>:CONTrol:DOMain

–CALCulate<1|2>:LIMit<1...8>:CONTrol:MODE

–CALCulate<1|2>:LIMit<1...8>:CONTrol:OFFSet

–CALCulate<1|2>:LIMit<1...8>:CONTrol:SHIFt

–CALCulate<1|2>:LIMit<1...8>:CONTrol:SPACing

CALCulate<1|2>:LIMit<1...8>:CONTrol[:DATA]

This command defines the x–axis values (frequencies or times) of the upper or lower limit lines.

The number of values for the CONTrol axis and for the corresponding UPPer and/or LOWer

limit lines has to be identical. Otherwise default values are entered for missing values or not

required values are deleted.

In analyzer mode, the unit of values depends on the span setting of the x–axis. For details refer

to CALCulate<1|2>:LIMit<1...8>:CONTrol:DOMain.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

<numeric_value>,<numeric_value>

Example

CALC:LIM2:CONT 1MHz,30MHz,100MHz,300MHz,1GHz

Defines 5 reference values for the x–axis of limit line 2.

CALC:LIM2:CONT?

Outputs the reference values for the x–axis of limit line 2 separated by a comma.

Characteristics

*RST value: – (CALCulate<1|2>:LIMit<1...8>:STATe is set to OFF)

SCPI: conform

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate<1|2>:LIMit<1...8>:CONTrol:DOMain

This command defines the span setting for the x–axis values.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

FREQuency | TIME

CALCulate Subsystem R&S FSL

1300.2519.12 6.42 E-11

Example

CALC:LIM2:CONT:DOM TIME

Defines zero span for the x–axis of limit line 2.

Characteristics

*RST value: FREQuency

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:CONTrol:MODE

This command selects the relative or absolute scaling for the x–axis of the selected limit line.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

RELative | ABSolute

Example

CALC:LIM2:CONT:MODE REL

Defines the x–axis of limit line 2 as relatively scaled.

Characteristics

*RST value: ABSolute

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:CONTrol:OFFSet

This command defines an offset for the x–axis value of the selected relative limit line for span >

0or zero span.

In analyzer mode, the unit of values depends on the span setting of the x–axis. For details refer

to CALCulate<1|2>:LIMit<1...8>:CONTrol:DOMain.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

<numeric_value>

Example

CALC:LIM2:CONT:OFFS 100us

Sets the X offset for limit line 2 (defined in zero span) to 100Us.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.43 E-11

CALCulate<1|2>:LIMit<1...8>:CONTrol:SHIFt

This command moves a limit line by the indicated value in x direction. In contrast to

CALCulate<1|2>:LIMit<1...8>:CONTrol:OFFSet,the line is shifted by modifying the

individual x values and not by means of an additive offset.

In analyzer mode, the unit of values depends on the span setting of the x–axis. For details refer

to CALCulate<1|2>:LIMit<1...8>:CONTrol:DOMain.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.10.

Parameter

<numeric_value>

Example

CALC:LIM2:CONT:SHIF 50KHZ

Shifts all reference values of limit line 2 by 50 kHz.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate<1|2>:LIMit<1...8>:CONTrol:SPACing

This command selects linear or logarithmic interpolation for the calculation of limit lines from

frequency points.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

LINear | LOGarithmic

Example

CALC:LIM:CONT:SPAC LIN

Characteristics

*RST value: LIN

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate Subsystem R&S FSL

1300.2519.12 6.44 E-11

CALCulate:LIMit:ESPectrum Subsystem

The CALCulate:LIMit:ESPectrum subsystem defines the power classes used in Spectrum Emission

Mask measurements. This subsystem is available from firmware version 1.90.

Commands of the CALCulate:LIMit:ESPectrum subsystem

–CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>[:EXCLusive]

–CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:MINimum

–CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:MAXimum

–CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:COUNt

–CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:LIMit[:STATe]

CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>[:EXCLusive]

This command sets the power classes used in the measurement. It is only possible to use

power classes for which limits are defined. Also, either only one power class at a time or all

power classes together can be selected.

The numeric suffixes <1|2> and <1…8> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:LIM:ESP:PCL1 ON

Activates the first defined power class.

Characteristics

*RST value: –

SCPI: conform

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:MINimum

This command sets the lower limit level for one power class. The unit is dBm. The limit always

start at – 200 dBm, i.e. the first lower limit can not be set. If more than one power class is in use,

the lower limit must equal the upper limit of the previous power class.

The numeric suffix at PCLass<1…4> denotes the power class to be defined.

The numeric suffixes <1|2> and <1…8> are irrelevant for this command.

Parameter

<numeric_value>

Example

CALC:LIM:ESP:PCL2:MIN -40 dBm

Sets the minimum power value of the second power class to -40 dBm.

Characteristics:

*RST value: –

SCPI: conform

Mode

A, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.45 E-11

CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:MAXimum

This command sets the upper limit level for one power class. The unit is dBm. The limit always

ends at + 200 dBm, i.e. the upper limit of the last power class can not be set. If more than one

power class is in use, the upper limit must equal the lower limit of the next power class.

The numeric suffix at PCLass<1…4> denotes the power class to be defined.

The numeric suffixes <1|2> and <1…8> are irrelevant for this command.

Parameter

<numeric_value>

Example

CALC:LIM:ESP:PCL1:MAX -40 dBm

Sets the maximum power value of the first power class to -40 dBm.

Characteristics:

*RST value: –

SCPI: conform

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:COUNt

This command sets the number of power classes to be defined.

The numeric suffixes are irrelevant

Parameter

1to 4

Example

CALC:LIM:ESP:PCL:COUN 2

Two power classes can be defined.

Characteristics:

*RST value: –

SCPI: conform

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:LIMit[:STATe]

This command defines which limits are evaluated in the measurement.

The numeric suffix at PCLass<1..4> defines the power class to be evaluated. The numeric

suffixes <1|2> and <1..8> are irrelevant

Parameter

ABSolute Evaluates only limit lines with absolute power values

RELative Evaluates only limit lines with relative power values

OR Evaluates limit lines with relative and absolute power values. A

negative result is returned if both limits fail.

AND Evaluates limit lines with relative and absolute power values. A

negative result is returned if at least one limit failed.

CALCulate Subsystem R&S FSL

1300.2519.12 6.46 E-11

Example

CALC:LIM:ESP:PCL:COUN ABS

Characteristics:

*RST value: –

SCPI: conform

Mode

A, CDMA

CALCulate<1|2>:LIMit<1…8>:ESPectrum:LIMits

This command sets the limits for all power classes you want to use. The limit defined by the

string always starts at -200 dBm and always ends at 200 dBm. Between these up to three limits

can be defined. See also CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:MINimum

and CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:MAXimum

The numeric suffixes <1|2> and <1…8> are irrelevant for this command.

Parameter

Example

-200, -90, 0, 90, 200

Sets the minimum power value of the first power class to -200 dBm and the maximum power

value of the first power class to -90 dBm. The second power class begins at -90 dBm and ends

at 0 dBm etc.

Characteristics

*RST value: -

SCPI: conform

Mode

A, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.47 E-11

CALCulate:LIMit:LOWer Subsystem

The CALCulate:LIMit:LOWer subsystem defines the lower limit line. This subsystem is available from

firmware version 1.10.

Commands of the CALCulate:LIMit:LOWer Subsystem

–CALCulate<1|2>:LIMit<1...8>:LOWer[:DATA]

–CALCulate<1|2>:LIMit<1...8>:LOWer:STATe

–CALCulate<1|2>:LIMit<1...8>:LOWer:OFFSet

–CALCulate<1|2>:LIMit<1...8>:LOWer:MARGin

–CALCulate<1|2>:LIMit<1...8>:LOWer:MODE

–CALCulate<1|2>:LIMit<1...8>:LOWer:SHIFt

–CALCulate<1|2>:LIMit<1...8>:LOWer:SPACing

–CALCulate<1|2>:LIMit<1...8>:LOWer:THReshold

CALCulate<1|2>:LIMit<1...8>:LOWer[:DATA]

This command defines the values for the selected lower limit line.

The number of values for the CONTrol axis and for the corresponding LOWer limit line has to be

identical. Otherwise default values are entered for missing values or not necessary values are

deleted.

The unit must be identical with the unit selected by CALCulate<1|2>:LIMit<1...8>:UNIT.

If no unit is indicated, the unit defined with CALCulate<1|2>:LIMit<1...8>:UNIT is

automatically used.

If the measured values are smaller than the LOWer limit line, the limit check signals errors.

The units DEG, RAD, S, HZ, PCT are not available in the spectrum analyzer mode.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

<numeric_value>,<numeric_value>

Example

CALC:LIM2:LOW –30,–40,–10,–40,–30

Defines 5 lower limit values for limit line 2 in the preset unit.

CALC:LIM2:LOW?

Outputs the lower limit values of limit line 2 separated by a comma.

Characteristics

*RST value: – (LIMit:STATe is set to OFF)

SCPI: conform

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate Subsystem R&S FSL

1300.2519.12 6.48 E-11

CALCulate<1|2>:LIMit<1...8>:LOWer:STATe

This command switches on or off the indicated limit line. The limit check is activated separately

with CALCulate<1|2>:LIMit<1...8>:STATe.

In spectrum analyzer mode, the result of the limit check can be queried with

CALCulate<1|2>:LIMit<1...8>:FAIL?.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

CALC:LIM4:LOW:STAT ON

Switches on limit line 4 (lower limit).

Characteristics

*RST value: OFF

SCPI: conform

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate<1|2>:LIMit<1...8>:LOWer:OFFSet

This command defines an offset for the y–axis of the selected relative lower limit line. In contrast

to CALCulate<1|2>:LIMit<1...8>:LOWer:SHIFt,the line is not shifted by modifying the

individual Y values but by means of an additive offset.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

<numeric_value>

Example

CALC:LIM2:LOW:OFFS 3dB

Shifts limit line 2 by 3 dB upwards.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.49 E-11

CALCulate<1|2>:LIMit<1...8>:LOWer:MARGin

This command defines a margin to a lower limit line, at which out–of–limit values are signaled (if

the limit check is active), but not handled as a violation of the limit value.

Only the unit dB is available in spectrum analyzer mode.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

<numeric_value>

Example

CALC:LIM:LOW:MARG 10dB

Characteristics

*RST value: 0

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:LOWer:MODE

This command selects the relative or absolute scaling for the y–axis of the selected lower limit

line.

Selecting RELative causes the unit to be switched to DB.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

RELative | ABSolute

Example

CALC:LIM:LOW:MODE REL

Defines the y–axis of limit line 2 as relative scaled.

Characteristics

*RST value: ABSolute

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:LOWer:SHIFt

This command shifts a limit line by the indicated value in Y direction. In contrast to

CALCulate<1|2>:LIMit<1...8>:LOWer:OFFSet,the line is shifted by modifying the

individual Y values but not by means of an additive offset.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.10.

Parameter

<numeric_value>

CALCulate Subsystem R&S FSL

1300.2519.12 6.50 E-11

Example

CALC:LIM3:LOW:SHIF 20DB

Shifts all Y values of limit line 3 by 20 dB.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate<1|2>:LIMit<1...8>:LOWer:SPACing

This command selects linear or logarithmic interpolation for the lower limit line.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

LINear | LOGarithmic

Example

CALC:LIM:LOW:SPAC LIN

Characteristics

*RST value: LIN

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:LOWer:THReshold

This command defines an absolute threshold value for limit lines with relative y–axis scaling.

The absolute threshold value is used in the limit check as soon as it exceeds the relative limit

value.

The unit must correspond to the unit selected with CALCulate<1|2>:LIMit<1...8>:UNIT

(except dB which is not allowed). If no unit is indicated, the unit defined with

CALCulate<1|2>:LIMit<1...8>:UNIT is automatically used (exception: dBm instead of

dB).

The units DEG, RAD, S, HZ, PCT are not available in the spectrum analyzer mode.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

<numeric_value>

Example

CALC:LIM2:LOW:THR –35DBM

Defines an absolute threshold value for limit line 2.

Characteristics

*RST value: –200 dBm

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.51 E-11

CALCulate:LIMit:UPPer Subsystem

The CALCulate:LIMit:UPPer subsystem defines the upper limit line. This subsystem is available from

firmware version 1.10.

Commands of the CALCulate:LIMit:UPPer Subsystem

–CALCulate<1|2>:LIMit<1...8>:UPPer[:DATA]

–CALCulate<1|2>:LIMit<1...8>:UPPer:MARGin

–CALCulate<1|2>:LIMit<1...8>:UPPer:MODE

–CALCulate<1|2>:LIMit<1...8>:UPPer:OFFSet

–CALCulate<1|2>:LIMit<1...8>:UPPer:SHIFt

–CALCulate<1|2>:LIMit<1...8>:UPPer:SPACing

–CALCulate<1|2>:LIMit<1...8>:UPPer:STATe

–CALCulate<1|2>:LIMit<1...8>:UPPer:THReshold

CALCulate<1|2>:LIMit<1...8>:UPPer[:DATA]

This command defines the values for the upper limit lines

The number of values for the CONTrol axis and for the corresponding UPPer and/or LOWer

limit line has to be identical. Otherwise default values are entered for missing values or not

necessary values are deleted.

The unit must be identical with the unit selected by CALCulate<1|2>:LIMit<1...8>:UNIT.

If no unit is indicated, the unit defined with CALCulate<1|2>:LIMit<1...8>:UNIT is

automatically used.

In spectrum analyzer mode, the limit check indicates errors if the measured values exceed the

UPPer limit line. The units DEG, RAD, S, HZ, PCT are not available in spectrum analyzer mode.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

<numeric_value>,<numeric_value>

Example

CALC:LIM2:UPP –10,0,0,–10,–5

Defines 5 upper limit values for limit line 2 in the preset unit.

CALC:LIM2:UPP?

Outputs the upper limit values for limit line 2 separated by a comma.

Characteristics

*RST value: – (CALCulate<1|2>:LIMit<1...8>:STATe is set to OFF)

SCPI: conform

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate Subsystem R&S FSL

1300.2519.12 6.52 E-11

CALCulate<1|2>:LIMit<1...8>:UPPer:MARGin

This command defines a margin to an upper limit line, at which out–of–limit values are signaled

(if the limit check is active), but not handled as a violation of the limit value.

Only the unit dB is available in spectrum analyzer mode.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

<numeric_value>

Example

CALC:LIM2:UPP:MARG 10dB

Defines the margin of limit line 2 to 10 dB below the limit value.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:UPPer:MODE

This command selects the relative or absolute scaling for the y–axis of the selected upper limit

line.

Selecting RELative causes the unit to be switched to DB.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

RELative | ABSolute

Example

CALC:LIM2:UPP:MODE REL

Defines the y–axis of limit line 2 as relative scaled.

Characteristics

*RST value: ABSolute

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:UPPer:OFFSet

This command defines an offset for the y–axis of the selected relative upper limit line. In

contrast to CALCulate<1|2>:LIMit<1...8>:UPPer:SHIFt,the line is not shifted by

modifying the individual Y values but by means of an additive offset.

Only the unit dB is available in the spectrum analyzer mode.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

R&S FSL CALCulate Subsystem

1300.2519.12 6.53 E-11

Parameter

<numeric_value>

Example

CALC:LIM2:UPP:OFFS 3dB

Shifts limit line 2 by 3 dB upwards.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

CALCulate<1|2>:LIMit<1...8>:UPPer:SHIFt

This command moves a limit line by the indicated value in Y direction. In contrast to

CALCulate<1|2>:LIMit<1...8>:UPPer:OFFSet,the line is shifted by modifying the

individual Y values and not by means of an additive offset.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.10.

Parameter

<numeric_value>

Example

CALC:LIM3:UPP:SHIF 20

Shifts all Y values of limit line 3 by 20 limit line units, e.g. dB.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate<1|2>:LIMit<1...8>:UPPer:SPACing

This command selects linear or logarithmic interpolation for the upper limit line.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

LINear | LOGarithmic

Example

CALC:LIM:UPP:SPAC LIN

Characteristics

*RST value: LIN

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate Subsystem R&S FSL

1300.2519.12 6.54 E-11

CALCulate<1|2>:LIMit<1...8>:UPPer:STATe

This command switches on or off the indicated limit line. The limit check is activated separately

with CALCulate<1|2>:LIMit<1...8>:STATe.

In spectrum analyzer mode, the result of the limit check can be queried with

CALCulate<1|2>:LIMit<1...8>:FAIL?.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

CALC:LIM4:UPP:STAT ON

Switches on limit line 4 (upper limit).

Characteristics

*RST value: OFF

SCPI: conform

Mode

A, ADEMOD, CDMA, EVDO, NF

CALCulate<1|2>:LIMit<1...8>:UPPer:THReshold

This command defines an absolute threshold value for limit lines with relative y–axis scaling.

The absolute threshold value is used in the limit check as soon as it exceeds the relative limit

value.

The unit must correspond to the unit selected with CALCulate<1|2>:LIMit<1...8>:UNIT

(except dB which is not possible). If no unit is indicated, the unit defined with

CALCulate<1|2>:LIMit<1...8>:UNIT is automatically used (exception: dBm instead of

dB).

The units DEG, RAD, S, HZ, PCT are not available in the spectrum analyzer mode.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

<numeric_value>

Example

CALC:LIM2:UPP:THR –35DBM

Defines an absolute threshold value for limit line 2.

Characteristics

*RST value: –200 dBm

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.55 E-11

CALCulate:MARKer Subsystem

The CALCulate:MARKer subsystem checks the marker functions of the instrument.

The following subsystem is included:

•"CALCulate:MARKer:FUNCtion Subsystem" on page 6.68

Commands of the CALCulate:MARKer Subsystem

–CALCulate<1|2>:MARKer<1...4>[:STATe]

–CALCulate<1|2>:MARKer<1...4>:AOFF

–CALCulate<1|2>:MARKer<1...4>:COUNt

–CALCulate<1|2>:MARKer<1...4>:COUNt:FREQuency?

–CALCulate<1|2>:MARKer<1...4>:COUNt:RESolution

–CALCulate<1|2>:MARKer<1...4>:LOEXclude

–CALCulate<1|2>:MARKer<1...4>:MAXimum[:PEAK]

–CALCulate<1|2>:MARKer<1...4>:MAXimum:AUTO

–CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT

–CALCulate<1|2>:MARKer<1...4>:MAXimum:NEXT

–CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt

–CALCulate<1|2>:MARKer<1...4>:MINimum[:PEAK]

–CALCulate<1|2>:MARKer<1...4>:MINimum:AUTO

–CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT

–CALCulate<1|2>:MARKer<1...4>:MINimum:NEXT

–CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt

–CALCulate<1|2>:MARKer<1...4>:PEXCursion

–CALCulate<1|2>:MARKer<1...4>:TRACe

–CALCulate<1|2>:MARKer<1...4>:X

–CALCulate<1|2>:MARKer<1...4>:X:SLIMits[:STATe]

–CALCulate<1|2>:MARKer<1...4>:X:SLIMits:LEFT

–CALCulate<1|2>:MARKer<1...4>:X:SLIMits:RIGHT

–CALCulate<1|2>:MARKer<1...4>:X:SSIZe

–CALCulate<1|2>:MARKer<1...4>:Y?

–CALCulate<1|2>:MARKer<1...4>:Y:PERCent

CALCulate Subsystem R&S FSL

1300.2519.12 6.56 E-11

CALCulate<1|2>:MARKer<1...4>[:STATe]

This command switches on or off the currently selected marker. If no indication is made, marker

1is selected automatically. If marker 2, 3 or 4 is selected and used as a delta marker, it is

switched to marker mode.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

Parameter

ON | OFF

Example

CALC:MARK3 ON

Switches on marker 3 or switches to marker mode.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:MARKer<1...4>:AOFF

This command switches off all active markers and all delta markers and active marker/delta

marker measurement functions.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

CALC:MARK:AOFF

Switches off all markers.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, WCDMA

CALCulate<1|2>:MARKer<1...4>:COUNt

This command switches on or off the frequency counter at the marker position.

The count result is queried with CALCulate<1|2>:MARKer<1...4>:COUNt:FREQuency?.

Frequency counting is possible only for one marker at a time. If it is activated for another

marker, it is automatically deactivated for the previous marker.

It should be noted that a complete sweep must be performed after switching on the frequency

counter to ensure that the frequency to be measured is actually reached. The synchronization to

the sweep end required for this is only possible in single sweep mode.

The numeric suffixes <1|2> are irrelevant for this command.

R&S FSL CALCulate Subsystem

1300.2519.12 6.57 E-11

Parameter

ON | OFF

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK ON

Switches on marker 1.

CALC:MARK:COUN ON

Switches on the frequency counter for marker 1.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:COUN:FREQ?

Outputs the measured value.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:COUNt:FREQuency?

This command queries the result of the frequency counter for the indicated marker. Before the

command, the frequency counter should be switched on and a complete measurement

performed to obtain a correct count result. Therefore, a single sweep with synchronization must

be performed between switching on the frequency counter and querying the count result.

The numeric suffixes <1|2> are irrelevant for this command.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK2 ON

Switches on marker 2.

CALC:MARK2:COUN ON

Switches the frequency counter for marker 2.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK2:COUN:FREQ?

Outputs the measured value of marker 2.

Characteristics

*RST value: –

SCPI: device–specific

Mode

CALCulate Subsystem R&S FSL

1300.2519.12 6.58 E-11

CALCulate<1|2>:MARKer<1...4>:COUNt:RESolution

This command specifies the resolution of the frequency counter.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

Parameter

0.1 | 1 | 10 | 100 | 1000 | 10000 Hz

Example

CALC:MARK:COUN:RES 1kHz

Sets the resolution of the frequency counter to 1 kHz.

Characteristics

*RST value: 1kHz

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:LOEXclude

This command switches the local oscillator suppression for peak search on or off. This setting

applies to all markers and delta markers.

The numeric suffixes <1|2> and <1…4> are irrelevant.

Parameter

ON | OFF

Example

CALC:MARK:LOEX ON

Characteristics

*RST value: ON

SCPI: device–specific

Mode

A–F, ADEMOD, CATV, SPECM

CALCulate<1|2>:MARKer<1...4>:MAXimum[:PEAK]

This command positions the marker to the current maximum value of the corresponding trace.

The corresponding marker is activated first or switched to the marker mode.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Note: If no maximum value is found on the trace (level spacing to adjacent values < peak

excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK2:MAX

Positions marker 2 to the maximum value of the trace.

R&S FSL CALCulate Subsystem

1300.2519.12 6.59 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:MARKer<1...4>:MAXimum:AUTO

Activates the automatic peak search function for marker 1 at the end of each particular sweep.

This function may be used during adjustments of a device under test to keep track of the actual

peak marker position and level.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is available from firmware version 1.50.

Note: If no maximum value is found on the trace (level spacing to adjacent values < peak

excursion), an execution error (error code: –200) is produced.

Parameter

ON | OFF

Example

CALC:MARK:MAX:AUTO ON

Activates the automatic peak search function for marker 1 at the end of each particular sweep.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT

This command positions the marker to the next smaller maximum value to the left of the current

value (i.e. in descending X values) on the trace.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Note: If no next smaller maximum value is found on the trace (level spacing to adjacent

values < peak excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK2:MAX:LEFT

Positions marker 2 to the next lower maximum value to the left of the current value.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, BT, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate Subsystem R&S FSL

1300.2519.12 6.60 E-11

CALCulate<1|2>:MARKer<1...4>:MAXimum:NEXT

This command positions the marker to the next smaller maximum value of the corresponding

trace.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Note: If no next smaller maximum value is found on the trace (level spacing to adjacent

values < peak excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK2:MAX:NEXT

Positions marker 2 to the next lower maximum value.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt

This command positions the marker to the next smaller maximum value to the right of the

current value (i.e. in ascending X values) on the corresponding trace.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Note: If no next smaller maximum value is found on the trace (level spacing to adjacent

values < peak excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK2:MAX:RIGH

Positions marker 2 to the next lower maximum value to the right of the current value.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:MARKer<1...4>:MINimum[:PEAK]

This command positions the marker to the current minimum value of the corresponding trace.

The corresponding marker is activated first or switched to marker mode, if necessary.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Note: If no minimum value is found on the trace (level spacing to adjacent values < peak

excursion), an execution error (error code: –200) is produced.

R&S FSL CALCulate Subsystem

1300.2519.12 6.61 E-11

Example

CALC:MARK2:MIN

Positions marker 2 to the minimum value of the trace.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:MARKer<1...4>:MINimum:AUTO

Activates the automatic minimum value search function for marker 1 at the end of each

particular sweep. This function may be used during adjustments of a device under test to keep

track of the actual peak marker position and level.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.50.

Note: If no minimum value is found on the trace (level spacing to adjacent values < peak

excursion), an execution error (error code: –200) is produced.

Parameter

ON | OFF

Example

CALC:MARK:MIN:AUTO ON

Activates the automatic minimum value search function for marker 1 at the end of each

particular sweep.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT

This command positions the marker to the next higher minimum value to the left of the current

value (i.e. in descending X direction) on the corresponding trace.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Note: If no next higher minimum value is found on the trace (level spacing to adjacent values

<peak excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK2:MIN

Positions marker 2 to the minimum value of the trace.

CALC:MARK2:MIN:LEFT

Positions marker 2 to the next higher minimum value to the left of the current value.

CALCulate Subsystem R&S FSL

1300.2519.12 6.62 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:MARKer<1...4>:MINimum:NEXT

This command positions the marker to the next higher minimum value of the corresponding

trace.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Note: If no next higher minimum value is found on the trace (level spacing to adjacent values

<peak excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK2:MIN

Positions marker 2 to the minimum value of the trace.

CALC:MARK2:MIN:NEXT

Positions marker 2 to the next higher maximum value.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt

This command positions the marker to the next higher minimum value to the right of the current

value (i.e. in ascending X direction) on the corresponding trace.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

This command is an event and therefore has no *RST value and no query.

Note: If no next higher minimum value is found on the trace (level spacing to adjacent values

<peak excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK2:MIN

Positions marker 2 to the minimum value of the trace.

CALC:MARK2:MIN:RIGH

Positions marker 2 to the next higher minimum value to the right of the current value.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

R&S FSL CALCulate Subsystem

1300.2519.12 6.63 E-11

CALCulate<1|2>:MARKer<1...4>:PEXCursion

This command defines the peak excursion, i.e. the spacing below a trace maximum which must

be attained before a new maximum is recognized, or the spacing above a trace minimum which

must be attained before a new minimum is recognized. The set value applies to all markers and

delta markers. The unit depends on the selected operating mode.

The numeric suffixes <1|2> and <1...4> are irrelevant.

Parameter

<numeric_value>

Example

CALC:MARK:PEXC 10dB

Defines peak excursion 10 dB in spectrum Spectrum Analyzer mode.

Characteristics

*RST value: 6dB in Spectrum Analyzer mode

SCPI: device–specific

Mode

A, ADEMOD, BT, CATV, SPECM

CALCulate<1|2>:MARKer<1...4>:TRACe

This command assigns the selected marker (1 to 4) to the indicated measurement curve. The

corresponding trace must be active, i.e. its status must be different from "BLANK".

If necessary the corresponding marker is switched on prior to the assignment.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

1to 6

Example

CALC:MARK3:TRAC 2

Assigns marker 3 to trace 2.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV

CALCulate Subsystem R&S FSL

1300.2519.12 6.64 E-11

CALCulate<1|2>:MARKer<1...4>:X

This command positions the selected marker to the indicated frequency (span > 0), time (span =

0) or level (APD measurement or CCDF measurement ON).

If marker 2, 3 or 4 is selected and used as delta marker, it is switched to marker mode.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

Parameter

0to MAX (frequency | sweep time)

Example

CALC:MARK2:X 10.7MHz

Positions marker 2 to frequency 10.7 MHz.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

CALCulate<1|2>:MARKer<1...4>:X:SLIMits[:STATe]

This command switches between a limited (ON) and unlimited (OFF) search range.

If the power measurement in zero span is active, this command limits the evaluation range on

the trace.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:MARK:X:SLIM ON

Switches on search limitation.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, ADEMOD, CATV, SPECM

R&S FSL CALCulate Subsystem

1300.2519.12 6.65 E-11

CALCulate<1|2>:MARKer<1...4>:X:SLIMits:LEFT

This command sets the left limit of the search range for markers and delta markers. Depending

on the span setting of the x–axis the indicated value defines a frequency (span > 0) or time

(span = 0).

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

If the power measurement in zero span is active, this command limits the evaluation range to

the trace.

Note: The function is only available if the search limit for marker and delta marker is switched

on (CALCulate<1|2>:MARKer<1...4>:X:SLIMits[:STATe]).

Parameter

0to MAX (frequency | sweep time)

Example

CALC:MARK:X:SLIM ON

Switches the search limit function on.

CALC:MARK:X:SLIM:LEFT 10MHz

Sets the left limit of the search range to 10 MHz.

Characteristics

*RST value: – (is set to the left diagram border when switching on search limits)

SCPI: device–specific

Mode

A, ADEMOD, CATV, SPECM

CALCulate<1|2>:MARKer<1...4>:X:SLIMits:RIGHT

This command sets the right limit of the search range for markers and delta markers. Depending

on the span setting of the x–axis the indicated value defines a frequency (span > 0) or time

(span = 0).

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

If the power measurement in zero span is active, this command limits the evaluation range to

the trace.

Note: The function is only available if the search limit for marker and delta marker is switched

on (CALCulate<1|2>:MARKer<1...4>:X:SLIMits[:STATe]).

Parameter

0to MAX (frequency | sweep time)

Example

CALC:MARK:X:SLIM ON

Switches the search limit function on.

CALC:MARK:X:SLIM:RIGH 20MHz

Sets the right limit of the search range to 20 MHz.

Characteristics

*RST value: – (is set to the right diagram border when switching on search limits)

SCPI: device–specific

Mode

A, ADEMOD, CATV, SPECM

CALCulate Subsystem R&S FSL

1300.2519.12 6.66 E-11

CALCulate<1|2>:MARKer<1...4>:X:SSIZe

This command defines the step size of the rotary knob for marker or delta marker value

changes. It takes only effect in manual operation. It is available for all base unit measurements

with the exception of statistics.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

This command is available from firmware version 1.60.

Parameter

STANdard measurement point step size

POINts measured value step size (number of measured values is defined via the

[SENSe<1|2>:]SWEep:POINts command)

Example

CALC:MARK:X:SSIZ POIN

Sets the measured value step size.

Characteristics

RST value: STANdard

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:Y?

This command queries the measured value of the selected marker. The corresponding marker

is activated before or switched to marker mode, if necessary.

To obtain a correct query result, a complete sweep with synchronization to the sweep end must

be performed between the activation of the marker and the query of the Y value. This is only

possible in single sweep mode.

The query result is output in the unit determined with CALCulate<1|2>:UNIT:POWer.

In the default setting, the output is made depending on the unit determined with

CALCulate<1|2>:UNIT:POWer;only with linear level scaling is the output in %.

For CDMA2000 and 1xEV-DO code domain measurements (option K82 and K84) the numeric

suffix <1|2> selects the measurement screen. In the other modes the numeric suffix <1|2> is

irrelevant.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK2 ON

Switches marker 2.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK2:Y?

Outputs the measured value of marker 2.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, ADEMOD, BT, CATV, CDMA, EVDO, SPECM, WCDMA

R&S FSL CALCulate Subsystem

1300.2519.12 6.67 E-11

CALCulate<1|2>:MARKer<1...4>:Y:PERCent

This command positions the selected marker to the given probability. If marker 2, 3 or 4 is

selected and used as a delta marker, it is switched to marker mode.

The numeric suffixes <1|2> are irrelevant for this command.

Note: The command is only available with the CCDF measurement switched on. The

associated level value can be determined with the

CALCulate<1|2>:MARKer<1...4>:X command.

Parameter

0to100%

Example

CALC1:MARK:Y:PERC 95PCT

Positions marker 1 to a probability of 95%.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, CATV, CDMA, EVDO

CALCulate Subsystem R&S FSL

1300.2519.12 6.68 E-11

CALCulate:MARKer:FUNCtion Subsystem

The CALCulate:MARKer:FUNCtion subsystem checks the marker functions in the instrument.

The following subsystems are included:

•"CALCulate:MARKer:FUNCtion:HARMonics Subsystem" on page 6.82

•"CALCulate:MARKer:FUNCtion:POWer Subsystem" on page 6.86

•"CALCulate:MARKer:FUNCtion:STRack Subsystem" on page 6.93

•"CALCulate:MARKer:FUNCtion:SUMMary Subsystem" on page 6.95

Commands of the CALCulate:MARKer:FUNCtion Subsystem

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation[:STATe]

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation:CONTinuous

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation:HOLDoff

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation:SELect

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:CENTer

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:CSTep

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks[:IMMediate]

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:COUNt?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:SORT

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:X?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:Y?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:MDEPth[:STATe]

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:MDEPth:RESult?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:MDEPth:SEARchsignal

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:FREQuency?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:QFACtor?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:RESult?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:STATe

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:TIME?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:NOISe[:STATe]

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:NOISe:RESult?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:REFerence

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:TOI[:STATe]

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:TOI:RESult?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:TOI:SEARchsignal

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:ZOOM

R&S FSL CALCulate Subsystem

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CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation[:STATe]

This command switches on or off the audio demodulator when the indicated marker is reached.

With span > 0 the hold time can be defined at the corresponding marker position with

CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation:HOLDoff.In zero span

the demodulation is permanently active.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:MARK3:FUNC:DEM ON

Switches on the demodulation for marker 3.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation:CONTinuous

This command switches on or off the continuous demodulation for span >0. Thus acoustic

monitoring of the signals can be performed.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

CALC2:MARK3:FUNC:DEM:CONT ON

Switches on the continuous ' demodulation.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation:HOLDoff

This command defines the hold time at the marker position for the demodulation with span > 0.

The setting is independent of the selected marker, the suffixes <1|2> and <1...4> are irrelevant.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

10ms to 1000s

Example:

CALC:MARK:FUNC:DEM:HOLD 3s

CALCulate Subsystem R&S FSL

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Characteristics:

*RST value: – (DEModulation is set to OFF)

SCPI: device–specific

Mode:

CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation:SELect

This command selects the demodulation type for the audio demodulator. The command is

independent of the selected marker, the suffixes 1|2 and 1 to 4 are irrelevant.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

AM | FM

Example

CALC:MARK:FUNC:DEM:SEL FM

Characteristics

*RST value: AM

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CENTer

This command sets the center frequency equal to the frequency of the indicated marker.

If marker 2, 3 or 4 is selected and used as delta marker, the marker is switched to the marker

mode.

The numeric suffix <1|2> are irrelevant for this command.

This command is an "event" and therefore has no *RST value and no query.

Example

CALC:MARK2:FUNC:CENT

Sets the center frequency to the frequency of marker 2.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F, CATV, SPECM

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1300.2519.12 6.71 E-11

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CSTep

This command sets the step size of the center frequency to the X value of the current marker.

Ifmarker 2, 3 or 4 is selected and used as delta marker, it is switched to the marker mode.

The numeric suffix <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

CALC:MARK3:FUNC:CST

Sets the center frequency to the same value as the frequency of marker 3.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks[:IMMediate]

This command searches the selected trace for the indicated number of maxima. The results are

entered in a list and can be queried with the

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:X? and

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:Y? commands. The number of

maxima found can be queried with

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:COUNt?.The trace to be examined

is selected with CALCulate<1|2>:MARKer<1...4>:TRACe.The order of the results in the

list can be defined with CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:SORT.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.30.

Note: The number of maxima found depends on the waveform and value set for the Peak

Excursion parameter (CALCulate<1|2>:MARKer<1...4>:PEXCursion), however,

amaximum number of 200 maxima are determined. Only the signals which exceed their

surrounding values at least by the value indicated by the peak excursion parameter will

be recognized as maxima. Therefore, the number of maxima found is not automatically

the same as the number of maxima desired.

Parameter

1to 200

Example

INIT:CONT OFF

Switches to single sweep mode

INIT;*WAI

Starts measurement and synchronizes to end

CALC:MARK:TRAC 1

Sets marker 1 to trace 1

CALC:MARK:FUNC:FPE:SORT X

Sets the sort mode to increasing X values

CALC:MARK:FUNC:FPE 3

Searches the 3 highest maxima for trace 1

CALC:MARK:FUNC:FPE:COUN?

Queries the number of maxima found

CALCulate Subsystem R&S FSL

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CALC:MARK:FUNC:Y?

Queries the level of maxima found

CALC:MARK:FUNC:X?

Queries the frequencies (span <> 0) or time (span = 0) of maxima found.

Characteristics

*RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:COUNt?

This query reads out the number of maxima found during the search. If no search for maxima

has been performed, 0 is returned.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.30.

Example

CALC:MARK:FUNC:FPE 3

Searches the 3 highest maxima for trace 1

CALC:MARK:FUNC:FPE:COUN?

Queries the number of maxima found

Characteristics

*RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:SORT

This command sets the sort mode for the search for maxima:

X: the maxima are sorted in the list of responses according to increasing X values

Y: the maxima are sorted in the list of responses according to decreasing Y values

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.30.

Parameter

X | Y

Example

CALC:MARK:FUNC:FPE:SORT Y

Sets the sort mode to decreasing y values

Characteristics

*RST value: –

SCPI: device–specific

Mode

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1300.2519.12 6.73 E-11

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:X?

This query reads out the list of X values of the maxima found. The number of available values

can be queried with CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:COUNt?.

With sort mode X, the X values are in increasing order; with sort mode Y the order corresponds

to the decreasing order of the Y values.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.30.

Example

CALC:MARK:FUNC:FPE:SORT Y

Sets the sort mode to decreasing y values

CALC:MARK:FUNC:FPE 3

Searches the 3 highest maxima for trace 1

CALC:MARK:FUNC:FPE:COUN?

Queries the number of maxima found

CALC:MARK:FPE:FUNC:X?

Queries the frequencies (span <> 0) or. time (span = 0) of the maxima found

Return values

107.5E6,153.8E6,187.9E6

frequencies in increasing order

2.05E–3,2.37E–3, 3.71e–3

times in increasing order

Characteristics

*RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:Y?

This query reads out the list of X values of the maxima found. The number of available values

can be queried with CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:COUNt?.

With sort mode X, the X values are in increasing order; with sort mode Y the order corresponds

to the decreasing order of the Y values.

The numeric suffixes <1|2> are irrelevant for this command.

This command is available from firmware version 1.30.

Example

CALC:MARK:FUNC:FPE:SORT Y

Sets the sort mode to decreasing y values

CALC:MARK:FUNC:FPE 3

Searches the 3 highest maxima for trace 1

CALC:MARK:FUNC:FPE:COUN?

Queries the number of maxima found

CALC:MARK:FUNC:FPE:Y?

Queries the levels of the maxima found

Return values

–37.5,–58.3,–59.6

level in decreasing order

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Characteristics

*RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:MDEPth[:STATe]

This command switches on the measurement of the AM modulation depth. An AM–modulated

carrier is required on the screen for correct operation. If necessary, marker 1 is previously

activated and set to the largest signal available.

The level value of marker 1 is regarded as the carrier level. On activating the function, marker 2

and marker 3 are automatically set as delta markers symmetrically to the carrier to the adjacent

maxima of the trace.

If the position of delta marker 2 is changed, delta marker 3 is moved symmetrically with respect

to the reference marker (marker 1). If the position of delta marker 3 is changed, fine adjustment

can be performed independently of delta marker 2.

The power at the marker positions is calculated from the measured levels.

The AM modulation depth is calculated from the ratio of power values at the reference marker

and the delta markers. If the two AM sidebands differ in power, the average value of the two

power values is used for calculating the AM modulation depth.

The numeric suffix <1|2> and <1...4> are irrelevant for this command.

Example

CALC:MARK:X 10MHZ

Sets the reference marker (marker 1) to the carrier signal at 10 MHz.

CALC:MARK:FUNC:MDEP ON

Switches on the modulation depth measurement.

CALC:DELT2:X 10KHZ

Sets delta markers 2 and 3 to the signals at 10 kHz from the carrier signal.

CALC:DELT3:X 9.999KHZ

Corrects the position of delta marker 3 relative to delta marker 2.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:MDEPth:RESult?

This command queries the AM modulation depth.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffix <1|2> and <1...4> are irrelevant for this command.

This command is only a query and therefore has no *RST value.

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Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:X 10MHZ

Sets the reference marker (marker 1) to the carrier signal at 10 MHz.

CALC:MARK:FUNC:MDEP ON

Switches on the modulation depth measurement.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:MDEP:RES?

Outputs the measured value.

Characteristics

*RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:MDEPth:SEARchsignal

This command starts the search of the signals required for the modulation depth measurement.

The numeric suffix <1|2> are irrelevant for this command.

Note: No new measurement is done. Only the currently available trace selected for the

modulation depth measurement is used

Parameter

ONCE

Example

CALC:MARK:FUNC:MDEP:SEAR ONCE

Executes the search of an AM modulated signal at the currently available trace.

Characteristics

*RST value: –

SCPI: conform

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown

This command defines the level spacing of the two temporary markers to the right and left of

marker 1.

The temporary markers T1 and T2 are positioned by n dB below the active reference marker.

The value measured by these markers can be queried with

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:RESult??.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

Parameter

<numeric_value>

CALCulate Subsystem R&S FSL

1300.2519.12 6.76 E-11

Example

CALC:MARK:FUNC:NDBD 3dB

Sets the level spacing to 3 dB.

Characteristics

*RST value: 6dB

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:FREQuency?

This command queries the values of the two temporary markers for span>0. The frequency

values are separated by comma and output in ascending order.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:NDBD ON

Switches on the n dB down function.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:NDBD:FREQ?

Outputs the frequencies of the temporary markers.

Characteristics

*RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:QFACtor?

This command queries the Q factor (quality) of the measured bandwidth for span>0.

This command is only a query and therefore has no *RST value.

This command is available from firmware version 1.80.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:NDBD ON

Switches on the n dB down function.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:NDBD:QFAC?

Queries the Q factor of the measured bandwidth.

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1300.2519.12 6.77 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:RESult?

This command queries the measured value. The value depends on the span setting:

–span > 0: frequency spacing of the two temporary markers (in Hz)

–span = 0: pulse width between the two temporary markers (in s)

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value in order to obtain a correct query result. This is

only possible in single sweep mode.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:NDBD ON

Switches on the n dB down function.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:NDBD:RES?

Outputs the measured value.

Characteristics

*RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:STATe

This command switches the "N dB Down" function on or off. Marker 1 is activated first, if

necessary.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:NDBD:STAT ON

Switches on the "N dB Down" function.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

CALCulate Subsystem R&S FSL

1300.2519.12 6.78 E-11

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:TIME?

This command queries the values of the two temporary markers in zero span. The time values

are separated by comma and output in ascending order.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode

CALC:MARK:FUNC:NDBD ON

Switches on the n dB down function.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:NDBD:TIME?

Outputs the time values of the temporary markers.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NOISe[:STATe]

This command switches the noise measurement on or off for all markers. The noise power

density is measured at the position of the markers. The result can be queried with

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NOISe:RESult?.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:NOIS ON

Switches on the noise measurement.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

R&S FSL CALCulate Subsystem

1300.2519.12 6.79 E-11

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NOISe:RESult?

This command queries the result of the noise measurement.

Acomplete sweep with synchronization to the sweep end must be performed between switching

on the function and querying the measured value in order to obtain a correct query result. This

is only possible in single sweep mode.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK2 ON

Switches on marker 2.

CALC:MARK2:FUNC:NOIS ON

Switches on noise measurement for marker 2.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK2:NOIS:RES?

Outputs the noise result of marker 2.

Characteristics

*RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:REFerence

This command sets the reference level to the power measured by the indicated marker. If

marker 2, 3 or 4 is selected and used as delta marker, it is switched to marker mode.

The numeric suffix <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

CALC:MARK2:FUNC:REF

Sets the reference level to the level of marker 2.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, CATV, SPECM

CALCulate Subsystem R&S FSL

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CALCulate<1|2>:MARKer<1...4>:FUNCtion:TOI[:STATe]

This command initiates the measurement of the third–order intercept point.

Atwo–tone signal with equal carrier levels is expected at the RF input of the instrument. Marker

1and marker 2 (both normal markers) are set to the maximum of the two signals. Delta marker

3and delta marker 4 are positioned to the intermodulation products. The delta markers can be

modified separately afterwards with the CALCulate<1|2>:DELTamarker<1...4>:X

command.

The third–order intercept is calculated from the level spacing between the normal markers and

the delta markers.

The numeric suffix <1|2> and <1...4> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:TOI ON

Switches on the measurement of the third–order intercept.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:TOI:RESult?

This command queries the third–order intercept point measurement.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffix <1|2> and <1...4> are irrelevant for this command.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:TOI ON

Switches the intercept measurement.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:TOI:RES?

Outputs the measured value.

Characteristics

*RST value: –

SCPI: device–specific

Mode

R&S FSL CALCulate Subsystem

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CALCulate<1|2>:MARKer<1...4>:FUNCtion:TOI:SEARchsignal

This command starts the search of the signals required for the third order intercept

measurement.

The numeric suffix <1|2> are irrelevant for this command.

Note: No new measurement is done. Only the currently available trace selected for the TOI

measurement is used

Parameter

ONCE

Example

CALC:MARK:FUNC:TOI:SEAR ONCE

Executes the search for 2 signals and their intermodulation product at the currently available

trace.

Characteristics

*RST value: –

SCPI: conform

Mode

CALCulate<1|2>:MARKer<1...4>:FUNCtion:ZOOM

This command defines the range to be zoomed around marker 1. Marker 1 is activated first, if

necessary.

The subsequent frequency sweep is stopped at the marker position and the frequency of the

signal is counted. This frequency becomes the new center frequency, and the zoomed span is

set. In order to recognize the end of the operation the synchronization to the sweep end should

be activated. This is only possible in single sweep mode.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Parameter

<numeric_value>

Example

INIT:CONT OFF

Switches to single sweep mode

CALC:MARK:FUNC:ZOOM 1kHz;*WAI

Activates zooming and waits for its end.

CALC:MARK1:FUNC:ZOOM 10

Zooms in around marker 1 by afactor of 10.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F

CALCulate Subsystem R&S FSL

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CALCulate:MARKer:FUNCtion:HARMonics Subsystem

The CALCulate:MARKer:FUNCtion:POWER subsystem contains the commands to define the settings

for harmonics measurement.

This subsystem is available from firmware version 1.10.

Commands of the CALCulate:MARKer:FUNCtion:HARMonics Subsystem

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics[:STATe]

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:BANDwidth:AUTO

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:DISTortion?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:LIST?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:NHARmonics

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:PRESet

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics[:STATe]

This command activates/deactivates the harmonic distortion measurement.

If the measurement is started in span > 0, the last span defines the search range for the first

harmonic. The level is determined for the first harmonic.

If the measurement is started in zero span, center frequency and level are used unchanged.

The numeric suffix <1|2> and <1...4> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:HARM ON

Activates the harmonic distortion measurement.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

A–F, A–T

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:BANDwidth:AUTO

This command defines the resolution bandwidth of the harmonic in respect to the bandwidth of

the first harmonic. For details refer to chaper "Instrument Functions", section "Harmonic RBW

Auto".

The numeric suffix <1|2> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

OFF identical

ON a multiple

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Example

CALC:MARK:FUNC:HARM:BAND:AUTO OFF

Deactivates the automatic bandwidth enlargement.

Characteristics

RST value: ON

SCPI: device–specific

Mode

A–F, A–T

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:DISTortion?

This command queries the distortion results (THD: total harmonic distortion). Two values

separated by a comma are returned: <THD in %>, <THD in dB>.

To obtain a correct result, a complete sweep with synchronization to the end of the sweep must

be performed before a query is output. Synchronization is possible only in the single sweep

mode.

The numeric suffix <1|2> and <1...4> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

TOTal

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:HARM:NHARM 3

Sets the number of harmonics to be measured to 3.

CALC:MARK:FUNC:HARM ON

Activates the harmonic distortion measurement.

INIT;*WAI

Starts a sweep and waits for the end of the sweep.

CALC:MARK:FUNC:HARM:DIST? TOT

Returns the total distortion in % and dB.

Characteristics

RST value: –

SCPI: device–specific

Mode

A–F, A–T

CALCulate Subsystem R&S FSL

1300.2519.12 6.84 E-11

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:LIST?

This command reads out the list of the harmonics. The first value is the absolute power of the

first harmonic (the unit is set via the CALCulate<1|2>:UNIT:POWer command). The following

values are relative to the carrier signal and have the unit dB. They are separated by commas

and correspond to the harmonics to be measured (set via the

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:NHARmonics command).

To obtain a correct result, a complete sweep with synchronization to the end of the sweep must

be performed before a query is output. Synchronization is possible only in the single sweep

mode.

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.10.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:HARM:NHARM 3

Sets the number of harmonics to be measured to 3.

CALC:MARK:FUNC:HARM ON

Activates the harmonic distortion measurement.

INIT;*WAI

Starts a sweep and waits for the end of the sweep.

CALC:MARK:FUNC:HARM:LIST?

Returns the values for the 3 measured harmonics.

Characteristics

RST value: –

SCPI: device–specific

Mode

A–F, A–T

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:NHARmonics

This command sets the number of harmonics to be measured.

The numeric suffix <1|2> and <1...4> are irrelevant for this command.

This command is available from firmware version 1.10.

Parameter

1...26

Example

CALC:MARK:FUNC:HARM:NHARM 3

Sets the number of harmonics to be measured to 3.

Characteristics

RST value: 10

SCPI: device–specific

Mode

A–F, A–T

R&S FSL CALCulate Subsystem

1300.2519.12 6.85 E-11

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:PRESet

This command optimizes the device settings depending on the span setting:

span > 0 Frequency and level of the first harmonic are determined and used for the

measurement list.

zero span The level of the first harmonic is determined. The frequency remains

unchanged.

The numeric suffixes <1/2> and <1...4> are irrelevant.

This command is an event and therefore has no *RST value.

This command is available from firmware version 1.10.

Example

CALC:MARK:FUNC:HARM:PRES

Optimizes the device settings for the harmonic measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

A–F, A–T

CALCulate Subsystem R&S FSL

1300.2519.12 6.86 E-11

CALCulate:MARKer:FUNCtion:POWer Subsystem

The CALCulate:MARKer:FUNCtion:POWER subsystem contains the commands for control of power

measurement.

Commands of the CALCulate:MARKer:FUNCtion:POWer Subsystem

–CALCulate<1|2>:MARKer:FUNCtion:POWer[:STATe]

–CALCulate<1|2>:MARKer:FUNCtion:POWer:MODe

–CALCulate<1|2>:MARKer:FUNCtion:POWer:PRESet

–CALCulate<1|2>:MARKer:FUNCtion:POWer:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:POWer:RESult:PHZ

–CALCulate<1|2>:MARKer:FUNCtion:POWer:SELect

Further information

–"Predefined CP / ACP standards" on page 6.86

Predefined CP / ACP standards

Parameter Standard

AWLan WLAN 802.11A

BWLan WLAN 802.11B

CDPD CDPD

D2CDma CDMA 2000 direct sequence

FIS95A, F8CDma CDMA IS95A forward

FIS95C0 CDMA IS95C Class 0 forward

FIS95C1 CDMA IS95C Class 1 forward

FJ008, F19CDma CDMA J–STD008 forward

FTCDMa / TCDMa TD–SCDMA forward

FW3Gppcdma W–CDMA 3.84 MHz forward

M2CDma CDMA 2000 MC3 multi carrier with 3 carriers

NADC NADC IS136

PDC PDC

PHS PHS

RFID14443 RFID 14443

RIS95A, R8CDma CDMA IS95A reverse

RIS95C0 CDMA IS95C Class 0 reverse

RIS95C1 CDMA IS95C Class 1 reverse

RJ008, R19CDma CDMA J–STD008 reverse

RTCDMA TD–SCDMA reverse

RW3Gppcdma W–CDMA 3.84 MHz reverse

S2CDma CDMA 2000 MC1 multi carrier with 1 carrier

TETRA TETRA

WIBRo WIBRO

WIMax WiMAX

R&S FSL CALCulate Subsystem

1300.2519.12 6.87 E-11

CALCulate<1|2>:MARKer:FUNCtion:POWer[:STATe]

This command switches off the power measurement.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value.

Parameter

OFF

Example

CALC:MARK:FUNC:POW OFF

Switches off the power measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F

CALCulate<1|2>:MARKer:FUNCtion:POWer:MODe

This commands defines the method by which the channel power values are calculated from the

current trace.

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.30.

Parameter

WRITe The channel power and the adjacent channel powers are calculated directly

from the current trace

MAXHold The power values are calculated from the current trace and compared with

the previous power value using a maximum algorithm.

Example

CALC:MARK:FUNC:POW:MODE MAXH

Sets the Maxhold channel power mode.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F

CALCulate Subsystem R&S FSL

1300.2519.12 6.88 E-11

CALCulate<1|2>:MARKer:FUNCtion:POWer:PRESet

This command selects the power measurement setting for a standard and previously switches

on the corresponding measurement, if required.

The configuration for a standard comprises of the parameters weighting filter, channel

bandwidth and spacing, resolution and video bandwidth, as well as detector and sweep time.

The numeric suffixes <1|2> are not relevant.

Note: The settings for standards IS95A and C differ as far as the calculation method of

channel spacings is concerned. For IS95A and J–STD008 the spacing is calculated

from the center of the main channel to the center of the corresponding adjacent

channel, for IS95C from the center of the main channel to the nearest border of the

adjacent channel.

Parameter

WIMax | WIBRo | RFID14443 | NONE

For further details refer to "Predefined CP / ACP standards" on page 6.86.

The parameters WIMax and WIBRo are available from firmware version 1.30.

Example

CALC:MARK:FUNC:POW:PRES NADC

Selects the standard setting for NADC

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F

CALCulate<1|2>:MARKer:FUNCtion:POWer:RESult?

This command queries the result of the performed power measurement. If necessary, the

measurement is switched on prior to the query.

The channel spacings and channel bandwidths are configured in the "SENSe:POWer

Subsystem" on page 6.220.

To obtain a correct result, a complete sweep with synchronization to the end of the sweep must

be performed before a query is output. Synchronization is possible only in the single sweep

mode.

The numeric suffixes <1|2> are not relevant.

This command is a query and therefore has no *RST value.

R&S FSL CALCulate Subsystem

1300.2519.12 6.89 E-11

Parameter

ACPower Adjacent–channel power measurement

Results are output in the following sequence, separated by commas:

Power of transmission channel

Power of lower adjacent channel

Power of upper adjacent channel

Power of lower alternate channel 1

Power of upper alternate channel 1

Power of lower alternate channel 2

Power of upper alternate channel 2

The number of measured values returned depends on the number of

adjacent/alternate channels selected with

[SENSe<1|2>:]POWer:ACHannel:ACPairs.

With logarithmic scaling (RANGE LOG), the power is output in the currently

selected level unit; with linear scaling (RANGE LIN dB or LIN %), the

power is output in W. If [SENSe<1|2>:]POWer:ACHannel:MODE is set

to REL, the adjacent/alternate–channel power is output in dB.

CN Measurement of carrier–to–noise ratio

The carrier–to–noise ratio in dB is returned.

CN0 Measurement of carrier–to–noise ratio referenced to 1 Hz bandwidth.

The carrier–to–noise ratio in dB/Hz is returned.

CPOWer Channel power measurement

In a Spectrum Emission Mask measurement, the query returns the power

result for the reference range, if this power reference type is selected.

With logarithmic scaling (RANGE LOG), the channel power is output in the

currently selected level unit; with linear scaling (RANGE LIN dB or LIN %),

the channel power is output in W.

MCACpower Channel/adjacent–channel power measurement with several carrier

signals

Results are output in the following sequence, separated by commas:

Power of carrier signal 1 to 12 in ascending order

Total power of all carrier signals

Power of lower adjacent channel

Power of upper adjacent channel

Power of lower alternate channel 1

Power of upper alternate channel 1

Power of lower alternate channel 2

Power of upper alternate channel 2

The number of measured values returned depends on the number of

carrier signals and adjacent/alternate channels selected with

[SENSe<1|2>:]POWer:ACHannel:TXCHannel:COUNt and

[SENSe<1|2>:]POWer:ACHannel:ACPairs.

If only one carrier signal is measured, the total value of all carrier signals

will not be output.

With logarithmic scaling (RANGE LOG), the power is output in dBm; with

linear scaling (RANGE LIN dB or LIN %), the power is output in W. If

[SENSe<1|2>:]POWer:ACHannel:MODE is set to REL, the

adjacent/alternate–channel power is output in dB.

CALCulate Subsystem R&S FSL

1300.2519.12 6.90 E-11

OBANdwidth |

OBWidth

Measurement of occupied bandwidth

The occupied bandwidth in Hz is returned.

PPOWer Power of the highest peak

In a Spectrum Emission Mask measurement, the query returns the power

result for the reference range, if this power reference type is selected.

Example of channel/adjacent–channel power measurement

POW:ACH:ACP 3

Sets the number of adjacent/alternate channels to 3.

POW:ACH:BAND 30KHZ

Sets the bandwidth of the transmission channel to 30 kHz.

POW:ACH:BAND:ACH 40KHZ

Sets the bandwidth of each adjacent channel to 40 kHz.

POW:ACH:BAND:ALT1 50KHZ

Sets the bandwidth of each alternate channel to 50 kHz.

POW:ACH:BAND:ALT2 60KHZ

Sets the bandwidth of alternate channel 2 to 60 kHz.

POW:ACH:SPAC 30KHZ

Sets the spacing between the transmission channel and the adjacent channel to 30 kHz, the

spacing between the transmission channel and alternate channel 1 to 60 kHz, and the spacing

between the transmission channel and alternate channel 2 to 90 kHz.

POW:ACH:SPAC:ALT1 100KHZ

Sets the spacing between the alternate adjacent channels and the TX channel. For details refer

to the [SENSe<1|2>:]POWer:ACHannel:SPACing:ALTernate<1...11> command.

POW:ACH:SPAC:ALT2 140KHZ

Sets the spacing between the transmission channel and alternate channel 2 to 140 kHz.

POW:ACH:MODE ABS

Switches on absolute power measurement.

CALC:MARK:FUNC:POW:SEL ACP

Switches on the adjacent–channel power measurement.

INIT:CONT OFF

Switches over to single sweep mode.

INIT;*WAI

Starts a sweep and waits for the end of the sweep.

CALC:MARK:FUNC:POW:RES? ACP

Queries the result of adjacent–channel power measurement.

POW:ACH:REF:AUTO ONCE

Defines the measured channel power as the reference value for relative power measurements.

Note: If the channel power only is to be measured, all commands relating to

adjacent/alternate channel bandwidth and channel spacings are omitted. The number of

adjacent/alternate channels is set to 0 with

[SENSe<1|2>:]POWer:ACHannel:ACPairs.

R&S FSL CALCulate Subsystem

1300.2519.12 6.91 E-11

Example of occupied bandwidth measurement

POW:BAND 90PCT

Defines 90% as the percentage of the power to be contained in the bandwidth range to be

measured.

INIT:CONT OFF

Switches over to single sweep mode.

INIT;*WAI

Starts a sweep and waits for the end of the sweep.

CALC:MARK:FUNC:POW:RES? OBW

Queries the occupied bandwidth measured.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F, CDMA, EVDO, WCDMA

CALCulate<1|2>:MARKer:FUNCtion:POWer:RESult:PHZ

This command switches the query response of the power measurement results between output

of absolute values and output referred to the measurement bandwith.

The measurement results are output with the

CALCulate<1|2>:MARKer:FUNCtion:POWer:RESult? command.

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.50.

Parameter

ON Results output: channel power density in dBm/Hz

OFF Results output: channel power is displayed in dBm

Example

CALC:MARK:FUNC:POW:RES:PHZ ON

Output of results referred to the channel bandwidth.

For details on a complete measurement example refer to Example of channel/adjacent–channel

power measurement.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–F

CALCulate Subsystem R&S FSL

1300.2519.12 6.92 E-11

CALCulate<1|2>:MARKer:FUNCtion:POWer:SELect

This command selects – and switches on – specified power measurement type.

The channel spacings and channel bandwidths are configured in the "SENSe:POWer

Subsystem" on page 6.220.

The numeric suffixes <1|2> are not relevant.

Note: If CPOWer is selected, the number of adjacent channels

([SENSe<1|2>:]POWer:ACHannel:ACPairs)is set to 0. If ACPower is selected, the

number of adjacent channels is set to 1, unless adjacent–channel power measurement

is switched on already.

The channel/adjacent–channel power measurement is performed for the trace selected

with [SENSe<1|2>:]POWer:TRACe.

The occupied bandwidth measurement is performed for the trace on which marker 1 is

positioned. To select another trace for the measurement, marker 1 is to be positioned on the

desired trace by means of CALCulate<1|2>:MARKer<1...4>:TRACe.

Parameter

ACPower Adjacent–channel power measurement with a single carrier signal

CPOWer Channel power measurement with a single carrier signal (equivalent

to adjacent–channel power measurement with NO. OF ADJ CHAN =

MCACpower Channel/adjacent–channel power measurement with several carrier

signals

OBANdwidth |

OBWidth

Measurement of occupied bandwidth

CN Measurement of carrier–to–noise ratio

CN0 Measurement of carrier–to–noise ratio referenced to 1 Hz bandwidth

Example

CALC:MARK:FUNC:POW:SEL ACP

Switches on adjacent–channel power measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F

R&S FSL CALCulate Subsystem

1300.2519.12 6.93 E-11

CALCulate:MARKer:FUNCtion:STRack Subsystem

The CALCulate:MARKer:FUNCtion:STRack subsystem defines the settings of the signal track.

Commands of the CALCulate:MARKer:FUNCtion:STRack Subsystem

–CALCulate<1|2>:MARKer:FUNCtion:STRack[:STATe]

–CALCulate<1|2>:MARKer:FUNCtion:STRack:BANDwidth|BWIDth

–CALCulate<1|2>:MARKer:FUNCtion:STRack:THReshold

–CALCulate<1|2>:MARKer:FUNCtion:STRack:TRACe

CALCulate<1|2>:MARKer:FUNCtion:STRack[:STATe]

This command switches the signal–track function on or off.

With signal track activated, the maximum signal is determined after each frequency sweep and

the center frequency is set to the frequency of this signal. Thus with drifting signals the center

frequency follows the signal.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:STR ON

Switches on the signal track function.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–F

CALCulate<1|2>:MARKer:FUNCtion:STRack:BANDwidth|BWIDth

These commands have the same function. They define the bandwidth around the center

frequency within which the largest signal is searched.

The numeric suffixes <1|2> are not relevant.

Note: The entry of the search bandwidth is only possible if the Signal Track function is

switched on (CALCulate<1|2>:MARKer:FUNCtion:STRack[:STATe]).

Parameter

10Hz to MAX (span)

Example

CALC:MARK:FUNC:STR:BAND 1MHZ

Sets the search bandwidth to 1 MHz.

CALC:MARK:FUNC:STR:BWID 1MHZ

Alternative command for the same function.

CALCulate Subsystem R&S FSL

1300.2519.12 6.94 E-11

Characteristics

*RST value: – (= span/10 on activating the function)

SCPI: device–specific

Mode

A–F

CALCulate<1|2>:MARKer:FUNCtion:STRack:THReshold

This command defines the threshold above which the largest signal is searched for.

The response unit depends on the settings defined with CALCulate<1|2>:UNIT:POWer.

The numeric suffixes <1|2> are not relevant.

Note: The entry of the search bandwidth is only possible if the Signal Track function is

switched on (CALCulate<1|2>:MARKer:FUNCtion:STRack[:STATe]).

Parameter

–330dBm to +30dBm

Example

CALC:MARK:FUNC:STR:THR –50DBM

Sets the threshold for signal tracking to –50 dBm.

Characteristics

*RST value: –120 dBm

SCPI: device–specific

Mode

A–F

CALCulate<1|2>:MARKer:FUNCtion:STRack:TRACe

This command defines the trace on which the largest signal is searched for.

The numeric suffixes <1|2> are not relevant.

Parameter

1to 6

Example

CALC:MARK:FUNC:STR:TRAC 3

Defines trace 3 as the trace for signal tracking.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

A–F

R&S FSL CALCulate Subsystem

1300.2519.12 6.95 E-11

CALCulate:MARKer:FUNCtion:SUMMary Subsystem

This subsystem contains the commands for controlling the power functions in zero span.

Commands of the CALCulate:MARKer:FUNCtion:SUMMary Subsystem

–CALCulate<1|2>:MARKer:FUNCtion:MSUMmary?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary[:STATe]

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:AOFF

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:AVERage

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN[:STATe]

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN:AVERage:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN:PHOLd:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MODE

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PHOLd

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak[:STATe]

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak:AVERage:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak:PHOLd:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:REFerence:AUTO

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS[:STATe]

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS:AVERage:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS:PHOLd:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation[:STATe]

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation:AVERage:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation:PHOLd:RESult?

–CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation:RESult?

CALCulate<1|2>:MARKer:FUNCtion:MSUMmary?

The commands of this subsystem are used to determine the power of a sequence of signal

pulses having the same interval, as are typical for the slots of a GSM signal, for example. The

number of pulses to be measured as well as the measurement time and the period can be set.

To define the position of the first pulse in the trace, a suitable offset can be entered.

The evaluation is performed on the measurement data of a previously recorded trace. The data

recorded during the set measurement time is combined to a measured value for each pulse

according to the detector specified and the indicated number of results is output as a list.

Trace 1 is always used by the function.

The numeric suffixes <1|2> are not relevant.

CALCulate Subsystem R&S FSL

1300.2519.12 6.96 E-11

Trace start

Time offset of

first pulse

Measurement

Time

Measurement

Time

Measurement

Time

Period Period

Parameter

Example

DISP:WIND:TRAC:Y:RLEV –10dBm

Sets the reference level to 10 dB

INP:ATT 30 dB

Sets the input attenuation to 30 dB

FREQ:CENT 935.2MHz;SPAN 0Hz

Sets the receive frequency to 935.2 MHz and the span to 0 Hz

BAND:RES 1MHz;VID 3MHz

Sets the resolution bandwidth to 1 MHz and the video bandwidth to 3 MHz

DET RMS

Sets the RMS detector

TRIG:SOUR VID;LEV:VID 50 PCT

Selects the trigger source VIDeo and sets the level of the video trigger source to 50 PCT

SWE:TIME 50ms

Sets the sweep time to 50 ms

INIT;*WAI

Starts the measurement with synchronization

CALC:MARK:FUNC:MSUM? 50US,450US,576.9US,8

Queries 8 bursts with an offset of 50 µs, a test time of 450 µsand a period of 576.9 µs

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

R&S FSL CALCulate Subsystem

1300.2519.12 6.97 E-11

CALCulate<1|2>:MARKer:FUNCtion:SUMMary[:STATe]

This command switches on or off the previously selected power measurements in zero span.

Thus one or several measurements can be first selected and then switched on and off together

with CALCulate<1|2>:MARKer:FUNCtion:SUMMary[:STATe].

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:SUMM:STAT ON

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:AOFF

This command switches off all measurements in zero span.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

Example

CALC:MARK:FUNC:SUMM:AOFF

Switches off the functions for power measurement in zero span.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:AVERage

This command switches on or off averaging for the active power measurement in zero span.

Averaging is reset by switching it off and on again.

The number of results required for the calculation of average is defined with

[SENSe<1|2>:]AVERage:COUNt.

Synchronization to the end of averaging is only possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:AVER ON

Switches on the calculation of average.

CALCulate Subsystem R&S FSL

1300.2519.12 6.98 E-11

AVER:COUN 200

Sets the measurement counter to 200.

INIT;*WAI

Starts a sweep and waits for the end.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN[:STATe]

This command switches on or off the measurement of the mean value.

The numeric suffixes <1|2> are not relevant.

Note: The measurement is performed on the trace on which marker 1 is positioned. In order to

evaluate another trace, marker 1 must be positioned on another trace with

CALCulate<1|2>:MARKer<1...4>:TRACe.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:SUMM:MEAN ON

Switches on the function.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN:AVERage:RESult?

This command queries the result of the measurement of the averaged mean value. The query is

only possible if averaging has been activated previously using

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:AVERage.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:MEAN ON

Switches on the function.

CALC:MARK:FUNC:SUMM:AVER ON

Switches on the average value calculation.

INIT;*WAI

Starts a sweep and waits for the end.

R&S FSL CALCulate Subsystem

1300.2519.12 6.99 E-11

CALC:MARK:FUNC:SUMM:MEAN:AVER:RES?

Outputs the result.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN:PHOLd:RESult?

This command queries the result of the measurement of the mean value with active peak hold.

The query is only possible if the peak hold function has been switched on previously using

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PHOLd.

The query is possible only if the peak hold function is active.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:MEAN ON

Switches on the function.

CALC:MARK:FUNC:SUMM:PHOL ON

Switches on the peak value measurement.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:MEAN:PHOL:RES?

Outputs the result.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN:RESult?

This command queries the result of the measurement of the mean value.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALCulate Subsystem R&S FSL

1300.2519.12 6.100 E-11

CALC:MARK:FUNC:SUMM:MEAN ON

Switches on the function.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:MEAN:RES?

Outputs the result.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MODE

This command selects absolute or relative power measurement in zero span.

The reference power for relative measurement is defined with

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:REFerence:AUTO.If the reference power

is not defined, the value 0 dBm is used.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

Parameter

ABSolute | RELative

Example

CALC:MARK:FUNC:SUMM:MODE REL

Switches the power measurement in zero span to relative.

Characteristics

RST value: ABSolute

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PHOLd

This command switches on or off the peak–hold function for the active power measurement in

zero span.

The peak–hold function is reset by switching it off and on again.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:SUMM:PHOL ON

Switches on the function.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–T

R&S FSL CALCulate Subsystem

1300.2519.12 6.101 E-11

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak[:STATe]

This command switches on or off the measurement of the positive peak value.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:SUMM:PPE ON

Switches on the function.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak:AVERage:RESult?

This command is used to query the result of the measurement of the averaged positive peak

value. The query is only possible if averaging has been activated previously using

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:AVERage.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:PPE ON

Switches on the function.

CALC:MARK:FUNC:SUMM:AVER ON

Switches on the calculation of average.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:PPE:AVER:RES?

Outputs the result.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate Subsystem R&S FSL

1300.2519.12 6.102 E-11

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak:PHOLd:RESult?

This command is used to query the result of the measurement of the positive peak value with

active peak hold function. The query is only possible if the peak hold function has been

activated previously using CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PHOLd.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:PPE ON

Switches on the function.

CALC:MARK:FUNC:SUMM:PHOL ON

Switches on the measurement of the peak value.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:PPE:PHOL:RES?

Outputs the result.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak:RESult?

This command is used to query the result of the measurement of the positive peak value. The

measurement may have to be switched on previously.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:PPE ON

Switches on the function.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:PPE:RES?

Outputs the result.

R&S FSL CALCulate Subsystem

1300.2519.12 6.103 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:REFerence:AUTO

This command sets the currently measured average value

(CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN[:STATe])and RMS value

(CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS[:STATe])as reference values for

relative measurements in zero span.

If the measurement of RMS value and average is not activated, the reference value 0 dBm is

used.

If the function CALCulate<1|2>:MARKer:FUNCtion:SUMMary:AVERage or

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PHOLd is switched on, the current value is

the accumulated measurement value at the time considered.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Parameter

ONCE

Example

CALC:MARK:FUNC:SUMM:REF:AUTO ONCE

Takes the currently measured power as reference value for the relative power measurement in

zero span.

Characteristics

RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS[:STATe]

This command switches on or off the measurement of the effective (RMS) power. If necessary

the function is switched on previously.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:SUM:RMS ON

Switches on the function.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–T

CALCulate Subsystem R&S FSL

1300.2519.12 6.104 E-11

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS:AVERage:RESult?

This command queries the result of the measurement of the averaged RMS value. The query is

only possible if averaging has been activated previously using

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:AVERage.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:RMS ON

Switches on the function.

CALC:MARK:FUNC:SUMM:AVER ON

Switches on the average value calculation.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:RMS:AVER:RES?

Outputs the result.

Characteristics

*RST– value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS:PHOLd:RESult?

This command queries the result of the measurement of the RMS value with active peak hold.

The query is only possible only if the peak hold function has been activated previously using

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PHOLd.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:RMS ON

Switches on the function.

CALC:MARK:FUNC:SUMM:PHOL ON

Switches on the peak value measurement.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:RMS:PHOL:RES?

Outputs the result.

R&S FSL CALCulate Subsystem

1300.2519.12 6.105 E-11

Characteristics

*RST– value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS:RESult?

This command queries the result of the measurement of the RMS power value.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:RMS ON

Switches on the function.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:RMS:RES?

Outputs the result.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation[:STATe]

This command switches on or off the measurement of the standard deviation.

On switching on the measurement, the mean power measurement is switched on as well.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

CALC:MARK:FUNC:SUMM:SDEV ON

Switches on the measurement of the standard deviation.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

CALCulate Subsystem R&S FSL

1300.2519.12 6.106 E-11

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation:AVERage:RESult?

This command queries the result of the averaged standard deviation determined in several

sweeps. The query is possible only if averaging is active.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:SDEV ON

Switches on the function.

CALC:MARK:FUNC:SUMM:AVER ON

Switches on the calculation of average.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:MEAN:SDEV:RES?

Outputs the result.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation:PHOLd:RESult?

This command queries the maximum standard deviation value determined in several sweeps.

The query is possible only if the peak hold function is active.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:SDEV ON

Switches on the function.

CALC:MARK:FUNC:SUMM:PHOL ON

Switches on the peak value measurement.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:SDEV:PHOL:RES?

Outputs the result.

R&S FSL CALCulate Subsystem

1300.2519.12 6.107 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation:RESult?

This command queries the results of the standard deviation measurement.

Acomplete sweep with synchronization to sweep end must be performed between switching on

the function and querying the measured value to obtain a correct query result. This is only

possible in single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

Example

INIT:CONT OFF

Switches to single sweep mode.

CALC:MARK:FUNC:SUMM:SDEV ON

Switches on the function.

INIT;*WAI

Starts a sweep and waits for the end.

CALC:MARK:FUNC:SUMM:SDEV:RES?

Outputs the result.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T

CALCulate Subsystem R&S FSL

1300.2519.12 6.108 E-11

CALCulate:MATH Subsystem

The CALCulate:MATH subsystem allows to process data from the SENSe–subsystem in numeric

expressions.

Commands of the CALCulate:MATH Subsystem

–CALCulate<1|2>:MATH[:EXPression][:DEFine]

–CALCulate<1|2>:MATH:MODE

–CALCulate<1|2>:MATH:POSition

–CALCulate<1|2>:MATH:STATe

CALCulate<1|2>:MATH[:EXPression][:DEFine]

This command defines the mathematical expression for relating traces to trace1.

This command is available from firmware version 1.30.

Parameter

(TRACE1–TRACE2) Subtracts trace 2 from trace 1.

(TRACE1–TRACE3) Subtracts trace 3 from trace 1.

(TRACE1–TRACE4) Subtracts trace 4 from trace 1.

(TRACE1–TRACE5) Subtracts trace 5 from trace 1.

(TRACE1–TRACE6) Subtracts trace 6 from trace 1.

Example

CALC1:MATH (TRACE1 – TRACE2)

Selects the subtraction of trace 2 from trace 1.

Characteristics

*RST value: –

SCPI: conform

Mode

CALCulate<1|2>:MATH:MODE

This command selects the averaging method for the average trace mode.

The numeric suffixes <1|2> are irrelevant.

This command is available from firmware version 1.90.

Parameter

LIN | LOG | POWer

Example

CALC:MATH:MODE LIN

Selects linear averaging for average trace mode.

R&S FSL CALCulate Subsystem

1300.2519.12 6.109 E-11

Characteristics

*RST value: LOG

SCPI: device–specific

Mode

CALCulate<1|2>:MATH:POSition

This command defines the position of the result of the trace mathematics. The indication is in %

of the screen height, with 100% corresponding to the upper diagram border.

This command is available from firmware version 1.30.

Parameter

–100PCT to 200PCT

Example

CALC:MATH:POS 50PCT

Sets the position to the horizontal diagram center.

Characteristics

*RST value: 50PCT

SCPI: device–specific

Mode

CALCulate<1|2>:MATH:STATe

This command switches the mathematical relation of traces on or off.

This command is available from firmware version 1.30.

Parameter

ON | OFF

Example

CALC:MATH:STAT ON

Switches on the trace mathematics.

Characteristics

*RST value: OFF

SCPI: conform

Mode

CALCulate Subsystem R&S FSL

1300.2519.12 6.110 E-11

CALCulate:PSEarch|PEAKsearch Subsystem

The CALCulate:PSEarch|PEAKsearch subsystem contains the remote commands for Spurious

Emissions measurements. Both groups of commands (PSEarch and PEAKsearch) perform the same

functions.

Commands of the CALCulate:PSEarch|PEAKsearch Subsystem

–CALCulate<1|2>:PSEarch|PEAKsearch[:IMMediate]

–CALCulate<1|2>:PSEarch|PEAKsearch:AUTO

–CALCulate<1|2>:PSEarch|PEAKsearch:MARGin

–CALCulate<1|2>:PSEarch|PEAKsearch:PSHow

–CALCulate<1|2>:PSEarch|PEAKsearch:SUBRanges

CALCulate<1|2>:PSEarch|PEAKsearch[:IMMediate]

This command determines the list of the subrange maximums from the existing sweep results.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.80.

Example

CALC:PSE

Starts to determine the list.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:PSEarch|PEAKsearch:AUTO

For details refer to "CALCulate<1|2>:ESPectrum:PSEarch|:PEAKsearch:AUTO" on page 6.24.

This command is available from firmware version 1.80.

CALCulate<1|2>:PSEarch|PEAKsearch:MARGin

For details refer to "CALCulate<1|2>:ESPectrum:PSEarch|:PEAKsearch:MARGin" on page

6.25.

This command is available from firmware version 1.80.

CALCulate<1|2>:PSEarch|PEAKsearch:PSHow

For details refer to "CALCulate<1|2>:ESPectrum:PSEarch|:PEAKsearch:PSHow" on page 6.24.

This command is available from firmware version 1.80.

R&S FSL CALCulate Subsystem

1300.2519.12 6.111 E-11

CALCulate<1|2>:PSEarch|PEAKsearch:SUBRanges

This command sets the number of peaks per range that are stored in the list. Once the selected

number of peaks has been reached, the peak search is stopped in the current range and

continued in the next range.

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

1to 50

Example

CALC:PSE:SUBR 10

Sets 10 peaks per range to be stored in the list.

Characteristics

RST value: 25

SCPI: device–specific

Mode

CALCulate Subsystem R&S FSL

1300.2519.12 6.112 E-11

CALCulate:STATistics Subsystem

The CALCulate:STATistics subsystem controls the statistical measurement functions in the instrument.

Commands of the CALCulate:STATistics Subsystem

–CALCulate:STATistics:APD[:STATe]

–CALCulate:STATistics:CCDF[:STATe]

–CALCulate:STATistics:NSAMples

–CALCulate:STATistics:PRESet

–CALCulate:STATistics:RESult<1...6>?

–CALCulate:STATistics:SCALe:AUTO

–CALCulate:STATistics:SCALe:X:RANGe

–CALCulate:STATistics:SCALe:X:RLEVel

–CALCulate:STATistics:SCALe:Y:LOWer

–CALCulate:STATistics:SCALe:Y:UNIT

–CALCulate:STATistics:SCALe:Y:UPPer

CALCulate:STATistics:APD[:STATe]

This command switches on or off the measurement of amplitude distribution (APD). On

activating this function, the CCDF measurement is switched off.

Parameter

ON | OFF

Example

CALC:STAT:APD ON

Switches on the APD measurement.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

CALCulate:STATistics:CCDF[:STATe]

This command switches on or off the measurement of the complementary cumulative

distribution function (CCDF). On activating this function, the APD measurement is switched off.

Parameter

ON | OFF

Example

CALC:STAT:CCDF ON

Switches on the CCDF measurement.

R&S FSL CALCulate Subsystem

1300.2519.12 6.113 E-11

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, CDMA, EVDO

CALCulate:STATistics:NSAMples

This command sets the number of measurement points to be acquired for the statistical

measurement functions.

Parameter

100 to 1E9

Example

CALC:STAT:NSAM 500

Sets the num ber of measurem ent points to be acquired to 500 .

Characteristics

*RST value: 100000

SCPI: device–specific

Mode

A, CATV, CDMA, EVDO

CALCulate:STATistics:PRESet

This command resets the scaling of the X and Y axes in a statistical measurement. The

following values are set:

x–axis ref level: –20 dBm

x–axis range APD: 100 dB

x–axis range CCDF: 20 dB

y–axis upper limit: 1.0

y–axis lower limit: 1E–6

This command is an event and therefore has no *RST value and no query.

Example

CALC:STAT:PRES

Resets the scaling for statistical functions

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, CATV, CDMA, EVDO

CALCulate Subsystem R&S FSL

1300.2519.12 6.114 E-11

CALCulate:STATistics:RESult<1...6>?

This command reads out the results of statistical measurements of a recorded trace. The trace

is selected with the numeric suffix <1...6> attached to RESult.

Parameter

The required result is selected via the following parameters:

MEAN Average (=RMS) power in dBm measured during the measurement time.

PEAK Peak power in dBm measured during the measurement time.

CFACtor Determined CREST factor (= ratio of peak power to average power) in dB.

ALL Results of all three measurements mentioned before, separated by commas:

Example

CALC:STAT:RES2? ALL

Reads out the three measurement results of trace 2. Example of answer string:

5.56,19.25,13.69 i.e. mean power: 5.56 dBm, peak power 19.25 dBm, CREST factor 13.69 dB

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, CATV, CDMA, EVDO

CALCulate:STATistics:SCALe:AUTO

This command optimizes the level setting of the instrument depending on the measured peak

power, in order to obtain maximum instrument sensitivity.

To obtain maximum resolution, the level range is set as a function of the measured spacing

between peak power and the minimum power for the APD measurement and of the spacing

between peak power and mean power for the CCDF measurement. In addition, the probability

scale for the number of test points is adapted.

This command is an event and therefore has no *RST value and no query.

Note: Subsequent commands have to be synchronized with *WAI,*OPC or *OPC? to the end

of the auto range process which would otherwise be aborted.

Parameter

ONCE

Example

CALC:STAT:SCAL:AUTO ONCE;*WAI

Adapts the level setting for statistical measurements.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, CATV, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.115 E-11

CALCulate:STATistics:SCALe:X:RANGe

This command defines the level range for the x–axis of the measurement diagram. The setting

is identical to the level range setting defined with the

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe] command.

Parameter

10dB to 200dB

Example

CALC:STAT:SCAL:X:RANG 20dB

Characteristics

*RST value: 100dB

SCPI: device–specific

Mode

A, CATV, CDMA, EVDO

CALCulate:STATistics:SCALe:X:RLEVel

This command defines the reference level for the x–axis of the measurement diagram. The

setting is identical to the reference level setting using the

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel command.

With the reference level offset <> 0 the indicated value range of the reference level is modified

by the offset.

The unit depends on the setting performed with CALCulate<1|2>:UNIT:POWer.

Parameter

–120dBm to 20dBm

Example

CALC:STAT:SCAL:X:RLEV –60dBm

Characteristics

*RST value: –20dBm

SCPI: device–specific

Mode

A, CATV, CDMA, EVDO

CALCulate:STATistics:SCALe:Y:LOWer

This command defines the lower limit for the y–axis of the diagram in statistical measurements.

Since probabilities are specified on the y–axis, the entered numeric values are dimensionless.

Parameter

1E–9 to 0.1

Example

CALC:STAT:SCAL:Y:LOW 0.001

Characteristics

*RST value: 1E–6

SCPI: device–specific

Mode

A, CATV, CDMA, EVDO

CALCulate Subsystem R&S FSL

1300.2519.12 6.116 E-11

CALCulate:STATistics:SCALe:Y:UNIT

This command defines the scaling type of the y–axis.

This command is available from firmware version 1.80.

Parameter

PCT | ABS

Example

CALC:STAT:SCAL:Y:UNIT PCT

Sets the percentage scale.

Characteristics

RST value: ABS

SCPI: device–specific

Mode

A, EVDO

CALCulate:STATistics:SCALe:Y:UPPer

This command defines the upper limit for the y–axis of the diagram in statistical measurements.

Since probabilities are specified on the y–axis, the entered numeric values are dimensionless.

Parameter

1E–8 to 1.0

Example

CALC:STAT:Y:UPP 0.01

Characteristics

*RST value: 1.0

SCPI: device–specific

Mode

A, CATV, CDMA, EVDO

R&S FSL CALCulate Subsystem

1300.2519.12 6.117 E-11

CALCulate:THReshold Subsystem

The CALCulate:THReshold subsystem controls the threshold value for the maximum/minimum search

of markers.

Commands of the CALCulate:THReshold Subsystem

–CALCulate<1|2>:THReshold

–CALCulate<1|2>:THReshold:STATe

CALCulate<1|2>:THReshold

This command defines the threshold value for the maximum/minimum search of markers with

marker search functions. The associated display line is automatically switched on.

The numeric suffixes <1|2> are not relevant.

Parameter

MINimum to MAXimum (depending on current unit)

Example

CALC:THR –82DBM

Sets the threshold value to –82 dBm.

Characteristics

*RST value: – (STATe to OFF)

SCPI: device–specific

Mode

A, ADEMOD, SPECM

CALCulate<1|2>:THReshold:STATe

This command switches on or off the threshold line. The unit depends on the setting performed

with CALCulate<1|2>:UNIT:POWer.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

CALC:THR:STAT ON

Switches on the threshold line.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, ADEMOD, SPECM

CALCulate Subsystem R&S FSL

1300.2519.12 6.118 E-11

CALCulate:TLINe Subsystem

The CALCulate:TLINe subsystem defines the position of the time lines.

Commands of the CALCulate:TLINe Subsystem

–CALCulate<1|2>:TLINe<1|2>

–CALCulate<1|2>:TLINe<1|2>:STATe

CALCulate<1|2>:TLINe<1|2>

This command defines the position of the time lines that mark the times.

The numeric suffixes <1|2> are not relevant.

Parameter

0to 1000s

Example

CALC:TLIN 10ms

Characteristics

*RST value: – (STATe to OFF)

SCPI: device–specific

Mode

A–T

CALCulate<1|2>:TLINe<1|2>:STATe

This command switches the time line on or off.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

CALC:TLIN2:STAT ON

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–T

R&S FSL CALCulate Subsystem

1300.2519.12 6.119 E-11

CALCulate:UNIT Subsystem

The CALCulate:UNIT subsystem defines the units for the parameters that can be set and the

measurement results.

Commands of the CALCulate:UNIT Subsystem

–CALCulate<1|2>:UNIT:POWer

CALCulate<1|2>:UNIT:POWer

This command selects the unit for power.

The numeric suffixes <1|2> are not relevant.

Parameter

Example

CALC:UNIT:POW DBM

Sets the power unit to dBm.

Characteristics

*RST value: dBm

SCPI: device–specific

Mode

CALibration Subsystem R&S FSL

1300.2519.12 6.120 E-11

CALibration Subsystem

The commands of the CALibration subsystem determine the data for system error correction in the

instrument.

Commands of the CALibration Subsystem

–CALibration[:ALL]?

–CALibration:ABORt

–CALibration:RESult?

–CALibration:STATe

CALibration[:ALL]?

This command initiates the acquisition of system error correction data. A "0" is returned if the

acquisition was successful.

Note: During the acquisition of correction data the instrument does not accept any remote

control commands.

In order to recognize when the acquisition of correction data is completed, the MAV bit in the

status byte can be used. If the associated bit is set in the Service Request Enable Register, the

instrument generates a service request after the acquisition of correction data has been

completed.

Example

*CLS

Resets the status management.

*SRE 16

Enables MAV bit in the Service Request Enable Register.

*CAL?

Starts the correction data recording, and then a service request is generated.

Characteristics

*RST value: -

SCPI: conform

Mode

all

R&S FSL CALibration Subsystem

1300.2519.12 6.121 E-11

CALibration:ABORt

This command has no effect, but is implemented to provide compatibility with the FSP family.

The collection of self alignment data can only be aborted via manual operation. For details refer

to chapter 4 "Instrument Functions - Basic Settings", section "Instrument Setup and Interface

Configuration - SETUP Key" - "Alignment".

This command is an event and therefore has no *RST value and no query.

Example

CAL:ABOR

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

CALibration:RESult?

This command outputs the results of the correction data acquisition. The lines of the result table

are output as string data separated by commas:

Total Calibration Status: PASSED,Date (dd/mm/yyyy): 12/07/2004,

Time: 16:24:54,Runtime: 00.06

Example

CAL:RES?

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

CALibration:STATe

This command determines whether the current calibration data are taken into account by the

instrument (ON) or not (OFF).

Parameter

ON | OFF

Example

CAL:STAT OFF

Sets up the instrument to ignore the calibration data.

Characteristics

*RST value: -

SCPI: conform

Mode

all

DIAGnostic Subsystem R&S FSL

1300.2519.12 6.122 E-11

DIAGnostic Subsystem

The DIAGnostic subsystem contains the commands which support instrument diagnostics for

maintenance, service and repair. In accordance with the SCPI standard, all of these commands are

device-specific.

Commands of the DIAGnostic Subsystem

–DIAGnostic<1|2>:SERVice:BIOSinfo?

–DIAGnostic<1|2>:SERVice:HWINfo?

–DIAGnostic<1|2>:SERVice:INPut[:SELect]

–DIAGnostic<1|2>:SERVice:INPut:PULSed[:STATe]

–DIAGnostic<1|2>:SERVice:INPut:PULSed:PRATe

–DIAGnostic<1|2>:SERVice:NSOurce (option Additional Interfaces, B5)

–DIAGnostic<1|2>:SERVice:SFUNction

–DIAGnostic<1|2>:SERVice:STESt:RESult?

DIAGnostic<1|2>:SERVice:BIOSinfo?

This command reads the CPU board BIOS version and returns it as ASCII string.

The numeric suffixes <1|2> are irrelevant for this command.

Example

DIAG:SERV:BIOS?

Returns the BIOS version.

Return values (example)

47.11

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

DIAGnostic<1|2>:SERVice:HWINfo?

This command queries the hardware information.

The numeric suffixes <1|2> are irrelevant for this command.

Return values

...

Table lines are output as string data and are separated by commas. The individual columns of

the table are separated from each other by |.

R&S FSL DIAGnostic Subsystem

1300.2519.12 6.123 E-11

Example

DIAG:SERV:HWIN?

Queries the hardware information.

"FRONTEND|100001/003|1300.3009|03|01|00|00",

"MOTHERBOARD|123456/002|1300.3080|02|00|00|00",

...

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

DIAGnostic<1|2>:SERVice:INPut[:SELect]

This command toggles between the RF input on the front panel and the internal 65.83 MHz

reference signal.

Parameter

CALibration | RF | TG

Example

DIAG:SERV:INP CAL

Characteristics

*RST value: RF

SCPI: device-specific

Mode

all

DIAGnostic<1|2>:SERVice:INPut:PULSed[:STATe]

This command has no effect (only the comb generator is available), but is implemented to

provide compatibility with the FSP family.

Parameter

ON | OFF

Example

DIAG:SERV:INP:PULS ON

Characteristics

*RST value: ON

SCPI: conform

Mode

all

DIAGnostic Subsystem R&S FSL

1300.2519.12 6.124 E-11

DIAGnostic<1|2>:SERVice:INPut:PULSed:PRATe

This command sets the comb generator frequency. This command only takes effect, if the internal

reference signal is selected for calibration (DIAGnostic<1|2>:SERVice:INPut[:SELect]).

Parameter

COMB1 65.8333 MHz / 1

COMB64 65.8333 MHz / 64

COMB65 65.8333 MHz / 65

Example

DIAG:SERV:INP:PULS:PRAT COMB64

Sets the comb generator frequency to

1of 65.8333 MHz.

Characteristics

*RST value: COMB1

SCPI: conform

Mode

all

DIAGnostic<1|2>:SERVice:NSOurce (option Additional Interfaces, B5)

This command switches the 28 V supply of the noise source at the rear panel on or off.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

DIAG:SERV:NSO ON

Characteristics

*RST value: OFF

SCPI: device-specific

Mode

all

R&S FSL DIAGnostic Subsystem

1300.2519.12 6.125 E-11

DIAGnostic<1|2>:SERVice:SFUNction

This command activates a service function which can be selected by indicating the five

parameters: function group number, board number, function number, parameter 1 and

parameter 2 (see service manual). The contents of the parameter string are identical to the code

to be entered in the edit dialog box of manual operation.

The entry of a service function is accepted only if the system password level 1 or level 2 has

been entered previously (SYSTem:PASSword[:CENable]).

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

Example

DIAG:SERV:SFUN 2.0.2.12.1

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

DIAGnostic<1|2>:SERVice:STESt:RESult?

This command reads the results of the self test out of the instrument. The lines of the result

table are output as string data separated by commas:

"Total Selftest Status: PASSED","Date (dd/mm/yyyy): 09/07/2004

TIME: 16:24:54","Runtime: 00:06","...

The numeric suffixes <1|2> are irrelevant for this command.

Example

DIAG:SERV:STES:RES?

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

DISPlay Subsystem R&S FSL

1300.2519.12 6.126 E-11

DISPlay Subsystem

The DISPLay subsystem controls the selection and presentation of textual and graphic information as

well as of measurement data on the display.

Commands of the DISPlay Subsystem

–DISPlay:ANNotation:FREQuency

–DISPlay:CMAP<1...26>:DEFault<1|2>

–DISPlay:CMAP<1...26>:HSL

–DISPlay:CMAP<1...26>:PDEFined

–DISPlay:FORMat

–DISPlay:LOGO

–DISPlay:PSAVe[:STATe]

–DISPlay:PSAVe:HOLDoff

–DISPlay[:WINDow<1|2>]:SIZE

–DISPlay[:WINDow<1|2>]:TEXT[:DATA]

–DISPlay[:WINDow<1|2>]:TEXT:STATe

–DISPlay[:WINDow<1|2>]:TIME

–DISPlay[:WINDow<1|2>]:TRACe<1...6>[:STATe]

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE:HCONtinuous

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:X:SPACing

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y:SPACing

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:MODE

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel:OFFSet

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition (models with tracking generator)

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue (models with tracking generator)

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue:AUTO

Further Information

–CMAP suffix assignment

R&S FSL DISPlay Subsystem

1300.2519.12 6.127 E-11

CMAP suffix assignment

Each numeric suffix of CMAP is assigned one or several graphical elements which can be

modified by varying the corresponding color setting. The following assignment applies:

Suffix Description

CMAP1 Background

CMAP2 Grid

CMAP3 Common Text

CMAP4 Check Status OK

CMAP5 Check Status Error

CMAP6 Text Special 1

CMAP7 Text Special 2

CMAP8 Trace 1

CMAP9 Trace 2

CMAP10 Trace 3

CMAP11 Marker Info Text

CMAP12 Limit Lines

CMAP13 Limit and Margin Check - "Pass"

CMAP14 Limit and Margin Check - "Fail"

CMAP15 Softkey Text

CMAP16 Softkey Background

CMAP17 Selected Field Text

CMAP18 Selected Field Background

CMAP19 Softkey 3D Bright Part

CMAP20 Softkey 3D Dark Part

CMAP21 Softkey State "On"

CMAP22 Softkey State "Dialog open"

CMAP23 Softkey Text Disabled

CMAP24 Logo

CMAP25 Trace 4

CMAP26 Grid - Minorlines

DISPlay:ANNotation:FREQuency

This command switches the x-axis annotation on or off.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

DISP:ANN:FREQ OFF

Characteristics

*RST value: ON

SCPI: conform

Mode

all

DISPlay Subsystem R&S FSL

1300.2519.12 6.128 E-11

DISPlay:CMAP<1...26>:DEFault<1|2>

This command resets the screen colors of all display items to their default settings. Two default

settings DEFault1 and DEFault2 are available. The numeric suffix of CMAP is irrelevant.

This command is an event and therefore has no query and no *RST value.

This command is available from firmware version 1.10.

Example

DISP:CMAP:DEF2

Selects default setting 2 for setting the colors.

Characteristics

*RST value: -

SCPI: conform

Mode

all

DISPlay:CMAP<1...26>:HSL

This command defines the color table of the instrument.

For the numeric suffix assignment of CMAP refer to "CMAP suffix assignment" on page 6.127.

The set values are not changed by *RST.

This command is available from firmware version 1.10.

Parameter

hue = TINT

sat = SATURATION

lum = BRIGHTNESS

The value range is 0 to 1 for all parameters.

Example

DISP:CMAP2:HSL 0.3,0.8,1.0

Changes the grid color.

Characteristics

*RST value: -

SCPI: conform

Mode

all

DISPlay:CMAP<1...26>:PDEFined

This command defines the color table of the instrument using predefined color values. Each

numeric suffix of CMAP is assigned to one or several graphical elements which can be modified

by varying the corresponding color setting.

For the numeric suffix assignment of CMAP refer to "CMAP suffix assignment" on page 6.127.

The values set are not changed by *RST.

This command is available from firmware version 1.10.

Parameter

R&S FSL DISPlay Subsystem

1300.2519.12 6.129 E-11

Example

DISP:CMAP2:PDEF GRE

Characteristics

*RST value: -

SCPI: conform

Mode

all

DISPlay:FORMat

This command has no effect but is implemented for reasons of compatibility with the FSP family.

It switches the measurement result display between FULL SCREEN and SPLIT SCREEN.

This command is available from firmware version 1.10.

Parameter

SINGle | SPLit

Example

DISP:FORM SPL

Switches the display to 2 measurement windows.

Characteristics

*RST value: SINGle

SCPI: device-specific

Mode

DISPlay:LOGO

This command switches the company logo on the screen on or off.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

DISP:LOGO OFF

Characteristics

*RST value: ON

SCPI: device-specific

Mode

all

DISPlay Subsystem R&S FSL

1300.2519.12 6.130 E-11

DISPlay:PSAVe[:STATe]

This command switches on or off the power-save mode of the display. With the power-save

mode activated the display including backlight is completely switched off after the elapse of the

response time (see DISPlay:PSAVe:HOLDoff command).

Note: This mode is recommended for preserving the display especially if the instrument is

exclusively operated via remote control.

This command is available from firmware version 1.20.

Parameter

ON | OFF

Example

DISP:PSAVe ON

Switches on the power-save mode.

Characteristics

*RST value: OFF

SCPI: device-specific

Mode

all

DISPlay:PSAVe:HOLDoff

This command sets the holdoff time for the power-save mode of the display. The available value

range is 1 to 60 minutes, the resolution 1 minute. The entry is dimensionless.

This command is available from firmware version 1.20.

Parameter

1to 60

Example

DISP:PSAV:HOLD 30

Characteristics

*RST value: 15

SCPI: device-specific

Mode

all

DISPlay[:WINDow<1|2>]:SIZE

This command configures the measurement display.

Channel and adjacent–channel power measurements: Only "1" is allowed as a numeric suffix.

Spectrum Emission Mask and Spurious Emissions measurements: The numeric suffix <1|2>

selects the item that is displayed in full size; 1 for measurement diagram, 2 for list

Parameter

LARGe Channel and adjacent–channel power measurements: diagram in full screen.

Spectrum Emission Mask and Spurious Emissions measurements: diagram or

list in full screen, depending on the value of the numeric suffix.

SMALl split screen (diagram and list)

R&S FSL DISPlay Subsystem

1300.2519.12 6.131 E-11

Example

DISP:SIZE LARG

Displays the measurement diagram in full screen size.

DISP:WIND2:SIZE LARG

Displays the list in full screen size.

Characteristics

*RST value: SMALl

SCPI: device–specific

Mode

A, ADEMOD

DISPlay[:WINDow<1|2>]:TEXT[:DATA]

This command defines a comment (max. 20 characters) which can be displayed on the screen.

This command is available from firmware version 1.10.

Parameter

Example

DISP:WIND:TEXT 'Noise Measurement'

Defines the screen title.

Characteristics

*RST value: "" (empty)

SCPI: conform

Mode

all

DISPlay[:WINDow<1|2>]:TEXT:STATe

This command switches on or off the display of the comment (screen title).

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

DISP:TEXT:STAT ON

Switches on the title.

Characteristics

*RST value: OFF

SCPI: conform

Mode

all

DISPlay Subsystem R&S FSL

1300.2519.12 6.132 E-11

DISPlay[:WINDow<1|2>]:TIME

This command switches on or off the screen display of date and time. The numeric suffix in

WINDow<1| 2> is irrelevant.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

DISP:TIME ON

Characteristics

*RST value: OFF

SCPI: device-specific

Mode

all

DISPlay[:WINDow<1|2>]:TRACe<1...6>[:STATe]

This command switches on or off the display of the corresponding trace.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

DISP:TRAC3 ON

Characteristics

*RST value: ON for TRACe1, OFF for TRACe2 to 6

SCPI: conform

Mode

all

DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE

This command defines the type of display and the evaluation of the traces. WRITE corresponds

to the Clr/Write mode of manual operation. The trace is switched off (= BLANK in manual

operation) with DISPlay[:WINDow<1|2>]:TRACe<1...6>[:STATe].

The number of measurements for AVERage, MAXHold and MINHold is defined with the

[SENSe<1|2>:]AVERage:COUNt or [SENSe<1|2>:]SWEep:COUNt commands. It should be

noted that synchronization to the end of the indicated number of measurements is only possible

in single sweep mode.

If calculation of average values is active, selection between logarithmic and linear averaging is

possible. For more detail see [SENSe<1|2>:]AVERage:TYPE command.

The numeric suffixes <1|2> are irrelevant.

Parameter

For details on trace modes refer to chapter "Instrument Functions", section "Trace mode

overview".

R&S FSL DISPlay Subsystem

1300.2519.12 6.133 E-11

Example

SWE:CONT OFF

Switching to single sweep mode.

SWE:COUN 16

Sets the number of measurements to 16.

DISP:TRAC3:MODE MAXH

Switches on the calculation of the for trace 3.

INIT;*WAI

Starts the measurement and waits for the end of the 16 sweeps.

Characteristics

*RST value: WRITe for TRACe1, STATe OFF for TRACe2/3/4/5/6

SCPI: device–specific

Mode

all

DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE:HCONtinuous

This command defines, whether traces in Min Hold, Max Hold and Average mode are reset after

parameter change or not.

Normally, the measurement is started anew after parameter changes, before the measurement

results are evaluated (e.g. using a marker). In all cases that require a new measurement after

parameter changes, the trace is reset automatically to avoid false results (e.g. with span

changes). For applications that require no reset after parameter changes, the automatic reset

can be switched off.

The numeric suffixes <1|2> are irrelevant.

Parameter

OFF After certain parameter changes the traces are reset.

ON The automatic reset is switched off.

Example

DISP:WIND:TRAC3:MODE:HCON ON

Switches off the reset function.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, CATV

DISPlay[:WINDow<1|2>]:TRACe<1...6>:X:SPACing

This command toggles between linear and logarithmic scaling of the x-axis.

Parameter

LINear | LOGarithmic

Example

DISP:TRAC:X:SPAC LOG

Sets the x-axis to a logarithmic scale

DISPlay Subsystem R&S FSL

1300.2519.12 6.134 E-11

Characteristics

*RST value: LOG

SCPI: conform

Mode

A-F

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y:SPACing

This command selects the scaling for the level display range.

The numeric suffixes <1|2> and <1...6> are irrelevant.

Parameter

LOGarithmic Selects logarithmic scaling.

LINear Selects linear scaling in %.

LDB Selects linear scaling in dB.

Example

DISP:TRAC:Y:SPAC LIN

Characteristics

*RST value: LOGarithmic

SCPI: conform

Mode

A, ADEMOD, CATV

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]

This command defines the display range of the y–axis (level axis) with logarithmic scaling

(DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y:SPACing).

For linear scaling, the display range is fixed and cannot be modified.

The numeric suffixes <1|2> and <1...6> are irrelevant.

Parameter

10 dB to 200 dB or value in Hz

Example

DISP:TRAC:Y 110dB

Characteristics

*RST value: 100dB

SCPI: device–specific

Mode

all

R&S FSL DISPlay Subsystem

1300.2519.12 6.135 E-11

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:MODE

This command defines the scale type of the y–axis (absolute or relative).

When SYSTem:DISPlay:UPDate is set to OFF, this command has no immediate effect on the

screen. The numeric suffixes <1|2> and <1...6> are irrelevant.

Parameter

ABSolute | RELative

Example

DISP:TRAC:Y:MODE REL

Characteristics

*RST value: ABS

SCPI: device–specific

Mode

all

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel

This command defines the reference level.

With the reference level offset <> 0, the indicated value range of the reference level is modified

by the offset.

The unit depends on the setting defined with CALCulate<1|2>:UNIT:POWer.

The numeric suffixes <1|2> and <1...6> are irrelevant.

Parameter

<numeric_value> in dBm, range specified in data sheet

Example

DISP:TRAC:Y:RLEV –60dBm

Characteristics

*RST value: –20dBm

SCPI: conform

Mode

A, CATV, CDMA, EVDO, WCDMA

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel:OFFSet

This command defines the offset of the reference level.

The numeric suffixes <1|2> and <1...6> are irrelevant.

Parameter

–200dB to 200dB

Example

DISP:TRAC:Y:RLEV:OFFS –10dB

DISPlay Subsystem R&S FSL

1300.2519.12 6.136 E-11

Characteristics

*RST value: 0dB

SCPI: conform

Mode

A, CATV, CDMA, EVDO, PSM, WCDMA, WLAN

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition (models with tracking generator)

This command requires a tracking generator and active normalization in the Tracking

Generator mode. It defines the position of the reference value.

The numeric suffixes <1|2> and <1...6> are irrelevant.

Parameter

0to 100PCT

Example

DISP:TRAC:Y:RPOS 50PCT

Characteristics

*RST value:

100 PCT Spectrum Analyzer mode

50 PCT Tracking Generator mode

SCPI: conform

Mode

A, ADEMOD, BT, CATV, CDMA, EVDO, WCDMA

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue (models with tracking generator)

This command requires a tracking generator and active normalization in the Tracking

Generator mode. The command defines the power value assigned to the reference position.

The numeric suffixes <1|2> and <1...6> are irrelevant.

Parameter

<numeric_value>

Example

DISP:TRAC:Y:RVAL –20dBm

(Analyzer)

DISP:TRAC:Y:RVAL 0

Sets the power value assigned to the reference position to 0 dB (tracking generator)

Characteristics

*RST value: 0 dB, coupled to reference level

SCPI: device–specific

Mode

A, ADEMOD, BT, CDMA, EVDO

R&S FSL DISPlay Subsystem

1300.2519.12 6.137 E-11

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue:AUTO

This command defines whether the reference value for the y–axis is coupled to the reference

level (default) or not.

The numeric suffixes <1|2> and <1...6> are irrelevant.

Parameter

ON | OFF

Example

DISP:TRAC:Y:RVAL:AUTO ON

Characteristics

*RST value: ON

SCPI: device–specific

Mode

A, CDMA, EVDO

FORMat Subsytem R&S FSL

1300.2519.12 6.138 E-11

FORMat Subsytem

The FORMat subsystem specifies the data format of the data transmitted from and to the instrument.

Commands of the FORMat Subsystem

–FORMat[:DATA]

–FORMat:DEXPort:DSEParator

FORMat[:DATA]

This command specifies the data format for the data transmitted from the instrument to the

control PC. It is used for the transmission of trace data. The data format of trace data received

by the instrument is automatically recognized, regardless of the format which is programmed. In

the spectrum mode, the format setting REAL, 32 is used for the binary transmission of trace

data (see also TRACe<1|2>[:DATA] command).

Parameter

ASCii | REAL| UINT | MATLAB [,8 | 32]

ASCII data are transmitted in plain text, separated by commas. REAL data are transmitted as

32-bit IEEE 754 floating-point numbers in the "definite length block format". The format UINT is

only used in operating mode vector signal analysis, for the symbol table.

Example

FORM REAL,32

FORM ASC

FORM UINT,8

Characteristics

*RST value: ASCII

SCPI: conform

Mode

all

FORMat:DEXPort:DSEParator

This command defines which decimal separator (decimal point or comma) is to be used for

outputting measurement data to the file in ASCII format. Different languages of evaluation

programs (e.g. MS Excel) can thus be supported.

Parameter

POINt | COMMA

Example

FORM:DEXP:DSEP POIN

Sets the decimal point as separator.

Characteristics

*RST value: – (factory setting is POINt; *RST does not affect setting)

SCPI: device–specific

Mode

all

R&S FSL HCOPy Subsystem

1300.2519.12 6.139 E-11

HCOPy Subsystem

The HCOPy subsystem controls the output of display information for documentation purposes on output

devices or files. The instrument allows two independent printer configurations which can be set

separately with the numeric suffix <1|2>.

Commands of the HCOPy Subsystem

–HCOPy[:IMMediate<1|2>]

–HCOPy[:IMMediate<1|2>]:NEXT

–HCOPy:ABORt

–HCOPy:CMAP<1...26>:DEFault

–HCOPy:CMAP<1...26>:HSL

–HCOPy:CMAP<1...26>:PDEFined

–HCOPy:DESTination<1|2>

–HCOPy:DEVice:COLor

–HCOPy:DEVice:LANGuage<1|2>

–HCOPy:ITEM:ALL

–HCOPy:ITEM:WINDow<1|2>:TEXT

–HCOPy:ITEM:WINDow<1|2>:TRACe:STATe

–HCOPy:PAGE:ORIentation<1|2>

HCOPy[:IMMediate<1|2>]

This command starts a hardcopy output. The numeric suffix selects which printer configuration

(device 1 or 2) is to be used for the hardcopy output. If there is no suffix, configuration 1 is

automatically selected.

This command is an event and therefore has no *RST value and no query.

Example

HCOP:DEV:LANG BMP

Selects the data format.

HCOP:DEST 'MMEM'

Directs the hardcopy to a file.

MMEM:NAME 'C:\R_S\instr\user\Print.bmp'

Selects the file name. If the file Print.bmp already exists, it is replaced.

HCOP

Saves the hardcopy output into the file Print.bmp.

Characteristics

*RST value: -

SCPI: conform

Mode

all

HCOPy Subsystem R&S FSL

1300.2519.12 6.140 E-11

HCOPy[:IMMediate<1|2>]:NEXT

This command starts a hardcopy output. The numeric suffix selects which printer configuration

(device 1 or 2) is to be used for the hardcopy output. If there is no suffix, configuration 1 is

automatically selected. If the output is printed to a file (see HCOPy:DESTination<1|2>

command), the file name used in the last saving process is automatically counted up to the next

unused name.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.70.

Example

HCOP:DEV:LANG BMP

Selects the data format.

HCOP:DEST 'MMEM'

Directs the hardcopy to a file.

MMEM:NAME 'C:\R_S\instr\user\Print.bmp'

Selects the file name.

HCOP

Saves the hardcopy output into the file Print.bmp.

HCOP:NEXT

Saves the hardcopy output into the file Print_001.bmp.

HCOP:NEXT

Saves the hardcopy output into the file Print_002.bmp.

Characteristics

RST value: -

SCPI: device-specific

Mode

all

HCOPy:ABORt

This command aborts a running hardcopy output.

This command is an event and therefore has no *RST value and no query.

Example

HCOP:ABOR

Characteristics

*RST value: -

SCPI: conform

Mode

all

R&S FSL HCOPy Subsystem

1300.2519.12 6.141 E-11

HCOPy:CMAP<1...26>:DEFault

This command sets the colors for a printout or hardcopy. The numeric suffix in CMAP is not

significant.

This command is an event and therefore has no query and no *RST value.

This command is available from firmware version 1.10.

Parameter

1current screen colors with the background in white and the grid in black.

2optimized color set

3user defined color set

4current screen colors without any changes (setting for hardcopies)

Example

HCOP:CMAP:DEF2

Selects the optimized color set for the color settings of a printout or a hardcopy.

Characteristics

*RST value: -

SCPI: conform

Mode

all

HCOPy:CMAP<1...26>:HSL

This command defines the color table in user defined colors.

To each numeric suffix of CMAP is assigned one or several picture elements which can be

modified by varying the corresponding color setting. For details on the CMAP assignment refer

to "CMAP suffix assignment" on page 6.127.

The values set are not changed by *RST.

This command is available from firmware version 1.10.

Parameter

hue = tint

sat = saturation

lum = brightness

The value range is 0 to 1 for all parameters.

Example

HCOP:CMAP2:HSL 0.3,0.8,1.0

Changes the grid color

Characteristics

*RST value: -

SCPI: conform

Mode

all

HCOPy Subsystem R&S FSL

1300.2519.12 6.142 E-11

HCOPy:CMAP<1...26>:PDEFined

This command defines the color table in user defined colors using predefined color values. To

each numeric suffix of CMAP is assigned one or several picture elements which can be modified

by varying the corresponding color setting. For details on the CMAP assignment refer to "CMAP

suffix assignment" on page 6.127.

The values set are not changed by *RST.

This command is available from firmware version 1.10.

Parameter

Example

HCOP:CMAP2:PDEF GRE

Characteristics

*RST value: -

SCPI: conform

Mode

all

HCOPy:DESTination<1|2>

This command selects the printer output medium (Disk, Printer or Clipboard) associated with

configuration 1 or 2.

Note: The type of instrument is selected with SYSTem:COMMunicate:PRINter:SELect

<1|2>,which will automatically select a default output medium. Therefore the

HCOPy:DESTination<1|2> command should always be sent after setting the device

type.

Parameter

MMEM Directs the hardcopy to a file. The MMEMory:NAME command

defines the file name. All formats can be selected for

HCOPy:DEVice:LANGuage<1|2>.

SYST:COMM:PRIN Directs the hardcopy to the printer. The printer is selected with

the SYSTem:COMMunicate:PRINter:SELect <1|2>

command.

GDI should be selected for

HCOPy:DEVice:LANGuage<1|2>.

SYST:COMM:CLIP Directs the hardcopy to the clipboard. EWMF should be

selected for HCOPy:DEVice:LANGuage<1|2>.

Example

SYST:COMM:PRIN:SEL2 'LASER on LPT1'

Selects the printer and output medium for device 2.

HCOP:DEST2 'SYST:COMM:PRIN'

Selects the printer interface as device 2.

R&S FSL HCOPy Subsystem

1300.2519.12 6.143 E-11

Characteristics

*RST value: SYST:COMM:CLIP

SCPI: conform

Mode

all

HCOPy:DEVice:COLor

This command selects between color and monochrome hardcopy of the screen.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

HCOP:DEV:COL ON

Characteristics

*RST value: OFF

SCPI: conform

Mode

all

HCOPy:DEVice:LANGuage<1|2>

This command determines the data format of the printout.

Parameter

GDI Graphics Device Interface:

Default format for the output to a printer configured under Windows.

Must be selected for the output to the printer interface.

Can be used for the output to a file. The printer driver configured

under Windows is used in this case and a printer-specific file format is

thus generated.

(see also HCOPy:DESTination<1|2> command)

WMF, EWMF WINDOWS Metafile and Enhanced Metafile Format:

Data formats for output files which can be integrated in corresponding

programs for documentation purposes at a later time. WMF can only

be used for output to a file and EWMF also for the output to the

clipboard.

(see also HCOPy:DESTination<1|2> command)

BMP, JPG,

PNG

Data format for output to files only.

Example

HCOP:DEV:LANG WMF

HCOPy Subsystem R&S FSL

1300.2519.12 6.144 E-11

Characteristics

*RST value: -

SCPI: conform

Mode

all

HCOPy:ITEM:ALL

This command selects the complete screen to be output.

The hardcopy output is always provided with comments, title, time and date. As an alternative to

the whole screen, e.g. only traces (HCOPy:ITEM:WINDow<1|2>:TRACe:STATe command)

can be output.

Example

HCOP:ITEM:ALL

Characteristics

*RST value: -

SCPI: conform

Mode

all

HCOPy:ITEM:WINDow<1|2>:TEXT

This command defines the comment text for the printout.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

<string> with a maximum of 100 characters; line feed by means of character @

Example

HCOP:ITEM:WIND:TEXT 'comment'

Characteristics

RST value: -

SCPI: device-specific

Mode

all

HCOPy:ITEM:WINDow<1|2>:TRACe:STATe

This command selects the output of the currently displayed trace.

The numeric suffixes <1|2> are irrelevant for this command.

Both the HCOPy:ITEM:WINDow<1|2>:TRACe:STATe command and the HCOPy:ITEM:ALL

command enable the output of the whole screen.

Parameter

ON | OFF

R&S FSL HCOPy Subsystem

1300.2519.12 6.145 E-11

Example

HCOP:ITEM:WIND:TRACe:STAT ON

Characteristics

*RST value: OFF

SCPI: device-specific

Mode

all

HCOPy:PAGE:ORIentation<1|2>

The command selects the format of the output (portrait and landscape) (hardcopy unit 1 or 2).

Note: The command is only available provided that the output device "printer"

(HCOPy:DESTination<1|2>) has been selected.

Parameter

LANDscape | PORTrait

Example

HCOP:PAGE:ORI LAND

Characteristics

*RST value: PORT

SCPI: conform

Mode

all

HCOPy:TDSTamp:STATe<1|2>

This command activates and deactivates if the time and date are on the printout.

The numeric suffixes <1|2> define the print device number.

Parameter

ON | OFF

Example

HCOP:TDST:STAT OFF

Deactivates the time and time for printouts.

HCOP:TDST:STAT?

Queries if time and date are activated or not.

Characteristics

*RST value: OFF

SCPI: device-specific

Mode

all

INITiate Subsystem R&S FSL

1300.2519.12 6.146 E-11

INITiate Subsystem

The INITiate subsystem is used to control the init–measurement function.

Commands of the INITiate Subsystem

–INITiate<1|2>[:IMMediate]

–INITiate<1|2>:CONMeas

–INITiate<1|2>:CONTinuous

–INITiate<1|2>:DISPlay

–INITiate<1|2>:ESPectrum

–INITiate<1|2>:SPURious

INITiate<1|2>[:IMMediate]

The command initiates a new measurement sequence.

With sweep count > 0 or average count > 0, this means a restart of the indicated number of

measurements. With trace functions MAXHold, MINHold and AVERage, the previous results are

reset on restarting the measurement.

In single sweep mode, synchronization to the end of the indicated number of measurements can

be achieved with the command *OPC,*OPC? or *WAI.In continuous–sweep mode,

synchronization to the sweep end is not possible since the overall measurement never ends.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

INIT:CONT OFF

Switches to single sweep mode.

DISP:WIND:TRAC:MODE AVER

Activates trace averaging.

SWE:COUN 20

Setting the sweep counter to 20 sweeps.

INIT;*WAI

Starts the measurement and waits for the end of the 20 sweeps.

Characteristics

*RST value: –

SCPI: conform

Mode

all

R&S FSL INITiate Subsystem

1300.2519.12 6.147 E-11

INITiate<1|2>:CONMeas

This command continues a stopped measurement at the current position in single sweep mode.

The function is useful especially for trace functions MAXHold, MINHold and AVERage, if the

previous results are not to be cleared with sweep count > 0 or average count > 0 on restarting

the measurement (INIT:IMMediate resets the previous results on restarting the measurement).

The single sweep mode is automatically switched on. Synchronization to the end of the

indicated number of measurements can then be performed with the commands *OPC,*OPC? or

*WAI.In the continuous sweep mode, synchronization to the sweep end is not possible since

the overall measurement "never" ends.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

INIT:CONT OFF

Switches to single sweep mode.

DISP:WIND:TRAC:MODE AVER

Switches on trace averaging.

SWE:COUN 20

Setting the sweep counter to 20 sweeps.

INIT;*WAI

Starts the measurement and waits for the end of the 20 sweeps.

INIT:CONM;*WAI

Continues the measurement (next 20 sequences) and waits for the end.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A, CATV, CDMA, EVDO

INITiate<1|2>:CONTinuous

This command determines whether the trigger system is continuously initiated (continuous) or

performs single measurements (single).

This setting refers to the sweep sequence (switching between continuous/single sweep).

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

INIT:CONT OFF

Switches the sequence single sweep.

INIT:CONT ON

Switches the sequence to continuous sweep.

Characteristics

*RST value: ON

SCPI: conform

Mode

all

INITiate Subsystem R&S FSL

1300.2519.12 6.148 E-11

INITiate<1|2>:DISPlay

This command switches the display during a single sweep measurement on (ON) or off (OFF).

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

INIT:CONT OFF

Switches to single sweep mode

INIT:DISP OFF

Sets the display behavior to OFF

INIT;*WAI

Starts the measurement with display switched off.

Characteristics

*RST value: ON

SCPI: device–specific

Mode

INITiate<1|2>:ESPectrum

This command starts a Spectrum Emission Mask measurement.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.80.

Example

INIT:ESP

Starts a Spectrum Emission Mask measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

R&S FSL INITiate Subsystem

1300.2519.12 6.149 E-11

INITiate<1|2>:SPURious

This command starts a Spurious Emissions measurement.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.80.

Example

INIT:SPUR

Starts a Spurious Emissions measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

INPut Subsystem R&S FSL

1300.2519.12 6.150 E-11

INPut Subsystem

The INPut subsystem controls the input characteristics of the RF inputs of the instrument.

Commands of the INPut Subsystem

–INPut<1|2>:ATTenuation

–INPut<1|2>:ATTenuation:AUTO

–INPut<1|2>:GAIN:STATe (option RF Preamplifier, B22)

–INPut<1|2>:IMPedance

–INPut<1|2>:UPORt[:VALue]?

–INPut<1|2>:UPORt:STATe

INPut<1|2>:ATTenuation

This command programs the input attenuator. To protect the input mixer against damage from

overloads, the setting 0 dB can be obtained by entering numerals, not by using the DEC

command.

The attenuation can be set in 5 dB steps. If the defined reference level cannot be set for the set

RF attenuation, the reference level will be adjusted accordingly.

In the default state with Spectrum Analyzer mode, the attenuation set on the step attenuator is

coupled to the reference level of the instrument. If the attenuation is programmed directly, the

coupling to the reference level is switched off.

Parameter

<numeric_value> in dB; range specified in data sheet

Example

INP:ATT 30dB

Sets the attenuation on the attenuator to 30 dB and switches off the coupling to the reference

level.

Characteristics

*RST value: 0 dB (AUTO is set to ON)

SCPI: conform

Mode

all

R&S FSL INPut Subsystem

1300.2519.12 6.151 E-11

INPut<1|2>:ATTenuation:AUTO

This command automatically couples the input attenuation to the reference level (state ON) or

switches the input attenuation to manual entry (state OFF).

Parameter

ON | OFF

Example

INP:ATT:AUTO ON

Couples the attenuation set on the attenuator to the reference level.

Characteristics

*RST value: ON

SCPI: conform

Mode

all

INPut<1|2>:GAIN:STATe (option RF Preamplifier, B22)

This command switches the preamplifier on or off. The preamplifier only has an effect below

6GHz.

Parameter

ON | OFF

Example

INP:GAIN:STAT ON

Switches on 20 dB preamplification.

Characteristics

*RST value: OFF

SCPI: conform

Mode

A, NF, CATV, WCDMA, CDMA, EVDO

INPut<1|2>:IMPedance

This command sets the nominal input impedance of the instrument. The set impedance is taken

into account in all level indications of results.

The setting 75 should be selected, if the 50 input impedance is transformed to a higher

impedance using a 75 adapter of the RAZ type (= 25 in series to the input impedance of

the instrument). The correction value in this case is 1.76 dB = 10 log ( 75/50).

Parameter

50 | 75

Example

INP:IMP 75

INPut Subsystem R&S FSL

1300.2519.12 6.152 E-11

Characteristics

*RST value: 50 

SCPI: conform

Mode

All

INPut<1|2>:UPORt[:VALue]?

This command queries the control lines of the user ports.

This command is a query and therefore has no *RST value.

Example

INP:UPOR?

Characteristics

RST value: –

SCPI: device–specific

Mode

all

INPut<1|2>:UPORt:STATe

This command toggles the control lines of the user ports between INPut and OUTPut. With ON,

the user port is switched to INPut, with OFF to OUTPut.

Parameter

ON | OFF

Example

INP:UPOR:STAT ON

Characteristics

RST value: ON

SCPI: device–specific

Mode

all

R&S FSL INSTrument Subsystem

1300.2519.12 6.153 E-11

INSTrument Subsystem

The INSTrument subsystem selects the operating mode of the unit either via text parameters or fixed

numbers.

Commands of the INSTrument Subsystem

–INSTrument[:SELect]

–INSTrument:NSELect

INSTrument[:SELect]

This command switches between the measurement modes by means of text parameters.

Parameter

SANalyzer spectrum analyzer

The parameters of the other measurement modes are included in the option descriptions.

Example

INST SAN

Switches the instrument to spectrum analyzer mode.

Characteristics

*RST value: SANalyzer

SCPI: conform

Mode

all

INSTrument:NSELect

This command switches between the measurement modes by means of numbers.

Parameter

1spectrum analyzer

The parameters of the other measurement modes are included in the option descriptions.

Example

INST:NSEL 1

Switches the instrument to spectrum analyzer mode.

Characteristics

*RST value: 1

SCPI: conform

Mode

all

MMEMory Subsystem R&S FSL

1300.2519.12 6.154 E-11

MMEMory Subsystem

The MMEMory (mass memory) subsystem provides commands which allow for access to the storage

media of the instrument and for storing and loading various instrument settings.

The various drives can be addressed via the "mass storage unit specifier" <msus> using the conven-

tional DOS syntax. The internal hard disk is addressed by "C:". For details on drives refer to chapter 4

"Instrument Functions - Basic Settings", section "Saving and Recalling Settings Files - FILE Key".

The file names <file_name> are indicated as string parameters with the commands being enclosed in

quotation marks. They also comply with DOS conventions.

DOS file names consist of max. 8 ASCII characters and an extension of up to three characters

separated from the file name by a dot "." Both, the dot and the extension are optional. The dot is not

part of the file name. DOS file names do not distinguish between uppercase and lowercase notation. All

letters and digits are permitted as well as the special characters "_", "^", "$", "~", "!", "#", "%", "&", "-",

"{", "}", "(", ")", "@" and "`". Reserved file names are CLOCK$, CON, AUX, COM1 to COM4, LPT1 to

LPT3, NUL and PRN.

The two characters "*" and "?" have the function of so-called "wildcards", i.e., they are variables for

selection of several files. The question mark "?" replaces exactly one character, the asterisk means any

of the remaining characters in the file name. "*.*" thus means all files in a directory.

Commands of the MMEMory Subsystem

–MMEMory:CATalog?

–MMEMory:CDIRectory

–MMEMory:CLEar:ALL

–MMEMory:CLEar:STATe

–MMEMory:COMMent

–MMEMory:COPY

–MMEMory:DATA

–MMEMory:DELete

–MMEMory:LOAD:AUTO

–MMEMory:LOAD:STATe

–MMEMory:MDIRectory

–MMEMory:MOVE

–MMEMory:MSIS

–MMEMory:NAME

–MMEMory:NETWork:MAP

–MMEMory:NETWork:DISConnect

–MMEMory:NETWork:UNUSeddrives?

–MMEMory:NETWork:USEDdrives?

–MMEMory:RDIRectory

–MMEMory:SELect[:ITEM]:ALL

–MMEMory:SELect[:ITEM]:DEFault

–MMEMory:SELect[:ITEM]:FINal

R&S FSL MMEMory Subsystem

1300.2519.12 6.155 E-11

–MMEMory:SELect[:ITEM]:HWSettings

–MMEMory:SELect[:ITEM]:LINes:ALL

–MMEMory:SELect[:ITEM]:NONE

–MMEMory:SELect[:ITEM]:SCData (models with tracking generator)

–MMEMory:SELect[:ITEM]:TRACe[:ACTive]

–MMEMory:SELect[:ITEM]:TRANsducer:ALL

–MMEMory:STORe<1|2>:LIST

–MMEMory:STORe<1|2>:PEAK

–MMEMory:STORe<1|2>:STATe

–MMEMory:STORe<1|2>:STATe:NEXT

–MMEMory:STORe<1|2>:TRACe

MMEMory:CATalog?

This command reads the indicated directory. According to DOS convention, wild card characters

can be entered in order to query e.g. a list of all files of a certain type.

This command is an event and therefore has no *RST value and no query.

Parameter

<path> = DOS Path name

The path name should be in conformance with DOS conventions and may also include the drive

name.

Example

MMEM:CAT? 'C:\R_S\Instr\user\*.DFL'

Returns all files in C:\R_S\Instr\user with extension ".DFL"

MMEM:CAT? 'C:\R_S\Instr\user\SPOOL?.WMF'

Returns all files in C:\R_S\Instr\user whose names start with SPOOL, have 6 letters and the

extension ".WMF".

Response value

List of file names in the form of strings separated by commas, i.e.

SPOOL1.WMF,SPOOL2.WMF,SPOOL3.WMF

Characteristics

*RST value: -

SCPI: conform

Mode

all

MMEMory Subsystem R&S FSL

1300.2519.12 6.156 E-11

MMEMory:CDIRectory

This command changes the current directory.

Parameter

<directory_name> = DOS path name

In addition to the path name, the indication of the directory may contain the drive name. The

path name complies with the DOS conventions.

Example

MMEM:CDIR 'C:\R_S\Instr\user'

Selects the directory C:\R_S\Instr\user.

Characteristics

*RST value: -

SCPI: conform

Mode

all

MMEMory:CLEar:ALL

This command deletes all settings files in the current directory. The current directory can be

selected with the MMEMory:CDIRectory command. The default directory is C:\R_S\instr\user.

This command is an event and therefore has no *RST value and no query.

Example

MMEM:CLE:ALL

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

MMEMory:CLEar:STATe

This command deletes the instrument settings file selected by <file_name>. All associated files

on the mass memory storage are cleared.

This command is an event and therefore has no *RST value and no query.

Parameter

1,<file_name>

with <file_name> = DOS file name without extension

The file name includes indication of the path and may also include the drive. The path name

complies with DOS conventions.

Example

MMEM:CLE:STAT 1,'TEST'

R&S FSL MMEMory Subsystem

1300.2519.12 6.157 E-11

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

MMEMory:COMMent

This command defines a comment (max. 60 characters) for a device setting to be stored.

Example

MMEM:COMM ’Setup for FM measurement’

Characteristics

*RST value: blank comment

SCPI: device-specific

Mode

MMEMory:COPY

This command copies the files indicated in <file_source> to the destination directory indicated

with <file_destination> or to the destination file indicated by <file_destination> if <file_source> is

just a file.

This command is an event and therefore has no *RST value and no query.

Parameter

<file_source>,<file_destination> = <file_name> = DOS file name

The indication of the file name may include the path and the drive name. The file names and

path information must be in accordance with the DOS conventions.

Example

MMEM:COPY 'C:\R_S\Instr\user\SETUP.CFG','E:'

Characteristics

*RST value: -

SCPI: conform

Mode

all

MMEMory:DATA

This command writes the block data contained in <block> into the file characterized by

<file_name>. The delimiter must be set to EOI to obtain error-free data transfer.

The associated query command reads the indicated file from the mass memory and transfers it

to the remote control computer. It should be noted that the buffer memory of the control

computer should be large enough to store the file. The setting of the delimiter is irrelevant in this

case.

The command is useful for reading stored settings files or trace data from the instrument or for

transferring them to the instrument.

MMEMory Subsystem R&S FSL

1300.2519.12 6.158 E-11

Parameter

<file_name>[,<block>]

<file_name> selects the file to be transferred

<block> binary data block with the following structure:

•character '#'

•digit for the length of the length information

•indicated number of digits as length information

(number of bytes) for the binary data themselves

•binary data with the indicated number of bytes

Example

MMEM:DATA 'TEST01.HCP,#216This is the file'

means: #2: the next 2 characters are the length indication; 16: number of subsequent binary

data bytes; This is the file: 16 bytes stored as binary data in the file TEST01.HCP.

MMEM:DATA? 'TEST01.HCP'

Transfers the file TEST01.HCP from the instrument to the control computer.

Characteristics

*RST value: -

SCPI: conform

Mode

all

MMEMory:DELete

This command deletes the indicated files.

Parameter

<file_name> = DOS file name

The indication of the file name contains the path and, optionally, the drive name. Indication of

the path complies with DOS conventions.

Example

MMEM:DEL 'TEST01.HCP'

The file TEST01.HCP is deleted.

Characteristics

*RST value: -

SCPI: conform

Mode

all

R&S FSL MMEMory Subsystem

1300.2519.12 6.159 E-11

MMEMory:LOAD:AUTO

This command defines which settings file is automatically loaded after the device is switched on. The

contents of the file are read after switching on the device and used to define the new device state.

The settings file defined as auto recall set can also be restored by the *RST command.

This command is an event and therefore has no *RST value and no query.

Parameter

1,'FACTORY' deactivates the startup recall function

1,'<file_name>' activates the startup recall function and defines the settings file to be

loaded

with <file_name> = DOS file name without extension

The file name includes indication of the path and may also include the drive name. The path

name complies with DOS conventions.

Example

MMEM:LOAD:AUTO 1,'C:\R_S\Instr\user\TEST'

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

MMEMory:LOAD:STATe

This command loads the device settings from *.FSL.dfl files. The contents of the file are loaded

and set as the new device state.

Parameter

1,<file_name>

with <file_name> = DOS file name without extension

The file name includes indication of the path and may also include the drive name. The path

name complies with DOS conventions.

Example

MMEM:LOAD:STAT 1,'C:\R_S\Instr\user\TEST01'

Characteristics

*RST value: -

SCPI: conform

Mode

all

MMEMory Subsystem R&S FSL

1300.2519.12 6.160 E-11

MMEMory:MDIRectory

This command creates a new directory. The file name includes indication of the path and may

also include the drive name. The path name complies with DOS conventions.

This command is an event and therefore has no *RST value and no query.

Parameter

<directory_name> = DOS path name

Example

MMEM:MDIR 'C:\R_S\Instr\user'

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

MMEMory:MOVE

This command renames existing files, if <file_destination> contains no path indication.

Otherwise the file is moved to the indicated path and stored under the file name specified there,

if any.

This command is an event and therefore has no *RST value and no query.

Parameter

<file_source>,<file_destination> = <file_name> = DOS file name

The file name includes indication of the path and may also include the drive. The path name

complies with DOS conventions.

Example

MMEM:MOVE 'C:\TEST01.CFG','SETUP.CFG'

Renames TEST01.CFG in SETUP.CFG in directory C:\.

MMEM:MOVE 'C:\TEST01.CFG','C:\R_S\Instr\user

Moves TEST01.CFG from C:\ to C:\R_S\Instr\user.

MMEM:MOVE 'C:\TEST01.CFG','C:\R_S\Instr\user\SETUP.CFG'

Moves TEST01.CFG from C:\ to C:\R_S\Instr\user and renames the file in SETUP.CFG.

Characteristics

*RST value: -

SCPI: conform

Mode

all

R&S FSL MMEMory Subsystem

1300.2519.12 6.161 E-11

MMEMory:MSIS

This command changes to the drive indicated. The drive may be the internal hard disk C:.

Parameter

<device> = A: | C: ... Z:

The path name complies with DOS conventions.

Example

MMEM:MSIS 'C:'

Characteristics

*RST value: "C:

SCPI: conform

Mode

all

MMEMory:NAME

This command defines a destination file for the printout started with the

HCOPy[:IMMediate<1|2>] command. In this case the printer output must be routed to a file

as destination.

This command is an event and therefore has no *RST value and no query.

Parameter

<file_name> = DOS file name

The file name includes indication of the path and may also include the drive name. The file

name and path information comply with DOS conventions.

Example

MMEM:NAME 'C:\R_S\instr\user\PRINT1.BMP'

Selects the file name.

Characteristics

*RST value: -

SCPI: conform

Mode

all

MMEMory:NETWork:MAP

This command maps a drive to a server or server folder of the network. As a prerequisite in

Microsoft networks, sharing of this server or server folder must be enabled.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.70.

Parameter

'<string>','<string>'[,'<string>','<string>'],[<Boolean>]

with '<string>','<string>' = '<drive>','<\\host name or IP address\share name>'

[,'<string>','<string>'],[<Boolean>] = '<user name>','<password>',ON | OFF for

connecting under a different user name, and enabling/disabling reconnect at logon.

The entry is optional. The Boolean parameter can be omitted.

MMEMory Subsystem R&S FSL

1300.2519.12 6.162 E-11

Example

MMEM:NETW:MAP 'T:','\\server\folder'

Maps drive T: to folder on server.

Characteristics

RST value: -

SCPI: device-specific

Mode

all

MMEMory:NETWork:DISConnect

This command disconnects the selected drive.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.70.

Parameter

'<string>' = <drive name>

Example

MMEM:NETW:DISC 'T:'

Disconnects network drive T:

Characteristics

RST value: -

SCPI: device-specific

Mode

all

MMEMory:NETWork:UNUSeddrives?

This command lists all unused network drive names.

This command is only a query and therefore has no *RST value.

This command is available from firmware version 1.70.

Example

MMEM:NETW:UNUS?

Lists all unused network drive names.

Characteristics

RST value: -

SCPI: device-specific

Mode

all

R&S FSL MMEMory Subsystem

1300.2519.12 6.163 E-11

MMEMory:NETWork:USEDdrives?

This command lists all mapped network drives.

This command is available from firmware version 1.70.

Parameter

ON Lists all mapped network drives including the folder information.

OFF Lists all mapped network drive names.

Example

MMEM:NETW:USED ON

Lists all mapped network drives including the folder information.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

all

MMEMory:RDIRectory

This command deletes the indicated directory. The directory name includes indication of the

path and may also include the drive name. The path name complies with DOS conventions.

This command is an event and therefore has no *RST value and no query.

Parameter

<directory_name> = DOS path name

Example

MMEM:RDIR 'C:\TEST'

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

MMEMory:SELect[:ITEM]:ALL

This command includes all data subsets in the list of device settings to be stored/loaded.

This command is an event and therefore has no *RST value.

Example

MMEM:SEL:ALL

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

MMEMory Subsystem R&S FSL

1300.2519.12 6.164 E-11

MMEMory:SELect[:ITEM]:FINal

This command includes the final measurement data in the list of partial datasets of a device

setting to be stored/loaded.

Parameter

ON | OFF

Example

"MMEM:SEL:FIN ON"

inserts the final measurement data in the list of partial data sets

Characteristics:

*RST value: ON

SCPI: device-specific

Mode

R, A

MMEMory:SELect[:ITEM]:DEFault

This command includes the default list in the settings file to be stored/loaded. For details on

hardware settings refer to the MMEMory:SELect[:ITEM]:HWSettings command.

Example

MMEM:SEL:DEFault

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

MMEMory:SELect[:ITEM]:HWSettings

This command includes the hardware settings in the settings file to be stored/loaded. The

hardware settings include:

•current configuration of general device parameters (general setup)

•current setting of the measurement hardware including markers

•activated limit lines:

Asettings file may include 8 limit lines at maximum. This number includes the activated limit

lines and, if available, the de-activated limit lines last used.

Therefore the combination of the non-activated restored limit lines depends on the sequence of

use with the MMEMory:LOAD:STATe command.

•user-defined color setting

•configuration for the hardcopy output

•tracking generator settings (models 13, 16 and 28)

•correction data for source calibration (models 13, 16 and 28)

Parameter

ON | OFF

R&S FSL MMEMory Subsystem

1300.2519.12 6.165 E-11

Example

MMEM:SEL:HWS ON

Characteristics

*RST value: ON

SCPI: device-specific

Mode

all

MMEMory:SELect[:ITEM]:LINes:ALL

This command includes all li mit lines (activated and de-activated) in the settings file to be

stored/loaded.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

MMEM:SEL:LIN:ALL ON

Characteristics

*RST value: ON

SCPI: device-specific

Mode

all

MMEMory:SELect[:ITEM]:NONE

This command excludes all items from the settings file to be stored/loaded.

This command is an event and therefore has no *RST value.

Example

MMEM:SEL:NONE

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

MMEMory:SELect[:ITEM]:SCData (models with tracking generator)

This command includes the tracking generator calibration data in the settings file to be

stored/loaded.

This command is only available in conjunction with the tracking generator.Parameter

ON | OFF

Example

MMEM:SEL:SCD ON

Adds the tracking generator correction data to the items list.

MMEMory Subsystem R&S FSL

1300.2519.12 6.166 E-11

Characteristics

*RST value: OFF

SCPI: device-specific

Mode

all

MMEMory:SELect[:ITEM]:TRACe[:ACTive]

This command includes the active traces in the settings file to be stored/loaded. Active traces

are all traces whose state is not blank.

Parameter

ON | OFF

Example

MMEM:SEL:TRAC ON

Characteristics

*RST value: OFF, i.e. no traces will be stored

SCPI: device-specific

Mode

all

MMEMory:SELect[:ITEM]:TRANsducer:ALL

This command includes all transducer factors and sets in the settings file to be stored/loaded.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

MMEM:SEL:TRAN:ALL ON

Characteristics

*RST value: ON

SCPI: device-specific

Mode

all

MMEMory:STORe<1|2>:LIST

This command stores the current list evaluation results in a *.dat file. The file consists of a data

section containing the list evaluation results.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.80.

Example

MMEM:STOR:LIST 'test'

Stores the current list evaluation results in the a test.dat file.

R&S FSL MMEMory Subsystem

1300.2519.12 6.167 E-11

Characteristics

RST value: -

SCPI: device-specific

Mode

MMEMory:STORe<1|2>:PEAK

This command stores the current marker peak list in a *.dat file. The file consists of a data

section containing the peak list.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.80.

Parameter

<file_name> = DOS file name without extension

The file name includes the indication of the path and may also include the drive name. The path

name complies with DOS conventions.

Example

MMEM:STOR:PEAK 'test'

Saves the current marker peak list in the file test.dat.

Characteristics

RST value: -

SCPI: device-specific

Mode

all

MMEMory:STORe<1|2>:STATe

This command stores the current device settings in a *.FSL.dfl file.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Parameter

1,<file_name>

with <file_name> = DOS file name without extension

The file name includes the indication of the path and may also include the drive name. The path

name complies with DOS conventions.

Example

MMEM:STOR:STAT 1,'Save'

Saves the current device settings in the file Save.FSL.dfl.

Characteristics

*RST value: -

SCPI: conform

Mode

all

MMEMory Subsystem R&S FSL

1300.2519.12 6.168 E-11

MMEMory:STORe<1|2>:STATe:NEXT

This command stores the current device settings in a *.FSL.dfl file. The file name used in the

last saving process is automatically counted up to the next unused name. The numeric suffix in

STORe<1|2> is irrelevant with this command.

This command is an event and therefore has no *RST value and no query.

Example

MMEM:STOR:STAT 1,'Save'

Saves the current device settings in the file Save.FSL.dfl.

MMEM:STOR:STAT:NEXT

Saves the current device settings in the file Save_001.FSL.dfl

MMEM:STOR:STAT:NEXT

Saves the current device settings in the file Save_002.FSL.dfl

Characteristics

RST value: -

SCPI: device-specific

Mode

all

MMEMory:STORe<1|2>:TRACe

This command stores the selected trace in a file with ASCII format. The file format is described

in chapter 4 "Instrument Functions - Analyzer", section "Setting Traces - TRACE Key", ASCII

File Export softkey.

The decimal separator (decimal point or comma) for floating-point numerals contained in the file

is defined with the FORMat:DEXPort:DSEParator command.

This command is an event and therefore has no *RST value and no query.

Parameter

1to 6,<file_name>

with 1 to 6 = selected measurement curve trace 1 to 6 and <file_name> = DOS file name

The file name includes indication of the path and the drive name. Indication of the path complies

with DOS conventions.

Example

MMEM:STOR:TRAC 3,'TEST.ASC'

Stores trace 3 in the file TEST.ASC.

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

R&S FSL OUTPut Subsystem

1300.2519.12 6.169 E-11

OUTPut Subsystem

The OUTPut subsystem controls the output features of the instrument.

Commands of the OUTPut Subsystem

–OUTPut<1|2>[:STATe] (models with tracking generator)

–OUTPut<1|2>:IF[:SOURce]

–OUTPut:UPORt[:VALue]

–OUTPut:UPORt:STATe

OUTPut<1|2>[:STATe] (models with tracking generator)

This command switches the tracking generator on or off.

Note: With the tracking generator switched on, the maximum stop frequency is limited to 3

GHz. This upper limit is automatically modified by the set frequency offset of the

generator.

If measurements in compliance with specs are to be performed with the tracking

generator, the start frequency has to be



3 x resolution bandwidth.

If a sweep time shorter than recommended in the data sheet is selected, the sweep

time indicator SWT on the screen is marked with a red asterisk and the message

UNCAL is also displayed.

With the tracking generator switched on, the FFT filters

([SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:TYPE)are not available.

To switch off the tracking generator without loosing the the corresponding hardware

settings and the normalization see the

SOURce<1|2>:POWer[:LEVel][:IMMediate][:AMPLitude] command.

Parameter

ON | OFF

Example

OUTP ON

Switches on the tracking generator.

Characteristics

*RST value: –

SCPI: conform

Mode

OUTPut Subsystem R&S FSL

1300.2519.12 6.170 E-11

OUTPut<1|2>:IF[:SOURce]

This command switches the source of the IF output between the demodulated signal (2 possible

values) and the IF signal.

Note: The AF output available at the frontpanel can only be used if the IF output source is set

to video.

Parameter

IF intermediate frequency output

VIDeo video output, 200 mV

HVIDeo video output, 1V

Example

OUTP IF VID

Selects the video signal for the IF output connector.

Characteristics

*RST value: IF

SCPI: conform

Mode

OUTPut:UPORt[:VALue]

This command sets the control lines of the user ports.

The user port is written to with the given binary pattern. If the user port is programmed to INPut

instead of OUTPut, the output value is temporarily stored.

Parameter

#B00000000 to #B11111111

Example

OUTP:UPOR #B10100101

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

R&S FSL OUTPut Subsystem

1300.2519.12 6.171 E-11

OUTPut:UPORt:STATe

This command switches the control line of the user ports between INPut and OUTPut. The user

port is switched to OUTPut with parameter ON, to INPut with OFF.

Parameter

ON | OFF

Example

OUTP:UPOR:STAT ON

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

all

SENSe Subsystem R&S FSL

1300.2519.12 6.172 E-11

SENSe Subsystem

The SENSe subsystem is organized in several subsystems. The commands of these subsystems

directly control device–specific settings, they do not refer to the signal characteristics of the

measurement signal.

The SENSe subsystem controls the essential parameters of the analyzer. In accordance with the SCPI

standard, the keyword "SENSe" is optional for this reason, which means that it is not necessary to

include the SENSe node in command sequences.

The following subsystems are included:

•"SENSe:AVERage Subsystem" on page 6.172

•"SENSe:BANDwidth Subsystem" on page 6.175

•"SENSe:CORRection Subsystem (Models with tracking generator)" on page 6.179

•"SENSe:DETector Subsystem" on page 6.186

•"SENSe:ESPectrum Subsystem" on page 6.187

•"SENSe:FREQuency Subsystem" on page 6.200

•"SENSe:LIST Subsystem" on page 6.205

•"SENSe:MPOWer Subsystem" on page 6.215

•"SENSe:POWer Subsystem" on page 6.220

•"SENSe:ROSCillator Subsystem" on page 6.228

•"SENSe:SWEep Subsystem" on page 6.229

SENSe:AVERage Subsystem

The SENSe:AVERage subsystem calculates the average of the acquired data. A new test result is

obtained from several successive measurements.

There are two types of average calculation: logarithmic and linear. In case of logarithmic average

calculation (denoted with VIDeo), the average value of the measured logarithmic power is calculated

and in case of linear average calculation, the linear power is averaged before the logarithm is applied.

Commands of the SENSe:AVERage Subsystem

–[SENSe<1|2>:]AVERage[:STATe<1...6>]

–[SENSe<1|2>:]AVERage:COUNt

–[SENSe<1|2>:]AVERage:COUNt:AUTO

–[SENSe<1|2>:]AVERage:TYPE

R&S FSL SENSe Subsystem

1300.2519.12 6.173 E-11

[SENSe<1|2>:]AVERage[:STATe<1...6>]

This command switches on or off the average calculation for the selected trace (STATe<1...4>).

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

AVER OFF

Switches off the average calculation for trace 1.

AVER:STAT3 ON

Switches on the average calculation for trace 3.

Characteristics

*RST value: OFF

SCPI: conform

Mode

all

[SENSe<1|2>:]AVERage:COUNt

This command defines the number of measurements which contribute to the average value.

It should be noted that continuous averaging will be performed after the indicated number has

been reached in continuous sweep mode.

In single sweep mode, the sweep is stopped as soon as the indicated number of measurements

(sweeps) is reached. Synchronization to the end of the indicated number of measurements is

only possible in single sweep mode.

The [SENSe<1|2>:]AVERage:COUNt command effects the same as the

[SENSe<1|2>:]SWEep:COUNt command. In both cases, the number of measurements is

defined whether the average calculation is active or not.

The number of measurements applies to all traces.

The numeric suffixes <1|2> are not relevant.

Parameter

0to 32767

Example

SWE:CONT OFF

Switching to single sweep mode.

AVER:COUN 16

Sets the number of measurements to 16.

AVER:STAT ON

Switches on the calculation of average.

INIT;*WAI

Starts the measurement and waits for the end of the 16 sweeps.

Characteristics

*RST value: 0

SCPI: conform

Mode

all

SENSe Subsystem R&S FSL

1300.2519.12 6.174 E-11

[SENSe<1|2>:]AVERage:COUNt:AUTO

This command is implemented only for reasons of compatibility with the FSP family. It selects a

suitable number of counts for the selected measurement type.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

AVER:COUN:AUTO ON

Characteristics

RST value: OFF

SCPI: conform

Mode

all

[SENSe<1|2>:]AVERage:TYPE

This command selects the type of average function.

Parameter

VIDeo The logarithmic power values are averaged.

LINear The power values are averaged before they are converted to logarithmic values.

Example

AVER:TYPE LIN

Switches to linear average calculation.

Characteristics

RST value: VIDeo

SCPI: device–specific

Mode

R&S FSL SENSe Subsystem

1300.2519.12 6.175 E-11

SENSe:BANDwidth Subsystem

This subsystem controls the setting of the instruments filter bandwidths. Both groups of commands

(BANDwidth and BWIDth) perform the same functions.

Commands of the SENSe:BANDwidth Subsystem

–[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]

–[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:AUTO

–[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:RATio

–[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:TYPE

–[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo

–[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:AUTO

–[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:RATio

–[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:TYPE

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]

This command defines the analyzers resolution bandwidth.

The available resolution bandwidths are specified in the data sheet. For details on the

correlation between resolution bandwidth and filter type refer to chapter "Instrument Functions",

section "To choose the appropriate filter type".

If the resolution bandwidth is modified, the coupling to the span is automatically switched off.

The numeric suffixes <1|2> are not relevant.

Parameter

refer to data sheet

Example

BAND 1MHz

Sets the resolution bandwidth to 1 MHz

Characteristics

*RST value: – (AUTO is set to ON)

SCPI: conform

Mode

all, except ADEMOD

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:AUTO

This command either automatically couples the resolution bandwidth of the instrument to the

span or cancels the coupling.

The automatic coupling adapts the resolution bandwidth to the currently set frequency span

according to the relationship between frequency span and resolution bandwidth. The 6 dB

bandwidths 200 Hz, 9 kHz and 120 kHz and the channel filters available are not set by the

automatic coupling.

The ratio resolution bandwidth/span can be modified with the

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:RATio command.

The numeric suffixes <1|2> are not relevant.

SENSe Subsystem R&S FSL

1300.2519.12 6.176 E-11

Parameter

ON | OFF

Example

BAND:AUTO OFF

Switches off the coupling of the resolution bandwidth to the span.

Characteristics

*RST value: ON

SCPI: conform

Mode

A–F, CATV, CDMA, EVDO

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:RATio

This command defines the ratio resolution bandwidth (Hz) / span (Hz). The ratio to be entered is

reciprocal to the ratio span/RBW used in manual operation.

The numeric suffixes <1|2> are not relevant.

Parameter

0.0001 to 1

Example

BAND:RAT 0.1

Characteristics

*RST value: 0.02 with BAND:TYPE NORMal or RBW > 30 kHz; 0.01 with BAND:TYPE FFT for

RBW 30 kHz

SCPI: conform

Mode

A, EVDO

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:TYPE

This command switches the filter type for the resolution bandwidth between "normal" analog or

FIR filters in 1, 3, 10 steps and the FFT filtering for bandwidths <100 kHz.

For detailed information on filters see chapter "Instrument Functions", section "To choose the

appropriate filter" and "List of available RRC and channel filters".

The numeric suffixes <1|2> are not relevant.

Note: When changing the filter type, the next larger filter bandwidth is selected if the same

filter bandwidth is not available for the new filter type.

Parameter

NORMal Gaussian filters

FFT FFT filters

CFILter channel filters

RRC RRC filters

PULSe EMI (6dB) filters (available from firmware version 1.30)

R&S FSL SENSe Subsystem

1300.2519.12 6.177 E-11

Example

BAND:TYPE NORM

Characteristics

*RST value: NORMal

SCPI: device–specific

Mode

all, except ADEMOD

[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo

This command defines the instruments video bandwidth. The available video bandwidths are

specified in the data sheet. The command is not available if FFT filtering is switched on and the

set bandwidth is 30 kHz or if the quasi–peak detector is switched on.

The numeric suffixes <1|2> are not relevant.

Parameter

refer to data sheet

Example

BAND:VID 10kHz

Characteristics

*RST value: – (AUTO is set to ON)

SCPI: conform

Mode

A, CATV, EVDO

[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:AUTO

This command either automatically couples the instruments video bandwidth to the resolution

bandwidth or cancels the coupling.

The ratio video bandwidth/resolution bandwidth can be modified with the

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:RATio command.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

BAND:VID:AUTO OFF

Characteristics

*RST value: ON

SCPI: conform

Mode

A, CATV, CDMA, EVDO

SENSe Subsystem R&S FSL

1300.2519.12 6.178 E-11

[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:RATio

This command defines the ratio video bandwidth (Hz) / resolution bandwidth (Hz).The ratio to be

entered is reciprocal to the ratio RBW/VBW used in manual operation.

The numeric suffixes <1|2> are not relevant.

Parameter

0.01 to 1000

Example

BAND:VID:RAT 3

Sets the coupling of video bandwidth to video bandwidth = 3*resolution bandwidth

Characteristics

*RST value: 3

SCPI: conform

Mode

A, EVDO

[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:TYPE

This command selects the position of the video filter in the signal path, provided that the

resolution bandwidth is 100 kHz.

The essential difference between the two modes is the transient response at falling signal

edges: If LINear is selected, the measurement with logarithmic level scaling yields a much

"flatter" falling edge than LOGarithmic. This behavior is due to the conversion of linear power

into logarithmic level. If the linear power is halved, the level decreases by only 3 dB.

The numeric suffixes <1|2> are not relevant.

Parameter

LINear The video filter is connected ahead of the logarithmic amplifier (default).

LOGarithmic The video filter follows the logarithmic amplifier

Example

BAND:VID:TYPE LIN

Video filter ahead of the logarithmic amplifier

Characteristics

RST value: LIN

SCPI: device–specific

Mode

A, CDMA, EVDO

R&S FSL SENSe Subsystem

1300.2519.12 6.179 E-11

SENSe:CORRection Subsystem (Models with tracking generator)

This subsystem controls calibration and normalization during operation with the tracking generator.

Commands of the SENSe:CORRection Subsystem

–[SENSe<1|2>:]CORRection[:STATe]

–[SENSe<1|2>:]CORRection:COLLect[:ACQuire]

–[SENSe<1|2>:]CORRection:EGAin:INPut[:MAGNitude]

–[SENSe<1|2>:]CORRection:METHod

–[SENSe<1|2>:]CORRection:RECall

–[SENSe<1|2>:]CORRection:TRANsducer[:STATe]

–[SENSe<1|2>:]CORRection:TRANsducer:ADJust:RLEVel[:STATe]

–[SENSe<1|2>:]CORRection:TRANsducer:COMMent

–[SENSe<1|2>:]CORRection:TRANsducer:DATA

–[SENSe<1|2>:]CORRection:TRANsducer:DELete

–[SENSe<1|2>:]CORRection:TRANsducer:SCALing

–[SENSe<1|2>:]CORRection:TRANsducer:SELect

–[SENSe<1|2>:]CORRection:TRANsducer:UNIT

–[SENSe<1|2>:]CORRection:TRANsducer:VIEW

[SENSe<1|2>:]CORRection[:STATe]

This command activates/deactivates the normalization of the measurement results provided that

the tracking generator is active. The command is available only after acquisition of a reference

trace for the selected type of measurement (transmission/reflection, see

[SENSe<1|2>:]CORRection:COLLect[:ACQuire] command).

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

CORR ON

Activates normalization.

Characteristics

*RST value: OFF

SCPI: conform

Mode

SENSe Subsystem R&S FSL

1300.2519.12 6.180 E-11

[SENSe<1|2>:]CORRection:COLLect[:ACQuire]

When the tracking generator is active, this command determines the type of result acquisition

for the normalization reference measurement and starts the measurement selected:

To obtain a correct reference measurement, a complete sweep with synchronization to the end

of the sweep must have been carried out. This is only possible in the single sweep mode.

The numeric suffixes <1|2> are not relevant.

This command is an "event" and therefore has no *RST value and no query.

Parameter

THRough "TRANsmission" mode calibration with direct connection

between tracking generator and

device input

"REFLection" mode calibration with short circuit at the

input

OPEN only allowed in "REFLection" mode calibration with open input

Example

INIT:CONT OFF

Selects single sweep operation

CORR:COLL THR;*WAI

Starts the measurement of reference data using direct connection between generator and

device input and waits for the sweep end.

Characteristics

*RST value: –

SCPI: conform

Mode

[SENSe<1|2>:]CORRection:EGAin:INPut[:MAGNitude]

This command makes an external gain known to the analyzer, which will take it into account

during the display of measurement results. With this function the gain of an antenna or of an

external preamplifier can be taken into account for the measurement values.

The numeric suffixes <1|2> are not relevant.

Parameter

–200...200dB

Example

CORR:EGA:INP 10DB

Takes 10 dB external gain into account.

Characteristics

*RST value: 0 dB

SCPI: device–specific

Mode

R&S FSL SENSe Subsystem

1300.2519.12 6.181 E-11

[SENSe<1|2>:]CORRection:METHod

This command selects the type of measurement with active tracking generator

(transmission/reflection).

The numeric suffixes <1|2> are not relevant.

Parameter

TRANsmission | REFLection

Example

CORR:METH TRAN

Sets the type of measurement to "transmission".

Characteristics

*RST value: TRANsmission

SCPI: device–specific

Mode

[SENSe<1|2>:]CORRection:RECall

This command restores the instrument setting that was applied to the measurement of the

reference data, provided that the tracking generator is active.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

Example

CORR:REC

Characteristics

*RST value: –

SCPI: conform

Mode

[SENSe<1|2>:]CORRection:TRANsducer[:STATe]

This command switches the selected transducer factor on or off.

Note: Prior to this command, the [SENSe<1|2>:]CORRection:TRANsducer:SELect

command must be sent.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

CORR:TRAN ON

Characteristics

*RST value: OFF

SCPI: device-specific

Mode A

SENSe Subsystem R&S FSL

1300.2519.12 6.182 E-11

[SENSe<1|2>:]CORRection:TRANsducer:ADJust:RLEVel[:STATe]

This command switches the automatic adjustment of the reference level to the selected

transducer factor on or off. For details refer to chapter 4, section "Instrument Setup and

Interface Configuration - SETUP Key", Ref Level Adjust Man/Auto softkey.

Note: Prior to this command, the [SENSe<1|2>:]CORRection:TRANsducer:SELect

command must be sent.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

CORR:TRAN:ADJ:RLEV ON

Characteristics

*RST value: OFF

SCPI: device-specific

Mode

[SENSe<1|2>:]CORRection:TRANsducer:COMMent

This command defines the comment for the selected transducer factor.

Note: Prior to this command, the [SENSe<1|2>:]CORRection:TRANsducer:SELect

command must be sent.

This command is available from firmware version 1.10.

Parameter

Example

CORR:TRAN:COMM 'FACTOR FOR ANTENNA'

Characteristics

*RST value: (empty comment)

SCPI: device-specific

Mode A

[SENSe<1|2>:]CORRection:TRANsducer:DATA

This command defines the reference values of the transducer factor selected. These values are

entered as a sequence of frequency/level pairs. The frequencies must be sent in ascending

order.

Note: Prior to this command, the [SENSe<1|2>:]CORRection:TRANsducer:SELect

command must be sent. The level values are sent as dimensionless numbers; the unit

is specified by means of the [SENSe<1|2>:]CORRection:TRANsducer:UNIT

command.

This command is available from firmware version 1.10.

Parameter

R&S FSL SENSe Subsystem

1300.2519.12 6.183 E-11

Example

SENS:CORR:TRAN:SEL 'TRAN_1'

Selects the transducer factor

CORR:TRAN:UNIT 'DB'

Selects the unit for the transducer.

CORR:TRAN:DATA 1MHZ,-30,2MHZ,-40

Defines the frequency/level pairs 1 MHz, -30 dB and 2 MHz, -40 dB.

Characteristics

*RST value: -

SCPI: device-specific

Mode

[SENSe<1|2>:]CORRection:TRANsducer:DELete

This command deletes the selected transducer factor.

This command is an event and therefore has no *RST value.

Note: Prior to this command, the [SENSe<1|2>:]CORRection:TRANsducer:SELect

command must be sent.

This command is available from firmware version 1.10.

Example

CORR:TRAN:DEL

Characteristics

*RST value: -

SCPI: device-specific

Mode

[SENSe<1|2>:]CORRection:TRANsducer:SCALing

This command defines whether the frequency scaling of the transducer factor is linear or

logarithmic.

Note: Prior to this command, the [SENSe<1|2>:]CORRection:TRANsducer:SELect

command must be sent.

This command is available from firmware version 1.10.

Parameter

LINear | LOGarithmic

Example

CORR:TRAN:SCAL LOG

Characteristics

*RST value: LINear

SCPI: device-specific

Mode

SENSe Subsystem R&S FSL

1300.2519.12 6.184 E-11

[SENSe<1|2>:]CORRection:TRANsducer:SELect

This command selects the transducer factor designated by <name>. If <name> does not exist

yet, a new transducer factor is created.

Note: This command must be sent prior to the subsequent commands for modifying/activating

transducer factors.

This command is available from firmware version 1.10.

Parameter

<name> = Name of the transducer factor in string data form with a maximum of 8 characters.

Example

CORR:TRAN:SEL 'FACTOR1'

Characteristics

*RST value: -

SCPI: device-specific

Mode

[SENSe<1|2>:]CORRection:TRANsducer:UNIT

This command defines the unit of the transducer factor selected.

Note: Prior to this command, the [SENSe<1|2>:]CORRection:TRANsducer:SELect

command must be sent.

This command is available from firmware version 1.10.

Parameter

Example

CORR:TRAN:UNIT 'DBUV'

Characteristics

*RST value: DB

SCPI: device-specific

Mode

R&S FSL SENSe Subsystem

1300.2519.12 6.185 E-11

[SENSe<1|2>:]CORRection:TRANsducer:VIEW

This command switches on the display of the active transducer factor or set.

Note: Prior to this command, the [SENSe<1|2>:]CORRection:TRANsducer:SELect

command must be sent.

This command is available from firmware version 1.10.

Parameter

ON | OFF

Example

CORR:TRAN:VIEW ON

Characteristics

*RST value: OFF

SCPI: device-specific

Mode

SENSe Subsystem R&S FSL

1300.2519.12 6.186 E-11

SENSe:DETector Subsystem

The SENSe:DETector subsystem controls the acquisition of measurement data via the selection of the

detector for the corresponding trace.

Commands of the SENSe:DETector Subsystem

–[SENSe<1|2>:]DETector<1...6>[:FUNCtion]

–[SENSe<1|2>:]DETector<1...6>[:FUNCtion]:AUTO

[SENSe<1|2>:]DETector<1...6>[:FUNCtion]

This command switches on the detector for the data acquisition in the selected trace.

The trace is indicated as numeric suffix in DETector.

The numeric suffixes <1|2> are not relevant.

Parameter

For details on detectors refer to chapter "Instrument Functions", section "Detector overview".

Example

DET POS

Sets the detector to "positive peak".

Characteristics

*RST value: APEak

SCPI: conform

Mode

A, CATV

[SENSe<1|2>:]DETector<1...6>[:FUNCtion]:AUTO

This command either couples the detector to the current trace setting or turns coupling off. The

trace is selected by the numeric suffix at DETector.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

DET:AUTO OFF

Characteristics

*RST value: ON

SCPI: conform

Mode

A, CATV

R&S FSL SENSe Subsystem

1300.2519.12 6.187 E-11

SENSe:ESPectrum Subsystem

The SENSe:ESPectrum subsystem contains the remote commands to configure Spectrum Emission

Mask (SEM) measurements.

Commands of the SENSe:ESPectrum Subsystem

–[SENSe<1|2>:]ESPectrum:BWID

–[SENSe<1|2>:]ESPectrum:FILTer[:RRC][:STATe]

–[SENSe<1|2>:]ESPectrum:FILTer[:RRC]:ALPHa

–[SENSe<1|2>:]ESPectrum:PRESet[:STANdard]

–[SENSe<1|2>:]ESPectrum:PRESet:RESTore

–[SENSe<1|2>:]ESPectrum:PRESet:STORe

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth:RESolution

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth:VIDeo

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:COUNt?

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:DELete

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>[:FREQuency]:STARt

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>[:FREQuency]:STOP

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:FILTer:TYPE

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:ATTenuation

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:ATTenuation:AUTO

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:GAIN:STATe

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INSert

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:ABSolute:STARt

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:ABSolute:STOP

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:RELative:STARt

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:RELative:STOP

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:STATe

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:RLEVel

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:SWEep:TIME

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:SWEep:TIME:AUTO

–[SENSe<1|2>:]ESPectrum:RANGe<1...20>:TRANsducer

–[SENSe<1|2>:]ESPectrum:RRANge?

–[SENSe<1|2>:]ESPectrum:RTYPe

SENSe Subsystem R&S FSL

1300.2519.12 6.188 E-11

[SENSe<1|2>:]ESPectrum:BWID

This command defines the bandwidth used for measuring the channel power (reference range).

This setting takes only effect if channel power is selected as power reference type

([SENSe<1|2>:]ESPectrum:RTYPe command).

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

minimum span



value



span of reference range

Example

ESP:RTYP CPOW

Sets the power reference type to channel power.

ESP:BWID 1MHZ

Sets the Tx bandwidth to 1 MHz.

Characteristics

RST value: 3.84 MHz

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:FILTer[:RRC][:STATe]

This command activates or deactivates the use of an RRC filter. This setting takes only effect if

channel power is selected as power reference type ([SENSe<1|2>:]ESPectrum:RTYPe

command).

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

ON | OFF

Example

ESP:RTYP CPOW

Sets the power reference type to channel power.

ESP:FILT OFF

Deactivates the use of an RRC filter.

Characteristics

RST value: ON

SCPI: device–specific

Mode

A, CDMA, EVDO

R&S FSL SENSe Subsystem

1300.2519.12 6.189 E-11

[SENSe<1|2>:]ESPectrum:FILTer[:RRC]:ALPHa

This command sets the alpha value of the RRC filter. This setting takes only effect if channel

power is selected as power reference type ([SENSe<1|2>:]ESPectrum:RTYPe command)

and if the RRC filter is activated ([SENSe<1|2>:]ESPectrum:FILTer[:RRC][:STATe]

command).

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

0to 1

Example

ESP:RTYP CPOW

Sets the power reference type to channel power.

ESP:FILT ON

Activates the use of an RRC filter.

ESP:FILT:ALPH 0.5

Sets the alpha value of the RRC filter to 0.5.

Characteristics

RST value: 0.22

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:PRESet[:STANdard]

This command selects the specified XML file under C:\r_s\instr\sem_std.If the file is stored in a

subdirectory, include the relative path.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.80.

Example

ESP:PRES 'WCDMA\3GPP\DL\PowerClass_31_39.xml'

Selects the PowerClass_31_39.xml XML file in the C:\R_S\instr\sem_std\WCDMA\3GPP\DL

directory.

ESP:PRES?

W–CDMA 3GPP DL (31,39)dBm

The query returns information about the selected standard, the link direction and the power

class. If no standard has been selected, the query returns None.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, CDMA, EVDO

SENSe Subsystem R&S FSL

1300.2519.12 6.190 E-11

[SENSe<1|2>:]ESPectrum:PRESet:RESTore

This command copies the XML files from the C:\R_S\instr\sem_backup folder to the

C:\R_S\instr\sem_std folder. Files of the same name are overwritten.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.80.

Example

ESP:PRES:REST

Restores the originally provided XML files.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:PRESet:STORe

This command saves the specified XML file under C:\r_s\instr\sem_std. To save the file in

subdirectory, include the relative path.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

Example

ESP:STOR 'DL\BandClass_20.xml'

Saves the BandClass_20.xml XML file in the C:\R_S\instr\sem_std\DL directory.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth /

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth:RESolution

This command sets the RBW value for the specified range.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

Refer to the data sheet.

Example

ESP:RANG2:BAND:RES 5000

Sets the RBW for range 2 to 5 kHz.

R&S FSL SENSe Subsystem

1300.2519.12 6.191 E-11

Characteristics

RST value: 30.0 kHz

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth:VIDeo

This command sets the VBW value for the specified range.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

Refer to the data sheet.

Example

ESP:RANG1:BAND:VID 5000000

Sets the VBW for range 1 to 5 MHz.

Characteristics

RST value: 10.0 MHz

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:COUNt?

This command returns the number of defined ranges.

The numeric suffixes are not relevant.

This command is only a query and therefore has no *RST value.

This command is available from firmware version 1.80.

Example

ESP:RANG:COUNt?

Returns the number of defined ranges.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, CDMA, EVDO

SENSe Subsystem R&S FSL

1300.2519.12 6.192 E-11

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:DELete

This command deletes the specified range. The range numbers are updated accordingly. The

reference range cannot be deleted. A minimum of three ranges is mandatory.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.80.

Example

ESP:RANG4:DEL

Deletes range 4.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>[:FREQuency]:STARt

This command sets the start frequency for the specified range.

In order to change the start/stop frequency of the first/last range, select the appropriate span. If

you set a span that is smaller than the overall span of the ranges, the measurement includes

only the ranges that lie within the defined span and have a minimum span of 20 Hz. The first

and last range are adapted to the given span as long as the minimum span of 20 Hz is not

violated.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

see rules in chapter 4, "Ranges and settings"

Example

ESP:RANG1:STAR 100000000

Sets the start frequency for range 1 to 100 MHz.

Characteristics

RST value: –250.0 MHz (range 1), –2.52 MHz (range 2), 2.52 MHz (range 3)

SCPI: device–specific

Mode

A, CDMA, EVDO

R&S FSL SENSe Subsystem

1300.2519.12 6.193 E-11

[SENSe<1|2>:]ESPectrum:RANGe<1...20>[:FREQuency]:STOP

This command sets the stop frequency for the specified range. For further details refer to the

[SENSe<1|2>:]ESPectrum:RANGe<1...20>[:FREQuency]:STARt command.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

see rules in chapter 4, "Ranges and settings"

Example

ESP:RANG3:STOP 10000000

Sets the stop frequency for range 2 to 10 MHz.

Characteristics

RST value: –2.52 MHz (range 1), 2.52 MHz (range 2), 250.0 MHz (range 3)

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:FILTer:TYPE

This command sets the filter type for the specified range.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

NORMal Gaussian filters

CFILter channel filters

RRC RRC filters

PULSe EMI (6dB) filters

The available bandwidths of the filters are specified in the data sheet.

Example

ESP:RANG1:FILT:TYPE RRC

Sets the RRC filter type for range 1.

Characteristics

RST value: NORM

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:ATTenuation

This command sets the attenuation for the specified range.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

Refer to the data sheet.

SENSe Subsystem R&S FSL

1300.2519.12 6.194 E-11

Example

ESP:RANG3:INP:ATT 10

Sets the attenuation of range 3 to 10 dB.

Characteristics

RST value: 0 dB

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:ATTenuation:AUTO

This command activates or deactivates the automatic RF attenuation setting for the specified

range.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

ON | OFF

Example

ESP:RANG2:INP:ATT:AUTO OFF

Deactivates the RF attenuation auto mode for range 2.

Characteristics

RST value: ON

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:GAIN:STATe

This command switches the preamplifier on or off for the specified range.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

ON | OFF

Example

ESP:RANG3:INP:GAIN:STATe ON

Switches the preamplifier for range 3 on or off.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

A, CDMA, EVDO

R&S FSL SENSe Subsystem

1300.2519.12 6.195 E-11

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INSert

This command inserts a new range before or after the specified range. The range numbers are

updated accordingly.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

AFTer | BEFore

Example

ESP:RANG3:INS BEF

Inserts a new range before range 3.

ESP:RANG1:INS AFT

Inserts a new range after range 1.

Characteristics

RST value:

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:ABSolute:STARt

This command sets an absolute limit value at the start frequency of the specified range.

Different from manual operation, this setting is independently of the defined limit check type.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

–400 to in 400 dBm

Example

ESP:RANG1:LIM:ABS:STAR 10

Sets an absolute limit of 10 dBm at the start frequency of the range.

Characteristics

RST value: –13 dBm

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:ABSolute:STOP

This command sets an absolute limit value at the stop frequency of the specified range.

Different from manual operation, this setting is independently of the defined limit check type.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

–400 to in 400 dBm

SENSe Subsystem R&S FSL

1300.2519.12 6.196 E-11

Example

ESP:RANG1:LIM:ABS:STOP 20

Sets an absolute limit of 20 dBm at the stop frequency of the range.

Characteristics

RST value: –13 dBm

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:RELative:STARt

This command sets a relative limit value at the start frequency of the specified range. Different

from manual operation, this setting is independently of the defined limit check type.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

–400 to in 400 dBc

Example

ESP:RANG3:LIM:REL:STAR –20

Sets a relative limit of –20 dBc at the start frequency of the range.

Characteristics

RST value: –50 dBc

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:RELative:STOP

This command sets a relative limit value at the stop frequency of the specified range. Different

from manual operation, this setting is independently of the defined limit check type.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

–400 to in 400 dBc

Example

ESP:RANG3:LIM:REL:STOP 20

Sets a relative limit of 20 dBc at the stop frequency of the range.

Characteristics

RST value: –50 dBc

SCPI: device–specific

Mode

A, CDMA, EVDO

R&S FSL SENSe Subsystem

1300.2519.12 6.197 E-11

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:STATe

This command sets the type of limit check for all ranges.

The numeric suffixes are not relevant.

This command is available from firmware version 1.80.

Parameter

ABSolute Checks only the absolute limits defined.

RELative Checks only the relative limits. Relative limits are defined as relative to the

measured power in the reference range.

AND Combines the absolute and relative limit. The limit check fails when both limits

are violated.

OR Combines the absolute and relative limit. The limit check fails when one of the

limits is violated.

Example

ESP:RANG3:LIM:STAT AND

Sets for all ranges the combined absolute/relative limit check.

Characteristics

RST value: REL

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:RLEVel

This command sets the reference level for the specified range.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

Refer to the data sheet.

Example

ESP:RANG2:RLEV 0

Sets the reference level of range 2 to 0 dBm.

Characteristics

RST value: –20 dBm

SCPI: device–specific

Mode

A, CDMA, EVDO

SENSe Subsystem R&S FSL

1300.2519.12 6.198 E-11

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:SWEep:TIME

This command sets the sweep time for the specified range.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

Allowed values depend on the ratio of span to RBW and RBW to VBW. For details refer to the

data sheet.

Example

ESP:RANG1:SWE:TIME 1

Sets the sweep time for range 1 to 1 s.

Characteristics

RST value: 0.27 s

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:SWEep:TIME:AUTO

This command activates or deactivates the automatic sweep time setting for the specified

range.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

ON | OFF

Example

ESP:RANG3:SWE:TIME:AUTO OFF

Deactivates the sweep time auto mode for range 3.

Characteristics

RST value: ON

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:TRANsducer

This command sets a transducer for the specified range. You can only choose a transducer that

fulfills the following conditions:

–The transducer overlaps or equals the span of the range.

– The x–axis is linear.

–The unit is dB.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

'string' = name of the transducer

R&S FSL SENSe Subsystem

1300.2519.12 6.199 E-11

Example

ESP:RANG1:TRAN 'test'

Sets the transducer called test for range 1.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RRANge?

This command returns the current position (number) of the reference range.

The numeric suffixes <1|2> are not relevant.

This command is only a query and therefore has no *RST value.

This command is available from firmware version 1.80.

Example

ESP:RRAN?

Returns the current position (number) of the reference range.

Characteristics

RST value: –

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]ESPectrum:RTYPe

This command sets the power reference type.

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

PEAK Measures the highest peak within the reference range.

CPOWer Measures the channel power within the reference range (integral bandwidth

method).

Example

ESP:RTYP PEAK

Sets the peak power reference type.

Characteristics

RST value: CPOWer

SCPI: device–specific

Mode

A, CDMA, EVDO

SENSe Subsystem R&S FSL

1300.2519.12 6.200 E-11

SENSe:FREQuency Subsystem

The SENSe:FREQuency subsystem defines the frequency axis of the active display. The frequency

axis can either be defined via the start/stop frequency or via the center frequency and span.

Commands of the SENSe:FREQuency Subsystem

–[SENSe<1|2>:]FREQuency:CENTer

–[SENSe<1|2>:]FREQuency:CENTer:STEP

–[SENSe<1|2>:]FREQuency:CENTer:STEP:AUTO

–[SENSe<1|2>:]FREQuency:CENTer:STEP:LINK

–[SENSe<1|2>:]FREQuency:CENTer:STEP:LINK:FACTor

–[SENSe<1|2>:]FREQuency:MODE

–[SENSe<1|2>:]FREQuency:OFFSet

–[SENSe<1|2>:]FREQuency:SPAN

–[SENSe<1|2>:]FREQuency:SPAN:FULL

–[SENSe<1|2>:]FREQuency:STARt

–[SENSe<1|2>:]FREQuency:STOP

[SENSe<1|2>:]FREQuency:CENTer

This command defines the center frequency of the analyzer or the measuring frequency for

span = 0.

The numeric suffixes <1|2> are not relevant.

Parameter

0to fmax

fmax is specified in the data sheet. To help analyze signals located at the end of the frequency

range, for R&S FSL models with an upper frequency limit of 6 GHz or less, the fmax value is

extended by 0.05 GHz for direct entry. The preset and maximum values remain unchanged.

Example

FREQ:CENT 100MHz

Characteristics

*RST value: fmax /2 with fmax = maximum frequency

SCPI: conform

Mode

all

R&S FSL SENSe Subsystem

1300.2519.12 6.201 E-11

[SENSe<1|2>:]FREQuency:CENTer:STEP

This command defines the step size of the center frequency.

The numeric suffixes <1|2> are not relevant.

Parameter

0to fmax

Example

FREQ:CENT:STEP 120MHz

Characteristics

*RST value: – (AUTO 0.1 ×SPAN is switched on)

SCPI: conform

Mode

all

[SENSe<1|2>:]FREQuency:CENTer:STEP:AUTO

This command couples the step size of the center frequency to the span (ON) or sets the value

of the center frequency entered via [SENSe<1|2>:]FREQuency:CENTer:STEP (OFF).

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

FREQ:CENT:STEP:AUTO ON

Activates the coupling of the step size to the span.

Characteristics

*RST value: ON

SCPI: device–specific

Mode

all

[SENSe<1|2>:]FREQuency:CENTer:STEP:LINK

This command couples the step size of the center frequency to span (span >0) or to the

resolution bandwidth (span = 0) or cancels the couplings.

The numeric suffixes <1|2> are not relevant.

Parameter

SPAN coupling to frequency display range (for span > 0)

RBW coupling to resolution bandwidth (for span = 0)

OFF manual input, no coupling

Example

FREQ:CENT:STEP:LINK SPAN

SENSe Subsystem R&S FSL

1300.2519.12 6.202 E-11

Characteristics

*RST value: SPAN

SCPI: device–specific

Mode

A, ADEMOD, CDMA, EVDO

[SENSe<1|2>:]FREQuency:CENTer:STEP:LINK:FACTor

This command couples the step size of the center frequency with a factor to the span (span >0)

or to the resolution bandwidth (span = 0).

The numeric suffixes <1|2> are not relevant.

Parameter

1to 100 PCT

Example

FREQ:CENT:STEP:LINK:FACT 20PCT

Characteristics

*RST value: – (AUTO 0.1 ×SPAN is switched on)

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]FREQuency:MODE

This command switches between span > 0 (SWEep) and zero span (CW | FIXed) in the

Spectrum Analyzer mode.

For CW and FIXed, the frequency setting is via the [SENSe<1|2>:]FREQuency:CENTer

command. In the sweep mode, the setting is via the [SENSe<1|2>:]FREQuency:STARt,

[SENSe<1|2>:]FREQuency:STOP,[SENSe<1|2>:]FREQuency:CENTer,and

[SENSe<1|2>:]FREQuency:SPAN commands.

The numeric suffixes <1|2> are not relevant.

Parameter

CW | FIXed | SWEep | SCAN

Example

FREQ:MODE SWE

Characteristics

*RST value: SWEep

SCPI: conform

Mode

A, CDMA

R&S FSL SENSe Subsystem

1300.2519.12 6.203 E-11

[SENSe<1|2>:]FREQuency:OFFSet

This command defines the frequency offset of the instrument.

The numeric suffixes <1|2> are not relevant.

Parameter

–100 GHz to 100 GHz

Example

FREQ:OFFS 1GHZ

Characteristics

*RST value: 0 Hz

SCPI: conform

Mode

A, ADEMOD, CDMA, EVDO, WCDMA

[SENSe<1|2>:]FREQuency:SPAN

This command defines the frequency span in the Spectrum Analyzer mode.

The numeric suffixes <1|2> are not relevant.

Parameter

0to fmax

fmax is specified in the data sheet. To help analyze signals located at the end of the frequency

range, for R&S FSL models with an upper frequency limit of 6 GHz or less, the fmax value is

extended by 0.05 GHz for direct entry. The preset and maximum values remain unchanged.

Example

FREQ:SPAN 10MHz

Characteristics

*RST value: fmax with fmax = maximum frequency

SCPI: conform

Mode

A, CATV, CDMA, EVDO

[SENSe<1|2>:]FREQuency:SPAN:FULL

This command sets the frequency span to its maximum.

The numeric suffixes <1|2> are not relevant.

Parameter

fmax,specified in the data sheet.

Example

FREQ:SPAN:FULL

Characteristics

*RST value: –

SCPI: conform

Mode

A, CATV, CDMA, EVDO

SENSe Subsystem R&S FSL

1300.2519.12 6.204 E-11

[SENSe<1|2>:]FREQuency:STARt

This command defines the start frequency of the analyzer. This command is only available with

span > 0.

The numeric suffixes <1|2> are not relevant.

Parameter

0to fmax

fmax is specified in the data sheet. To help analyze signals located at the end of the frequency

range, for R&S FSL models with an upper frequency limit of 6 GHz or less, the fmax value is

extended by 0.05 GHz for direct entry. The preset and maximum values remain unchanged.

Example

FREQ:STAR 20MHz

Characteristics

*RST value: 0

SCPI: conform

Mode

A–F, CATV, CDMA, EVDO

[SENSe<1|2>:]FREQuency:STOP

This command defines the stop frequency of the analyzer. This command is only available with

span > 0.

The numeric suffixes <1|2> are not relevant.

Parameter

0to fmax

fmax is specified in the data sheet. To help analyze signals located at the end of the frequency

range, for R&S FSL models with an upper frequency limit of 6 GHz or less, the fmax value is

extended by 0.05 GHz for direct entry. For the R&S FSL18 model, the fmax value is extended to

20 GHz. The preset and maximum values remain unchanged.

For the R&S FSL18, the query returns a maximum frequency of 20 GHz.

Example

FREQ:STOP 2000MHz

Characteristics

*RST value: fmax

SCPI: conform

Mode

A–F, CATV, CDMA, EVDO

R&S FSL SENSe Subsystem

1300.2519.12 6.205 E-11

SENSe:LIST Subsystem

The commands of this subsystem are used for measuring the power at a list of frequency points with

different device settings. The measurement is always performed in zero span. A new trigger event is

required for each test point (exception: trigger FREE RUN).

The results are output as a list in the order of the entered frequency points. The number of results per

test point depends on the number of concurrently active measurements (peak/RMS/average). The

number of frequencies is limited to 100 entries.

Selection of concurrently active measurements and setting of parameters that are constant for the

whole measurement is performed via a configuration command ([SENSe<1|2>:]LIST:POWer:SET).

This also includes the setting for trigger and gate parameters.

Note: Settings that are not directly included in commands of this subsystem can be configured by

sending the corresponding commands prior to the SENSe:LIST Subsystem commands.

Please note that changes to the trigger level have to be executed in zero span in order to take

effect for the SENSe:LIST Subsystem commands.

The following subsystem is included:

•"SENSe:LIST:RANGe Subsystem" on page 6.210

Commands of the SENSe:LIST Subsystem

–[SENSe<1|2>:]LIST:POWer[:SEQuence]

–[SENSe<1|2>:]LIST:POWer:RESult?

–[SENSe<1|2>:]LIST:POWer:SET

–[SENSe<1|2>:]LIST:POWer:STATe

Further information

–More details on the SENSe:LIST Subsystem

More details on the SENSe:LIST Subsystem

The following setting parameters can be selected independently for each frequency point:

•analyzer frequency

•reference level

•resolution filter

•resolution bandwidth

•video bandwidth

•measurement time

•detector

The commands of this subsystem can be used in two different ways:

•Instrument setup, measurement and querying of the results in a single command line. With this

method, there is the least delay between the measurement and the result output. However, it

requires the control computer to wait for the response from the instrument.

SENSe Subsystem R&S FSL

1300.2519.12 6.206 E-11

•Instrument setup and querying of the result list at the end of the measurement: With this method,

the control computer may be used for other activities while the measurement is being performed.

However, more time is needed for synchronization via service request.

[SENSe<1|2>:]LIST:POWer[:SEQuence]

This command configures the list of settings (max. 200 entries) for the multiple power

measurement and starts a measurement sequence. When synchronizing the command with

*OPC, a service request is generated as soon as all frequency points are processed and the

defined number of individual measurements is reached.

To reduce the setting time, all indicated parameters are set up simultaneously at each test point.

The query form of the command processes the list and immediately returns the list of results.

The number of results per test point depends on the setting of the

[SENSe<1|2>:]LIST:POWer:SET command.

The numeric suffixes <1|2> are not relevant.

Parameter

The following parameters are the settings for an individual frequency point. They are repeated

for every other frequency point.

<analyzer freq> Receive frequency for the signal to be measured (= center frequency

in manual operation)

Range of values: 0 Hz to max. frequency, depending on the

instrument model.

<ref level> Reference level

Range of values: +20 dBm to –130 dBm in 0.1 dB steps

<rf att> RF input attenuation

Range of values: 0 dB to 30 dB in 5 dB steps

<rf att 2> Only listed due to reasons of compatibility with the FSP family.

Takes no effect.

<filter type> For details refer to

"[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:TYPE"on page

6.176

<rbw> Resolution bandwidth

For the range of values refer to chapter "Instrument Functions",

section "Res BW Manual".

Refer to chapter "Instrument Functions", section "To choose the

appropriate filter type", for possible combinations of filter type and

filter bandwidth for the <filter type> = CFILter and <filter type> =

RRC.

<vbw> Video bandwidth

Range of values:1 Hz to 10 MHz in 1, 3, 10 steps. The value is

ignored for <filter type> = CFILter or RRC

<meas time> Measurement time

Range of values: 1us to 16000s

For details refer to chapter "Instrument Functions", section

"Sweeptime Manual"

<trigger level> Reserved. Must be set to 0.

R&S FSL SENSe Subsystem

1300.2519.12 6.207 E-11

Return values

The query command returns a list of comma–separated values (CSV) which contains the power

measurement results in floating–point format. The unit depends on the setting with

CALCulate<1|2>:UNIT:POWer

The command

SENSe:LIST:POWer?

935.2MHz,0dBm,10dB,OFF,NORM,1MHz,3MHz,440us,0,

935.4MHz,0dBm,10dB,10dB,NORM,30kHz,100kHz,440us,0,

935.6MHz,0dBm,10dB,20dB,NORM,30kHz,100kHz,440us,0

thus returns the following list, for example:

–28.3,–30.6,–38.1

If the command sequence is extended to

SENSe:LIST:POWer:SET ON,ON,ON,IMM,POS,0,0

SENSe:LIST:POWer?

935.2MHz,0dBm,10dB,OFF,NORM,1MHz,3MHz,440us,0,

935.4MHz,0dBm,10dB,10dB,NORM,30kHz,100kHz,440us,0,

935.6MHz,0dBm,10dB,20dB,NORM,30kHz,100kHz,440us,0

the result list is extended to 3 results per frequency point (peak, RMS and average):

–28.3, –29.6, 1.5, –30.6, –31.9, 0.9, –38.1, –40.0, 2.3

Example

SENSe:LIST:POWer

935.2MHz,0dBm,10dB,OFF,NORM,1MHz,3MHz,440us,0,

935.4MHz,0dBm,10dB,10dB,CFIL,30kHz,100kHz,440us,0,

935.6MHz,0dBm,10dB,20dB,CFIL,30kHz,100kHz,440us,0

Performs a measurement sequence with the following settings:

Step Freq.

[MHz]

Ref

Level

[dBm]

Att

[dB]

el Att

[dB]

Filter

type

RBW VBW Meas

Time

[us]

TRG Level

(reserved)

1935.2 0 10 OFF Normal 1 MHz 3 MHz 440 0

2935.4 0 10 10 Channel 30 kHz 100 kHz 440 0

3935.6 0 10 20 Channel 30 kHz 100 kHz 440 0

SENSe:LIST:POWer?

935.2MHz,0dBm,10dB,OFF,NORM,1MHz,3MHz,440us,0,

935.4MHz,0dBm,10dB,10dB,CFIL,30kHz,100kHz,440us,0,

935.6MHz,0dBm,10dB,20dB,CFIL,30kHz,100kHz,440us,0

Performs the same measurement and returns the result list immediately after the last frequency

point.

Note: The measurement is performed in zero span and therefore the span is set to 0 Hz. If the

span > 0 is set, the function is automatically switched off.

The measurement is not compatible with other measurements, especially as far as

marker, adjacent channel power measurement or statistics are concerned. The

corresponding commands thus automatically deactivate the function.

The function is only available in REMOTE operation. It is deactivated when switching

the instrument back to LOCAL.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F, A–T

SENSe Subsystem R&S FSL

1300.2519.12 6.208 E-11

[SENSe<1|2>:]LIST:POWer:RESult?

This command queries the result of a previous list measurement as configured and initiated with

[SENSe<1|2>:]LIST:POWer[:SEQuence].The measured results are output in a list of

floating point values separated by commas. The unit of the results depends on the setting made

with the CALCulate<1|2>:UNIT:POWer command.

This command may be used to obtain measurement results in an asynchronous way, using the

service request mechanism for synchronization with the end of the measurement.

If no measurement results are available, the command will return a query error.

The numeric suffixes <1|2> are not relevant.

Example

*ESE 1

*SRE 32

Configuration of the status reporting system for the generation of an SRQ on operation

complete

SENSe:LIST:POWer

935.2MHz,–20dBm,10dB,OFF,NORM,1MHz,3MHz,434us,0,

935.4MHz,–20dBm,10dB,10dB,NORM,30kHz,100kHz,434us,0,

935.6MHz,–20dBm,10dB,20dB,NORM,30kHz,100kHz,434us,0;

*OPC

Configuring and starting the measurement

...

Further actions of the control computer during measurement

On SRQ:

SENSe:LIST:POWer:RESult?

Response to service request

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F, A–T

[SENSe<1|2>:]LIST:POWer:SET

This command defines the constant settings for the list during multiple power measurement.

Parameters <PEAK meas>, <RMS meas> and <AVG meas> define, which measurements are

to be performed at the same time at the frequency point. Correspondingly, one, two or three

results per frequency point are returned for the [SENSe<1|2>:]LIST:POWer[:SEQuence]

command. If all three parameters are set to OFF, the command generates an execution error.

The numeric suffixes <1|2> are not relevant.

Parameter

<PEAK meas> ON: activates the measurement of the peak power (peak detector)

OFF: deactivates the measurement of the peak power

<RMS meas> ON: activates the measurement of the RMS power (RMS detector)

OFF: deactivates the measurement of the RMS power

<AVG meas> ON: activates the measurement of the average power (average

detector)

OFF: deactivates the measurement of the average power

<trigger mode> Selection of the trigger source used for the list measurement

R&S FSL SENSe Subsystem

1300.2519.12 6.209 E-11

Possible values: IMMediate | EXTernal | VIDeo | IFPower

<trigger slope> Used trigger slope

Possible values: POSitive | NEGative

<trigger offset> Offset between the detection of the trigger signal and the start of the

measurement at the next frequency point.

Range of values: 0 s, 125 ns to 100s

<gate length> Gate length with gated sweep

Range of values: 0 s, 125 ns to 100s

The value 0 s deactivates the use of gated trigger; other values

activate the gated trigger function.

Values <> 0 s are only possible if <trigger mode> is different from

IMMediate. Otherwise, an execution error is triggered.

Return values

The query command returns a list of comma–separated values (CSV) of the settings, i.e.

ON,ON,ON,IMM,POS,0,0

if the configuration has been set with the command

SENSe:LIST:POWer:SET ON,ON,ON,IMM,POS,0,0

Example

SENSe:LIST:POWer:SET ON,OFF,OFF,EXT,POS,10US,434US

Characteristics

*RST value: ON,OFF,OFF,IMM,POS,0S,0S

SCPI: device–specific

Mode

A–F, A–T

[SENSe<1|2>:]LIST:POWer:STATe

This command deactivates the list measurement.

The numeric suffixes <1|2> are not relevant.

Parameter

OFF

Example

SENSe:LIST:POWer:STATe OFF

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F, A–T

SENSe Subsystem R&S FSL

1300.2519.12 6.210 E-11

SENSe:LIST:RANGe Subsystem

The SENSe:LIST:RANGe Subsystem contains the remote commands to configure Spurious Emissions

measurements.

Commands of the SENSe:LIST:RANGe Subsystem

–[SENSe<1|2>:]LIST:RANGe<1...20>:BANDwidth

–[SENSe<1|2>:]LIST:RANGe<1...20>:BANDwidth:RESolution

–[SENSe<1|2>:]LIST:RANGe<1...20>:BANDwidth:VIDeo

–[SENSe<1|2>:]LIST:RANGe<1...20>:BREak

–[SENSe<1|2>:]LIST:RANGe<1...20>:DELete

–[SENSe<1|2>:]LIST:RANGe<1...20>:COUNt?

–[SENSe<1|2>:]LIST:RANGe<1...20>:DETector

–[SENSe<1|2>:]LIST:RANGe<1...20>[:FREQuency]:STARt

–[SENSe<1|2>:]LIST:RANGe<1...20>[:FREQuency]:STOP

–[SENSe<1|2>:]LIST:RANGe<1...20>:FILTer:TYPE

–[SENSe<1|2>:]LIST:RANGe<1...20>:INPut:ATTenuation

–[SENSe<1|2>:]LIST:RANGe<1...20>:INPut:ATTenuation:AUTO

–[SENSe<1|2>:]LIST:RANGe<1...20>:INPut:GAIN:STATe

–[SENSe<1|2>:]LIST:RANGe<1...20>:POINts

–[SENSe<1|2>:]LIST:RANGe<1...20>:RLEVel

–[SENSe<1|2>:]LIST:RANGe<1...20>:SWEep:TIME

–[SENSe<1|2>:]LIST:RANGe<1...20>:SWEep:TIME:AUTO

–[SENSe<1|2>:]LIST:RANGe<1...20>:LIMit:STARt

–[SENSe<1|2>:]LIST:RANGe<1...20>:LIMit:STOP

–[SENSe<1|2>:]LIST:RANGe<1...20>:LIMit:STATe

–[SENSe<1|2>:]LIST:RANGe<1...20>:TRANsducer

[SENSe<1|2>:]LIST:RANGe<1...20>:BANDwidth

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth" on page 6.190.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:BANDwidth:RESolution

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth:RESolution" on

page 6.190.

This command is available from firmware version 1.80.

R&S FSL SENSe Subsystem

1300.2519.12 6.211 E-11

[SENSe<1|2>:]LIST:RANGe<1...20>:BANDwidth:VIDeo

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth:VIDeo" on page

6.191.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:BREak

This command configures the sweep behavior.

The numeric suffixes are not relevant.

This command is available from firmware version 1.80.

Parameter

ON The R&S FSL stops after one range is swept and continues only if you confirm

(a message box is displayed).

OFF The R&S FSL sweeps all ranges in one go.

Example

LIST:RANG:BRE ON

Configures a stop after each range.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

[SENSe<1|2>:]LIST:RANGe<1...20>:DELete

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:DELete" on page 6.192.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:COUNt?

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:COUNt?" on page 6.191.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:DETector

This command sets the detector for the specified range. For details refer to chapter 4, "Detector

overview".

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

SENSe Subsystem R&S FSL

1300.2519.12 6.212 E-11

Parameter

APEak auto peak detector

NEGative minimum peak detector

POSitive peak detector

SAMPle sample detector

RMS RMS detector

AVERage average detector

Example

LIST:RANGe3:DET SAMP

Sets the sample detector for range 3.

Characteristics

RST value: RMS

SCPI: device–specific

Mode

[SENSe<1|2>:]LIST:RANGe<1...20>[:FREQuency]:STARt

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>[:FREQuency]:STARt" on page

6.192.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>[:FREQuency]:STOP

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>[:FREQuency]:STOP" on page

6.193.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:FILTer:TYPE

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:FILTer:TYPE" on page 6.193.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:INPut:ATTenuation

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:ATTenuation" on page

6.193.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:INPut:ATTenuation:AUTO

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:ATTenuation:AUTO" on

page 6.194.

This command is available from firmware version 1.80.

R&S FSL SENSe Subsystem

1300.2519.12 6.213 E-11

[SENSe<1|2>:]LIST:RANGe<1...20>:INPut:GAIN:STATe

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:GAIN:STATe" on page

6.194.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:POINts

This command sets the number of sweep points for the specified range.

The numeric suffixes <1...20> specify the range. The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

For details on possible values refer to chapter 4, Sweep Points softkey of the sweep menu.

Example

LIST:RANG3:POIN 601

Sets 601 sweep points for range 3.

Characteristics

RST value: 501

SCPI: device–specific

Mode

[SENSe<1|2>:]LIST:RANGe<1...20>:RLEVel

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:RLEVel" on page 6.197.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:SWEep:TIME

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:SWEep:TIME" on page 6.198.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:SWEep:TIME:AUTO

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:SWEep:TIME:AUTO" on page

6.198.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:LIMit:STARt

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:ABSolute:STARt" on page

6.195.

This command is available from firmware version 1.80.

SENSe Subsystem R&S FSL

1300.2519.12 6.214 E-11

[SENSe<1|2>:]LIST:RANGe<1...20>:LIMit:STOP

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:ABSolute:STOP" on page

6.195.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:LIMit:STATe

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:STATe" on page 6.197.

This command is available from firmware version 1.80.

[SENSe<1|2>:]LIST:RANGe<1...20>:TRANsducer

For details refer to "[SENSe<1|2>:]ESPectrum:RANGe<1...20>:TRANsducer" on page 6.198.

This command is available from firmware version 1.80.

R&S FSL SENSe Subsystem

1300.2519.12 6.215 E-11

SENSe:MPOWer Subsystem

The commands of this subsystem are used to determine the mean burst power or peak burst power for

agiven number of signal bursts, and for outputting the results in a list. Since all the settings required for

ameasurement are combined in a single command, the measurement speed is considerably higher

than when using individual commands.

For measuring the signal bursts, the gated sweep function is used in zero span. The gate is controlled

either by an external trigger signal or by the video signal. An individual trigger event is required for each

burst to be measured. If an external trigger signal is used, the threshold is fixed to TTL level, while with

avideo signal the threshold can be set as desired.

Commands of the SENSe:MPOWer Subsystem

–[SENSe<1|2>:]MPOWer[:SEQuence]

–[SENSe<1|2>:]MPOWer:FTYPe

–[SENSe<1|2>:]MPOWer:RESult[:LIST]?

–[SENSe<1|2>:]MPOWer:RESult:MIN?

Further information

–More details on the SENSe:MPOWer Subsystem

More details on the SENSe:MPOWer Subsystem

The following graphics shows the relation between trigger time, trigger offset (for delayed gate opening)

and measurement time.

Trigger

Signal

Trigger

Offset

Measurement

Time

Trigger

Signal

Trigger

Offset

Measurement

Time

Trigger

Signal

Trigger

Offset

Measurement

Time

Depending on the settings made, the measurements are performed with the RMS detector for RMS

power or the PEAK detector for peak power. For all these measurements, trace 1 of the selected

system is used.

The setting parameters for this measurement are:

•analyzer frequency

•resolution bandwidth

•measurement time used for a single burst

SENSe Subsystem R&S FSL

1300.2519.12 6.216 E-11

•trigger source

•trigger level

•trigger offset

•type of power measurement (PEAK, MEAN)

•number of bursts to be measured

The commands of this subsystem can be used in two different ways:

•Setting up the instrument and at the same time querying the result list: This method ensures the

smallest delay between measurement and the output of the measured values, but requires the

control computer to wait actively for the response of the instrument.

•Setting up the instrument and querying the result list after synchronization to the end of

measurement: With this method the control computer can be used for other activities while the

instrument is performing the measurement at the cost of additional time needed for synchronization

via service request.

[SENSe<1|2>:]MPOWer[:SEQuence]

This command configures the instrument setup for multiple burst power measurement and starts

ameasurement sequence. When synchronizing the command with *OPC, a service request is

generated as soon as the defined number of individual measurements (# of meas) is reached.

To reduce the setting time, the setup is performed simultaneously for all selected parameters.

The command in the form of a query makes the instrument settings, performs the defined

number of measurements and outputs the measurement results list.

The numeric suffixes <1|2> are not relevant.

Parameter

<analyzer freq> Receive frequency for the burst signals to be measured (= center

frequency in manual operation)

Range: 0 Hz to max. frequency, depending on instrument model

<rbw> resolution bandwidth for the measurement

Range: 10 Hz to 10 MHz in steps of 1, 3, 10

<meas time> Time span during which measurement samples are sampled for RMS

/peak measurement. The type of measurement is selected by <type

of meas>.

Range: 1us to 30s

<trigger

source>

trigger signal source. Possible settings:

EXTernal: The trigger signal is fed from the "Ext. Trigger/Gate" input

on the rear of the unit.

VIDeo: The internal video signal is used as trigger signal.

<trigger level> Signal level at which the trigger becomes active. For <trigger source>

=VIDeo this is the level of the video signal as a percentage of the

diagram height. If <trigger source> = EXTernal is selected, the value

entered here is ignored, as in this case the trigger input uses TTL

levels.

Range: 0 – 100PCT(<trigger source> = VIDeo)

<trigger offset> Offset between the detection of the trigger signal and the start of the

measurement.

Range: 125 ns to 100s

R&S FSL SENSe Subsystem

1300.2519.12 6.217 E-11

<type of meas> Determines whether mean power (RMS) or peak power (PEAK) is to

be measured. The detector is selected accordingly.

Possible values: MEAN, PEAK

<# of meas> Number of individual bursts to be measured.

Range: 1 to 32001

Return values

The query command returns a list separated by commas (comma separated values = CSV),

which contains the power measurement results in floating–point format. The unit used for the

return values is always dBm.

The command SENSe:MPOWer? 935.2MHz,1MHz,434us,VIDEO,50PCT,5us,MEAN,20

may, for instance, cause the following list to be returned:

18.3,18.6,18.1,18.0,17.9,18.3,18.6,18.1,18.0,17.9,18.3,18.6,18.1,18.0,17.9,18.3,18.6,18.1,18.0,

17.9

Example

SENSe:MPOWer 935.2MHz,1MHz,434us,VIDEO,50PCT,5us,MEAN,20

Performs a measurement sequence with the following settings:

Frequency = 935.2 MHz,

Resolution bandwidth = 1 MHz

Measurement time = 434 µs

Trigger source = VIDEO

Trigger threshold = 50%

Trigger offset = 5 µs

Type of measurement = MEAN power

No. of measurements = 20

SENSe:MPOWer? 935.2MHz,1MHz,434us,VIDEO,50PCT,5us,MEAN,20

Performs the same measurement and in addition returns the results list immediately after

completion of the last measurement.

Note: The measurement function always uses trace 1.

Repeated use of the command without changes to its parameters (i.e. using the same

settings again) will speed up the measurement since the previous hardware settings will

be cached and therefore additional hardware settling times will be avoided. This also

holds true if only part of the parameters (e.g. only the trigger delay) are changed, as in

this case the rest of the parameters will be cached.

This measurement is not compatible with other measurements, especially as far as

marker functions, adjacent–channel measurement or statistics are concerned. The

corresponding functions are therefore automatically switched off. In return incompatible

commands will automatically deactivate the multi burst power function.

The function is only available in the REMOTE operation. It is deactivated on switching

back to LOCAL.

Characteristics

*RST value: –

SCPI: device–specific

Mode

SENSe Subsystem R&S FSL

1300.2519.12 6.218 E-11

[SENSe<1|2>:]MPOWer:FTYPe

This command defines the filter type for the measurement.

The numeric suffixes <1|2> are not relevant.

Parameter

NORMal | CFILter | RRC

Example

SENSe:MPOWer:FTYPe CFILter

Characteristics

*RST value: –

SCPI: device–specific

Mode

[SENSe<1|2>:]MPOWer:RESult[:LIST]?

This command queries the results of a multiple burst power measurement as configured and

initiated with [SENSe<1|2>:]MPOWer[:SEQuence].The results are output in a comma–

separated list of floating point values. The unit used for the return values is always dBm.

This command may be used to obtain measurement results in an asynchronous way using the

service request mechanism for synchronization with the end of the measurement.

The numeric suffixes <1|2> are not relevant.

If no measurement results are available, the command will return a query error.

Example

*ESE 1

*SRE 32

Configuration of status reporting systems for the generation of an SRQ on operation complete

SENSe:MPOWer 935.2MHz,1MHz,434us,VIDEO,50PCT,5us,MEAN,20;*OPC

Configuring and starting the measurement

...

Further actions of the control computer during measurement

On SRQ:

Response to service request

SENSe:MPOWer:RESult?

Characteristics

*RST value: –

SCPI: device–specific

Mode

R&S FSL SENSe Subsystem

1300.2519.12 6.219 E-11

[SENSe<1|2>:]MPOWer:RESult:MIN?

This command queries the minimum power value in a multiple burst power measurement as

configured and initiated with [SENSe<1|2>:]MPOWer[:SEQuence].The unit used for the

return values is always dBm.

The numeric suffixes <1|2> are not relevant.

If no measurement result is available, the command will return a query error.

Example

*ESE 1

*SRE 32

Configuration of status reporting systems for the generation of an SRQ on operation complete

SENSe:MPOWer 935.2MHz,1MHz,434us,VIDEO,50PCT,5us,MEAN,20;*OPC

Configuring and starting the measurement

...

Further actions of the control computer during measurement

On SRQ:

Response to service request

SENSe:MPOWer:RESult:MIN?

Characteristics

*RST value: –

SCPI: device–specific

Mode

SENSe Subsystem R&S FSL

1300.2519.12 6.220 E-11

SENSe:POWer Subsystem

This subsystem controls the setting of the instruments channel and adjacent channel power

measurements.

Commands of the SENSe:POWer Subsystem

–[SENSe<1|2>:]POWer:ACHannel:ACPairs

–[SENSe<1|2>:]POWer:ACHannel:BANDwidth|BWIDth[:CHANnel]

–[SENSe<1|2>:]POWer:ACHannel:BANDwidth|BWIDth:ACHannel

–[SENSe<1|2>:]POWer:ACHannel:BANDwidth|BWIDth:ALTernate<1...11>

–[SENSe<1|2>:]POWer:ACHannel:MODE

–[SENSe<1|2>:]POWer:ACHannel:PRESet

–[SENSe<1|2>:]POWer:ACHannel:PRESet:RLEVel

–[SENSe<1|2>:]POWer:ACHannel:REFerence:AUTO

–[SENSe<1|2>:]POWer:ACHannel:REFerence:TXCHannel:AUTO

–[SENSe<1|2>:]POWer:ACHannel:REFerence:TXCHannel:MANual

–[SENSe<1|2>:]POWer:ACHannel:SPACing[:ACHannel]

–[SENSe<1|2>:]POWer:ACHannel:SPACing:ALTernate<1...11>

–[SENSe<1|2>:]POWer:ACHannel:SPACing:CHANnel

–[SENSe<1|2>:]POWer:ACHannel:TXCHannel:COUNt

–[SENSe<1|2>:]POWer:BANDwidth|BWIDth

–[SENSe<1|2>:]POWer:HSPeed

–[SENSe<1|2>:]POWer:TRACe

[SENSe<1|2>:]POWer:ACHannel:ACPairs

This command sets the number of adjacent channels (upper and lower channel in pairs).The

figure 0 stands for pure channel power measurement.

The numeric suffixes <1|2> are not relevant.

Parameter

1to 12

Example

POW:ACH:ACP 3

Sets the number of adjacent channels to 3, i.e. the adjacent channel and alternate adjacent

channels 1 and 2 are switched on.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

A–F

R&S FSL SENSe Subsystem

1300.2519.12 6.221 E-11

[SENSe<1|2>:]POWer:ACHannel:BANDwidth|BWIDth[:CHANnel]

This command sets the channel bandwidth of the radio communication system. The bandwidths

of adjacent channels are not influenced by this modification.

With [SENSe<1|2>:]POWer:HSPeed set to ON, steep–edged channel filters are available.

For further information on filters refer to chapter "Instrument Functions", section "List of

available RRC and channel filters".

The numeric suffixes <1|2> are not relevant.

Parameter

100 Hz to 1000 MHz

Example

POW:ACH:BWID 30kHz

Sets the bandwidth of the TX channel to 30 kHz.

Characteristics

*RST value: 14 kHz

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:ACHannel:BANDwidth|BWIDth:ACHannel

This command defines the channel bandwidth of the adjacent channel of the radio transmission

system. If the bandwidth of the adjacent channel is changed, the bandwidths of all alternate

adjacent channels are automatically set to the same value.

With [SENSe<1|2>:]POWer:HSPeed set to ON, steep–edged channel filters are available.

For further information on filters refer to chapter "Instrument Functions", section "List of

available RRC and channel filters".

The numeric suffixes <1|2> are not relevant.

Parameter

100 Hz to 1000 MHz

Example

POW:ACH:BWID:ACH 30kHz

Sets the bandwidth of all adjacent channels to 30 kHz.

Characteristics

*RST value: 14 kHz

SCPI: device–specific

Mode

A–F

SENSe Subsystem R&S FSL

1300.2519.12 6.222 E-11

[SENSe<1|2>:]POWer:ACHannel:BANDwidth|BWIDth:ALTernate<1...11>

This command defines the channel bandwidth of the alternate adjacent channels of the radio

transmission system. If the channel bandwidth of alternate adjacent channel 1 is changed, the

bandwidth of alternate adjacent channels 2 to 11 is automatically set to the same value.

With [SENSe<1|2>:]POWer:HSPeed set to ON, steep–edged channel filters are available.

For further information on filters refer to chapter "Instrument Functions", section "List of

available RRC and channel filters".

Parameter

100 Hz to 1000 MHz

Example

POW:ACH:BWID:ALT2 30kHz

Characteristics

*RST value: 14 kHz

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:ACHannel:MODE

This command switches between absolute and relative adjacent channel measurement. The

command is only available with span > 0 and if the number of adjacent channel is greater than 0.

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.10.

Parameter

ABSolute | RELative

Example

POW:ACH:MODE REL

Sets the adjacent channel measurement mode to relative.

Characteristics

RST value: RELative

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:ACHannel:PRESet

This command adjusts the frequency span, the measurement bandwidths and the detector as

required for the number of channels, the channel bandwidths and the channel spacings selected

in the active power measurement. If necessary, adjacent–channel power measurement is

switched on prior to the adjustment.

To obtain correct results, a complete sweep with synchronization to the end of the sweep must

be performed after the adjustment. Synchronization is possible only in the single sweep mode.

The result is queried with the CALCulate<1|2>:MARKer:FUNCtion:POWer:RESult?

command.

The numeric suffixes <1|2> are not relevant.

R&S FSL SENSe Subsystem

1300.2519.12 6.223 E-11

Parameter

Example

POW:ACH:PRES ACP

Sets the frequency span, the measurement bandwidths and the detector as required for the

ACP measurement.

INIT:CONT OFF

Switches over to single sweep mode.

INIT;*WAI

Starts a sweep and waits for the end of the sweep.

CALC:MARK:FUNC:POW:RES? ACP

Queries the result of the adjacent–channel power measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:ACHannel:PRESet:RLEVel

This command adapts the reference level to the measured channel power and – if required –

switches on previously the adjacent channel power measurement. This ensures that the signal

path of the instrument is not overloaded. Since the measurement bandwidth is significantly

smaller than the signal bandwidth in channel power measurements, the signal path can be

overloaded although the trace is still significantly below the reference level. If the measured

channel power equals the reference level, the signal path is not overloaded.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

Note: Subsequent commands have to be synchronized with *WAI,*OPC or *OPC? to the end

of the auto range process which would otherwise be aborted.

Example

POW:ACH:PRES:RLEV;*WAI

Adapts the reference level to the measured channel power.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F, CATV, WCDMA

[SENSe<1|2>:]POWer:ACHannel:REFerence:AUTO

This command sets the reference value to the currently measured channel power for the relative

measurement.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

Parameter

ONCE

SENSe Subsystem R&S FSL

1300.2519.12 6.224 E-11

Example

POW:ACH:REF:AUTO ONCE

Characteristics

RST value: –

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:ACHannel:REFerence:TXCHannel:AUTO

This command activates the automatic selection of a transmission channel to be used as a

reference channel in relative adjacent–channel power measurements.

The transmission channel with the highest power, the transmission channel with the lowest

power, or the transmission channel nearest to the adjacent channels can be defined as a

reference channel.

The command is available only for multicarrier channel and adjacent–channel power

measurements with span > 0 (CALCulate<1|2>:MARKer:FUNCtion:POWer:SELect).

The numeric suffixes <1|2> are not relevant.

Parameter

MINimum Transmission channel with the lowest power

MAXimum Transmission channel with the highest power

LHIGhest Lowermost transmission channel for the lower adjacent channels,

uppermost transmission channel for the upper adjacent channels

Example

POW:ACH:REF:TXCH:AUTO MAX

The transmission channel with the highest power is used as a reference channel.

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:ACHannel:REFerence:TXCHannel:MANual

This command selects a transmission channel to be used as a reference channel in relative

adjacent–channel power measurements.

The command is available only for multicarrier channel and adjacent–channel power

measurements with span > 0 (CALCulate<1|2>:MARKer:FUNCtion:POWer:SELect).

The numeric suffixes <1|2> are not relevant.

Parameter

1to 12

Example

POW:ACH:REF:TXCH:MAN 3

Transmission channel 3 is used as a reference channel.

R&S FSL SENSe Subsystem

1300.2519.12 6.225 E-11

Characteristics

*RST value: 1

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:ACHannel:SPACing[:ACHannel]

This command defines the spacing between the carrier signal and the adjacent channel (ADJ).

The modification of the adjacent–channel spacing (ADJ) causes a change in all higher

adjacent–channel spacings (ALT1, ALT2, ...): they are all multiplied by the same factor (new

spacing value / old spacing value).

The numeric suffixes <1|2> are not relevant.

Parameter

100 Hz to 2000 MHz

Example

POW:ACH:SPAC 33kHz

Sets the spacing between the carrier signal and the adjacent channel to 33 kHz, the alternate

adjacent channel 1 to 66 kHz, the alternate adjacent channel 2 to 99 kHz, and so on.

Characteristics

*RST value: 14 kHz

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:ACHannel:SPACing:ALTernate<1...11>

This command defines the spacing between the alternate adjacent channels and the TX

channel (ALT1, ALT2, ...). A modification of a higher adjacent–channel spacing causes a

change by the same factor (new spacing value / old spacing value) in all higher adjacent–

channel spacings, while the lower adjacent–channel spacings remain unchanged.

The numeric suffixes <1...11> defines the alternate adjacent channel. The numeric suffixes

<1|2> are not relevant.

Parameter

100 Hz to 2000 MHz

Example

POW:ACH:SPAC:ALT1 100kHz

Sets the spacing between TX channel and alternate adjacent channel 1 (ALT1) from 40 kHz to

100 kHz. In consequence, the spacing between the TX channel and all higher alternate adjacent

channels is increased by the factor 100/40 = 2.5: ALT2 = 150 kHz, ALT3 = 200 kHz, ALT4 = 250

kHz.

Characteristics

*RST value: 40 kHz (ALT1), 60 kHz (ALT2), 80 kHz (ALT3), ...

SCPI: device–specific

Mode

A–F

SENSe Subsystem R&S FSL

1300.2519.12 6.226 E-11

[SENSe<1|2>:]POWer:ACHannel:SPACing:CHANnel<1...11>

This command defines the channel spacing for the carrier signals.

The numeric suffixes <1...11> defines the TX channel. The numeric suffixes <1|2> are not

relevant.

Parameter

14 kHz to 2000 MHz

Example

POW:ACH:SPAC:CHAN 25kHz

Characteristics

*RST value: 20 kHz

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:ACHannel:TXCHannel:COUNt

This command selects the number of carrier signals.

The command is available only for multicarrier channel and adjacent–channel power

measurements with span > 0 (CALCulate<1|2>:MARKer:FUNCtion:POWer:SELect).

The numeric suffixes <1|2> are not relevant.

Parameter

1to 12

Example

POW:ACH:TXCH:COUN 3

Characteristics

*RST value: 1

SCPI: device–specific

Mode

[SENSe<1|2>:]POWer:BANDwidth|BWIDth

This command defines the percentage of the power with respect to the total power. This value is

the basis for the occupied bandwidth measurement

([SENSe<1|2>:]POWer:ACHannel:PRESet).

The numeric suffixes <1|2> are not relevant.

Parameter

10 to 99.9PCT

Example

POW:BWID 95PCT

R&S FSL SENSe Subsystem

1300.2519.12 6.227 E-11

Characteristics

*RST value: 99PCT

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:HSPeed

This command switches on or off the high–speed channel/adjacent channel power

measurement. The measurement itself is performed in zero span on the center frequencies of

the individual channels. The command automatically switches to zero span and back.

Depending on the selected mobile radio standard, weighting filters with cos characteristic or

very steep–sided channel filters are used for band limitation.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

POW:HSP ON

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–F

[SENSe<1|2>:]POWer:TRACe

This command assigns the channel/adjacent channel power measurement to the indicated

trace. The corresponding trace must be active, i.e. its state must be different from blank.

The numeric suffixes <1|2> are not relevant.

Note: The measurement of the occupied bandwidth (OBW) is performed on the trace on

which marker 1 is positioned. To evaluate another trace, marker 1 must be positioned to

another trace with CALCulate<1|2>:MARKer<1...4>:TRACe.

Parameter

1to 6

Example

POW:TRAC 2

Assigns the measurement to trace 2.

Characteristics

*RST value: –

SCPI: device–specific

Mode

SENSe Subsystem R&S FSL

1300.2519.12 6.228 E-11

SENSe:ROSCillator Subsystem

This subsystem controls the reference oscillator. The numeric suffix in SENSe is irrelevant for the

commands of this subsystem.

Commands of the SENSe:ROSCillator Subsystem

–[SENSe<1|2>:]ROSCillator:SOURce

[SENSe<1|2>:]ROSCillator:SOURce

This command controls selection of the reference oscillator.

If the external reference oscillator is selected, the reference signal must be connected to the

rear panel of the instrument.

Parameter

INTernal | EXTernal

Example

ROSC:SOUR EXT

Characteristics

*RST value: -

SCPI: conform

Mode

all

R&S FSL SENSe Subsystem

1300.2519.12 6.229 E-11

SENSe:SWEep Subsystem

The SENSe:SWEep subsystem controls the sweep parameters.

Commands of the SENSe:SWEep Subsystem

–[SENSe<1|2>:]SWEep:COUNt

–[SENSe<1|2>:]SWEep:COUNt:CURRent?

–[SENSe<1|2>:]SWEep:EGATe

–[SENSe<1|2>:]SWEep:EGATe:HOLDoff

–[SENSe<1|2>:]SWEep:EGATe:LENGth

–[SENSe<1|2>:]SWEep:EGATe:POLarity

–[SENSe<1|2>:]SWEep:EGATe:SOURce

–[SENSe<1|2>:]SWEep:EGATe:TYPE

–[SENSe<1|2>:]SWEep:MODE

–[SENSe<1|2>:]SWEep:POINts

–[SENSe<1|2>:]SWEep:TIME

–[SENSe<1|2>:]SWEep:TIME:AUTO

[SENSe<1|2>:]SWEep:COUNt

In analyzer mode, the command defines the number of sweeps started with single sweep, which

are used for calculating the average or maximum value. If the values 0 or 1 are set, one sweep

is performed.

The numeric suffixes <1|2> are not relevant.

Parameter

0to 32767

Example

SWE:COUN 64

Sets the number of sweeps to 64.

INIT:CONT OFF

Switches to single sweep mode.

INIT;*WAI

Starts a sweep and waits for its end.

Characteristics

*RST value: 0

SCPI: conform

Mode

A, ADEMOD, CATV, CDMA, EVDO, WCDMA

SENSe Subsystem R&S FSL

1300.2519.12 6.230 E-11

[SENSe<1|2>:]SWEep:COUNt:CURRent?

This query command returns the current number of started sweeps. A sweep count value

should be set and the device should be in single sweep mode.

The numeric suffixes <1|2> are not relevant.

Example

SWE:COUNt 64

Sets sweep count to 64

INIT:CONT OFF

Switches to single sweep mode

INIT

Starts a sweep (without waiting for the sweep end!)

SWE:COUN:CURR?

Queries the number of started sweeps

Characteristics

*RST value: 0

SCPI: conform

Mode

A, ADEMOD

[SENSe<1|2>:]SWEep:EGATe

This command switches on/off the sweep control by an external gate signal. If the external gate

is selected the trigger source is automatically switched to EXTernal as well.

In case of measurement with external gate, the measured values are recorded as long as the

gate is opened. During a sweep the gate can be opened and closed several times. The

synchronization mechanisms with *OPC, *OPC? and *WAI remain completely unaffected.

The sweep end is detected when the required number of measurement points (501 in

Spectrum Analyzer mode) has been recorded.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

SWE:EGAT ON

Switches on the external gate mode.

SWE:EGAT:TYPE EDGE

Switches on the edge–triggered mode.

SWE:EGAT:HOLD 100US

Sets the gate delay to 100 µs.

SWE:EGAT:LEN 500US

Sets the gate opening time to 500 µs.

INIT;*WAI

Starts a sweep and waits for its end.

R&S FSL SENSe Subsystem

1300.2519.12 6.231 E-11

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A, WLAN, OFDM, OFDMA/WiBro

[SENSe<1|2>:]SWEep:EGATe:HOLDoff

This command defines the delay time between the external gate signal and the continuation of

the sweep.

The numeric suffixes <1|2> are not relevant.

Parameter

125 Usto 100 s

Example

SWE:EGAT:HOLD 100us

Characteristics

*RST value: 0s

SCPI: device–specific

Mode

A, BT

[SENSe<1|2>:]SWEep:EGATe:LENGth

In case of edge triggering, this command determines the time interval during which the

instrument sweeps.

The numeric suffixes <1|2> are not relevant.

Parameter

0to 100 s

Example

SWE:EGAT:LENG 10ms

Characteristics

*RST value: 0s

SCPI: device–specific

Mode

A, BT

[SENSe<1|2>:]SWEep:EGATe:POLarity

This command determines the polarity of the external gate signal. The setting applies both to

the edge of an edge–triggered signal and the level of a level–triggered signal.

The numeric suffixes <1|2> are not relevant.

Parameter

POSitive | NEGative

SENSe Subsystem R&S FSL

1300.2519.12 6.232 E-11

Example

SWE:EGAT:POL POS

Characteristics

*RST value: POSitive

SCPI: device–specific

Mode

[SENSe<1|2>:]SWEep:EGATe:SOURce

This command toggles between external gate signal and IF power signal as a signal source for

the gate mode. If an IF power signal is used, the gate is opened as soon as a signal at > –20

dBm is detected within the IF path bandwidth (10 MHz).

The numeric suffixes <1|2> are not relevant.

Parameter

EXTernal | IFPower | VIDeo

Example

SWE:EGAT:SOUR IFP

Switches the gate source to IF power.

Characteristics

*RST value: IFPower

SCPI: device–specific

Mode

[SENSe<1|2>:]SWEep:EGATe:TYPE

This command sets the type of triggering (level or edge) by the external gate signal.

The gate is edge–triggered ([SENSe<1|2>:]SWEep:EGATe:TYPE EDGE):

After detection of the set gate signal edge, the gate remains open until the gate delay

([SENSe<1|2>:]SWEep:EGATe:HOLDoff) has expired.

The gate is level–triggered ([SENSe<1|2>:]SWEep:EGATe:TYPE LEVel):

After detection of the gate signal, the gate remains open until the gate signal disappears. The

gate opening time cannot be defined with the parameter

[SENSe<1|2>:]SWEep:EGATe:LENGth.

Adelay between applying the gate signal and the start of recording measured values can be

defined with [SENSe<1|2>:]SWEep:EGATe:HOLDoff.

The numeric suffixes <1|2> are not relevant.

Parameter

LEVel | EDGE

Example

SWE:EGAT:TYPE EDGE

R&S FSL SENSe Subsystem

1300.2519.12 6.233 E-11

Characteristics

*RST value: EDGE

SCPI: device–specific

Mode

[SENSe<1|2>:]SWEep:MODE

This command changes from Spectrum Analyzer to Spectrum Emission Mask or Spurious

Emissions measurement mode and back.

The numeric suffixes <1|2> are not relevant.

This command is available from firmware version 1.80.

Parameter

AUTO Switches to Spectrum Analyzer measurement mode or stays in the

current mode if it is not ESP / LIST

ESPectrum Spectrum Emission Mask measurement mode

LIST Spurious Emissions measurement mode

Example

SWE:MODE ESP

Sets the Spectrum Emission Mask measurement mode.

Characteristics

RST value: AUTO

SCPI: device–specific

Mode

A, CDMA, EVDO

[SENSe<1|2>:]SWEep:POINts

This command defines the number of measurement points to be collected during one sweep.

The numeric suffixes <1|2> are not relevant.

Parameter

101 to 32001

Example

SWE:POIN 251

Characteristics

*RST value: 501

SCPI: conform

Mode

A, CATV, CDMA, EVDO, SPECM

SENSe Subsystem R&S FSL

1300.2519.12 6.234 E-11

[SENSe<1|2>:]SWEep:TIME

In analyzer mode, this command defines the sweep time. The available time values vary

depending on the span setting.

If [SENSe<1|2>:]SWEep:TIME is directly programmed, automatic coupling to resolution

bandwidth and video bandwidth is switched off.

The numeric suffixes <1|2> are not relevant.

Parameter

refer to data sheet

Example

SWE:TIME 10s

Characteristics

*RST value: – (AUTO is set to ON)

SCPI: conform

Mode

A, ADEMOD, NF, CATV, CDMA, EVDO, OFDM, OFDMA/WiBro, SPECM, WLAN

[SENSe<1|2>:]SWEep:TIME:AUTO

This command controls the automatic coupling of the sweep time to the frequency span and

bandwidth settings.

If [SENSe<1|2>:]SWEep:TIME is directly programmed, automatic coupling is switched off.

The numeric suffixes <1|2> are not relevant.

Parameter

ON | OFF

Example

SWE:TIME:AUTO ON

Switches on the coupling to frequency span and bandwidths.

Characteristics

*RST value: ON

SCPI: conform

Mode

A, CATV, CDMA, EVDO, SPECM

R&S FSL SOURce Subsystem

1300.2519.12 6.235 E-11

SOURce Subsystem

The SOURce subsystem controls the output signals of the instrument.

The following subsystem is included:

•"SOURce:POWer Subsystem" on page 6.235

Commands of the SOURce subsystem

–SOURce<1|2>:EXTernal<1|2>:ROSCillator[:SOURce]

–SOURce:TEMPerature:APRobe?

SOURce<1|2>:EXTernal<1|2>:ROSCillator[:SOURce]

This command switches between external and internal reference oscillator.

Parameter

INTernal | EXTernal

Example

SOUR:EXT:ROSC EXT

Switches to external reference oscillator

Characteristics

*RST value: INT

SCPI: device-specific

Mode

all

SOURce:TEMPerature:APRobe?

This command queries the sensor temperature.

Parameter

1(CPU)

Example

SOUR:TEMP:APR? 1

Queries the temperature of the CPU sensor.

Characteristics

RST value: -

SCPI: device-specific

Mode

all

SOURce Subsystem R&S FSL

1300.2519.12 6.236 E-11

SOURce:POWer Subsystem (models with tracking generator)

The SOURce:POWer subsystem controls the power of the tracking generator signal.

Commands of the SOURce:POWer Subsystem

–SOURce<1|2>:POWer[:LEVel][:IMMediate][:AMPLitude]

–SOURce<1|2>:POWer[:LEVel][:IMMediate]:OFFSet

SOURce<1|2>:POWer[:LEVel][:IMMediate][:AMPLitude]

This command defines the output level of the tracking generator.

Parameter

<numeric_value> in dBm, range specified in data sheet;

–400 dBm: switches off the tracking generator and keeps the corresponding hardware settings

and the normalization

Example

SOUR:POW –20dBm

Sets the tracking generator level to –20 dBm.

Characteristics

*RST value: –20 dBm

SCPI: conform

Mode

all

SOURce<1|2>:POWer[:LEVel][:IMMediate]:OFFSet

This command defines a level offset for the tracking generator level. Thus, for example,

attenuators or amplifiers at the output of the tracking generator can be taken into account for the

setting.

Parameter

–200 dB to +200 dB

Example

SOUR:POW:OFFS –10dB

Sets the level offset of the tracking generator to – 20 dBm.

Characteristics

*RST value: 0dB

SCPI: conform

Mode

all

R&S FSL STATus Subsystem

1300.2519.12 6.237 E-11

STATus Subsystem

The STATus subsystem contains the commands for the status reporting system (for details refer to

chapter 5 "Remote Control – Basics", section "Status Reporting System"). *RST does not influence the

status registers.

The following subsystem is included:

•"STATus:QUEStionable Subsystem" on page 6.239

Commands of the STATus subsystem

–STATus:OPERation[:EVENt]?

–STATus:OPERation:CONDition?

–STATus:OPERation:ENABle

–STATus:OPERation:PTRansition

–STATus:OPERation:NTRansition

–STATus:PRESet

STATus:OPERation[:EVENt]?

This command queries the contents of the EVENt section of the STATus:OPERation register.

The contents of the EVENt section are deleted after readout.

Example

STAT:OPER?

Characteristics

*RST value: -

SCPI: conform

Mode

all

STATus:OPERation:CONDition?

This command queries the CONDition section of the STATus:OPERation register. Readout

does not delete the contents of the CONDition section. The value returned reflects the current

hardware status.

Example

STAT:OPER:COND?

Characteristics

*RST value: -

SCPI: conform

Mode

all

STATus Subsystem R&S FSL

1300.2519.12 6.238 E-11

STATus:OPERation:ENABle

This command sets the bits of the ENABle section of the STATus:OPERation register. The

ENABle register selectively enables the individual events of the associated EVENt section for

the summary bit in the status byte.

Parameter

0to 65535

Example

STAT:OPER:ENAB 65535

Characteristics

*RST value: -

SCPI: conform

Mode

all

STATus:OPERation:PTRansition

This command sets the edge detectors of all bits of the STATus:OPERation register from 0 to 1

for the transitions of the CONDition bit.

Parameter

0to 65535

Example

STAT:OPER:PTR 65535

Characteristics

*RST value: -

SCPI: conform

Mode

all

STATus:OPERation:NTRansition

This command sets the edge detectors of all bits of the STATus:OPERation register from 1 to 0

for the transitions of the CONDition bit.

Parameter

0to 65535

Example

STAT:OPER:NTR 65535

Characteristics

*RST value: -

SCPI: conform

Mode

all

R&S FSL STATus Subsystem

1300.2519.12 6.239 E-11

STATus:PRESet

This command resets the edge detectors and ENABle parts of all registers to a defined value.

All PTRansition parts are set to FFFFh, i.e. all transitions from 0 to 1 are detected. All

NTRansition parts are set to 0, i.e. a transition from 1 to 0 in a CONDition bit is not detected.

The ENABle part of the STATus:OPERation and STATus:QUEStionable registers are set to 0,

i.e. all events in these registers are not passed on.

Example

STAT:PRES

Characteristics

*RST value: -

SCPI: conform

Mode

all

STATus:QUEStionable Subsystem

The STATus:QUEStionable subsystem contains information about the observance of limits during

adjacent power measurements, the reference and local oscillator, the observance of limit lines and limit

margins and possible overloads of the unit.

Commands of the STATus:QUEStionable Subsystem

–STATus:QUEStionable[:EVENt]?

–STATus:QUEStionable:CONDition?

–STATus:QUEStionable:ENABle

–STATus:QUEStionable:PTRansition

–STATus:QUEStionable:NTRansition

–STATus:QUEStionable:ACPLimit[:EVENt]?

–STATus:QUEStionable:ACPLimit:CONDition?

–STATus:QUEStionable:ACPLimit:ENABle

–STATus:QUEStionable:ACPLimit:NTRansition

–STATus:QUEStionable:ACPLimit:PTRansition

–STATus:QUEStionable:FREQuency[:EVENt]?

–STATus:QUEStionable:FREQuency:CONDition?

–STATus:QUEStionable:FREQuency:ENABle

–STATus:QUEStionable:FREQuency:NTRansition

–STATus:QUEStionable:FREQuency:PTRansition

–STATus:QUEStionable:LIMit<1|2>[:EVENt]?

–STATus:QUEStionable:LIMit<1|2>:CONDition?

–STATus:QUEStionable:LIMit<1|2>:ENABle

–STATus:QUEStionable:LIMit<1|2>:NTRansition

–STATus:QUEStionable:LIMit<1|2>:PTRansition

–STATus:QUEStionable:LMARgin<1|2>[:EVENt]?

STATus Subsystem R&S FSL

1300.2519.12 6.240 E-11

–STATus:QUEStionable:LMARgin<1|2>:CONDition?

–STATus:QUEStionable:LMARgin<1|2>:ENABle

–STATus:QUEStionable:LMARgin<1|2>:NTRansition

–STATus:QUEStionable:LMARgin<1|2>:PTRansition

–STATus:QUEStionable:POWer[:EVENt]?

–STATus:QUEStionable:POWer:CONDition?

–STATus:QUEStionable:POWer:ENABle

–STATus:QUEStionable:POWer:NTRansition

–STATus:QUEStionable:POWer:PTRansition

–STATus:QUEStionable:SYNC[:EVENt]?

–STATus:QUEStionable:SYNC:CONDition?

–STATus:QUEStionable:SYNC:ENABle

–STATus:QUEStionable:SYNC:NTRansition

–STATus:QUEStionable:SYNC:PTRansition

STATus:QUEStionable[:EVENt]?

This command queries the contents of the EVENt section of the STATus:QUEStionable register.

The contents of the EVENt section are deleted after the readout.

Example

STAT:QUES?

Characteristics

*RST value: -

SCPI: conform

Mode

all

STATus:QUEStionable:CONDition?

This command queries the CONDition section of the STATus:QUEStionable register. Readout

does not delete the contents of the CONDition section.

Example

STAT:QUES:COND?

Characteristics

*RST value: -

SCPI: conform

Mode

all

R&S FSL STATus Subsystem

1300.2519.12 6.241 E-11

STATus:QUEStionable:ENABle

This command sets the bits of the ENABle section of the STATus:QUEStionable register. The

ENABle register selectively enables the individual events of the associated EVENt section for

the summary bit in the status byte.

Parameter

0to 65535

Example

STAT:QUES:ENAB 65535

Characteristics

*RST value: -

SCPI: conform

Mode

all

STATus:QUEStionable:PTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable register from 0

to 1 for the transitions of the CONDition bit.

Parameter

0to 65535

Example

STAT:QUES:PTR 65535

Characteristics

*RST value: -

SCPI: conform

Mode

all

STATus:QUEStionable:NTRansition

This command sets the edge detectors of all bits of the STATus:OPERation register from 1 to 0

for the transitions of the CONDition bit.

Parameter

0to 65535

Example

STAT:QUES:NTR 65535

Characteristics

*RST value: -

SCPI: conform

Mode

all

STATus Subsystem R&S FSL

1300.2519.12 6.242 E-11

STATus:QUEue[:NEXT?]

This command queries the earliest error queue entry and deletes it.

Positive error numbers indicate device-specific errors, negative error numbers are error

messages defined by SCPI. If the error queue is empty, the error number 0, "No error", is

returned. This command is identical to the SYSTem:ERRor[:NEXT]? command.

Example

STAT:QUES?

Characteristics

*RST value: -

SCPI: conform

Mode

all

STATus:QUEStionable:ACPLimit[:EVENt]?

This command queries the contents of the EVENt section of the

STATus:QUEStionable:ACPLimit register. Readout deletes the contents of the EVENt section.

Example

STAT:QUES:ACPL?

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:ACPLimit:CONDition?

This command queries the contents of the CONDition section of the

STATus:QUEStionable:ACPLimit register. Readout does not delete the contents of the

CONDition section.

Example

STAT:QUES:ACPL:COND?

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

R&S FSL STATus Subsystem

1300.2519.12 6.243 E-11

STATus:QUEStionable:ACPLimit:ENABle

This command sets the bits of the ENABle section of the STATus:QUEStionable:ACPLimit

section for the summary bit.

Parameter

0to 65535

Example

STAT:QUES:ACPL:ENAB 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:ACPLimit:NTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable: ACPLimit

Parameter

0to 65535

Example

STAT:QUES:ACPL:NTR 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:ACPLimit:PTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable: ACPLimit

Parameter

0to 65535

Example

STAT:QUES:ACPL:PTR 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus Subsystem R&S FSL

1300.2519.12 6.244 E-11

STATus:QUEStionable:FREQuency[:EVENt]?

This command queries the contents of the EVENt section of the STATus:QUEStionable:

FREQuency register.

Readout deletes the contents of the EVENt section.

Example

STAT:QUES:FREQ?

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:FREQuency:CONDition?

This command queries the contents of the CONDition section of the

STATus:QUEStionable:FREQuency register. Readout does not delete the contents of the

CONDition section.

Example

STAT:QUES:FREQ:COND?

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:FREQuency:ENABle

This command sets the bits of the ENABle section of the STATus:QUEStionable:FREQuency

section for the summary bit.

Parameter

0to 65535

Example

STAT:QUES:FREQ:ENAB 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

R&S FSL STATus Subsystem

1300.2519.12 6.245 E-11

STATus:QUEStionable:FREQuency:NTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable:FREQuency

Parameter

0to 65535

Example

STAT:QUES:FREQ:NTR 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all, except NF

STATus:QUEStionable:FREQuency:PTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable:FREQuency

Parameter

0to 65535

Example

STAT:QUES:FREQ:PTR 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all, except NF

STATus:QUEStionable:LIMit<1|2>[:EVENt]?

This command queries the contents of the EVENt section of the STATus:QUEStionable:LIMit

This command is available from firmware version 1.10.

Example

STAT:QUES:LIM?

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus Subsystem R&S FSL

1300.2519.12 6.246 E-11

STATus:QUEStionable:LIMit<1|2>:CONDition?

This command queries the contents of the CONDition section of the

STATus:QUEStionable:LIMit register.

Readout does not delete the contents of the CONDition section.

This command is available from firmware version 1.10.

Example

STAT:QUES:LIM:COND?

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:LIMit<1|2>:ENABle

This command sets the bits of the ENABle section of the STATus:QUEStionable register. The

ENABle register selectively enables the individual events of the associated EVENt section for

the summary bit.

This command is available from firmware version 1.10.

Parameter

0to 65535

Example

STAT:QUES:LIM:ENAB 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:LIMit<1|2>:NTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable:LIMit register

from 1 to 0 for the transitions of the CONDition bit.

This command is available from firmware version 1.10.

Parameter

0to 65535

Example

STAT:QUES:LIM:NTR 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all, except NF

R&S FSL STATus Subsystem

1300.2519.12 6.247 E-11

STATus:QUEStionable:LIMit<1|2>:PTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable:LIMit register

from 0 to 1 for the transitions of the CONDition bit.

This command is available from firmware version 1.10.

Parameter

0to 65535

Example

STAT:QUES:LIM:PTR 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all, except NF

STATus:QUEStionable:LMARgin<1|2>[:EVENt]?

This command queries the contents of the EVENt section of the

STATus:QUEStionable:LMARgin register. Readout deletes the contents of the EVENt section.

Example

STAT:QUES:LMAR?

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:LMARgin<1|2>:CONDition?

This command queries the contents of the CONDition section of the

STATus:QUEStionable:LMARgin register. Readout does not delete the contents of the

CONDition section.

Example

STAT:QUES:LMAR:COND?

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus Subsystem R&S FSL

1300.2519.12 6.248 E-11

STATus:QUEStionable:LMARgin<1|2>:ENABle

This command sets the bits of the ENABle section of the STATus:QUEStionable:LMARgin

section for the summary bit.

Parameter

0to 65535

Example

STAT:QUES:LMAR:ENAB 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:LMARgin<1|2>:NTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable:LMARgin

Parameter

0to 65535

Example

STAT:QUES:LMAR:NTR 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:LMARgin<1|2>:PTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable:LMARgin

Parameter

0to 65535

Example

STAT:QUES:LMAR:PTR 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

R&S FSL STATus Subsystem

1300.2519.12 6.249 E-11

STATus:QUEStionable:POWer[:EVENt]?

This command queries the contents of the EVENt section of the STATus:QUEStionable:POWer

Example

STAT:QUES:POW?

Characteristics

*RST value: –

SCPI: conform

Mode

all

STATus:QUEStionable:POWer:CONDition?

This command queries the contents of the CONDition section of the

STATus:QUEStionable:POWer register. Readout does not delete the contents of the CONDition

section.

Example

STAT:QUES:POW:COND?

Characteristics

*RST value: –

SCPI: conform

Mode

all

STATus:QUEStionable:POWer:ENABle

This command sets the bits of the ENABle section of the STATus:QUEStionable:POWer

section for the summary bit.

Parameter

0to 65535

Example

STAT:QUES:POW:ENAB 65535

Characteristics

*RST value: –

SCPI: conform

Mode

all

STATus Subsystem R&S FSL

1300.2519.12 6.250 E-11

STATus:QUEStionable:POWer:NTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable:POWer register

from 1 to 0 for the transitions of the CONDition bit.

Parameter

0to 65535

Example

STAT:QUE:POWS:NTR 65535

Characteristics

*RST value: –

SCPI: conform

Mode

all

STATus:QUEStionable:POWer:PTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable:POWer register

from 0 to 1 for the transitions of the CONDition bit.

Parameter

0to 65535

Example

STAT:QUES:POW:PTR 65535

Characteristics

*RST value: –

SCPI: conform

Mode

all

STATus:QUEStionable:SYNC[:EVENt]?

This command queries the contents of the EVENt section of the STATus:QUEStionable:SYNC

Readout deletes the contents of the EVENt section.

This command is available from firmware version 1.30.

Example

STAT:QUES:SYNC?

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

R&S FSL STATus Subsystem

1300.2519.12 6.251 E-11

STATus:QUEStionable:SYNC:CONDition?

This command queries the contents of the CONDition section of the

STATus:QUEStionable:SYNC register. Readout does not delete the contents of the CONDition

section.

This command is available from firmware version 1.30.

Example

STAT:QUES:SYNC:COND?

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:SYNC:ENABle

This command sets the bits of the ENABle section of the STATus:QUEStionable:SYNC register.

The ENABle register selectively enables the individual events of the associated EVENt section

for the summary bit.

This command is available from firmware version 1.30.

Parameter

0to 65535

Example

STAT:QUES:SYNC:ENAB 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus:QUEStionable:SYNC:NTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable:SYNC register

from 1 to 0 for the transitions of the CONDition bit.

This command is available from firmware version 1.30.

Parameter

0to 65535

Example

STAT:QUES:SYNC:NTR 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

STATus Subsystem R&S FSL

1300.2519.12 6.252 E-11

STATus:QUEStionable:SYNC:PTRansition

This command sets the edge detectors of all bits of the STATus:QUEStionable:SYNC register

from 0 to 1 for the transitions of the CONDition bit.

This command is available from firmware version 1.30.

Parameter

0to 65535

Example

STAT:QUES:SYNC:PTR 65535

Characteristics

*RST value: –

SCPI: device–specific

Mode

all

R&S FSL SYSTem Subsystem

1300.2519.12 6.253 E-11

SYSTem Subsystem

This subsystem contains a series of commands for general functions.

Commands of the SYSTem Subsystem

–SYSTem:COMMunicate:GPIB[:SELF]:ADDRess

–SYSTem:COMMunicate:GPIB[:SELF]:RTERminator

–SYSTem:COMMunicate:PRINter:ENUMerate[:NEXT?]

–SYSTem:COMMunicate:PRINter:ENUMerate:FIRSt?

–SYSTem:COMMunicate:PRINter:SELect <1|2>

–SYSTem:DATE

–SYSTem:DISPlay:FPANel

–SYSTem:DISPlay:UPDate

–SYSTem:ERRor[:NEXT]?

–SYSTem:ERRor:CLEar:ALL

–SYSTem:ERRor:LIST?

–SYSTem:FIRMware:UPDate

–SYSTem:FORMat:IDENt

–SYSTem:LANGuage

–SYSTem:LXI:INFo?

–SYSTem:LXI:LANReset

–SYSTem:LXI:PASSword

–SYSTem:LXI:MDEScription

–SYSTem:PASSword[:CENable]

–SYSTem:PASSword:RESet

–SYSTem:PRESet

–SYSTem:TIME

–SYSTem:VERSion?

SYSTem Subsystem R&S FSL

1300.2519.12 6.254 E-11

SYSTem:COMMunicate:GPIB[:SELF]:ADDRess

This command changes the GPIB address of the unit.

Parameter

0to 30

Example

SYST:COMM:GPIB:ADDR 18

Characteristics

*RST value: - (no influence on this parameter, factory default 20)

SCPI: conform

Mode

all

SYSTem:COMMunicate:GPIB[:SELF]:RTERminator

This command changes the GPIB receive terminator.

According to the standard the terminator in ASCII is <LF> and/or <EOI>. For binary data

transfers (e.g. trace data) from the control computer to the instrument, the binary code (0AH)

used for <LF> might be included in the binary data block, and therefore should not be

interpreted as a terminator in this particular case. This can be avoided by changing the receive

terminator to EOI.

Output of binary data from the instrument to the control computer does not require such a

terminator change.

Parameter

LFEOI | EOI

Example

SYST:COMM:GPIB:RTER EOI

Characteristics

*RST value: - (no influence on this parameter, factory default LFEOI)

SCPI: device-specific

Mode

all

SYSTem:COMMunicate:PRINter:ENUMerate[:NEXT?]

This command queries the name of the next printer installed under Windows XP. After all

available printer names have been output, an empty string enclosed by quotation marks (") is

output for the next query. Further queries are answered by a query error.

The SYSTem:COMMunicate:PRINter:ENUMerate:FIRSt? command should be sent

previously to return to the beginning of the printer list and query the name of the first printer.

Example

SYST:COMM:PRIN:ENUM?

R&S FSL SYSTem Subsystem

1300.2519.12 6.255 E-11

Characteristics

*RST value: NONE

SCPI: device-specific

Mode

all

SYSTem:COMMunicate:PRINter:ENUMerate:FIRSt?

This command queries the name of the first printer (in the list of printers) available under

Windows XP.

The names of other installed printers can be queried with the

SYSTem:COMMunicate:PRINter:ENUMerate[:NEXT?] command.

If no printer is configured an empty string is output.

Example

SYST:COMM:PRIN:ENUM:FIRS?

Characteristics

*RST value: NONE

SCPI: device-specific

Mode

all

SYSTem:COMMunicate:PRINter:SELect <1|2>

This command selects one of the printers configured under Windows XP including the

associated output destination.

The specified printer name must be a string as returned by the commands

SYSTem:COMMunicate:PRINter:ENUMerate:FIRSt? or

SYSTem:COMMunicate:PRINter:ENUMerate[:NEXT?]

Note: The HCOPy:DESTination<1|2> command is used to select an output medium other

than the default one.

Parameter

<printer_name>

Example

SYST:COMM:PRIN:SEL LASER on LPT1

Characteristics

*RST value: NONE

SCPI: device-specific

Mode

all

SYSTem Subsystem R&S FSL

1300.2519.12 6.256 E-11

SYSTem:DATE

This command is used to enter the date for the internal calendar.

The sequence of entry is year, month, day.

Parameter

1980 to 2099, 1 to 12, 1 to 31

Example

SYST:DATE 2000,6,1

Characteristics

*RST value: -

SCPI: conform

Mode

all

SYSTem:DISPlay:FPANel

This command activates or deactivates the display of the front panel keys on the screen.

With the display activated, the instrument can be operated on the screen using the mouse by

pressing the corresponding buttons.

Parameter

ON | OFF

Example

SYST:DISP:FPAN ON

Characteristics

*RST value: OFF

SCPI: device-specific

Mode

all

SYSTem:DISPlay:UPDate

In remote control mode, this command switches on or off the instrument display. If switched on,

only the diagrams, traces and display fields are displayed and updated.

Note: The best performance is obtained if the display output is switched off during remote

control.

Parameter

ON | OFF

Example

SYST:DISP:UPD ON

Characteristics

*RST value: OFF

SCPI: device-specific

Mode

all

R&S FSL SYSTem Subsystem

1300.2519.12 6.257 E-11

SYSTem:ERRor[:NEXT]?

This command queries the earliest error queue entry and deletes it.

Positive error numbers indicate device-specific errors, negative error numbers are error

messages defined by SCPI. If the error queue is empty, the error number 0, "No error", is

returned.

This command is a query and therefore has no *RST value.

Example

STAT:ERR?

Characteristics

*RST value: -

SCPI: conform

Mode

all

SYSTem:ERRor:CLEar:ALL

This command deletes all entries in the table SYSTEM MESSAGES.

This command is an event and therefore has no query and no *RST value.

Example

SYST:ERR:CLE:ALL

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

SYSTem:ERRor:LIST?

This command reads all system messages and returns a list of comma separated strings. Each

string corresponds to an entry in the table SYSTEM MESSAGES.

If the error list is empty, an empty string "" will be returned.

This command is a query and therefore has no *RST value.

Example

SYST:ERR:LIST?

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

SYSTem Subsystem R&S FSL

1300.2519.12 6.258 E-11

SYSTem:FIRMware:UPDate

This command starts a firmware update using the *.msi files in the selected directory. The

default path is D:\FW_UPDATE. The path is changed via the MMEMory:CDIRectory

command. To store the update files the MMEMory:DATA command is used.

This command is an event and therefore has no query and no *RST value.

Example

SYST:FIRM:UPD 'D:\FW_UPDATE'

Starts the firmware update from directory D:\FW_UPDATE.

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

SYSTem:FORMat:IDENt

This command defines the response format to the *IDN? command. This function is intended

for re-use of existing control programs together with the R&S FSL.

Parameter

LEGacy format is compatible to the R&S FSP/FSU/FSQ family

NEW R&S FSL format

Example

SYST:FORM:IDEN LEG

Adapts the return value of *IDN? to the R&S FSP/FSU/FSQ family.

Characteristics

RST value: LEG

SCPI: device-specific

Mode

all

SYSTem:LANGuage

This command defines the system language.

Parameter

SCPI

Example

SYST:LANG 'SCPI'

Sets the system language to SCPI.

Characteristics

RST value: SCPI

SCPI: device-specific

Mode

all

R&S FSL SYSTem Subsystem

1300.2519.12 6.259 E-11

SYSTem:LXI:INFo?

This query returns the current parameters of the LXI class C.

This command is available from firmware version 1.90.

Return values (example)

"<current version>|<LXI class>|<Computername>|<MAC adress>|<IP

adress>|<Auto MDIX>"

Characteristics

RST value: -

SCPI: device-specific

Mode

all

SYSTem:LXI:LANReset

This command resets the LAN configuration to the values required by the LXI standard. In

addition, the password is reset to its initial state aas well as the LXI instrument description.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.90.

Example

SYST:LXI:LANR

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

SYSTem:LXI:MDEScription

This command shows the LXI instrument description. Also, the instrument description can be

changed using this command.

This command is available from firmware version 1.90.

Parameter

Example

SYST:LXI:MDES

Characteristics

*RST value: -

SCPI: device-specific

Mode

all

SYSTem Subsystem R&S FSL

1300.2519.12 6.260 E-11

SYSTem:LXI:PASSword

This command shows or changes the LXI password.

This command is available from firmware version 1.90.

Parameter

Example

SYST:LXI:PASS

Characteristics

*RST value:

SCPI: device-specific

Mode

all

SYSTem:PASSword[:CENable]

This command enables access to the service functions by means of the password.

This command is an event and therefore has no *RST value and no query.

Parameter

Example

SYST:PASS XXXX

Characteristics

*RST value: -

SCPI: conform

Mode

all

SYSTem:PASSword:RESet

This command resets the service password.

This command is an event and therefore has no *RST value and no query.

Example

SYST:PASS:RES

Characteristics

*RST value: -

SCPI: conform

Mode

all

R&S FSL SYSTem Subsystem

1300.2519.12 6.261 E-11

SYSTem:PRESet

This command initiates an instrument reset.

The effect of this command corresponds to that of the PRESET key with manual operation or to

the *RST command. For details on preset settings refer to chapter 4 "Instrument Functions -

Analyzer", section "Initializing the Configuration - PRESET Key".

Example

SYST:PRES

Characteristics

*RST value: -

SCPI: conform

Mode

all

SYSTem:TIME

This command sets the internal clock. The sequence of entry is hour, minute, second.

Parameter

0to 23, 0 to 59, 0 to 59

Example

SYST:TIME 12,30,30

Characteristics

*RST value: -

SCPI: conform

Mode

all

SYSTem:VERSion?

This command queries the number of the SCPI version, which is relevant for the instrument.

This command is a query and therefore has no *RST value.

Example

SYST:VERS?

Characteristics

*RST value: -

SCPI: conform

Mode

all

SYSTem Subsystem R&S FSL

1300.2519.12 6.262 E-11

SYSTem:SPEaker Subsystem

This subsystem controls the headset functions.

Commands of the SYSTem:SPEaker Subsystem

–SYSTem:SPEaker:VOLume

SYSTem:SPEaker:VOLume

This command sets the volume of the headset for demodulated signals.

Parameter

0to 1; value 0 is the lowest volume, value 1 the highest volume.

Example

SYST:SPE:VOL 0.5

Characteristics

*RST value: 0

SCPI: device–specific

Mode

all

R&S FSL TRACe Subsystem

1300.2519.12 6.263 E-11

TRACe Subsystem

The TRACe subsystem controls access to the instruments internal trace memory.

The following subsystem is included:

•"TRACe:IQ Subsystem" on page 6.265

Commands of the TRACe Subsystem

–TRACe<1|2>[:DATA]

–TRACe:COPY

TRACe<1|2>[:DATA]

This command transfers trace data from the control computer to the instrument, the query reads

trace data out of the instrument. The transfer of trace data from the control computer to the

instrument takes place by indicating the trace name and then the data to be transferred.

For details on saving and recalling data refer to chapter 5 "Remote Control – Basics", section

"MMEMory Subsystem".

Parameter

<numeric_value>

TRACE1, ... , TRACE6 trace memory to be read out

<block> or <numeric_value> data to be transferred

query only:

LIST lists all results of the Spectrum Emission Mask and Spurious

Emissions measurement

SPURious lists all peaks of the Spurious Emissions measurement

Return values for trace data

501 results are returned. The returned values are scaled in the current level unit.

FORMat REAL,32 is used as format for binary transmission, and FORMat ASCii for ASCII

transmission. For details on formats refer to "Formats for returned values: ASCII format and

binary format" on page 6.300.

Note: With the auto peak detector, only positive peak values can be read out.

TRACe Subsystem R&S FSL

1300.2519.12 6.264 E-11

Return values for Spectrum Emission Mask/Spurious Emissions measurement results

Returns the list evaluation results.

<no>, <start>, <stop>, <rbw>, <freq>, <power abs>, <power rel>, <delta>, <limit check>,

Value Description

<no> range number

<start> start frequency

<stop> stop frequency

<rbw> resolution bandwidth of range

<freq> frequency of peak

<power abs> absolut power in dBm of peak

<power rel> relative power in dBc (related to the channel power) of peak

<delta> distance to the limit line in dB (positive indicates value above the limit, fail)

<limit check> limit fail (pass = 0, fail =1)

<unused1> reserved (0.0)

<unused2> reserved (0.0)

Example

TRAC TRACE1

TRAC? TRACE1

Characteristics

*RST value: –

SCPI: conform

Mode

all

TRACe:COPY

This command copies data from one trace to another.

This command is an event and therefore has no query and no *RST value.

Parameter

TRACE4 | TRACE5 | TRACE6

The first operand the destination of the data to be copied, the second operand describes the

source.

Example

TRAC:COPY TRACE1,TRACE2

Characteristics

*RST value: –

SCPI: conform

Mode

A, CATV

R&S FSL TRACe Subsystem

1300.2519.12 6.265 E-11

TRACe:IQ Subsystem

The commands of this subsystem are used for collection and output of measured IQ data. A special

memory is therefore available in the instrument for about 512k complex samples (pairs of I and Q data).

The measurement is always performed in zero span at the selected center frequency. The number of

complex samples to be collected and the sample rate can be set (for details refer to "Sample rate and

maximum usable bandwidth"on page 6.267). Prior to being stored in memory or output via GPIB, the

measurement data are corrected in terms of frequency response.

The block diagrams below show the analyzer hardware from the IF section to the processor. The block

diagrams differ between the instrument models because two different motherboards are fitted. The main

difference is the position of the fractional resampling and the analog IF bandwidth. For details on the

distinction refer to "Sample rate and maximum usable bandwidth" on page 6.267.

The A/D converter samples the IF signal (47.9 MHz) at a rate of MHz365.8 . The digital signal is

down–converted to the complex baseband, lowpass–filtered, and the sampling rate is reduced. The

continuously adjustable sampling rates are realized using an optimal decimation filter and subsequent

resampling on the set sampling rate.

The I/Q data are written to separate memories of 512 k words each. The memories are hardware–

triggered. 512 samples are designated as buffer for triggering, which leads to a max. recording length of

523776 (=512k – 512) complex samples.

Imemory

512 k

processor

analog IF

filter

bandwidth

28 MHz

analyzer IF

47.9 MHz A

A/D

converter

65.83 MHz

sampling

clock

digital down conversion

+continuous decimation

cos

sin

decimation

filters

NCO

-47.9 MHz

Qmemory

512 k

arbitrary

sampling rate

10kHz ... 65.83MHz

Data aquisition hardware

Idata

Qdata

Trigger

fractional resampling

Fig. 6–1 Signal processing in models with UDC motherboards

TRACe Subsystem R&S FSL

1300.2519.12 6.266 E-11

Fig. 6–2 Signal processing in models with WDDC motherboards

The trigger sources EXT (external trigger) and IFP (IF Power Trigger) can be used for triggering,

additionally IMM (Free Run). The number of complex sample to be recorded prior to the trigger event

can be selected (TRACe<1|2>:IQ:SET command) for all available trigger sources, except for FREE

RUN.

The measurement results are output in the form of a list, with the Q values following immediately after

the list of I values in the output buffer. The FORMAT command can be used to select between binary

output (32 bit IEEE 754 floating–point values) and output in ASCII format.

For details on formats refer to "Formats for returned values: ASCII format and binary format" on page

6.300.

The commands of this subsystem can be used in two ways:

•Measurement and result query with one command:

This method causes the least delay between measurement and output of the result data, but it

requires the control computer to wait actively for the response data.

•Setting up the instrument, start of the measurement via INIT and query of the result list at the end

of the measurement:

With this method the control computer can be used for other activities during the measurement. In

this case the additional time needed for synchronization via service request must be taken into

account.

Commands of the TRACe:IQ Subsystem

–TRACe<1|2>:IQ[:STATe]

–TRACe<1|2>:IQ:AVERage[:STATe]

–TRACe<1|2>:IQ:AVERage:COUNt

–TRACe<1|2>:IQ:DATA?

–TRACe<1|2>:IQ:DATA:MEMory?

–TRACe<1|2>:IQ:SET

–TRACe<1|2>:IQ:SRATe

R&S FSL TRACe Subsystem

1300.2519.12 6.267 E-11

Further information

–Sample rate and maximum usable bandwidth

Sample rate and maximum usable bandwidth

Within the usable bandwidth range, the analog IF filter of the R&S FSL is equalized in regard to

amplitude characteristic and group delay (provided that the R&S FSL is aligned; for details see chapter

4, section "Instrument Setup and Interface Configuration – SETUP Key", "Alignment"). In consequence,

signals within this bandwidth range are hardly distorted at all (provided the R&S FSL is not overloaded).

For the I/Q data acquisition, digital decimation filters are used internally. The passband of these digital

filters corresponds to the maximum usable bandwidth. In consequence, signals within the usable

bandwidth (passband) remain unchanged, while signals outside the usable bandwidth (passband) are

suppressed. Usually, the suppressed signals are noise, artifacts, and the second IF side band. If

frequencies of interest to you are also suppressed, you should try to increase the output sample rate,

since this increases the maximum usable IQ bandwidth.

As a rule, the usable bandwidth is proportional to the output sample rate (see section Instrument

models with UDC motherboard or Instrument models with WDDC motherboard). Yet, when the I/Q

bandwidth reaches the bandwidth of the analog IF filter (at very high output sample rates), the curve

breaks. For the base unit, the sample rate ranges from 10 kHz to MHz365.8 .

The maximum usable bandwidth is listed in the data sheet. The value differs between the instrument

models due to different motherboards:

•UDC motherboard (order # 2112.1800)

•WDDC motherboard (order # 1300.3080)

If you are not sure which motherboard your model has, check the Hardware Information list (SETUP

key – More – System Info – Hardware Info;for details see chapter 4).

Instrument models with UDC motherboard

The following diagram shows the maximum usable IQ bandwidths depending on the output sample

rates. The values are rounded off to two decimal places.

TRACe Subsystem R&S FSL

1300.2519.12 6.268 E-11

Fig. 6–3 Relation between maximum usable bandwidth and output sample rate

Note: Do not use an output sample rate in the range from 65.833333.0 MHz to MHz365.8 for

measurements. This range is for test purposes only.

At this sample rate, the whole bandwidth of the IF filter is equalized, but the digital filters are

switched to bypass. In consequence, not only the effective signal but all signals pass, including

noise and image–spectra.

R&S FSL TRACe Subsystem

1300.2519.12 6.269 E-11

Instrument models with WDDC motherboard

The following tables list the maximum bandwidths depending on the output sample rates.

–65,833,333.333 MHz to 65,833,333.000 MHz

–65,833,332.999 MHz to 10.7 MHz

–10.7 MHz to 3.2 MHz

–3.2 MHz to 1 MHz

– 1 MHz to 105 kHz

–105 kHz to 10 kHz

65,833,333.333 MHz to 65,833,333.000 MHz

This small range of the sample rate is for test purposes only and is not recommended for normal

measurements!

Sample rate from

[Hz]

Sample rate to

[Hz]

Max bandwidth

[Hz]

65 833 333.333 65 833 333.000 20 000 000.000

Beware:

decimation filters

are bypassed!

65,833,332.999 MHz to 10.7 MHz

Sample rate from

[Hz]

Sample rate to

[Hz]

Max bandwidth

[Hz]

65 833 332.999 32 916 666.670 20 000 000.000

22 500 000.000 20 248 687.500 17 998 833.330

20 248 687.500 16 401 436.880 14 579 055.000

16 401 436.880 14 812 500.000 13 166 666.670

14 812 500.000 13 331 250.000 11 850 000.000

13 331 250.000 11 998 125.000 10 665 000.000

11 998 125.000 10 798 312.500 9 598 500.000

10.7 MHz to 3.2 MHz

Sample rate from

[Hz]

Sample rate to

[Hz]

Max bandwidth

[Hz]

10 798 312.500 9 875 000.000 8 777 777.778

9875 000.000 8 887 500.000 7 900 000.000

8887 500.000 7 998 750.000 7 110 000.000

7998 750.000 7 406 250.000 6 583 333.333

7406 250.000 6 665 625.000 5 925 000.000

6665 625.000 6 583 333.333 5 851 851.852

6583 333.333 5 925 000.000 5 266 666.667

5925 000.000 5 332 500.000 4 740 000.000

5332 500.000 4 937 500.000 4 388 888.889

4937 500.000 4 443 750.000 3 950 000.000

TRACe Subsystem R&S FSL

1300.2519.12 6.270 E-11

Sample rate from

[Hz]

Sample rate to

[Hz]

Max bandwidth

[Hz]

4443 750.000 4 232 142.857 3 761 904.762

4232 142.857 3 950 000.000 3 511 111.111

3950 000.000 3 703 125.000 3 291 666.667

3703 125.000 3 332 812.500 2 962 500.000

3332 812.500 3 291 666.667 2 925 925.926

3.2 MHz to 1 MHz

Sample rate from

[Hz]

Sample rate to

[Hz]

Max bandwidth

[Hz]

3291 666.667 2 962 500.000 2 633 333.333

2962 500.000 2 821 428.571 2 507 936.508

2821 428.571 2 539 285.714 2 257 142.857

2539 285.714 2 468 750.000 2 194 444.444

2468 750.000 2 370 000.000 2 106 666.667

2370 000.000 2 194 444.444 1 950 617.284

2194 444.444 2 116 071.429 1 880 952.381

2116 071.429 1 975 000.000 1 755 555.556

1975 000.000 1 851 562.500 1 645 833.333

1851 562.500 1 795 454.545 1 595 959.596

1795 454.545 1 645 833.333 1 462 962.963

1645 833.333 1 481 250.000 1 316 666.667

1481 250.000 1 346 590.909 1 196 969.697

1346 590.909 1 234 375.000 1 097 222.222

1234 375.000 1 139 423.077 1 012 820.513

1139 423.077 1 039 473.684 923 976.608

1MHz to 105 kHz

Sample rate from

[Hz]

Sample rate to

[Hz]

Max bandwidth

[Hz]

1039 473.684 940 476.191 835 978.836

940 476.191 846 428.571 752 380.952

846 428.571 779 605.263 692 982.456

779 605.263 705 357.143 626 984.127

705 357.143 637 096.774 566 308.244

637 096.774 580 882.353 516 339.869

580 882.353 529 017.857 470 238.095

529 017.857 477 822.581 424 731.183

477 822.581 435 661.765 387 254.902

435 661.765 395 000.000 351 111.111

395 000.000 359 090.909 319 191.919

359 090.909 323 770.492 287 795.993

R&S FSL TRACe Subsystem

1300.2519.12 6.271 E-11

Sample rate from

[Hz]

Sample rate to

[Hz]

Max bandwidth

[Hz]

323 770.492 294 776.119 262 023.217

294 776.119 266 891.892 237 237.237

266 891.892 240 853.659 214 092.141

240 853.659 217 032.967 192 918.193

217 032.967 195 544.555 173 817.382

195 544.555 176 339.286 156 746.032

176 339.286 159 274.194 141 577.061

159 274.194 143 810.680 127 831.715

143 810.680 129 934.211 115 497.076

129 934.211 117 559.524 104 497.355

117 559.524 105 803.571 94 047.619

105 kHz to 10 kHz

Sample rate from

[Hz]

Sample rate to

[Hz]

Max bandwidth

[Hz]

105 803.571 95 410.628 84 809.447

95 410.628 85 869.565 76 328.502

85 869.565 77 450.980 68 845.316

77 450.980 69 787.986 62 033.765

69 787.986 62 898.089 55 909.413

62 898.089 56 752.874 50 446.999

56 752.874 51 077.586 45 402.299

51 077.586 46 001.553 40 890.269

46 001.553 41 404.612 36 804.100

41 404.612 37 264.151 33 123.690

37 264.151 33 588.435 29 856.387

33 588.435 30 229.592 26 870.748

30 229.592 27 228.860 24 203.431

27 228.860 24 524.007 21 799.117

24 524.007 22 075.261 19 622.454

22 075.261 19 869.215 17 661.525

19 869.215 17 889.493 15 901.771

17 889.493 16 100.543 14 311.594

16 100.543 14 493.640 12 883.235

14 493.640 13 044.914 11 595.479

13 044.914 11 741.974 10 437.310

11 741.974 10 572.805 9 398.049

10 572.805 10 000.000 8 460.509

TRACe Subsystem R&S FSL

1300.2519.12 6.272 E-11

TRACe<1|2>:IQ[:STATe]

This command switches the I/Q data acquisition on or off.

Note: The I/Q data acquisition is not compatible with other measurement functions. Therefore

all other measurement functions will be switched off as soon as the I/Q measurement

function is switched on. Additionally a trace display is not possible in this operating

mode. Therefore all traces are set to "BLANK".

Parameter

ON | OFF

Example

TRAC:IQ ON

Switches on I/Q data acquisition

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–T

TRACe<1|2>:IQ:AVERage[:STATe]

The command enables averaging of the recorded I/Q data provided that I/Q data acquisition

was previously enabled with TRACe<1|2>:IQ[:STATe].

Parameter

ON | OFF

Example

TRAC:IQ ON

Switches on acquisition of I/Q data.

TRAC:IQ:AVER ON

Enables averaging of the I/Q measurement data.

TRAC:IQ:AVER:COUN 10

Selects averaging over 10 data sets.

TRAC:IQ:DATA?

Starts the measurement and reads out the averaged data.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–T

R&S FSL TRACe Subsystem

1300.2519.12 6.273 E-11

TRACe<1|2>:IQ:AVERage:COUNt

This command defines the number of I/Q data sets that are to serve as a basis for averaging.

Parameter

0to 32767

Example

TRAC:IQ ON

Switches on acquisition of I/Q data.

TRAC:IQ:AVER ON

Enables averaging of the I/Q measurement data

TRAC:IQ:AVER:COUN 10

Selects averaging over 10 data sets

TRAC:IQ:DATA?

Starts the measurement and reads out the averaged data.

Characteristics

*RST value: 0

SCPI: conform

Mode

A-T

TRACe<1|2>:IQ:DATA?

This command starts a measurement with the settings defined via TRACe<1|2>:IQ:SET and

returns the list of measurement results immediately after they are corrected in terms of

frequency response. The number of measurement results depends on the settings defined with

TRACe<1|2>:IQ:SET,the output format depends on the settings of the FORMat subsystem.

Note: The command requires that all response data are read out completely before the

instrument accepts further commands.

Return values

The result values are scaled linear in unit Volt and correspond to the voltage at the RF input of

the instrument. In ASCII format, the number of the returned values is 2 * the number of samples.

The first set contains the I–data, the second the Q–data.

Note: If the sampling rate exceeds 512k (



524288), the data are output in 512k blocks.

In binary format, the number of I– and Q–data can be calculated as follows:

DataBytesof#

DataQof#DataIof# ==

The offset of Q–data in the output buffer can be calculated as follows:

scatorDigitLengthIndi

DataBytesof

OffsetDataQ+=

)(#

with LengthIndicatorDigits being the number of digits of the length indicator including the #. In

the example above (#41024...) this results in a value of 6 for LengthIndicatorDigits and the

offset for the Q–data will result in 512 + 6 = 518.

For further details on formats refer to "Formats for returned values: ASCII format and binary

format" on page 6.300.

TRACe Subsystem R&S FSL

1300.2519.12 6.274 E-11

Example

TRAC:IQ:STAT ON

Enables acquisition of I/Q data

TRAC:IQ:SET NORM,10MHz,32MHz,EXT,POS,0,4096

Measurement configuration:

Sample Rate: 32 MHz

Trigger Source: External

Trigger Slope: Positive

Pretrigger Samples: 0

#of Samples: 4096

FORMat REAL,32

Selects format of response data

TRAC:IQ:DATA?

Starts measurement and reads results

Characteristics

*RST value: –

Note: Using the command with the *RST values for the TRACe<1|2>:IQ:SET command, the

following minimum buffer sizes for the response data are recommended: ASCII format

10 kBytes, binary format: 2 kBytes

SCPI: device–specific

Mode

A–T

TRACe<1|2>:IQ:DATA:MEMory?

This command permits the readout of previously acquired (and frequency response corrected)

I/Q data from the memory, with indication of the offset related to the start of measurement and

with indication of the number of measurement values. Therefore a previously acquired data set

can be read out in smaller portions. The maximum amount of available data depends on the

settings of the TRACe<1|2>:IQ:SET command, the output format on the settings in the

FORMat subsystem.

Note: The command requires that all response data are read out completely before the

instrument accepts further commands.

If there are not I/Q data available in memory because the corresponding measurement

had not been started, the command will cause a query error.

Parameter

<offset samples> Offset of the values to be read related to the start of the acquired data.

Value range: 0 to <# of samples> – 1, with <# of samples> being the

value indicated with the TRACe<1|2>:IQ:SET command.

<# of samples> Number of measurement values to be read.

Value range: 1 to <# of samples> – <offset samples> with <# of

samples> being the value indicated with the TRACe<1|2>:IQ:SET

command.

Return values

The returned values are scaled linear in unit Volt and correspond to the voltage at the RF input

of the instrument.

The format of the output buffer corresponds to the TRACe<1|2>:IQ:DATA? command.

R&S FSL TRACe Subsystem

1300.2519.12 6.275 E-11

Example

TRAC:IQ:STAT ON

Enables acquisition of I/Q data

TRAC:IQ:SET NORM,10MHz,32MHz,EXT,POS,100,4096

To configure the measurement:

Sample Rate: 32 MHz

Trigger Source: External

Slope: Positive

Pretrigger Samples: 100

#of Samples: 4096

INIT;*WAI

Starts measurement and wait for sync

FORMat REAL,32

Determines output format

To read the results:

TRAC:IQ:DATA:MEM? 0,2048

Reads 2048 I/Q data starting at the beginning of data acquisition

TRAC:IQ:DATA:MEM? 2048,1024

Reads 1024 I/Q data from half of the recorded data

TRAC:IQ:DATA:MEM? 100,512

Reads 512 I/Q data starting at the trigger point (<Pretrigger Samples> was 100)

Characteristics

*RST value: –

SCPI: device–specific

Mode

A–T, WLAN, OFDM, OFDMA/WiBro

TRACe<1|2>:IQ:SET

This command defines the settings of the analyzer hardware for the measurement of I/Q data.

This allows setting the bandwidth of the analog filters in front of the A/D converter as well as

setting the sample rate, trigger conditions and the record length.

Note: If this command is omitted, the current analyzer settings will be used for the

corresponding parameters.

This command switches to IQ mode automatically (see also

TRACe<1|2>:IQ[:STATe]).

The parameter <filter_type> has no effect but is indicated for reasons of compatibility

with the FSP family.

The trigger level can be set using the TRIGger<1|2>[:SEQuence]:LEVel:IFPower

command.

Parameter

<filter type> can be omitted

<rbw> can be omitted

<sample rate> Sampling rate for the data acquisition.

Value range: 10 kHz to MHz365.8 , continuously adjustable

<trigger mode> Selection of the trigger source used for the measurement.

Values: IMMediate | EXTernal | IFPower

TRACe Subsystem R&S FSL

1300.2519.12 6.276 E-11

<trigger slope> Used trigger slope.

Values: POSitive

<pretrigger samples> Number of measurement values to be recorded before the

trigger point.

Range:–16253439 (= –(224–1–512k –512)) ... 523775 (=

512*1024 – 512 – 1). Negative values correspond to a trigger

delay.

<# of samples> Number of measurement values to record.

Value range:1 ... 523776(= 512*1024 – 512)

Example

TRAC:IQ:SET NORM,10MHz,32MHz,EXT,POS,0,2048

Reads 2048 I/Q–values starting at the trigger point.

sample rate: 32 MHz

trigger: External

slope: Positive

TRAC:IQ:SET NORM,10MHz,4MHz,EXT,POS,1024,512

Reads 512 I/Q–values from 1024 measurement points before the trigger point.

filter type: NORMAL

RBW: 10 MHz

sample rate: 4 MHz

trigger: External

slope: Positive

Characteristics

*RST values: –,–,32MHz,IMM,POS,0,128

Note: For using these default settings with the TRACe<1|2>:IQ:DATA? command the

following minimum buffer sizes for the response data are recommended: ASCII format

10 kBytes, Binary format 2 kBytes.

SCPI: device–specific

Mode

A–T

TRACe<1|2>:IQ:SRATe

This command sets the sampling rate for the I/Q data acquisition. Thus the sample rate can be

modified without affecting the other settings.

Parameter

10 kHz to MHz365.8 , continuously adjustable

Example

TRAC:IQ:SRAT 4MHZ

Characteristics

*RST value: 32 MHz

SCPI: device–specific

Mode

A–T

R&S FSL TRIGger Subsystem

1300.2519.12 6.277 E-11

TRIGger Subsystem

The TRIGger subsystem is used to synchronize instrument actions with events. It is thus possible to control

and synchronize the start of a sweep.

Commands of the TRIGger Subsystem

–TRIGger<1|2>[:SEQuence]:HOLDoff[:TIME]

–TRIGger<1|2>[:SEQuence]:IFPower:HOLDoff

–TRIGger<1|2>[:SEQuence]:IFPower:HYSTeresis

–TRIGger<1|2>[:SEQuence]:LEVel:IFPower

–TRIGger<1|2>[:SEQuence]:LEVel:VIDeo

–TRIGger<1|2>[:SEQuence]:SLOPe

–TRIGger<1|2>[:SEQuence]:SOURce

–TRIGger<1|2>[:SEQuence]:TIME:RINTerval

–TRIGger<1|2>[:SEQuence]:VIDeo:CONTinuous (option TV Trigger, B6)

–TRIGger<1|2>[:SEQuence]:VIDeo:FIELd:SELect (option TV Trigger, B6)

–TRIGger<1|2>[:SEQuence]:VIDeo:FORMat:LPFRame (option TV Trigger, B6)

–TRIGger<1|2>[:SEQuence]:VIDeo:LINE:NUMBer (option TV Trigger, B6)

–TRIGger<1|2>[:SEQuence]:VIDeo:SSIGnal:POLarity (option TV Trigger, B6)

TRIGger<1|2>[:SEQuence]:HOLDoff[:TIME]

This command defines the length of the trigger delay.

Anegative delay time (pretrigger) can be set in zero span only.

Parameter

–100 s to +100 s

for TV trigger (option B6, available from firmware version 1.10): –50 Usto +50 Us

Example

TRIG:HOLD 500us

Characteristics

*RST value: 0 s

SCPI: conform

Mode

all

TRIGger Subsystem R&S FSL

1300.2519.12 6.278 E-11

TRIGger<1|2>[:SEQuence]:IFPower:HOLDoff

ffThis command sets the holding time before the next IF power trigger event.

This command is available from firmware version 1.30.

Parameter

<numeric_value> in s: 150 ns to 1000 s

Example

TRIG:SOUR IFP

Sets the IF power trigger source.

TRIG:IFP:HOLD 200 ns

Sets the holding time to 200 ns.

Characteristics

*RST value: 150 ns

SCPI: device–specific

Mode

A–F

TRIGger<1|2>[:SEQuence]:IFPower:HYSTeresis

sThis command sets the limit that the hysteresis value has to fall below in order to trigger the

next measurement.

This command is available from firmware version 1.30.

Parameter

<numeric_value> in dB: 3 dB to 50 dB

Example

TRIG:SOUR IFP

Sets the IF power trigger source.

TRIG:IFP:HYST 10DB

Sets the hysteresis limit value.

Characteristics

*RST value: 3 dB

SCPI: device–specific

Mode

A–F

R&S FSL TRIGger Subsystem

1300.2519.12 6.279 E-11

TRIGger<1|2>[:SEQuence]:LEVel:IFPower

This command sets the level of the IF power trigger source.

Parameter

–50 to –10 DBM

Example

TRIG:LEV:IFP –30DBM

Characteristics

*RST value: –20 DBM

SCPI: device–specific

Mode

all

TRIGger<1|2[:SEQuence]:LEVel[:EXTernal]

This command sets the level of the external trigger source.

Parameter

Characteristics

*RST value: 50 PCT

SCPI: device–specific

Mode

all

TRIGger<1|2>[:SEQuence]:LEVel:VIDeo

This command sets the level of the video trigger source.

Parameter

0to 100 PCT

Example

TRIG:LEV:VID 50PCT

Characteristics

*RST value: 50 PCT

SCPI: device–specific

Mode

all, except ADEMOD

TRIGger Subsystem R&S FSL

1300.2519.12 6.280 E-11

TRIGger<1|2>[:SEQuence]:SLOPe

This command selects the slope of the trigger signal. The selected trigger slope applies to all

trigger signal sources except the TV trigger (option B6, available from firmware version 1.10).

Parameter

POSitive | NEGative

Example

TRIG:SLOP NEG

Characteristics

*RST value: POSitive

SCPI: conform

Mode

all

TRIGger<1|2>[:SEQuence]:SOURce

This command selects the trigger source for the start of a sweep.

Parameter

IMMediate (Free Run) | EXTern | IFPower | VIDeo | TIME (available from firmware version 1.60)

TV (option TV Trigger, B6, available from firmware version 1.10)

For details on trigger modes refer to chapter "Instrument Functions", section "Trigger mode

overview".

Example

TRIG:SOUR EXT

Selects the external trigger input as source of the trigger signal

Characteristics

*RST value: IMMediate

SCPI: conform

Mode

A, ADEMOD, CATV, CDMA, EVDO, SPECM, WCDMA

TRIGger<1|2>[:SEQuence]:TIME:RINTerval

This command sets the time intervall for the time trigger source.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0.1 to 5000 s

Example

TRIG:SOUR TIME

Selects the time trigger input for triggering.

TRIG:TIME:RINT 50

The sweep starts after 50 s.

R&S FSL TRIGger Subsystem

1300.2519.12 6.281 E-11

Characteristics

RST value: 1.0

SCPI: device–specific

Mode

A, SPECM

TRIGger<1|2>[:SEQuence]:VIDeo:CONTinuous (option TV Trigger, B6)

Activates or deactivates the free run trigger mode.

This command is available from firmware version 1.30.

Parameter

ON | OFF

Example

TRIG:VID:CONT ON

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

A–T

TRIGger<1|2>[:SEQuence]:VIDeo:FIELd:SELect (option TV Trigger, B6)

With active TV trigger this command activates triggering at the vertical sync signal.

Option TV Trigger, B6, is available from firmware version 1.10.

Parameter

ALL (both fields) | ODD (odd fields) | EVEN (even fields)

Example

TRIG:VID:FIEL:SEL ALL

Characteristics

*RST value: –

SCPI: conform

Mode

A–T

TRIGger<1|2>[:SEQuence]:VIDeo:FORMat:LPFRame (option TV Trigger, B6)

This command defines the line system in use (525 or 625 lines) with active TV trigger.

Option TV Trigger, B6, is available from firmware version 1.10.

Parameter

525 | 625

Example

TRIG:VID:FORM:LPFR 525

TRIGger Subsystem R&S FSL

1300.2519.12 6.282 E-11

Characteristics

*RST value: 625

SCPI: conform

Mode

A–T

TRIGger<1|2>[:SEQuence]:VIDeo:LINE:NUMBer (option TV Trigger, B6)

With active TV trigger this command activates triggering at the horizontal sync signal of the

indicated line number.

Option TV Trigger, B6, is available from firmware version 1.10.

Parameter

<numeric_value>

Example

TRIG:VID:LINE:NUMB 17

Characteristics

*RST value: –

SCPI: conform

Mode

A–T

TRIGger<1|2>[:SEQuence]:VIDeo:SSIGnal:POLarity (option TV Trigger, B6)

With active TV trigger this command selects the polarity of the video sync signal.

Option TV Trigger, B6, is available from firmware version 1.10.

Parameter

NEGative | POSitive

Example

TRIG:VID:SSIG:POL NEG

Characteristics

*RST value: NEGative

SCPI: conform

Mode

A–T

R&S FSL UNIT Subsystem

1300.2519.12 6.283 E-11

UNIT Subsystem

The UNIT subsystem sets the basic unit of the setting parameters.

Commands of the UNIT Subsystem

–UNIT<1|2>:POWer

UNIT<1|2>:POWer

This command selects the default unit.

Parameter

Example

UNIT:POW DBUV

Sets the power unit to dBm.

Characteristics

*RST value: DBM

SCPI: conform

Mode

Remote Commands of the Analog Demodulation Option (K7) R&S FSL

1300.2519.12 6.284 E-11

Remote Commands of the Analog Demodulation

Option (K7)

In this section all remote control commands for Analog Demodulation option are described in detail. The

abbreviation ADEMOD stands for the Analog Demodulation operating mode. For details on conventions

used in this chapter refer to section "Notation" on page 6.2 at the beginning of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in "Remote Commands of the Base Unit" on page 6.5.

This option is available from firmware version 1.10.

Subsystems of the Analog Demodulation option (K7)

–"CALCulate Subsystem (Analog Demodulation, K7)" on page 6.285

–"DISPlay Subsystem (Analog Demodulation, K7)" on page 6.295

–"INSTrument Subsystem (Analog Demodulation, K7)" on page 6.297

–"SENSe Subsystem (Analog Demodulation, K7)" on page 6.298

–"TRACe Subsystem (Analog Demodulation, K7)" on page 6.328

–"TRIGger Subsystem (Analog Demodulation, K7)" on page 6.329

–"UNIT Subsystem (Analog Demodulation, K7)" on page 6.331

R&S FSL CALCulate Subsystem (Analog Demodulation, K7)

1300.2519.12 6.285 E-11

CALCulate Subsystem (Analog Demodulation, K7)

The CALCulate subsystem contains commands for converting instrument data, transforming and

carrying out corrections. These functions are carried out subsequent to data acquisition, i.e. following

the SENSe subsystem.

The following subsystems are included:

•"CALCulate:DELTamarker Subsystem" on page 6.285

•"CALCulate:FEED Subsystem" on page 6.286

•"CALCulate:FORMat Subsystem (Analog Demodulation, K7)" on page 6.287

•"CALCulate:MARKer Subsystem" on page 6.288

•"CALCulate:UNIT Subsystem" on page 6.294

CALCulate:DELTamarker Subsystem (Analog Demodulation, K7)

The CALCulate:DELTamarker subsystem controls the delta marker functions of the instrument.

Commands of the CALCulate:DELTamarker Subsystem

–CALCulate<1|2>:DELTamarker<1...4>:Y?

CALCulate<1|2>:DELTamarker<1...4>:Y?

Depending on the unit defined with CALCulate<1|2>:UNIT:POWer or on the activated

measuring functions, the query result is output in the units below:

Result display Output unit

AM result display (R&S FSL–K7) % (lin)

dB (log)

FM result display (R&S FSL–K7) Hz (lin)

dB (log)

PM result display (R&S FSL–K7) rad | deg (lin)

dB (log)

RF result display (R&S FSL–K7) output unit defined with CALCulate<1|2>:UNIT:POWer

For further details refer to "CALCulate<1|2>:DELTamarker<1...4>:Y?" on page 6.22.

CALCulate Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.286 E-11

CALCulate:FEED Subsystem (Analog Demodulation, K7)

The CALCulate:FEED subsystem selects the evaluation method of the measured data. This

corresponds to the selection of the result display in manual mode.

Commands of the CALCulate:FEED Subsystem

–CALCulate<1|2>:FEED

CALCulate<1|2>:FEED

This command selects the measured data that are to be displayed.

The numeric suffixes <1|2> are irrelevant.

Parameter

XTIM:AM:RELative[:TDOMain] Demodulated AM signal in standardized

display

XTIM:AM:RELative:AFSPectrum<1...6> AF spectrum of the demodulated AM signal in

standardized display, results referenced to

traces 1 to 4

XTIM:AM[:ABSolute][:TDOMain] Demodulated AM signal in level display

Same as 'XTIM:RFPower'

XTIM:RFPower[:TDOMain] RF power of the signal

XTIM:FM[:TDOMain] Demodulated FM signal

XTIM:FM:AFSPectrum<1...6> AF spectrum of the demodulated FM signal,

results referenced to traces 1 to 4

XTIM:PM[:TDOMain] Demodulated PM signal

XTIM:PM:AFSPectrum<1...6> AF spectrum of the demodulated PM signal,

results referenced to traces 1 to 4

XTIM:AMSummary<1...6>[:ABSolute] AM results in level display, referenced to

traces 1 to 4

XTIM:AMSummary<1...6>:RELative AM results in standardized display, referenced

to traces 1 to 4

XTIM:FMSummary<1...6> FM results, referenced to traces 1 to 4

XTIM:PMSummary<1...6> PM results, referenced to traces 1 to 4

XTIM:SPECtrum RF spectrum of the signal determined from

the measured data via FFT

Example

INST:SEL ADEM

Activates analog demodulator.

CALC:FEED 'XTIM:FM'

Selects the display of the FM signal.

Characteristics

RST value: –

SCPI: conform

Mode

ADEMOD

R&S FSL CALCulate Subsystem (Analog Demodulation, K7)

1300.2519.12 6.287 E-11

CALCulate:FORMat Subsystem (Analog Demodulation, K7)

The CALCulate:FORMat subsystem defines the conversion of measured data.

Commands of the CALCulate:FORMat Subsystem

–CALCulate<1|2>:FORMat

CALCulate<1|2>:FORMat

This command activates the limitation to ±180°.

The numeric suffixes <1|2> are irrelevant.

Parameter

PHASe Limitation to ±180°

UPHase Unwrapped

Example

CALC:FORM PHAS

Activates the limitation to ±180°.

Characteristics

RST value: UPHase

SCPI: conform

Mode

ADEMOD

CALCulate Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.288 E-11

CALCulate:MARKer Subsystem (Analog Demodulation, K7)

The CALCulate:MARKer subsystem checks the marker functions of the instrument.

The following subsystem is included:

•"CALCulate:MARKer:FUNCtion:ADEMod Subsystem (Analog Demodulation, K7)" on page 6.289

Commands of the CALCulate:MARKer Subsystem

–CALCulate<1|2>:MARKer<1...4>:PEXCursion

–CALCulate<1|2>:MARKer<1...4>:Y?

CALCulate<1|2>:MARKer<1...4>:PEXCursion

The unit depends on the active display.

Example

CALC:MARK:PEXC 100 HZ

Defines peak excursion 100 Hz

Characteristics

*RST value:

6dB RF displays

5PCT AM displays

50 kHz FM displays

0.5 RAD PM displays

For further details refer to "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

CALCulate<1|2>:MARKer<1...4>:Y?

If the analog demodulator (option Analog Demodulation, R&S FSL–K7) is activated, the query

result is output in the following units:

Result display Output unit

AM %

FM Hz

PM rad/deg (defined with CALCulate<1|2>: UNIT:ANGLe)

RF output unit defined with CALCulate<1|2>:UNIT:POWer

For further details refer to "CALCulate<1|2>:MARKer<1...4>:Y?" on page 6.66.

R&S FSL CALCulate Subsystem (Analog Demodulation, K7)

1300.2519.12 6.289 E-11

CALCulate:MARKer:FUNCtion:ADEMod Subsystem (Analog Demodulation, K7)

The CALCulate:MARKer:FUNCtion:ADEMod subsystem contains the marker functions for the option

Analog Demodulation, R&S FSL–K7.

Commands of the CALCulate:MARKer:FUNCtion:ADEMod Subsystem

–CALCulate<1|2>:MARKer:FUNCtion:ADEMod:AFRequency[:RESult<1...6>?]

–CALCulate<1|2>:MARKer:FUNCtion:ADEMod:AM[:RESult<1...6>?]

–CALCulate<1|2>:MARKer:FUNCtion:ADEMod:CARRier[:RESult<1...6>?]

–CALCulate<1|2>:MARKer:FUNCtion:ADEMod:FERRor[:RESult<1...6>?]

–CALCulate<1|2>:MARKer:FUNCtion:ADEMod:FM[:RESult<1...6>?]

–CALCulate<1|2>:MARKer:FUNCtion:ADEMod:PM[:RESult<1...6>?]

–CALCulate<1|2>:MARKer:FUNCtion:ADEMod:SINad:RESult<1...6>?

–CALCulate<1|2>:MARKer:FUNCtion:ADEMod:THD:RESult<1...6>?

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:AFRequency[:RESult<1...6>?]

This command queries the audio frequency with analog demodulation. The numeric suffix

(:RESult<1...6>)indicates whether trace 1, 2, 3, 4, 5 or 6 is selected. The numeric suffixes

<1|2> are irrelevant.

Note: If several demodulation modes are activated simultaneously (e.g. with the

[SENSe:]ADEMod:FM[:TDOMain][:TYPE] command, the audio frequency of the

display mode selected with CALCulate<1|2>:FEED is returned.

Example

ADEM ON

Switches on analog demodulator

CALC:FEED 'XTIM:AM:TDOM'

Switches on AM result display.

CALC:FEED 'XTIM:FM:TDOM'

Switches on FM result display.

CALC:FEED 'XTIM:FM:AFSP'

DISP:TRAC ON

Switches on AF spectrum result display of FM and trace.

CALC:MARK:FUNC:ADEM:AFR?

Queries the audio frequency.

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

CALCulate Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.290 E-11

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:AM[:RESult<1...6>?]

This command queries the results of the AM modulation measurement. The numeric suffix

(:RESult<1...6>)indicates whether trace 1, 2, 3, 4, 5 or 6 is selected. The numeric suffixes

<1|2> are irrelevant.

Parameter

PPEak Result of measurement with detector +PK

MPEak Result of measurement with detector –PK

MIDDle Result of averaging ±PK/2

RMS Result of rms measurement

Example

ADEM ON

Switches on the analog demodulator.

CALC:FEED 'XTIM:AM:REL:TDOM'

Switches on the AM result display.

DISP:TRAC ON

Switches on the trace.

CALC:MARK:FUNC:ADEM:AM? PPE

Queries the peak value.

Characteristics

RST value: –

SCPI: device–specific

Mode

ADEMOD

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:CARRier[:RESult<1...6>?]

This command queries the carrier power. The numeric suffix (:RESult<1...6>)indicates

whether trace 1, 2, 3, 4, 5 or 6 is selected. The numeric suffixes <1|2> are irrelevant.

With RF Power result display, the carrier power is determined from trace 1 to 6 indicated in the

numeric suffix. With all other result displays, the carrier power is determined from the current

trace data (CLR/WRITE trace).

This command is only a query and therefore has no *RST value.

Example

ADEM ON

Switches on analog demodulator

CALC:FEED 'XTIM:RFP'

Switches on RF power result display

CALC:MARK:FUNC:ADEM:CARR?

Queries the carrier power

R&S FSL CALCulate Subsystem (Analog Demodulation, K7)

1300.2519.12 6.291 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:FERRor[:RESult<1...6>?]

This command queries the frequency error with FM and PM demodulation. With FM

demodulation, trace 1 to 6 is selected with the numeric suffix (:RESult<1...6>). With PM

demodulation, the frequency error is determined from the current measurement data

(CLR/WRITE trace). The numeric suffixes <1|2> are irrelevant.

The offset thus determined differs from that calculated in the [SENSe:]ADEMod:FM:OFFSet?

command since, for determination of the frequency deviation, the modulation is removed by

means of lowpass filtering, producing results that are different from those obtained by averaging

with the SENSe command.

This command is only available for traces in the FM and PM result display. If another result

display is selected, the command is disabled.

Example

ADEM ON

Switches on analog demodulator

CALC:FEED 'XTIM:FM:TDOM'

Switches on FM result display

CALC:MARK:FUNC:ADEM:FERR?

Queries the frequency error of trace 1

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:FM[:RESult<1...6>?]

This command queries the results of FM modulation measurement. The numeric suffix

(:RESult<1...6>)indicates whether trace 1, 2, 3, 4, 5 or 6 is selected. The numeric suffixes

<1|2> are irrelevant.

Parameter

PPEak Result of measurement with detector +PK

MPEak Result of measurement with detector –PK

MIDDle Result of averaging ±PK/2

RMS Result of rms measurement

CALCulate Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.292 E-11

Example

ADEM ON

Switches on the analog demodulator.

CALC:FEED 'XTIM:FM:TDOM'

Switches on the FM result display.

CALC:MARK:FUNC:ADEM:FM? PPE

Queries the peak value.

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:PM[:RESult<1...6>?]

This command queries the results of PM modulation measurement of analog demodulation. The

numeric suffix (:RESult<1...6>)indicates whether trace 1, 2, 3, 4, 5 or 6 is selected. The

numeric suffixes <1|2> are irrelevant.

Parameter

PPEak Result of measurement with detector +PK

MPEak Result of measurement with detector –PK

MIDDle Result of averaging ±PK/2

RMS Result of rms measurement

Example

ADEM ON

Switches on the analog demodulator.

CALC:FEED 'XTIM:PM:TDOM'

Switches on the FM result display.

CALC:MARK:FUNC:ADEM:PM? PPE

Queries the peak value.

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

R&S FSL CALCulate Subsystem (Analog Demodulation, K7)

1300.2519.12 6.293 E-11

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:SINad:RESult<1...6>?

This command queries the result of the SINAD measurement. The numeric suffix

(:RESult<1...6>)indicates whether trace 1, 2, 3, 4, 5 or 6 is selected. The numeric suffixes

<1|2> are irrelevant.

This command is a query only and thus has no *RST value.

Example

ADEM ON

Switches on analog demodulator

CALC:FEED 'XTIM:FM:AFSP'

DISP:TRAC ON

Switches on AF spectrum of FM and trace

CALC:MARK:FUNC:ADEM:SIN:RES?

Queries SINAD value

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:THD:RESult<1...6>?

This command queries the result of the THD measurement. The numeric suffix

(:RESult<1...6>)indicates whether trace 1, 2, 3, 4, 5 or 6 is selected. The numeric suffixes

<1|2> are irrelevant.

This command is a query only and thus has no *RST value.

Example

ADEM ON

Switches on analog demodulator

CALC:FEED 'XTIM:FM:AFSP'

Switches on AF spectrum of FM and trace

DISP:TRAC ON

Switches on the trace

CALC:MARK:FUNC:ADEM:THD:RES?

Queries THD result

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

CALCulate Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.294 E-11

CALCulate:UNIT Subsystem (Analog Demodulation, K7)

The CALCulate:Unit subsystem defines the units for the parameters that can be set and the

measurement results.

Commands of the CALCulate:UNIT Subsystem

–CALCulate<1|2>: UNIT:ANGLe

CALCulate<1|2>: UNIT:ANGLe

This command selects the unit for angles.

Parameter

DEG | RAD

Example:

CALC:UNIT:ANGL DEG

Characteristics:

*RST value: RAD

SCPI: device–specific

Mode

ADEMOD

R&S FSL DISPlay Subsystem (Analog Demodulation, K7)

1300.2519.12 6.295 E-11

DISPlay Subsystem (Analog Demodulation, K7)

The DISPLay subsystem controls the selection and presentation of textual and graphic information as

well as of measurement data on the display.

Commands of the DISPlay Subsystem

–DISPlay[:WINDow<1|2>]:SIZE

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:PDIVision

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y:SPACing

DISPlay[:WINDow<1|2>]:SIZE

This command switches the measurement window for active analog demodulation to full screen

or half screen.

For further details refer to "DISPlay[:WINDow<1|2>]:SIZE" on page 6.130.

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:PDIVision

This command defines the scaling of the y–axis in the current unit. The numeric suffix in

TRACe<1...6> is irrelevant. The numeric suffixes <1|2> are irrelevant.

Parameter

<numeric_value>

Example

DISP:TRAC:Y:PDIV +10kHz

Sets the Y scale to 10 kHz/div.

Characteristics

*RST value:

20 PCT linear AM display

50 kHz linear FM display

2rad linear PM display

10 dB logarithmic AF spectrum display

SCPI: conform

Mode

ADEMOD

DISPlay Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.296 E-11

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

Characteristics

*RST value:

100 PCT AF spectrum display of AM, FM, or PM

50 PCT AM, FM, or PM display

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

(models with tracking generator)" on page 6.136.

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue

This command defines the reference value assigned to the reference position. Separate

reference values are maintained for the various displays.

Example

DISP:TRAC:Y:RVAL 0

Sets the value assigned to the reference position to 0 Hz (analog demodulation)

Characteristics

*RST value:

0PCT AM display

0Hz FM display

0rad PM display

100 PCT AF spectrum display of AM signal

250 kHz AF spectrum display of FM signal

10 rad AF spectrum display of PM signal

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

(models with tracking generator)" on page 6.136.

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y:SPACing

When the AF spectrum result display is selected, only the parameters LINear and LOGarithmic

are allowed.

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y:SPACing" on page 6.134.

R&S FSL INSTrument Subsystem (Analog Demodulation, K7)

1300.2519.12 6.297 E-11

INSTrument Subsystem (Analog Demodulation, K7)

The INSTrument subsystem selects the operating mode of the unit either via text parameters or fixed

numbers.

Commands of the INSTrument Subsystem

–INSTrument[:SELect]

–INSTrument:NSELect

INSTrument[:SELect]

Parameter

ADEMod (Analog Demodulation option, R&S FSL–K7)

For further details refer to the INSTrument subsystem of the base unit.

INSTrument:NSELect

Parameter

3(Analog Demodulation option, R&S FSL–K7)

For further details refer to the INSTrument subsystem of the base unit.

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.298 E-11

SENSe Subsystem (Analog Demodulation, K7)

The SENSe subsystem is organized in several subsystems. The commands of these subsystems

directly control device–specific settings, they do not refer to the signal characteristics of the

measurement signal.

The SENSe subsystem controls the essential parameters of the analyzer. In accordance with the SCPI

standard, the keyword "SENSe" is optional for this reason, which means that it is not necessary to

include the SENSe node in command sequences.

The following subsystems are included:

•"SENSe:ADEMod Subsystem" on page 6.299

•"SENSe:BANDwidth Subsystem" on page 6.323

•"SENSe:FILTer Subsystem" on page 6.324

•"SENSe:FREQuency Subsystem" on page 6.327

•"SENSe:SWEep Subsystem" on page 6.327

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.299 E-11

SENSe:ADEMod Subsystem (Analog Demodulation, K7)

The SENSe:ADEMod Subsystem contains commands to set up the instrument for the measurement of

analog demodulated signals and query the result at the end of the measurement.

Commands of the SENSe:ADEMod Subsystem

–[SENSe:]ADEMod[:STATe]

–[SENSe:]ADEMod:AF:CENTer

–[SENSe:]ADEMod:AF:COUPling

–[SENSe:]ADEMod:AF:SPAN

–[SENSe:]ADEMod:AF:SPAN:FULL

–[SENSe:]ADEMod:AF:STARt

–[SENSe:]ADEMod:AF:STOP

–[SENSe:]ADEMod:AM[:ABSolute][:TDOMain][:TYPE]

–[SENSe:]ADEMod:AM[:ABSolute][:TDOMain]:RESult?

–[SENSe:]ADEMod:AM:RELative[:TDOMain][:TYPE]

–[SENSe:]ADEMod:AM:RELative[:TDOMain]:RESult?

–[SENSe:]ADEMod:AM:RELative:AFSPectrum[:TYPE]

–[SENSe:]ADEMod:AM:RELative:AFSPectrum:RESult?

–[SENSe:]ADEMod:BANDwidth|BWIDth:DEModulation

–[SENSe:]ADEMod:FM[:TDOMain][:TYPE]

–[SENSe:]ADEMod:FM[:TDOMain]:RESult?

–[SENSe:]ADEMod:FM:AFSPectrum[:TYPE]

–[SENSe:]ADEMod:FM:AFSPectrum:RESult?

–[SENSe:]ADEMod:FM:OFFSet?

–[SENSe:]ADEMod:MTIMe

–[SENSe:]ADEMod:PM[:TDOMain][:TYPE]

–[SENSe:]ADEMod:PM[:TDOMain]:RESult?

–[SENSe:]ADEMod:PM:AFSPectrum[:TYPE]

–[SENSe:]ADEMod:PM:AFSPectrum:RESult?

–[SENSe:]ADEMod:PM:RPOint[:X]

–[SENSe:]ADEMod:RLENgth?

–[SENSe:]ADEMod:SET

–[SENSe:]ADEMod:SPECtrum[:TYPE]

–[SENSe:]ADEMod:SPECtrum:BANDwidth|BWIDth[:RESolution]

–[SENSe:]ADEMod:SPECtrum:RESult?

–[SENSe:]ADEMod:SPECtrum:SPAN[:MAXimum]

–[SENSe:]ADEMod:SPECtrum:SPAN:ZOOM

–[SENSe:]ADEMod:SRATe?

–[SENSe:]ADEMod:ZOOM[:STATe]

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.300 E-11

–[SENSe:]ADEMod:ZOOM:STARt

Further information

–Trace mode result types

–Formats for returned values: ASCII format and binary format

Trace mode result types

The following result types can be set:

WRITe The current trace results will be obtained

AVERage The trace results will be averaged over the given # of measurements

MAXHold The maximum trace result values will be obtained over the given # of

measurements

MINHold The minimum trace result values will be obtained over the given # of measurements

VIEW The trace results are frozen and displayed, i.e. they are not calculated for

subsequent measurements. Traces in this mode cannot be queried.

OFF The result type will not be used.

Note: It is not possible to query trace data when result type VIEW is selected.

Each value besides OFF can only be assigned to one result type at a time.

If all result types are set to OFF, the AM, FM, or PM demodulator will be deactivated.

Formats for returned values: ASCII format and binary format

•ASCII Format (FORMat ASCII):

The command reads out a list of comma separated values (CSV) of the measured values in floating

point format.

•Binary Format (FORMat REAL,32):

The command reads out binary data (Definite Length Block Data according to IEEE 488.2), each

measurement value being formatted in 32 Bit IEEE 754 Floating–Point–Format. The schematics of

the result string will be as follows:

#41024<value1><value2>...<value n> with

#4 number of digits (= 4 in the example) of the following number of data bytes

1024 number of following data bytes (= 1024 in the example)

<value> 4–byte floating point value

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.301 E-11

[SENSe:]ADEMod[:STATe]

This command activates the analog demodulator of the instrument. The instrument will be set to

zero span at the current center frequency.

Parameter

ON | OFF

Example

ADEM ON

Switches the analog demodulator on.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:AF:CENTer

This command sets the center frequency for AF spectrum result display.

Parameter

<numeric_value>

Example

ADEM ON

Switches on the analog demodulator

CALC:FEED 'XTIM:FM:AFSP'

Switches on AF spectrum result display of FM

ADEM:BAND 5 MHz

Sets the measurement bandwidth to 5 MHz

ADEM:AF:CENT 500kHz

Sets the AF center frequency to 500 kHz

ADEM:AF:SPAN 200kHz

Sets the AF span to 200 kHz

Characteristics

*RST value: 1.25 MHz

SCPI: device–specific

Mode

ADEMOD

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.302 E-11

[SENSe:]ADEMod:AF:COUPling

This command selects the coupling of the AF path of the analyzer.

Parameter

AC | DC

Example

ADEM:AF:COUP DC

Switches on DC coupling.

Characteristics

*RST value: AC (PM); DC (FM)

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:AF:SPAN

This command sets the span for AF spectrum result display.l

The span is limited to half the measurement bandwidth of analog demodulation

([SENSe:]ADEMod:BANDwidth|BWIDth:DEModulation).

Parameter

<numeric_value>

Example

ADEM ON

Switches on the analog demodulator

CALC:FEED 'XTIM:FM:AFSP'

Switches on AF spectrum result display of FM

ADEM:BAND 5 MHz

Sets the measurement bandwidth to 5 MHz

ADEM:AF:CENT 500kHz

Sets the AF center frequency to 500 kHz

ADEM:AF:SPAN 200kHz

Sets the AF span to 200 kHz

Characteristics

*RST value: 2.5 MHz

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.303 E-11

[SENSe:]ADEMod:AF:SPAN:FULL

This command sets the maximum span for AF spectrum result display.

The maximum span corresponds to half the measurement bandwidth of analog demodulation

([SENSe:]ADEMod:BANDwidth|BWIDth:DEModulation).

Example

ADEM ON

Switches on the analog demodulator

CALC:FEED 'XTIM:FM:AFSP'

Switches on AF spectrum result display of FM

ADEM:BAND 5 MHz

Sets the measurement bandwidth to 5 MHz

ADEM:AF:SPAN:FULL

Sets the AF span to 2.5 MHz

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:AF:STARt

This command sets the start frequency for AF spectrum result display.

Parameter

<numeric_value>

Example

ADEM ON

Switches on analog demodulator

CALC:FEED 'XTIM:FM:AFSP'

Switches on AF spectrum result display of FM

ADEM:BAND 5 MHz

Sets the measurement bandwidth to 5 MHz

ADEM:AF:STAR 0kHz

Sets the AF start frequency to 0 kHz

ADEM:AF:STOP 500kHz

Sets the AF stop frequency to 500 kHz

Characteristics

*RST value: 0 MHz

SCPI: device–specific

Mode

ADEMOD

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.304 E-11

[SENSe:]ADEMod:AF:STOP

This command sets the stop frequency for AF spectrum result display.

The stop frequency is limited to half the measurement bandwidth of analog demodulation

([SENSe:]ADEMod:BANDwidth|BWIDth:DEModulation).

Parameter

<numeric_value>

Example

ADEM ON

Switches on the analog demodulator

CALC:FEED 'XTIM:FM:AFSP'

Switches on AF spectrum result display of FM

ADEM:BAND 5 MHz

Sets the measurement bandwidth to 5 MHz

ADEM:AF:STAR 0kHz

Sets the AF start frequency to 0 kHz

ADEM:AF:STOP 500kHz

Sets the AF stop frequency to 500 kHz

Characteristics

*RST value: 2.5 MHz

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:AM[:ABSolute][:TDOMain][:TYPE]

This command selects the result types of the RF signal to be measured simultaneously in zero

span.

Parameter

<result type 1|2|3|4|5|6>: WRITe, AVERage, MAXHold, MINHold, VIEW, OFF; for details see

"Trace mode result types" on page 6.300.

Example

ADEM:AM AVER,MAXH,MINH

Determines average, max hold and min hold values at a time.

ADEM:AM WRIT,OFF,OFF

Determines only the current measurement values.

ADEM:AM OFF,OFF,OFF

Switches AM demodulation off.

Characteristics

*RST value: WRITe,OFF,OFF

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.305 E-11

[SENSe:]ADEMod:AM[:ABSolute][:TDOMain]:RESult?

This command reads the result data of the RF signal in zero span for the specified result type.

The data format of the output data block is defined by the FORMat command.

Parameter

<result type>: WRITe, AVERage, MAXHold, MINHold; for details see "Trace mode result types"

on page 6.300.

Note: The result type indicated must be one of those configured by

[SENSe:]ADEMod:AM[:ABSolute][:TDOMain][:TYPE].Otherwise a query error

will be generated.

Return values

ASCII Format (FORMat ASCII) or Binary Format (FORMat REAL,32); for details see "Formats

for returned values: ASCII format and binary format" on page 6.300. The ouput units are

described in "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

Example

ADEM:SET 8MHz,32000,EXT,POS,–500,30

Sets up demodulator parameters

ADEM:AM AVER,MAXH,MINH

Sets up AM results to be measured

ADEM ON

Switches on demodulator

INIT;*WAI

Starts measurement and waits for sync

FORM ASC

Selects output format

ADEM:AM:RES? AVER

Reads AM average results

ADEM:AM:RES? MAXH

Reads AM max hold results

ADEM:AM:RES? MINH

Reads AM min hold results

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:AM:RELative[:TDOMain][:TYPE]

This command selects the result types to be measured simultaneously by AM demodulation.

Parameter

<result type 1|2|3|4|5|6>: WRITe, AVERage, MAXHold, MINHold, VIEW, OFF; for details see

"Trace mode result types" on page 6.300.

Example

ADEM:AM:REL AVER,MAXH,MINH

Determines average, max hold and min hold values simultaneously.

ADEM:AM:REL WRIT,OFF,OFF

Determines only the current measurement values.

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.306 E-11

ADEM:AM:REL OFF,OFF,OFF

Switches AM demodulation off.

Characteristics

*RST value: OFF,OFF,OFF

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:AM:RELative[:TDOMain]:RESult?

This command reads the result data obtained by AM demodulation for the specified result type.

The data format of the output data block is defined by the FORMat command.

Parameter

<result type>: WRITe, AVERage, MAXHold, MINHold; for details see "Trace mode result types"

on page 6.300.

Note: The result type indicated must be one of those configured by

[SENSe:]ADEMod:AM:RELative[:TDOMain][:TYPE].Otherwise a query error will

be generated.

Return values

ASCII Format (FORMat ASCII) or Binary Format (FORMat REAL,32); for details see "Formats

for returned values: ASCII format and binary format" on page 6.300. The ouput units are

described in "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

Example

ADEM:SET 8MHz,32000,EXT,POS,–500,30

Sets up demodulator parameters

ADEM:FM AVER,MAXH,MINH

Selects FM results to be measured

ADEM:AM:REL WRIT,OFF,OFF

Selects AM results to be measured

ADEM ON

Switches on demodulator

INIT;*WAI

Starts measurement and waits for sync

FORM ASC

Selects output format

ADEM:FM:RES? AVER

Reads FM average results

ADEM:FM:RES? MAXH

Reads FM max hold results

ADEM:FM:RES? MINH

Reads FM min hold results

ADEM:AM:REL:RES? WRIT

Reads current AM result data

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.307 E-11

[SENSe:]ADEMod:AM:RELative:AFSPectrum[:TYPE]

This command selects the AF spectrum result types of the AM–demodulated signal to be

measured simultaneously.

Parameter

<result type 1|2|3|4|5|6>: WRITe, AVERage, MAXHold, MINHold, VIEW, OFF; for details see

"Trace mode result types" on page 6.300.

Note: The result type "AF spectrum of AM–demodulated signal" cannot be activated at the

same time as "AF spectrum of FM or PM demodulated signal".

Example

ADEM:AM:REL:AFSP AVER,MAXH,MINH

Determines average, maximum and minimum value simultaneously

ADEM:AM:REL:AFSP WRIT,OFF,OFF

Determines only current measurement results

ADEM:AM:REL:AFSP OFF,OFF,OFF

Switches off calculation of the AF spectrum

Characteristics

*RST value: OFF,OFF,OFF

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:AM:RELative:AFSPectrum:RESult?

This command reads out the AF spectrum result data of the AM–demodulated signal for the

specified result type. The data format of the output data is determined with the FORMat

command.

Parameter

<result type>: WRITe, AVERage, MAXHold, MINHold; for details see "Trace mode result types"

on page 6.300.

Note: The specified result type must be one of those configured with the

[SENSe:]ADEMod:AM:RELative:AFSPectrum[:TYPE] command. Otherwise a

query error will be generated.

Return values

ASCII Format (FORMat ASCII) or Binary Format (FORMat REAL,32); for details see "Formats

for returned values: ASCII format and binary format" on page 6.300. The ouput units are

described in section "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

Example

ADEM:SET 8MHz,32000,EXT,POS,–500,30

Sets the demodulator

ADEM:FM AVER,MAXH,MINH

Selects the FM results to be measured

ADEM:AM:REL WRIT,OFF,OFF

Selects the AM results to be measured

ADEM:AM:REL:AFSP WRIT,OFF,OFF

Selects the AF spectrum results of the demodulated AM signal to be measured

ADEM ON

Switches on the demodulator

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.308 E-11

INIT;*WAI

Starts the measurement and waits for the termination

FORM ASC

Selects the output format

ADEM:FM:RES? AVER

Reads the FM average result data

ADEM:FM:RES? MAXH

Reads the FM Maxhold result data

ADEM:FM:RES? MINH

Reads the FM Minhold result data

ADEM:AM:REL:RES? WRIT

Reads the current AM result data

ADEM:AM:REL:AFSP:RES? WRIT

Reads the current AF spectrum result data of the demodulated AM signal

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:BANDwidth|BWIDth:DEModulation

This command defines the demodulation bandwidth used for analog demodulation. The required

sampling rate is automatically set depending on the selected demodulation bandwidth. The

available demodulation bandwidths are determined by the existing sampling rates (see table

below).

Parameter

<numeric_value>

For details on the correlation of bandwidth and sample rate refer to chapter "Instrument

Functions", section "Analog Demodulation (Option K7)" – "Sample rate, measurement time and

trigger offset".

Example

ADEM:BAND:DEM 1MHz

Sets the demodulation bandwidth to 1 MHz.

Characteristics

*RST value: 5 MHz

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.309 E-11

[SENSe:]ADEMod:FM[:TDOMain][:TYPE]

This command selects the result types to be measured simultaneously by FM demodulation.

Parameter

<result type 1|2|3|4>: WRITe, AVERage, MAXHold, MINHold, VIEW, OFF; for details see

"Trace mode result types" on page 6.300.

Example

ADEM:FM AVER,MAXH,MINH

"Creates average, max hold and min hold values simultaneously

DEM:FM WRIT,OFF,OFF

Only creates the current measurement values

ADEM:FM OFF,OFF,OFF

Switches analog demodulator off

Characteristics

*RST value: WRITe,OFF,OFF

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:FM[:TDOMain]:RESult?

This command reads the result data obtained by analog demodulation for the specified result

type. The data format of the output data block is defined by the FORMat command.

Parameter

<result type>: WRITe, AVERage, MAXHold, MINHold; for details see "Trace mode result types"

on page 6.300.

Note: The result type indicated must be one of those configured by

[SENSe:]ADEMod:FM[:TDOMain][:TYPE].Otherwise a query error will be

generated.

Return values

ASCII Format (FORMat ASCII) or Binary Format (FORMat REAL,32); for details see "Formats

for returned values: ASCII format and binary format" on page 6.300. The ouput units are

described in "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

Example

ADEM:SET 8MHz,32000,EXT,POS,–500,30

Sets up demodulator parameters

ADEM:FM AVER,MAXH,MINH

Selects FM results to be measured

ADEM:AM WRIT,OFF,OFF

Selects AM results to be measured

ADEM ON

Switches on demodulator

INIT;*WAI

Starts measurement and waits for sync

FORM ASC

Selects output format

ADEM:FM:RES? AVER

Reads FM average results

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.310 E-11

ADEM:FM:RES? MAXH

Reads FM max hold results

ADEM:FM:RES? MINH

Reads FM min hold results

ADEM:AM:RES? WRIT

Reads current AM results

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:FM:AFSPectrum[:TYPE]

This command selects the AF spectrum result types of the FM demodulated signal to be

measured simultaneously.

Parameter

<result type 1|2|3|4|5|6>: WRITe, AVERage, MAXHold, MINHold, VIEW, OFF; for details see

"Trace mode result types" on page 6.300.

Note: The result type "AF spectrum of the FM demodulated signal" cannot be activated at the

same time as "AF spectrum of AM or PM demodulated signal".

Example

ADEM:FM:AFSP AVER,MAXH,MINH

Determines average, maximum and minimum value simultaneously

ADEM:FM:AFSP WRIT,OFF,OFF

Determines only current measurement results

ADEM:FM:AFSP OFF,OFF,OFF

Switches calculation of AF spectrum off

Characteristics

*RST value: OFF,OFF,OFF

SCPI: device–specific

Mode

[SENSe:]ADEMod:FM:AFSPectrum:RESult?

This command reads out the AF spectrum result data of the FM demodulated signal for the

specified result type. The data format of the output data is determined with the FORMat

command.

Parameter

<result type>: WRITe, AVERage, MAXHold, MINHold; for details see "Trace mode result types"

on page 6.300.

Note: The specified result type must be one of those configured with the

[SENSe:]ADEMod:FM:AFSPectrum[:TYPE] command. Otherwise a query error will

be generated.

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.311 E-11

Return values

ASCII Format (FORMat ASCII) or Binary Format (FORMat REAL,32); for details see "Formats

for returned values: ASCII format and binary format" on page 6.300. The ouput units are

described in "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

Example

ADEM:SET 8MHz,32000,EXT,POS,–500,30

Sets demodulator

ADEM:FM AVER,MAXH,MINH

Selects the FM results to be measured

ADEM:AM:REL WRIT,OFF,OFF

Selects the AM results to be measured

ADEM:FM:AFSP WRIT,OFF,OFF

Selects the AF spectrum results of the demodulated FM signal to be measured

ADEM ON

Switches the demodulator on

INIT;*WAI

Starts the measurement and waits for termination

FORM ASC

Selects output format

ADEM:FM:RES? AVER

Reads FM average result data

ADEM:FM:RES? MAXH

Reads FM maxhold result data

ADEM:FM:RES? MINH

Reads FM minhold result data

ADEM:AM:RES? WRIT

Reads current AM result data

ADEM:FM:AFSP:RES? WRIT

Reads current AF spectrum result data of demodulated FM signal

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:FM:OFFSet?

This command calculates the FM offset of the currently available measurement data set.

If averaging has been activated before acquiring the data set (using

[SENSe:]ADEMod:FM[:TDOMain][:TYPE],the averaged FM offset over several

measurements can also be obtained by setting <result type> = AVERage.

The offset thus determined differs from the one calculated by the

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:FERRor[:RESult<1...6>?] command

since, for determination of the frequency deviation, the modulation is removed by means of

lowpass filtering, producing results that are different from those obtained by averaging.

Parameter

IMMediate The current measurement results will be used for calculating the FM

offset

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.312 E-11

AVERage The measurement results that were averaged over the given # of

measurements will be used for calculating the FM offset

Note: If no average measurement was active during the last measurement sequence only the

[SENSe:]ADEMod:FM:OFFSet? IMMediate command will return a correct result

(data to calculate the offset are taken from the last measured data set).

[SENSe:]ADEMod:FM:OFFSet? AVERage will cause a query error in this case.

Example

ADEM:SET 8MHz,32000,EXT,POS,–500,30

Sets up demodulator parameters to execute 30 measurements

ADEM:FM AVER,OFF,OFF

Selects FM results to perform averaging

ADEM:AM OFF,OFF,OFF

Switches off AM demodulation

ADEM ON

Switches on analog demodulator

INIT;*WAI

Starts measurement and waits for sync

ADEM:FM:OFFS? IMM

Reads FM offset of last measurement of the sequence of 30

ADEM:FM:OFFS? AVER

Reads FM offset averaged over 30 measurements

Characteristics

*RST values: –

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:MTIMe

This command defines the measurement time for analog demodulation.

Parameter

<numeric_value>

Example

ADEM:MTIM 62.5us

Sets the measurement time to 62.5 µs.

Characteristics

*RST value: 62.5us

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.313 E-11

[SENSe:]ADEMod:PM[:TDOMain][:TYPE]

This command selects the result types of the PM–demodulated signal to be created

simultaneously.

Parameter

<result type 1|2|3|4|5|6>: WRITe, AVERage, MAXHold, MINHold, VIEW; for details see "Trace

mode result types" on page 6.300.

Example

ADEM:PM AVER,MAXH,MINH

Determines average, maximum and minimum value simultaneously

ADEM:PM WRIT,OFF,OFF

Determines only current measurement results

ADEM:PM OFF,OFF,OFF

Switches the PM demodulator off.

Characteristics

RST value: OFF,OFF,OFF

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:PM[:TDOMain]:RESult?

This command reads the result data of the PM demodulation for the specified result type. The

data format of the output data is determined with the FORMat command.

Parameter

<result type>: WRITe, AVERage, MAXHold, MINHold; for details see "Trace mode result types"

on page 6.300.

Note: The specified result type must be one of those configured with the

[SENSe:]ADEMod:PM[:TDOMain][:TYPE] command. Otherwise a query error will

be generated.

Return values

ASCII Format (FORMat ASCII) or Binary Format (FORMat REAL,32); for details see "Formats

for returned values: ASCII format and binary format" on page 6.300. The ouput units are

described in "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

Example

ADEM:SET 8MHz,32000,EXT,POS,–500,30

Sets the demodulator parameters.

ADEM:PM AVER,MAXH,MINH

Selects the PM results to be measured.

ADEM:AM WRIT,OFF,OFF

Selects the AM results to be measured.

ADEM ON

Switches on the demodulator.

INIT;*WAI

Starts the measurement and waits for termination.

FORM ASC

Selects the output format.

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.314 E-11

ADEM:PM:RES? AVER

Reads the PM average result data.

ADEM:PM:RES? MAXH

Reads the PM maxhold result data.

ADEM:PM:RES? MINH

Reads the PM minhold result data.

ADEM:AM:RES? WRIT

Reads the current AM result data.

Characteristics

RST value: –

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:PM:AFSPectrum[:TYPE]

This command selects the AF spectrum result types of the PM–demodulated signal to be

measured simultaneously.

Parameter

<result type 1|2|3|4|5|6>: WRITe, AVERage, MAXHold, MINHold, VIEW; for details see "Trace

mode result types" on page 6.300.

Note: The result type "AF spectrum of the PM demodulated signal" cannot be activated at the

same time as "AF spectrum of AM or FM demodulated signal".

Example

ADEM:PM:AFSP AVER,MAXH,MINH

Determines average, maximum and minimum value simultaneously

ADEM:PM:AFSP WRIT,OFF,OFF

Determines only current measurement results

ADEM:PM:AFSP OFF,OFF,OFF

Switches calculation of AF spectrum off

Characteristics

RST value: OFF,OFF,OFF

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.315 E-11

[SENSe:]ADEMod:PM:AFSPectrum:RESult?

This command reads out the AF spectrum result data of the PM–demodulated signal for the specified

result type. The data format of the output data is determined with the FORMat command.

Parameter

<result type>: WRITe, AVERage, MAXHold, MINHold; for details see "Trace mode result types"

on page 6.300.

Note: The specified result type must be one of those configured with the

[SENSe:]ADEMod:PM:AFSPectrum[:TYPE] command. Otherwise a query error will

be generated.

Return values

ASCII Format (FORMat ASCII) or Binary Format (FORMat REAL,32); for details see "Formats

for returned values: ASCII format and binary format" on page 6.300. The ouput units are

described in section "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

Example

ADEM:SET 8MHz,32000,EXT,POS,–500,30

Sets demodulator

ADEM:PM AVER,MAXH,MINH

Selects the PM results to be measured

ADEM:AM:REL WRIT,OFF,OFF

Selects the AM results to be measured

ADEM:PM:AFSP WRIT,OFF,OFF

Selects the AF spectrum results of the demodulated PM signal to be measured

ADEM ON

Switches the demodulator on

INIT;*WAI

Starts the measurement and waits for termination

FORM ASC

Selects output format

ADEM:PM:RES? AVER

Reads PM average result data

ADEM:PM:RES? MAXH

Reads PM maxhold result data

ADEM:PM:RES? MINH

Reads PM minhold result data

ADEM:AM:RES? WRIT

Reads current AM result data

ADEM:PM:AFSP:RES? WRIT

Reads current AF spectrum result data of demodulated PM signal

Characteristics

RST value: –

SCPI: device–specific

Mode

ADEMOD

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.316 E-11

[SENSe:]ADEMod:PM:RPOint[:X]

This command determines the position where the phase of the PM–demodulated signal is set to

0rad. The maximum possible value depends on the measurement time selected in the

instrument; this value is output in response to the query ADEM:PM:RPO:X? MAX.

Parameter

0 s to measurement time

Example

ADEM:PM:RPO 500us

Sets the position where the phase to 0 rad setting to 500 µs.

Characteristics

RST value: 0 s

SCPI: conform

Mode

ADEMOD

[SENSe:]ADEMod:RLENgth?

This command returns the record length set up for the current analog demodulation

measurement.

Example

ADEM:RLEN?

Returns the current record length.

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:SET

This command configures the analog demodulator of the instrument.

Parameter

<sample rate> The frequency at which measurement values are taken from the

A/D–converter and stored in I/Q memory.

Allowed range: refer to chapter "Instrument Functions", section

"Analog Demodulation (Option K7)" – "Sample rate,

measurement time and trigger offset".

<record length> Number of samples to be stored in I/Q memory.

Allowed range:

1to 400001 with AF filter or AF trigger active

1to 480001 with both AF filter and AF trigger deactive

<trigger source> Selection of the trigger source to use for the demodulator.

Allowed values: IMMediate | EXTernal | IFPower | RFPower| AF

|AM | AMRelative | FM | PM (see note below)

<trigger slope> Used slope of the trigger signal.

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.317 E-11

Allowed values: POSitive | NEGative

The value indicated here will be ignored for <trigger source> =

IMMediate.

<offset samples> Number of samples to be used as an offset to the trigger signal.

Allowed range: –65024 to 130559 (= –64 * 1024 + 512 to 128 *

1024 – 513)

The value indicated here will be ignored for <trigger source> =

IMMediate.

<# of meas> Number of repetitions of the measurement to be executed. The

value indicated here is especially necessary for the

average/maxhold/minhold function.

Allowed range: 0 to 32767

Note: After selecting IFPower, the trigger threshold can be set with the

TRIGger<1|2>[:SEQuence]:LEVel:IFPower command.

Example

ADEM:SET 8MHz,32000,EXT,POS,–500,30

Performs a measurement at:

sample rate 8 MHz

record length 32000

trigger source EXTernal

trigger slope POSitive

offset samples –500 (500 samples before trigger occurred)

#of meas 30

Characteristics

*RST value:

sample rate 8 MHz

record length 501

trigger source IMMediate

trigger slope POSitive

offset samples 0

#of meas 0

SCPI: device–specific

Mode

ADEMOD

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.318 E-11

[SENSe:]ADEMod:SPECtrum[:TYPE]

This command selects the result types to be created in parallel by the RF spectrum

measurement with active analog demodulation.

Parameter

<result type 1|2|3|4>: WRITe, AVERage, MAXHold, MINHold, VIEW, OFF; for details see

"Trace mode result types" on page 6.300.

Example

ADEM:SPEC AVER,MAXH,MINH

Creates average, max hold and min hold values at a time

ADEM:SPEC WRIT,OFF,OFF

Only creates the current measurement values

ADEM:SPEC OFF,OFF,OFF

Switches analog demodulator off

Characteristics

*RST value: OFF,OFF,OFF

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:SPECtrum:BANDwidth|BWIDth[:RESolution]

This command sets the resolution bandwidth for spectrum representation that was determined

from the analog demodulation data.

The recording time required is calculated from the sampling rate indirectly set via

[SENSe:]ADEMod:SPECtrum:SPAN[:MAXimum] or

[SENSe:]ADEMod:BANDwidth|BWIDth:DEModulation.If the available recording time is

not sufficient for the given bandwidth, the recording time is set to is maximum and the resolution

bandwidth is enlarged to the resulting bandwidth.

Parameter

refer to data sheet

Example

ADEM ON

Switches on the analog demodulator

CALC:FEED 'XTIM:SPEC'

Switches on the RF spectrum result display

CALC:FEED 'XTIM:FM:AFSP'

Switches on the AF spectrum result display of FM signal

ADEM:SPEC:BAND 61.2kHz

Sets the resolution bandwidth to 61.2 kHz.

Characteristics

*RST value: 61.2 kHz

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.319 E-11

[SENSe:]ADEMod:SPECtrum:RESult?

This command reads out the RF spectrum result data for the specified result type. The data format of

the output data block is defined by the FORMat command.

Parameter

<result type>: WRITe, AVERage, MAXHold, MINHold; for details see "Trace mode result types"

on page 6.300.

Note: The result type indicated must be one of those configured by

[SENSe:]ADEMod:SPECtrum[:TYPE].Otherwise a query error will be generated.

Return values

ASCII Format (FORMat ASCII) or Binary Format (FORMat REAL,32); for details see "Formats

for returned values: ASCII format and binary format" on page 6.300. The ouput units are

described in "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

Example

ADEM:SET 8MHz,32000,EXT,POS,–500,30

Sets up demodulator parameters

ADEM:SPEC AVER,MAXH,MINH

Selects RF spectrum results to be measured

ADEM:SPEC WRIT,OFF,OFF

Selects AM results to be measured

ADEM ON

Switches on demodulator

INIT;*WAI

Starts measurement and waits for sync

FORM ASC

Selects output format

ADEM:SPEC:RES? AVER

Reads RF spectrum average results

ADEM:SPEC:RES? MAXH

Reads RF spectrum max hold results

ADEM:SPEC:RES? MINH

Reads RF spectrum min hold results

ADEM:SPEC:RES? WRIT

Reads spectrum current results

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.320 E-11

[SENSe:]ADEMod:SPECtrum:SPAN[:MAXimum]

This command sets the maximum frequency range for displaying the RF spectrum that was

determined from the analog demodulation data. The maximum span corresponds to the

measurement bandwidth of analog demodulation (for details refer to

[SENSe:]ADEMod:BANDwidth|BWIDth:DEModulation).For details refer on the relation of

bandwidth and sample rate refer to chapter "Instrument Functions", section "Analog

Demodulation (Option K7)" – "Sample rate, measurement time and trigger offset".

Parameter

<numeric_value>

Example

ADEM ON

Switches on the analog demodulator

CALC:FEED 'XTIM:SPEC'

Switches on RF spectrum result display.

ADEM:SPEC:SPAN:MAX 5 MHz

Sets the max. span to 5 MHz

ADEM:SPEC:SPAN:ZOOM 1 MHz

Sets the displayed span to 1 MHz

Characteristics

*RST value: 5 MHz

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:SPECtrum:SPAN:ZOOM

This command sets the frequency range for the RF spectrum result display determined from

analog demodulation data. The frequency range for result display is limited to the maximum

span ([SENSe:]ADEMod:SPECtrum:SPAN[:MAXimum])or to the measurement bandwidth of

analog demodulation ([SENSe:]ADEMod:BANDwidth|BWIDth:DEModulation).

Parameter

<numeric_value>

Example

ADEM ON

Switches on the analog demodulator

CALC:FEED 'XTIM:SPEC'

Switches on RF spectrum result display"

ADEM:SPEC:SPAN:MAX 5 MHz

Sets the maximum span to 5 MHz

ADEM:SPEC:SPAN:ZOOM 1 MHz

Sets displayed span to 1 MHz

Characteristics

*RST value: 5 MHz

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.321 E-11

[SENSe:]ADEMod:SRATe?

This command returns the sample rate set up for the current analog demodulation

measurement.

Example

ADEM:SRAT?

Returns the current sample rate.

Characteristics

*RST value: –

SCPI: device–specific

Mode

ADEMOD

[SENSe:]ADEMod:ZOOM[:STATe]

The command enables or disables the zoom function for the analog–demodulated

measurement data. Depending on the selected measurement time and the demodulation

bandwidth, the number of recorded test points may be greater than that shown on the display.

If the zoom function is enabled, 501 test points of the result memory are displayed from the

specified start time with [SENSe:]ADEMod:ZOOM:STARt.

If the zoom function is disabled, data reduction is used to adapt the test points to the number of

points available on the display.

Parameter

ON | OFF

Example

ADEM:ZOOM ON

Switches on the zoom function

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

ADEMOD

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.322 E-11

[SENSe:]ADEMod:ZOOM:STARt

The command selects the start time for the display of individual measured values of the analog

demodulation. The maximum possible value depends on the measurement time, which is set in

the instrument and can be queried with the [SENSe:]ADEMod:MTIMe command.

Ifthe zoom function is enabled, 501 test points of the result memory are displayed from the

specified start time with [SENSe:]ADEMod:ZOOM:STARt.

Parameter

0 s to measurement time – (500 * 1/sample rate)

Example

ADEM:ZOOM ON

Switches on the zoom function

ADEM:ZOOM:STAR 500us

Sets the starting point of the display to 500 µs.

Characteristics

*RST value: 0 s

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.323 E-11

SENSe:BANDwidth Subsystem (Analog Demodulation, K7)

This subsystem controls the setting of the instruments filter bandwidths. Both groups of

commands (BANDwidth and BWIDth) perform the same functions.

Commands of the SENSe:BANDwidth Subsystem

–[SENSe<1|2>:]BANDwidth|BWIDth:DEMod

[SENSe<1|2>:]BANDwidth|BWIDth:DEMod

This command sets the bandwidth for analog demodulation. Depending on the selected

demodulation bandwidth, the instrument selects the required sampling rate.

The available values of the demodulation bandwidths are determined by the sampling rates. For

details on the correlation between demodulation bandwidth and sampling rate refer to chapter

"Instrument Functions", sections "Analog Demodulation (Option K7)" – "Sample rate,

measurement time and trigger offset".

Parameter

<numeric_value>

Example:

BAND:DEM 1MHz

Sets test bandwidth to 1 MHz

Characteristics:

*RST value: 5 MHz

SCPI: device–specific

Mode

A–F, ADEMOD

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.324 E-11

SENSe:FILTer Subsystem (Analog Demodulation, K7)

The SENSe:FILTer subsystem selects the filters to reduce the bandwidth of the demodulated signal.

The selected filters are used for AM, FM and PM demodulation in common.

Commands of the SENSe:FILTer subsystem

–[SENSe<1|2>:]FILTer:DEMPhasis[:STATe]

–[SENSe<1|2>:]FILTer:DEMPhasis:TCONstant

–[SENSe<1|2>:]FILTer:HPASs[:STATE]

–[SENSe<1|2>:]FILTer:HPASs:FREQuency

–[SENSe<1|2>:]FILTer:LPASs[:STATE]

–[SENSe<1|2>:]FILTer:LPASs:FREQuency[:ABSolute]

–[SENSe<1|2>:]FILTer:LPASs:FREQuency:RELative

[SENSe<1|2>:]FILTer:DEMPhasis[:STATe]

This command activates/deactivates the selected deemphasis.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

FILT:DEMP ON

Activates the selected deemphasis.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

ADEMOD

[SENSe<1|2>:]FILTer:DEMPhasis:TCONstant

This command selects the deemphasis. For details on deemphasis refer to chapter "Instrument

Functions", section "Analog Demodulation (Option K7)", Deemphasis softkey.

The numeric suffixes <1|2> are irrelevant.

Parameter

25 us | 50 us | 75 us | 750 us

Example

FILT:DEMP:TCON 750us

Selects the deemphasis for the demodulation bandwidth range from 800 Hz to 4 MHz with a

time constant of 750 Us.

Characteristics

RST value: 50 us

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.325 E-11

[SENSe<1|2>:]FILTer:HPASs[:STATE]

This command activates/deactivates the selected high pass filter.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

FILT:HPAS ON

Activates the selected high pass filter.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

ADEMOD

[SENSe<1|2>:]FILTer:HPASs:FREQuency

This command selects the high pass filter type. For details on filters refer to chapter "Instrument

Functions", section "Analog Demodulation (Option K7)", High Pass AF Filter softkey.

The numeric suffixes <1|2> are irrelevant.

Parameter

50Hz | 300Hz

Example

FILT:HPAS:FREQ 300Hz

Selects the high pass filter for the demodulation bandwidth range from 800 Hz to 16 MHz.

Characteristics

RST value: 300Hz

SCPI: device–specific

Mode

ADEMOD

[SENSe<1|2>:]FILTer:LPASs[:STATE]

This command activates/deactivates the selected low pass filter.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

FILT:LPAS ON

Activates the selected low pass filter.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

ADEMOD

SENSe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.326 E-11

[SENSe<1|2>:]FILTer:LPASs:FREQuency[:ABSolute]

This command selects the absolute low pass filter type. For details on filters refer to chapter

"Instrument Functions", section "Analog Demodulation (Option K7)", Low Pass AF Filter

softkey.

The numeric suffixes <1|2> are irrelevant.

Parameter

3kHz | 15kHz | 150kHz

Example

FILT:LPAS:FREQ 150kHz

Selects the low pass filter for the demodulation bandwidth range from 400 kHz to 16 MHz.

Characteristics

RST value: 15kHz

SCPI: device–specific

Mode

ADEMOD

[SENSe<1|2>:]FILTer:LPASs:FREQuency:RELative

This command selects the relative low pass filter type. For details on filters refer to chapter

"Instrument Functions", section "Analog Demodulation (Option K7)", Low Pass AF Filter

softkey.

The numeric suffixes <1|2> are irrelevant.

Parameter

5PCT | 10PCT | 25PCT

Example

FILT:LPAS:FREQ 25PCT

Selects the low pass filter as 25% of the demodulation bandwidth.

Characteristics

RST value: 25PCT

SCPI: device–specific

Mode

ADEMOD

R&S FSL SENSe Subsystem (Analog Demodulation, K7)

1300.2519.12 6.327 E-11

SENSe:FREQuency Subsystem (Analog Demodulation, K7)

The SENSe:FREQuency subsystem defines the frequency axis of the active display. The frequency

axis can either be defined via the start/stop frequency or via the center frequency and span.

Commands of the SENSe:FREQuency Subsystem

–[SENSe<1|2>:]FREQuency:CENTer:STEP:LINK

[SENSe<1|2>:]FREQuency:CENTer:STEP:LINK

Parameter

SPAN coupling to frequency display range (for RF spectrum result display)

RBW coupling to demodulation bandwidth (for all result displays except RF spectrum)

OFF manual input, no coupling

For further details refer to "[SENSe<1|2>:]FREQuency:CENTer:STEP:LINK" on page 6.201.

SENSe:SWEep Subsystem (Analog Demodulation, K7)

The SENSe:SWEep subsystem controls the sweep parameters.

Commands of the SENSe:SWEep Subsystem

–[SENSe<1|2>:]SWEep:TIME

[SENSe<1|2>:]SWEep:TIME

Parameter

Refer to chapter "Instrument Functions", section "Analog Demodulation (Option K7)" – "Sample

rate, measurement time and trigger offset".

For further details refer to "[SENSe<1|2>:]SWEep:TIME" on page 6.234.

TRACe Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.328 E-11

TRACe Subsystem (Analog Demodulation, K7)

The TRACe subsystem controls access to the instruments internal trace memory.

Commands of the TRACe Subsystem

–TRACe<1|2>[:DATA]

TRACe<1|2>[:DATA]

If the analog demodulator (option Analog Demodulation, R&S FSL–K7) is active, only the

displayed trace data is read out and recalled. A portion of the measurement data that can be

called by means of a marker, however, is calculated from the raw measurement data. These

results are no longer available after recalling a trace; the associated queries generate a query

error.

For further information refer to "TRACe<1|2>[:DATA]" on page 6.263.

R&S FSL TRIGger Subsystem (Analog Demodulation, K7)

1300.2519.12 6.329 E-11

TRIGger Subsystem (Analog Demodulation, K7)

The TRIGger subsystem is used to synchronize instrument actions with events. It is thus possible to control

and synchronize the start of a sweep.

Commands of the TRIGger Subsystem

–TRIGger<1|2>[:SEQuence]:LEVel:AM[:ABSolute]

–TRIGger<1|2>[:SEQuence]:LEVel:AM:RELative

–TRIGger<1|2>[:SEQuence]:LEVel:FM

–TRIGger<1|2>[:SEQuence]:LEVel:PM

–TRIGger<1|2>[:SEQuence]:SOURce

TRIGger<1|2>[:SEQuence]:LEVel:AM[:ABSolute]

The command sets the level when RF power signals are used as trigger source.

Note: For triggering with AF, AM, AMRelative, FM, and PM trigger sources to be successful,

the measurement time must cover at least 5 periods of the audio signal.

Parameter

–100 to +30 dBm

Example

TRIG:LEV:AM –30 dBm

Sets the RF power signal trigger threshold to –30 dBm

Characteristics

*RST value: –20 dBm

SCPI: device–specific

Mode

ADEMOD

TRIGger<1|2>[:SEQuence]:LEVel:AM:RELative

The command sets the level when AM–modulated signals are used as trigger source.

Note: For triggering with AF, AM, AMRelative, FM, and PM trigger sources to be successful,

the measurement time must cover at least 5 periods of the audio signal.

Parameter

–100 to +100 %

Example

TRIG:LEV:AM:REL –20 %

Sets the AM trigger threshold to –20 %

Characteristics

*RST value: 0 %

SCPI: device–specific

Mode

ADEMOD

TRIGger Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.330 E-11

TRIGger<1|2>[:SEQuence]:LEVel:FM

The command sets the level when FM–modulated signals are used as trigger source.

Note: For triggering with AF, AM, AMRelative, FM, and PM trigger sources to be successful,

the measurement time must cover at least 5 periods of the audio signal.

Parameter

–10 to +10 MHz

Example

TRIG:LEV:FM 10 kHz

Sets the FM trigger threshold to 10 kHz

Characteristics

*RST value: 0 Hz

SCPI: device–specific

Mode

ADEMOD

TRIGger<1|2>[:SEQuence]:LEVel:PM

The command sets the level when PM–modulated signals are used as trigger source.

Note: For triggering with AF, AM, AMRelative, FM, and PM trigger sources to be successful,

the measurement time must cover at least 5 periods of the audio signal.

Parameter

–1000 to +1000 RAD | DEG

Example

TRIG:LEV:PM 1.2 RAD

Sets the PM trigger threshold to 1.2 rad

Characteristics

*RST value: 0 RAD

SCPI: device–specific

Mode

ADEMOD

TRIGger<1|2>[:SEQuence]:SOURce

Parameter

IMMediate (Free Run) | EXTern | IFPower | AF | FM | AM | AMRelative | PM

The parameter AM corresponds to the RF power signal, the parameter AMRelative corresponds

to the AM signal.

For details on trigger modes refer to chapter "Instrument Functions", section "Analog

Demodulation (Option K7)".

Note: For triggering with AF, AM, AMRelative, FM, and PM trigger sources to be successful,

the measurement time must cover at least 5 periods of the audio signal.

For further details refer to "TRIGger<1|2>[:SEQuence]:SOURce" on page 6.280.

R&S FSL UNIT Subsystem (Analog Demodulation, K7)

1300.2519.12 6.331 E-11

UNIT Subsystem (Analog Demodulation, K7)

The UNIT subsystem sets the basic unit of the setting parameters.

Commands of the UNIT Subsystem

–UNIT:ANGLe

UNIT:ANGLe

This command selects the unit for angles.

Parameter

DEG | RAD

Example

UNIT:ANGL DEG

Characteristics

RST value: RAD

SCPI: conform

Mode

ADEMOD

UNIT Subsystem (Analog Demodulation, K7) R&S FSL

1300.2519.12 6.332 E-11

Remote Commands of the Bluetooth Measurements

Option (K8)

In this section all remote control commands for the Bluetooth Measurements option are described in

detail. The abbreviation BT stands for the Bluetooth operating mode. For details on conventions used in

this chapter refer to section "Notation" on page 6.2 at the beginning of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in "Remote Commands of the Base Unit" on page 6.5.

This option is available from firmware version 1.30.

Subsystems of the Bluetooth Measurements option (K9)

–"CALCulate:BTOoth Subsystem (BLUETOOTH, K8)" on page 6.333

–"CALCulate:DELTamarker Subsystem (BLUETOOTH, K8)" on page 6.353

–"CALCulate:MARKer Subsystem (BLUETOOTH, K8)" on page 6.354

–"CONFigure:BTOoth Subsystem (BLUETOOTH, K8)" on page 6.355

–"DISPlay Subsystem (BLUETOOTH, K8)" on page 6.369

–"INSTrument Subsystem (BLUETOOTH, K8)" on page 6.370

–"SENSe Subsystem (BLUETOOTH, K8)" on page 6.371

R&S FSL CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.333 E-11

CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

The following commands are used to configure the BLUETOOTH analyzer operating mode. This

operating mode requires option R&S FSL–K8.

Commands of the CALCulate:BTOoth Subsystem

–CALCulate<1|2>:BTOoth:ACLR[:LIST]?

–CALCulate<1|2>:BTOoth:ACLR:EXCeptions?

–CALCulate<1|2>:BTOoth:CFDRift[:MAXimum]?

–CALCulate<1|2>:BTOoth:CFDRift:RATE?

–CALCulate<1|2>:BTOoth:CFSTability:COUNt?

–CALCulate<1|2>:BTOoth:CFSTability:DEVM:[RMS]?

–CALCulate<1|2>:BTOoth:CFSTability:DEVM:D99Pct?

–CALCulate<1|2>:BTOoth:CFSTability:DEVM:DPCT?

–CALCulate<1|2>:BTOoth:CFSTability:DEVM:PEAK?

–CALCulate<1|2>:BTOoth:CFSTability:FERRor:[TOTal]?

–CALCulate<1|2>:BTOoth:CFSTability:FERRor:BLOCk?

–CALCulate<1|2>:BTOoth:CFSTability:FERRor:INITial?

–CALCulate<1|2>:BTOoth:DPENcoding:[TOTal]?

–CALCulate<1|2>:BTOoth:DPENcoding:BER?

–CALCulate<1|2>:BTOoth:DPENcoding:NERRor?

–CALCulate<1|2>:BTOoth:IBSemissions:[List]?

–CALCulate<1|2>:BTOoth:IBSemissions:EXCeptions?

–CALCulate<1|2>:BTOoth:IBSemissions:HADJacent?

–CALCulate<1|2>:BTOoth:IBSemissions:TXReference?

–CALCulate<1|2>:BTOoth:ICFTolerance?

–CALCulate<1|2>:BTOoth:MCHar:DF<1|2>:AVERage?

–CALCulate<1|2>:BTOoth:MCHar:DF<1|2>:MAXimum?

–CALCulate<1|2>:BTOoth:MCHar:DF2:PERCent?

–CALCulate<1|2>:BTOoth:MCHar:RATio?

–CALCulate<1|2>:BTOoth:OPOWer[:PEAK]?

–CALCulate<1|2>:BTOoth:OPOWer:AVERage?

–CALCulate<1|2>:BTOoth:PLENgth?

–CALCulate<1|2>:BTOoth:PTYPe?

–CALCulate<1|2>:BTOoth:RTPower:[DPSK]?

–CALCulate<1|2>:BTOoth:RTPower:GFSK?

–CALCulate<1|2>:BTOoth:RTPower:RATio?

–CALCulate<1|2>:BTOoth:STATus?

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.334 E-11

Further information

–Example: Adapting the settings to the characteristics of the DUT

Example: Adapting the settings to the characteristics of the DUT

INST:SEL BTO

Activates the Bluetooth Measurements option

INIT:CONT OFF

Selects single sweep operation

CONF:BTO:CHAN 10

Selects channel 10

CONF:BTO:PCL 1

Selects power class 1

CONF:BTO:PRAT 4

Selects 4 points per symbol

CONF:BTO:PTYP DH1

Selects 1 slot packet

DDEM:SEAR:SYNC ON

Activates the FIND SYNC function

DDEM:SEAR:SYNC:OFFS 0

Sets the sync offset = 0

DDEM:SEAR:SYNC:LAP #H0

Sets the lower address part = 0

DDEM:SEAR:TIME:AUTO ON

Selects automatic search length

R&S FSL CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.335 E-11

CALCulate<1|2>:BTOoth:ACLR[:LIST]?

This command determines the power of the selected adjacent channels. The number of

adjacent channel pairs is defined with the CONFigure:BTOoth:ACLR:ACPairs command.

The results are returned as a list of power values. The structure of the list is as follows:

The number of adjacent channels is limited at the Bluetooth band limits.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Adjacent Channel Power measurement (see

CONFigure:BTOoth:MEASurement command). With all other measurements this

command will lead to a query error.

Example

INST:SEL BTO

Activates the Bluetooth Measurements option.

INIT:CONT OFF

Selects single sweep operation.

CONF:BTO:MEAS ACLR

Activates the Adjacent Channel Power measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:ACLR?

Queries the power list.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:ACLR:EXCeptions?

This command determines the number of exceptions which occurred during the adjacent

channel power measurement according to the Bluetooth specification.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Adjacent Channel Power measurement (see

CONFigure:BTOoth:MEASurement command). With all other measurements this

command will lead to a query error.

Example

INST:SEL BTO

Activates the Bluetooth Measurements option.

INIT:CONT OFF

Selects single sweep operation.

CONF:BTO:MEAS ACLR

Activates the Adjacent Channel Power measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:ACLR?

Queries the power list.

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.336 E-11

CALC:BTO:ACLR:EXC?

Queries the number of exceptions.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:CFDRift[:MAXimum]?

This command determines the maximum Carrier Frequency Drift.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Carrier Frequency Drift measurement (see

CONFigure:BTOoth:MEASurement command). With all other measurements this

command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS CFDR

Activates the Carrier Frequency Drift measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:CFDR?

Queries the result.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:CFDRift:RATE?

This command determines the maximum Carrier Frequency Drift per 50 µs.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Carrier Frequency Drift measurement (see

CONFigure:BTOoth:MEASurement command). With all other measurements this

command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS CFDR

Activates the Carrier Frequency Drift measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:CFDR:RATE?

Queries the result.

R&S FSL CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.337 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:CFSTability:COUNt?

This command reads the number of measured blocks during or after a measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Carrier Frequency Stability and Modulation

Accuracy measurement (see CONFigure:BTOoth:MEASurement command). With all

other measurements this command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS CFST

Activates the Carrier Frequency Stability and Modulation Accuracy measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:CFST:COUNt?

Reads the number of measured blocks.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:CFSTability:DEVM:[RMS]?

This command reads the root mean square (RMS) of the differential error vector magnitude

(DEVM) in the Carrier Frequency Stability and Modulation Accuracy measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Carrier Frequency Stability and Modulation

Accuracy measurement (see CONFigure:BTOoth:MEASurement command). With all

other measurements this command will lead to a query error.

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS CFST

Activates the Carrier Frequency Stability and Modulation Accuracy measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:CFST:DEVM? AVER

Reads the root mean square of the average differential error vector magnitude.

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.338 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:CFSTability:DEVM:D99Pct?

This command reads 99% of the differential error vector magnitude (DEVM) in the Carrier

Frequency Stability and Modulation Accuracy measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Carrier Frequency Stability and Modulation

Accuracy measurement (see CONFigure:BTOoth:MEASurement command). With all

other measurements this command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS CFST

Activates the Carrier Frequency Stability and Modulation Accuracy measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:CFST:DEVM:D99Pct?

Reads 99% of the differential error vector magnitude.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:CFSTability:DEVM:DPCT?

This command is synonym to CALCulate<1|2>:BTOoth:CFSTability:DEVM:D99Pct?.

This command is available from firmware version 1.60.

Characteristics

RST value: –

SCPI: conform

Mode

R&S FSL CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.339 E-11

CALCulate<1|2>:BTOoth:CFSTability:DEVM:PEAK?

This command reads the peak of the differential error vector magnitude (DEVM) in the Carrier

Frequency Stability and Modulation Accuracy measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Carrier Frequency Stability and Modulation

Accuracy measurement (see CONFigure:BTOoth:MEASurement command). With all

other measurements this command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS CFST

Activates the Carrier Frequency Stability and Modulation Accuracy measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:CFST:DEVM:PEAK?

Reads the peak of the differential error vector magnitude.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:CFSTability:FERRor:[TOTal]?

This command reads the carrier frequency deviation of all packets in the Carrier Frequency

Stability and Modulation Accuracy measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Carrier Frequency Stability and Modulation

Accuracy measurement (see CONFigure:BTOoth:MEASurement command). With all

other measurements this command will lead to a query error.

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS CFST

Activates the Carrier Frequency Stability and Modulation Accuracy measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:CFST:FERR? MIN

Reads the minimum carrier frequency deviation of all packets.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.340 E-11

CALCulate<1|2>:BTOoth:CFSTability:FERRor:BLOCk?

This command reads the maximum frequency deviation of all blocks in the Carrier Frequency

Stability and Modulation Accuracy measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Carrier Frequency Stability and Modulation

Accuracy measurement (see CONFigure:BTOoth:MEASurement command). With all

other measurements this command will lead to a query error.

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS CFST

Activates the Carrier Frequency Stability and Modulation Accuracy measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:CFST:FERR:BLOC? AVER

Reads the maximum average frequency deviation of all blocks.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:CFSTability:FERRor:INITial?

This command reads the combined frequency deviation of all packets and all blocks in the

Carrier Frequency Stability and Modulation Accuracy measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Carrier Frequency Stability and Modulation

Accuracy measurement (see CONFigure:BTOoth:MEASurement command). With all

other measurements this command will lead to a query error.

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS CFST

Activates the Carrier Frequency Stability and Modulation Accuracy measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:CFST:FERR:INIT? MAX

Reads the combined maximum frequency deviation of all packets and all blocks.

R&S FSL CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.341 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:DPENcoding:[TOTal]?

This command reads the number of tested packets in the Differential Phase Encoding

measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Differential Phase Encoding measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS DPEN

Activates the Differential Phase Encoding measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:DPEN?

Reads the number of tested packets.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:DPENcoding:BER?

This command reads the bit error rate (BER) in the Differential Phase Encoding measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Differential Phase Encoding measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS DPEN

Activates the Differential Phase Encoding measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:DPEN:BER?

Reads the bit error rate.

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.342 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:DPENcoding:NERRor?

This command reads the number of passed packets in the Differential Phase Encoding

measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Differential Phase Encoding measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS DPEN

Activates the Differential Phase Encoding measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:DPEN:NERR?

Reads the number of passed packets.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:IBSemissions:[List]?

This command reads the power of all adjacent channels in the In–band Spurious Emissions

measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active In–band Spurious Emissions measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS IBS

Activates the In–band Spurious Emissions measurement.

CONF:BTO:CHAN 7

Adjust the TX channel number.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:IBS?

Reads the results of the In–band Spurious Emissions measurement.

R&S FSL CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.343 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:IBSemissions:EXCeptions?

This command reads the number of results that exceeded the specified limits in the In–band

Spurious Emissions measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active In–band Spurious Emissions measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS IBS

Activates the In–band Spurious Emissions measurement.

CONF:BTO:CHAN 7

Adjust the TX channel number.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:IBS:EXC?

Reads the number of results that exceeded the specified limits.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:IBSemissions:HADJacent?

This command reads the maximum power of the upper or lower frequency band (500 kHz) of

the TX channel in the In–band Spurious Emissions measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active In–band Spurious Emissions measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Parameter

UPPer | LOWer

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.344 E-11

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS IBS

Activates the In–band Spurious Emissions measurement.

CONF:BTO:CHAN 7

Adjust the TX channel number.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:IBS:HADJ? LOW

Reads the maximum power of the lower frequency band.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:IBSemissions:TXReference?

This command reads the TX channel reference power.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active In–band Spurious Emissions measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS IBS

Activates the In–band Spurious Emissions measurement.

CONF:BTO:CHAN 7

Adjust the TX channel number.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:IBS:TXR?

Reads the TX channel reference power.

Characteristics

RST value: –

SCPI: device–specific

Mode

R&S FSL CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.345 E-11

CALCulate<1|2>:BTOoth:ICFTolerance?

This command determines the Initial Carrier Frequency Tolerance.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Modulation Characteristics measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS ICFT

Activates the Initial Carrier Frequency Tolerance measurement.

CONF:BTO:SWE:COUN 20

Initiates the sweep counter with 20.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:ICFT? AVER

Queries the average value.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:MCHar:DF<1|2>:AVERage?

This command determines the average frequency deviation for varying bit patterns of the

payload. The suffixes of DF<1|2> assign the frequency deviation and the bit pattern as follows:

Frequency

deviation

f1avg f2avg

Bit pattern "11110000" "10101010"

The numeric suffixes <1|2> of CALCulate are irrelevant for this command.

Note: This command is only available with active Modulation Characteristics measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Parameter

MINimum | MAXimum

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS MCH

Activates the Modulation Characteristics measurement.

CONF:BTO:SWE:COUN 20

Initiates the sweep counter with 20.

... EUT emits bit pattern 1111000

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.346 E-11

INIT:IMM;*WAI

Starts the measurement with synchronization and erase previous measurement results.

CALC:BTO:MCH:DF1:AVER? MIN

Queries minimum value "11110000".

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:MCHar:DF<1|2>:MAXimum?

This command determines the maximum frequency deviation for different bit patterns of the

payload. The suffixes of DF<1|2> assign the frequency deviation and the bit pattern as follows:

Frequency

deviation

f1max f2max

Bit pattern "11110000" "10101010"

The numeric suffixes <1|2> of CALCulate are irrelevant for this command.

Note: This command is only available with active Modulation Characteristics measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS MCH

Activates the Modulation Characteristics measurement.

CONF:BTO:SWE:COUN 20

Initiates the sweep counter with 20.

... EUT emits bit pattern 1111000

INIT:IMM;*WAI

Starts the measurement with synchronization and erase previous measurement results.

CALC:BTO:MCH:DF1:MAX? MIN

Queries minimum value "11110000".

Characteristics

RST value: –

SCPI: device–specific

Mode

R&S FSL CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.347 E-11

CALCulate<1|2>:BTOoth:MCHar:DF2:PERCent?

This command determines the percentage of measurements of the frequency deviation, for

which the value of f2max is within the allowed range. Therefore only the numeric suffix 2 is

allowed for DF.

The numeric suffixes <1|2> of CALCulate are irrelevant for this command.

Note: This command is only available with active Modulation Characteristics measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS MCH

Activates the Modulation Characteristics measurement.

CONF:BTO:SWE:COUN 20

Initiates the sweep counter with 20.

... EUT emits bit pattern 10101010

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:MCH:DF2:PERC?

Queries the percentage of "in range" measurements.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:MCHar:RATio?

This command determines the ratio of the average frequency deviations for varying bit patterns

of the payload.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Modulation Characteristics measurement

(see CONFigure:BTOoth:MEASurement command). With all other measurements

this command will lead to a query error.

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS MCH

Activates the Modulation Characteristics measurement.

CONF:BTO:SWE:COUN 20

Initiates the sweep counter with 20.

... EUT emits bit pattern 1111000

INIT:IMM;*WAI

Starts the measurement with synchronization and erase previous measurement results.

... EUT emits bit pattern 10101010

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.348 E-11

INIT:CONM;*WAI

Starts additional measurement with synchronization.

CALC:BTO:MCH:RAT? MIN

Queries the minimum value.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:OPOWer[:PEAK]?

This command reads the peak value of the Output Power measurement according to the

BLUETOOTH standard.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Output Power measurement (see

CONFigure:BTOoth:MEASurement command). With all other measurements it will

lead to a query error.

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS OPOW

Activates the Output Power measurement.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:OPOW?

Queries the output power result.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:OPOWer:AVERage?

This command reads the average value of the Output Power measurement according to the

Bluetooth standard.

With a sweep count value of 1 (CONFigure:BTOoth:SWEep:COUNt)and trace mode

clear/write (DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE)the selected number of

measurements is performed when a single sweep is started

(INITiate<1|2>[:IMMediate]). During these measurements the minimum and maximum

values are determined. If only a single measurement is performed, the minimum and maximum

value will be identical.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Output Power measurement (see

CONFigure:BTOoth:MEASurement command). With all other measurements it will

lead to a query error.

R&S FSL CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.349 E-11

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS OPOW

Activates the Output Power measurement.

CONF:BTO:SWE:COUN 20

Activates measurement over 20 sweeps.

INIT;*WAI

Activates measurement over 20 sweeps.

CALC:BTO:OPOW:AVER? MAX

Queries the maximum average value of the Output Power measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:PLENgth?

This command reads the length of the packet analyzed by the preceding measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available, if a measurement was started via

INITiate<1|2>[:IMMediate] before and if this measurement is completed. With a

missing or incomplete measurement the command will cause a query error.

This command is only available with the measurements Output Power, Modulation

Characteristics, Initial Carrier Frequency Tolerance, and Carrier Frequency Drift (see

CONFigure:BTOoth:MEASurement command).

Example

INST:SEL BTO

Activates the Bluetooth Measurements option

INIT:CONT OFF

Selects single sweep operation

CONF:BTO:MEAS OPOW

Activates the Output Power measurement

INIT;*WAI

Starts the measurement with synchronization

CALC:BTO:PLEN?

Queries the packet length

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.350 E-11

CALCulate<1|2>:BTOoth:PTYPe?

This command determines the type of the packet analyzed by a preceding measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available, if a measurement was started via

INITiate<1|2>[:IMMediate] before and if this measurement is completed. With a

missing or incomplete measurement the command will cause a query error.

This command is only available with the measurements Output Power, Modulation

Characteristics, Initial Carrier Frequency Tolerance, and Carrier Frequency Drift (see

CONFigure:BTOoth:MEASurement command).

Response

The following packet types are recognized and returns as character data: AUX1, DH1, DH3,

DH5, DM1, DM3, DM5, FHS, HV1, HV2, HV3, DV, NULL, POLL, UNDEF

Example

INST:SEL BTO

Activates the Bluetooth Measurements option

INIT:CONT OFF

Selects single sweep operation

CONF:BTO:MEAS OPOW

Activates the Output Power measurement

INIT;*WAI

Starts the measurement with synchronization

CALC:BTO:PTYP?

Queries the packet type

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:RTPower:[DPSK]?

This command reads the average transmission power for the DPSK sections of the packet in

the Relative Transmission Power measurement. With a sweep count



1, the command returns

the current value, irrespective of the parameter.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Relative Transmit Power measurement (see

CONFigure:BTOoth:MEASurement command). With all other measurements this

command will lead to a query error.

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS RTP

Activates the Relative Transmit Power measurement.

CONF:BTO:SWE:COUN 10

Initiates the sweep counter with 10.

R&S FSL CALCulate:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.351 E-11

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:RTP? MIN

Reads the lowest recorded average power of the DPSK section of all packets.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:RTPower:GFSK?

This command reads the transmission power for the GFSK sections of the packet in the

Relative Transmission Power measurement. With a sweep count



1, the command returns the

current value, irrespective of the parameter.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Relative Transmit Power measurement (see

CONFigure:BTOoth:MEASurement command). With all other measurements this

command will lead to a query error.

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS RTP

Activates the Relative Transmit Power measurement.

CONF:BTO:SWE:COUN 10

Initiates the sweep counter with 10.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:RTP:GFSK? MIN

Reads the highest recorded average power of the GFSK section of all packets.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:RTPower:RATio?

This command reads the ratio of the transmission power for the GFSK and DPSK modulation in

the Relative Transmission Power measurement (PDPSK/PGFSK). With a sweep count



1, the

command returns the current value, irrespective of the parameter.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Relative Transmit Power measurement (see

CONFigure:BTOoth:MEASurement command). With all other measurements this

command will lead to a query error.

CALCulate:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.352 E-11

Parameter

MINimum | MAXimum | AVERage

Example

For the first steps refer to "Example: Adapting the settings to the characteristics of the DUT" on

page 6.334.

CONF:BTO:MEAS RTP

Activates the Relative Transmit Power measurement.

CONF:BTO:SWE:COUN 10

Initiates the sweep counter with 10.

INIT;*WAI

Starts the measurement with synchronization.

CALC:BTO:RTP:RAT? MIN

Queries the minimum value.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate<1|2>:BTOoth:STATus?

This command queries the status of a preceding measurement.

Results: 0: PASS, 1: FAIL

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available, if a measurement was started via

INITiate<1|2>[:IMMediate] before and if this measurement is completed. With a

missing or incomplete measurement the command will cause a query error.

Example

INST:SEL BTO

Activates the Bluetooth Measurements option

INIT:CONT OFF

Selects single sweep operation

CONF:BTO:MEAS OPOW

Activates Output Power measurement

INIT;*WAI

Starts the measurement with synchronization

CALC:BTO:STAT?

Queries the status

Characteristics

RST value: –

SCPI: device–specific

Mode

R&S FSL CALCulate:DELTamarker Subsystem (BLUETOOTH, K8)

1300.2519.12 6.353 E-11

CALCulate:DELTamarker Subsystem (BLUETOOTH, K8)

The CALCulate:DELTamarker subsystem controls the delta marker functions of the instrument.

Commands of the CALCulate:DELTamarker Subsystem

–CALCulate<1|2>:DELTamarker<1...4>:Y?

CALCulate<1|2>:DELTamarker<1...4>:Y?

Depending on the unit defined with CALCulate<1|2>:UNIT:POWer or on the activated

measuring functions, the query result is output in the units below:

Result display Output unit

OUTPUT POWER result display dB

TX SPECTRUM ACP result display dB

MODULATION CHARACTERISTICS result display Hz

INITIAL CARR FREQ TOL result display Hz

CARRIER FREQ DRIFT result display Hz

RELATIVE TX POWER dB

IN–BAND SPURIOUS EMISSIONS dB

CARRIER FREQUENCY STABILITY –

DIFF PHASE ENCODING –

For further details refer to "CALCulate<1|2>:DELTamarker<1...4>:Y?" on page 6.22.

CALCulate:MARKer Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.354 E-11

CALCulate:MARKer Subsystem (BLUETOOTH, K8)

The CALCulate:MARKer subsystem checks the marker functions of the instrument.

Commands of the CALCulate:MARKer Subsystem

–CALCulate<1|2>:MARKer<1...4>:PEXCursion

–CALCulate<1|2>:MARKer<1...4>:Y?

CALCulate<1|2>:MARKer<1...4>:PEXCursion

The unit depends on the selected operating mode.

Example

CALC:MARK:PEXC 100 HZ

Defines peak excursion 100 Hz

Characteristics

RST value: 6dB

For further details refer to "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

CALCulate<1|2>:MARKer<1...4>:Y?

If the analog demodulator (option Analog Demodulation, R&S FSL–K7) is activated, the query

result is output in the following units:

Result display Output unit

AM %

FM Hz

PM rad/deg (defined with UNIT:ANGLe)

RF output unit defined with

CALCulate<1|2>:UNIT:POWer

For further details refer to "CALCulate<1|2>:MARKer<1...4>:Y?" on page 6.66.

R&S FSL CONFigure:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.355 E-11

CONFigure:BTOoth Subsystem (BLUETOOTH, K8)

The following commands are used for configuration of the BLUETOOTH analyzer operating mode.

Commands of the CONFigure:BTOoth Subsystem

–CONFigure:BTOoth:ACLR:ACPairs

–CONFigure:BTOoth:BANDwidth|BWIDth[:RESolution]

–CONFigure:BTOoth:BANDwidth|BWIDth[:RESolution]:AUTO

–CONFigure:BTOoth:BANDwidth|BWIDth:VIDeo

–CONFigure:BTOoth:BANDwidth|BWIDth:VIDeo:AUTO

–CONFigure:BTOoth:CFSTability:BCOunt

–CONFigure:BTOoth:CHANnel

–CONFigure:BTOoth:DETector<1...6>[:FUNCtion]

–CONFigure:BTOoth:IBSemissions:ACPairs

–CONFigure:BTOoth:IBSemissions:GATE:AUTO

–CONFigure:BTOoth:MEASurement

–CONFigure:BTOoth:PBSCo

–CONFigure:BTOoth:PCLass

–CONFigure:BTOoth:POWer:AVERage:STARt

–CONFigure:BTOoth:POWer:AVERage:STOP

–CONFigure:BTOoth:PRATe

–CONFigure:BTOoth:PTYPe

–CONFigure:BTOoth:RTPower:DAVerage:STARt

–CONFigure:BTOoth:RTPower:DAVerage:STOP

–CONFigure:BTOoth:RTPower:GAVerage:STARt

–CONFigure:BTOoth:RTPower:GAVerage:STOP

–CONFigure:BTOoth:SWEep:COUNt

–CONFigure:BTOoth:SWEep:TIME

–CONFigure:BTOoth:SWEep:TIME:AUTO

–CONFigure:BTOoth:TRACe<1...6>:MODE

–CONFigure:BTOoth:TRACe<1...6>:SELect

CONFigure:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.356 E-11

CONFigure:BTOoth:ACLR:ACPairs

This command selects the number of adjacent channel pairs during the Adjacent Channel

Power measurement. The number of adjacent channels will be limited as soon as the border of

the Bluetooth frequency band is reached.

Note: This command is only available with active Adjacent Channel Power measurement (see

CONFigure:BTOoth:MEASurement command).

Parameter

1to 78

Example

CONF:BTO:ACLR:ACP 10

Selects 10 adjacent channel pairs.

Characteristics

*RST value: 78

SCPI: device–specific

Mode

CONFigure:BTOoth:BANDwidth|BWIDth[:RESolution]

This command sets the resolution bandwidth of the analyzer for the currently selected Bluetooth

measurement (see [SENSe<1|2>:]BANDwidth|BWIDth[:RESolution] command).

For the measurements of modulation characteristics, initial carrier frequency tolerance, and

carrier frequency drift (CONFigure:BTOoth:MEASurement), the resolution bandwidth

corresponds to the IF bandwidth of the signal. If the resolution bandwidth is changed, its

coupling to the settings according to the RF Test Specification is cancelled.

Note: The settings for the measurements are valid for all three measurements.

For all other Bluetooth measurements the setting is only valid for the currently active

measurement (see CONFigure:BTOoth:MEASurement command).

This command is not available with active Adjacent Channel Power measurement.

Parameter

300kHz to 10MHz

Example

INST:SEL BTO

Activates the Bluetooth Measurements option.

CONF:BTO:MEAS OPOW

Activates the Output Power measurement.

CONF:BTO:BAND 1KHZ

Sets the resolution bandwidth to 1kHz.

Characteristics

*RST value: – (AUTO is set to ON)

SCPI: device–specific

Mode

R&S FSL CONFigure:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.357 E-11

CONFigure:BTOoth:BANDwidth|BWIDth[:RESolution]:AUTO

This command couples the resolution bandwidth to the settings according to the RF Test

Specification.

Note: The settings for the measurements of Modulation Characteristics, Initial Carrier

Frequency Tolerance, and Carrier Frequency Drift are common to all three

measurements.

For all other Bluetooth measurements the setting is only valid for the currently active

measurement (see CONFigure:BTOoth:MEASurement command).

Parameter

ON | OFF

Example

INST:SEL BTO

Activates the Bluetooth Measurements option.

CONF:BTO:MEAS MCH

Activates the Modulation Characteristics measurement.

CONF:BTO:BAND:AUTO ON

Activates the RBW coupling.

Characteristics

*RST value: ON

SCPI: device–specific

Mode

CONFigure:BTOoth:BANDwidth|BWIDth:VIDeo

This command sets the video bandwidth for the Adjacent Channel Power measurement (see

CONFigure:BTOoth:MEASurement command).

The available filters have a bandwidth range of 1 Hz to 10 MHz. On a change in video

bandwidth its link according to the RF Test Specification is switched off.

Note: This setting is only available for Output Power measurements.

Parameter

1Hz to 10 MHz

Example

INST:SEL BTO

Activates the Bluetooth Measurements option.

CONF:BTO:MEAS ACLR

Activates the Adjacent Channel Power measurement.

CONF:BTO:BAND:VID 100HZ

Sets the video bandwidth to 100 Hz.

Characteristics

*RST value: – (AUTO is set to ON)

SCPI: device–specific

Mode

CONFigure:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.358 E-11

CONFigure:BTOoth:BANDwidth|BWIDth:VIDeo:AUTO

This command links the video bandwidth to the settings according to the RF Test Specification.

It is only available for the Adjacent Channel Power measurement (see

CONFigure:BTOoth:MEASurement command).

Note: This setting is only valid for the currently active measurement (see

CONFigure:BTOoth:MEASurement command) and it is independent of the other

Bluetooth measurements.

Parameter

ON | OFF

Example

INST:SEL BTO

Activates the Bluetooth Measurements option.

CONF:BTO:MEAS ACLR

Activates the Adjacent Channel Power measurement.

CONF:BTO:BAND:VID:AUTO ON

Switches the VBW coupling on.

Characteristics

*RST value: ON

SCPI: device–specific

Mode

CONFigure:BTOoth:CFSTability:BCOunt

This command sets the number of blocks to be measured.

Note: This command is only available with active Carrier Frequency Stability and Modulation

Accuracy measurement (see CONFigure:BTOoth:MEASurement command).

Parameter

0to 1,000,000

Example

CONF:BTO:CFST:BCO 1000

Selects 1000 blocks to be measured.

Characteristics

RST value: 200

SCPI: device–specific

Mode

R&S FSL CONFigure:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.359 E-11

CONFigure:BTOoth:CHANnel

This command selects the frequency channel for the measurements according to the Bluetooth

standard.

Parameter

0to 78

Example

CONF:BTO:CHAN 20

Selects channel 20

Characteristics

*RST value: 0

SCPI: device–specific

Mode

CONFigure:BTOoth:DETector<1...6>[:FUNCtion]

This command selects the detector for the currently selected Bluetooth measurement. The

numeric suffix assigns the detector to a trace (1 to 6).

Note: The RMS detector is not available for the measurements Modulation Characteristics,

Initial Carrier Frequency Tolerance, and Carrier Frequency Drift (see

CONFigure:BTOoth:MEASurement command).

The setting is valid for the currently selected measurement (see

CONFigure:BTOoth:MEASurement command) and independent of other Bluetooth

measurements.

Parameter

Example

CONF:BTO:MEAS OPOW

Activates the Output Power measurement.

CONF:BTO:DET2 RMS

Sets the detector for trace 2 to RMS.

Characteristics

*RST value:

PEAK Output Power

AVER Adjacent Channel Power

EDR Rel TX Power

EDR In–band Spurious Emissions

APEAK Modulation Characteristics

Initial Carrier Frequency Tolerance

Carrier Frequency Drift

EDR Differential Phase Encoding

EDR Carrier Frequency Stability and

Modulation Accuracy

SCPI: device–specific

Mode

CONFigure:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.360 E-11

CONFigure:BTOoth:IBSemissions:ACPairs

This command selects the number of adjacent channel pairs during the In–band Spurious

Emissions measurement. The number of adjacent channels will be limited as soon as the border

of the Bluetooth frequency band is reached.

Note: This command is only available with active In–band Spurious Emissions measurement

(see CONFigure:BTOoth:MEASurement command).

Parameter

1to 78

Example

CONF:BTO:IBS:ACP 20

Selects 20 adjacent channel pairs.

Characteristics

*RST value: 78

SCPI: device–specific

Mode

CONFigure:BTOoth:IBSemissions:GATE:AUTO

This command adjusts the gate settings for the In–band Spurious Emissions automatically.

Note: This command is only available with active In–band Spurious Emissions measurement

(see CONFigure:BTOoth:MEASurement command).

Parameter

ONCE

Example

CONF:BTO:IBS:GATE:AUTO ONCE

Adjusts the gate automatically once.

Characteristics

RST value: ONCE

SCPI: device–specific

Mode

CONFigure:BTOoth:MEASurement

This command selects the current measurement according to the Bluetooth standard.

Parameter

OPOWer Output Power measurement

ACLR Adjacent Channel Power measurement

MCHar Modulation Characteristics measurement

ICFTolerance Initial Carrier Frequency Tolerance measurement

CFDRift Carrier Frequency Drift measurement

RTPower Relative Transmit Power (EDR) measurement

R&S FSL CONFigure:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.361 E-11

IBSemissions Spurious Emissions (EDR) measurement

DPENcoding Differential Phase Encoding (EDR) measurement

CFSTability Carrier Frequency Stability and Modulation Accuracy (EDR)

measurement

Example

CONF:BTO:MEAS ACLR

Selects the measurement of the adjacent channel power.

Characteristics

*RST value: OPOWer

SCPI: device–specific

Mode

CONFigure:BTOoth:PBSCo

This command selects the number of payload bytes that are transmitted in a packet.

Parameter

1–1000

Example

CONF:BTO:PBSC 50

Selects the number of payload bytes.

Characteristics

RST value: 1

SCPI: device–specific

Mode

CONFigure:BTOoth:PCLass

This command selects the power class for the Output Power measurement. The power class

defines the limits for the output power measurement.

Parameter

1to 3

Example

CONF:BTO:PCL 3

Selects power class 3

Characteristics

*RST value: 1

SCPI: device–specific

Mode

CONFigure:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.362 E-11

CONFigure:BTOoth:POWer:AVERage:STARt

This command defines the start position for the calculation of the average power of a burst.

Note: Depending on the setting FIND SYNC ON or OFF

([SENSe<1|2>:]DDEMod:SEARch:SYNC[:STATe] command) the burst is either

defined by the p0 bit and the packet length or the 3 dB points according to the RF Test

Specification. As a result there are different areas within the burst for calculating the

average power:

Burst Length

(=Paket Length)

with FIND SYNC ON

Burst Length

with FIND SYNC OFF

3dB

Parameter

0to 100PCT

Example

CONF:BTO:POW:AVER:STAR 10PCT

Sets the starting point for the calculation to 10% of the burst length.

Characteristics

*RST value: 20%

SCPI: device–specific

Mode

CONFigure:BTOoth:POWer:AVERage:STOP

This command defines the end position for the calculation of the average power of a burst.

Note: Depending on the setting FIND SYNC ON or OFF

([SENSe<1|2>:]DDEMod:SEARch:SYNC[:STATe] command) the burst is either

defined by the p0 bit and the packet length or the 3 dB points according to the RF Test

Specification. As a result there are different areas within the burst for calculating the

average power (see CONFigure:BTOoth:POWer:AVERage:STARt command).

Parameter

0to 100PCT

Example

CONF:BTO:POW:AVER:STAR 90PCT

Sets the end point for the calculation to 90% of the burst length.

R&S FSL CONFigure:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.363 E-11

Characteristics

*RST value: 80%

SCPI: device–specific

Mode

CONFigure:BTOoth:PRATe

This command selects the number of measurement samples (points) per symbol for the

measurement. This command is not avaiable for EDR measurements. For EDR measurements,

this parameter is set to 4 points/symbol and cannot be changed.

Note: The RF Test Specification specifies an oversampling factor of at least 4.

Parameter

2 | 4 | 8 | 16 | 32

Example

CONF:BTO:PRAT 16

Selects 16 points/symbol.

Characteristics

*RST value: 4

SCPI: device–specific

Mode

CONFigure:BTOoth:PTYPe

This command selects the packet type to be measured.

Parameter

DH1 1 slot packet

DH3 3 slot packet

DH5 5 slot packet

AUTO automatic selection of the packet type

Example

CONF:BTO:PTYP DH5

Selects type "5 slot packet".

Characteristics

*RST value: DH1

SCPI: device–specific

Mode

CONFigure:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.364 E-11

CONFigure:BTOoth:RTPower:DAVerage:STARt

This command sets the start time for the power measurement of the DPSK sections of the

packet.

Note: This command is only available with active Relative Transmit Power measurement (see

CONFigure:BTOoth:MEASurement command).

Parameter

0to 100%

Example

CONF:BTO:RTP:DAV:STAR 20

Sets the start time for the power measurement of the DPSK sections of the packet.

Characteristics

RST value: 10%

SCPI: device–specific

Mode

CONFigure:BTOoth:RTPower:DAVerage:STOP

This command sets the stop time for the power measurement of the DPSK sections of the

packet.

Note: This command is only available with active Relative Transmit Power measurement (see

CONFigure:BTOoth:MEASurement command).

Parameter

0to 100%

Example

CONF:BTO:RTP:DAV:STOP 80

Sets the stop time for the power measurement of the DPSK sections of the packet.

Characteristics

RST value: 90%

SCPI: device–specific

Mode

CONFigure:BTOoth:RTPower:GAVerage:STARt

This command sets the start time for the power measurement of the GFSK sections of the

packet.

Note: This command is only available with active Relative Transmit Power measurement (see

CONFigure:BTOoth:MEASurement command).

Parameter

0to 100%

Example

CONF:BTO:RTP:GAV:STAR 20

Sets the start time for the power measurement of the GFSK sections of the packet.

R&S FSL CONFigure:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.365 E-11

Characteristics

RST value: 10%

SCPI: device–specific

Mode

CONFigure:BTOoth:RTPower:GAVerage:STOP

This command sets the stop time for the power measurement of the GFSK sections of the

packet.

Note: This command is only available with active Relative Transmit Power measurement (see

CONFigure:BTOoth:MEASurement command).

Parameter

0to 100%

Example

CONF:BTO:RTP:GAV:STOP 80

Sets the stop time for the power measurement of the GFSK sections of the packet.

Characteristics

RST value: 90%

SCPI: device–specific

Mode

CONFigure:BTOoth:SWEep:COUNt

This command defines the number of sweeps for the currently selected Bluetooth

measurement. This number will be started as a "single sweep". With trace mode setting

clear/write (CONFigure:BTOoth:TRACe<1...6>:MODE)the measurement results will be

calculated for each sweep and taken into account for the calculation of minimum, maximum and

average values. For the remaining trace settings (AVER, MAXH, MINH) the measurement

results will be calculated from the resulting trace. In average mode the value 0 defines the

sliding average of the measurement data over 10 sweeps.

Note: The setting is valid only for the currently active measurement (see

CONFigure:BTOoth:MEASurement command) and independent of the other

Bluetooth measurements.

Parameter

0to 32767

Example

CONF:BTO:MEAS OPOW

Activates the Output Power measurement.

INIT:CONT OFF

Selects single sweep operation.

CONF:BTO:SWE:COUN 20

Sets the number of sweeps to 20.

INIT;*OPC

Starts a sweep with synchronization.

CONFigure:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.366 E-11

Characteristics

*RST value:

0Output Power

10 Adjacent Channel Power

Modulation Characteristics

Initial Carrier Frequency Tolerance

Carrier Frequency Drift

EDR Relative TX Power

EDR In–band Spurious Emissions

100 Differential Phase Encoding

Mode

CONFigure:BTOoth:SWEep:TIME

This command defies the duration of a sweep sequence for the active Bluetooth measurement.

Parameter

<numeric_value>

(1us to 130560us) /

(points per symbol)

Output Power

Modulation Characteristics

Initial Carrier Frequency Tolerance

Carrier Frequency Drift

EDR Relative TX Power

EDR Differential Phase Encoding

EDR Carrier Frequency Stability and Modulation

Accuracy

10µs... 16000s Adjacent Channel Power

Direct programming using the [SENSe<1|2>:]SWEep:TIME command will cancel the coupling

to the settings according to the RF Test Specification.

Note: The setting is valid only for the currently active measurement (see

CONFigure:BTOoth:MEASurement command) and independent of the other

Bluetooth measurements.

Example

INST:SEL BTO

Activates the Bluetooth Measurements option.

CONF:BTO:MEAS OPOW

Activates the Output Power measurement.

CONF:BTO:SWE:TIME 10MS

Sets a sweep time of 10 ms.

Characteristics

*RST value: – (AUTO is set to ON)

SCPI: device–specific

Mode

R&S FSL CONFigure:BTOoth Subsystem (BLUETOOTH, K8)

1300.2519.12 6.367 E-11

CONFigure:BTOoth:SWEep:TIME:AUTO

This command couples the sweep time to the settings according to the RF Test Specification.

Note: The setting is valid only for the currently active measurement (see

CONFigure:BTOoth:MEASurement command) and independent of the other

Bluetooth measurements.

Parameter

ON | OFF

Example

INST:SEL BTO

Activates the Bluetooth Measurements option.

CONF:BTO:MEAS OPOW

Activates the Output Power measurement.

CONF:BTO:SWE:TIME:AUTO ON

Switches the sweep time coupling on.

Characteristics

*RST value: ON

SCPI: device–specific

Mode

CONFigure:BTOoth:TRACe<1...6>:MODE

This command defines the way of displaying and evaluating the measurement curves for the

selected Bluetooth measurement. WRITe corresponds to manual operating mode Clr/Write.

The numeric suffix selects the trace related to this setting.

The number of measurement to be executed for AVERage, MAXHold and MINHold is defined

with the CONFigure:BTOoth:SWEep:COUNt command. Please note that a synchronization to

the end of the indicated number of measurements is only possible during single sweep

operation.

Note: The setting is valid only for the currently active measurement (see

CONFigure:BTOoth:MEASurement command) and independent of the other

Bluetooth measurements.

Parameter

Example

INST:SEL BTO

Activates the Bluetooth Measurements option.

CONF:BTO:MEAS OPOW

Activates the Output Power measurement.

INIT:CONT OFF

Selects single sweep operation.

CONF:BTO:SWE:COUN 10

Sets the sweep count to 10.

CONF:BTO:TRAC2:MODE AVER

Switches averaging for trace 2 on.

INIT;*OPC

Starts a measurement with synchronization.

CONFigure:BTOoth Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.368 E-11

Characteristics

*RST value: WRITe

SCPI: device–specific

Mode

CONFigure:BTOoth:TRACe<1...6>:SELect

This command selects the measurement curve for evaluation of the modulation characteristics.

Example

INST:SEL BTO

Activates the Bluetooth Measurements option.

CONF:BTO:MEAS ACLR

Activates the Adjacent Channel Power measurement.

INIT:CONT OFF

Selects single sweep operation.

CONF:BTO:TRAC2:SEL

Selects trace 2 for measurement result queries.

Characteristics

*RST value: –

SCPI: device–specific

Mode

R&S FSL DISPlay Subsystem (BLUETOOTH, K8)

1300.2519.12 6.369 E-11

DISPlay Subsystem (BLUETOOTH, K8)

The DISPLay subsystem controls the selection and presentation of textual and graphic information as

well as of measurement data on the display.

Commands of the DISPlay Subsystem

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:PDIVision

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:PDIVision

This command defines the scaling of the y–axis in the currently selected unit. The numeric suffix

in TRACe<1...6> is irrelevant.

Parameter

<numeric_value>

Example

DISP:TRAC:Y:PDIV 10kHz

Sets the Y scale to 10 kHz/div.

Characteristics

*RST value: –

SCPI: conform

Mode

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

This command defines the position of the reference value. In Bluetooth mode, the selected

reference position is valid for all measurements.

Characteristics

*RST value: 50 PCT

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

(models with tracking generator)" on page 6.136.

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue

This command defines the result value assigned to the reference position on the graticule.

Example

DISP:TRAC:Y:RVAL 0

Sets the value assigned to the reference position to 0 Hz

Characteristics

*RST value: 0 Hz

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

(models with tracking generator)" on page 6.136.

INSTrument Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.370 E-11

INSTrument Subsystem (BLUETOOTH, K8)

The INSTrument subsystem selects the operating mode of the unit either via text parameters or fixed

numbers.

Commands of the INSTrument Subsystem

–INSTrument[:SELect]

–INSTrument:NSELect

INSTrument[:SELect]

Parameter

BTOoth Bluetooth mode (option Bluetooth Measurements, R&S FSL–K8)

For details refer to the INSTrument subsystem of the base unit.

INSTrument:NSELect

Parameter

12 Bluetooth mode (option Bluetooth Measurements, R&S FSL–K8)

For details refer to the INSTrument subsystem of the base unit .

R&S FSL SENSe Subsystem (BLUETOOTH, K8)

1300.2519.12 6.371 E-11

SENSe Subsystem (BLUETOOTH, K8)

The SENSe subsystem controls the essential parameters of the Bluetooth Measurements option. In

accordance with the SCPI standard, the keyword "SENSe" is optional for this reason, which means that

it is not necessary to include the SENSe node in command sequences.

The following subsystem is included:

•"SENSe:ADEMod Subsystem (BLUETOOTH, K8)" on page 6.371

•"SENSe:DDEMod Subsystem (BLUETOOTH, K8)" on page 6.373

[SENSe<1|2>:]CORRection:EGAin:INPut[:MAGNitude]

This command makes an external gain known to the analyzer, which will take it into account

during the display of measurement results. With this function the gain of an antenna or of an

external preamplifier can be taken into account for the measurement values.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

–200 to +200 dB

Example

CORR:EGA:INP 10DB

Takes 10 dB external gain into account

Characteristics

*RST value: 0 dB

SCPI: device–specific

Mode

SENSe:ADEMod Subsystem (BLUETOOTH, K8)

The SENSe:ADEMod Subsystem contains commands to set up the instrument for the measurement of

analog demodulated signals.

Commands of the SENSe:ADEMod Subsystem

–[SENSe:]ADEMod:ZOOM[:STATe]

–[SENSe:]ADEMod:ZOOM:STARt

[SENSe:]ADEMod:ZOOM[:STATe]

The command enables or disables the zoom function. Depending on the selected measurement

time and the demodulation bandwidth, the number of recorded measurement points may be

greater than that shown on the display.

If the zoom function is enabled, 501 test points of the result memory are displayed from the start

time specified by the [SENSe:]ADEMod:ZOOM:STARt command.

If the zoom function is disabled, data reduction is used to adapt the measurement points to the

number of points available on the display.

Note: The zoom function is only available for the Output Power, Modulation Characteristics,

Initial Carrier Frequency Tolerance, and Carrier Frequency Drift measurements.

SENSe Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.372 E-11

Parameter

ON | OFF

Example

ADEM:ZOOM ON

Switches on the zoom function

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

[SENSe:]ADEMod:ZOOM:STARt

The command sets the start time for the display of individual measured values.

The zoom function is enabled or disabled by the [SENSe:]ADEMod:ZOOM[:STATe]

command.

Note: The zoom function is only available for the Output Power, Modulation Characteristics,

Initial Carrier Frequency Tolerance, and Carrier Frequency Drift measurements.

Parameter

0 s to (meas time – 500 / sampling rate)

Example

ADEM:ZOOM ON

Switches on the zoom function

ADEM:ZOOM:STAR 500us

Sets the starting point of the display to 500 µs.

Characteristics

*RST value: 0 s

SCPI: device–specific

Mode

R&S FSL SENSe Subsystem (BLUETOOTH, K8)

1300.2519.12 6.373 E-11

SENSe:DDEMod Subsystem (BLUETOOTH, K8)

This subsystem controls the parameters for digital demodulators.

Commands of the SENSe:DDEMod Subsystem

–[SENSe<1|2>:]DDEMod:FILTer:MEASurement

–[SENSe<1|2>:]DDEMod:SEARch:PULSe[:STATe]

–[SENSe<1|2>:]DDEMod:SEARch:PULSe:OFFSet

–[SENSe<1|2>:]DDEMod:SEARch:SYNC[:STATe]

–[SENSe<1|2>:]DDEMod:SEARch:SYNC:LAP

–[SENSe<1|2>:]DDEMod:SEARch:SYNC:OFFSet

–[SENSe<1|2>:]DDEMod:SEARch:TIME

–[SENSe<1|2>:]DDEMod:SEARch:TIME:AUTO

[SENSe<1|2>:]DDEMod:FILTer:MEASurement

This command selects the receive filter for the signal to measure.

The numeric suffixes <1|2> are irrelevant for this command.

Note: This command is only available with active Modulation Characteristics, Initial Carrier

Frequency Tolerance, and Carrier Frequency Drift measurement (see

CONFigure:BTOoth:MEASurement command). With all other measurements it will

lead to a query error.

Parameter

OFF | BTOoth

Example

DDEM:FILT:MEAS BTO

Activates the Bluetooth measurement filter.

Characteristics

*RST value: ON

SCPI: device–specific

Mode

[SENSe<1|2>:]DDEMod:SEARch:PULSe[:STATe]

This command switches the search for a signal burst on or off.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

DDEM:SEAR:PULS OFF

SENSe Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.374 E-11

Characteristics

*RST value: ON

SCPI: device–specific

Mode

[SENSe<1|2>:]DDEMod:SEARch:PULSe:OFFSet

This command defines the time to be recorded before a signal burst is recognized. The valid

value range is 0 to ± 10 ms.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0to 10 ms

Example

DDEM:SEAR:PULS:OFFS 1MS

Sets the burst offset to 1ms before the start of the burst.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

[SENSe<1|2>:]DDEMod:SEARch:SYNC[:STATe]

This command switches the search for a sync pattern on or off.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

DDEM:SEAR:SYNC ON

Switches the sync pattern search on.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

R&S FSL SENSe Subsystem (BLUETOOTH, K8)

1300.2519.12 6.375 E-11

[SENSe<1|2>:]DDEMod:SEARch:SYNC:LAP

This command determines the 24 least significant bits (LAP) of the DUT 'Bluetooth device

address'. They are used to define the synchronization pattern to determine the start of a packet.

The value range is 0 to FFFFFF hex.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

<hex>

Example

DDEM:SEAR:SYNC:LAP #HA3F45B

Sets on LAP A3F45B Hex

Characteristics

*RST value: #H0

SCPI: device–specific

Mode

[SENSe<1|2>:]DDEMod:SEARch:SYNC:OFFSet

This command defines the number of bits to be recorded before the first preamble bit is

detected. The valid value range is 0 to ± 10000.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0to 10,000

Example

DDEM:SEAR:SYNC:OFFS 10

Sets the sync offset to 10 bits before the preamble bits.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

[SENSe<1|2>:]DDEMod:SEARch:TIME

This command selects manual setting of the record length and defines the record length to be

used for the search of sync word and burst. The input of the record length is expected in

seconds.

The numeric suffixes <1|2> are irrelevant for this command.

Note: For information on the correlation of trigger and record length refer to the

[SENSe<1|2>:]DDEMod:SEARch:TIME:AUTO command.

SENSe Subsystem (BLUETOOTH, K8) R&S FSL

1300.2519.12 6.376 E-11

Parameter

100µsto 130560µs / (points per symbol)

Points per Symbol Maximum record length

2104.4 slots

452.2 slots

826.1 slots

16 13.1 slots

32 6.5 slots

Example

DDEM:SEAR:TIME 100US

Sets the record length for sync word and burst search to 100µs.

Characteristics

*RST value: 1875µs

SCPI: device–specific

Mode

[SENSe<1|2>:]DDEMod:SEARch:TIME:AUTO

This command activates the automatic setting of the record length for the sync word and burst

search, depending on the selected packet type.

The automatic record length is determined a follows:

Trigger free run:

search length = 3 * packet length + | sync offset or burst offset |

All other trigger modes:

search length = 1 * packet length + 1 Slot + | sync offset or burst offset |

If the selected measurement time is higher than the packet length, the following difference is

added to the search length:

measurement time – packet length

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

DDEM:SEAR:TIME:AUTO OFF

Selects manual input for the record length

Characteristics

*RST value: ON

SCPI: device–specific

Mode

R&S FSL Remote Commands of the Power Meter Option (K9)

1300.2519.12 6.377 E-11

Remote Commands of the Power Meter Option (K9)

In this section all remote control commands for Power Meter option are described in detail. The

abbreviation For details on conventions used in this chapter refer to section "Notation" on page 6.2 at

the beginning of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in "Remote Commands of the Base Unit" on page 6.5.

Subsystems of the Power Meter option (K9)

–"CALCulate Subsystem (Power Meter, K9)" on page 6.378

–"CALibration Subsystem (Power Meter, K9)" on page 6.380

–"FETCh Subsystem (Power Meter, K9)" on page 6.381

–"READ Subsystem (Power Meter, K9)" on page 6.382

–"SENSe Subsystem (Power Meter, K9)" on page 6.383

–"UNIT Subsystem (Power Meter, K9)" on page 6.388

CALCulate Subsystem (Power Meter, K9) R&S FSL

1300.2519.12 6.378 E-11

CALCulate Subsystem (Power Meter, K9)

The CALCulate subsystem contains commands for converting instrument data, transforming and

carrying out corrections. These functions are carried out subsequent to data acquisition, i.e. following

the SENSe subsystem.

The following subsystems are included:

•"CALCulate:PMETer Subsystem" on page 6.378

CALCulate:PMETer Subsystem (Power Meter, K9)

This subsystem controls the instrument settings for power sensor measurements.

Commands of the CALCulate:PMETer Subsystem

–CALCulate<1|2>:PMETer:RELative[:MAGNitude]

–CALCulate<1|2>:PMETer:RELative[:MAGNitude]:AUTO

–CALCulate<1|2>:PMETer:RELative:STATe

CALCulate<1|2>:PMETer:RELative[:MAGNitude]

This command sets the reference value for relative measurements.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200

Example

CALC:PMET:REL –30

Sets the reference value for relative measurements to –30 dBm.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

PSM

CALCulate<1|2>:PMETer:RELative[:MAGNitude]:AUTO

This command takes the current measurement value as reference value for relative

measurements.

The numeric suffixes <1|2> are irrelevant.

Parameter

ONCE

Example

CALC:PMET:REL:AUTO ONCE

Takes the current measurement value as reference value for relative measurements.

R&S FSL CALCulate Subsystem (Power Meter, K9)

1300.2519.12 6.379 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

PSM

CALCulate<1|2>:PMETer:RELative:STATe

This command switches between relative and absolute display of the measured power.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

CALC:PMET:REL:STAT ON

Activates the relative display of the measured value.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

PSM

CALibration Subsystem (Power Meter, K9) R&S FSL

1300.2519.12 6.380 E-11

CALibration Subsystem (Power Meter, K9)

The CALibration subsystem determines the data for system error correction in the instrument.

The following subsystem is included:

•"CALibration:PMETer Subsystem (Power Meter, K9)" on page 6.380

CALibration:PMETer Subsystem (Power Meter, K9)

The CALibration:PMETer Subsystem determines the error correction data for measurements in the

power meter mode.

Commands of the CALibration:PMETer Subsystem

–CALibration:PMETer:ZERO:AUTO

CALibration:PMETer:ZERO:AUTO

This command starts zeroing of the power sensor.

Parameter

ONCE

Example

:CAL:PMET:ZERO:AUTO ONCE;*WAI

Starts zeroing and delays the execution of further commands until zeroing is concluded.

Characteristics

*RST value: –

SCPI: device–specific

Mode

PSM

R&S FSL FETCh Subsystem (Power Meter, K9)

1300.2519.12 6.381 E-11

FETCh Subsystem (Power Meter, K9)

The FETCh subsystem contains commands for reading out results of complex measurement tasks.

The following subsystem is included:

•"FETCh:PMETer Subsystem" on page 6.381

FETCh:PMETer Subsystem (Power Meter, K9)

The FETCh:PMETer subsystem contains commands to read measurement results of power sensor

measurements without starting the measurement itself.

Commands of the FETCh:PMETer Subsystem

–FETCh<1|2>:PMETer?

FETCh<1|2>:PMETer?

This command reads the result of the power sensor measurement.

If no measurement has been performed, this command will lead to a query error. This command

is a query and therefore has no *RST value.

Example

FETC:PMET?

Reads the result of the power sensor measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

PSM

READ Subsystem (Power Meter, K9) R&S FSL

1300.2519.12 6.382 E-11

READ Subsystem (Power Meter, K9)

The READ subsystem contains commands for starting complex measurement tasks, and for querying

the results subsequently.

The following subsystem is included:

•"READ:PMETer Subsystem" on page 6.382

READ:PMETer Subsystem

This subsystem contains commands to start power sensor measurements and to read the results after

the measurement is concluded.

Commands of the READ:PMETer Subsystem

–READ<1|2>:PMETer?

READ<1|2>:PMETer?

This command starts a power sensor measurement and reads the result after the measurement

is concluded.

This command is a query and therefore has no *RST value.

Example

READ:PMET?

Starts a measurement and read the result.

Characteristics

*RST value: –

SCPI: device–specific

Mode

PSM

R&S FSL SENSe Subsystem (Power Meter, K9)

1300.2519.12 6.383 E-11

SENSe Subsystem (Power Meter, K9)

The SENSe subsystem is organized in several subsystems. The commands of these subsystems

directly control device–specific settings, they do not refer to the signal characteristics of the

measurement signal.

The SENSe subsystem controls the essential parameters of the analyzer. In accordance with the SCPI

standard, the keyword "SENSe" is optional for this reason, which means that it is not necessary to

include the SENSe node in command sequences.

The following subsystems are included:

•"SENSe:PMETer Subsystem" on page 6.383

SENSe:PMETer Subsystem (Power Meter, K9)

This subsystem controls the device settings for power sensor measurements.

Commands of the SENSe:PMETer Subsystem

–[SENSe<1|2>:]PMETer[:STATe]

–[SENSe<1|2>:]PMETer:FREQuency

–[SENSe<1|2>:]PMETer:FREQuency:LINK

–[SENSe<1|2>:]PMETer:MTIMe

–[SENSe<1|2>:]PMETer:MTIMe:AVERage[:STATe]

–[SENSe<1|2>:]PMETer:MTIMe:AVERage:COUNt

–[SENSe<1|2>:]PMETer:ROFFset[:STATe]

–[SENSe<1|2>:]PMETer:TRIGger[:STATe]

–[SENSe<1|2>:]PMETer:TRIGger:LEVel

[SENSe<1|2>:]PMETer[:STATe]

This command switches the power sensor measurements on or off.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

PMET ON

Switches the power sensor measurements on.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

PSM

SENSe Subsystem (Power Meter, K9) R&S FSL

1300.2519.12 6.384 E-11

[SENSe<1|2>:]PMETer:FREQuency

This command sets the frequency of the power sensor. The limits fmin and fmax are defined by the

power sensor.

The numeric suffixes <1|2> are irrelevant.

Parameter

fmin ... fmax

Example

PMET:FREQ 1GHZ

Sets the frequency of the power sensor to 1 GHz.

Characteristics

*RST value: 50 MHz

SCPI: device–specific

Mode

PSM

[SENSe<1|2>:]PMETer:FREQuency:LINK

This command sets the frequency coupling of the power sensor.

The numeric suffixes <1|2> are irrelevant.

Parameter

CENTer couples the frequency to the center frequency of the analyzer

MARKer1 couples the frequency to the position of marker 1

OFF switches the frequency coupling off

Example

PMET:FREQ:LINK CENT

Couples the frequency to the center frequency of the analyzer

Characteristics

*RST value: CENT

SCPI: device–specific

Mode

PSM

[SENSe<1|2>:]PMETer:MTIMe

This command sets the measurement duration of the power sensor.

The numeric suffixes <1|2> are irrelevant.

Parameter

SHORt | NORMal | LONG

Example

PMET:MTIM SHOR

Sets a short measurement duration for measurements of stationary high power signals.

R&S FSL SENSe Subsystem (Power Meter, K9)

1300.2519.12 6.385 E-11

Characteristics

*RST value: NORM

SCPI: device–specific

Mode

PSM

[SENSe<1|2>:]PMETer:MTIMe:AVERage[:STATe]

This command activates or deactivates manual averaging. The average count is set with the

[SENSe<1|2>:]PMETer:MTIMe:AVERage:COUNt command.

This command is available from firmware version 1.70.

Parameter

ON | OFF

Example

PMET:MTIM:AVER ON

Activates manual averaging.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

PSM

[SENSe<1|2>:]PMETer:MTIMe:AVERage:COUNt

This command defines the number of readings (averagings) to be performed after a single

sweep has been started. This command is only available if the

[SENSe<1|2>:]PMETer:MTIMe:AVERage[:STATe] command is set to ON.

Results become more stable with extended average, particularly if signals with low power are

measured. This setting can be used to minimize the influence of noise in the power meter

measurement.

This command is available from firmware version 1.70.

Parameter

0to 256 in binary steps (1, 2, 4, 8,…)

For average count = 0 or 1, one reading is performed.

Example

PMET:MTIM:AVER ON

Activates manual averaging.

PMET:MTIM:AVER:COUN 8

Sets the number of readings to 8.

Characteristics

RST value:

SCPI: device–specific

Mode

PSM

SENSe Subsystem (Power Meter, K9) R&S FSL

1300.2519.12 6.386 E-11

[SENSe<1|2>:]PMETer:ROFFset[:STATe]

This command defines whether the reference level offset set for the analyzer is taken into

account for the measured power or not.

The numeric suffixes <1|2> are irrelevant.

This command is available from firmware version 1.50.

Parameter

ON Adds the offset defined by the

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel:OFFSet

command to the measured level.

OFF Takes no offset into account.

Example

PMET:ROFF OFF

Takes no offset into account for the measured power.

Characteristics

*RST value: ON

SCPI: device–specific

Mode

PSM

[SENSe<1|2>:]PMETer:TRIGger[:STATe]

This command switches the external power trigger on or off.

The numeric suffixes <1|2> are irrelevant.

This command is only available in conjunction with a NRP-Z81 power sensor.

This command is available from firmware version 1.90.

Parameter

ON | OFF

Example

PMET:TRIG ON

Switches the external power trigger on.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

PSM

R&S FSL SENSe Subsystem (Power Meter, K9)

1300.2519.12 6.387 E-11

[SENSe<1|2>:]PMETer:TRIGger:LEVel

This command sets the power level of the external power trigger.

The numeric suffixes <1|2> are irrelevant.

This command is only available in conjunction with a NRP-Z81 power sensor.

This command is available from firmware version 1.90.

Parameter

-20 bis + 20 dBm

Example

PMET:TRIG:LEV -10 dBm

Sets the level of the trigger.

Characteristics

*RST value: -20dBm

SCPI: device–specific

Mode

PSM

UNIT Subsystem (Power Meter, K9) R&S FSL

1300.2519.12 6.388 E-11

UNIT Subsystem (Power Meter, K9)

The UNIT subsystem sets the basic unit of the setting parameters.

The following subsystems are included:

•"UNIT:PMETer Subsystem (Power Meter, K9)" on page 6.388

UNIT:PMETer Subsystem (Power Meter, K9)

The UNIT:PMETer subsystem sets the basic unit for power sensor measurement.

Commands of the UNIT:PMETer Subsystem

–UNIT<1|2>:PMETer:POWer

–UNIT<1|2>:PMETer:POWer:RATio

UNIT<1|2>:PMETer:POWer

This command selects the unit for absolute power sensor measurement.

Parameter

DBM | WATT | W

Example

UNIT:PMET:POW DBM

Characteristics

*RST value: DBM

SCPI: conform

Mode

PSM

UNIT<1|2>:PMETer:POWer:RATio

This command selects the unit for relative power sensor measurement.

Parameter

DB | PCT

Example

UNIT:PMET:POW DB

Characteristics

*RST value: DB

SCPI: conform

Mode

PSM

R&S FSL UNIT Subsystem (Power Meter, K9)

1300.2519.12 6.389 E-11

Remote Commands of the Spectrogram

Measurement Option (K14)

This section describes the remote commands for the Spectrogram Measurement option (K14). The

abbreviation SPECM stands for the Spectrogram measurement mode. For details on conventions used

in this chapter refer to section "Notation" on page 6.2 at the beginning of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in "Remote Commands of the Base Unit" on page 6.5.

This option is available from firmware version 1.60.

Subsystems of the Spectrogram Measurement option (K14)

–"CALCulate Subsystem (SPECM, K14)" on page 6.390

–"INITiate Subsystem (SPECM, K14)" on page 6.407

–"MMEMory Subsystem (SPECM, K14)" on page 6.408

–"TRACe Subsystem (SPECM, K14)" on page 6.409

CALCulate Subsystem (SPECM, K14) R&S FSL

1300.2519.12 6.390 E-11

CALCulate Subsystem (SPECM, K14)

The CALCulate subsystem contains commands for converting instrument data, transforming and

carrying out corrections. These functions are carried out subsequent to data acquisition, i.e. following

the SENSe subsystem.

The following subsystems are included:

•"CALCulate:DELTamarker:SPECtrogram Subsystem (SPECM, K14)" on page 6.390

•"CALCulate:MARKer:SPECtrogram Subsystem (SPECM, K14)" on page 6.396

•"CALCulate:SPECtrogram Subsystem (SPECM, K14)" on page 6.402

Note: For the search commands in x direction refer to the base unit, section "CALCulate:MARKer

Subsystem" on page 6.55.

CALCulate:DELTamarker:SPECtrogram Subsystem (SPECM, K14)

The CALCulate:DELTamarker:SPECtrogram subsystem controls the delta marker functions of the

Spectrogram Measurement option.

Commands of the CALCulate:DELTamarker:SPECtrogram Subsystem

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:FRAMe

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:SARea

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:XY:MAXimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:XY:MINimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum:ABOVe

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum:BELow

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum:NEXT

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum:ABOVe

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum:BELow

–CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum:NEXT

R&S FSL CALCulate Subsystem (SPECM, K14)

1300.2519.12 6.391 E-11

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:FRAMe

This command defines the frame number of the specified delta marker.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0to <number of recorded frames>

If the maximum number of frames is recorded, the max. value depends on the history depth (for

details refer to CALCulate<1|2>:SPECtrogram:HDEPth command)

Example

CALC:DELT3 ON

Switches on delta marker 3 or switches to delta marker mode.

CALC:DELT3:SPEC:FRAM –50

Positions delta marker 3 on frame number –50.

Characteristics

RST value: 0

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:SARea

This command defines the search area of the specified delta marker.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

VISible | MEMory

Example

CALC:DELT2 ON

Switches on delta marker 2 or switches to delta marker mode.

CALC:DELT2:SPEC:SAR MEM

Searches the whole data range stored in the history buffer.

Characteristics

RST value: VIS

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:XY:MAXimum[:PEAK]

This command positions the specified delta marker on the current maximum of the search area.

The search area is defined via the

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:SARea command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

CALCulate Subsystem (SPECM, K14) R&S FSL

1300.2519.12 6.392 E-11

Example

CALC:DELT2 ON

Switches on delta marker 2 or switches to delta marker mode.

CALC:DELT2:SPEC:XY:MAX

Positions delta marker 2 on the current maximum.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:XY:MINimum[:PEAK]

This command positions the specified delta marker on the current minimum of the search area.

The search area is defined via the

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:SARea command. .

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT3 ON

Switches on delta marker 3 or switches to delta marker mode.

CALC:DELT3:SPEC:XY:MIN

Positions delta marker 3 on the current minimum.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum[:PEAK]

This command positions the specified delta marker on the current maximum in y–axis direction

(constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:DELTamarker<1...4>:MAXimum[:PEAK] command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT4 ON

Switches on delta marker 4 or switches to delta marker mode.

CALC:DELT4:SPEC:Y:MAX

Positions delta marker 4 on the current maximum in y–axis direction.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

R&S FSL CALCulate Subsystem (SPECM, K14)

1300.2519.12 6.393 E-11

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum:ABOVe

This command positions the specified delta marker on the next maximum above its current

position (constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT and

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt commands.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT2 ON

Switches on delta marker 2 or switches to delta marker mode.

CALC:DELT2:SPEC:Y:MAX:ABOV

Positions delta marker 2 on the next maximum above its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum:BELow

This command positions the specified delta marker on the next maximum below its current

position (constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT and

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt commands.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT3 ON

Switches on delta marker 3 or switches to delta marker mode.

CALC:DELT3:SPEC:Y:MAX:BEL

Positions delta marker 3 on the next maximum below its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum:NEXT

This command positions the specified delta marker on the next maximum below or above its

current position (constant x–axis value). The corresponding search in x direction is performed

via the CALCulate<1|2>:DELTamarker<1...4>:MAXimum:NEXT command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT4 ON

Switches on delta marker 4 or switches to delta marker mode.

CALCulate Subsystem (SPECM, K14) R&S FSL

1300.2519.12 6.394 E-11

CALC:DELT4:SPEC:Y:MAX:NEXT

Positions delta marker 4 on the next maximum below or above its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum[:PEAK]

This command positions the specified delta marker on the current minimum in y–axis direction

(constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:DELTamarker<1...4>:MINimum[:PEAK] command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT4 ON

Switches on delta marker 4 or switches to delta marker mode.

CALC:DELT4:SPEC:Y:MIN

Positions delta marker 4 on the current minimum in y–axis direction.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum:ABOVe

This command positions the specified delta marker on the next minimum above its current

position (constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT and

CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt commands.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT2 ON

Switches on delta marker 2 or switches to delta marker mode.

CALC:DELT2:SPEC:Y:MIN:ABOV

Positions delta marker 2 on the next minimum above its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

R&S FSL CALCulate Subsystem (SPECM, K14)

1300.2519.12 6.395 E-11

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum:BELow

This command positions the specified delta marker on the next minimum below its current

position (constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT and

CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt commands.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT3 ON

Switches on delta marker 3 or switches to delta marker mode.

CALC:DELT3:SPEC:Y:MIN:BEL

Positions delta marker 3 on the next minimum below its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum:NEXT

This command positions the specified delta marker on the next minimum below or above its

current position (constant x–axis value). The corresponding search in x direction is performed

via the CALCulate<1|2>:DELTamarker<1...4>:MINimum:NEXT command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT4 ON

Switches on delta marker 4 or switches to delta marker mode.

CALC:DELT4:SPEC:Y:MIN:NEXT

Positions delta marker 4 on the next minimum below or above its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate Subsystem (SPECM, K14) R&S FSL

1300.2519.12 6.396 E-11

CALCulate:MARKer:SPECtrogram Subsystem (SPECM, K14)

The CALCulate:MARKer:SPECtrogram subsystem controls the marker functions of the Spectrogram

Measurement option.

Commands of the CALCulate:MARKer:SPECtrogram Subsystem

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:FRAMe

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:SARea

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:XY:MAXimum[:PEAK]

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:XY:MINimum[:PEAK]

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum[:PEAK]

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum:ABOVe

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum:BELow

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum:NEXT

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum[:PEAK]

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum:ABOVe

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum:BELow

–CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum:NEXT

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:FRAMe

This command defines the frame number of the specified marker.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0to <number of recorded frames>

If the maximum number of frames is recorded, the max. value depends on the history depth (for

details refer to CALCulate<1|2>:SPECtrogram:HDEPth command)

Example

CALC:MARK3:SPEC:FRAM –20

Positions marker 3 on frame number –20.

Characteristics

RST value: 0

SCPI: device–specific

Mode

SPECM

R&S FSL CALCulate Subsystem (SPECM, K14)

1300.2519.12 6.397 E-11

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:SARea

This command defines the search area of the specified marker.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

VISible | MEMory

Example

CALC:MARK2:SPEC:SAR MEM

Searches the whole data range stored in the history buffer.

Characteristics

RST value: VIS

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:XY:MAXimum[:PEAK]

This command positions the specified marker on the current maximum of the search area. The

search area is defined via the CALCulate<1|2>:MARKer<1...4>:SPECtrogram:SARea

command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:MARK2:SPEC:XY:MAX

Positions marker 2 on the current maximum.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:XY:MINimum[:PEAK]

This command positions the specified marker on the current minimum of the search area. The

search area is defined via the CALCulate<1|2>:MARKer<1...4>:SPECtrogram:SARea

command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:MARK3:SPEC:XY:MIN

Positions marker 3 on the current minimum.

CALCulate Subsystem (SPECM, K14) R&S FSL

1300.2519.12 6.398 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum[:PEAK]

This command positions the specified marker on the current maximum in y–axis direction

(constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:MARKer<1...4>:MAXimum[:PEAK] command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Note: If no maximum value is found (level spacing to adjacent values < peak excursion), an

execution error (error code: –200) is produced.

Example

CALC:MARK:SPEC:Y:MAX

Positions marker 1 on the current maximum in y–axis direction.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum:ABOVe

This command positions the specified marker on the next maximum above its current position

(constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT and

CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt commands.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Note: If no next smaller maximum value is found (level spacing to adjacent values < peak

excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK2:SPEC:Y:MAX

Positions marker 2 on the current maximum in y–axis direction.

CALC:MARK2:SPEC:Y:MAX:ABOV

Positions marker 2 on the next maximum above its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

R&S FSL CALCulate Subsystem (SPECM, K14)

1300.2519.12 6.399 E-11

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum:BELow

This command positions the specified marker on the next maximum below its current position

(constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT and

CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt commands.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Note: If no next smaller maximum value is found (level spacing to adjacent values < peak

excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK3:SPEC:Y:MAX

Positions marker 3 on the current maximum in y–axis direction.

CALC:MARK3:SPEC:Y:MAX:BEL

Positions marker 3 on the next maximum below its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum:NEXT

This command positions the specified marker on the next maximum below or above its current

position (constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:MARKer<1...4>:MAXimum:NEXT command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Note: If no next smaller maximum value is found (level spacing to adjacent values < peak

excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK:SPEC:Y:MAX

Positions marker 1 on the current maximum in y–axis direction.

CALC:MARK:SPEC:Y:MAX:NEXT

Positions marker 1 on the next maximum below or above its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate Subsystem (SPECM, K14) R&S FSL

1300.2519.12 6.400 E-11

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum[:PEAK]

This command positions the specified marker on the current minimum in y–axis direction

(constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:MARKer<1...4>:MINimum[:PEAK] command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Note: If no minimum value is found (level spacing to adjacent values < peak excursion), an

execution error (error code: –200) is produced.

Example

CALC:MARK:SPEC:Y:MIN

Positions marker 1 on the current minimum in y–axis direction.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum:ABOVe

This command positions the specified marker on the next minimum above its current position

(constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT and

CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt commands.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Note: If no next higher minimum value is found (level spacing to adjacent values < peak

excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK2:SPEC:Y:MIN

Positions marker 2 on the current minimum in y–axis direction.

CALC:MARK2:SPEC:Y:MIN:ABOV

Positions marker 2 on the next minimum above its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

R&S FSL CALCulate Subsystem (SPECM, K14)

1300.2519.12 6.401 E-11

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum:BELow

This command positions the specified marker on the next minimum below its current position

(constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT and

CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt commands.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Note: If no next higher minimum value is found (level spacing to adjacent values < peak

excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK3:SPEC:Y:MIN

Positions marker 3 on the current minimum in y–axis direction.

CALC:MARK3:SPEC:Y:MIN:BEL

Positions marker 3 on the next minimum below its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum:NEXT

This command positions the specified marker on the next minimum below or above its current

position (constant x–axis value). The corresponding search in x direction is performed via the

CALCulate<1|2>:MARKer<1...4>:MINimum:NEXT command.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Note: If no next higher minimum value is found (level spacing to adjacent values < peak

excursion), an execution error (error code: –200) is produced.

Example

CALC:MARK:SPEC:Y:MIN

Positions marker 1 on the current minimum in y–axis direction.

CALC:MARK:SPEC:Y:MIN:NEXT

Positions marker 1 on the next minimum below or above its current position.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

CALCulate Subsystem (SPECM, K14) R&S FSL

1300.2519.12 6.402 E-11

CALCulate:SPECtrogram Subsystem (SPECM, K14)

The CALCulate:SPECtrogram subsystem configures the Spectrogram Measurement option.

Commands of the CALCulate:SPECtrogram Subsystem

–CALCulate<1|2>:SPECtrogram[:STATe]

–CALCulate<1|2>:SPECtrogram:CLEar[:IMMediate]

–CALCulate<1|2>:SPECtrogram:COLor

–CALCulate<1|2>:SPECtrogram:CONTinuous

–CALCulate<1|2>:SPECtrogram:FRAMe:COUNt

–CALCulate<1|2>:SPECtrogram:FRAMe:SELect

–CALCulate<1|2>:SPECtrogram:HDEPth

–CALCulate<1|2>:SPECtrogram:SIZE

–CALCulate<1|2>:SPECtrogram:TSTamp[:STATe]

–CALCulate<1|2>:SPECtrogram:TSTamp:DATA

CALCulate<1|2>:SPECtrogram[:STATe]

This command activates or deactivates the Spectrogram Measurement option.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:SPEC ON

Activates the Spectrogram Measurement option.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:SPECtrogram:CLEar[:IMMediate]

This command deletes the spectrogram result display and the history buffer.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

CALC:SPEC ON

Activates the Spectrogram Measurement option.

CALC:SPEC:CLE

Deletes the spectrogram result display and the history buffer.

Characteristics

RST value: –

SCPI: device–specific

R&S FSL CALCulate Subsystem (SPECM, K14)

1300.2519.12 6.403 E-11

Mode

SPECM

CALCulate<1|2>:SPECtrogram:COLor

This command defines the frame color setting.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

COLor RGB colors

RADar black – green – white

GRAYscale black and white

Example

CALC:SPEC ON

Activates the Spectrogram Measurement option.

CALC:SPEC:COL RAD

Sets the black–green–white color scheme for the frame coloring.

Characteristics

RST value: COL

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:SPECtrogram:CONTinuous

This command determines whether the results of the last measurement are deleted before

starting a new measurement in single sweep mode.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:SPEC ON

Activates the Spectrogram Measurement option.

INIT:CONT OFF

Sets the single sweep mode.

INIT;*WAI

Starts the measurement and waits for the end of the single sweep measurement.

CALC:SPEC:CONT ON

Repeats the single sweep measurement without deleting the spectrogram results of the last

measurement.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

SPECM

CALCulate Subsystem (SPECM, K14) R&S FSL

1300.2519.12 6.404 E-11

CALCulate<1|2>:SPECtrogram:FRAMe:COUNt

This command sets the number of frames recorded in a single sweep measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

1to <max value, depending on history depth (for details refer to

CALCulate<1|2>:SPECtrogram:HDEPth command)>

Example

CALC:SPEC ON

Activates the Spectrogram Measurement option.

INIT:CONT OFF

Sets the single sweep mode

CALC:SPEC:FRAM:COUN 200

Sets the number of frames to 200.

Characteristics

RST value: 1

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:SPECtrogram:FRAMe:SELect

This command selects the frame if no measurement is running. During a measurement, the

value is fixed to 0 and this command is not available.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0to <number of recorded frames>

If the maximum number of frames is recorded, the max. value depends on the history depth (for

details refer to CALCulate<1|2>:SPECtrogram:HDEPth command)

Example

CALC:SPEC ON

Activates the Spectrogram Measurement option.

INIT:CONT OFF

Stops the measurement in continuous sweep mode.

CALC:SPEC:FRAM:SEL –10

Selects the frame number –10.

Characteristics

RST value: 0

SCPI: device–specific

Mode

SPECM

R&S FSL CALCulate Subsystem (SPECM, K14)

1300.2519.12 6.405 E-11

CALCulate<1|2>:SPECtrogram:HDEPth

This command sets the number of frames to be stored in the history buffer.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

282 to 20000

The maximum number of frames depends on the number of sweep points

([SENSe<1|2>:]SWEep:POINts command) and is determined as described in chapter 2,

section Spectrogram Measurement (Option K14), Maximum number of frames.

Example

CALC:SPEC ON

Activates the Spectrogram Measurement option.

CALC:SPEC:HDEP 1000

Sets 1000 as number of frames to be stored in the history buffer.

Characteristics

RST value: 3000

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:SPECtrogram:SIZE

This command changes the screen layout.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

LARGe Enlarges the spectrogram result display and scales down the spectrum analyzer

result display.

SMALl Divides the screen in two equally sized panes.

Example

CALC:SPEC ON

Activates the Spectrogram Measurement option.

CALC:SPEC:SIZE LARG

Enlarges the spectrogram result display.

Characteristics

RST value: SMAL

SCPI: device–specific

Mode

SPECM

CALCulate Subsystem (SPECM, K14) R&S FSL

1300.2519.12 6.406 E-11

CALCulate<1|2>:SPECtrogram:TSTamp[:STATe]

This command activates or deactivates the time stamp.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

CALC:SPEC ON

Activates the Spectrogram Measurement option.

CALC:SPEC:TST ON

Activates the time stamp.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

SPECM

CALCulate<1|2>:SPECtrogram:TSTamp:DATA?

This command queries the time stamp of the frames. All available frame results are returned via

the TRACe<1|2>[:DATA]? command).

The numeric suffixes <1|2> are irrelevant for this command.

This command is only a query and therefore has no *RST value.

Parameter

CURRent Returns the time stamp of the current frame.

ALL Returns the time stamp of all frames sorted in a descending order, starting with

the current frame.

The return values consist of four values for each frame.

The first value is the date of the measurement in seconds that have passed since 01.01.1970 in

seconds. For a better resolution the second value shows the additional milliseconds. This value

is also displayed on screen.

These numbers are appropiate for relative uses, but you can also calculate the absolute date

and time as displayed on the screen.

The third and fourth value are reserved for future uses.

Example

CALC:SPEC ON

Activates the Spectrogram Measurement option.

CALC:SPEC:TST ON

Activates the time stamp.

CALC:SPEC:TST:DATA? ALL

Returns the time stamp of all frames sorted in a descending order.

Characteristics

RST value: –

SCPI: device–specific

Mode

SPECM

R&S FSL INITiate Subsystem (SPECM, K14)

1300.2519.12 6.407 E-11

INITiate Subsystem (SPECM, K14)

The INITiate subsystem is used to control the init–measurement function.

INITiate<1|2>:CONTinuous

This command starts a continuous sweep measurement or stops it and switches to single

sweep mode.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON Starts a continuous sweep measurement.

OFF Stops the continuous sweep measurement and switches to single sweep

mode.

Example

INIT:CONT OFF

Stops the continuous sweep measurement and switches to single sweep mode.

Characteristics

*RST value: ON

SCPI: conform

Mode

SPECM

MMEMory Subsystem (SPECM, K14) R&S FSL

1300.2519.12 6.408 E-11

MMEMory Subsystem (SPECM, K14)

The MMEMory (mass memory) subsystem provides commands which allow for access to the storage

media of the instrument and for storing and loading various instrument settings.

The commands of the base unit are described in the chapter MMEMory Subsystem.

Commands of the MMEMory Subsystem

–MMEMory:SELect[:ITEM]:SPECtrogram

MMEMory:SELect[:ITEM]:SPECtrogram

This command adds the spectrogram data to the list of data subsets of a save/recall device

setting.

Parameter

ON | OFF

Example

MMEM:SEL:SPEC ON

Adds the spectrogram data to the list of data subsets.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

SPECM

R&S FSL TRACe Subsystem (SPECM, K14)

1300.2519.12 6.409 E-11

TRACe Subsystem (SPECM, K14)

The TRACe subsystem controls access to the instruments internal trace memory.

Commands of the TRACe Subsystem

–TRACe<1|2>[:DATA]?

TRACe<1|2>[:DATA]?

Parameter

SPECtrogram

Additional to the parameters of the base unit, the SPECtrogram parameter queries all available

frame results.

Return values

All available frame results are returned. The frames are sorted according to their time stamp in

descending order (starting with the current frame). The time stamp of the frames is returned via

the CALCulate<1|2>:SPECtrogram:TSTamp:DATA command.

The returned values are scaled in the current level unit.

FORMat REAL,32 is used as format for binary transmission, and FORMat ASCii for ASCII

transmission. For details on formats refer to "Formats for returned values: ASCII format and

binary format" on page 6.300.

For further details refer to "TRACe<1|2>[:DATA]" on page 6.263.

Remote Commands of the Cable TV Measurements Option (K20) R&S FSL

1300.2519.12 6.410 E-11

Remote Commands of the Cable TV Measurements

Option (K20)

This section describes the remote commands for the Cable TV Measurement option (K20). The

abbreviation CATV stands for the Cable TV operating mode. For details on conventions used in this

chapter refer to section "Notation" on page 6.2 at the beginning of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in "Remote Commands of the Base Unit" on page 6.5.

This option is available from firmware version 1.30.

Subsystems of the Cable TV Analyzer option (K20)

–"ABORt Subsystem (CATV, K20)" on page 6.411

–"CALCulate Subsystem (CATV, K20)" on page 6.412

–"CONFigure Subsystem (CATV, K20)" on page 6.469

–"DISPlay Subsystem (CATV, K20)" on page 6.474

–"FORMat Subsystem (CATV, K20)" on page 6.479

– "INITiate Subsystem (CATV, K20)" on page 6.480

–"INPut Subsystem (CATV, K20)" on page 6.481

–"INSTrument Subsystem (CATV, K20)" on page 6.482

–"MMEMory Subsystem (CATV, K20)" on page 6.483

–"SENSe Subsystem (CATV, K20)" on page 6.484

–"SETup:TV Subsystem (CATV, K20)" on page 6.509

–"SOURce Subsystem (CATV, K20)" on page 6.511

–"STATus Subsystem (CATV, K20)" on page 6.512

–"TRACe Subsystem (CATV, K20)" on page 6.516

–"TRIGger Subsystem (CATV, K20)" on page 6.517

–"UNIT Subsystem (CATV, K20)" on page 6.520

R&S FSL ABORt Subsystem (CATV, K20)

1300.2519.12 6.411 E-11

ABORt Subsystem (CATV, K20)

The ABORt subsystem contains the commands for aborting triggered actions.

Commands of the ABORt Subsystem

–ABORt

ABORt

For details refer to "ABORt" on page 6.10.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.412 E-11

CALCulate Subsystem (CATV, K20)

The CALCulate subsystem contains commands for converting instrument data, transforming and

carrying out corrections. These functions are carried out subsequent to data acquisition, i.e. following

the SENSe subsystem.

The following subsystems are included:

•"CALCulate:ATV Subsystem (CATV, K20)" on page 6.412

•"CALCulate:DELTamarker Subsystem (CATV, K20)" on page 6.439

•"CALCulate:DTV Subsystem (CATV, K20)" on page 6.441

•"CALCulate:MARKer Subsystem (CATV, K20)" on page 6.464

•"CALCulate:STATistics Subsystem (CATV, K20)" on page 6.467

•"CALCulate:UNIT Subsystem (CATV, K20)" on page 6.468

CALCulate:ATV Subsystem (CATV, K20)

The CALCulate:ATV subsystem contains commands to analyze the analog TV measurement data.

The following subsystems are included:

•"CALCulate:ATV:LIMit Subsystem (CATV, K20)" on page 6.413

•"CALCulate:ATV:RESult Subsystem (CATV, K20)" on page 6.434

•"CALCulate:ATV:UNIT:POWer Subsystem (CATV, K20)" on page 6.438

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.413 E-11

CALCulate:ATV:LIMit Subsystem (CATV, K20)

The CALCulate:ATV:LIMit subsystem sets and checks the measurement limits for analog TV

measurements.

The following subsystem is included:

•"CALCulate:ATV:LIMit:RESult Subsystem (CATV, K20)" on page 6.423

Commands of the CALCulate:ATV:LIMit Subsystem

–CALCulate<1|2>:ATV:LIMit:CARRiers:S1IFoffset:LOWer

–CALCulate<1|2>:ATV:LIMit:CARRiers:S1IFoffset:UPPer

–CALCulate<1|2>:ATV:LIMit:CARRiers:S1PRelative:LOWer

–CALCulate<1|2>:ATV:LIMit:CARRiers:S1PRelative:UPPer

–CALCulate<1|2>:ATV:LIMit:CARRiers:S2IFoffset:LOWer

–CALCulate<1|2>:ATV:LIMit:CARRiers:S2IFoffset:UPPer

–CALCulate<1|2>:ATV:LIMit:CARRiers:S2PRelative:LOWer

–CALCulate<1|2>:ATV:LIMit:CARRiers:S2PRelative:UPPer

–CALCulate<1|2>:ATV:LIMit:CARRiers:VCFoffset:LOWer

–CALCulate<1|2>:ATV:LIMit:CARRiers:VCFoffset:UPPer

–CALCulate<1|2>:ATV:LIMit:CARRiers:VCPabsolute:LOWer

–CALCulate<1|2>:ATV:LIMit:CARRiers:VCPabsolute:UPPer

–CALCulate<1|2>:ATV:LIMit:CN:CN[:LOWer]

–CALCulate<1|2>:ATV:LIMit:CSO:CSO[:LOWer]

–CALCulate<1|2>:ATV:LIMit:CTB:CTB[:LOWer]

–CALCulate<1|2>:ATV:LIMit:HUM:HUM:LOWer

–CALCulate<1|2>:ATV:LIMit:HUM:HUM:UPPer

–CALCulate<1|2>:ATV:LIMit:VMODulation:MDEPth:LOWer

–CALCulate<1|2>:ATV:LIMit:VMODulation:MDEPth:UPPer

–CALCulate<1|2>:ATV:LIMit:VMODulation:RPC:LOWer

–CALCulate<1|2>:ATV:LIMit:VMODulation:RPC:UPPer

–CALCulate<1|2>:ATV:LIMit:VMODulation:VCPower:LOWer

–CALCulate<1|2>:ATV:LIMit:VMODulation:VCPower:UPPer

CALCulate<1|2>:ATV:LIMit:CARRiers:S1IFoffset:LOWer

This command defines the lower frequency offset limit of the sound carrier 1.

The numeric suffixes <1|2> are irrelevant.

Parameter

–999,999 to 999,999 Hz

Example

CALC:ATV:LIM:CARR:S1IF:LOW 1KHZ

Sets the lower frequency offset limit for sound carrier 1 to 1 kHz.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.414 E-11

Characteristics

RST value: –10 kHz

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:CARRiers:S1IFoffset:UPPer

This command defines the upper frequency offset limit of the sound carrier 1.

The numeric suffixes <1|2> are irrelevant.

Parameter

–999,999 to 999,999 Hz

Example

CALC:ATV:LIM:CARR:S1IF:UPP 10KHZ

Sets the upper frequency offset limit for sound carrier 1 to 10 kHz.

Characteristics

RST value: 10 kHz

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:CARRiers:S1PRelative:LOWer

This command defines the relative lower power limit of the sound carrier 1.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

CALC:ATV:LIM:CARR:S1PR:LOW –10

Sets the relative lower power limit for sound carrier 1 to –10 dB.

Characteristics

RST value: –20 dB

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.415 E-11

CALCulate<1|2>:ATV:LIMit:CARRiers:S1PRelative:UPPer

This command defines the relative upper power limit of the sound carrier 1.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

CALC:ATV:LIM:CARR:S1PR:UPP 20

Sets the relative lower power limit for sound carrier 1 to 20 dB.

Characteristics

RST value: –6 dB

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:CARRiers:S2IFoffset:LOWer

This command defines the lower frequency offset limit of the sound carrier 2.

The numeric suffixes <1|2> are irrelevant.

Parameter

–999,999 to 999,999 Hz

Example

CALC:ATV:LIM:CARR:S2IF:LOW 1KHZ

Sets the lower frequency offset limit for sound carrier 2 to 1 kHz.

Characteristics

RST value: –10 kHz

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:CARRiers:S2IFoffset:UPPer

This command defines the upper frequency offset limit of the sound carrier 2.

The numeric suffixes <1|2> are irrelevant.

Parameter

–999,999 to 999,999 Hz

Example

CALC:ATV:LIM:CARR:S2IF:UPP 500000HZ

Sets the upper frequency offset limit for sound carrier 2 to 500 kHz.

Characteristics

RST value: 10 kHz

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.416 E-11

CALCulate<1|2>:ATV:LIMit:CARRiers:S2PRelative:LOWer

This command defines the relative lower power limit of the sound carrier 2.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

CALC:ATV:LIM:CARR:S2PR:LOW –20

Sets the relative lower power limit for sound carrier 2 to –20 dB.

Characteristics

RST value: –27 dB

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:CARRiers:S2PRelative:UPPer

This command defines the relative upper power limit of the sound carrier 2.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

CALC:ATV:LIM:CARR:S2PR:UPP –14

Sets the relative lower power limit for sound carrier 2 to –14 dB.

Characteristics

RST value: –13 dB

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:CARRiers:VCFoffset:LOWer

This command defines the lower frequency offset limit of the vision carrier.

The numeric suffixes <1|2> are irrelevant.

Parameter

–999,999 to 999,999 Hz

Example

CALC:ATV:LIM:CARR:VCF:LOW –1KHZ

Sets the lower frequency offset limit of the vision carrier to –1 kHz.

Characteristics

RST value: –10 kHz

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.417 E-11

CALCulate<1|2>:ATV:LIMit:CARRiers:VCFoffset:UPPer

This command defines the upper frequency offset limit of the vision carrier.

The numeric suffixes <1|2> are irrelevant.

Parameter

–999,999 to 999,999 Hz

Example

CALC:ATV:LIM:CARR:VCF:UPP 1KHZ

Sets the upper frequency offset limit of the vision carrier to 1 kHz.

Characteristics

RST value: 10 kHz

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:CARRiers:VCPabsolute:LOWer

This command defines the absolute lower limit for the vision carrier.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

CALC:ATV:LIM:CARR:VCP:LOW –40

Sets the absolute lower limit of the vision carrier to –40 dBm.

Characteristics

RST value: –60 dBm

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:CARRiers:VCPabsolute:UPPer

This command defines the absolute upper limit for the vision carrier.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

CALC:ATV:LIM:CARR:VCP:UPP –20

Sets the absolute lower limit of the vision carrier to –20 dBm.

Characteristics

RST value: –30 dBm

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.418 E-11

CALCulate<1|2>:ATV:LIMit:CN:CN[:LOWer]

This command defines the lower limit for the carrier–to–noise ratio.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

CALC:ATV:LIM:CN:CN 10

Sets the lower limit of the carrier–to–noise ratio to 10 dB.

Characteristics

RST value: 40 dB

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:CSO:CSO[:LOWer]

This command defines the lower limit for the carrier–to–second order beat ratio.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

CALC:ATV:LIM:CSO:CSO 10

Sets the lower limit of the carrier–to–second order beat ratio to 10 dB.

Characteristics

RST value: 0 dB

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:CTB:CTB[:LOWer]

This command defines the lower limit for the carrier–to–composite triple beat ratio.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

CALC:ATV:LIM:CTB:CTB 10

Sets the lower limit of the carrier–to–second order beat ratio to 10 dB.

Characteristics

RST value: 0 dB

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.419 E-11

CALCulate<1|2>:ATV:LIMit:HUM:HUM:LOWer

This command defines the lower limit for the hum values in dB. If the wrong unit is set, the

command produces an execution error. The unit is set via the

CALCulate<1|2>:ATV:UNIT:POWer:HUM command.

The numeric suffixes <1|2> are irrelevant.

Parameter

–60 to 60 dB

Example

CALC:ATV:UNIT:POW:HUM DB

Sets the unit for the Hum measurement values to dB.

CALC:ATV:LIM:HUM:HUM:LOW 10

Sets the lower limit for the hum values to 10 dB.

Characteristics

RST value: 40 dB

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:HUM:HUM:UPPer

This command defines the upper limit for the hum values in %. If the wrong unit is set, the

command produces an execution error. The unit is set via the

CALCulate<1|2>:ATV:UNIT:POWer:HUM command.

The numeric suffixes <1|2> are irrelevant.

Parameter

0.1 to 100.000%

Example

CALC:ATV:UNIT:POW:HUM PCT

Sets the unit for the Hum measurement values to percent.

CALC:ATV:LIM:HUM:HUM:UPP 6

Sets the upper limit of the hum values to 6%.

Characteristics

RST value: 1%

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.420 E-11

CALCulate<1|2>:ATV:LIMit:VMODulation:MDEPth:LOWer

This command defines the lower modulation depth limit for the vision modulation.

The numeric suffixes <1|2> are irrelevant.

Parameter

0to 100%

Example

CALC:ATV:LIM:VMOD:MDEP:LOW 0.5

Sets the lower modulation depth limit of the vision modulation to 0.5%.

Characteristics

RST value: 0%

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:VMODulation:MDEPth:UPPer

This command defines the upper modulation depth limit for the vision modulation.

The numeric suffixes <1|2> are irrelevant.

Parameter

0to 100%

Example

CALC:ATV:LIM:VMOD:MDEP:UPP 30

Sets the upper modulation depth limit of the vision modulation to 30%.

Characteristics

RST value: 100%

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:VMODulation:RPC:LOWer

This command defines the lower limit for the residual picture in the Vision Modulation

measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

0to 100%

Example

CALC:ATV:LIM:VMOD:RPC:LOW 0.5

Sets the lower limit for the residual picture to 0.5%.

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.421 E-11

Characteristics

RST value: 0%

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:VMODulation:RPC:UPPer

This command defines the upper limit for the residual picture in the Vision Modulation

measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

0to 100%

Example

CALC:ATV:LIM:VMOD:RPC:UPP 80

Sets the upper limit for the residual picture to 80%.

Characteristics

RST value: 100%

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:VMODulation:VCPower:LOWer

This command defines the lower vision carrier power limit in the Vision Modulation

measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dBm

Example

CALC:ATV:LIM:VMOD:VCP:LOW –50

Sets the lower vision carrier power limit to –50 dBm.

Characteristics

RST value: –60 dBm

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.422 E-11

CALCulate<1|2>:ATV:LIMit:VMODulation:VCPower:UPPer

This command defines the upper vision carrier power limit in the Vision Modulation

measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dBm

Example

CALC:ATV:LIM:VMOD:VCP:UPP 20

Sets the upper vision carrier power limit to 20 dBm.

Characteristics

RST value: 30 dBm

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.423 E-11

CALCulate:ATV:LIMit:RESult Subsystem (CATV, K20)

The CALCulate:ATV:LIMit:RESult subsystem checks the measurement limits for analog TV

measurements.

Commands of the CALCulate:ATV:LIMit:RESult Subsystem

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1IFoffset:LOWer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1IFoffset:UPPer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1PRelative:LOWer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1PRelative:UPPer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2IFoffset:LOWer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2IFoffset:UPPer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2PRelative:LOWer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2PRelative:UPPer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCFoffset:LOWer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCFoffset:UPPer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCPabsolute:LOWer?

–CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCPabsolute:UPPer?

–CALCulate<1|2>:ATV:LIMit:RESult:CN:CN[:LOWer]?

–CALCulate<1|2>:ATV:LIMit:RESult:CSO:CSO[:LOWer]?

–CALCulate<1|2>:ATV:LIMit:RESult:CTB:CTB[:LOWer]?

–CALCulate<1|2>:ATV:LIMit:RESult:HUM:HUM:LOWer?

–CALCulate<1|2>:ATV:LIMit:RESult:HUM:HUM:UPPer?

–CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:MDEPth:LOWer?

–CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:MDEPth:UPPer?

–CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:RPC:LOWer?

–CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:RPC:UPPer?

–CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:VCPower:LOWer?

–CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:VCPower:UPPer?

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1IFoffset:LOWer?

This command performs a lower limit check for the frequency offset of the sound carrier 1.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:S1IF:LOW 1KHZ

Sets the lower frequency offset limit for sound carrier 1 to 1 kHz.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CARR:S1IF:LOW?

Performs a lower limit check for the frequency offset of the sound carrier 1.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.424 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1IFoffset:UPPer?

This command performs an upper limit check for the frequency offset of the sound carrier 1.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:S1IF:UPP 10KHZ

Sets the upper frequency offset limit for sound carrier 1 to 10 kHz.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CARR:S1IF:UPP?

Performs an upper limit check for the frequency offset of the sound carrier 1.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1PRelative:LOWer?

This command performs a lower limit check for the relative power of the sound carrier 1.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:S1PR:LOW –10

Sets the relative lower power limit for sound carrier 1 to –10 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CARR:S1PR:LOW?

Performs a lower limit check for the relative power of the sound carrier 1.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.425 E-11

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1PRelative:UPPer?

This command performs an upper limit check for the relative power of the sound carrier 1.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:S1PR:UPP 20

Sets the relative lower power limit for sound carrier 1 to 20 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CARR:S1PR:UPP?

Performs an upper limit check for the relative power of the sound carrier 1.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2IFoffset:LOWer?

This command performs a lower limit check for the frequency offset of the sound carrier 2.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:S2IF:LOW 1KHZ

Sets the lower frequency offset limit for sound carrier 2 to 1 kHz.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CARR:S2IF:LOW?

Performs a lower limit check for the frequency offset of the sound carrier 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2IFoffset:UPPer?

This command performs an upper limit check for the frequency offset limit of the sound carrier 2.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:S2IF:UPP 500000HZ

Sets the upper frequency offset limit for sound carrier 2 to 500 kHz.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.426 E-11

CALC:ATV:LIM:RES:CARR:S2IF:UPP?

Performs an upper limit check for the frequency offset limit of the sound carrier 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2PRelative:LOWer?

This command performs a lower limit check for the relative power of the sound carrier 2.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:S2PR:LOW –20

Sets the relative lower power limit for sound carrier 2 to –20 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CARR:S2PR:LOW?

Performs a lower limit check for the relative power of the sound carrier 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2PRelative:UPPer?

This command performs an upper limit check for the relative power of the sound carrier 2.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:S2PR:UPP –14

Sets the relative lower power limit for sound carrier 2 to –14 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CARR:S2PR:UPP?

Performs an upper limit check for the relative power of the sound carrier 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.427 E-11

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCFoffset:LOWer?

This command performs a lower limit check for the frequency offset of the vision carrier.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:VCF:LOW –1KHZ

Sets the lower frequency offset limit of the vision carrier to –1 kHz.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CARR:VCF:LOW?

Performs a lower limit check for the frequency offset of the vision carrier.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCFoffset:UPPer?

This command performs an upper limit check for the frequency offset of the vision carrier.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:VCF:UPP 1KHZ

Sets the upper frequency offset limit of the vision carrier to 1 kHz.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CARR:VCF:UPP?

Performs an upper limit check for the frequency offset of the vision carrier.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCPabsolute:LOWer?

This command performs a lower limit check for the absolute vision carrier power.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:VCP:LOW –40

Sets the absolute lower limit of the vision carrier to –40 dBm.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.428 E-11

CALC:ATV:LIM:RES:CARR:VCP:LOW?

Performs a lower limit check for the absolute vision carrier power.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCPabsolute:UPPer?

This command performs an upper limit check for the absolute vision carrier power.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CARR:VCP:UPP –20

Sets the absolute lower limit of the vision carrier to –20 dBm.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CARR:VCP:UPP?

Performs an upper limit check for the absolute vision carrier power.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CN:CN[:LOWer]?

This command performs a lower limit check for the carrier–to–noise ratio.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CN:CN 10

Sets the lower limit of the carrier–to–noise ratio to 10 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CN:CN?

Performs a lower limit check for the carrier–to–noise ratio.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.429 E-11

CALCulate<1|2>:ATV:LIMit:RESult:CSO:CSO[:LOWer]?

This command performs a lower limit check for the carrier–to–second order beat ratio.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CSO:CSO 10

Sets the lower limit of the carrier–to–second order beat ratio to 10 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CSO:CSO?

Performs a lower limit check for the carrier–to–second order beat ratio.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:CTB:CTB[:LOWer]?

This command performs a lower limit check for the carrier–to–composite triple beat ratio.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:CTB:CTB 10

Sets the lower limit of the carrier–to–second order beat ratio to 10 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:CTB:CTB?

Performs a lower limit check for the carrier–to–composite triple beat ratio.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:HUM:HUM:LOWer?

This command performs a lower limit check for the Hum measurement.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:HUM:HUM:LOW 10

Sets the lower limit for the hum values to 10 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.430 E-11

CALC:ATV:LIM:RES:HUM:HUM:LOW?

Performs a lower limit check for the hum values.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:HUM:HUM:UPPer?

This command performs an upper limit check for the Hum measurement.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:HUM:HUM:UPP 6

Sets the upper limit of the hum values to 6%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:HUM:HUM:UPP?

Performs an upper limit check for the hum values.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:MDEPth:LOWer?

This command performs a lower limit check for the modulation depth of the Vision Modulation

measurement.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:VMOD:MDEP:LOW 0.5

Sets the lower modulation depth limit of the vision modulation to 0.5%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:VMOD:MDEP:LOW?

Performs a lower limit check for the modulation depth of the Vision Modulation measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.431 E-11

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:MDEPth:UPPer?

This command performs an upper limit check for the modulation depth of the Vision Modulation

measurement.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:VMOD:MDEP:UPP 30

Sets the upper modulation depth limit of the vision modulation to 30%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:VMOD:MDEP:UPP?

Performs an upper limit check for the modulation depth of the Vision Modulation measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:RPC:LOWer?

This command performs a lower limit check for the residual picture in the Vision Modulation

measurement.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:VMOD:RPC:LOW 0.5

Sets the lower limit for the residual picture to 75%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:VMOD:RPC:LOW?

Performs a lower limit check for the residual picture in the Vision Modulation measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.432 E-11

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:RPC:UPPer?

This command performs an upper limit check for the residual picture in the Vision Modulation

measurement.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:VMOD:RPC:UPP 80

Sets the upper limit for the residual picture to 80%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:VMOD:RPC:UPP?

Performs an upper limit check for the residual picture in the Vision Modulation measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:VCPower:LOWer?

This command performs a lower limit check for the vision carrier power in the Vision Modulation

measurement.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:VMOD:VCP:LOW –50

Sets the lower vision carrier power limit to 10 dBm.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:VMOD:VCP:LOW?

Performs a lower limit check for the vision carrier power in the Vision Modulation measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.433 E-11

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:VCPower:UPPer?

This command performs an upper limit check for the vision carrier power in the Vision

Modulation measurement.

The numeric suffixes <1|2> are irrelevant.

This command is a query and therefore has no *RST value.

Example

CALC:ATV:LIM:VMOD:VCP:UPP 20

Sets the upper vision carrier power limit to 20 dBm.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:LIM:RES:VMOD:VCP:UPP?

Performs an upper limit check for the vision carrier power in the Vision Modulation

measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.434 E-11

CALCulate:ATV:RESult Subsystem (CATV, K20)

The CALCulate:ATV:RESult subsystem displays the measurement results for analog TV

measurements.

Commands of the CALCulate:ATV:RESult Subsystem

–CALCulate<1|2>:ATV:RESult:CARRiers?

–CALCulate<1|2>:ATV:RESult:CN?

–CALCulate<1|2>:ATV:RESult:CSO?

–CALCulate<1|2>:ATV:RESult:CTB?

–CALCulate<1|2>:ATV:RESult:HUM?

–CALCulate<1|2>:ATV:RESult:VMODulation?

CALCulate<1|2>:ATV:RESult:CARRiers?

This command reads the measurement values (power, frequency) of the Carrier Power

measurements.

The numeric suffixes <1|2> are irrelevant.

This command is a query only and thus has no *RST value.

Parameter

VCPabsolute vision carrier power absolute

VCFoffset vision carrier frequency offset

S1PRelative sound carrier 1 power relative

S1IFoffset sound carrier 1 intercarrier frequency offset

S2PRelative sound carrier 2 power relative

S2IFoffset sound carrier 2 intercarrier frequency offset

ALL Results of all measurements above, separated by commas.

If a measurement result is not valid, a comma will be output only.

Example

CONF:ATV:MEAS CARR

Configures the analog TV Carrier Power measurement.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:RES:CARR? VCF

Reads the result of the vision carrier frequency offset parameter.

CALC:ATV:RES:CARR? ALL

Reads all measured values.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.435 E-11

CALCulate<1|2>:ATV:RESult:CN?

This command reads the measurement values of the Carrier–to–Noise Ratio measurements.

The numeric suffixes <1|2> are irrelevant.

This command is a query only and thus has no *RST value.

Parameter

RPOWer reference power

NRBW noise reference bandwidth

NFCorrection noise floor correction

MFRelative measurement frequency (relative)

CN carrier–to–noise ratio

ALL Results of all measurements above, separated by commas.

If a measurement result is not valid, a comma will be output only.

Example

CONF:ATV:MEAS CN

Configures the analog TV Carrier–to–Noise Ratio measurement.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:RES:CN? NFC

Reads the result of the noise floor correction measurement.

CALC:ATV:RES:CN? ALL

Reads all measured values.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:RESult:CSO?

This command reads the measurement values of the Carrier–to–Second Order Beat Ratio

measurements.

The numeric suffixes <1|2> are irrelevant.

This command is a query only and thus has no *RST value.

Parameter

RPOWer reference power

NFCorrection noise reference bandwidth

MFRelative measurement frequency relative

CSO carrier–to–second order beat ratio

ALL Results of all measurements above, separated by commas.

If a measurement result is not valid, a comma will be output only.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.436 E-11

Example

CONF:ATV:MEAS CSO

Configures the analog TV Carrier–to–Second Order Beat Ratio measurement.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:RES:CSO? RPOW

Reads the result of the reference power parameter.

CALC:ATV:RES:CSO? ALL

Reads all measured values.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:RESult:CTB?

This command reads the measurement values of the Carrier–to–Composite Triple Beat Ratio

measurements.

The numeric suffixes <1|2> are irrelevant.

This command is a query only and thus has no *RST value.

Parameter

RPOWer reference power

NFCorrection noise reference bandwidth

MFRelative measurement frequency relative

CTB carrier–to–composite triple beat ratio

ALL Results of all measurements above, separated by commas.

If a measurement result is not valid, a comma will be output only.

Example

CONF:ATV:MEAS CTB

Configures the analog TV Carrier–to–Composite Triple Beat Ratio measurement.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:RES:CTB? MFR

Reads the result of the relative measurement frequency parameter.

CALC:ATV:RES:CTB? ALL

Reads all measured values.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.437 E-11

CALCulate<1|2>:ATV:RESult:HUM?

This command reads the measurement values of the Hum measurement.

The numeric suffixes <1|2> are irrelevant.

This command is a query only and thus has no *RST value.

Example

CONF:ATV:MEAS HUM

Configures the analog TV Hum measurement.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:RES:HUM?

Reads the measured value.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:RESult:VMODulation?

This command reads the measurement values of the Vision Modulation measurements.

The numeric suffixes <1|2> are irrelevant.

This command is a query only and thus has no *RST value.

Parameter

VCPower vision carrier power

RPC residual picture carrier

MDEPth modulation depth

ALL Results of all measurements above, separated by commas.

If a measurement result is not valid, a comma will be output only.

Example

CONF:ATV:MEAS VMOD

Configures the analog TV Vision Modulation measurement.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:ATV:RES:VMOD? MDEP

Reads the result of the modulation depth parameter.

CALC:ATV:RES:VMOD? ALL

Reads all measured values.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.438 E-11

CALCulate:ATV:UNIT:POWer Subsystem (CATV, K20)

The CALCulate:ATV:UNIT:POWer subsystem sets the unit for the measurements for analog TV

measurements.

Commands of the CALCulate:ATV:UNIT:POWer Subsystem

–CALCulate<1|2>:ATV:UNIT:POWer:HUM

–CALCulate<1|2>:ATV:UNIT:POWer:VCPabsolute

CALCulate<1|2>:ATV:UNIT:POWer:HUM

This command defines the unit of the Hum measurement values.

The numeric suffixes <1|2> are irrelevant.

Parameter

DB | PCT

Example

CALC:ATV:UNIT:POW:HUM PCT

Sets the unit for the Hum measurement values to percent.

Characteristics

RST value: dB

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:ATV:UNIT:POWer:VCPabsolute

This command defines the unit of the absolute vision carrier power.

The numeric suffixes <1|2> are irrelevant.

Parameter

DB | PCT

Example

CALC:ATV:UNIT:POW:VCP DB

Sets the unit for the absolute vision carrier power to dB.

Characteristics

RST value: dBm

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.439 E-11

CALCulate:DELTamarker Subsystem (CATV, K20)

The CALCulate:DELTamarker subsystem controls the delta marker functions of the instrument.

Commands of the CALCulate:DELTamarker Subsystem

–CALCulate<1|2>:DELTamarker<1...4>[:STATe]

–CALCulate<1|2>:DELTamarker<1...4>:AOFF

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum:NEXT

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt

–CALCulate<1|2>:DELTamarker<1...4>:MINimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT

–CALCulate<1|2>:DELTamarker<1...4>:MINimum:NEXT

–CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt

–CALCulate<1|2>:DELTamarker<1...4>:MODE

–CALCulate<1|2>:DELTamarker<1...4>:TRACe

–CALCulate<1|2>:DELTamarker<1...4>:X

–CALCulate<1|2>:DELTamarker<1...4>:X:RELative?

–CALCulate<1|2>:DELTamarker<1...4>:Y?

CALCulate<1|2>:DELTamarker<1...4>[:STATe]

For details refer to "CALCulate<1|2>:DELTamarker<1...4>[:STATe]" on page 6.12.

CALCulate<1|2>:DELTamarker<1...4>:AOFF

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:AOFF" on page 6.13.

CALCulate<1|2>:DELTamarker<1...4>:MAXimum[:PEAK]

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MAXimum[:PEAK]" on page 6.17.

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT" on page 6.17.

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:NEXT

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MAXimum:NEXT" on page 6.17.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.440 E-11

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt" on page 6.18.

CALCulate<1|2>:DELTamarker<1...4>:MINimum[:PEAK]

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MINimum[:PEAK]" on page 6.18.

CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT" on page 6.19.

CALCulate<1|2>:DELTamarker<1...4>:MINimum:NEXT

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MINimum:NEXT" on page 6.19.

CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt" on page 6.19.

CALCulate<1|2>:DELTamarker<1...4>:MODE

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MODE" on page 6.20.

CALCulate<1|2>:DELTamarker<1...4>:TRACe

Parameter

1to 4

For further details refer to "CALCulate<1|2>:DELTamarker<1...4>:TRACe" on page 6.20.

CALCulate<1|2>:DELTamarker<1...4>:X

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:X" on page 6.21.

CALCulate<1|2>:DELTamarker<1...4>:X:RELative?

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:X:RELative?" on page 6.21.

CALCulate<1|2>:DELTamarker<1...4>:Y?

Parameter

<numeric_value> in DBM

For further details refer to "CALCulate<1|2>:DELTamarker<1...4>:Y?" on page 6.22.

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.441 E-11

CALCulate:DTV Subsystem (CATV, K20)

The CALCulate:DTV subsystem contains commands to analyze the digital TV measurement data.

The following subsystems are included:

•"CALCulate:DTV:LIMit Subsystem (CATV, K20)" on page 6.441

•"CALCulate:DTV:RESult Subsystem (CATV, K20)" on page 6.459

•"CALCulate:DTV:UNIT:POWer Subsystem (CATV, K20)" on page 6.461

CALCulate:DTV:LIMit Subsystem (CATV, K20)

The CALCulate:DTV:LIMit subsystem sets and checks the measurement limits for digital TV

measurements.

The following subsystem is included:

•"CALCulate:DTV:LIMit:RESult Subsystem (CATV, K20)" on page 6.450

Commands of the CALCulate:DTV:LIMit Subsystem

–CALCulate:DTV:LIMit:CFOFfset:LOWer

–CALCulate:DTV:LIMit:CFOFfset:UPPer

–CALCulate:DTV:LIMit:CHPower:UPPer

–CALCulate:DTV:LIMit:CHPower:LOWer

–CALCulate:DTV:LIMit:CSUPpression[:LOWer]

–CALCulate:DTV:LIMit:EVMPeak:LOWer

–CALCulate:DTV:LIMit:EVMPeak:UPPer

–CALCulate:DTV:LIMit:EVMRms:LOWer

–CALCulate:DTV:LIMit:EVMRms:UPPer

–CALCulate:DTV:LIMit:IMBalance:LOWer

–CALCulate:DTV:LIMit:IMBalance:UPPer

–CALCulate:DTV:LIMit:MERPeak:LOWer

–CALCulate:DTV:LIMit:MERPeak:UPPer

–CALCulate:DTV:LIMit:MERRms:LOWer

–CALCulate:DTV:LIMit:MERRms:UPPer

–CALCulate:DTV:LIMit:PJITter[:UPPer]

–CALCulate:DTV:LIMit:QERRor:LOWer

–CALCulate:DTV:LIMit:QERRor:UPPer

–CALCulate:DTV:LIMit:SROFfset:LOWer

–CALCulate:DTV:LIMit:SROFfset:UPPer

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.442 E-11

CALCulate:DTV:LIMit:CFOFfset:LOWer

This command defines the lower limit of the carrier frequency offset in the Overview

measurement.

Parameter

–99,999 to 99,999 Hz

Example

CALC:DTV:LIM:CFOF:LOW –10KHZ

Sets the lower limit for the carrier frequency offset to –10 kHz.

Characteristics

RST value: –30 kHz

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:CFOFfset:UPPer

This command defines the upper limit of the carrier frequency offset in the Overview

measurement.

Parameter

–99,999 to 99,999 Hz

Example

CALC:DTV:LIM:CFOF:UPP 20KHZ

Sets the upper limit for the carrier frequency offset to 20 kHz.

Characteristics

RST value: 30 kHz

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:CHPower:UPPer

This command defines the upper limit for the Channel Power measurement.

Parameter

–200 to 200 dBm

Example

CALC:DTV:LIM:CHP:UPP –18 DBM

Sets the upper limit for the Channel Power measurement to –18 dBm.

Characteristics

RST value: 30 dBm

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.443 E-11

CALCulate:DTV:LIMit:CHPower:LOWer

This command defines the lower limit for the Channel Power measurement.

Parameter

–200 to 200 dBm

Example

CALC:DTV:LIM:CHP:LOW –22 DBM

Sets the lower limit for the Channel Power measurement to –22 dBm.

Characteristics

RST value: –60 dBm

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:CSUPpression[:LOWer]

This command defines the lower limit of the carrier suppression in the Modulation Errors

measurement.

Parameter

0to 200 dB

Example

CALC:DTV:LIM:CSUP 30

Sets the lower limit for the carrier suppression to 30 dB.

Characteristics

RST value: 35 dB

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:EVMPeak:LOWer

This command defines the lower limit of the error vector magnitude peak in dB for the Overview

/Modulation Errors measurement. If the wrong unit is set, the command produces an execution

error. The unit is set via the CALCulate<1|2>:DTV:UNIT:POWer:EVMPeak command.

Parameter

0to 80 dB

Example

CALC:DTV:UNIT:POW:EVMP DB

Sets the unit for the error vector magnitude peak to dB.

CALC:DTV:LIM:EVMP:LOW 5

Sets the lower limit for the error vector magnitude peak to 5 dB.

Characteristics

RST value: 20.7 dB

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.444 E-11

CALCulate:DTV:LIMit:EVMPeak:UPPer

This command defines the upper limit of the error vector magnitude peak in % for the Overview /

Modulation Errors measurement. If the wrong unit is set, the command produces an execution

error. The unit is set via the CALCulate<1|2>:DTV:UNIT:POWer:EVMPeak command.

Parameter

0.01 to 100%

Example

CALC:DTV:UNIT:POW:EVMP PCT

Sets the unit for the error vector magnitude peak to %.

CALC:DTV:LIM:EVMP:UPP 1

Sets the upper limit for the error vector magnitude peak to 1%.

Characteristics

RST value: 22%

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:EVMRms:LOWer

This command defines the lower limit of the root mean square value of the error vector

magnitude in dB for the Overview / Modulation Errors measurement. If the wrong unit is set, the

command produces an execution error. The unit is set via the

CALCulate<1|2>:DTV:UNIT:POWer:EVMRms command.

Parameter

0to 80 dB

Example

CALC:DTV:UNIT:POW:EVMR dB

Sets the unit for the root mean square value of the error vector magnitude to dB.

CALC:DTV:LIM:EVMR:LOW 5

Sets the lower limit for the root mean square value of the error vector magnitude to 5 dB.

Characteristics

RST value: 27.1 dB

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:EVMRms:UPPer

This command defines the upper limit of the root mean square value of the error vector

magnitude in % for the Overview / Modulation Errors measurement. If the wrong unit is set, the

command produces an execution error. The unit is set via the

CALCulate<1|2>:DTV:UNIT:POWer:EVMRms command.

Parameter

0.01 to 100%

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.445 E-11

Example

CALC:DTV:UNIT:POW:EVMR PCT

Sets the unit for the root mean square value of the error vector magnitude to percent.

CALC:DTV:LIM:EVMR:UPP 2

Sets the upper limit for the root mean square value of the error vector magnitude to 2%.

Characteristics

RST value: 4.4%

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:IMBalance:LOWer

This command defines the lower limit of the I/Q amplitude imbalance value in the Modulation

Errors measurement.

Parameter

–100 to 100%

Example

CALC:DTV:LIM:IMB:LOW 7

Sets the lower limit for the I/Q amplitude imbalance value to 7%.

Characteristics

RST value: –2%

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:IMBalance:UPPer

This command defines the upper limit of the I/Q amplitude imbalance value in the Modulation

Errors measurement.

Parameter

–100 to 100%

Example

CALC:DTV:LIM:IMB:UPP 10

Sets the upper limit for the I/Q amplitude imbalance value to 10%.

Characteristics

RST value: 2%

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.446 E-11

CALCulate:DTV:LIMit:MERPeak:LOWer

This command defines the lower limit of the modulation error rate peak in dB for the Overview /

Modulation Errors measurement. If the wrong unit is set, the command produces an execution

error. The unit is set via the CALCulate<1|2>:DTV:UNIT:POWer:MERPeak command.

Parameter

0to 80 dB

Example

CALC:DTV:UNIT:POW:MERP DB

Sets the unit for the unit of the modulation error rate peak to dB.

CALC:DTV:LIM:MERP:LOW 15

Sets the lower limit for the modulation error rate peak to 15 dB.

Characteristics

RST value: 10 dB

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:MERPeak:UPPer

This command defines the upper limit of the modulation error rate peak in % for the Overview /

Modulation Errors measurement. If the wrong unit is set, the command produces an execution

error. The unit is set via the CALCulate<1|2>:DTV:UNIT:POWer:MERPeak command.

Parameter

0.01 to 100%

Example

CALC:DTV:UNIT:POW:MERP PCT

Sets the unit for the unit of the modulation error rate peak to percent.

CALC:DTV:LIM:MERP:UPP 20

Sets the upper limit for the modulation error rate peak to 20%.

Characteristics

RST value: 3.2%

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:MERRms:LOWer

This command defines the lower limit of the root mean square value of the modulation error rate

in dB for the Overview / Modulation Errors measurement. If the wrong unit is set, the command

produces an execution error. The unit is set via the

CALCulate<1|2>:DTV:UNIT:POWer:MERRms command.

Parameter

0to 80 dB

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.447 E-11

Example

CALC:DTV:UNIT:POW:MERR DB

Sets the unit for the root mean square value of the modulation error rate to dB.

CALC:DTV:LIM:MERR:LOW 20

Sets the lower limit for the root mean square value of the modulation error rate to 20 dB.

Characteristics

RST value: 24 dB

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:MERRms:UPPer

This command defines the upper limit of the root mean square value of the modulation error rate

in % for the Overview / Modulation Errors measurement. If the wrong unit is set, the command

produces an execution error. The unit is set via the

CALCulate<1|2>:DTV:UNIT:POWer:MERRms command.

Parameter

0.01 to 100%

Example

CALC:DTV:UNIT:POW:MERR PCT

Sets the unit for the root mean square value of the modulation error rate to %.

CALC:DTV:LIM:MERR:UPP 30

Sets the upper limit for the root mean square value of the modulation error rate to 30%.

Characteristics

RST value: 6.3%

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:PJITter[:UPPer]

This command defines the upper limit of the phase jitter (root mean square value of the phase

error) in the Modulation Errors measurement.

Parameter

0° to 180°

Example

CALC:DTV:LIM:PJIT 1

Sets the upper limit for the phase jitter to 1 deg.

Characteristics

RST value: 2 deg

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.448 E-11

CALCulate:DTV:LIMit:QERRor:LOWer

This command defines the lower limit of the quadrature error in the Modulation Errors

measurement.

Parameter

–180° to 180°

Example

CALC:DTV:LIM:QERR:LOW 10

Sets the lower limit for the quadrature error to 10 deg.

Characteristics

RST value: –2 deg

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:QERRor:UPPer

This command defines the upper limit of the quadrature error in the Modulation Errors

measurement.

Parameter

–180° to 180°

Example

CALC:DTV:LIM:QERR:UPP 20

Sets the upper limit for the quadrature error to 20 deg.

Characteristics

RST value: +2 deg

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:SROFfset:LOWer

This command defines the lower limit of the symbol rate offset in the Overview measurement.

Parameter

–99,999 to 99,999 symb/s

Example

CALC:DTV:LIM:SROF:LOW –5000

Sets the lower limit for the symbol rate offset to –5000 symb/s.

Characteristics

RST value: –10000 symb/s

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.449 E-11

CALCulate:DTV:LIMit:SROFfset:UPPer

This command defines the upper limit of the symbol rate offset in the Overview measurement.

Parameter

–99,999 to 99,999 symb/s

Example

CALC:DTV:LIM:SROF:UPP 1000

Sets the upper limit for the symbol rate offset to 1000 symb/s.

Characteristics

RST value: 10000 symb/s

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.450 E-11

CALCulate:DTV:LIMit:RESult Subsystem (CATV, K20)

The CALCulate:DTV:LIMit:RESult subsystem checks the measurement limits for digital TV

measurements.

Commands of the CALCulate:DTV:LIMit:RESult Subsystem

–CALCulate:DTV:LIMit:RESult:CFOFfset:LOWer?

–CALCulate:DTV:LIMit:RESult:CFOFfset:UPPer?

–CALCulate:DTV:LIMit:RESult:CHPower?

–CALCulate:DTV:LIMit:RESult:CSUPpression[:LOWer]?

–CALCulate:DTV:LIMit:RESult:EVMPeak:LOWer?

–CALCulate:DTV:LIMit:RESult:EVMPeak:UPPer?

–CALCulate:DTV:LIMit:RESult:EVMRms:LOWer?

–CALCulate:DTV:LIMit:RESult:EVMRms:UPPer?

–CALCulate:DTV:LIMit:RESult:IMBalance:LOWer?

–CALCulate:DTV:LIMit:RESult:IMBalance:UPPer?

–CALCulate:DTV:LIMit:RESult:MERPeak:LOWer?

–CALCulate:DTV:LIMit:RESult:MERPeak:UPPer?

–CALCulate:DTV:LIMit:RESult:MERRms:LOWer?

–CALCulate:DTV:LIMit:RESult:MERRms:UPPer?

–CALCulate:DTV:LIMit:RESult:PJITter[:UPPer]?

–CALCulate:DTV:LIMit:RESult:QERRor:LOWer?

–CALCulate:DTV:LIMit:RESult:QERRor:UPPer?

–CALCulate:DTV:LIMit:RESult:SROFfset:LOWer?

–CALCulate:DTV:LIMit:RESult:SROFfset:UPPer?

CALCulate:DTV:LIMit:RESult:CFOFfset:LOWer?

This command performs a lower limit check for the carrier frequency offset in the Overview

measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:CFOF:LOW –10KHZ

Sets the lower limit for the carrier frequency offset to –10 kHz.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:CFOF:LOW?

Performs a lower limit check for the carrier frequency offset.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.451 E-11

CALCulate:DTV:LIMit:RESult:CFOFfset:UPPer?

This command performs an upper limit check for the carrier frequency offset in the Overview

measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:CFOF:UPP 20KHZ

Sets the upper limit for the carrier frequency offset to 20 kHz.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:CFOF:UPP?

Performs an upper limit check for the carrier frequency offset.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:CHPower?

This command queries the result of the Channel Power measurement. Upper and lower limit

check can not be handled separately.

Example

CALC:DTV:LIM:CHP:UPP –18

Sets the upper limit for the Channel Power measurement to –18 dBm.

CALC:DTV:LIM:CHP:LOW –22

Sets the lower limit for the Channel Power measurement to –22 dBm.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:CHP?

Performs a limit check for the Channel Power measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:CSUPpression[:LOWer]?

This command performs a lower limit check for the lower limit of the carrier suppression in the

Modulation Errors measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:CSUP 30

Sets the lower limit for the carrier suppression to 30 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.452 E-11

CALC:DTV:LIM:RES:CSUP?

Performs a lower limit check for the lower limit of the carrier suppression.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:EVMPeak:LOWer?

This command performs an lower limit check for the error vector magnitude peak in the

Overview measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:EVMP:LOW 5DB

Sets the lower limit for the error vector magnitude peak to 5 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:EVMP:LOW?

Performs an lower limit check for the error vector magnitude peak.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:EVMPeak:UPPer?

This command performs an upper limit check for the error vector magnitude peak in the

Overview measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:EVMP:UPP 1PCT

Sets the upper limit for the error vector magnitude peak to 1%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:EVMP:UPP?

Performs an upper limit check for the error vector magnitude peak.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.453 E-11

CALCulate:DTV:LIMit:RESult:EVMRms:LOWer?

This command performs an lower limit check for the root mean square value of the error vector

magnitude in the Overview measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:EVMR:LOW 5DB

Sets the lower limit for the root mean square value of the error vector magnitude to 5 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:EVMR:LOW?

Performs an lower limit check for the root mean square value of the error vector magnitude.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:EVMRms:UPPer?

This command performs an upper limit check for the root mean square value of the error vector

magnitude in the Overview measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:EVMR:UPP 2PCT

Sets the upper limit for the root mean square value of the error vector magnitude to 2%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:EVMR:UPP?

Performs an upper limit check for the root mean square value of the error vector magnitude.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:IMBalance:LOWer?

This command performs a lower limit check for the I/Q amplitude imbalance value in the

Modulation Errors measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:IMB:LOW 7

Sets the lower limit for the I/Q amplitude imbalance value to 7%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:IMB:LOW?

Performs a lower limit check for the I/Q amplitude imbalance value.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.454 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:IMBalance:UPPer?

This command performs an upper limit check for the I/Q amplitude imbalance value in the

Modulation Errors measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:IMB:UPP 10

Sets the upper limit for the I/Q amplitude imbalance value to 10%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:IMB:UPP?

Performs an upper limit check for the I/Q amplitude imbalance value.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:MERPeak:LOWer?

This command performs a lower limit check for the modulation error rate peak in the Overview

measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:MERP:LOW 20

Sets the lower limit for the modulation error rate peak to 20 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:MERP:LOW?

Performs a lower limit check for the modulation error rate peak.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.455 E-11

CALCulate:DTV:LIMit:RESult:MERPeak:UPPer?

This command performs an upper limit check for the modulation error rate peak in the Overview

measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:MERP:UPP 20

Sets the upper limit for the modulation error rate peak to 20%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:MERP:UPP?

Performs an upper limit check for the modulation error rate peak.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:MERRms:LOWer?

This command performs a lower limit check for the root mean square value of the modulation

error rate in the Overview measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:MERR:LOW 30

Sets the lower limit for the root mean square value of the modulation error rate to 30 dB.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:MERR:LOW?

Performs a lower limit check for the root mean square value of the modulation error rate.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:MERRms:UPPer?

This command performs an upper limit check for the root mean square value of the modulation

error rate in the Overview measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:MERR:UPP 30

Sets the upper limit for the root mean square value of the modulation error rate to 30%.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.456 E-11

CALC:DTV:LIM:RES:MERR:UPP?

Performs an upper limit check for the root mean square value of the modulation error rate.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:PJITter[:UPPer]?

This command performs an upper limit check for the phase jitter in the Modulation Errors

measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:PJIT 1

Sets the upper limit for the phase jitter to 1 deg.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:PJIT?

Performs an upper limit check for the phase jitter.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:QERRor:LOWer?

This command performs a lower limit check for the quadrature error in the Modulation Errors

measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:QERR:LOW 10

Sets the lower limit for the quadrature error to 10 deg.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:QERR:LOW?

Performs a lower limit check for the quadrature error.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.457 E-11

CALCulate:DTV:LIMit:RESult:QERRor:UPPer?

This command performs an upper limit check for the quadrature error in the Modulation Errors

measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:QERR:UPP 20

Sets the upper limit for the quadrature error to 20 deg.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:QERR:UPP?

Performs an upper limit check for the quadrature error.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

CALCulate:DTV:LIMit:RESult:SROFfset:LOWer?

This command performs a lower limit check for the symbol rate offset in the Overview

measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:SROF:LOW –5000

Sets the lower limit for the symbol rate offset to –5000 symb/s.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:SROF:LOW?

Performs a lower limit check for the symbol rate offset.

Characteristics

RST value: –10000

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.458 E-11

CALCulate:DTV:LIMit:RESult:SROFfset:UPPer?

This command performs an upper limit check for the symbol rate offset in the Overview

measurement.

This command is a query and therefore has no *RST value.

Example

CALC:DTV:LIM:SROF:UPP 1000

Sets the upper limit for the symbol rate offset to 1000 symb/s.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:LIM:RES:SROF:UPP?

Performs an upper limit check for the symbol rate offset.

Characteristics

RST value: 10000

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.459 E-11

CALCulate:DTV:RESult Subsystem (CATV, K20)

The CALCulate:DTV:RESult subsystem displays the measurement results for digital TV measurements.

Commands of the CALCulate:DTV:RESult Subsystem

–CALCulate<1|2>:DTV:RESult?

CALCulate<1|2>:DTV:RESult?

This command reads the measurement values for the digital TV measurements.

The numeric suffixes <1|2> are irrelevant.

This command is a query only and thus has no *RST value.

Parameter

Spectrum SALower lower shoulder attenuation

SAUPper upper shoulder attenuation

Overview MERRms root mean square of the modulation error rate

MERPeak peak of the modulation error rate

EVMRms root mean square of the error vector magnitude

EVMPeak peak of the error vector magnitude

CFOFfset carrier frequency offset

SROFfset symbol rate offset

ALL Results of all measurements above, separated

by commas.

If a measurement result is not valid, a comma

will be output only.

Modulation

Errors

IMBalance amplitude imbalance

QERRor quadrature error

CSUPpression carrier suppression

PJITter phase jitter

ALL Results of all measurements above, separated

by commas.

If a measurement result is not valid, a comma

will be output only.

Example

CONF:DTV:MEAS MERR

Configures the digital TV Modulation Errors measurement.

INIT;*WAI

Starts a new measurement and waits for the sweep end.

CALC:DTV:RES? QERR

Reads the result (quadrature error) of the Modulation Errors measurement.

CALC:DTV:RES? ALL

Reads all measured values.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.460 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.461 E-11

CALCulate:DTV:UNIT:POWer Subsystem (CATV, K20)

The CALCulate:DTV:UNIT:POWer subsystem sets the unit for the measurements for digital TV

measurements.

Commands of the CALCulate:DTV:UNIT:POWer Subsystem

–CALCulate<1|2>:DTV:UNIT:POWer:EPATtern

–CALCulate<1|2>:DTV:UNIT:POWer:EVMPeak

–CALCulate<1|2>:DTV:UNIT:POWer:EVMRms

–CALCulate<1|2>:DTV:UNIT:POWer:MERPeak

–CALCulate<1|2>:DTV:UNIT:POWer:MERRms

CALCulate<1|2>:DTV:UNIT:POWer:EPATtern

This command defines the unit of the Echo Pattern measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

s | m

Example

CALC:DTV:UNIT:POW:EPAT M

Sets the unit for the Echo Pattern measurement to meters.

Characteristics

RST value: s (seconds)

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:DTV:UNIT:POWer:EVMPeak

This command defines the unit of the error vector magnitude peak in the Overview / Modulation

Errors measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

DB | PCT

Example

CALC:DTV:UNIT:POW:EVMP DB

Sets the unit for the error vector magnitude peak to dB.

Characteristics

RST value: % (PCT)

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.462 E-11

CALCulate<1|2>:DTV:UNIT:POWer:EVMRms

This command defines the unit of the root mean square value of the error vector magnitude in

the Overview / Modulation Errors measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

DB | PCT

Example

CALC:DTV:UNIT:POW:EVMR PCT

Sets the unit for the root mean square value of the error vector magnitude to percent.

Characteristics

RST value: dB

SCPI: device–specific

Mode

CATV

CALCulate<1|2>:DTV:UNIT:POWer:MERPeak

This command defines the unit of the modulation error rate peak in the Overview / Modulation

Errors measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

DB | PCT

Example

CALC:DTV:UNIT:POW:MERP PCT

Sets the unit for the unit of the modulation error rate peak to percent.

Characteristics

RST value: dB

SCPI: device–specific

Mode

CATV

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.463 E-11

CALCulate<1|2>:DTV:UNIT:POWer:MERRms

This command defines the unit of the root mean square value of the modulation error rate in the

Overview / Modulation Errors measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

DB | PCT

Example

CALC:DTV:UNIT:POW:MERR DB

Sets the unit for the root mean square value of the modulation error rate to dB.

Characteristics

RST value: % (PCT)

SCPI: device–specific

Mode

CATV

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.464 E-11

CALCulate:MARKer Subsystem (CATV, K20)

The CALCulate:MARKer subsystem checks the marker functions of the instrument.

The following subsystem is included:

•"CALCulate:MARKer:FUNCtion Subsystem (CATV, K20)" on page 6.466

Commands of the CALCulate:MARKer Subsystem

–CALCulate<1|2>:MARKer<1...4>[:STATe]

–CALCulate<1|2>:MARKer<1...4>:AOFF

–CALCulate<1|2>:MARKer<1...4>:LOEXclude

–CALCulate<1|2>:MARKer<1...4>:MAXimum[:PEAK]

–CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT

–CALCulate<1|2>:MARKer<1...4>:MAXimum:NEXT

–CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt

–CALCulate<1|2>:MARKer<1...4>:MINimum[:PEAK]

–CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT

–CALCulate<1|2>:MARKer<1...4>:MINimum:NEXT

–CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt

–CALCulate<1|2>:MARKer<1...4>:PEXCursion

–CALCulate<1|2>:MARKer<1...4>:TRACe

–CALCulate<1|2>:MARKer<1...4>:X

–CALCulate<1|2>:MARKer<1...4>:X:SLIMits:LEFT

–CALCulate<1|2>:MARKer<1...4>:X:SLIMits:RIGHT

–CALCulate<1|2>:MARKer<1...4>:X:SLIMits[:STATe]

–CALCulate<1|2>:MARKer<1...4>:Y?

–CALCulate<1|2>:MARKer<1...4>:Y:PERCent

CALCulate<1|2>:MARKer<1...4>[:STATe]

For details refer to "CALCulate<1|2>:MARKer<1...4>[:STATe]" on page 6.56.

CALCulate<1|2>:MARKer<1...4>:AOFF

For details refer to "CALCulate<1|2>:MARKer<1...4>:AOFF" on page 6.56.

CALCulate<1|2>:MARKer<1...4>:LOEXclude

For details refer to "CALCulate<1|2>:MARKer<1...4>:LOEXclude" on page 6.58.

CALCulate<1|2>:MARKer<1...4>:MAXimum[:PEAK]

For details refer to "CALCulate<1|2>:MARKer<1...4>:MAXimum[:PEAK]" on page 6.58.

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.465 E-11

CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT

For details refer to "CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT" on page 6.59.

CALCulate<1|2>:MARKer<1...4>:MAXimum:NEXT

For details refer to "CALCulate<1|2>:MARKer<1...4>:MAXimum:NEXT" on page 6.60.

CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt

For details refer to "CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt" on page 6.60.

CALCulate<1|2>:MARKer<1...4>:MINimum[:PEAK]

For details refer to "CALCulate<1|2>:MARKer<1...4>:MINimum[:PEAK]" on page 6.60.

CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT

For details refer to "CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT" on page 6.61.

CALCulate<1|2>:MARKer<1...4>:MINimum:NEXT

For details refer to "CALCulate<1|2>:MARKer<1...4>:MINimum:NEXT" on page 6.62.

CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt

For details refer to "CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt" on page 6.62.

CALCulate<1|2>:MARKer<1...4>:PEXCursion

For details refer to "CALCulate<1|2>:MARKer<1...4>:PEXCursion" on page 6.63.

CALCulate<1|2>:MARKer<1...4>:TRACe

Parameter

1to 4

For further details refer to "CALCulate<1|2>:MARKer<1...4>:TRACe" on page 6.63.

CALCulate<1|2>:MARKer<1...4>:X

For details refer to "CALCulate<1|2>:MARKer<1...4>:X" on page 6.64.

CALCulate<1|2>:MARKer<1...4>:X:SLIMits:LEFT

For details refer to "CALCulate<1|2>:MARKer<1...4>:X:SLIMits:LEFT" on page 6.65.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.466 E-11

CALCulate<1|2>:MARKer<1...4>:X:SLIMits:RIGHT

For details refer to "CALCulate<1|2>:MARKer<1...4>:X:SLIMits:RIGHT" on page 6.65.

CALCulate<1|2>:MARKer<1...4>:X:SLIMits[:STATe]

For details refer to "CALCulate<1|2>:MARKer<1...4>:X:SLIMits[:STATe]" on page 6.64.

CALCulate<1|2>:MARKer<1...4>:Y?

For details refer to "CALCulate<1|2>:MARKer<1...4>:Y?" on page 6.66.

CALCulate<1|2>:MARKer<1...4>:Y:PERCent

For details refer to "CALCulate<1|2>:MARKer<1...4>:Y:PERCent" on page 6.67.

CALCulate:MARKer:FUNCtion Subsystem (CATV, K20)

The CALCulate:MARKer:FUNCtion subsystem checks the marker functions in the instrument.

Commands of the CALCulate:MARKer:FUNCtion Subsystem

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:CENTer

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:REFerence

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CENTer

For details refer to "CALCulate<1|2>:MARKer<1...4>:FUNCtion:CENTer" on page 6.70.

CALCulate<1|2>:MARKer<1...4>:FUNCtion:REFerence

For details refer to "CALCulate<1|2>:MARKer<1...4>:FUNCtion:REFerence" on page 6.79.

R&S FSL CALCulate Subsystem (CATV, K20)

1300.2519.12 6.467 E-11

CALCulate:STATistics Subsystem (CATV, K20)

The CALCulate: STATistics subsystem defines the scaling for the APD and CCDF measurements.

Commands of the CALCulate: STATistics Subsystem

–CALCulate: STATistics:NSAMples

–CALCulate:STATistics:PRESet

–CALCulate:STATistics:RESult<1...4>?

–CALCulate:STATistics:SCALe:AUTO

–CALCulate:STATistics:SCALe:X:RANGe

–CALCulate:STATistics:SCALe:X:RLEVel

–CALCulate:STATistics:SCALe:Y:LOWer

–CALCulate:STATistics:SCALe:Y:UPPer

CALCulate: STATistics:NSAMples

For details refer to "CALCulate:STATistics:NSAMples" on page 6.113.

CALCulate:STATistics:PRESet

For details refer to "CALCulate:STATistics:PRESet" on page 6.113.

CALCulate:STATistics:RESult<1...4>?

For details refer to "CALCulate:STATistics:RESult<1...6>?" on page 6.114.

CALCulate:STATistics:SCALe:AUTO

For details refer to "CALCulate:STATistics:SCALe:AUTO" on page 6.114.

CALCulate:STATistics:SCALe:X:RANGe

For details refer to "CALCulate:STATistics:SCALe:X:RANGe" on page 6.115.

CALCulate:STATistics:SCALe:X:RLEVel

For details refer to "CALCulate:STATistics:SCALe:X:RLEVel" on page 6.115.

CALCulate:STATistics:SCALe:Y:LOWer

For details refer to "CALCulate:STATistics:SCALe:Y:LOWer" on page 6.115.

CALCulate:STATistics:SCALe:Y:UPPer

For details refer to "CALCulate:STATistics:SCALe:Y:UPPer" on page 6.116.

CALCulate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.468 E-11

CALCulate:UNIT Subsystem (CATV, K20)

The CALCulate:UNIT subsystem defines the units for the parameters that can be set and the

measurement results.

Commands of the CALCulate:UNIT Subsystem

–CALCulate<1|2>:UNIT:POWer

CALCulate<1|2>:UNIT:POWer

This command selects the unit for power.

The numeric suffixes <1|2> are irrelevant.

Parameter

Example

CALC:UNIT:POW V

Sets the unit to Volt.

Characteristics

RST value: dBm

SCPI: device–specific

Mode

CATV

R&S FSL CONFigure Subsystem (CATV, K20)

1300.2519.12 6.469 E-11

CONFigure Subsystem (CATV, K20)

The CONFigure subsystem contains commands for configuring complex measurement tasks.

The following subsystems are included:

•"CONFigure:ATV Subsystem (CATV, K20)" on page 6.469

•"CONFigure:DTV Subsystem (CATV, K20)" on page 6.472

•"CONFigure:TV Subsystem (CATV, K20)" on page 6.473

CONFigure:ATV Subsystem (CATV, K20)

The CONFigure:ATV subsystem contains commands to configure analog TV measurements.

Commands of the CONFigure:ATV Subsystem

–CONFigure:ATV:CN:MEASurement

–CONFigure:ATV:CSO:MEASurement

–CONFigure:ATV:CTB:MEASurement

–CONFigure:ATV:MEASurement

CONFigure:ATV:CN:MEASurement

This command configures a new carrier or noise measurement with the next sweep for the

Carrier–to–Noise Ratio measurement.

Parameter

CARRier | NOISe

Example

CONF:ATV:MEAS CN

Configures the analog TV Carrier–to–Noise Ratio measurement.

ATV:CN:MEAS:MODE OSER

Sets the Off–Service measurement method.

CONF:ATV:CN:MEAS CARR

Configures a new carrier measurement with the next sweep.

INIT;*OPC

Starts the new noise measurement.

Characteristics

RST value: CARRier

SCPI: device–specific

Mode

CATV

CONFigure Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.470 E-11

CONFigure:ATV:CSO:MEASurement

This command configures a new carrier or noise measurement with the next sweep for the

Carrier–to–Second Order Beat Ratio measurement.

Parameter

CARRier | NOISe

Example

CONF:ATV:MEAS CSO

Configures the analog TV Carrier–to–Second Order Beat Ratio measurement.

ATV:CSO:MEAS:MODE OSER

Sets the Off–Service measurement method.

CONF:ATV:CSO:MEAS CARR

Configures a new carrier measurement with the next sweep.

INIT;*OPC

Starts the new noise measurement.

Characteristics

RST value: CARRier

SCPI: device–specific

Mode

CATV

CONFigure:ATV:CTB:MEASurement

This command configures a new carrier or noise measurement with the next sweep for the

Carrier–to–Composite Triple Beat Ratio measurement.

Parameter

CARRier | NOISe

Example

CONF:ATV:MEAS CTB

Configures the analog TV Carrier–to–Composite Triple Beat Ratio measurement.

ATV:CTB:MEAS:MODE OSER

Sets the Off–Service measurement method.

CONF:ATV:CTB:MEAS CARR

Configures a new carrier measurement with the next sweep.

INIT;*OPC

Starts the new noise measurement.

Characteristics

RST value: CARRier

SCPI: device–specific

Mode

CATV

R&S FSL CONFigure Subsystem (CATV, K20)

1300.2519.12 6.471 E-11

CONFigure:ATV:MEASurement

This command defines the analog measurement type.

Parameter

ASPectrum Spectrum measurement

CARRiers Carrier Power measurement

CN Carrier–to–Noise Ratio measurement

HUM Hum measurement

VMODulation Vision Modulation measurement

CTB Carrier–to–Composite Triple Beat Ratio measurement

CSO Carrier–to–Second Order Beat Ratio measurement

VSCope Video Scope measurement

Example

CONF:ATV:MEAS CARR

Configures the R&S FSL to measure the carrier power.

Characteristics

RST value: ASPectrum

SCPI: device–specific

Mode

CATV

CONFigure Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.472 E-11

CONFigure:DTV Subsystem (CATV, K20)

The CONFigure:DTV subsystem contains commands to configure digital TV measurements.

Commands of the CONFigure:DTV:MEASurement Subsystem

–CONFigure:DTV:MEASurement

–CONFigure:DTV:MEASurement:SATTenuation

CONFigure:DTV:MEASurement

This command defines the digital measurement type.

Parameter

DSPectrum Spectrum measurement

CHPower Channel Power measurement

CONS Constellation Diagram measurement

MERRors Modulation Errors measurement

EPATtern Echo Pattern measurement

APD Amplitude Probability Density Function measurement

CCDF Complementary Cumulative Distribution Function measurement

OVERview Overview measurement

Example

CONF:DTV:MEAS APD

Configures the R&S FSL to measure the amplitude probability density function.

Characteristics

RST value: DSP

SCPI: device–specific

Mode

CATV

CONFigure:DTV:MEASurement:SATTenuation

This command activates or deactivates the shoulder measurement in accordance to

ETSI TR 101290 standard.

Parameter

ON | OFF

Example

CONF:DTV:MEAS:SATT OFF

Configures the R&S FSL to measure the upper and lower shoulder attenuation.

Characteristics

RST value: ON

SCPI: device–specific

Mode

CATV

R&S FSL CONFigure Subsystem (CATV, K20)

1300.2519.12 6.473 E-11

CONFigure:TV Subsystem (CATV, K20)

The CONFigure:TV subsystem contains commands to configure TV Analyzer measurements.

Commands of the CONFigure:TV Subsystem

–CONFigure:TV:CTABle:SELect

–CONFigure:TV:MEASurement

CONFigure:TV:CTABle:SELect

This command activates the selected channel table.

Parameter

<file_name>, max. 45 characters

Example

CONF:TV:CTAB:SEL 'TV–ITALY'

Activates the channel table TV–ITALY.

Characteristics

RST value: <none>

SCPI: device–specific

Mode

CATV

CONFigure:TV:MEASurement

This command defines the TV Analyzer measurement type.

Parameter

TILT (Tilt measurement)

Example

CONF:TV:MEAS TILT

Configures the R&S FSL to measure the channel power of every channel.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

DISPlay Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.474 E-11

DISPlay Subsystem (CATV, K20)

The DISPLay subsystem controls the selection and presentation of textual and graphic information as

well as of measurement data on the display.

Commands of the DISPlay Subsystem

–DISPlay[:WINDow<1|2>]:TRACe<1...4>[:STATe]

–DISPlay[:WINDow<1|2>]:TRACe<1...4>:MODE

–DISPlay[:WINDow<1|2>]:TRACe<1...4>:MODE:FREeze[:STATe]

–DISPlay[:WINDow<1|2>]:TRACe<1...4>:MODE:HCONtinuous

–DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]

–DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:AUTO

–DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:MODE

–DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:RLEVel

–DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:RLEVel:OFFSet

–DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:RPOSition

–DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y:SPACing

–DISPlay[:WINDow<1|2>]:ZOOM:EPATtern

–DISPlay[:WINDow<1|2>]:ZOOM:EPATtern:STATe

–DISPlay[:WINDow<1|2>]:ZOOM:MERRors

–DISPlay[:WINDow<1|2>]:ZOOM:OVERview

–DISPlay[:WINDow<1|2>]:ZOOM:QUADrant

DISPlay[:WINDow<1|2>]:TRACe<1...4>[:STATe]

The numeric suffixes <1...4> select the trace.

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>[:STATe]" on page 6.132.

DISPlay[:WINDow<1|2>]:TRACe<1...4>:MODE

The numeric suffixes <1...4> select the trace.

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE" on page 6.132.

DISPlay[:WINDow<1|2>]:TRACe<1...4>:MODE:FREeze[:STATe]

This command sets the display mode of the constallation diagram.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON The constellation diagram is displayed unchanged, while the I/Q samples are

collected in the background.

OFF The constellation diagram is displayed on basis of the current I/Q samples and, in

continuous sweep mode, is updated with every measurement.

R&S FSL DISPlay Subsystem (CATV, K20)

1300.2519.12 6.475 E-11

Example

CONF:DTV:MEAS CONS

Configures the R&S FSL for the Constellation Diagram measurement.

DISP:TRAC1:MODE:FRE ON

Sets the display mode of the constallation diagram to on.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

CATV

DISPlay[:WINDow<1|2>]:TRACe<1...4>:MODE:HCONtinuous

The numeric suffixes <1...4> select the trace.

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE:HCONtinuous" on

page 6.133..

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]

The numeric suffixes <1...4> select the trace.

For details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]" on page 6.134.

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:AUTO

This command activates the automatic scaling for the Hum and Tilt measurement. If activated,

the scaling is automatically optimized to the best display of data. This rescaling may affect the

values of any of the parameters under the SCALe node.

The numeric suffixes <1|2> and <1...4> are irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

DISP:TRAC:Y:AUTO

Activates the automatic scaling for the Hum measurement.

Characteristics

RST value: –

SCPI: conform

Mode

CATV

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:MODE

The numeric suffixes <1...4> select the trace.

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:MODE" on page

6.135.

DISPlay Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.476 E-11

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:RLEVel

The numeric suffixes <1...4> select the trace.

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel" on page

6.135.

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:RLEVel:OFFSet

The numeric suffixes <1...4> select the trace.

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel:OFFSet"

on page 6.135.

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:RPOSition

The numeric suffixes <1...4> select the trace.

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

(models with tracking generator)" on page 6.136.

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y:SPACing

The numeric suffixes <1...4> select the trace.

Parameter

LINear | LOGarithmic

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y:SPACing" on page 6.134.

DISPlay[:WINDow<1|2>]:ZOOM:EPATtern

This command sets the zoom factor for the Echo Pattern measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

1to 20

Example

CONF:DTV:MEAS EPAT

Configures the R&S FSL for the Echo Pattern measurement.

DISP:ZOOM:EPAT 2

Sets the zoom factor for the Echo Pattern measurement.

Characteristics

RST value: 1

SCPI: device–specific

Mode

CATV

R&S FSL DISPlay Subsystem (CATV, K20)

1300.2519.12 6.477 E-11

DISPlay[:WINDow<1|2>]:ZOOM:EPATtern:STATe

This command activates or deactivates the zoom on around 0 Usfor the Echo Pattern

measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

CONF:DTV:MEAS EPAT

Configures the R&S FSL for the Echo Pattern measurement.

DISP:ZOOM:EPAT:STAT ON

Switches on the zoom for the Echo Pattern measurement.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

CATV

DISPlay[:WINDow<1|2>]:ZOOM:MERRors

This command sets the zoom for the Modulation Errors measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

NONE The whole result table is displayed.

<parameter> The result table of the selected parameter is displayed.

with parameter = IMBalance | QERRor | SUPpression | PJITter | MERRms

| MERPeak | EVMRms | EVMPeak

Example

CONF:DTV:MEAS MERR

Configures the R&S FSL for the Modulation Errors measurement.

DISP:ZOOM:MERR MERP

Displays the measurement results of the peak of the modulation error rate.

Characteristics

RST value: NONE

SCPI: device–specific

Mode

CATV

DISPlay Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.478 E-11

DISPlay[:WINDow<1|2>]:ZOOM:OVERview

This command sets the zoom for the Overview measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

NONE The whole result table is displayed.

<parameter> The result table of the selected parameter is displayed.

with parameter = MERRms | MERPeak | EVMRms | EVMPeak | CFOFfset

|SROFfset

Example

CONF:DTV:MEAS MERR

Configures the R&S FSL for the Modulation Errors measurement.

DISP:ZOOM:OVER MERP

Displays the measurement results of the peak of the modulation error rate.

Characteristics

RST value: NONE

SCPI: device–specific

Mode

CATV

DISPlay[:WINDow<1|2>]:ZOOM:QUADrant

This command sets the zoom for the constellation diagram.

The numeric suffixes <1|2> are irrelevant.

Parameter

NONE The whole constellation diagram is displayed.

1 | 2 | 3 | 4 The selected quadrant is displayed.

Example

CONF:DTV:MEAS CONS

Configures the R&S FSL for the Constellation Diagram measurement.

DISP:ZOOM:QUAD 1

Display the first quadrant of the constallation diagram.

Characteristics

RST value: NONE

SCPI: device–specific

Mode

CATV

R&S FSL FORMat Subsystem (CATV, K20)

1300.2519.12 6.479 E-11

FORMat Subsystem (CATV, K20)

The FORMat subsystem specifies the data format of the data transmitted from and to the instrument.

Commands of the FORMat Subsystem

–FORMat[:DATA]

–FORMat:DEXPort:DSEParator

FORMat[:DATA]

For details refer to the FORMat[:DATA] command description of the base unit on page 6.138.

FORMat:DEXPort:DSEParator

For details refer to "FORMat:DEXPort:DSEParator"on page 6.138.

INITiate Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.480 E-11

INITiate Subsystem (CATV, K20)

The INITiate subsystem is used to control the init–measurement function.

Commands of the INITiate Subsystem

–INITiate<1|2>[:IMMediate]

–INITiate<1|2>:CONMeas

–INITiate<1|2>:CONTinuous

INITiate<1|2>[:IMMediate]

For details refer to "INITiate<1|2>[:IMMediate]" on page 6.146.

INITiate<1|2>:CONMeas

For details refer to "INITiate<1|2>:CONMeas" on page 6.147.

INITiate<1|2>:CONTinuous

For details refer to "INITiate<1|2>:CONTinuous" on page 6.147.

R&S FSL INPut Subsystem (CATV, K20)

1300.2519.12 6.481 E-11

INPut Subsystem (CATV, K20)

The INPut subsystem controls the input characteristics of the RF inputs of the instrument.

Commands of the INPut Subsystem

–INPut:ATTenuation

–INPut:ATTenuation:AUTO

–INPut:GAIN:STATe

–INPut:IMPedance

INPut:ATTenuation

For details refer to "INPut<1|2>:ATTenuation" on page 6.150.

INPut:ATTenuation:AUTO

For details refer to "INPut<1|2>:ATTenuation:AUTO" on page 6.151.

INPut:GAIN:STATe

For details refer to "Error! Reference source not found."on page Error! Bookmark not

defined..

INPut:IMPedance

For details refer to "INPut<1|2>:IMPedance" on page 6.151.

INSTrument Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.482 E-11

INSTrument Subsystem (CATV, K20)

The INSTrument subsystem selects the operating mode of the unit either via text parameters or fixed

numbers.

Commands of the INSTrument Subsystem

–INSTrument[:SELect]

–INSTrument:NSELect

INSTrument[:SELect]

Parameter

CATV (Cable TV Measurements option, R&S FSL–K20)

For further details refer to the INSTrument subsystem of the base unit.

INSTrument:NSELect

Parameter

30 (Cable TV Measurements option, R&S FSL–K20)

For further details refer to the INSTrument subsystem of the base unit.

R&S FSL MMEMory Subsystem (CATV, K20)

1300.2519.12 6.483 E-11

MMEMory Subsystem (CATV, K20)

The MMEMory (mass memory) subsystem provides commands which allow for access to the storage

media of the instrument and for storing and loading various instrument settings.

Commands of the MMEMory Subsystem

–MMEMory:STORe<1|2>:TRACe

MMEMory:STORe<1|2>:TRACe

For details refer to the MMEMory:STORe<1|2>:TRACe command description of the base unit

on page 6.168.

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.484 E-11

SENSe Subsystem (CATV, K20)

The SENSe subsystem is organized in several subsystems. The commands of these subsystems

directly control device–specific settings, they do not refer to the signal characteristics of the

measurement signal.

The SENSe subsystem controls the essential parameters of the analyzer. In accordance with the SCPI

standard, the keyword "SENSe" is optional for this reason, which means that it is not necessary to

include the SENSe node in command sequences.

The following subsystems are included:

•"SENSe:ATV Subsystem (CATV, K20)" on page 6.485

•"SENSe:BANDwidth Subsystem (CATV, K20)" on page 6.496

•"SENSe:CORRection Subsystem (CATV, K20)" on page 6.497

•"SENSe:DETector Subsystem (CATV, K20)" on page 6.498

•"SENSe:DDEMod Subsystem (CATV, K20)" on page 6.499

•"SENSe:FREQuency Subsystem (CATV, K20)" on page 6.502

•"SENSe:POWer Subsystem (CATV, K20)" on page 6.504

•"SENSe:SWEep Subsystem (CATV, K20)" on page 6.505

•"SENSe:TV Subsystem (CATV, K20)" on page 6.506

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.485 E-11

SENSe:ATV Subsystem (CATV, K20)

The SENSe:ATV subsystem contains commands to control the analog TV measurement settings.

The following subsystems are included:

•"SENSe:ATV:CN Subsystem (CATV, K20)" on page 6.485

•"SENSe:ATV:CSO Subsystem (CATV, K20)" on page 6.489

•"SENSe:ATV:CTB Subsystem (CATV, K20)" on page 6.493

SENSe:ATV:CN Subsystem (CATV, K20)

The SENSe:ATV:CN subsystem contains commands for the Carrier–to–Noise Ratio (C/N)

measurement setup.

Commands of the SENSe:ATV:CN Subsystem

–[SENSe<1|2>:]ATV:CN:BWIDth

–[SENSe<1|2>:]ATV:CN:CFRelative:NEXT

–[SENSe<1|2>:]ATV:CN:MEASurement:MODE

–[SENSe<1|2>:]ATV:CN:POWer:NCORrection

–[SENSe<1|2>:]ATV:CN:POWer:REFerence:CHANnel:MANual

–[SENSe<1|2>:]ATV:CN:POWer:REFerence:MANual

–[SENSe<1|2>:]ATV:CN:POWer:REFerence:MODE

–[SENSe<1|2>:]ATV:CN:TABle<1...10>:MFRequencies

[SENSe<1|2>:]ATV:CN:BWIDth

This command defines the noise reference bandwidth in the C/N measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

100 to 20 MHz

Example

ATV:CN:BWID 7MHZ

Sets the noise reference bandwidth to 7 MHz.

Characteristics

RST value: 5 MHz

SCPI: device–specific

Mode

CATV

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.486 E-11

[SENSe<1|2>:]ATV:CN:CFRelative:NEXT

This command switches from one frequency range to the next according to the measurement

frequencies defined by the [SENSe<1|2>:]ATV:CN:TABle<1...10>:MFRequencies

command.

The numeric suffixes <1|2> are irrelevant.

This command is an event and therefore has no *RST value and no query.

Parameter

(RF–10 MHz) to (RF+10 MHz)

Example

ATV:CN:TABL1:MFR 1,1000,1000

Activates the first row entries for the measurement and sets the center frequency to 1 kHz and

the span to 1 kHz.

ATV:CN:TABL2:MFR 1,2000,2000

Activates the second row entries for the measurement and sets the center frequency to 2 kHz

and the span to 2 kHz.

ATV:CN:CFR:NEXT

Switches from the frequency range defined in table row 1 to 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CN:MEASurement:MODE

This command defines the measurement method for the Carrier–to–Noise Ratio measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

ISERvice

(In–Service)

While an analog TV signal is present, a gap between two consecutive

channels, where only noise exists, is used to determine the noise power. A

noise marker is placed there, and the noise power is determined.

OSERvice

(Off–Service)

The current measurement channel is switched off by the provider. In this

channel, a noise marker is placed, and the noise power is determined.

QLINe

(Quiet Line)

While an analog TV signal is present, the carrier–to–noise ratio is measured

using the so–called "Quiet Line''. The measurement is fully automated.

Example

ATV:CN:MEAS:MODE OSER

Sets the Off–Service measurement method.

Characteristics

RST value: ISER

SCPI: device–specific

Mode

CATV

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.487 E-11

[SENSe<1|2>:]ATV:CN:POWer:NCORrection

This command activates or deactivates the noise floor correction.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

ATV:CN:POW:NCOR ON

Activates the noise floor correction.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CN:POWer:REFerence:CHANnel:MANual

This command defines the reference channel.

The numeric suffixes <1|2> are irrelevant.

Parameter

<numeric_value>, corresponding to active channel

Example

ATV:CN:POW:REF:CHAN:MAN 5

Sets channel 5 in the active channel table as reference channel.

Characteristics

RST value: active measurement channel

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CN:POWer:REFerence:MANual

This command defines the manual reference power. The unit is set via the

CALCulate<1|2>:UNIT:POWer command.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

ATV:CN:POW:REF:MAN 10

Sets the reference power to 10.

Characteristics

RST value: 0

SCPI: device–specific

Mode

CATV

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.488 E-11

[SENSe<1|2>:]ATV:CN:POWer:REFerence:MODE

This command defines the reference power method.

The numeric suffixes <1|2> are irrelevant.

Parameter

RCHannel reference channel

([SENSe<1|2>:]ATV:CN:POWer:REFerence:CHANnel:MANual

command)

MCHannel same as measurement channel

MANual manual reference power

([SENSe<1|2>:]ATV:CN:POWer:REFerence:MANual command)

Example

ATV:CN:POW:REF:MODE RCH

Sets the reference channel method.

Characteristics

RST value: MCH

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CN:TABle<1...10>:MFRequencies

This command defines the measurement frequencies (center frequencies and span values), and

activates or deactivates them for the C/N measurement.

The numeric suffix <1...10> defines the table row. The numeric suffixes <1|2> are irrelevant.

Parameter

0 | 1,<numeric_value>,<numeric_value>

0deactivated

1activated

first numeric value center frequency in Hz

second numeric value span in Hz

Example

ATV:CN:TABL1:MFR 1,1000,1000

Activates the entries of the first table row for the measurement and sets the center frequency to

1kHz and the span to 1 kHz.

ATV:CN:TABL2:MFR 1,2000,2000

Activates the second row entries for the measurement and sets the center frequency to 2 kHz

and the span to 2 kHz.

Characteristics

RST value: 1,1.25 KHz,1 MHz (row 1); 0,1.25 kHz,1 MHz (row 2–10)

SCPI: device–specific

Mode

CATV

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.489 E-11

SENSe:ATV:CSO Subsystem (CATV, K20)

The SENSe:ATV:CSO subsystem contains commands for the Carrier–to–Second Order Beat Ratio

(CSO) measurement setup.

Commands of the SENSe:ATV:CSO Subsystem

–[SENSe<1|2>:]ATV:CSO:CFRelative:NEXT

–[SENSe<1|2>:]ATV:CSO:MEASurement:MODE

–[SENSe<1|2>:]ATV:CSO:POWer:NCORrection

–[SENSe<1|2>:]ATV:CSO:POWer:REFerence:CHANnel:MANual

–[SENSe<1|2>:]ATV:CSO:POWer:REFerence:MANual

–[SENSe<1|2>:]ATV:CSO:POWer:REFerence:MODE

–[SENSe<1|2>:]ATV:CSO:TABle<1...10>:MFRequencies

[SENSe<1|2>:]ATV:CSO:CFRelative:NEXT

This command switches from one frequency range to the next according to the measurement

frequencies defined by the [SENSe<1|2>:]ATV:CSO:TABle<1...10>:MFRequencies

command.

The numeric suffixes <1|2> are irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

ATV:CSO:TABL1:MFR 1,–1000,1000

Activates the entries of the first table row for the measurement and sets the center frequency to

–1 kHz and the span to 1 kHz.

ATV:CSO:TABL2:MFR 1,–2000,2000

Activates the second row entries for the measurement and sets the center frequency to –2 kHz

and the span to 2 kHz.

ATV:CSO:CFR:NEXT

Switches from the frequency range defined in table row 1 to 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CSO:MEASurement:MODE

This command defines the measurement method for the Carrier–to–Second Order Beat Ratio

measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

OSERvice

(Off–Service)

The current measurement channel is switched off by the provider. In this

channel, a noise marker is placed, and the noise power is determined.

QLINe

(Quiet Line)

While an analog TV signal is present, the carrier–to–noise ratio is

measured using the so–called "Quiet Line''. The measurement is fully

automated.

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.490 E-11

Example

ATV:CSO:MEAS:MODE QLIN

Sets the Quiet Line measurement method.

Characteristics

RST value: OSER

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CSO:POWer:NCORrection

This command activates or deactivates the noise floor correction.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

ATV:CSO:POW:NCOR ON

Activates the noise floor correction.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CSO:POWer:REFerence:CHANnel:MANual

This command defines the reference channel.

The numeric suffixes <1|2> are irrelevant.

Parameter

<numeric_value>, corresponding to active channel

Example

ATV:CSO:POW:REF:CHAN:MAN 6

Sets channel 6 in the active channel table as reference channel.

Characteristics

RST value: active measurement channel

SCPI: device–specific

Mode

CATV

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.491 E-11

[SENSe<1|2>:]ATV:CSO:POWer:REFerence:MANual

This command defines the manual reference power. The unit is set via the

CALCulate<1|2>:UNIT:POWer command.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

ATV:CSO:POW:REF:MAN 20

Sets the reference power to 20.

Characteristics

RST value: 10

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CSO:POWer:REFerence:MODE

This command defines the reference power method.

The numeric suffixes <1|2> are irrelevant.

Parameter

RCHannel reference channel

([SENSe<1|2>:]ATV:CSO:POWer:REFerence:CHANnel:MANual

command)

MCHannel same as measurement channel

MANual manual reference power

([SENSe<1|2>:]ATV:CSO:POWer:REFerence:MANual command)

Example

ATV:CSO:POW:REF:MODE RCH

Sets the reference channel method.

Characteristics

RST value: MCH

SCPI: device–specific

Mode

CATV

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.492 E-11

[SENSe<1|2>:]ATV:CSO:TABle<1...10>:MFRequencies

This command defines the measurement frequencies (center frequencies and span values), and

activates or deactivates them for the CSO measurement.

The numeric suffixes <1|2> are irrelevant.

The numeric suffix <1...10> defines the table row.

Parameter

0 | 1,<numeric_value>,<numeric_value>

0deactivated

1activated

first numeric value center frequency in Hz

second numeric value span in Hz

Example

ATV:CSO:TABL1:MFR 1,–1000,1000

Activates the entries of the first table row for the measurement and sets the center frequency to

–1 kHz and the span to 1 kHz.

ATV:CSO:TABL2:MFR 1,–2000,2000

Activates the second row entries for the measurement and sets the center frequency to –2 kHz

and the span to 2 kHz.

Characteristics

RST value:

Row State Center frequency Span

1ON –1.25 MHz 200 kHz

2ON –750 kHz 200 kHz

3ON –250 kHz 200 kHz

4ON 250 kHz 200 kHz

5ON 750 kHz 200 kHz

6ON 1.25 MHz 200 kHz

7ON 2.25 MHz 200 kHz

8OFF 3.25 MHz 200 kHz

9OFF 4.25 MHz 200 kHz

10 OFF 5.25 MHz 200 kHz

SCPI: device–specific

Mode

CATV

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.493 E-11

SENSe:ATV:CTB Subsystem (CATV, K20)

The SENSe:ATV:CTB subsystem contains commands for the Carrier–to–Composite Triple Beat Ratio

(CTB) measurement setup.

Commands of the SENSe:ATV:CTB Subsystem

–[SENSe<1|2>:]ATV:CTB:CFRelative:NEXT

–[SENSe<1|2>:]ATV:CTB:POWer:NCORrection

–[SENSe<1|2>:]ATV:CTB:POWer:REFerence:CHANnel:MANual

–[SENSe<1|2>:]ATV:CTB:POWer:REFerence:MANual

–[SENSe<1|2>:]ATV:CTB:POWer:REFerence:MODE

–[SENSe<1|2>:]ATV:CTB:TABle<1...10>:MFRequencies

[SENSe<1|2>:]ATV:CTB:CFRelative:NEXT

This command switches from one frequency range to the next according to the measurement

frequencies defined by the [SENSe<1|2>:]ATV:CTB:TABle<1...10>:MFRequencies command.

The numeric suffixes <1|2> are irrelevant.

This command is an event and therefore has no *RST value and no query.

Example

ATV:CTB:TABL1:MFR 1,100,10000

Activates the entries of the first table row for the measurement and sets the center frequency to

100 Hz and the span to 10 kHz.

ATV:CTB:TABL2:MFR 1,200,20000

Activates the second row entries for the measurement and sets the center frequency to 200 Hz

and the span to 20 kHz.

ATV:CTB:CFR:NEXT

Switches from the frequency range defined in table row 1 to 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CTB:POWer:NCORrection

This command activates or deactivates the noise floor correction.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

ATV:CTB:POW:NCOR ON

Activates the noise floor correction.

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.494 E-11

Characteristics

RST value: OFF

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CTB:POWer:REFerence:CHANnel:MANual

This command defines the reference channel.

The numeric suffixes <1|2> are irrelevant.

Parameter

<numeric_value>, corresponding to active channel

Example

ATV:CTB:POW:REF:CHAN:MAN 5

Sets channel 5 in the active channel table as reference channel.

Characteristics

RST value: active measurement channel

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CTB:POWer:REFerence:MANual

This command defines the manual reference power. The unit is set via the

CALCulate<1|2>:UNIT:POWer command.

The numeric suffixes <1|2> are irrelevant.

Parameter

–200 to 200 dB

Example

ATV:CTB:POW:REF:MAN 10

Sets the reference power to 10.

Characteristics

RST value: 0

SCPI: device–specific

Mode

CATV

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.495 E-11

[SENSe<1|2>:]ATV:CTB:POWer:REFerence:MODE

This command defines the reference power method.

The numeric suffixes <1|2> are irrelevant.

Parameter

RCHannel reference channel

([SENSe<1|2>:]ATV:CTB:POWer:REFerence:CHANnel:MANual

command)

MCHannel same as measurement channel

MANual manual reference power

([SENSe<1|2>:]ATV:CTB:POWer:REFerence:MANual command)

Example

ATV:CTB:POW:REF:MODE MAN

Sets the reference channel method.

Characteristics

RST value: RCH

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]ATV:CTB:TABle<1...10>:MFRequencies

This command defines the measurement frequencies (center frequencies and span values), and

activates or deactivates them for the CTB measurement.

The numeric suffix <1...10> defines the table row. The numeric suffixes <1|2> are irrelevant.

Parameter

0 | 1,<numeric_value>,<numeric_value>

0deactivated

1activated

first numeric value center frequency in Hz

second numeric value span in Hz

Example

ATV:CTB:TABL1:MFR 1,100,10000

Activates the entries of the first table row for the measurement and sets the center frequency to

100 Hz and the span to 10 kHz.

ATV:CTB:TABL2:MFR 1,200,20000

Activates the second row entries for the measurement and sets the center frequency to 200 Hz

and the span to 20 kHz.

Characteristics

RST value: 1,0 Hz, 200 kHz (row 1); 0,0,200 kHz (row 2–10)

SCPI: device–specific

Mode

CATV

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.496 E-11

SENSe:BANDwidth Subsystem (CATV, K20)

This subsystem controls the setting of the instruments filter bandwidths. Both groups of commands

(BANDwidth and BWIDth) perform the same functions.

Commands of the SENSe:BANDwidth Subsystem

–[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]

–[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:AUTO

–[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo

–[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:AUTO

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]

For details refer to "[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]" on page 6.175.

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:AUTO

For details refer to "[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:AUTO" on page 6.175.

[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo

For details refer to "[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo" on page 6.177.

[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:AUTO

For details refer to "[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:AUTO" on page 6.177.

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.497 E-11

SENSe:CORRection Subsystem (CATV, K20)

The SENSe:CORRection subsystem controls correction factors.

Commands of the SENSe:CORRection Subsystem

–[SENSe<1|2>:]CORRection:RVELocity

[SENSe<1|2>:]CORRection:RVELocity

This command defines the velocity of propagation of the signal in the transmission channel (e.g.

cable), relative to speed of light.

The numeric suffixes <1|2> are irrelevant.

Parameter

0.0001 to 1.0

Example

CONF:DTV:MEAS EPAT

Configures the R&S FSL for the Echo Pattern measurement.

CORR:RVEL 0.2

Sets the velocity of propagation to 0.2.

Characteristics

RST value: 1

SCPI: device–specific

Mode

CATV

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.498 E-11

SENSe:DETector Subsystem (CATV, K20)

The SENSe:DETector subsystem controls the acquisition of measurement data via the selection of the

detector for the corresponding trace.

Commands of the SENSe:DETector Subsystem

–[SENSe<1|2>:]DETector<1...4>[:FUNCtion]

–[SENSe<1|2>:]DETector<1...4>[:FUNCtion]:AUTO

[SENSe<1|2>:]DETector<1...4>[:FUNCtion]

For details refer to "[SENSe<1|2>:]DETector<1...6>[:FUNCtion]" on page 6.186.

[SENSe<1|2>:]DETector<1...4>[:FUNCtion]:AUTO

For details refer to "[SENSe<1|2>:]DETector<1...6>[:FUNCtion]:AUTO" on page 6.186.

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.499 E-11

SENSe:DDEMod Subsystem (CATV, K20)

The SENSe:DDEMod subsystem controls the digital TV settings.

Commands of the SENSe:DDEMod Subsystem

–[SENSe<1|2>:]DDEMod:EQUalizer[:STATe]

–[SENSe<1|2>:]DDEMod:EQUalizer:FREeze[:STATe]

–[SENSe<1|2>:]DDEMod:EQUalizer:RESet

–[SENSe<1|2>:]DDEMod:FILTer:ALPHa

–[SENSe<1|2>:]DDEMod:SBANd

–[SENSe<1|2>:]DDEMod:SRATe

[SENSe<1|2>:]DDEMod:EQUalizer[:STATe]

This command activates or deactivates the equalizer.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON | OFF

Example

DDEM:EQU OFF

Switches the equalizer off.

Characteristics

RST value: ON

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]DDEMod:EQUalizer:FREeze[:STATe]

This command defines the change of the equalizer coefficients.

The numeric suffixes <1|2> are irrelevant.

Parameter

ON The equalizer coefficients remain unchanged.

OFF The equalizer taps are changed with every measurement.

Example

DDEM:EQU:FRE ON

Activates the change of the equalizer coefficients.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

CATV

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.500 E-11

[SENSe<1|2>:]DDEMod:EQUalizer:RESet

This command resets the equalizer and all equalizer parameters are set to their default values.

The numeric suffixes <1|2> are irrelevant.

Example

DDEM:EQU:RES

Resets the equalizer.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]DDEMod:FILTer:ALPHa

This command defines the roll–off.

The numeric suffixes <1|2> are irrelevant.

Parameter

R012 | R013 | R015 | R018

Example

DDEM:FILT:ALPH R018

Sets the roll–off to 0.180.

Characteristics

RST value: R015

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]DDEMod:SBANd

This command defines the sideband position.

The numeric suffixes <1|2> are irrelevant.

Parameter

AUTO | NORMal | INVerse

Example

DDEM:SBAN NORM

Sets the sideband position to normal.

Characteristics

RST value: AUTO

SCPI: device–specific

Mode

CATV

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.501 E-11

[SENSe<1|2>:]DDEMod:SRATe

This command defines the symbol rate.

The numeric suffixes <1|2> are irrelevant.

Parameter

<numeric_value>

Example

DDEM:SRAT 1000000

Sets the symbol rate to 1.0 MSymb/s

Characteristics

RST value: 6.9 MSYMB/S

SCPI: device–specific

Mode

CATV

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.502 E-11

SENSe:FREQuency Subsystem (CATV, K20)

The SENSe:FREQuency subsystem defines the frequency axis of the active display. The frequency

axis can either be defined via the start/stop frequency or via the center frequency and span.

Commands of the SENSe:FREQuency Subsystem

–[SENSe<1|2>:]FREQuency:CHANnel

–[SENSe<1|2>:]FREQuency:RF

–[SENSe<1|2>:]FREQuency:SPAN:FULL

–[SENSe<1|2>:]FREQuency:STARt

–[SENSe<1|2>:]FREQuency:STEP

–[SENSe<1|2>:]FREQuency:STOP

[SENSe<1|2>:]FREQuency:CHANnel

This command defines the active measurement channel. To display the available channel tables

and channels refer to the "CONFigure:TV Subsystem (CATV, K20)" on page 6.473.

The numeric suffixes <1|2> are irrelevant.

Parameter

<numeric_value>

Example

CONF:TV:CTAB:SEL 'TV–EUROPE'

Selects and activates the channel table TV–EUROPE.

FREQ:CHAN 3

Sets channel 3 as active measurement channel.

Characteristics

RST value: active measurement channel

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]FREQuency:RF

This command defines the RF frequency. The interpretation of the RF frequency depends on

the signal type. For details refer to chapter "Instrument Functions", section "Cable TV

Measurement Option (K20)", RF softkey.

The numeric suffixes <1|2> are irrelevant.

Parameter

5MHz to 1.5 GHz

Example

FREQ:RF 10MHZ

Sets the RF frequency to 10 MHz.

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.503 E-11

Characteristics

RST value: 1.5 GHz for R&S FSL3, 48.25 MHz for R&S FSL6/18 (the FREQ:RF DEF command

sets 48.25 MHz for all models)

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]FREQuency:SPAN:FULL

For details refer to "[SENSe<1|2>:]FREQuency:SPAN:FULL" on page 6.203.

[SENSe<1|2>:]FREQuency:STARt

For details refer to "[SENSe<1|2>:]FREQuency:STARt" on page 6.204.

[SENSe<1|2>:]FREQuency:STEP

For details refer to "[SENSe<1|2>:]FREQuency:CENTer:STEP" on page 6.201.

[SENSe<1|2>:]FREQuency:STOP

For details refer to "[SENSe<1|2>:]FREQuency:STOP" on page 6.204.

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.504 E-11

SENSe:POWer Subsystem (CATV, K20)

The SENSe:POWer subsystem adjusts the input attenuator.

Commands of the SENSe:POWer Subsystem

–[SENSe<1|2>:]POWer:ACHannel:PRESet:RLEVel

[SENSe<1|2>:]POWer:ACHannel:PRESet:RLEVel

For details refer to "[SENSe<1|2>:]POWer:ACHannel:PRESet:RLEVel" on page 6.223.

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.505 E-11

SENSe:SWEep Subsystem (CATV, K20)

The SENSe:SWEep subsystem controls the sweep parameters.

Commands of the SENSe:SWEep Subsystem

–[SENSe<1|2>:]SWEep:COUNt

–[SENSe<1|2>:]SWEep:POINts

–[SENSe<1|2>:]SWEep:SPACing

–[SENSe<1|2>:]SWEep:TIME

–[SENSe<1|2>:]SWEep:TIME:AUTO

[SENSe<1|2>:]SWEep:COUNt

For details refer to "[SENSe<1|2>:]SWEep:COUNt" on page 6.229.

[SENSe<1|2>:]SWEep:POINts

For details refer to "[SENSe<1|2>:]SWEep:POINts" on page 6.233.

[SENSe<1|2>:]SWEep:SPACing

This command defines the labeling of the frequency axis. For details refer to chapter

"Instrument Functions", section "Cable TV Measurement Option (K20)", Frequency Abs/Rel

softkey.

The numeric suffixes <1|2> are irrelevant.

Parameter

ABSolute | RELative

Example

SWE:SPAC ABS

Sets absolute labeling of the frequency axis.

Characteristics

RST value: REL

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]SWEep:TIME

For details refer to "[SENSe<1|2>:]SWEep:TIME" on page 6.234.

[SENSe<1|2>:]SWEep:TIME:AUTO

For details refer to "[SENSe<1|2>:]SWEep:TIME:AUTO" on page 6.234.

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.506 E-11

SENSe:TV Subsystem (CATV, K20)

The SENSe:DDEMod subsystem controls the TV settings.

Commands of the SENSe:TV Subsystem

–[SENSe<1|2>:]TV:MSTandard:FILTer:GDELay

–[SENSe<1|2>:]TV:MSTandard:NAME

–[SENSe<1|2>:]TV:MSTandard:STYPe

–[SENSe<1|2>:]TV:TILT:MSTandard:CDISable

–[SENSe<1|2>:]TV:TILT:MSTandard:CENable

[SENSe<1|2>:]TV:MSTandard:FILTer:GDELay

This command defines the group delay for a modulation standard.

The numeric suffixes <1|2> are irrelevant.

Parameter

OIRT | CHINa | CCIR | TDF | FFC

Example

TV:MST:FILT:GDEL FLAT

Sets the group delay FLAT.

Characteristics

RST value: GENERAL

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]TV:MSTandard:NAME

This command defines the name for a modulation standard.

The numeric suffixes <1|2> are irrelevant.

Parameter

<string>: 1 to 15 characters

Example

TV:MST:NAME 'TEST'

Gives the modulation standard the name 'TEST'.

Characteristics

RST value: Analog TV

SCPI: device–specific

Mode

CATV

R&S FSL SENSe Subsystem (CATV, K20)

1300.2519.12 6.507 E-11

[SENSe<1|2>:]TV:MSTandard:STYPe

This command defines the signal type of a modulation standard.

The numeric suffixes <1|2> are irrelevant.

Parameter

ATV | DTV

Example

TV:MST:STYP DTV

Sets the signal type DTV.

Characteristics

RST value: ATV

SCPI: device–specific

Mode

CATV

[SENSe<1|2>:]TV:TILT:MSTandard:CDISable

This command deactivates a modulation standard for the Tilt measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

<string>: modulation standard name

Example

CONF:TV:CTAB:SEL 'TV–ITALY'

Activates the channel table TV–ITALY.

CONF:TV:MEAS TILT

Configures the R&S FSL to measure the channel power of every channel.

TV:TILT:MST:CDIS 'PAL BG ITALY'

Deactivates the modulation standard PAL BG ITALY.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

SENSe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.508 E-11

[SENSe<1|2>:]TV:TILT:MSTandard:CENable

This command activates a modulation standard for the Tilt measurement.

The numeric suffixes <1|2> are irrelevant.

Parameter

<string>: modulation standard name

Example

CONF:TV:CTAB:SEL 'TV–ITALY'

Activates the channel table TV–ITALY.

CONF:TV:MEAS TILT

Configures the R&S FSL to measure the channel power of every channel.

TV:TILT:MST:CEN 'PAL BG ITALY'

Activates the modulation standard PAL BG ITALY.

Characteristics

RST value: –

SCPI: device–specific

Mode

CATV

R&S FSL SETup:TV Subsystem (CATV, K20)

1300.2519.12 6.509 E-11

SETup:TV Subsystem (CATV, K20)

The SETup:TV subsystem controls the modulation standard settings.

Commands of the SETup:TV Subsystem

–SETup:TV:STANdard

–SETup:TV:STANdard:AUDio

–SETup:TV:STANdard:COLor

SETup:TV:STANdard

This command sets the TV standard.

Parameter

BG | DK | I | K1 | L | M | N (analog TV)

J83A | J83B | J83C (digital TV)

Note: In the Video Scope measurement, the y–axis of the diagram is scaled in Volt for all TV

standards except M. If M is the selected TV standard, the y–axis of the diagram is

scaled in IRE.

Example

SET:TV:STAN DK

Sets the TV standard DK.

Characteristics

RST value: BG

SCPI: device–specific

Mode

CATV

SETup:TV:STANdard:AUDio

This command sets the sound system for analog TV measurements.

Parameter

AM60MONO | FM45BTSC | FM45EIA_J | FM45FM4742 | FM45MONO

Example

SET:TV:STAN:AUD FM65MONO

Sets the sound system FM65MONO.

Characteristics

RST value: FM65FM6742

SCPI: device–specific

Mode

CATV

SETup:TV Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.510 E-11

SETup:TV:STANdard:COLor

This command sets the color system for analog TV measurements.

Parameter

PAL | NTSC | SECam

Example

SET:TV:STAN:COL SEC

Sets the color system SECam.

Characteristics

RST value: PAL

SCPI: device–specific

Mode

CATV

R&S FSL SOURce Subsystem (CATV, K20)

1300.2519.12 6.511 E-11

SOURce Subsystem (CATV, K20)

The SOURce subsystem controls the digital TV settings.

Commands of the SOURce Subsystem

–SOURce:DM:FORMat

SOURce:DM:FORMat

This command sets the constellation parameter for digital TV measurements.

Parameter

QAM4 | QAM16 | QAM32 | QAM64 | QAM128 | QAM256 | QAM512 | QAM1024

Example

SOURce:DM:FORM QAM128

Sets the constellation parameter

Characteristics

RST value: QAM64

SCPI: device–specific

Mode

CATV

STATus Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.512 E-11

STATus Subsystem (CATV, K20)

The STATus subsystem contains the commands for the status reporting system (for details refer to

chapter 5 "Remote Control – Basics". *RST does not influence the status registers.

Commands of the STATus Subsystem

–STATus:QUEStionable:ACPLimit[:EVENt?]

–STATus:QUEStionable:ACPLimit:CONDition?

–STATus:QUEStionable:ACPLimit:ENABle

–STATus:QUEStionable:ACPLimit:NTRansition

–STATus:QUEStionable:ACPLimit:PTRansition

–STATus:QUEStionable:FREQuency[:EVENt?]

–STATus:QUEStionable:FREQuency:CONDition?

–STATus:QUEStionable:FREQuency:ENABle

–STATus:QUEStionable:FREQuency:NTRansition

–STATus:QUEStionable:FREQuency:PTRansition

–STATus:QUEStionable:LIMit<1|2>[:EVENt?]

–STATus:QUEStionable:LIMit<1|2>:CONDition?

–STATus:QUEStionable:LIMit<1|2>:ENABle

–STATus:QUEStionable:LIMit<1|2>:NTRansition

–STATus:QUEStionable:LIMit<1|2>:PTRansition

–STATus:QUEStionable:LMARgin<1|2>[:EVENt?]

–STATus:QUEStionable:LMARgin<1|2>:CONDition?

–STATus:QUEStionable:LMARgin<1|2>:ENABle

–STATus:QUEStionable:LMARgin<1|2>:NTRansition

–STATus:QUEStionable:LMARgin<1|2>:PTRansition

–STATus:QUEStionable:POWer[:EVENt?]

–STATus:QUEStionable:POWer:CONDition?

–STATus:QUEStionable:POWer:ENABle

–STATus:QUEStionable:POWer:NTRansition

–STATus:QUEStionable:POWer:PTRansition

–STATus:QUEStionable:SYNC[:EVENt?]

–STATus:QUEStionable:SYNC:CONDition?

–STATus:QUEStionable:SYNC:ENABle

–STATus:QUEStionable:SYNC:NTRansition

–STATus:QUEStionable:SYNC:PTRansition

R&S FSL STATus Subsystem (CATV, K20)

1300.2519.12 6.513 E-11

STATus:QUEStionable:ACPLimit[:EVENt?]

For details refer to "STATus:QUEStionable:ACPLimit[:EVENt]?" on page 6.242.

STATus:QUEStionable:ACPLimit:CONDition?

For details refer to "STATus:QUEStionable:ACPLimit:CONDition?" on page 6.242.

STATus:QUEStionable:ACPLimit:ENABle

For details refer to "STATus:QUEStionable:ACPLimit:ENABle" on page 6.243.

STATus:QUEStionable:ACPLimit:NTRansition

For details refer to "STATus:QUEStionable:ACPLimit:NTRansition" on page 6.243.

STATus:QUEStionable:ACPLimit:PTRansition

For details refer to "STATus:QUEStionable:ACPLimit:PTRansition" on page 6.243.

STATus:QUEStionable:FREQuency[:EVENt?]

For details refer to "STATus:QUEStionable:FREQuency[:EVENt]?" on page 6.244.

STATus:QUEStionable:FREQuency:CONDition?

For details refer to "STATus:QUEStionable:FREQuency:CONDition?" on page 6.244.

STATus:QUEStionable:FREQuency:ENABle

For details refer to "STATus:QUEStionable:FREQuency:ENABle" on page 6.244.

STATus:QUEStionable:FREQuency:NTRansition

For details refer to "STATus:QUEStionable:FREQuency:NTRansition" on page 6.245.

STATus:QUEStionable:FREQuency:PTRansition

For details refer to "STATus:QUEStionable:FREQuency:PTRansition" on page 6.245.

STATus:QUEStionable:LIMit<1|2>[:EVENt?]

For details refer to "STATus:QUEStionable:LIMit<1|2>[:EVENt]?" on page 6.245.

STATus Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.514 E-11

STATus:QUEStionable:LIMit<1|2>:CONDition?

For details refer to "STATus:QUEStionable:LIMit<1|2>:CONDition?" on page 6.246.

STATus:QUEStionable:LIMit<1|2>:ENABle

For details refer to "STATus:QUEStionable:LIMit<1|2>:ENABle" on page 6.246.

STATus:QUEStionable:LIMit<1|2>:NTRansition

For details refer to "STATus:QUEStionable:LIMit<1|2>:NTRansition" on page 6.246.

STATus:QUEStionable:LIMit<1|2>:PTRansition

For details refer to "STATus:QUEStionable:LIMit<1|2>:PTRansition" on page 6.247.

STATus:QUEStionable:LMARgin<1|2>[:EVENt?]

For details refer to "STATus:QUEStionable:LMARgin<1|2>[:EVENt]?" on page 6.247.

STATus:QUEStionable:LMARgin<1|2>:CONDition?

For details refer to "STATus:QUEStionable:LMARgin<1|2>:CONDition?" on page 6.247.

STATus:QUEStionable:LMARgin<1|2>:ENABle

For details refer to "STATus:QUEStionable:LMARgin<1|2>:ENABle" on page 6.248.

STATus:QUEStionable:LMARgin<1|2>:NTRansition

For details refer to "STATus:QUEStionable:LMARgin<1|2>:NTRansition" on page 6.248.

STATus:QUEStionable:LMARgin<1|2>:PTRansition

For details refer to "STATus:QUEStionable:LMARgin<1|2>:PTRansition" on page 6.248.

STATus:QUEStionable:POWer[:EVENt?]

For details refer to "STATus:QUEStionable:POWer[:EVENt]?" on page 6.249.

STATus:QUEStionable:POWer:CONDition?

For details refer to "STATus:QUEStionable:POWer:CONDition?" on page 6.249.

R&S FSL STATus Subsystem (CATV, K20)

1300.2519.12 6.515 E-11

STATus:QUEStionable:POWer:ENABle

For details refer to "STATus:QUEStionable:POWer:ENABle" on page 6.249.

STATus:QUEStionable:POWer:NTRansition

For details refer to "STATus:QUEStionable:POWer:NTRansition" on page 6.250.

STATus:QUEStionable:POWer:PTRansition

For details refer to "STATus:QUEStionable:POWer:PTRansition" on page 6.250.

STATus:QUEStionable:SYNC[:EVENt?]

For details refer to "STATus:QUEStionable:SYNC[:EVENt]?" on page 6.250.

STATus:QUEStionable:SYNC:CONDition?

For details refer to "STATus:QUEStionable:SYNC:CONDition?" on page 6.251.

STATus:QUEStionable:SYNC:ENABle

For details refer to "STATus:QUEStionable:SYNC:ENABle" on page 6.251.

STATus:QUEStionable:SYNC:NTRansition

For details refer to "STATus:QUEStionable:SYNC:NTRansition" on page 6.251.

STATus:QUEStionable:SYNC:PTRansition

For details refer to "STATus:QUEStionable:SYNC:PTRansition" on page 6.252.

TRACe Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.516 E-11

TRACe Subsystem (CATV, K20)

The TRACe subsystem controls access to the instruments internal trace memory.

Commands of the TRACe Subsystem

–TRACe<1|2>[:DATA]

–TRACe:COPY

TRACe<1|2>[:DATA]

Parameter

TRACE1 | TRACE2 | TRACE3 | TRACE4,<block> | <numeric_value>

TRACE1 to TRACE4 trace memory to be read out

<block> or <numeric_value> data to be transferred

For further details refer to "TRACe<1|2>[:DATA]" on page 6.263.

TRACe:COPY

Parameter

The first operand the destination of the data to be copied, the second operand describes the

source.

For further details refer to "TRACe:COPY" on page 6.264.

R&S FSL TRIGger Subsystem (CATV, K20)

1300.2519.12 6.517 E-11

TRIGger Subsystem (CATV, K20)

The TRIGger subsystem is used to synchronize instrument actions with events. It is thus possible to control

and synchronize the start of a sweep.

Commands of the TRIGger Subsystem

–TRIGger<1|2>[:SEQuence]:HOLDoff[:TIME]

–TRIGger<1|2>[:SEQuence]:VIDeo:BFIeld[:NUMBer]

–TRIGger<1|2>[:SEQuence]:VIDeo:BLINe[:NUMBer]

–TRIGger<1|2>[:SEQuence]:VIDeo:BLINe:TYPE

–TRIGger<1|2>[:SEQuence]:VIDeo:FIELd:[NUMBer]

–TRIGger<1|2>[:SEQuence]:VIDeo:LINE:[NUMBer]

–TRIGger<1|2>[:SEQuence]:VIDeo:QFIeld[:NUMBer]

–TRIGger<1|2>[:SEQuence]:VIDeo:QLINe[:NUMBer]

TRIGger<1|2>[:SEQuence]:HOLDoff[:TIME]

For details refer to "TRIGger<1|2>[:SEQuence]:HOLDoff[:TIME]" on page 6.277.

TRIGger<1|2>[:SEQuence]:VIDeo:BFIeld[:NUMBer]

This command sets the bar field parameter for analog TV measurements.

Parameter

1 | 2

Example

TRIG:VID:BFI 2

Sets the bar field parameter to 2.

Characteristics

RST value: 1

SCPI: device–specific

Mode

CATV

TRIGger<1|2>[:SEQuence]:VIDeo:BLINe[:NUMBer]

This command sets the bar line parameter for analog TV measurements.

Parameter

<numeric_value>

Example

TRIG:VID:BLIN 16

Sets the bar line parameter to 16.

TRIGger Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.518 E-11

Characteristics

RST value: 18

SCPI: device–specific

Mode

CATV

TRIGger<1|2>[:SEQuence]:VIDeo:BLINe:TYPE

This command sets the bar line type for analog TV measurements.

Parameter

CCIR17 | FCC | NTC7

Example

TRIG:VID:BLIN:TYPE CCIR17

Sets the bar line type to CCIR17.

Characteristics

RST value: CCIR17

SCPI: device–specific

Mode

CATV

TRIGger<1|2>[:SEQuence]:VIDeo:FIELd:[NUMBer]

This command defines the active field in the Video Scope measurement.

Parameter

1 | 2

Example

TRIG:VID:FIEL 2

Sets the active field 2.

Characteristics

RST value: 1

SCPI: conform

Mode

CATV

R&S FSL TRIGger Subsystem (CATV, K20)

1300.2519.12 6.519 E-11

TRIGger<1|2>[:SEQuence]:VIDeo:LINE:[NUMBer]

This command activates triggering at the horizontal sync signal of the indicated line number in

the Video Scope measurement.

Parameter

<numeric_value>, depending on the numbering conventions of the TV standard and the color

system

Example

TRIG:VID:LINE 17

Characteristics

*RST value: 1

SCPI: conform

Mode

CATV

TRIGger<1|2>[:SEQuence]:VIDeo:QFIeld[:NUMBer]

This command sets the quiet line field for analog TV measurements.

Parameter

1 | 2

Example

TRIG:VID:QFI 2

Sets the quiet line field to 2.

Characteristics

RST value: 1

SCPI: device–specific

Mode

CATV

TRIGger<1|2>[:SEQuence]:VIDeo:QLINe[:NUMBer]

This command sets the quiet line parameter for analog TV measurements.

Parameter

<numeric_value>

Example

TRIG:VID:QLIN 20

Sets the quiet line parameter to 20.

Characteristics

RST value: 22

SCPI: device–specific

Mode

CATV

UNIT Subsystem (CATV, K20) R&S FSL

1300.2519.12 6.520 E-11

UNIT Subsystem (CATV, K20)

The UNIT subsystem sets the basic unit of the setting parameters.

Commands of the UNIT Subsystem

–UNIT<1|2>:POWer

UNIT<1|2>:POWer

This command selects the default unit.

Parameter

Example

UNIT:POW DBUV

Sets the power unit to dBm.

Characteristics

*RST value: DBM

SCPI: conform

Mode

CATV

R&S FSL UNIT Subsystem (CATV, K20)

1300.2519.12 6.521 E-11

Remote Commands of the Noise Figure

Measurements Option (K30)

This section describes the remote commands for the Noise Figure Measurements option (K30). The

abbreviation NF stands for the operating mode of noise figure measurements. For details on

conventions used in this chapter refer to section "Notation" on page 6.2 at the beginning of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in section "Remote Commands of the Base Unit" on page 6.5.

This option is available from firmware version 1.50.

Subsystems of the Noise Figure Measurements option (K30)

–"ABORt Subsystem (Noise Figure, K30)" on page 6.522

–"CALCulate Subsystem (Noise Figure, K30)" on page 6.523

–"CONFigure Subsystem (Noise Figure, K30)" on page 6.532

–"DISPlay Subsystem (Noise Figure, K30)" on page 6.534

–"FETCh Subsystem (Noise Figure, K30)" on page 6.541

– "INITiate Subsystem (Noise Figure, K30)" on page 6.545

–"INPut Subsystem (Noise Figure, K30)" on page 6.546

–"INSTrument Subsystem (Noise Figure, K30)" on page 6.547

–"SENSe Subsystem (Noise Figure, K30)" on page 6.548

–"STATus Subsystem (Noise Figure, K30)" on page 6.558

–"SYSTem Subsystem (Noise Figure, K30)" on page 6.563

ABORt Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.522 E-11

ABORt Subsystem (Noise Figure, K30)

The ABORt subsystem contains the commands for aborting triggered actions.

Commands of the ABORt Subsystem

–ABORt

ABORt

For details refer to "ABORt" on page 6.10.

R&S FSL CALCulate Subsystem (Noise Figure, K30)

1300.2519.12 6.523 E-11

CALCulate Subsystem (Noise Figure, K30)

The CALCulate subsystem checks the marker functions and contains commands for limit lines and their

limit checks.

The following subsystems are included:

•"CALCulate:LIMit Subsystem (Noise Figure, K30)" on page 6.523

•"CALCulate:MARKer Subsystem (Noise Figure, K30)" on page 6.529

CALCulate:LIMit Subsystem (Noise Figure, K30)

The CALCulate:LIMit subsystem contains commands for the limit lines and the corresponding limit

checks. Limit lines can be defined as upper or lower limit lines. The individual y values of the limit lines

correspond to the values of the x–axis (CONTrol). The number of x and y values must be identical. For

details on limit lines refer to chapter "Instrument Functions", section "Using Limit Lines and Display

Lines – LINES Key".

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1 to

LIMIT6).

The following subsystems are included:

•"CALCulate:LIMit:CONTrol Subsystem" on page 6.526

•"CALCulate:LIMit:LOWer Subsystem" on page 6.527

•"CALCulate:LIMit:UPPer Subsystem" on page 6.528

Commands of the CALCulate:LIMit Subsystem

–CALCulate<1|2>:LIMit<1...6>:CLEar[:IMMediate]

–CALCulate<1|2>:LIMit<1...6>:COMMent

–CALCulate<1|2>:LIMit<1...6>:COPY

–CALCulate<1|2>:LIMit<1...6>:DELete

–CALCulate<1|2>:LIMit<1...6>:FAIL?

–CALCulate<1|2>:LIMit<1...6>:NAME

–CALCulate<1|2>:LIMit<1...6>:STATe

–CALCulate<1|2>:LIMit<1...6>:TRACe

CALCulate<1|2>:LIMit<1...6>:CLEar[:IMMediate]

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:CLEar[:IMMediate]" on page 6.29.

CALCulate<1|2>:LIMit<1...6>:COMMent

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:COMMent" on page 6.29.

CALCulate Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.524 E-11

CALCulate<1|2>:LIMit<1...6>:COPY

Parameter

1to 6 number of the new limit line

<name> name of the new limit line given as a string (max. 8 alphanumeric characters)

For further details refer to "CALCulate<1|2>:LIMit<1...8>:COPY" on page 6.30.

CALCulate<1|2>:LIMit<1...6>:DELete

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:DELete" on page 6.30.

CALCulate<1|2>:LIMit<1...6>:FAIL?

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:FAIL?" on page 6.31.

CALCulate<1|2>:LIMit<1...6>:NAME

This command assigns a name to a limit line. If it does not exist already, a limit line with this

name is created.

The numeric suffixes <1...6> indicate the limit line.

Parameter

<name of limit line>, max. 8 alphanumeric characters

Example

CALC:LIM1:NAME FM1

Assigns the name FM1 to limit line 1.

Characteristics

*RST value: REM1 to REM6 for lines 1 to 6

SCPI: device–specific

Mode

CALCulate<1|2>:LIMit<1...6>:STATe

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:STATe" on page 6.31.

R&S FSL CALCulate Subsystem (Noise Figure, K30)

1300.2519.12 6.525 E-11

CALCulate<1|2>:LIMit<1...6>:TRACe

This command assigns a limit line to a particular measurement type.

The numeric suffixes <1...6> indicate the limit line.

Parameter

NFIGure noise figure

TEFFective noise temperature

GAIN gain

Example

CALC:LIM2:TRAC NFIG

Assigns limit line 2 to the noise figure measurement.

CALC:LIM3:TRAC GAIN

Assigns limit line 3 to the gain measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

CALCulate Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.526 E-11

CALCulate:LIMit:CONTrol Subsystem (Noise Figure, K30)

The CALCulate:LIMit:CONTrol subsystem defines the x–axis (CONTrol axis).

Commands of the CALCulate:LIMit:CONTrol Subsystem

–CALCulate<1|2>:LIMit<1...6>:CONTrol[:DATA]

–CALCulate<1|2>:LIMit<1...6>:CONTrol:SHIFt

CALCulate<1|2>:LIMit<1...6>:CONTrol[:DATA]

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:CONTrol[:DATA]" on page 6.41.

CALCulate<1|2>:LIMit<1...6>:CONTrol:SHIFt

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:CONTrol:SHIFt" on page 6.43.

R&S FSL CALCulate Subsystem (Noise Figure, K30)

1300.2519.12 6.527 E-11

CALCulate:LIMit:LOWer Subsystem (Noise Figure, K30)

The CALCulate:LIMit:LOWer subsystem defines the lower limit line. If a set command is issued in this

subsystem the limit line effected is automatically converted to a lower limit line.

Commands of the CALCulate:LIMit:LOWer Subsystem

–CALCulate<1|2>:LIMit<1...6>:LOWer[:DATA]

–CALCulate<1|2>:LIMit<1...6>:LOWer:SHIFt

–CALCulate<1|2>:LIMit<1...6>:LOWer:STATe

CALCulate<1|2>:LIMit<1...6>:LOWer[:DATA]

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:LOWer[:DATA]" on page 6.47.

CALCulate<1|2>:LIMit<1...6>:LOWer:SHIFt

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:LOWer:SHIFt" on page 6.49.

CALCulate<1|2>:LIMit<1...6>:LOWer:STATe

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:LOWer:STATe" on page 6.48.

CALCulate Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.528 E-11

CALCulate:LIMit:UPPer Subsystem (Noise Figure, K30)

The CALCulate:LIMit:UPPer subsystem defines the upper limit line. If a set command is issued in this

subsystem the limit line effected is automatically converted to an upper limit line.

Commands of the CALCulate:LIMit:UPPer Subsystem

–CALCulate<1|2>:LIMit<1...6>:UPPer[:DATA]

–CALCulate<1|2>:LIMit<1...6>:UPPer:SHIFt

–CALCulate<1|2>:LIMit<1...6>:UPPer:STATe

CALCulate<1|2>:LIMit<1...6>:UPPer[:DATA]

Different to the basic unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:UPPer[:DATA]" on page 6.51.

CALCulate<1|2>:LIMit<1...6>:UPPer:SHIFt

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:UPPer:SHIFt" on page 6.53.

CALCulate<1|2>:LIMit<1...6>:UPPer:STATe

Different to the base unit, only 6 limit lines can be active at the same time (indicated by LIMIT1

to LIMIT6).

For further details refer to "CALCulate<1|2>:LIMit<1...8>:UPPer:STATe" on page 6.54.

R&S FSL CALCulate Subsystem (Noise Figure, K30)

1300.2519.12 6.529 E-11

CALCulate:MARKer Subsystem (Noise Figure, K30)

The CALCulate:MARKer subsystem checks the marker functions of the instrument.

Commands of the CALCulate:MARKer Subsystem

–CALCulate:MARKer[:STATe]

–CALCulate:MARKer:AOFF

–CALCulate:MARKer:TRACe

–CALCulate:MARKer:X

–CALCulate:MARKer:Y?

–CALCulate:MARKer:MAXimum[:PEAK]

–CALCulate:MARKer:MiNimum[:PEAK]

CALCulate:MARKer[:STATe]

This command switches on or off the marker 1 for the selected trace. It is only available if

measurement results are displayed.

If the selected trace is switched off (DISPlay[:WINDow<1>]:TRACe<1|2>[:STATe]), the

marker is also switched off. If the marker is switched on again, the marker is set to the active

trace. If both noise and gain traces are switched off, the marker can not be switched on again.

This command is available from firmware version 1.60.

Parameter

ON | OFF

Example

CALC:MARK ON

Marker 1 is switched on.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

CALCulate:MARKer:AOFF

This command switches off the marker 1.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.60.

Example

CALC:MARK:AOFF

Marker 1 is switched off.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.530 E-11

CALCulate:MARKer:TRACe

This command assigns the marker1 to the indicated trace.

This command is available from firmware version 1.60.

Parameter

NOISe | GAIN

Example

CALC:MARK:TRAC GAIN

Assigns marker 1 to the gain trace.

Characteristics

RST value: NOIS

SCPI: device–specific

Mode

CALCulate:MARKer:X

This command positions the marker1 to the indicated frequency measurement point. If the

marker is off, it is switched on first.

This command is available from firmware version 1.60.

Parameter

0to MAX (frequency | sweep time)

Example

CALC:MARK:X 550 MHZ

Positions marker 1 to frequency 550 MHz.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate:MARKer:Y?

This command queries the measured value of the marker 1. If the marker is off, it is switched on

first. To obtain a valid query result, a complete sweep with synchronization to the sweep end

must be performed before the query of the y value. The query result is output in the unit

determined with the selected trace (see also DISPlay:DATA:TRACe<1> command).

This command is only a query and therefore has no *RST value.

This command is available from firmware version 1.60.

Example

CALC:MARK:Y?

Outputs the measured value of marker 1.

R&S FSL CALCulate Subsystem (Noise Figure, K30)

1300.2519.12 6.531 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate:MARKer:MAXimum[:PEAK]

This command positions the marker to the current maximum value of the selected trace

(CALCulate:MARKer:TRACe command). If the marker is off, it is switched on first.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.60.

Example

CALC:MARK:MAX

Positions marker 1 to the maximum of the selected trace.

Characteristics

RST value: –

SCPI: device–specific

Mode

CALCulate:MARKer:MiNimum[:PEAK]

This command positions the marker to the current mininum value of the selected trace

(CALCulate:MARKer:TRACe command). If the marker is off, it is switched on first.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.60.

Example

CALC:MARK:MIN

Positions marker 1 to the minimum of the selected trace.

Characteristics

RST value: –

SCPI: device–specific

Mode

CONFigure Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.532 E-11

CONFigure Subsystem (Noise Figure, K30)

The CONFigure subsystem contains commands for configuring complex measurement tasks.

Commands of the CONFigure Subsystem

–CONFigure:ARRay:MEMory<1...3>

–CONFigure:CORRection

–CONFigure:LIST:CONTinuous

–CONFigure:LIST:SINGle

–CONFigure:SINGle

CONFigure:ARRay:MEMory<1...3>

This command saves the current trace results (noise figure, noise temperature and noise gain

traces) to trace memory <n>.

This command is an event and therefore has no *RST value and no query.

This command is available from firmware version 1.60.

Parameter

ONCE

Example

INIT

Starts a new measurement, if no measurement sequence is already in progress.

CONF:ARR:MEM2 ONCE

Copies the last recorded measurement result into the memory 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

CONFigure:CORRection

This command configures for a second stage correction measurement.

This command is an event and therefore has no *RST value and no query.

Example

CONF:CORR

Configures to run second stage correction measure measurements.

INIT

Starts a new measurement, if no measurement sequence is already in progress.

Characteristics

*RST value: –

SCPI: device–specific

Mode

R&S FSL CONFigure Subsystem (Noise Figure, K30)

1300.2519.12 6.533 E-11

CONFigure:LIST:CONTinuous

This command configures for a frequency list measurement in continuous sweep mode.

This command is an event and therefore has no *RST value and no query.

Example

CONF:LIST:CONT

Configures to run a frequency list measurement in continuous sweep mode.

INIT

Starts a new measurement, if no measurement sequence is already in progress.

Characteristics

*RST value: –

SCPI: device–specific

Mode

CONFigure:LIST:SINGle

This command configures for a frequency list measurement in single sweep mode.

This command is an event and therefore has no *RST value and no query.

Example

CONF:LIST:SING

Configures to run frequency list measurement in single sweep modes.

INIT

Starts a new measurement, if no measurement sequence is already in progress.

Characteristics

*RST value: –

SCPI: device–specific

Mode

CONFigure:SINGle

This command configures for a fixed frequency measurement.

This command is an event and therefore has no *RST value and no query.

Example

CONF:SING

Configures to run fixed frequency measurements.

INIT

Starts a new measurement, if no measurement sequence is already in progress.

Characteristics

*RST value: –

SCPI: device–specific

Mode

DISPlay Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.534 E-11

DISPlay Subsystem (Noise Figure, K30)

The DISPLay subsystem controls the selection and presentation of textual and graphic information as

well as of measurement data on the display.

Commands of the DISPlay Subsystem

–DISPlay:ARRay:MEMory<1...3>[:STATe]

–DISPlay:CURRent:DATA[:STATe]

–DISPlay:DATA:TRACe<1>

–DISPlay:FORMat

–DISPlay[:WINDow<1>]:TABLe

–DISPlay[:WINDow<1>]:TRACe<1|2>[:STATe]

–DISPlay[:WINDow<1>]:TRACe<1|2>:SYMBols

–DISPlay[:WINDow<1>]:TRACe<1|2>:X[:SCALe]

–DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:AUTO

–DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:BOTTom

–DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:RLEVel

–DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:RLEVel:AUTO

–DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:TOP

DISPlay:ARRay:MEMory<1...3>[:STATe]

This command switches the display of trace memory <n> on or off.

This command is available from firmware version 1.60.

Parameter

ON | OFF

Example

DISP:ARR:MEM2 ON

Switches on the display of memory 2.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

R&S FSL DISPlay Subsystem (Noise Figure, K30)

1300.2519.12 6.535 E-11

DISPlay:CURRent:DATA[:STATe]

This command switches the display of the current measurement results on or off.

This command is available from firmware version 1.60.

Parameter

ON | OFF

Example

DISP:CURR:DATA OFF

Removes the current result traces from display.

Characteristics

RST value: ON

SCPI: device–specific

Mode

DISPlay:DATA:TRACe<1>

This command specifies the type of noise results to be displayed in trace 1.

Only the numeric suffix <1> for noise results is valid.

Parameter

NFIGure noise figure results in dB

TEFFective noise temperature in K

Example

DISP:DATA:TRAC1 NFIG

Displays the noise figure results in trace 1.

Characteristics

*RST value: NFIGure

SCPI: device–specific

Mode

DISPlay:FORMat

This command activates or deactivates the combined trace display of noise and gain results.

Parameter

SPLit | SINGle

Example

DISP:FORM SPL

Displays noise and gain results in separate graphs.

DISPlay Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.536 E-11

Characteristics

*RST value: SING

SCPI: device–specific

Mode

DISPlay[:WINDow<1>]:TABLe

This command activates or deactivates the tabular result display.

Parameter

ON | OFF

Example

DISP:TABL ON

Displays the table of results.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

DISPlay[:WINDow<1>]:TRACe<1|2>[:STATe]

This command activates or deactivates the display of the corresponding trace and related

information.

The numeric suffixes <1|2> indicate the measurement results: Trace 1 is always used for noise

results, and trace 2 is always used for gain results.

Parameter

ON | OFF

Example

DISP:TRAC OFF

Switches off the display of trace 1 (noise results).

DISP:TRAC2 OFF

Switches off the display of trace 2 (gain results).

Characteristics

*RST value: ON for both traces

SCPI: conform

Mode

R&S FSL DISPlay Subsystem (Noise Figure, K30)

1300.2519.12 6.537 E-11

DISPlay[:WINDow<1>]:TRACe<1|2>:SYMBols

This command activates or deactivates the display of the symbols to mark the measurement

points for the specified trace.

The numeric suffixes <1|2> indicate the measurement results: Trace 1 is always used for noise

results, and trace 2 is always used for gain results.

Parameter

ON | OFF

Example

DISP:TRAC ON

Switches on the display of trace 1 (noise results).

DISP:TRAC:SYMB ON

Switches on the display of symbols for trace 1 (noise results)

Characteristics

*RST value: OFF for both traces

SCPI: device–specific

Mode

DISPlay[:WINDow<1>]:TRACe<1|2>:X[:SCALe]

This command selects the frequency to be displayed on the x–axis if the DUT is not an

amplifier, i.e. in a frequency–converting measurement mode.

The numeric suffixes <1|2> indicate the measurement results: Trace 1 is always used for noise

results, and trace 2 is always used for gain results.

Parameter

IF | RF

Example

CONF:MODE:DUT DOWN

The DUT converts the input frequency to a lower output frequency.

DISP:TRAC:X IF

The IF frequency is displayed on x–axis.

Characteristics

*RST value: RF

SCPI: device–specific

Mode

DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:AUTO

This command activates or deactivates the automatic scaling of the Y–axis for the specified

trace display. Automatic scaling provides best fit of the Y–axis to the measurement results.

The numeric suffixes <1|2> indicate the measurement results: Trace 1 is always used for noise

results, and trace 2 is always used for gain results.

Parameter

ON | OFF

DISPlay Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.538 E-11

Example

DISP:TRAC2 ON

Switches on the display of trace 2 (gain results).

DISP:TRAC2:Y:AUTO ON

Switches on automatic scaling of the Y–axis for trace 2.

Characteristics

*RST value: ON for both traces

SCPI: conform

Mode

DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:BOTTom

This command sets the minimum (bottom) Y–axis display value for the specified trace display. It

has no affect if automatic scaling of the Y–axis is enabled

(DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:AUTO command).

The numeric suffixes <1|2> indicate the measurement results: Trace 1 is always used for noise

results, and trace 2 is always used for gain results.

Parameter

noise figure: –75 dB to 75 dB

noise temperature: –999990000 K to 999990000 K

gain: –75 dB to 75 dB

Example 1

DISP:DATA:TRAC1 NFIG

Sets the noise figure to trace1.

DISP:TRAC ON

Switches on the display of trace 1 (noise results).

DISP:TRAC:Y:BOTT –30

Sets the minimum Y–axis display to –30 dB for trace 1.

Example 2

DISP:DATA:TRAC1 TEFF

Sets the noise temperature to trace1.

DISP:TRAC ON

Switches on the display of trace 1 (noise results).

DISP:TRAC:Y:BOTT 100

Sets the minimum Y–axis display to 100 K for trace 1.

Example 3

DISP:TRAC2 ON

Switches on the display of trace 2 (gain results).

DISP:TRAC2:Y:BOTT 1

Sets the minimum Y–axis display to 1 dB for trace 2.

Characteristics

*RST value: 0 dB

SCPI: conform

Mode

R&S FSL DISPlay Subsystem (Noise Figure, K30)

1300.2519.12 6.539 E-11

DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:RLEVel

This command sets the reference level for the Y–axis display value for all trace displays. This

command has no affect if automatic reference level detection is enabled

(DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:RLEVel:AUTO command).

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

<numeric_value> in dBm, range specified in data sheet

Example

DISP:TRAC:Y:RLEV 0

Sets the reference level 0 dBm

Characteristics

*RST value: –30 dBm

SCPI: conform

Mode

DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:RLEVel:AUTO

This command enables or disables the automatic reference level detection.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

DISP:TRAC:Y:RLEV:AUTO ON

Turns on automatic reference level detection.

Characteristics

*RST value: ON

SCPI: conform

Mode

DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:TOP

This command sets the maximum (top) Y–axis display value for the specified trace display. It

has no affect if automatic scaling of the Y–axis is enabled or the specified trace is not currently

active.

The numeric suffixes <1|2> indicate the measurement results: Trace 1 is always used for noise

results, and trace 2 is always used for gain results.

Parameter

noise figure: –75 dB to 75 dB

noise temperature: –999990000 K to 999990000 K

gain: –75 dB to 75 dB

DISPlay Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.540 E-11

Example 1

DISP:DATA:TRAC1 NFIG

Sets the noise figure to trace1.

DISP:TRAC:Y:TOP 30

Sets the maximum Y–axis display to 30 dB for trace 1.

Example 2

DISP:DATA:TRAC1 TEFF

Sets the noise temperature to trace1.

DISP:TRAC:Y:TOP 100

Sets the maximum Y–axis display to 100 K for trace 1.

Example 3

DISP:TRAC2:Y:TOP 10

Sets the maximum Y–axis display to 10 dB for trace 2.

Characteristics

*RST value: 20 dB for noise and gain figure, 10000K for noise temperature

SCPI: conform

Mode

R&S FSL FETCh Subsystem (Noise Figure, K30)

1300.2519.12 6.541 E-11

FETCh Subsystem (Noise Figure, K30)

The FETCh subsystem retrieves results for the most recently completed fixed frequency or frequency

list measurements. Frequency list results are returned as a list of results where the result is that

requested in the specific fetch command. Single frequency results are single numbers in the described

units.

Note: Corrected measurements are only accessible after a calibration has been performed.

Commands of the FETCh Subsystem

–FETCh:ARRay:MEMory<1...3>:NOISe:FIGure?

–FETCh:ARRay:MEMory<1...3>:NOISe:GAIN?

–FETCh:ARRay:MEMory<1...3>:NOISe:TEMPerature?

–FETCh:ARRay:NOISE:FIGure?

–FETCh:ARRay:NOISE:GAIN?

–FETCh:ARRay:NOISE:TEMPerature?

–FETCh:SCALar:NOISE:FIGure?

–FETCh:SCALar:NOISE:GAIN?

–FETCh:SCALar:NOISE:TEMPerature?

FETCh:ARRay:MEMory<1...3>:NOISe:FIGure?

This command queries the noise measurement results of the selected memory. The results are

returned as an array of up to 100 elements of noise figure results. This command produces an

error if no data is held in the selected trace memory.

This command is only a query and therefore has no *RST value.

This command is available from firmware version 1.60.

Example

INIT

Starts a new measurement, if no measurement sequence is already in progress.

CONF:ARR:MEM2 ONCE

Copies the last recorded measurement result into the memory 2.

FETC:ARR:MEM2:NOIS:FIG?

Returns an array of 100 noise figure results from the selected memory 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

FETCh Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.542 E-11

FETCh:ARRay:MEMory<1...3>:NOISe:GAIN?

This command queries the noise measurement results of the selected memory. The results are

returned as an array of up to 100 elements of noise gain results. This command produces an

error if no data is held in the selected trace memory.

This command is only a query and therefore has no *RST value.

This command is available from firmware version 1.60.

Example

INIT

Starts a new measurement, if no measurement sequence is already in progress.

CONF:ARR:MEM2 ONCE

Copies the last recorded measurement result into the memory 2.

FETC:ARR:MEM2:NOIS:GAIN?

Returns an array of 100 noise gain results from the selected memory 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

FETCh:ARRay:MEMory<1...3>:NOISe:TEMPerature?

This command queries the noise measurement results of the selected memory. The results are

returned as an array of up to 100 elements of noise temperature results. This command

produces an error if no data is held in the selected trace memory.

This command is only a query and therefore has no *RST value.

This command is available from firmware version 1.60.

Example

INIT

Starts a new measurement, if no measurement sequence is already in progress.

CONF:ARR:MEM2 ONCE

Copies the last recorded measurement result into the memory 2.

FETC:ARR:MEM2:NOIS:TEMP?

Returns an array of 100 noise temperature results from the selected memory 2.

Characteristics

RST value: –

SCPI: device–specific

Mode

R&S FSL FETCh Subsystem (Noise Figure, K30)

1300.2519.12 6.543 E-11

FETCh:ARRay:NOISE:FIGure?

This command queries the last recorded noise figure measurement results. The results are

returned as an array of up to 100 elements of noise figure results.

This command is only a query and therefore has no *RST value.

Example

FETCh:ARRay:NOISE:FIGure?

Returns an array of 100 measured elements associated with the last noise figure measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

FETCh:ARRay:NOISE:GAIN?

This command queries the last recorded noise gain measurement results. The results are

returned as an array of up to 100 elements of noise gain results.

This command is only a query and therefore has no *RST value.

Example

FETCh:ARRay:NOISE:GAIN?

Returns an array of 100 measured elements associated with the last noise gain measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

FETCh:ARRay:NOISE:TEMPerature?

This command queries the last recorded noise temperature measurement results. The results

are returned as an array of up to 100 elements of noise temperature results.

This command is only a query and therefore has no *RST value.

Example

FETCh:ARRay:NOISE:TEMPerature?

Returns an array of 100 measured elements associated with the last noise temperature

measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

FETCh Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.544 E-11

FETCh:SCALar:NOISE:FIGure?

This command queries the last recorded noise figure measurement result for a fixed frequency

measurement.

This command is only a query and therefore has no *RST value.

Example

FETCh:SCAL:NOISE:FIGure?

Returns the last noise figure measurement obtained from a fixed frequency measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

FETCh:SCALar:NOISE:GAIN?

This command queries the last recorded noise gain measurement result for a fixed frequency

measurement.

This command is only a query and therefore has no *RST value.

Example

FETCh:SCAL:NOISE:GAIN?

Returns the last noise gain measurement obtained from a fixed frequency measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

FETCh:SCALar:NOISE:TEMPerature?

This command queries the last recorded noise temperature measurement result for a fixed

frequency measurement.

This command is only a query and therefore has no *RST value.

Example

FETCh:SCAL:NOISE:TEMPerature?

Returns the last noise temperature measurement obtained from a fixed frequency

measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

R&S FSL INITiate Subsystem (Noise Figure, K30)

1300.2519.12 6.545 E-11

INITiate Subsystem (Noise Figure, K30)

The INITiate subsystem configures the instrument prior to a measurement being carried out. It is

basically used to tell the instrument which measurement is to be performed and takes any necessary

step to set up the instrument for the measurement.

Commands of the INPut Subsystem

–INITiate[:IMMediate]

INITiate[:IMMediate]

This command initiates the start of a new measurement sequence. If a measurement sequence

is already in progress, the command is ignored.

This command is an event and therefore has no *RST value and no query.

Example

INIT

Starts a new measurement, if no measurement sequence is already in progress.

Characteristics

*RST value: –

SCPI: conform

Mode

INPut Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.546 E-11

INPut Subsystem (Noise Figure, K30)

The INPut subsystem controls the input characteristics of the RF inputs of the instrument.

Commands of the INPut Subsystem

–INPut<1|2>:ATTenuation

–INPut<1|2>:GAIN:STATe (option RF Preamplifier, B22)

INPut<1|2>:ATTenuation

For details refer to "INPut<1|2>:ATTenuation" on page 6.150.

INPut<1|2>:GAIN:STATe (option RF Preamplifier, B22)

For details refer to "INPut<1|2>:GAIN:STATe" on page 6.151.

R&S FSL INSTrument Subsystem (Noise Figure, K30)

1300.2519.12 6.547 E-11

INSTrument Subsystem (Noise Figure, K30)

Commands of the INSTrument Subsystem

–INSTrument[:SELect]

–INSTrument:NSELect

INSTrument[:SELect]

Parameter

NOISe (Noise Figure Measurements option, R&S FSL–K30)

For further details refer to section "INSTrument Subsystem".

INSTrument:NSELect

Parameter

19 (Noise Figure Measurements option, R&S FSL–K30)

For further details refer to section "INSTrument Subsystem".

SENSe Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.548 E-11

SENSe Subsystem (Noise Figure, K30)

The SENSe subsystem is used to set and query the values of parameters in the remote instrument.

:DEFault If a parameter has a default a value, the command parameter can be substituted with

:DEFault which loads the default (reset) value of the parameter.

:UP/DOWN In addition, all numeric values are able to take :UP or :DOWN in place of the

parameter. This will increment or decrement the numeric value.

:MIN/MAX In addition, all numeric values are able to take either :MINimum or :MAXimum as

arguments to determine the minimum or maximum range available for the command.

The SENSe subsystem is divided into equipment settings and measurement settings:

•"Equipment Settings" on page 6.548

•"Measurement Settings" on page 6.554

Equipment Settings

Commands of the equipment settings

–[SENSe:]CORRection[:STATe]

–[SENSe:]CORRection:ENR:MODE

–[SENSe:]CORRection:ENR:SPOT

–[SENSe:]CORRection:ENR[:MEASurement]:TABLe:DATA

–[SENSe:]CORRection:IREJection

–[SENSe:]CORRection:LOSS:INPut:MODE

–[SENSe:]CORRection:LOSS:INPut:SPOT

–[SENSe:]CORRection:LOSS:INPut:TABLe

–[SENSe:]CORRection:LOSS:OUTPut:MODE

–[SENSe:]CORRection:LOSS:OUTPut:SPOT

–[SENSe:]CORRection:LOSS:OUTPut:TABLe

–[SENSe:]CORRection:TEMPerature

[SENSe:]CORRection[:STATe]

This command activates or deactivates the second stage correction.

Parameter

ON | OFF

Example

CORR ON

Activates the second stage correction.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

R&S FSL SENSe Subsystem (Noise Figure, K30)

1300.2519.12 6.549 E-11

[SENSe:]CORRection:ENR:MODE

This command specifies whether a constant ENR value applies for all measured frequencies or

an ENR table (ENR values specified at specific input frequencies). The constant ENR value is

specified by the [SENSe:]CORRection:ENR:SPOT command.

Parameter

TABLe ENR table is used.

SPOT Constant ENR value is used.

Example

CORR:ENR:MODE SPOT

Uses the configured constant ENR value for all measured frequencies.

Characteristics

*RST value: SPOT

SCPI: device–specific

Mode

[SENSe:]CORRection:ENR:SPOT

This command sets the constant ENR value of the noise source that is used throughout the

entire frequency range.

Parameter

–999.99 to 999.99 dB

Example

CORR:ENR:MODE SPOT

Uses the configured constant ENR value for all measured frequencies.

CORR:ENR:SPOT 30

Sets the constant ENR value to 30 dB for all input frequencies to be measured.

Characteristics

*RST value: 15 dB

SCPI: device–specific

Mode

[SENSe:]CORRection:ENR[:MEASurement]:TABLe:DATA

This command specifies a new ENR table to determine the correct ENR (excess noise ratio)

figure to be used for the input frequencies. This new list completely overwrites all current ENR

f re qu en c y li st entri e s r eg ar dle ss of h o w m any e ntries a r e pr esent a nd h ow m a n y entr ie s are bein g

s u ppl i e d for the ne w l is t .

Parameter

<numeric_value>,<numeric_value>, ... (maximum of 100 argument pairs)

numeric value = a frequency ENR pair of arguments

frequency: 0 Hz to 999.99 GHz.

ENR figure: –999.99 to 999.99 (value in dB, accurate to two decimal places)

SENSe Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.550 E-11

Example

CORR:ENR:MODE TABL

Uses the ENR table.

CORR:ENR:MEAS:TABL:DATA 1MHZ,10,2MHZ,12

Specifies a new ENR table and overwrites the current ENR table with the two entry pairs

specified.

Characteristics

*RST value: –

SCPI: device–specific

Mode

[SENSe:]CORRection:IREJection

This command specifies an image rejection value for the selected DUT

([SENSe:]CONFigure:MODE:DUT command) which will be effective throughout the entire

frequency range.

Parameter

0dB to 999.99 dB

Example

CONF:MODE:DUT DOWN

The DUT converts the input frequency to a lower output frequency.

CORR:IREJ 100

Sets an image rejection value of 100 dB.

Characteristics

*RST value: 999.99 dB

SCPI: device–specific

Mode

[SENSe:]CORRection:LOSS:INPut:MODE

This command specifies whether a constant input loss value applies for all measured

frequencies or an input loss list (loss input values specified at specific input frequencies). The

constant loss input value is specified by the [SENSe:]CORRection:LOSS:INPut:SPOT

command.

Parameter

SPOT The constant loss input value for all measurement frequencies is used.

TABLe The loss input table is used.

Example

CORR:LOSS:INP:MODE SPOT

Uses the configured constant loss input value for all input frequencies to be measured.

R&S FSL SENSe Subsystem (Noise Figure, K30)

1300.2519.12 6.551 E-11

Characteristics

*RST value: SPOT

SCPI: device–specific

Mode

[SENSe:]CORRection:LOSS:INPut:SPOT

This command specifies the loss input constant for all input frequencies to be measured.

Parameter

–999.99 to 999.99 dB, accurate to two decimal places

Example

CORR:LOSS:INP:MODE SPOT

Uses the configured constant loss input value for all input frequencies to be measured.

CORR:LOSS:INP:SPOT 10

Sets the internal input loss constant value to 10 dB for all input frequencies to be measured.

Characteristics

*RST value: 0 dB

SCPI: device–specific

Mode

[SENSe:]CORRection:LOSS:INPut:TABLe

This command specifies a new input loss table to determine the correct input loss to be used for

the input frequencies. This new list completely overwrites all current input loss list entries

regardless of how many entries are present and how many entries are being supplied for the

new list.

Parameter

<numeric_value>,<numeric_value>,... (maximum of 100 argument pairs)

<numeric_value>,<numeric_value> = a frequency loss pair of arguments

frequency: 0 Hz to 999.99 GHz (max. two decimal places)

loss figure: –999.99 to 999.99 (value in dB, accurate to two decimal places)

Example

CORR:LOSS:INP:MODE TABL

Uses the loss input table.

CORR:LOSS:INP:TABL 1MHz,10,2MHz,12

Specifies a new input loss table and overwrites the current input loss table with the two entry

pairs specified.

Characteristics

*RST value: –

SCPI: device–specific

Mode

SENSe Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.552 E-11

[SENSe:]CORRection:LOSS:OUTPut:MODE

This command specifies whether a constant output loss value applies for all measured

frequencies or an output loss list (loss output values specified at specific input frequencies). The

constant loss output value is specified by the [SENSe:]CORRection:LOSS:OUTPut:SPOT

command.

Parameter

SPOT The constant loss input value for all measurement frequencies is used.

TABLe The loss input table is used.

Example

CORR:LOSS:OUTP:MODE SPOT

Uses the configured constant loss output value for all input frequencies to be measured.

Characteristics

*RST value: SPOT

SCPI: device–specific

Mode

[SENSe:]CORRection:LOSS:OUTPut:SPOT

This command specifies the loss output constant for all input frequencies to be measured.

Parameter

–999.99 to 999.99 dB, accurate to two decimal places

Example

CORR:LOSS:OUTP:MODE SPOT

Uses the configured constant loss output value for all input frequencies to be measured.

CORR:LOSS:OUTP:SPOT 10

Sets the internal output loss constant value to 10 dB for all input frequencies to be measured.

Characteristics

*RST value: 0 dB

SCPI: device–specific

Mode

[SENSe:]CORRection:LOSS:OUTPut:TABLe

This command specifies a new output loss table to determine the correct output loss to be used

for the input frequencies. This new list completely overwrites all current output loss list entries

regardless of how many entries are present and how many entries are being supplied for the

new list.

Parameter

<numeric_value>,<numeric_value>,... (maximum of 100 argument pairs)

<numeric_value>,<numeric_value> = a frequency loss pair of arguments

frequency: 0 Hz to 999.99 GHz (max. two decimal places)

loss figure: –999.99 to 999.99 (value in dB, accurate to two decimal places)

R&S FSL SENSe Subsystem (Noise Figure, K30)

1300.2519.12 6.553 E-11

Example

CORR:LOSS:OUTP:MODE TABL

Uses the loss output table.

CORR:LOSS:OUTP:TABL 1MHz,10,2MHz,12

Specifies a new output loss table and overwrites the current output loss table with the two entry

pairs specified.

Characteristics

*RST value: –

SCPI: device–specific

Mode

[SENSe:]CORRection:TEMPerature

This command specifies the room temperature of the operating environment. This value is taken

into account when calculating noise results.

Parameter

278.15 to 318.15 K; up to 2 decimal places can be specified.

Example

CORR:TEMP 291.50

Specifies the room temperature to 291.50 Kelvin (18.5 C).

Characteristics

*RST value: 293 K

SCPI: device–specific

Mode

SENSe Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.554 E-11

Measurement Settings

Commands of the measurement settings

–[SENSe:]BANDwidth|BWIDth[:RESolution]

–[SENSe:]CONFigure:MODE:DUT

–[SENSe:]CONFigure:MODE:SYSTem:LOSCillator:FREQuency

–[SENSe:]FREQuency[:CW|:FIXed]

–[SENSe:]FREQuency:LIST:DATA

–[SENSe:]FREQuency:STARt

–[SENSe:]FREQuency:STEP

–[SENSe:]FREQuency:STOP

–[SENSe:]SWEep:COUNt

–[SENSe:]SWEep:TIME

[SENSe:]BANDwidth|BWIDth[:RESolution]

For details refer to "[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]" on page 6.175.

[SENSe:]CONFigure:MODE:DUT

This command defines the type of DUT. This setting determines the method that is used to

create the frequency measurement list. Fixed local oscillator frequencies are taken from the

settings supplied by [SENSe:]CONFigure:MODE:SYSTem:LOSCillator:FREQuency.

Parameter

AMPLifier The DUT is an amplifier and not a frequency converting device.

DOWNconv The DUT converts the input frequency to a lower output frequency:

Fixed LO, IF=RF+LO

UPConv The DUT converts the input frequency to a higher output frequency:

Fixed LO, IF=abs(RF–LO).

Example

SENS:CONF:MODE:DUT DOWN

The DUT converts the input frequency to a lower output frequency.

Characteristics

*RST value: AMPLifier

SCPI: device–specific

Mode

R&S FSL SENSe Subsystem (Noise Figure, K30)

1300.2519.12 6.555 E-11

[SENSe:]CONFigure:MODE:SYSTem:LOSCillator:FREQuency

This command specifies a fixed local oscillator frequency for a new frequency measurement list

in frequency–converting measurement mode. If this value is altered, a new frequency list is

generated.

Parameter

0Hz to 999.99 GHz

Example

SENS:CONF:MODE:DUT DOWN

The DUT converts the input frequency to a lower output frequency.

SENS:CONF:MODE:SYST:LOSC:FREQ 1MHZ

Specifies the fixed local oscillator frequency for a new list to a value of 1 MHz.

Characteristics

*RST value: – 0 Hz

SCPI: device–specific

Mode

[SENSe:]FREQuency[:CW|:FIXed]

This command specifies a fixed frequency to measure noise and gain continuously (fixed

frequency measurement).

Parameter

Example

CONF:SING

Configures to run fixed frequency measurements.

FREQ 10MHz

Sets a fixed frequency of 10 MHz.

Characteristics

*RST value: 550 MHz

SCPI: conform

Mode

[SENSe:]FREQuency:LIST:DATA

This command specifies a new frequency list (for frequency list measurement). Each list entry

consists of three separate frequency entities: a receive frequency (RF), a local oscillator

frequency (LO), and an intermediate frequency (IF). The new list completely overwrites all the

current frequency list entries regardless of how many entries are present and how many entries

are being supplied for the new list. The new list is the active list until a new list is automatically

created.

The values specified in this command are not used for a fixed frequency measurement

(CONFigure:SINGle command).

SENSe Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.556 E-11

Parameter

<numeric_value>,<numeric_value>, ... (max. of 100 argument)

numeric value = set of three frequency measurements in the following order: fixed frequency,

local oscillator frequency, and intermediate frequency. The frequency range depends on the

selected measurement mode:

direct measurement RF: 0 Hz to fmax

frequency–converting

measurement

RF, LO: 0 Hz to 999.99 GHz

IF: 0 Hz to fmax

Example

FREQ:LIST:DATA 550MHz,300MHz,900MHz

Specifies one entry frequency list with a receive frequency of 550 MHz, a local oscillator

frequency of 300 MHz, and an intermediate frequency of 900 MHz.

Characteristics

*RST value: 550 MHz | 0 Hz | 550 MHz

SCPI: device–specific

Mode

[SENSe:]FREQuency:STARt

This command specifies the start frequency for a new frequency measurement list. If this value

is altered, a new frequency list is generated.

Parameter

Example

FREQ:STAR 500MHZ

Sets the start frequency for a new list to a value of 500 MHz.

Characteristics

*RST value: 550 MHz

SCPI: conform

Mode

[SENSe:]FREQuency:STEP

This command specifies the step frequency for a new frequency measurement list. If this value

is altered, a new frequency list is generated.

Parameter

Example

FREQ:STEP 10MHZ

Sets the step frequency for a new list to a value of 10 MHz.

R&S FSL SENSe Subsystem (Noise Figure, K30)

1300.2519.12 6.557 E-11

Characteristics

*RST value: 2 MHz

SCPI: device–specific

Mode

[SENSe:]FREQuency:STOP

This command specifies the stop frequency for a new frequency measurement list. If this value

is altered, a new frequency list is generated.

Parameter

Example

FREQ:STOP 700MHZ

Sets the stop frequency for a new list to a value of 700 MHz.

Characteristics

*RST value: 560 MHz

SCPI: conform

Mode

[SENSe:]SWEep:COUNt

This command specifies the number of sweeps over which the measurement results are

averaged. The higher the number of sweeps, the more accurate the results. However, a high

number of sweeps requires a longer measurement time.

Parameter

1to 32767

Example

SWE:COUN 10

Sets the number of sweeps for averaging to 10.

Characteristics

*RST value: 1

SCPI: conform

Mode

[SENSe:]SWEep:TIME

For details refer to "[SENSe<1|2>:]SWEep:TIME" on page 6.234.

STATus Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.558 E-11

STATus Subsystem (Noise Figure, K30)

The STATus subsystem contains the commands for the status reporting system (See Section ""). *RST

does not influence the status registers.

Commands of the STATus subsystem

–STATus:QUEStionable:CORRection[:EVENt]?

–STATus:QUEStionable:CORRection:CONDition?

–STATus:QUEStionable:CORRection:ENABle

–STATus:QUEStionable:CORRection:NTRansition

–STATus:QUEStionable:CORRection:PTRansition

–STATus:QUEStionable:FREQuency[:EVENt]?

–STATus:QUEStionable:FREQuency:CONDition?

–STATus:QUEStionable:FREQuency:ENABle

–STATus:QUEStionable:FREQuency:NTRansition

–STATus:QUEStionable:FREQuency:PTRansition

–STATus:QUEStionable:LIMit<1|2> [:EVENt]?

–STATus:QUEStionable:LIMit<1|2>:CONDition?

–STATus:QUEStionable:LIMit<1|2>:ENABle

–STATus:QUEStionable:LIMit<1|2>:NTRansition

–STATus:QUEStionable:LIMit<1|2>:PTRansition

STATus:QUEStionable:CORRection[:EVENt]?

This command queries the contents of the EVENt section of the

STATus:QUEStionable:CORRection register. Readout deletes the contents of the EVENt

section.

Example

STAT:QUES:CORR?

Characteristics

*RST value: –

SCPI: conform

Mode

R&S FSL STATus Subsystem (Noise Figure, K30)

1300.2519.12 6.559 E-11

STATus:QUEStionable:CORRection:CONDition?

This command queries the contents of the CONDition section of the

STATus:QUEStionable:CORRection register. Readout does not delete the contents of the

CONDition section.

Example

STAT:QUES:CORR:COND?

Characteristics

*RST value: –

SCPI: conform

Mode

STATus:QUEStionable:CORRection:ENABle

This command sets the bits of the ENABle section of the STATus:QUEStionable:CORRection

section for the summary bit.

Parameter

0to 65535

Example

STAT:QUES:CORR:ENAB 65535

All events bits are represented in the CORRection summary bit.

Characteristics

*RST value: –

SCPI: conform

Mode

STATus:QUEStionable:CORRection:NTRansition

This command determines what bits in the STATus:QUESionable:CORRection Condition

that bit has a negative transition (1 to 0). The variable <number> is the sum of the decimal

values of the bits that are to be enabled.

Parameter

0to 65535

Example

STAT:QUES:CORR:NTR 65535

All condition bits are summarized in the Event register if a positive transition occurs.

Characteristics

*RST value: –

SCPI: conform

Mode

STATus Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.560 E-11

STATus:QUEStionable:CORRection:PTRansition

This command determines what bits in the STATus:QUESionable:CORRection Condition

that bit has a positive transition (0 to 1). The variable <number> is the sum of the decimal

values of the bits that are to be enabled.

Parameter

0to 65535

Example

STAT:QUES:CORR:PTR 65535

All condition bits are summarized in the Event register if a positive transition occurs.

Characteristics

*RST value: –

SCPI: conform

Mode

STATus:QUEStionable:FREQuency[:EVENt]?

For details refer to "STATus:QUEStionable:FREQuency[:EVENt]?" on page 6.244.

STATus:QUEStionable:FREQuency:CONDition?

For details refer to "STATus:QUEStionable:FREQuency:CONDition?" on page 6.244.

STATus:QUEStionable:FREQuency:ENABle

For details refer to "STATus:QUEStionable:FREQuency:ENABle" on page 6.244.

STATus:QUEStionable:FREQuency:NTRansition

This command determines what bits in the STATus:QUESionable:FREQuency Condition

bit has a negative transition (1 to 0). The variable <number> is the sum of the decimal values of

the bits that are to be enabled.

Parameter

0to 65535

Example

STAT:QUES:FREQ:NTR 65535

All condition bits are summarized in the Event register if a positive transition occurs.

Characteristics

*RST value: –

SCPI: conform

Mode

R&S FSL STATus Subsystem (Noise Figure, K30)

1300.2519.12 6.561 E-11

STATus:QUEStionable:FREQuency:PTRansition

This command determines what bits in the STATus:QUESionable:FREQuency Condition

bit has a positive transition (0 to 1). The variable <number> is the sum of the decimal values of

the bits that are to be enabled.

Parameter

0to 65535

Example

STAT:QUES:FREQ:PTR 65535

All condition bits are summarized in the Event register if a positive transition occurs.

Characteristics

*RST value: –

SCPI: conform

Mode

STATus:QUEStionable:LIMit<1|2> [:EVENt]?

For details refer to "STATus:QUEStionable:LIMit<1|2>[:EVENt]?" on page 6.245.

STATus:QUEStionable:LIMit<1|2>:CONDition?

For details refer to "STATus:QUEStionable:LIMit<1|2>:CONDition?" on page 6.246.

STATus:QUEStionable:LIMit<1|2>:ENABle

For details refer to "STATus:QUEStionable:LIMit<1|2>:ENABle" on page 6.246.

STATus:QUEStionable:LIMit<1|2>:NTRansition

This command determines what bits in the STATus:QUESionable:LIMit Condition register set

the corresponding bit in the STATus:QUESionable:LIMit Event register if that bit has a negative

transition (1 to 0). The variable <number> is the sum of the decimal values of the bits that are to

be enabled.

Parameter

0to 65535

Example

STAT:QUES:NTR 65535

All condition bits are summarized in the Event register if a positive transition occurs.

Characteristics

*RST value: –

SCPI: device–specific

Mode

STATus Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.562 E-11

STATus:QUEStionable:LIMit<1|2>:PTRansition

This command determines what bits in the STATus:QUESionable:LIMit Condition register set

the corresponding bit in the STATus:QUESionable:LIMit Event register if that bit has a positive

transition (0 to 1). The variable <number> is the sum of the decimal values of the bits that are to

be enabled.

Parameter

0to 65535

Example

STAT:QUES:PTR 65535

All condition bits are summarized in the Event register if a positive transition occurs.

Characteristics

*RST value: –

SCPI: device–specific

Mode

R&S FSL SYSTem Subsystem (Noise Figure, K30)

1300.2519.12 6.563 E-11

SYSTem Subsystem (Noise Figure, K30)

This subsystem contains a series of commands for general functions.

Commands of the SYSTem subsystem

–SYSTem:CONFigure:DUT:GAIN

–SYSTem:CONFigure:DUT:STIMe

SYSTem:CONFigure:DUT:GAIN

This command specifies the maximum gain of the DUT.

Parameter

10 dB to 999.99 dB

Example

SYST:CONF:DUT:GAIN 10

Specifies the gain of the DUT to be 10 dB.

Characteristics

*RST value: 30 dB

SCPI: device–specific

Mode

SYSTem:CONFigure:DUT:STIMe

This command spcifies the DUT settling time. It represents the time to wait for the DUT to settle

after a noise source has been turned on or off.

Parameter

0to 20 s

Example

SYST:CONF:DUT:STIM 1000MS

Specifies a period of one second for the DUT to settle down after exposure to the noise source

has been removed.

Characteristics

*RST value: 50 milliseconds

SCPI: device–specific

Mode

SYSTem Subsystem (Noise Figure, K30) R&S FSL

1300.2519.12 6.564 E-11

Remote Commands of the 3GPP Base Station

Measurements Option (K72)

This section describes the remote commands for the 3GPP Base Station Measurements option (K72).

The abbreviation WCDMA stands for the operating mode of this option. For details on conventions used

in this chapter refer to section "Notation" on page 6.2 at the beginning of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in section "Remote Commands of the Base Unit" on page 6.5.

This option is available from firmware version 1.60.

Subsystems of the 3GPP Base Station Measurements option (K72)

–"ABORt Subsystem (WCDMA, K72)" on page 6.565

–"CALCulate Subsystem (WCDMA, K72)" on page 6.566

–"CONFigure:WCDPower Subsystem (WCDMA, K72)" on page 6.576

–"DISPlay Subsystem (WCDMA, K72)" on page 6.577

– "INITiate Subsystem (WCDMA, K72)" on page 6.579

–"INPut Subsystem (WCDMA, K72)" on page 6.580

–"INSTrument Subsystem (WCDMA, K72)" on page 6.581

–"SENSe Subsystem (WCDMA, K72)" on page 6.582

–"STATus:QUEStionable Subsystem (WCDMA, K72)" on page 6.591

–"TRACe Subsystem (WCDMA, K72)" on page 6.592

–"TRIGger Subsystem (WCDMA, K72)" on page 6.595

R&S FSL ABORt Subsystem (WCDMA, K72)

1300.2519.12 6.565 E-11

ABORt Subsystem (WCDMA, K72)

The ABORt subsystem contains the commands for aborting triggered actions.

Commands of the ABORt Subsystem

–ABORt

ABORt

For details refer to "ABORt" on page 6.10.

CALCulate Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.566 E-11

CALCulate Subsystem (WCDMA, K72)

The CALCulate subsystem contains commands for converting instrument data, transforming and

carrying out corrections. These functions are carried out subsequent to data acquisition, i.e. following

the SENSe subsystem.

The following subsystems are included:

•"CALCulate:DELTamarker Subsystem (WCDMA, K72)" on page 6.566

•"CALCulate:FEED Subsystem (WCDMA, K72)" on page 6.569

•"CALCulate:LIMit:ESPectrum (WCDMA, K72)" on page 6.570

•"CALCulate:MARKer Subsystem (WCDMA, K72)" on page 6.573

CALCulate:DELTamarker Subsystem (WCDMA, K72)

The CALCulate:DELTamarker subsystem controls the delta marker functions of the instrument.

Commands of the CALCulate:DELTamarker Subsystem

–CALCulate<1|2>:DELTamarker<1...4>[:STATe]

–CALCulate<1|2>:DELTamarker<1...4>:AOFF

–CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:CPICh

–CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PCCPch

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum:NEXT

–CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt

–CALCulate<1|2>:DELTamarker<1...4>:MINimum[:PEAK]

–CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT

–CALCulate<1|2>:DELTamarker<1...4>:MINimum:NEXT

–CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt

–CALCulate<1|2>:DELTamarker<1...4>:X

–CALCulate<1|2>:DELTamarker<1...4>:X:RELative?

–CALCulate<1|2>:DELTamarker<1...4>:Y?

CALCulate<1|2>:DELTamarker<1...4>[:STATe]

For details refer to "CALCulate<1|2>:DELTamarker<1...4>[:STATe]" on page 6.12.

CALCulate<1|2>:DELTamarker<1...4>:AOFF

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:AOFF" on page 6.13.

R&S FSL CALCulate Subsystem (WCDMA, K72)

1300.2519.12 6.567 E-11

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:CPICh

This command sets the active delta marker on the common pilot channel.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT1:FUNC:CPIC

Sets the active delta marker on the common pilot channel.

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PCCPch

This command sets the active delta marker on the primary common control physical channel.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:DELT1:FUNC:PCCP

Sets the active delta marker on the primary common control physical channel.

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

CALCulate<1|2>:DELTamarker<1...4>:MAXimum[:PEAK]

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MAXimum[:PEAK]" on page 6.17.

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT" on page 6.17.

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:NEXT

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MAXimum:NEXT" on page 6.17.

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt" on page 6.18.

CALCulate Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.568 E-11

CALCulate<1|2>:DELTamarker<1...4>:MINimum[:PEAK]

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MINimum[:PEAK]" on page 6.18.

CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT" on page 6.19.

CALCulate<1|2>:DELTamarker<1...4>:MINimum:NEXT

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MINimum:NEXT" on page 6.19.

CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt" on page 6.19.

CALCulate<1|2>:DELTamarker<1...4>:X

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:X" on page 6.21.

CALCulate<1|2>:DELTamarker<1...4>:X:RELative?

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:X:RELative?" on page 6.21.

CALCulate<1|2>:DELTamarker<1...4>:Y?

For details refer to "CALCulate<1|2>:DELTamarker<1...4>:Y?" on page 6.22.

R&S FSL CALCulate Subsystem (WCDMA, K72)

1300.2519.12 6.569 E-11

CALCulate:FEED Subsystem (WCDMA, K72)

The CALCulate:FEED subsystem selects the evaluation method of the measured code domain power

data. This corresponds to the selection of the result display in manual mode.

Commands of the CALCulate:FEED Subsystem

–CALCulate<1|2>:FEED

CALCulate<1|2>:FEED

This command selects the result display for the Code Domain Power Diagram measurement.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

Result display Display format

XPOWer:CDP Code Domain Power Diagram

in relative scaling

bar graph

XPOWer:CDP:ABSolute Code Domain Power Diagram

in absolute scaling

bar graph

XTIMe:CDPower:ERRor:CTABle Code Domain Channel Table channel assignment table

XTIMe:CDPower:ERRor:SUMMary Code Domain Result Summary

(default setting)

results in table format

Example

CALC:FEED 'XPOW:CDP'

Selects the Code Domain Power Diagram result display in absolute scaling.

Characteristics

RST value: –

SCPI: conform

Mode

WCDMA

CALCulate Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.570 E-11

CALCulate:LIMit:ESPectrum (WCDMA, K72)

The CALCulate:LIMit:ESPectrum subsystem defines limit checking for RF measurements.

Commands of the CALCulate:LIMit:ESPectrum Subsystem

–CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE

–CALCulate<1|2>:LIMit<1...8>:ESPectrum:RESTore

–CALCulate<1|2>:LIMit<1...8>:ESPectrum:TRANsition

–CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue

CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE

This command activates or deactivates automatic selection of the limit line in the spectrum

emission mask measurement.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

Parameter

AUTO Sets the limit line automatically according to the power determined in the useful

channel.

MANual Activates the selected predefined limit lines.

The selection is made with the

CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue command.

USER Activates the user–defined limit lines.

(for details refer to "Using Limit Lines and Display Lines – LINES Key").

Example

CONF:WCDP:MEAS ESP

Selects the spectrum emission mask measurement.

CALC:LIM:ESP:MODE MAN

Activates the selected predefined limit lines.

Characteristics

RST value: AUTO

SCPI: device–specific

Mode

WCDMA

CALCulate<1|2>:LIMit<1...8>:ESPectrum:RESTore

This command restores the predefined limit lines for the spectrum emission mask

measurement. All modifications made to the predefined limit lines are lost and the factory–set

values are restored.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

CONF:WCDP:MEAS ESP

Selects the spectrum emission mask measurement.

CALC:LIM:ESP:REST

Sets the spectrum emission mask limit lines back to the factory–set values.

R&S FSL CALCulate Subsystem (WCDMA, K72)

1300.2519.12 6.571 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

CALCulate<1|2>:LIMit<1...8>:ESPectrum:TRANsition

This command defines the offset frequency at which the resolution bandwidth is changed.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

Parameter

30 kHz to 1 MHz

Example

CONF:WCDP:MEAS ESP

Selects the spectrum emission mask measurement.

CALC:LIM:ESP:TRAN 5MHZ

Defines the offset frequency at which the resolution bandwidth is changed.

Characteristics

RST value: 4.0 MHz

SCPI: device–specific

Mode

WCDMA

CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue

This command selects one of the following predefined limit lines. As a prerequisite, the

predefined limit lines must be activated using the

CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE command.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

Parameter

43 P



43 dBm

39 39 dBm



P < 43 dBm

31 31 dBm



P < 39 dBm

0 P < 31 dBm

Pstands for the expected power value.

Example

CONF:WCDP:MEAS ESP

Selects the spectrum emission mask measurement.

CALC:LIM:ESP:MODE MAN

Activates the selected predefined limit lines.

CALC:LIM:ESP:VAL 39

Selects the predefined limit line 39 dBm



P < 43 dBm.

CALCulate Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.572 E-11

Characteristics

RST value: 0

SCPI: device–specific

Mode

WCDMA

R&S FSL CALCulate Subsystem (WCDMA, K72)

1300.2519.12 6.573 E-11

CALCulate:MARKer Subsystem (WCDMA, K72)

The CALCulate:MARKer subsystem checks the marker functions of the instrument.

Commands of the CALCulate:MARKer Subsystem

–CALCulate<1|2>:MARKer<1...4>[:STATe]

–CALCulate<1|2>:MARKer<1...4>:AOFF

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:CPICh

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:PCCPch

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:WCDPower[:BTS]:RESult?

–CALCulate<1|2>:MARKer<1...4>:MAXimum[:PEAK]

–CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT

–CALCulate<1|2>:MARKer<1...4>:MAXimum:NEXT

–CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt

–CALCulate<1|2>:MARKer<1...4>:MINimum[:PEAK]

–CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT

–CALCulate<1|2>:MARKer<1...4>:MINimum:NEXT

–CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt

–CALCulate<1|2>:MARKer<1...4>:X

–CALCulate<1|2>:MARKer<1...4>:Y?

CALCulate<1|2>:MARKer<1...4>[:STATe]

For details refer to "CALCulate<1|2>:MARKer<1...4>[:STATe]" on page 6.56.

CALCulate<1|2>:MARKer<1...4>:AOFF

For details refer to "CALCulate<1|2>:MARKer<1...4>:AOFF" on page 6.56.

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CPICh

This command sets the active marker on the common pilot channel.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:MARK1:FUNC:CPIC

Sets the active marker on the common pilot channel.

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

CALCulate Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.574 E-11

CALCulate<1|2>:MARKer<1...4>:FUNCtion:PCCPch

This command sets the active marker on the primary common control physical channel.

This command is an event and therefore has no *RST value and no query.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:MARK1:FUNC:PCCP

Sets the active marker on the primary common control physical channel.

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

CALCulate<1|2>:MARKer<1...4>:FUNCtion:WCDPower[:BTS]:RESult?

This command queries the measured and calculated results of the code domain power

measurement. The results are calculated from the recorded IQ data set.

This command is only a query and therefore has no *RST value.

The numeric suffixes <1|2> and <1...4> are irrelevant for this command.

Parameter

CDPabsolute channel power absolute

CDPRelative channel power relative

CERRor chip rate error

CHANnel channel number

CSLot channel slot number

EVMRms error vector magnitude RMS

FERRor frequency error in Hz

IQIMbalance I/Q imbalance

IQOFfset I/Q offset

MACCuracy composite EVM

MTYPe modulation type

PCDerror peak code domain error

PTOTal total power

RHO rho value for every slot

SRATe symbol rate

TFRame trigger to frame

TOFFset timing offset

Example

CALC:MARK:FUNC:WCDP:RES? CDP

Queries the absolute channel power.

R&S FSL CALCulate Subsystem (WCDMA, K72)

1300.2519.12 6.575 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

CALCulate<1|2>:MARKer<1...4>:MAXimum[:PEAK]

For details refer to "CALCulate<1|2>:MARKer<1...4>:MAXimum[:PEAK]" on page 6.58.

CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT

For details refer to "CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT" on page 6.59.

CALCulate<1|2>:MARKer<1...4>:MAXimum:NEXT

For details refer to "CALCulate<1|2>:MARKer<1...4>:MAXimum:NEXT" on page 6.60.

CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt

For details refer to "CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt" on page 6.60.

CALCulate<1|2>:MARKer<1...4>:MINimum[:PEAK]

For details refer to "CALCulate<1|2>:MARKer<1...4>:MINimum[:PEAK]" on page 6.60.

CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT

For details refer to "CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT" on page 6.61.

CALCulate<1|2>:MARKer<1...4>:MINimum:NEXT

For details refer to "CALCulate<1|2>:MARKer<1...4>:MINimum:NEXT" on page 6.62.

CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt

For details refer to "CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt" on page 6.62.

CALCulate<1|2>:MARKer<1...4>:X

For details refer to "CALCulate<1|2>:MARKer<1...4>:X" on page 6.64.

CALCulate<1|2>:MARKer<1...4>:Y?

For details refer to "CALCulate<1|2>:MARKer<1...4>:Y?" on page 6.66.

CONFigure:WCDPower Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.576 E-11

CONFigure:WCDPower Subsystem (WCDMA, K72)

The CONFigure subsystem contains commands for configuring the measurements.

Commands of the CONFigure:WCDPower Subsystem

–CONFigure:WCDPower:[BTS]:MEASurement

CONFigure:WCDPower:[BTS]:MEASurement

This command selects the measurements with their predefined settings according to the 3GPP

standard.

Parameter

ACLR adjacent–channel power measurement

ESPectrum measurement of spectrum emission mask

POWer channel power measurement

WCDPower code domain power measurement

Example

CONF:WCDP:MEAS POW

Selects the channel power measurement.

Characteristics

RST value: WCDP

SCPI: device–specific

Mode

WCDMA

R&S FSL DISPlay Subsystem (WCDMA, K72)

1300.2519.12 6.577 E-11

DISPlay Subsystem (WCDMA, K72)

The DISPLay subsystem controls the selection and presentation of textual and graphic information as

well as of measurement data on the display.

Commands of the DISPlay Subsystem

–DISPlay[:WINDow<1|2>]:TRACe<1...6>[:STATe]

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:PDIVision

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel:OFFSet

–DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

DISPlay[:WINDow<1|2>]:TRACe<1...6>[:STATe]

For details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>[:STATe]" on page 6.132.

DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE

Parameter

WRITe | VIEW | AVERage | MAXHold | MINHold

For details on trace modes refer to chapter "Instrument Functions", section "Trace mode

overview".

For further details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE" on page 6.132.

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:PDIVision

This command defines the scaling of the y–axis in dB.

The numeric suffixes <1|2> and <1...6> are irrelevant.

Parameter

0.01 to 100 dB

Example

DISP:TRAC:Y:PDIV +10DB

Sets the Y scale to 10 dB/div.

Characteristics

*RST value: 7

SCPI: conform

Mode

WCDMA

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel

For details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel" on page 6.135.

DISPlay Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.578 E-11

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel:OFFSet

For details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel:OFFSet" on

page 6.135.

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition

For details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition (models with

tracking generator)" on page 6.136.

R&S FSL INITiate Subsystem (WCDMA, K72)

1300.2519.12 6.579 E-11

INITiate Subsystem (WCDMA, K72)

The INITiate subsystem is used to control the init–measurement function.

Commands of the INITiate Subsystem

–INITiate<1|2>[:IMMediate]

–INITiate<1|2>:CONTinuous

INITiate<1|2>[:IMMediate]

For details refer to "INITiate<1|2>[:IMMediate]" on page 6.146.

INITiate<1|2>:CONTinuous

For details refer to "INITiate<1|2>:CONTinuous" on page 6.147.

INPut Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.580 E-11

INPut Subsystem (WCDMA, K72)

The INPut subsystem controls the input characteristics of the RF inputs of the instrument.

Commands of the INPut Subsystem

–INPut:ATTenuation

–INPut:ATTenuation:AUTO

–INPut:GAIN:STATe

INPut:ATTenuation

For details refer to "INPut<1|2>:ATTenuation" on page 6.150.

INPut:ATTenuation:AUTO

For details refer to "INPut<1|2>:ATTenuation:AUTO" on page 6.151.

INPut:GAIN:STATe

For details refer to "INPut<1|2>:GAIN:STATe" on page 6.151.

R&S FSL INSTrument Subsystem (WCDMA, K72)

1300.2519.12 6.581 E-11

INSTrument Subsystem (WCDMA, K72)

The INSTrument subsystem selects the operating mode of the unit either via text parameters or fixed

numbers.

Commands of the INSTrument Subsystem

–INSTrument[:SELect]

–INSTrument:NSELect

INSTrument[:SELect]

Parameter

BWCD (3GPP Base Station Measurements option, R&S FSL–K72)

For further details refer to the INSTrument subsystem of the base unit.

INSTrument:NSELect

Parameter

8(3GPP Base Station Measurements option, R&S FSL–K72)

For further details refer to the INSTrument subsystem of the base unit.

SENSe Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.582 E-11

SENSe Subsystem (WCDMA, K72)

The SENSe subsystem is organized in several subsystems. The commands of these subsystems

directly control device–specific settings, they do not refer to the signal characteristics of the

measurement signal.

The SENSe subsystem controls the essential parameters of the analyzer. In accordance with the SCPI

standard, the keyword "SENSe" is optional for this reason, which means that it is not necessary to

include the SENSe node in command sequences.

The following subsystems are included:

•"SENSe:AVERage Subsystem (WCDMA, K72)" on page 6.582

•"SENSe:CDPower Subsystem (WCDMA, K72)" on page 6.583

•"SENSe:FREQuency Subsystem (WCDMA, K72)" on page 6.590

•"SENSe:SWEep Subsystem (WCDMA, K72)" on page 6.590

SENSe:AVERage Subsystem (WCDMA, K72)

The SENSe:AVERage subsystem calculates the average of the acquired data. A new test result is

obtained from several successive measurements.

Commands of the SENSe:AVERage Subsystem

–[SENSe<1|2>:]AVERage:COUNt

[SENSe<1|2>:]AVERage:COUNt

For details refer to "[SENSe<1|2>:]AVERage:COUNt" on page 6.173.

R&S FSL SENSe Subsystem (WCDMA, K72)

1300.2519.12 6.583 E-11

SENSe:CDPower Subsystem (WCDMA, K72)

The SENSe:CDPower subsystem controls the parameters for the code domain mode. The numeric

suffix in SENSe<1|2> is not significant in this subsystem.

Commands of the SENSe:CDPower Subsystem

–[SENSe<1|2>:]CDPower:ANTenna

–[SENSe<1|2>:]CDPower:ASEQuence

–[SENSe<1|2>:]CDPower:CODE

–[SENSe<1|2>:]CDPower:HSDPamode

–[SENSe<1|2>:]CDPower:ICTReshold

–[SENSe<1|2>:]CDPower:LCODe[:VALue]

–[SENSe<1|2>:]CDPower:LCODe:DVALue

–[SENSe<1|2>:]CDPower:LCODe:SEARch[:IMMediate]

–[SENSe<1|2>:]CDPower:LCODe:SEARch:LIST?

–[SENSe<1|2>:]CDPower:LEVel:ADJust

–[SENSe<1|2>:]CDPower:NORMalize

–[SENSe<1|2>:]CDPower:PREFerence

–[SENSe<1|2>:]CDPower:QINVert

–[SENSe<1|2>:]CDPower:RSUMmary

–[SENSe<1|2>:]CDPower:SLOT

–[SENSe<1|2>:]CDPower:STYPe

[SENSe<1|2>:]CDPower:ANTenna

This command activates or deactivates the antenna diversity mode and selects the antenna to

be used.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

OFF The antenna diversity mode is switched off.

1 | 2 The antenna diversity mode is switched on, and the signal from antenna 1 or

antenna 2 is used for code domain power analysis.

Example

CDP:ANT 1

The signal from antenna 1 is used for code domain power analysis.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

WCDMA

SENSe Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.584 E-11

[SENSe<1|2>:]CDPower:ASEQuence

This command starts the following sequence:

–Adjusts the reference level.

–Searches automatically the scrambling code that leads to the highest signal power and stores it

as new scrambling code.

–Changes into the Result Summary result display.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

CDP:ASEQ

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:CODE

This command sets the code number. The code number refers to code class 9 (spreading factor

512).

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0to 511

Example

CDP:CODE 30

Sets code number 30.

Characteristics

RST value: 0

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:HSDPamode

This command activates or deactivates the HSUPA/DPA channel detection.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON The high speed channels can be detected.

The modulation type (QPSK /16QAM) is detected.

OFF The high speed channel can not be detected.

Pilot symbols are detected.

R&S FSL SENSe Subsystem (WCDMA, K72)

1300.2519.12 6.585 E-11

Example

CDP:HSDP OFF

Deactivates the HSUPA/DPA channel detection.

Characteristics

RST value: ON

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:ICTReshold

This command sets the minimum power threshold for a single channel (channel power

compared to total signal power). Only channels with a signal power above this value are

recognized as active channels.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

–100 dB to 10 dB

Example

CDP:ICTR –10

Sets the minimum power threshold to –10 dB.

Characteristics

RST value: –60 dB

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:LCODe[:VALue]

This command defines the scrambling code in hexadecimal format.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0x0 … 0x5FFF

Example

CDP:LCOD #H2

Defines the scrambling code in hexadecimal format.

Characteristics

RST value: 0

SCPI: device–specific

Mode

WCDMA

SENSe Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.586 E-11

[SENSe<1|2>:]CDPower:LCODe:DVALue

This command defines the scrambling code in decimal format.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0to 24575

Example

CDP:LCOD:DVAL 3

Defines the scrambling code in decimal format.

Characteristics

RST value: 0

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:LCODe:SEARch[:IMMediate]

This command searches automatically the scrambling code that leads to the highest signal

power and stores it as new scrambling code for further measurements.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

CDP:LCOD:SEAR

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:LCODe:SEARch:LIST?

This command returns a comma separated result table of the automatic search sequence

containing the highest power values calculated and the corresponding scrambling codes.

The numeric suffixes <1|2> are irrelevant for this command.

This command is only a query and therefore has no *RST value.

Returned value

Each found scrambling code consists of the following line:

Example:

16,0x10,–18.04,32,0x20,–22.87,48,0x30,–27.62,64,0x40,–29.46

in table format:

code (dec) code (hex) CPICH power (dBm)

16 0x10 –18.04

32 0x20 –22.87

48 0x30 –27.62

64 0x40 –29.46

R&S FSL SENSe Subsystem (WCDMA, K72)

1300.2519.12 6.587 E-11

Example

CDP:LCOD:SEAR

Starts the automatic scrambling code search.

CDP:LCOD:SEAR:LIST?

Lists the result table of the automatic search sequence.

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:LEVel:ADJust

This command adjusts the reference level to the measured channel power. This ensures that

the settings of the RF attenuation and the reference level are optimally adjusted to the signal

level without overloading the R&S FSL or limiting the dynamic range by an S/N ratio that is too

small.

The numeric suffixes <1|2> are irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

CDP:LEV:ADJ

Adjusts the reference level to the measured channel power.

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:NORMalize

This command activates and deactivates the elimination of the I/Q offset.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON | OFF

Example

CDPower:NORMalize ON

Activates the elimination of the I/Q offset.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

WCDMA

SENSe Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.588 E-11

[SENSe<1|2>:]CDPower:PREFerence

This command sets the power reference for the relative power displays.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

TOT total power

CPICH power of the common pilot channel

Example

CDP:PREF TOT

Sets the total power as power reference.

Characteristics

RST value: CPICH

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:QINVert

This command activates or deactivates the Q inversion.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

ON The sign of the Q–component of the signal is inverted.

OFF The sign of the Q–component of the signal remains unchanged.

Example

CDP:QINV ON

Activates the Q inversion.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:RSUMmary

This command sets the view of the Code Domain Result Summary.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

NORmal Some of the most important results are shown in the table on the R&S FSL

display.

EXTended All available result are shown in the table on the R&S FSL display.

Example

CDP:RSUM EXT

Sets the extended view of the Code Domain Result Summary.

R&S FSL SENSe Subsystem (WCDMA, K72)

1300.2519.12 6.589 E-11

Characteristics

RST value: NOR

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:SLOT

This command selects the slot that is evaluated in the Code Domain Power Diagram and is

used for slot–based evaluations in the Code Domain Result Summary.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

0to 14

Example

CDP:SLOT 3

Selects slot 3.

Characteristics

RST value: 0

SCPI: device–specific

Mode

WCDMA

[SENSe<1|2>:]CDPower:STYPe

This command defines the synchronization..

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

CPICh A synchronization to the CPICH control channel is performed. As a prerequisite,

the CPICH control channel must be present in the signal.

SCHannel A synchronization without assuming the presence of a CPICH channel is

performed.

While this setting can also be used with other channel configurations, but the

probability of synchronization failure increases with the number of data channels.

Example

CDP:STYP SCH

Asynchronization without assuming the presence of a CPICH channel is performed.

Characteristics

RST value: CPICH

SCPI: device–specific

Mode

WCDMA

SENSe Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.590 E-11

SENSe:FREQuency Subsystem (WCDMA, K72)

The SENSe:FREQuency subsystem defines the frequency axis of the active display. The frequency

axis can either be defined via the start/stop frequency or via the center frequency and span.

Commands of the SENSe:FREQuency Subsystem

–[SENSe<1|2>:]FREQuency:CENTer

–[SENSe<1|2>:]FREQuency:CENTer:STEP

–[SENSe<1|2>:]FREQuency:OFFSet

[SENSe<1|2>:]FREQuency:CENTer

For details refer to "[SENSe<1|2>:]FREQuency:CENTer" on page 6.200.

[SENSe<1|2>:]FREQuency:CENTer:STEP

For details refer to "[SENSe<1|2>:]FREQuency:CENTer:STEP" on page 6.201.

[SENSe<1|2>:]FREQuency:OFFSet

For details refer to "[SENSe<1|2>:]FREQuency:OFFSet" on page 6.203.

SENSe:SWEep Subsystem (WCDMA, K72)

The SENSe:SWEep subsystem controls the sweep parameters.

Commands of the SENSe:SWEep Subsystem

–[SENSe<1|2>:]SWEep:COUNt

[SENSe<1|2>:]SWEep:COUNt

For details refer to "[SENSe<1|2>:]SWEep:COUNt" on page 6.229.

R&S FSL STATus:QUEStionable Subsystem (WCDMA, K72)

1300.2519.12 6.591 E-11

STATus:QUEStionable Subsystem (WCDMA, K72)

The STATus:QUEStionable subsystem contains information about the error situation in the code

domain power analysis.

Commands of the STATus:QUEStionable Subsystem

–STATus:QUEStionable:SYNC[:EVENt?]

–STATus:QUEStionable:SYNC:CONDition?

STATus:QUEStionable:SYNC[:EVENt?]

For details refer to "STATus:QUEStionable:SYNC[:EVENt]?" on page 6.250.

STATus:QUEStionable:SYNC:CONDition?

For details refer to "STATus:QUEStionable:SYNC:CONDition?" on page 6.251.

TRACe Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.592 E-11

TRACe Subsystem (WCDMA, K72)

The TRACe subsystem controls access to the instruments internal trace memory.

Commands of the TRACe Subsystem

–TRACe<1|2>[:DATA]

–TRACe1:DATA? LIST

TRACe<1|2>[:DATA]

Parameter for code domain power measurements

TRACE1 | PWCDp | CWCDp | CTABle

Transmitted values for code domain power measurements

The transmitted values depend on the parameter selection.

Value Description Range Unit

<code class> code class of the channel

–1 indicates that the channel does not have a code class

(e.g. for PSCH)

{–1, 2 ... 9}

<class> spreading factor of the channel

code class 9 corresponds to the highest spreading factor

(512, symbol rate 7.5 ksps), code class 2 to the lowest

admissible spreading factor (4, symbol rate 960 ksps)

–1 indicates that the channel does not have a valid

spreading factor (e.g. for PSCH)

<channel number> code number of the channel

–1 indicates that the channel does not have a regular

channel number (e.g. for PSCH)

<absolute level> absolute level of the code channel at the selected channel

slot

{–



...



}dBm

<relative level> relative level of the code channel at the selected channel

slot referenced to CPICH or total power

{–



...



}dB

<timing offset> timing offset of the code channel to the frame start

step width is 256 chips for code class 2 to 8,

512 chips for code class 9

{0 ... 38400} chips

<pilot length> pilot length of the code channel

According to the 3GPP standard, the pilot length range

depends on the code class.

{0,2,4,8,16} symbols

<active flag> Flag to indicate whether a channel is active (1) or

not active (0)

{0,1}

<channel type> channel type indication

0 = DPCH, 1 = PICH, 2 = CPICH, 3 = PSCH, 4 = SSCH,

5 = PCCPCH6 = SCCPCH, 7 = HS_SCCH,

8 = HS_PDSCH, 9 = CHAN, 10 = CPRSD, 11 = CPR–TPC,

12 = CPR–SF/2, 13 = CPR–SF/2–TPC, 14 = EHICH–

ERGCH, 15 = EAGCH, 16 = SCPICH

For details on channels refer to chapter 4, section "3GPP

Base Station Measurements (Option K72)", "Channels of

the Code Domain Channel Table and their usage"

{0 ... 16}

<modulation type> modulation type of the code channel at the selected channel

slot

2 = QPSK, 4 = 16QAM, 15 = NONE

{2,4,15}

<reserved> reserved for future functionality {0}

R&S FSL TRACe Subsystem (WCDMA, K72)

1300.2519.12 6.593 E-11

TRACE1

5values are transmitted for each channel:

<class>,<channel number>,<absolute level>,<relative level>,<timing offset>, ...

For the Code Dom Power Diagram result display, the channels are output in ascending order

sorted by code number, i.e. in the same sequence they are displayed on screen.

For the Code Dom Channel Table result display, the channels are sorted by code class, i.e. the

unassigned channels are transmitted last.

PWCDp

6values are transmitted for each channel:

<class>,<channel number>,<absolute level>,<relative level>,<timing offset> or <I/Q–mapping>,

<pilot length>,...

CWCDp

10 values are transmitted for each channel:

<code class>,<channel number>,<absolute level>,<relative level>, <timing offset>, <pilot

length>, <active flag>, <channel type>, <modulation type>, <reserved>, ...

The channels are output in ascending order sorted by code number, i.e. in the same sequence

they are displayed on screen.

CTABle

7values are transmitted for each channel:

<class>,<channel number>,<absolute level>,<relative level>,<timing offset>,<pilot length>,

<active|inactive>...

Parameter for RF measurements

TRACE1 to TRACE4 trace memory to be read out

LIST peak list data

<block> or <numeric_value> data to be transferred

(For further details refer to "TRACe<1|2>[:DATA]" on page 6.263.

TRACe1:DATA? LIST

This command queries the list evaluation results. All results are float values.

This command is only a query and therefore has no *RST value.

Returned values

<no>, <start>, <stop>, <rbw>, <freq>, <power abs>, <power rel>, <delta>, <limit check>,

Value Description

<no> range number

<start> start frequency

<stop> stop frequency

<rbw> resolution bandwidth of range

<freq> frequency of peak

<power abs> absolut power in dBm of peak

<power rel> relative power in dBc (related to the channel power) of peak

<delta> distance to the limit line in dB (positive indicates value above the limit, fail)

TRACe Subsystem (WCDMA, K72) R&S FSL

1300.2519.12 6.594 E-11

Value Description

<limit check> limit fail (pass = 0, fail =1)

<unused1> reserved (0.0)

<unused2> reserved (0.0)

Example

CONF:WCDP:MEAS ESP

Selects the spectrum emission mask measurement.

TRACe1:DATA? LIST

Queries the list evaluation results.

Characteristics

RST value: –

SCPI: device–specific

Mode

WCDMA

R&S FSL TRIGger Subsystem (WCDMA, K72)

1300.2519.12 6.595 E-11

TRIGger Subsystem (WCDMA, K72)

The TRIGger subsystem is used to synchronize instrument actions with events. It is thus possible to control

and synchronize the start of a sweep.

Commands of the TRIGger Subsystem

–TRIGger<1|2>[:SEQuence]:SOURce

TRIGger<1|2>[:SEQuence]:SOURce

Parameter

IMMediate (Free Run) | EXTernal | IFPower

For further details refer to "TRIGger<1|2>[:SEQuence]:SOURce" on page 6.280.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.596 E-11

Remote Commands of the CDMA2000 BTS Analyzer

Option (K82)

This chapter describes the remote commands for the CDMA2000 BTS Analyzer option (K82). The

abbreviation CDMA stands for the operating mode of this option. For details on conventions used in this

chapter refer to section "Notation"on page 6.2 at the beginning of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in "Remote Commands of the Base Unit" on page 6.5.

This option is available from firmware version 1.90.

Subsystems of the CDMA2000 BTS Analyzer option (K82)

–"CALCulate Subsystem (CDMA, K82)" on page 6.597

–"CONFigure Subsystem (CDMA, K82)" on page 6.604

–"DISPlay Subsystem (CDMA, K82)" on page 6.611

–"INSTrument Subsystem (CDMA, K82)" on page 6.613

–"SENSe Subsystem (CDMA, K82)" on page 6.614

–"TRACe Subsystem (CDMA, K82)" on page 6.624

R&S FSL CALCulate Subsystem (CDMA, K82)

1300.2519.12 6.597 E-11

CALCulate Subsystem (CDMA, K82)

The CALCulate subsystem contains commands for converting instrument data, transforming and

carrying out corrections. These functions are carried out subsequent to data acquisition, i.e. following

the SENSe subsystem.

The following subsystems are included:

•"CALCulate:FEED Subsystem (CDMA, K82)" on page 6.597

•"CALCulate:LIMit:ESPectrum Subsystem (CDMA, K82)" on page 6.599

•"CALCulate:MARKer<1…4>:FUNCtion Subsystem (CDMA, K82)" on page 6.601

•"CALCulate:STATistics Subsystem (CDMA, K82)"on page 6.603

CALCulate:FEED Subsystem (CDMA, K82)

The CALCulate:FEED subsystem selects the type of evaluation for the measurement data. This

corresponds to the result display selection in manual operation.

Commands of the CALCulate:FEED Subsystem

–CALCulate<1|2>:FEED

CALCulate<1|2>:FEED

This command selects the result display for the measured data.The numeric suffix at

CALCulate<1|2> specifies the measurement window.

Parameter

XPOW:CDP Code Domain Power (CDP) result display (absolute)

XPOW:CDP:RAT Code Domain Power (CDP) result display (relative)

XPOW:CDEP Code Domain Error Power (CDEP) result display

XTIM:CDP:ERR:CTABle Channel Table result display

XTIM:CDP:PVSLot Power versus Power Control Group (PCG) result display

XTIM:CDP:ERR:SUMM Result Summary result display

XTIM:CDP:MACCuracy Composite EVM result display

XTIM:CDP:ERR:PCDomain Peak Code Domain Error result display

XTIM:CDP:SYMB:CONSt Channel Constellation result display

XTIM:CDP:SYMB:EVM Symbol Error Vector Magnitude result display

XTIM:CDP:BSTReam Channel Bitstream result display

XTIM:CDP:COMP:CONSt Composite Constellation result display

XTIM:CDP:PVSYmbol Power versus Symbol result display

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.598 E-11

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CALC2:FEED 'XTIM:CDP:MACC'

Selects the Composite EVM result display.

INIT;*WAI

Starts measurement with synchronization.

TRAC? TRACE2

Reads out the result.

Characteristics

RST value: 'XPOW:CDP:RAT'

SCPI: conform

Mode

CDMA

R&S FSL CALCulate Subsystem (CDMA, K82)

1300.2519.12 6.599 E-11

CALCulate:LIMit:ESPectrum Subsystem (CDMA, K82)

The CALCulate:LIMit:ESPectrum subsystem defines the limit check for thr Spectrum Emission Mask.

Commands of the CALCulate:LIMit:ESPectrum Subsystem

–CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE

–CALCulate<1|2>:LIMit<1...8>:ESPectrum:RESTore

–CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue

CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE

This command activates or deactivates the automatic selection of the limit line in the Spectrum

Emission Mask measurement.The numeric suffix at CALCulate<1|2> specifies the

measurement window. The numeric suffix at LIMit<1...8> is irrelevant for this command.

Parameter

AUTO The limit line depends on the measured channel power.

MANUAL One of the three specified limit lines is set. The selection is made with the

CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue command.

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CONF:CDP:BCL 1

Select band class 1, 1900 MHz

CONF:CDP:MEAS ESP

Selects Spectrum Emission Mask measurement.

CALC:LIM:ESP:MODE AUTO

Activates automatic selection of the limit line.

INIT;*WAI

Starts measurement with synchronization.

CALC:LIM:FAIL?

Queries result of the limit check.

Characteristics

RST value: AUTO

SCPI: device-specific

Mode

CDMA

CALCulate<1|2>:LIMit<1...8>:ESPectrum:RESTore

This command restores the predefined limit lines for the Spectrum Emission Mask

measurement. All modifications made to the predefined limit lines are lost and the factory–set

values are restored.

The numeric suffix at CALCulate<1|2> specifies the measurement window. The numeric suffix

at LIMit<1...8> is irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.600 E-11

Example

CALC:LIM:ESP:REST

Resets the limit lines for the Spectrum Emission Mask to the default setting.

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue

This command activates the manual limit line selection and specifies the expected power as a

value. Depending on the entered value, one of the predefined limit lines is selected.

The numeric suffix at CALCulate<1|2> specifies the measurement window. The numeric suffix

at LIMit<1...8> is irrelevant for this command.

Parameter

33 P



28 28



P < 33

0 P < 28

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CONF:CDP:BCL 1

Select band class 1, 1900 MHz

CONF:CDP:MEAS ESP

Selects Spectrum Emission Mask measurement.

CALC:LIM:ESP:VAL 33

Activates manual selection of the limit line and selects the limit line for P



33.

INIT;*WAI

Starts measurement with synchronization.

CALC:LIM:FAIL?

Queries result of the limit check.

Characteristics

RST value: 0

SCPI: device-specific

Mode

CDMA

R&S FSL CALCulate Subsystem (CDMA, K82)

1300.2519.12 6.601 E-11

CALCulate:MARKer<1…4>:FUNCtion Subsystem (CDMA, K82)

The CALCulate:MARKer:FUNCtion subsystem checks the marker functions in the instrument.

Commands of the CALCulate:MARKer<1…4>:FUNCtion Subsystem

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:CDPower[:BTS]:RESult?

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:PICH

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:TDPIch

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CDPower[:BTS]:RESult?

This command queries the results of the code domain measurement for the selected channel.

The channel is selected via the [SENSe<1|2>:]CDPower:CODE command.

The numeric suffix at CALCulate<1|2> specifies the measurement window. The numeric suffix

at MARKer<1...4> is irrelevant for this command.

Parameter

For a description of the parameter refer to "Result Summary"on page 6.629.

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

INIT;*WAI

Starts measurement with synchronization.

CALC:MARK:FUNC:CDP:RES? PTOT

Reads out total power.

CDP:SLOT 2

Selects power control group 2.

CDP:CODE 11

Selects code number 11.

CALC:MARK:FUNC:CDP:RES? EVMR

Reads out EVM rms of the code with number 11 in PCG 2.

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

CALCulate<1|2>:MARKer<1...4>:FUNCtion:PICH

This command sets the marker to channel 0.64.

The numeric suffix at CALCulate<1|2> specifies the measurement window. The numeric suffix

at MARKer<1...4> specifies the marker to be set to the pilot channel.

This command is an event and therefore has no *RST value and no query.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.602 E-11

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

INIT;*WAI

Starts measurement with synchronization.

CALC:MARK:FUNC:PICH

Activates marker and positions it at pilot 0.64.

CALC:MARK:Y?

Queries value of the relative Code Domain Power of the pilot channel.

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

CALCulate<1|2>:MARKer<1...4>:FUNCtion:TDPIch

This command sets the marker 1 to channel 16.128.

The numeric suffix at CALCulate<1|2> specifies the measurement window. The numeric suffix

at MARKer<1...4> specifies the marker to be set to the pilot channel.

This command is an event and therefore has no *RST value and no query.

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:ANT 2

Selects antenna 2.

CDP:SFAC 128

Selects base spreading factor 128.

INIT;*WAI

Starts measurement with synchronization.

CALC:MARK:FUNC:TDPI

Activates marker and positions it at TDPICH 16.128.

CALC:MARK:Y?

Queries value of the relative Code Domain Power of the transmit diversity pilot channel.

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

R&S FSL CALCulate Subsystem (CDMA, K82)

1300.2519.12 6.603 E-11

CALCulate:STATistics Subsystem (CDMA, K82)

The CALCulate:STATistics subsystem controls the statistical measurement functions. The

measurement window cannot be selected for these measurement functions. No numeric suffix at

CALCulate is available.

Commands of the CALCulate:STATistics Subsystem

–CALCulate:STATistics:CCDF[:STATe]

–CALCulate:STATistics:NSAMples

–CALCulate:STATistics:RESult<1…4>?

–CALCulate:STATistics:SCALe:Y:LOWer

–CALCulate:STATistics:SCALe:Y:UPPer

CALCulate:STATistics:CCDF[:STATe]

For details refer to the "CALCulate:STATistics:CCDF[:STATe]"command of the base unit on

page 6.112.

CALCulate:STATistics:NSAMples

For details refer to the "CALCulate:STATistics:NSAMples"command of the base unit on page

6.113.

CALCulate:STATistics:RESult<1…4>?

For details refer to the "CALCulate:STATistics:RESult<1...6>?"command of the base unit on

page 6.114.

CALCulate:STATistics:SCALe:Y:LOWer

For details refer to the "CALCulate:STATistics:SCALe:Y:LOWer"command of the base unit on

page 6.115.

CALCulate:STATistics:SCALe:Y:UPPer

For details refer to the "CALCulate:STATistics:SCALe:Y:UPPer"command of the base unit on

page 6.116.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.604 E-11

CONFigure Subsystem (CDMA, K82)

The CONFigure subsystem contains commands for configuring the measurements.

The following subsystem is included:

•"CONFigure:CDPower Subsystem (CDMA, K82)" on page 6.604

CONFigure:CDPower Subsystem (CDMA, K82)

This subsystem contains the commands for measurement selection and configuration of the

CDMA2000 BTS Analyzer option.

Further setting commands for the spectrum emission mask measurement are in the

"CALCulate:LIMit:ESPectrum Subsystem (CDMA, K82)" on page 6.599.

Commands of the CONFigure:CDPower Subsystem

–CONFigure:CDPower[:BTS]:CTABle[:STATe]

–CONFigure:CDPower[:BTS]:CTABle:CATalog?

–CONFigure:CDPower[:BTS]:CTABle:COMMent

–CONFigure:CDPower[:BTS]:CTABle:COPY

–CONFigure:CDPower[:BTS]:CTABle:DATA

–CONFigure:CDPower[:BTS]:CTABle:DELete

–CONFigure:CDPower[:BTS]:CTABle:NAME

–CONFigure:CDPower[:BTS]:CTABle:SELect

–CONFigure:CDPower[:BTS]:BCLass

–CONFigure:CDPower[:BTS]:MCARier[:STATe]

–CONFigure:CDPower[:BTS]:MEASurement

–CONFigure:CDPower:CTABle:RESTore

CONFigure:CDPower[:BTS]:CTABle[:STATe]

This command activates or deactivates the ‘RECENT’ channel table. To select another channel

table, use the CONFigure:CDPower[:BTS]:CTABle:SELect command.

Parameter

ON | OFF

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

INIT;*WAI

Starts measurement with synchronization.

CONF:CDP:CTAB ON

Activates predefined channel table.

CONF:CDP:CTAB:SEL 'CTAB_1'

Selects channel table.

R&S FSL CONFigure Subsystem (CDMA, K82)

1300.2519.12 6.605 E-11

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

CDMA

CONFigure:CDPower[:BTS]:CTABle:CATalog?

This command queries the names of all the channel tables stored on the flash disk for

CDMA2000.

Return values

<sum of file sizes of all subsequent files>, <spare storage space on hard disk>, <1st file name>,

<1st file size>, <2nd file name>, <2nd file size>, ..., <nth file name>, <nth file size>, ...

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

CONF:CDP:CTAB:CAT?

Queries catalog.

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

CONFigure:CDPower[:BTS]:CTABle:COMMent

This command defines a comment on the selected channel table.

Parameter

<'string'> = comment on the channel table

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

CONF:CDP:CTAB:NAME 'NEW_TAB'

Selects channel table for editing. If a channel table with this name does not exist, a new channel

table is created.

CONF:CDP:CTAB:DATA 0,6,0,0,0,0,1,0.0,10,5,3,4,0,0,1,0.0

Defines a table with the following channels: PICH 0.64 and data channel with RC4/Walsh code

3.32.

CONF:CDP:CTAB:COMM 'Comment for NEW_TAB'

Specifies 'Comment for NEW_TAB' as comment.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.606 E-11

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

CONFigure:CDPower[:BTS]:CTABle:COPY

This command copies one channel table to another. Select the channel table you want to copy

using the CONFigure:CDPower[:BTS]:CTABle:NAME command.

This command is an event and therefore has no *RST value and no query.

Parameter

<'string'> = name of the new channel table.

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

CONF:CDP:CTAB:NAME 'CTAB_1'

Selects channel table CTAB_1 for copying.

CONF:CDP:CTAB:COPY 'CTAB_2'

Copies CTAB_1 to C_TAB2.

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

CONFigure:CDPower[:BTS]:CTABle:DATA

This command defines a channel table.

Parameter

For one table line, eight values are specified .

<channel type>, <code class>, <code number>, <radio configuration>, <reserved1>,

<reserved2>, <status>, <CDP relative>, ....

channel type

code class

code number

radio configuration

For details on the values refer to Channel Table on

page 6.627.

reserved1

reserved2

always 0 (reserved)

status 0: inactive

1: active

CDP relative any value in dB

The inactive channels (INACtive) do not have to be defined.

R&S FSL CONFigure Subsystem (CDMA, K82)

1300.2519.12 6.607 E-11

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

CONF:CDP:CTAB:NAME 'NEW_TAB'

Selects channel table for editing. If a channel table with this name does not exist, a new channel

table is created.

CONF:CDP:CTAB:DATA 0,6,0,0,0,0,1,0.0,10,5,3,4,0,0,1,0.0

Defines a table with the following channels: PICH 0.64 and data channel with RC4/Walsh code

3.32.

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

CONFigure:CDPower[:BTS]:CTABle:DELete

This command deletes the selected channel table. Select the channel table you want to delete

using the CONFigure:CDPower[:BTS]:CTABle:NAME command.

This command is an event and therefore has no *RST value and no query.

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

CONF:CDP:CTAB:NAME 'CTAB_1'

Selects channel table CTAB_2 for deleting.

CONF:CDP:CTAB:DEL

Deletes channel table CTAB_2.

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

CONFigure:CDPower[:BTS]:CTABle:NAME

This command selects a channel table for editing or creating. To select a command for analysis,

use the CONFigure:CDPower[:BTS]:CTABle:SELect command.

Parameter

<'string'> = name of the channel table

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

CONF:CDP:CTAB:NAME 'NEW_TAB'

Selects channel table for editing. If a channel table with this name does not exist, a new channel

table is created.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.608 E-11

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

CONFigure:CDPower[:BTS]:CTABle:SELect

This command selects a predefined channel table.

Parameter

<'string'> = name of the channel table

Example

Refer to the example of the CONFigure:CDPower[:BTS]:CTABle[:STATe] command.

Characteristics

RST value: "RECENT"

SCPI: device-specific

Mode

CDMA

CONFigure:CDPower[:BTS]:BCLass

This command selects the band class to be used.

Parameter

0to 15

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option

INIT:CONT OFF

Selects single sweep

CONF:CDP:BCL 1

Selects band class 1, 1900 MHz

Characteristics

RST value: 0

SCPI: device specific

Mode

CDMA

R&S FSL CONFigure Subsystem (CDMA, K82)

1300.2519.12 6.609 E-11

CONFigure:CDPower[:BTS]:MCARier[:STATe]

This command activates or deactivates the settings that improve the processing of multi-carrier

signals.

Parameter

ON | OFF

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CONF:CDP:MCAR ON

Activates the multi-carrier settings.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

CDMA

CONFigure:CDPower[:BTS]:MEASurement

This command selects the measurements of the CDMA2000 BTS Analyzer option. The

predefined settings of the different measurements are described in chapter 4, section "Softkeys

of the measurement menu (CDMA2000 BTS Analyzer mode)".Parameter

ACLR Adjacent–Channel Power measurement with predefined settings

according to the CDMA2000 standard

CCDF measurement of the complementary cumulative distribution

function (signal statistics)

CDPower Code Domain Analyzer measurement.

ESPectrum check of signal power (Spectrum Emission Mask)

OBWidth measurement of the occupied bandwidth

POWer Signal Channel Power measurement with predefined settings

according to the CDMA2000 standard

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CONF:CDP:MEAS POW

Selects Signal Channel Power measurement .

INIT;*WAI

Starts measurement with synchronization.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.610 E-11

Characteristics

RST value: CDPower

SCPI: device-specific

Mode

CDMA

CONFigure:CDPower:CTABle:RESTore

This command restores the predefined channel tables to their factory–set values. In this way,

you can undo unintentional overwriting.

This command is an event and therefore has no *RST value and no query.

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

CONF:CDP:CTAB:REST

Restores the channel table.

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

R&S FSL DISPlay Subsystem (CDMA, K82)

1300.2519.12 6.611 E-11

DISPlay Subsystem (CDMA, K82)

The DISPLay subsystem controls the selection and presentation of textual and graphic information as

well as of measurement data on the display.

Commands of the DISPlay Subsystem

–DISPlay:FORMat

–DISPlay[:WINDow<1|2>]:SSELect

–DISPlay[:WINDow<1|2>]:TRACe<1…6>:Y[:SCALe]:AUTO

DISPlay:FORMat

This command sets the visible screen display type to full or split screen.

Parameter

SPLit | SINGle

Example

DISP:FORM SINGle

Sets the display to full screen.

Characteristics

*RST value: SPL

SCPI: device–specific

Mode

CDMA

DISPlay[:WINDow<1|2>]:SSELect

This command selects whether screen A or screen B is active. SSELect means Screen SELect.

Example

DISP:WIND1:SSEL

Sets the screen A active.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

CDMA

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.612 E-11

DISPlay[:WINDow<1|2>]:TRACe<1…6>:Y[:SCALe]:AUTO

This command switches on or off automatic scaling of the Y–axis for the specified trace display.

Automatic scaling sets the Y–axis to automatically scale to best fit the measurement results.

The numeric suffix at WINDow<1|2> selects the measurement window. The numeric suffix at

TRACe<1...6> must be 1.

Parameter

ONCE

Example

DISP:WIND2:TRAC:Y:SCAL:AUTO ONCE

activates automatic scaling of the Y–axis for the active trace

Characteristics

*RST value: OFF

Mode

CDMA

R&S FSL INSTrument Subsystem (CDMA, K82)

1300.2519.12 6.613 E-11

INSTrument Subsystem (CDMA, K82)

The INSTrument subsystem selects the operating mode of the unit either via text parameters or fixed

numbers.

Commands of the INSTrument Subsystem

–INSTrument[:SELect]

–INSTrument:NSELect

INSTrument[:SELect]

Parameter

BC2K (CDMA2000 BTS Analyzer option, R&S FSL–K82)

For further details refer to theINSTrument subsystem of the base unit.

INSTrument:NSELect

Parameter

10 (CDMA2000 BTS Analyzer option, R&S FSL–K82)

For further details refer to the INSTrument subsystem of the base unit.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.614 E-11

SENSe Subsystem (CDMA, K82)

The SENSe subsystem controls the essential parameters of the analyzer. In accordance with the SCPI

standard, the keyword "SENSe" is optional for this reason, which means that it is not necessary to

include the SENSe node in command sequences.

The following subsystems is included:

•"SENSe:CDPower Subsystem (CDMA, K82)" on page 6.615

•"SENSe:ESPectrum Subsystem (CDMA, K82)" on page 6.623

R&S FSL SENSe Subsystem (CDMA, K82)

1300.2519.12 6.615 E-11

SENSe:CDPower Subsystem (CDMA, K82)

This subsystem sets the parameters for the code domain measurements mode. The numeric suffix at

SENSe<1|2> is irrelevant.

Commands of the SENSe:CDPower Subsystem

–[SENSe<1|2>:]CDPower:ANTenna

–[SENSe<1|2>:]CDPower:CODE

–[SENSe<1|2>:]CDPower:ICTReshold

–[SENSe<1|2>:]CDPower:IQLength

–[SENSe<1|2>:]CDPower:LEVel:ADJust

–[SENSe<1|2>:]CDPower:NORMalize

–[SENSe<1|2>:]CDPower:ORDer

–[SENSe<1|2>:]CDPower:PNOFfset

–[SENSe<1|2>:]CDPower:PREFerence

–[SENSe<1|2>:]CDPower:QINVert

–[SENSe<1|2>:]CDPower:SFACtor

–[SENSe<1|2>:]CDPower:SLOT

–[SENSe<1|2>:]CDPower:TPMeas

[SENSe<1|2>:]CDPower:ANTenna

This command deactivates the orthogonal transmit diversity (two–antenna system) or defines

the antenna for which the result display evaluated.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

OFF The aggregate signal from both antennas is fed in.

1The signal of antenna 1 is fed in.

2The signal of antenna 2 is fed in.

For further details refer to chapter 4, "Antenna Diversity".

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:ANT 2

Selects antenna 2.

CDP:SFAC 128

Selects base spreading factor 128.

INIT;*WAI

Starts measurement with synchronization.

CALC:MARK:FUNC:PICH

Activates marker 1 and positions it at the transmit diversity pilot channel (TDPICH) 16.128.

CALC:MARK:Y?

Queries value of the relative Code Domain Power of the TDPICH.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.616 E-11

Characteristics

RST value: OFF

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:CODE

This command selects the code number.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

0to 127; the maximum value depends on the base spreading factor;

For further details refer to chapter 4, "Channel (Code) Number".

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:SFAC 128

Selects base spreading factor 128.

CDP:CODE 11

Selects code number 11.

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: 0

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:ICTReshold

This command defines the minimum power which a single channel must have compared to the

total signal in order to be regarded as an active channel. Channels below the specified

threshold are regarded as "inactive".

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

–100 dB to 0 dB

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:ICTR –10DB

Sets threshold value to –10 dB.

INIT;*WAI

Starts measurement with synchronization.

R&S FSL SENSe Subsystem (CDMA, K82)

1300.2519.12 6.617 E-11

Characteristics

RST value: –60 dB

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:IQLength

This command sets the capture length in multiples of the power control group.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

2to 12

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:IQL 8

Sets 8 PCGs as capture length.

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: 3

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:LEVel:ADJust

This command adjusts the reference level of the R&S FSL to the measured channel power. This

ensures that the settings of the RF attenuation and the reference level are optimally adjusted to

the signal level without overloading the R&S FSL or limiting the dynamic response by a too low

signal–to–noise ratio.The numeric suffix at SENSe<1|2> is irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:LEV:ADJ

Starts automatic level setting.

INIT;*WAI

Starts measurement with synchronization.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.618 E-11

Characteristics

RST value: -

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:NORMalize

This command activates or deactivates the elimination of the IQ offset from the signal.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

ON | OFF

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:NORM ON

Eliminates the DC offset from the signal.

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:ORDer

This command sets the channel sorting for the Code Domain Power and Code Domain Error

result displays.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

HADamard | BITReverse

For further details refer to chapter 4, "Code Order".

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

INIT;*WAI

Starts measurement with synchronization.

CDP:ORD HAD

Sets Hadamard order.

TRAC? TRACE2

Reads out the results in Hadamard order.

R&S FSL SENSe Subsystem (CDMA, K82)

1300.2519.12 6.619 E-11

CDP:ORD BITR

Sets BitReverse order.

TRAC? TRACE2

Reads out the results in BitReverse order.

Characteristics

RST value: HADamard

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:PNOFfset

This command sets the PN offset of the base station in multiples of 64 chips.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

0to 511

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:PNOF 45

Sets PN offset.

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: 0

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:PREFerence

This command specifies the reference power for the relative power result displays (Code

Domain Power, Power vs PCG).

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

PICH The reference power is the power of the pilot channel. Which pilot channel is

used as reference depends on the antenna diversity (for details see

[SENSe<1|2>:]CDPower:ANTenna command).

TOTal The reference power is the total power of the signal referred per power control

group (PCG) to the corresponding PCG.

For further information refer to chapter 4, "Power Reference"

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.620 E-11

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:PREF TOT

Sets total power as reference power.

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: PICH

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:QINVert

This command inverts the sign of the Q–component of the signal.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

ON | OFF

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:QINV ON

Activates the inversion of the Q–component sign.

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:SFACtor

This command defines the base spreading factor. If the base spreading factor of 64 is used for

channels of spreading factor 128 (code class 7), an alias power is displayed in the Code

Domain Power and Code Domain Error Power diagrams.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

64 | 128

R&S FSL SENSe Subsystem (CDMA, K82)

1300.2519.12 6.621 E-11

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:SFAC 128

Selects base spreading factor 128.

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: 64

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:SLOT

This command selects the power control group (PCG).

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

0to (capture length–1)

The capture length is defined via the [SENSe<1|2>:]CDPower:IQLength command.

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:SLOT 2

Selects power control group 2.

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: 0

SCPI: device-specific

Mode

CDMA

[SENSe<1|2>:]CDPower:TPMeas

This command actives or deactivates the timing and phase offset evaluation of the channels to

the pilot.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

The results are queried using the TRACe<1|2>[:DATA] command, Channel Table return

values, and the CALCulate<1|2>:MARKer<1...4>:FUNCtion:CDPower[:BTS]:RESult?

command.

Parameter

ON | OFF

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.622 E-11

Example

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:TPM ON

Activates timing and phase offset.

INIT;*WAI

Starts measurement with synchronization.

CDP:SLOT 2

Selects power control group 2.

CDP:CODE 11

Selects code number 11.

CALC:MARK:FUNC:CDP:RES? TOFF

Reads out timing offset of the code with number 11 in PCG 2.

CALC:MARK:FUNC:CDP:RES? POFF

Reads out the phase offset of the code with number 11 in PCG 2.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

CDMA

R&S FSL SENSe Subsystem (CDMA, K82)

1300.2519.12 6.623 E-11

SENSe:ESPectrum Subsystem (CDMA, K82)

This subsystem sets the parameters for the code domain measurements mode. The numeric suffix at

SENSe<1|2> is irrelevant.

Commands of the SENSe:ESPectrum Subsystem

–[SENSe<1|2>:]ESPectrum:PRESet[:STANdard]

–[SENSe<1|2>:]ESPectrum:PRESet:RESTore

–[SENSe<1|2>:]ESPectrum:STORe

[SENSe<1|2>:]ESPectrum:PRESet[:STANdard]

For details refer to the [SENSe<1|2>:]ESPectrum:PRESet[:STANdard] command of the base

unit on page 6.189.

[SENSe<1|2>:]ESPectrum:PRESet:RESTore

For details refer to the [SENSe<1|2>:]ESPectrum:PRESet:RESTore command of the base unit

on page 6.190.

[SENSe<1|2>:]ESPectrum:STORe

This command saves the specified XML file under C:\r_s\instr\sem_std. To save the file in

subdirectory, include the relative path.

The numeric suffixes <1|2> are not relevant.

This command is an event and therefore has no *RST value and no query.

Example

ESP:STOR 'CDMA2000\DL\BandClass_20.xml'

Saves the BandClass_20.xml XML file in the C:\R_S\instr\sem_std\CDMA2000\DL directory.

Characteristics

RST value: –

SCPI: device–specific

Mode

CDMA

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.624 E-11

TRACe Subsystem (CDMA, K82)

The TRACe subsystem controls access to the instruments internal trace memory.

Commands of the TRACe Subsystem

–TRACe<1|2>[:DATA]

TRACe<1|2>[:DATA]

This command transfers trace data from the controller to the R&S FSL, the query command

reads trace data from the R&S FSL.The numeric suffix at TRACe<1|2> is irrelevant.

For details on reading trace data for other than code domain measurements refer to

TRACe<1|2>[:DATA].

Parameter

TRACE1 |

TRACE2

Reads out the trace data of measurement window 1 or 2.

CTABle For the Channel Table result display, reads out the maximum values

of the timing/phase offset between every assigned channel and the

pilot channel (see also [SENSe<1|2>:]CDPower:TPMeas

command).

Return values

The measurement results are explained separately for each measurement and illustrated by a

short example:

–Code Domain Power on page 6.625

–Code Domain Error Power on page 6.626

–Channel Table on page 6.627

–Result Summary on page 6.629

–Power vs PCG on page 6.630

–Peak Code Domain Error on page 6.630

–Composite EVM on page 6.630

–EVM vs Symbol on page 6.631

–Power vs Symbol on page 6.631

–Channel Constellation on page 6.631

–Composite Constellation on page 6.631

–Channel Bitstream on page 6.632

Characteristics

RST value: -

SCPI: conform

Mode

CDMA

R&S FSL TRACe Subsystem (CDMA, K82)

1300.2519.12 6.625 E-11

Code Domain Power

The following values are transferred for each channel: <code class>, <code number>, <signal level>,

<power ID>, ...

Parameter Description Output value

code class code class of the channel, depending on the order

setting via the [SENSe<1|2>:]CDPower:ORDer

command

Hadamard order: corresponds to the class that

belongs to the base spreading factor

BitReverse order: 2 to 7

code number code number of the channel 0 to 127

signal level absolute or relative power, depending on the

reference setting via the

[SENSe<1|2>:]CDPower:PREFerence

command

Hadamard order: power values of the different

codes

BitReverse order: consolidated channel power

(see [SENSe<1|2>:]CDPower:ORDer

command)

power ID power detection

To avoid alias power set the base spreading factor

correctly (see [SENSe<1|2>:]CDPower:SFACtor

command).

0–inactive channel

1–power of own antenna

2–alias power of own antenna

3–alias power of other antenna

4–alias power of own and other antenna

For sorting the channels and consolidation, the order is important (refer to the

[SENSe<1|2>:]CDPower:ORDer command):

•In Hadamard order, the different codes are output in ascending order together with their code

power. The number of output codes corresponds to the base spreading factor.

•In BitReverse order, codes belonging to a channel are next to one another and are therefore output

in the class of the channel together with the consolidated channel power. The maximum number of

output codes or channels cannot be higher than the base spreading factor, but decreases with

every concentrated channel.

Example

The example shows the results of the query for five channels having the following configuration:

channel type channel spreading code code class signal level

PICH 0.64 6 –7.0 dB

PCH 1.64 6 –7.3 dB

CHAN 8.32 5 –8.0 dB

CHAN 24.128 7 –9.0 dB (alias with 24.64)

SYNC 32.64 6 –13.3 dB

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:ORD HAD

Sets order to Hadamard.

INIT;*WAI

Starts measurement with synchronization.

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.626 E-11

TRAC? TRACE1

Reads out the result.

Channel 8.32 is distributed to 8.64 and 40.64,

in each case with half power –8 dB –3 dB = –11.0 dB

6 0 –7.0 1 6 1–7.3 1 6

6 2 –54.6 0 6 3–55.3 0 6

... 6 7–58.2 0 6

6 8 –11.0 1 6 9 –53.4 0 6

... 624 –9.0 2 6

... 6

32 –13.3 1 6

... 640 –11.0 1 6

... 6

63 –54.7 0 6

CDP:ORD BITR

Sets order to BitReverse.

TRAC? TRACE1

Reads out the result.

Channel 8.32 can be directly read out with its total power. The order is changed in accordance

with BitReverse.

6 0 –7.0 1 632 –13.3 1 6

616 –56.3 0 6

48 –52.8 0 6

5 8 –8.0 1 624 –9.0 2 6

... 6 1–7.3 1 6

... 6

63 –54.7 0 6

Code Domain Error Power

The following values are transferred for each channel: <code class>, <code number>, <error power>,

<power ID>, ...

Parameter Description Output value

code class code class of the channel; corresponds to the class

that belongs to the base spreading factor

code number code number of the channel 0 to 127

error power error power in dB, no difference of power between

the Hadamard and BitReverse orders

power ID power detection

To avoid alias power set the base spreading factor

correctly (see [SENSe<1|2>:]CDPower:SFACtor

command).

0–inactive channel

1–power of own antenna

2–alias power of own antenna

3–alias power of other antenna

4–alias power of own and other antenna

For sorting the channels and consolidation, the order is important (refer to the

[SENSe<1|2>:]CDPower:ORDer command):

•In Hadamard order, the different codes are output in ascending order.

•In BitReverse order, codes belonging to a channel are next to one another. Because an error power

is output with the code domain error power, a consolidation of the power values is not sensible.

The number of output codes therefore generally corresponds to the base spreading factor.

R&S FSL TRACe Subsystem (CDMA, K82)

1300.2519.12 6.627 E-11

Example

The example shows the results of the query for five channels having the following configuration:

channel type channel spreading code code class signal level

PICH 0.64 6 –7.0 dB

PCH 1.64 6 –7.3 dB

CHAN 8.32 5 –8.0 dB

CHAN 24.128 7 –9.0 dB (alias with 24.64)

SYNC 32.64 6 –13.3 dB

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CALC2:FEED 'XPOW:CDEP'

Selects the Code Domain Error Power result display.

INIT;*WAI

Starts measurement with synchronization.

TRAC? TRACE1

Reads out the result in Hadamard order.

6 0 –52.6 1 6 1–60.1 1 6

6 2 –54.6 0 6 3–55.3 0 6

... 6 7–58.2 0 6

6 8 –51.9 1 69–53.4 0 6

... 624 –55.7 2 6

... 6

32 –58.6 1 6

... 640 –60.5 1 6

... 6

63 –54.7 0 6

Channel Table

With the TRACE1 | TRACE2 parameter, the following values are transferred for each channel: <channel

type>, <code class>, <code number>, <radio configuration>, <absolute level>, <relative level>, <timing

offset>, <phase offset>, ...

Parameter Description Output value

channel type channel type , coded with numbers 0 – PICH

1–SYNC

2–PCH

3–TDPICH

4–APICH

5–ATDPICH

6–BCH

7–CPCCH

8–CACH

9–CCCH

10 – CHAN

11 – INACTIVE

12 – PDCCH

13 – PDCH

code class code class of the channel, specifies the

spreading factor

2to 7

2corresponds to the lowest allowed spreading factor

(4, symbol rate 307.2 ksps)

7corresponds to the highest spreading factor (128,

symbol rate 9.6 ksps)

code number code number of the channel 0 to 127

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.628 E-11

Parameter Description Output value

radio configuration radio configuration, coded with numbers 0 – special channels

1to 5 – data channels (CHAN)

10 – QPSK

20 – 8PSK

30 – 16QAM

(If the auto search function is activated via the

CONFigure:CDPower[:BTS]:CTABle[:STATe]

command, '1' is returned for RCs 1&2, '3' for RCs 3

to 5 and 10 for PDCH)

absolute level in dBm

relative level in dB, referred to the total or pilot power via

the

[SENSe<1|2>:]CDPower:PREFerence

command

timing offset referred to the pilot in seconds

phase offset referred to the pilot in rad 9 – evaluation of the timing and phase offset is not

active (refer to [SENSe<1|2>:]CDPower:TPMeas)

or more than 50 active channels or channel is

inactive

Sorting of the channels:

5. all detected special channels

6. data channels, in ascending order by code class and within the code class in ascending order by

code number.

7. unassigned codes, with the code class of the base spreading factor

With the CTABle parameter, the following values are output: <max. time offset in s>, <code number for

max. time>, <code class for max. time>, <max. phase offset in rad>, <code number for max. phase>,

Example

The example shows the results of the query for five channels having the following configuration:

channel type channel spreading code code class signal level

PICH 0.64 6 –7.0 dB

PCH 1.64 6 –7.3 dB

CHAN 8.32 5 –8.0 dB

CHAN 24.128 7 –9.0 dB (alias with 24.64)

SYNC 32.64 6 –13.3 dB

INST:SEL BC2K

Activates the CDMA2000 BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CALC1:FEED 'XTIM:CDP:ERR:CTAB'

Selects the Channel Table result display.

INIT;*WAI

Starts measurement with synchronization.

R&S FSL TRACe Subsystem (CDMA, K82)

1300.2519.12 6.629 E-11

TRAC? TRACE1

Reads out the result in Hadamard order.

0 6 0 0 0.0 –7.0 9 9

1 6 32 0 –6.3 –13.3 9 9

2 6 1 0 –0.3 –7.3 9 9

10 5 8 3 –1.0 –8.0 9 9

10 7 24 3 –2.0 –9.0 9 9

11 6 2 3 –47.6 –54.6 9 9

...

11 6 63 3 –47.7 –54.7 9 9

CDP:TPM ON

Activates timing and phase offset measurement.

INIT;*WAI

Starts measurement with synchronization.

TRAC? CTAB

Reads out maximum timing and phase offsets.

1.20E–009,2,2,–3.01E–003,15,4,0,0,0,0,0,0

Max. time offset with code number and code class of associated channel, Max. phase offset

with code number and code class of associated channel, 6 reserved values

Result Summary

The results are output in the following order: <SLOT>, <PTOTal>, <PPICh>, <RHO>, <MACCuracy>,

<PCDerror>, <ACTive>, <FERRor>, <FERPpm>, <TFRame>, <CERRor>, <IQOFfset>,

<IQIMbalance>, <SRATe>, <CHANnel>, <SFACtor>, <TOFFset>, <POFFset>, <CDPRelative>,

Global results of the selected PCG

Parameter Description

SLOT PCG number

PTOTal total power in dBm

PPICh pilot power in dBm

RHO RHO

MACCuracy composite EVM in %

PCDerror peak code domain error in dB

IQOFfset IQ offset in %

IQIMbalance IQ imbalance in %

Global results of all PCGs

Parameter Description

ACTive number of active channels

FERRor frequency error in Hz

FERPpm frequency error in ppm

TFRame trigger to frame; returns a '9' if the

trigger is set to Free Run.

CERRor chip rate error in ppm

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.630 E-11

Channel results

Parameter Description

SRATe symbol rate in ksps

CHANnel channel number

SFACtor spreading factor of the channel

TOFFset

POFFset

timing offset in s;

phase offset in rad;

returns a '9' if the timing/phase offset

measurement is switched off (see

[SENSe<1|2>:]CDPower:TPMeas

command) or the number of active

channel exceeds 50.

CDPRelative channel power relative in dB

CDPabsolute channel power abs. in dBm (relative

to total or PICH power, refer to

CDP:PREF command)

EVMRms error vector magnitude rms in %

EVMPeak error vector mag. peak in %

Note: The result of the modulation type can be read out with the command

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CDPower[:BTS]:RESult?

Power vs PCG

The number of returned value pairs corresponds to the Capture length

(see [SENSe<1|2>:]CDPower:IQLength command).

The results are output in the following order: <slot number>,<level value in dB>, <slot number>, <level

value in dB>, ...

Peak Code Domain Error

The number of returned value pairs corresponds to the Capture length

(see [SENSe<1|2>:]CDPower:IQLength command).

The results are output in the following order: <slot number>, <level value in dB>, ...

Composite EVM

The number of returned value pairs corresponds to the Capture length

(see [SENSe<1|2>:]CDPower:IQLength command).

The results are output in the following order: <slot number>, <value in %>, ...

R&S FSL TRACe Subsystem (CDMA, K82)

1300.2519.12 6.631 E-11

EVM vs Symbol

The results are output in the following order: <value in % symbol 0>, <value in % symbol 1>,...

The number of values depends on the spreading factor. With transmit diversity activated (see

[SENSe<1|2>:]CDPower:ANTenna command), the number of values is reduced to the half.

Spreading

factor

Number of

values

128 12

64 24

32 48

16 96

8192

4384

Power vs Symbol

The results are output in the following order: <value in dBm symbol 0>, <value in dBm symbol 1>,...

The number of values depends on the spreading factor. With transmit diversity activated (see

[SENSe<1|2>:]CDPower:ANTenna command), the number of values is reduced to the half.

Spreading

factor

Number of

values

128 12

64 24

32 48

16 96

8192

4384

Channel Constellation

Real and imaginary parts are transferred as value pairs: <re 0>,<im 0>,<re 1>,<im 1>,...,<re n>, <im n>

The number of value pairs depends on the spreading factor. With transmit diversity activated (see

[SENSe<1|2>:]CDPower:ANTenna command), the number of pairs is reduced to the half.

Spreading

factor

Number of

value pairs

128 12

64 24

32 48

16 96

8192

4384

Composite Constellation

The number of value pairs corresponds to the chip number of 1536 chips in a power control group. Real

and imaginary parts are transferred as value pairs: <re chip 0>,<im chip 0>,<re chip 1>,<im chip 1>,...

Remote Commands of the CDMA2000 BTS Analyzer Option (K82) R&S FSL

1300.2519.12 6.632 E-11

Channel Bitstream

Depending on the spreading factor (symbol rate) of the channel, a minimum of 12 and a maximum of

384 symbols can be contained in a power control group. Depending on the modulation type, a symbol

consists of the following bits:

•BPSK: 1 bit (only the I–component is assigned)

•QPSK: 2 bits (I–component followed by the Q–component)

•8PSK: 3 bits

•16QAM: 4 bits

For each bit, a value is output (range 0,1).

BPSK modulation type

Spreading

factor

Number of

values

128 12

64 24

32 48

16 96

8192

4384

QPSK modulation type

Spreading

factor

Number of

values

128 24

64 48

32 96

16 192

8384

4768

8PSK modulation type

Spreading

factor

Number of

values

32 144

16QAM modulation type

Spreading

factor

Number of

values

32 192

With transmit diversity activated (see [SENSe<1|2>:]CDPower:ANTenna command), the values

reduce to the half.

Example

0, 0, 1, 0 , 1, 1, 0 ...

R&S FSL TRACe Subsystem (CDMA, K82)

1300.2519.12 6.633 E-11

Remote Commands of the 1xEV-DO BTS Analyzer

Option (K84)

This chapter describes the remote commands for the 1XEV-DO BTS Analyzer option (K84). The

abbreviation EVDO stands for the operating mode of this option. For details on conventions used in this

chapter refer to section "Notation"on page 6.2 at the beginning of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in "Remote Commands of the Base Unit" on page 6.5.

This option is available from firmware version 1.90.

Subsystems of the 1XEV-DO BTS Analyzer option (K84)

–"CALCulate Subsystem (EVDO, K84)" on page 6.634

–"CONFigure Subsystem (EVDO, K84)" on page 6.643

–"DISPlay Subsystem (EVDO, K84)" on page 6.653

–"INSTrument Subsystem (EVDO, K84)" on page 6.655

–"SENSe Subsystem (EVDO, K84)" on page 6.656

–"TRACe Subsystem (1xEV-DO, K84)" on page 6.664

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.634 E-11

CALCulate Subsystem (EVDO, K84)

The CALCulate subsystem contains commands for converting instrument data, transforming and

carrying out corrections. These functions are carried out subsequent to data acquisition, i.e. following

the SENSe subsystem.

The following subsystems are included:

•"CALCulate:FEED Subsystem (EVDO, K84)" on page 6.635

•"CALCulate:LIMit:ESPectrum Subsystem (EVDO, K84)" on page 6.636

•"CALCulate:LIMit:PVTime Subsystem (EVDO, K84)" on page 6.638

•"CALCulate:MARKer<1…4>:FUNCtion Subsystem (EVDO, K84)" on page 6.640

•"CALCulate:STATistics Subsystem (EVDO, K84)"on page 6.642

R&S FSL CALCulate Subsystem (EVDO, K84)

1300.2519.12 6.635 E-11

CALCulate:FEED Subsystem (EVDO, K84)

The CALCulate:FEED subsystem selects the type of evaluation for the measurement data. This

corresponds to the result display selection in manual operation.

Commands of the CALCulate:FEED Subsystem

–CALCulate<1|2>:FEED

CALCulate<1|2>:FEED

This command selects the result display for the measured data.The numeric suffix at

CALCulate<1|2> specifies the measurement window.

Parameter

XPOW:CDP Code Domain Power (CDP) result display (absolute)

XPOW:CDP:RAT Code Domain Power (CDP) result display (relative)

XPOW:CDEP Code Domain Error Power (CDEP) result display

XTIM:CDP:ERR:CTABle Channel Table result display

XTIM:CDP:PVChip Power vs Chip result display

XTIM:CDP:ERR:SUMM Result Summary result display

XTIM:CDP:MACCuracy Composite EVM result display

XTIM:CDP:ERR:PCDomain Peak Code Domain Error result display

XTIM:CDP:SYMB:CONSt Channel Constellation result display

XTIM:CDP:SYMB:EVM Symbol Error Vector Magnitude result display

XTIM:CDP:BSTReam Channel Bitstream result display

XTIM:CDP:COMP:CONSt Composite Constellation result display

XTIM:CDP:PVSYmbol Power versus Symbol result display

Example

CALC:FEED 'XTIM:CDP:MACC'

Selects the Composite EVM result display.

Characteristics

RST value: 'XPOW:CDP:RAT'

SCPI: device-specific

Mode

EVDO

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.636 E-11

CALCulate:LIMit:ESPectrum Subsystem (EVDO, K84)

The CALCulate:LIMit:ESPectrum subsystem defines the limit check for thr Spectrum Emission Mask.

Commands of the CALCulate:LIMit:ESPectrum Subsystem

–CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE

–CALCulate<1|2>:LIMit<1...8>:ESPectrum:RESTore

–CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue

CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE

This command activates or deactivates the automatic selection of the limit line in the Spectrum

Emission Mask measurement.The numeric suffix at CALCulate<1|2> specifies the

measurement window. The numeric suffix at LIMit<1...8> is irrelevant for this command.

Parameter

AUTO The limit line depends on the measured channel power.

MANUAL One of the three specified limit lines is set. The selection is made with the

CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue command.

Example

CONF:CDP:MEAS ESP

Selects Spectrum Emission Mask measurement.

CALC:LIM:ESP:MODE AUTO

Activates automatic selection of the limit line.

Characteristics

RST value: AUTO

SCPI: device-specific

Mode

EVDO

CALCulate<1|2>:LIMit<1...8>:ESPectrum:RESTore

This command restores the predefined limit lines for the Spectrum Emission Mask

measurement. All modifications made to the predefined limit lines are lost and the factory–set

values are restored.

The numeric suffix at CALCulate<1|2> specifies the measurement window. The numeric suffix

at LIMit<1...8> is irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

CALC:LIM:ESP:REST

Resets the limit lines for the Spectrum Emission Mask to the default setting.

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

R&S FSL CALCulate Subsystem (EVDO, K84)

1300.2519.12 6.637 E-11

CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue

.This command selects one of the following predefined limit lines. As a prerequisite, the

predefined limit lines must be activated using the

CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE command. This commands supported for

compatibility with the old FSL-K72. It is obsolete and only the

CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE command should be used. The user can

specify the exclusively used power class by using a value larger or equal to PMIN and smaller

than the PMAX of that Power Class.

The numeric suffixes <1|2> and <1...8> are irrelevant for this command.

Parameter

-200dBm to 200dBm

Example

Power Class 1 -200 dBm P < 28 dBm

Power Class 2 28 dBm P < 33 dBm

Power Class 3 33 dBm P < 200 dBm

Pstands for the expected power value.

CONF:CDP:MEAS ESP

Selects the spectrum emission mask measurement.

CALC:LIM:ESP:MODE MAN

Activates the selected predefined limit lines.

CALC:LIM:ESP:VAL 33

Selects the predefined limit line 33 dBm P < 200 dBm.(PowerClass3)

Characteristics

RST value: 0

SCPI: device–specific

Mode

EVDO

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.638 E-11

CALCulate:LIMit:PVTime Subsystem (EVDO, K84)

The CALCulate:LIMit:PVTime subsystem defines the limit check for power vs time measurement.

Commands of the CALCulate:LIMit:PVTime Subsystem

–CALCulate<1|2>:LIMit<1…8>:PVTime:REFerence

–CALCulate<1|2>:LIMit<1…8>:PVTime:RVALue

–CALCulate<1|2>:LIMit<1…8>:PVTime:RESTore

CALCulate<1|2>:LIMit<1…8>:PVTime:REFerence

This command sets the reference value. The standard asks for the sequence to first measure

the FULL slot with the limit line relative to the mean power of the averaged time response.

Therefore the parameter AUTO in a FULL slot measurement should be selected. In this mode

the mean power is calculated and the limit lines are relative to that mean power value. This

value should be used also as the reference for the IDLE slot measurement. With the parameter

ONCE the current mean power value of the averaged time response is used to set as the

fixedreference value for the limit lines. The mode is switched from AUTO to MANUAL. Now the

IDLE slot can be selected and the measurement sequence can be finished.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

AUTO | ONCE | MANual

Example

CALC:LIM:PVT:REF AUTO

Automatic reference value for limit lines. The value should be set to mean power

CALC:LIM:PVT:REF MAN

Manual reference value for limit lines

CALC:LIM:PVT:RVA -33.5

Set manual reference value to -33.5

CALC:LIM:PVT:REF ONCE

Set reference value to mean power

CALC:LIM:PVT:RVA?

Query reference value for limit lines. The value should be set to mean power value

Characteristics

RST value: AUTO

SCPI: device–specific

Mode

EVDO

R&S FSL CALCulate Subsystem (EVDO, K84)

1300.2519.12 6.639 E-11

CALCulate<1|2>:LIMit<1…8>:PVTime:RVALue

This command sets the reference level in dBm for calculating the limit lines Precondition is that

the automatic mode of power calculation is switched off via the commands

CALCulate<1|2>:LIMit<1…8>:PVTime:REFerence ONCE or .

CALCulate<1|2>:LIMit<1…8>:PVTime:REFerence MAN.

The numeric suffixes <1|2> are irrelevant for this command.

Parameter

-200dBm to 200dBm

Example

CALC:LIM:PVT:REF MAN

Manual reference value for limit lines

CALC:LIM:PVTime:RVA -33.5

Set manual reference value to -33.5

Characteristics

RST value: -20dBm

SCPI: device–specific

Mode

EVDO

CALCulate<1|2>:LIMit<1…8>:PVTime:RESTore

This command restores the standard limit lines for the power versus time measurement. All

changes made to the standard limit lines are lost and the state of these limit lines as they left the

factory is restored.

The numeric suffixes <1|2> are irrelevant for this command.

Example

CALC:LIM:PVT:REST

Reset the PVT limit lines to their default setting

Characteristics

RST value: --

SCPI: device–specific

Mode

EVDO

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.640 E-11

CALCulate:MARKer<1…4>:FUNCtion Subsystem (EVDO, K84)

The CALCulate:MARKer:FUNCtion subsystem checks the marker functions in the instrument.

Commands of the CALCulate:MARKer<1…4>:FUNCtion Subsystem

–CALCulate<1|2>:MARKer<1...4>:FUNCtion:CDPower[:BTS]:RESult?

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CDPower[:BTS]:RESult?

This command queries the measured and calculated values of the Code Domain Power

analysis. The channel type can be set by means of the [SENSe<1|2>:]CDPower:CTYPe

command, the slot number by means of the [SENSe<1|2>:]CDPower:SLOT command and

the code number by means of the [SENSe<1|2>:]CDPower:CODE command.

The numeric suffix at CALCulate<1|2> specifies the measurement window. The numeric suffix

at MARKer<1...4> is irrelevant for this command.

Parameter

CDPabsolute channel power absolute in dBm

CDPRelative channel power relative in dB

CERRor chip rate error in ppm

CHANnel channel number

DACtive number of active DATA channels

DMTYPe modulation type of the DATA channel type

(2=QPSK, 3=8-PSK, 4=16QAM)

EVMPeak error vector magnitude peak in %

EVMRms error vector magnitude rms in %

FERRor frequency error in Hz

FERPpm frequency error in ppm

IQIMbalance I/Q imbalance in %

IQOFfset I/Q offset in %

MACCuracy composite EVM in %

MACTive Number of active MAC channels

MTYPe modulation type of the channel type

(0=BPSK-I, 1=BPSK-Q, 2=QPSK, 3=8-PSK,

4=16QAM, 5=2BPSK)

PCDerror peak code domain error in dB

PDATa absolute power in the DATA channel type

PLENGth Length of preamble in chips

PMAC absolute power in the MAC channel type

POFFset phase offset in rad

PPILot absolute power in the PILOT channel type

PPReamble absolute power in the PREAMBLE channel type

PTOTal total power

R&S FSL CALCulate Subsystem (EVDO, K84)

1300.2519.12 6.641 E-11

RHO RHO value for the selected channel type/slot

RHOData RHO over all slots for the DATA area

RHOMac RHO over all slots for the MAC area

RHOPilot RHO over all slots for the pilot area

RHO1 RHOoverall–1 over all slots over all chips with

start of averaging at the half–slot limit

RHO2 RHOoverall–2 over all slots over all chips with

start of averaging at the quarter–slot limit

SFACtor spreading factor of the channel

SRATe symbol rate in ksps

TFRame trigger to frame in sec

TOFFset timing offset in s

Note: The Trigger to Frame value (TFRame) supplies a '9' if the trigger is at Free Run.

The Timing/Phase Offset values (TOFFset/POFFset) supply a '9' if timing and phase

measurement is disabled (refer to CDP:TPM) or the number of active channels is higher than

50.

Example

CALC:MARK:FUNC:CDP:RES? CDP

Reads out total power.

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.642 E-11

CALCulate:STATistics Subsystem (EVDO, K84)

The CALCulate:STATistics subsystem controls the statistical measurement functions. The

measurement window cannot be selected for these measurement functions. No numeric suffix at

CALCulate is available.

Commands of the CALCulate:STATistics Subsystem

–CALCulate:STATistics:CCDF[:STATe]

–CALCulate:STATistics:NSAMples

–CALCulate:STATistics:RESult<1…4>?

–CALCulate:STATistics:SCALe:Y:LOWer

–CALCulate:STATistics:SCALe:Y:UPPer

CALCulate:STATistics:CCDF[:STATe]

For details refer to the "CALCulate:STATistics:CCDF[:STATe]"command of the base unit on

page 6.112.

CALCulate:STATistics:NSAMples

For details refer to the "CALCulate:STATistics:NSAMples"command of the base unit on page

6.113.

CALCulate:STATistics:RESult<1…4>?

For details refer to the "CALCulate:STATistics:RESult<1...6>?"command of the base unit on

page 6.114.

CALCulate:STATistics:SCALe:Y:LOWer

For details refer to the "CALCulate:STATistics:SCALe:Y:LOWer"command of the base unit on

page 6.115.

CALCulate:STATistics:SCALe:Y:UPPer

For details refer to the "CALCulate:STATistics:SCALe:Y:UPPer"command of the base unit on

page 6.116.

R&S FSL CONFigure Subsystem (EVDO, K84)

1300.2519.12 6.643 E-11

CONFigure Subsystem (EVDO, K84)

The CONFigure subsystem contains commands for configuring the measurements.

The following subsystem is included:

•"CONFigure:CDPower Subsystem (EVDO, K84)" on page 6.644

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.644 E-11

CONFigure:CDPower Subsystem (EVDO, K84)

This subsystem contains the commands for measurement selection and configuration of the 1XEV-DO

BTS Analyzer option.

Further setting commands for the spectrum emission mask measurement are in the

"CALCulate:LIMit:ESPectrum Subsystem (EVDO, K84)" on page 6.636.

Commands of the CONFigure:CDPower Subsystem

–CONFigure:CDPower[:BTS]:CTABle[:STATe]

–CONFigure:CDPower[:BTS]:CTABle:CATalog?

–CONFigure:CDPower[:BTS]:CTABle:COMMent

–CONFigure:CDPower[:BTS]:CTABle:COPY

–CONFigure:CDPower[:BTS]:CTABle:DATA

–CONFigure:CDPower[:BTS]:CTABle:DELete

–CONFigure:CDPower[:BTS]:CTABle:NAME

–CONFigure:CDPower[:BTS]:CTABle:RESTore

–CONFigure:CDPower[:BTS]:CTABle:SELect

–CONFigure:CDPower[:BTS]:BCLass

–CONFigure:CDPower[:BTS]:MCARier[:STATe]

–CONFigure:CDPower[:BTS]:MEASurement

–CONFigure:CDPower[:BTS]:PVTime:BURSt

–CONFigure:CDPower[:BTS]:PVTime:FREStart

–CONFigure:CDPower[:BTS]:PVTime:LIST[:STATe]

–CONFigure:CDPower[:BTS]:PVTime:LIST:RESult?

–CONFigure:CDPower[:BTS]:REVision

–CONFigure:CDPower[:BTS]:RFSLot

CONFigure:CDPower[:BTS]:CTABle[:STATe]

This command activates or deactivates the ‘RECENT’ channel table. To select another channel

table, use the CONFigure:CDPower[:BTS]:CTABle:SELect command.

Parameter

ON | OFF

Example

CONF:CDP:CTAB ON

Activates predefined channel table.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

EVDO

R&S FSL CONFigure Subsystem (EVDO, K84)

1300.2519.12 6.645 E-11

CONFigure:CDPower[:BTS]:CTABle:CATalog?

This command queries the names of all the channel tables stored on the flash disk for 1xEV-

DO.

Return values

<sum of file sizes of all subsequent files>, <spare storage space on hard disk>, <1st file name>,

<1st file size>, <2nd file name>, <2nd file size>, ..., <nth file name>, <nth file size>, ...

Example

CONF:CDP:CTAB:CAT?

Queries catalog.

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:CTABle:COMMent

This command defines a comment on the selected channel table.

Parameter

<'string'> = comment on the channel table

Example

CONF:CDP:CTAB:NAME 'NEW_TAB'

Selects channel table for editing. If a channel table with this name does not exist, a new channel

table is created.

CONF:CDP:CTAB:COMM 'Comment for NEW_TAB'

Specifies 'Comment for NEW_TAB' as comment.

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:CTABle:COPY

This command copies one channel table to another. Select the channel table you want to copy

using the CONFigure:CDPower[:BTS]:CTABle:NAME command.

This command is an event and therefore has no *RST value and no query.

Parameter

<'string'> = name of the new channel table.

Example

CONF:CDP:CTAB:NAME 'CTAB_1'

Selects channel table CTAB_1 for copying.

CONF:CDP:CTAB:COPY 'CTAB_2'

Copies CTAB_1 to C_TAB2.

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.646 E-11

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:CTABle:DATA

This command defines a channel table.

Parameter

For one table line, eight values are specified .

<channel type>, <code class>, <code number>, <radio configuration>, <reserved1>,

<reserved2>, <status>, <CDP relative>, ....

Channel Type The channel type is numerically coded as follows:

0 = PILOT

1 = MAC

2 = PREAMBLE with 64 chip length

3 = PREAMBLE with 128 chip length

4 = PREAMBLE with 256 chip length

5 = PREAMBLE with 512 chip length

6 = PREAMBLE with 1024 chip length

7 = DATA

Code Class Depending on channel type, fixed: PILOT: 5, MAC: 6,

PREAMBLE: 5 and DATA: 4 (spreading factor =

2^code class)

Code number 0...spreading factor–1

Modulation Modulation type including mapping:

0 = BPSK–I

1 = BPSK–Q

2 = QPSK

3 = 8–PSK

4 = 16–QAM

Modulation types QPSK/8–PSK/16–QAM have

complex values.

Reserved 1 Always 0 (reserved)

Reserved 2 Always 0 (reserved)

Status 0: inactive, 1:active

Can be used in a setting command to disable a channel

temporarily

CDP relative Any with setting command, relative with CDP query

Before using this command, you must set the name of the channel table using the

CONFigure:CDPower[:BTS]:CTABle:NAME command.

R&S FSL CONFigure Subsystem (EVDO, K84)

1300.2519.12 6.647 E-11

Example

CONF:CDP:CTAB:NAME 'NEW_TAB'

Selects channel table for editing. If a channel table with this name does not exist, a new channel

table is created.

CONF:CDP:CTAB:DATA 0,6,0,0,0,0,1,0.0,10,5,3,4,0,0,1,0.0

Defines a table with the following channels: PICH 0.64 and data channel with RC4/Walsh code

3.32.

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:CTABle:DELete

This command deletes the selected channel table. Select the channel table you want to delete

using the CONFigure:CDPower[:BTS]:CTABle:NAME command.

This command is an event and therefore has no *RST value and no query.

Example

CONF:CDP:CTAB:NAME 'CTAB_2'

Selects channel table CTAB_2 for deleting.

CONF:CDP:CTAB:DEL

Deletes channel table CTAB_2.

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:CTABle:NAME

This command selects a channel table for editing or creating. To select a command for analysis,

use the CONFigure:CDPower[:BTS]:CTABle:SELect command.

Parameter

<'string'> = name of the channel table

Example

CONF:CDP:CTAB:NAME 'NEW_TAB'

Selects channel table for editing. If a channel table with this name does not exist, a new channel

table is created.

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.648 E-11

CONFigure:CDPower[:BTS]:CTABle:RESTore

This command restores the predefined channel tables to their factory–set values. In this way,

you can undo unintentional overwriting.

This command is an event and therefore has no *RST value and no query.

Example

INST:SEL BC2K

Activates the 1XEV-DO BTS Analyzer option.

CONF:CDP:CTAB:REST

Restores the channel table.

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:CTABle:SELect

This command selects a predefined channel table.

Parameter

<'string'> = name of the channel table

Example

Refer to the example of the CONFigure:CDPower[:BTS]:MCARier[:STATe] command.

Characteristics

RST value: "RECENT"

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:BCLass

This command selects the band class to be used.

Parameter

0800 MHz band

11900 MHz band

2TACS band

3JTACS band

4Korean PCS band

5450 MHz band

6 2 GHz band

7700 MHz band

81800 MHz band

9900 MHz band

R&S FSL CONFigure Subsystem (EVDO, K84)

1300.2519.12 6.649 E-11

10 Secondary 800 MHz band

11 400 MHz European PAMR band

12 800 MHz PAMR band

14US PCS 1.9GHz Band

15 AWS Band

Example

CONF:CDP:BCL 1

Selects band class 1, 1900 MHz

Characteristics

RST value: 0

SCPI: device specific

Mode

EVDO

CONFigure:CDPower[:BTS]:MCARier[:STATe]

This command activates or deactivates the settings that improve the processing of multi-carrier

signals.

Parameter

ON | OFF

Example

CONF:CDP:MCAR ON

Activates the multi-carrier settings.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:MEASurement

This command selects the measurements of the 1XEV-DO BTS Analyzer option. The

predefined settings of the different measurements are described in chapter 4, section "Softkeys

of the measurement menu (1XEV-DO BTS Analyzer mode)".

Parameter

ACLR adjacent–channel power measurement

CCDF measurement of complementary cumulative

distribution

CDPower code domain power measurement

ESPectrum measurement of spectrum emission mask

OBWidth measurement of the occupied bandwidth

POWer channel power measurement

PVTime Measurement of power versus time

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.650 E-11

Example

CONF:CDP:MEAS POW

Selects Signal Channel Power measurement .

Characteristics

RST value: CDPower

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:PVTime:BURSt

This command activates an automatic burst alignment to the center of the diagram.

Parameter

ON | OFF

Example

CONF:CDP:PVT:BURS ON

Activates the automatic alignment

Characteristics

RST value: OFF

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:PVTime:FREStart

If switched on, this command evaluates the limit line over all results at the end of a single

sweep. The sweep is restarted if this result is FAILED.

Parameter

ON | OFF

Example

CONF:CDP:PVT:FRES ON

Restarts a single sweep if the result evaluation is failed.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

EVDO

R&S FSL CONFigure Subsystem (EVDO, K84)

1300.2519.12 6.651 E-11

CONFigure:CDPower[:BTS]:PVTime:LIST[:STATe]

With this command the list evaluation which is off by default for backwards compatibility reasons

can be turned on.

Parameter

ON | OFF

Example

CONF:CDP:PVT:LIST[:STATe] ON

Characteristics

RST value: OFF

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:PVTime:LIST:RESult?

With this command the list evaluation results are queried in a defined order.

Example

CONF:CDP:PVT:LIST:RES

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

CONFigure:CDPower[:BTS]:REVision

With this command whether a revision 0 (subtype 0/1) signal or a revision A (subtype 2) signal

is analyzed.

Parameter

0 | A

Example

CONF:CDP:REV 0

Revision 0 signal is analyzed

Characteristics

RST value: 0

SCPI: device-specific

Mode

EVDO

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.652 E-11

CONFigure:CDPower[:BTS]:RFSLot

This command defines the expected signal: FULL slot or IDLE slot. Accordingly the limit lines

and the borders for calculating the mean power are set. The lower and upper limit line are called

DOPVTFL/DOPVTFU for FULL and DOPVTIL/DOPVTIU for IDLE mode. It is possible to change

these lines with the standard limit line editor.

Parameter

FULL | IDLE

Example

CONF:CDP:RFSL FULL

Use limit line for FILL slot and connect FILL slot signal

Characteristics

RST value: FULL

SCPI: device-specific

Mode

EVDO

R&S FSL DISPlay Subsystem (EVDO, K84)

1300.2519.12 6.653 E-11

DISPlay Subsystem (EVDO, K84)

The DISPLay subsystem controls the selection and presentation of textual and graphic information as

well as of measurement data on the display.

Commands of the DISPlay Subsystem

–DISPlay:FORMat

–DISPlay[:WINDow<1|2>]:SSELect

–DISPlay[:WINDow<1|2>]:TRACe<1…6>:Y[:SCALe]:AUTO

DISPlay:FORMat

This command sets the visible screen display type to full or split screen.

Parameter

SPLit | SINGle

Example

DISP:FORM SINGle

Sets the display to full screen.

Characteristics

*RST value: SPL

SCPI: device–specific

Mode

EVDO

DISPlay[:WINDow<1|2>]:SSELect

This command selects whether screen A or screen B is active. SSELect means Screen SELect.

Example

DISP:WIND1:SSEL

Sets the screen A active.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

EVDO

DISPlay[:WINDow<1|2>]:TRACe<1…6>:Y[:SCALe]:AUTO

This command switches on or off automatic scaling of the Y–axis for the specified trace display.

Automatic scaling sets the Y–axis to automatically scale to best fit the measurement results.

The numeric suffix at WINDow<1|2> selects the measurement window. The numeric suffix at

TRACe<1...6> must be 1.

Parameter

ONCE

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.654 E-11

Example

DISP:WIND2:TRAC1:Y:SCAL:AUTO ONCE

activates automatic scaling of the Y–axis for the active trace

Characteristics

*RST value: OFF

Mode

EVDO

R&S FSL INSTrument Subsystem (EVDO, K84)

1300.2519.12 6.655 E-11

INSTrument Subsystem (EVDO, K84)

The INSTrument subsystem selects the operating mode of the unit either via text parameters or fixed

numbers.

Commands of the INSTrument Subsystem

–INSTrument[:SELect]

–INSTrument:NSELect

INSTrument[:SELect]

Parameter

BC2K (1XEV-DO BTS Analyzer option, R&S FSL–K84)

For further details refer to theINSTrument subsystem of the base unit.

INSTrument:NSELect

Parameter

10 (1XEV-DO BTS Analyzer option, R&S FSL–K84)

For further details refer to the INSTrument subsystem of the base unit.

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.656 E-11

SENSe Subsystem (EVDO, K84)

The SENSe subsystem controls the essential parameters of the analyzer. In accordance with the SCPI

standard, the keyword "SENSe" is optional for this reason, which means that it is not necessary to

include the SENSe node in command sequences.

The following subsystems is included:

•"SENSe:CDPower Subsystem (EVDO, K84)" on page 6.656

SENSe:CDPower Subsystem (EVDO, K84)

This subsystem sets the parameters for the code domain measurements mode. The numeric suffix at

SENSe<1|2> is irrelevant.

Commands of the SENSe:CDPower Subsystem

–[SENSe<1|2>:]CDPower:AVERage

–[SENSe<1|2>:]CDPower:CODE

–[SENSe<1|2>:]CDPower:ICTReshold

–[SENSe<1|2>:]CDPower:IQLength

–[SENSe<1|2>:]CDPower:CTYPe

–[SENSe<1|2>:]CDPower:ICTReshold

–[SENSe<1|2>:]CDPower:IQLength

–[SENSe<1|2>:]CDPower:LEVel:ADJust

–[SENSe<1|2>:]CDPower:MAPPing

–[SENSe<1|2>:]CDPower:MMODe

–[SENSe<1|2>:]CDPower:NORMalize

–[SENSe<1|2>:]CDPower:OVERview

–[SENSe<1|2>:]CDPower:PNOFfset

–[SENSe<1|2>:]CDPower:QINVert

–[SENSe<1|2>:]CDPower:SBANd

–[SENSe<1|2>:]CDPower:SLOT

–[SENSe<1|2>:]CDPower:TPMeas

[SENSe<1|2>:]CDPower:AVERage

This command can be precisely enabled by means of ON when the Code Domain Power

analysis is active (refer to CALCulate<1|2>:FEED). If averaging is active, the CDP is calculated

over all slots and displayed as called for by the 1xEV–DO Standard.

Parameter

ON | OFF

Example

CDP:AVER ON

Activate averaging CDP relative over all slots and display on screen A.

R&S FSL SENSe Subsystem (EVDO, K84)

1300.2519.12 6.657 E-11

Characteristics

RST value: 0

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:CODE

This command selects the code number. The maximum number depends on the channel type

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

Channel Type Spreading factor Code number

PILOT 32 0…31

MAC REV 0 64

REV A 128

0...63

0...127

PREAMBLE REV 0 32

REV A 64

0...31

0...63

DATA 64 0...31

Example

CDP:CODE 11

Selects code number 11.

Characteristics

RST value: 0

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:ICTReshold

This command defines the minimum power which a single channel must have compared to the

total signal in order to be regarded as an active channel. Channels below the specified

threshold are regarded as "inactive".

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

–100 dB to 0 dB

Example

CDP:ICTR –10DB

Sets threshold value to –10 dB.

Characteristics

RST value: –40 dB

SCPI: device-specific

Mode

EVDO

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.658 E-11

[SENSe<1|2>:]CDPower:IQLength

This command sets the capture length in multiples of the power control group.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

2to 12

Example

CDP:IQL 8

Sets 8 PCGs as capture length.

Characteristics

RST value: 3

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:CTYPe

This command is used to select the channel type. The number of results then changes in most

analyses, such as code domain power, symbol EVM, and bit stream, because either a different

spreading factor or a different number of symbols is available for the analysis.

Parameter

PILot | MAC | PREamble | DATA

Example

CDP:CTYP MAC

Select MAC channel type.

Characteristics

RST value: PILOT

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:ICTReshold

This command defines the minimum power which a single channel must have compared to the

total signal in order to be regarded as an active channel. Channels below the specified

threshold are regarded as "inactive".

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

–100 dB to 10 dB

Example

CDP:ICTR –10

Sets the minimum power threshold to –10 dB.

R&S FSL SENSe Subsystem (EVDO, K84)

1300.2519.12 6.659 E-11

Characteristics

RST value: –40 dB

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:IQLength

This command sets the capture length in multiples of the slot.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

2to 12

Example

CDP:IQL 10

Sets the capture length to 10.

Characteristics

RST value: 3

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:LEVel:ADJust

This command adjusts the reference level of the R&S FSL to the measured channel power. This

ensures that the settings of the RF attenuation and the reference level are optimally adjusted to

the signal level without overloading the R&S FSL or limiting the dynamic response by a too low

signal–to–noise ratio.The numeric suffix at SENSe<1|2> is irrelevant for this command.

This command is an event and therefore has no *RST value and no query.

Example

CDP:LEV:ADJ

Adjusts the reference level to the measured channel power.

Characteristics

RST value: -

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:MAPPing

This command selects, when the mapping mode is not Complex, whether the I or Q branch

should be analyzed.

Parameter

I | Q

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.660 E-11

Example

CDP:MAPP Q

Selects the Q branch.

Characteristics

RST value: I

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:MMODe

This command defines the mapping mode. With AUTO, internal working takes place in

"Complex" mapping mode for the DATA channel type and "I or Q" for the PILOT, MAC and

PREAMBLE channel types. With this command, each mapping mode can be determined

personally for all channel types, or it is possible to return to AUTO.

Parameter

AUTO | IOQ | COMPlex

Example

CDP:MMODe COMP

The pilot channel type is analyzed complex

Characteristics

RST value: AUTO

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:NORMalize

This command activates or deactivates the elimination of the IQ offset from the signal.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

ON | OFF

Example

CDPower:NORMalize ON

Activates the elimination of the I/Q offset.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

EVDO

R&S FSL SENSe Subsystem (EVDO, K84)

1300.2519.12 6.661 E-11

[SENSe<1|2>:]CDPower:OVERview

This command can be enabled can be precisely enabled by means of ON when either the Code

Domain Power or the Code Domain Error Power analysis is active (refer to

CALCulate<1|2>:FEED). In Overview mode, the I branch of the signal is normally displayed on

screen A and the Q branch of the signal on screen B with the CDP/CDEP. The branches can be

read out separately by means of TRAC:DATA? TRACE1 and TRAC:DATA? TRACE2. The

previous analyses become active again when you exit Overview mode.

If an analysis other than Code Domain Power or Code Domain Error Power is selected when

Overview mode is active, you exit Overview mode and the previous analysis is reset on the

other screen.

Parameter

ON | OFF

Example

CDP:OVER ON

Activate Overview mode.

CDP Relative on screen A I branch.CDP Relative on screen B Q branch

Characteristics

RST value: OFF

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:PNOFfset

This command sets the PN offset of the base station in multiples of 64 chips.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

0to 511

Example

INST:SEL BC2K

Activates the 1XEV-DO BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:PNOF 45

Sets PN offset.

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: 0

SCPI: device-specific

Mode

EVDO

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.662 E-11

[SENSe<1|2>:]CDPower:QINVert

This command inverts the sign of the Q–component of the signal.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

ON | OFF

Example

INST:SEL BC2K

Activates the 1XEV-DO BTS Analyzer option.

INIT:CONT OFF

Selects single sweep.

CDP:QINV ON

Activates the inversion of the Q–component sign.

INIT;*WAI

Starts measurement with synchronization.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:SBANd

This command is used to swap the left and right sideband.

Parameter

NORMal | INVers

Example

CDP:SBAN INV

Swap sidebands.

Characteristics

RST value: NORMal

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:SLOT

This command selects the slot that is evaluated in the Code Domain Power Diagram and is

used for slot–based evaluations in the Code Domain Result Summary.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

Parameter

0to (capture length–1)

The capture length is defined via the [SENSe<1|2>:]CDPower:IQLength command.

R&S FSL SENSe Subsystem (EVDO, K84)

1300.2519.12 6.663 E-11

Example

CDP:SLOT 2

Selects power control group 2.

Characteristics

RST value: 0

SCPI: device-specific

Mode

EVDO

[SENSe<1|2>:]CDPower:TPMeas

This command actives or deactivates the timing and phase offset evaluation of the channels to

the pilot. If the value is OFF or if more than 50 channels are active, the command TRACe? and

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CDPower[:BTS]:RESult? returns a value

of '9' for the timing and phase offset as the result. If the value is ON, the timing and phase

offsets are calculated and returned.

The numeric suffix at SENSe<1|2> is irrelevant for this command.

The results are queried using theTRACe<1|2>[:DATA]command and the

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CDPower[:BTS]:RESult? command.

Parameter

ON | OFF

Example

CDP:TPM ON

Activate timing and phase offset.

Characteristics

RST value: OFF

SCPI: device-specific

Mode

EVDO

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.664 E-11

TRACe Subsystem (1xEV-DO, K84)

The TRACe subsystem controls access to the instruments internal trace memory.

Commands of the TRACe Subsystem

–TRACe<1|2>[:DATA]? LIST

–TRACe<1|2>[:DATA]

Further information

–Characteristics of the 1xEV-DO channel types

Characteristics of the 1xEV-DO channel types

The following table shows the characteristics of the channel types in the 1xEV-DO standard.

Bits per Slot and Code Channel

Type

Spreading

Factor

Symbol

Rate

Modulation Type Chips per Slot Symbols per

Slot and Code

Mapping I or Q Mapping

Complex

PILOT 32 38.4 ksps BPSK-I or BPSK-Q 96*2=192 6 6 12

MAC Rev. 0 64

Rev. A

19.2 ksps

9.6 ksps

BPSK-I or BPSK-Q 64*4=256 4

PREAMB

Rev. 0 32

Rev. A 64

38.4 ksps

19.2 ksps

BPSK-I or BPSK-Q

Preamble length

64:

128:

256:

512:

1024:

64:

128:

256:

512:

1024:

DATA 16 76.8 ksps QPSK, 8-PSK,

16QAM

Mapping always Complex

Modulation Type

400*4

-PreambleChips

=DataNettoChips

QPSK 8-PSK 16QA

1600-0 = 1600

1600-64 = 1536

1600-128 = 1472

1600-256 = 1344

1600-512 = 1088

1600-1024=576

100

200

192

184

168

136

300

288

276

252

204

104

400

384

368

336

272

144

R&S FSL TRACe Subsystem (1xEV-DO, K84)

1300.2519.12 6.665 E-11

TRACe<1|2>[:DATA]? LIST

This command returns the peak list. For each peak the following entries are given:

<freq1>, <level1>, <delta level 1>, <freq2>, <level2>, <delta level 2>, ... <freq n>, <level n>,

Parameter

LIST

Example

TRAC1:DATA? LIST

Peak list consist of Frequency of the peak, absolute level of the peak and distance to the limit

line

Characteristics

RST value: -

SCPI: device–specific

Mode

EVDO

TRACe<1|2>[:DATA]

The numeric suffixes <1|2> are irrelevant for this command except TRAC2? TRACe1 command

in this case the numeric suffix <2> is screen B.

Parameter for code domain power measurements

TRACE1 | TRACE2 Reads out the trace data of measurement window 1 or 2.

CTABle For the Channel Table result display, reads out the maximum values of the

timing/phase offset between every assigned channel and the pilot channel

(see also [SENSe<1|2>:]CDPower:TPMeas command).

Return values

The return values for each measurement are listed below:

–Code Domain Power

–General Results / Channel Results

–Power vs Chip

–Power vs Symbol

–Composite EVM

–Channel Table

–Bitstream

–Peak Code Domain Error

–Code Domain Error

–Symbol Constellation

–EVM vs Symbol

–Composite Constellation

–Return values for parameter CTABle

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.666 E-11

Characteristics

RST value: -

SCPI: device–specific

Mode

EVDO

Code Domain Power

The command returns three values for every code in a channel in the following order:

<code number>,<absolute level | relative level >,< power ID>, ...

Return values

Value Description Range Unit

<code number> code number of the channel {0…spreading

factor-1}

<absolute level> Absolute level of the code channel at the

selected channel slot

{–



...



}dBm

<relative level> relative level of the channel referenced to total

power in the channel type

{–



...



}dB

<power ID> Power indication

0–inactive channel, 1 – active channel

{0,1}

The number of codes that are displayed corresponds to the spreading factor. The spreading

factor in turn depends on the selected channel types. Therefore, 32 value triplets are returned

for PILOT and PREAMBLE channels, 16 value triplets for DATA channels and 64 value triplets

for MAC channels (see Characteristics of the 1xEV-DO channel types on page 6.664).

In addition, the output depends on the mapping settings. The output is either the I branch, the Q

branch or the complex signal. If Code Domain Overview is activated, trace 1 shows the I branch

and trace 2 shows the Q branch by default.

General Results / Channel Results

The command returns 30 values selected channel in the following order::

<FERRor>, <FERPpm>, <CERRor>, <TFRame>, <RHOPilot>, <RHO1>, <RHO2>, <PPILot>,

<PMAC>, <PDATa>, <PPReamble>, <MACCuracy>,<DMTYpe>, <MACTive>, <DACTive>,

<PLENGth>, <RHO>, <PCDerror> , <IQIMbalance>, <IQOFfset>, <SRATe>, <CHANnel>,

<SFACtor> <TOFFset>, <POFFset>, <CDPRelative>, <CDPabsolute>, <EVMRms>,

Return values

Value Description Range Unit

<FERRor> Frequency error in Hz Hz

<FERPpm> Frequency error in ppm ppm

<CERRor> Chip rate error in ppm ppm

<TFRame> Trigger to frame

Note: The Trigger to Frame value (TFRame)

supplies a '9' if the trigger is at FREE RUN.The

Timing/Phase Offset values (TOFFset/

POFFset) supply a '9' if timing and phase

measurement is disabled (refer to CDP:TPM)

or the number of active channels is higher than

<RHOPilot> RHO over all slots for the pilot area

R&S FSL TRACe Subsystem (1xEV-DO, K84)

1300.2519.12 6.667 E-11

Value Description Range Unit

<RHO1> RHOoverall–1 over all slots over all chips with

start of averaging at the half–slot limit

<RHO2> RHOoverall–2 over all slots over all chips with

start of averaging at the quarter–slot limit

<PPILot> Absolute power in the PILOT channel type dBm

<PMAC> Absolute power in the MAC channel type dBm

<PDATa> Absolute power in the DATA channel type dBm

<PPReamble> Absolute power in the PREAMBLE channel

type

dBm

<MACCuracy> Composit EVM in % %

<DMTYpe> Modulation type in the DATA channel type:

2 = QPSK, 3 = 8–PSK, 4 = 16–QAM

MACTive Number of active

<MACTive> Number of active MAC channels

<DACTive> Number of active DATA channels

<PLENGth> Length of preamble in chips

<RHO> RHO value for the selected channel type/slot

<PCDerror> Peak Code Domain error in dB dB

<IQIMbalance> IQ imbalance in % %

<IQOFfset> IQ offset in % %

<SRATe> Symbol rate in ksps ksps

<CHANnel> Channel number

<SFACtor> Spreading factor of the channel

<TOFFset> If the evaluation of the timing and phase offset

is not active(refer to CDPower:TPMeas) or

more than 50 active channels are in the signal,

the value 9 is returned. For inactive channels,

the value 9 is returned.

<POFFset> If the evaluation of the timing and phase offset

is not active (refer to CDPower:TPMeas) or

more than 50 active channels are in the signal,

the value 9 is returned. For inactive channels,

the value 9 is returned.

<CDPRelative> relative level of the channel referenced to total

power in the channel type

{–



...



}dB

<CDPAbsolute> absolute level of the code channel at the

selected channel slot

{–



...



}dBm

<EVMRms> Error vector magnitude rms in % %

<EVMPeak> Error vector magnitude peak in % %

<MTYPe> Modulation type:

0 = BPSK–I, 1 = BPSK–Q, 2 = QPSK, 3 = 8–

PSK, 4 = 16–QAM, 5 = 2BPSK (if complex

analysis selected for PILOT, PREAMBLE or

MAC)

Power vs Chip

The command returns one value for every chip in the following order:

<level value in dBm>, <level value in dBm>, …

The number of results that are displayed is always 2048, one power level for every chip.

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.668 E-11

Power vs Symbol

The command returns one value for every symbol in the following order:

<value in dBm symbol 0>, <value in dBm symbol 1>, …

The number of results that are displayed depends on the number of symbols and is between 2

and 100.

Composite EVM

The command returns two values for every slot in the following order:

<Slot number>, <value in %>, <Slot number>, <value in %>, …

The number of pairs of variates that is displayed corresponds to the IQ capture length.

Therefore the number of results is between 2 and 12.

Channel Table

The command returns 8 values for all active channels in the following order:

<channel type>, <code class>, <code number>, <modulation>, <absolute level>, <relative

level>, <timing offset>, <phase offset>, ...

The channels are listed in the following channel type order: PILOT, MAC, PREAMBLE, DATA.

Within the channel types, the channels are sorted in ascending code number order.

Return values

Value Description Range Unit

<channel type> channel type indication

The channel type is coded with numbers as follows:

0 = PILOT, 1 = MAC, 2 = PREAMBLE with 64chip , 3

=PREAMBLE with 128chip, 4 = PREAMBLE with

256chip, 5 = PREAMBLE with 512chip, 6 =

PREAMBLE with 1024chip, 7 = DATA

{0 ... 7} <channel type>

<code class> code class of the channel

The code class depends on channel type:

PILOT:5, MAC:6, PREAMBLE:5 and DATA:4

(spreading factor = 2^code class)

{2 ... 7}

<code number> code number of the channel {0…spreading

factor-1}

<Modulation> Modulation type including mapping:

0 = BPSK-I, 1= BPSK-Q, 2 = QPSK, 3 = 8-PSK, 4 =

16-QAM

<absolute level> absolute level of the code channel at the selected

channel slot

{–



...



}dBm

<relative level> relative level of the channel referenced to total power

in the channel type

{–



...



}dB

<timing offset> Timing offset of the channel to the frame start.

Referred to the first active channel in seconds

If the evaluation of the timing and phase offset is not

active(refer to CDPower:TPMeas) or more than 50

active channels are in the signal, the value 9 is

returned. For inactive channels, the value 9 is

returned.

<phase offset> Phase offset Referred to the first active channel in

rad.

If the evaluation of the timing and phase offset is not

active (refer to CDPower:TPMeas) or more than 50

active channels are in the signal, the value 9 is

returned. For inactive channels, the value 9 is

returned.

R&S FSL TRACe Subsystem (1xEV-DO, K84)

1300.2519.12 6.669 E-11

Bitstream

The command returns the bitstream of one slot, i.e. it returns one value for every bit (either 0 or

1) in a symbol in the following order:

<bit 1>, <bit 2>,…, <bit n>,...

The number of returned bits depends on the modulation type. For BPSK modulated signals

there is one bit per symbol, for 2BPSK and QPSK signals there are 2 bits per symbol, for 8-PSK

modulated signals there are 3 bits per symbol and for 16QAM modulated signal there are 4 bits

per symbol. Accordingly, the bitstream per slot is of different lengths. The number of results is

between 2 and 400.

Peak Code Domain Error

The command returns two values for every slot in the following order:

<slot number>, <level value in dB>, <slot number>, <level value in dB>, …

The number of results corresponds to the IQ capture length. The number of results is between 2

and 12.

Code Domain Error

The command returns three values for every code in a channel in the following order:

<code number>,<error power >,< power ID>, ...

Return values

Value Description Range Unit

<code number> number of the code

<error power> value of the composite EVM %

<power ID> Power indication

0–inactive channel, 1 – active channel

{0,1}

The number of results corresponds to the spreading factor. The spreading factor in turn

depends on the selected channel types. Therefore, 32 value triplets are returned for PILOT and

PREAMBLE channels, 16 value triplets for DATA channels and 64 value triplets for MAC

channels (see Characteristics of the 1xEV-DO channel types on page 6.664).

In addition, the output depends on the mapping settings. The output is either the I branch, the Q

branch or the complex signal. If Code Domain Overview is activated, trace 1 shows the I branch

and trace 2 shows the Q branch by default.

Symbol Constellation

The command returns two values, the real and imaginary parts, for every symbol in the following

order:

<re 0>, <im 0>, <re 1>, <im 1>, …, <re n>, <im n>, …

The number of results depends on the number of symbols and is between 2 and 100 (see

Characteristics of the 1xEV-DO channel types,column 'Number of symbols per slot and code'

on page 6.664).

EVM vs Symbol

The command returns one value for every symbol in the following order:

<value in % symbol 0>, <value in % symbol 1>, …

The number of results depends on the number of symbols and is between 2 and 100.

Remote Commands of the 1xEV-DO BTS Analyzer Option (K84) R&S FSL

1300.2519.12 6.670 E-11

Composite Constellation

The command returns two values, the real and imaginary parts, for every chip in the following

order:

<re chip 0>, <im chip 0>, <re chip 1>, <im chip 1>, …, <re chip n>, <im chip n>, …

The number of results corresponds to the number of chips of the selected channel type.

Therefore the number of results is between 64 and 1600 chips per slot (see Characteristics of

the 1xEV-DO channel types,column 'Chips per slot' on page 6.664).

Return values for parameter CTABle

The command returns 12 values (including 4 reserved values) for maximum timing and phase

offsets in the following order:

<max. time offset in s>, <channel type>, <code number for max. time>, <code class for max.

time>, <max. phase offset in rad>, <channel type>, <code number for max. phase>, <code

class for max. phase>, <reserved 1>, ..., <reserved 4>,

Return values

Value Description Range Unit

<max. time offset in s> Max timing offset value of all channels s

<channel type> channel type indication

The channel type is coded with numbers as follows:

0 = PILOT, 1 = MAC, 2 = PREAMBLE with 64chip , 3

=PREAMBLE with 128chip, 4 = PREAMBLE with

256chip, 5 = PREAMBLE with 512chip, 6 =

PREAMBLE with 1024chip, 7 = DATA

{0 ... 7}

<code number for max. time> The code number which has max timing offset value

<code class for max. time> The code class which has max timing offset value

<max. phase offset in rad> Max phase offset value of all channels rad

<code number for max. phase> The code number which has max phase offset value

<code class for max. phase> The code class which has max phase offset value

<reserved> reserved for future functionality {0}

R&S FSL TRACe Subsystem (1xEV-DO, K84)

1300.2519.12 6.671 E-11

Remote Commands of the WLAN TX Measurements

Option (K91 / K91n)

This section describes the remote commands for the WLAN TX Measurements option (K91 / K91n).

The abbreviation WLAN stands for the Wireless LAN operating mode. For details on conventions used

in this chapter refer to section "Notation" on page 6.2 at the beginning of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in section "Remote Commands of the Base Unit" on page 6.5.

The option R&S FSL-K91 is available from firmware version 1.20.

The option R&S FSL-K91n is available from firmware version 1.90.

Subsystems of the WLAN TX Measurements option (K91 / K91n)

–"ABORt Subsystem (WLAN, K91 / K91n)" on page 6.672

–"CALCulate:BURSt Subsystem (WLAN, K91 / K91n)" on page 6.673

–"CALCulate:LIMit Subsystem (WLAN, K91 / K91n)" on page 6.674

–"CALCulate:MARKer Subsystem (WLAN, K91 / K91n)" on page 6.691

–"CONFigure Subsystem (WLAN, K91 / K91n)" on page 6.698

–"DISPlay Subsystem (WLAN, K91 / K91n)" on page 6.709

–"FETCh Subsystem (WLAN, K91 / K91n)" on page 6.712

–"FORMat Subsystem (WLAN, K91 / K91n)" on page 6.721

– "INITiate Subsystem (WLAN, K91 / K91n)" on page 6.722

–"INPut Subsystem (WLAN, K91 / K91n)" on page 6.723

–"INSTrument Subsystem (WLAN, K91 / K91n)" on page 6.724

–"MMEMory Subsystem (WLAN, K91 / K91n)" on page 6.725

–"SENSe Subsystem (WLAN, K91 / K91n)" on page 6.726

–"STATus Subsystem (WLAN, K91 / K91n)" on page 6.741

–"TRACe Subsystem (WLAN, K91 / K91n)" on page 6.745

–"TRIGger Subsystem (WLAN, K91 / K91n)" on page 6.751

–"UNIT Subsystem (WLAN, K91 / K91n)" on page 6.753

ABORt Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.672 E-11

ABORt Subsystem (WLAN, K91 / K91n)

The ABORt subsystem contains the commands for aborting triggered actions.

Commands of the ABORt Subsystem

–ABORt

ABORt

For details refer to "ABORt" on page 6.10.

R&S FSL CALCulate:BURSt Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.673 E-11

CALCulate:BURSt Subsystem (WLAN, K91 / K91n)

The CALCulate:BURSt subsystem checks the IQ measurement results.

Commands of the CALCulate:BURSt Subsystem

–CALCulate<1|2>:BURSt[:IMMediate]

CALCulate<1|2>:BURSt[:IMMediate]

This command forces the IQ measurement results to be recalculated according to the current

settings.

This command is an event and therefore has no *RST value and no query.

Example

CALC1:BURS

Starts the recalculation of the IQ measurement results.

Characteristics

RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate:LIMit Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.674 E-11

CALCulate:LIMit Subsystem (WLAN, K91 / K91n)

The CALCulate:LIMit subsystem contains commands for the limit lines and the corresponding limit

checks.

Commands of the CALCulate:LIMit Subsystem

–CALCulate<1|2>:LIMit<1...8>:FAIL?

–CALCulate<1|2>:LIMit<1>:ACPower:ACHannel?

–CALCulate<1|2>:LIMit<1>:ACPower:ACHannel:RESult?

–CALCulate<1|2>:LIMit<1>:ACPower:ALTernate?

–CALCulate<1|2>:LIMit<1>:ACPower:ALTernate:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:ALL

–CALCulate<1|2>:LIMit<1>:BURSt:ALL:RESUlt?

–CALCulate<1|2>:LIMit<1>:BURSt:EVM[:AVERage]

–CALCulate<1|2>:LIMit<1>:BURSt:EVM[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL[:AVERage]

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL:MAXimum

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA[:AVERage]

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA:MAXimum

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:MAXimum

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot[:AVERage]

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot:MAXimum

–CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:FERRor[:AVERage]

–CALCulate<1|2>:LIMit<1>:BURSt:FERRor[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:FERRor:MAXimum

–CALCulate<1|2>:LIMit<1>:BURSt:FERRor:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset[:AVERage]

–CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset:MAXimum

–CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror[:AVERage]

–CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror[:AVERage]:RESult?

R&S FSL CALCulate:LIMit Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.675 E-11

–CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror:MAXimum

–CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:TFALl[:AVERage]

–CALCulate<1|2>:LIMit<1>:BURSt:TFALl[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:TFALl:MAXimum

–CALCulate<1|2>:LIMit<1>:BURSt:TFALl:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:TRISe[:AVERage]

–CALCulate<1|2>:LIMit<1>:BURSt:TRISe[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1>:BURSt:TRISe:MAXimum

–CALCulate<1|2>:LIMit<1>:BURSt:TRISe:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1>:SPECtrum:MASK:CHECk:X?

–CALCulate<1|2>:LIMit<1>:SPECtrum:MASK:CHECk:Y?

CALCulate<1|2>:LIMit<1...8>:FAIL?

For option WLAN TX Measurements, K91, the numeric suffixes <1...8> specify the limit lines as

follows:

Suffix Limit

1to 2 These indexes are not used

3ETSI Spectrum Mask limit line

4Spectrum Flatness (Upper) limit

line

5Spectrum Flatness (Lower) limit

line

6IEEE Spectrum Mask limit line

7PVT Rising Edge max limit

8PVT Rising Edge mean limit

9PVT Falling Edge max limit

10 PVT Falling Edge mean limit

For further details refer to "CALCulate<1|2>:LIMit<1...8>:FAIL?" on page 6.31.

CALCulate<1|2>:LIMit<1>:ACPower:ACHannel?

This command returns the ACP adjacent channel limit for IEEE 802.11j if defined.

This command is a query only and thus has no *RST value.

Parameter

numeric value in dB

Example

CALC:LIM:ACP:ACH?

Returns the IEEE 802.11j ACP adjacent channel limit.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate:LIMit Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.676 E-11

CALCulate<1|2>:LIMit<1>:ACPower:ACHannel:RESult?

For details refer to "CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:RESult?" on page 6.36.

CALCulate<1|2>:LIMit<1>:ACPower:ALTernate?

This command returns the ACP alternate channel limit for IEEE 802.11j if defined.

Parameter

numeric value in dB

Example

CALC:LIM:ACP:ALT?

Returns the IEEE 802.11j ACP alternate channel limit.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:ACPower:ALTernate:RESult?

For details refer to "CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1...11>:RESult?" on

page 6.40.

CALCulate<1|2>:LIMit<1>:BURSt:ALL

This command sets or returns all the limit values.

Parameter

The results are input or output as a list of values separated by ',' in the following (ASCII) format:

<average frequency error>, <max frequency error>,

<average symbol error>, <max symbol error>,

<average IQ offset>, <maximum IQ offset>,

<average EVM all bursts>, <max EVM all bursts>,

Note: The units for the EVM results are specified with the UNIT:EVM command.

Example

CALC:LIM:BURS:ALL?

All limit values are returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CALCulate:LIMit Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.677 E-11

CALCulate<1|2>:LIMit<1>:BURSt:ALL:RESUlt?

This command returns all the limit results.

This command is a query only and thus has no *RST value.

Parameter

For details on formats refer to "CALCulate<1|2>:LIMit<1>:BURSt:ALL" on page 6.676.

Example

CALC:LIM:BURS:ALL:RES?

All limit values are returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM[:AVERage]

This command sets the average Error Vector Magnitude Limit for the IEEE 802.11b standard.

Parameter

numeric value in dB

Example

CALC:LIM:BURS:EVM –25.0

Average EVM limit is set to –25 dB

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM[:AVERage]:RESult?

This command returns the average Error Vector Magnitude Limit result for the IEEE 802.11b

standard.

This command is a query only and thus has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:RES?

Average EVM limit result is returned

CALCulate:LIMit Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.678 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL[:AVERage]

This command sets the average Error Vector Magnitude Limit. This is a combined figure that

represents the pilot, data and the free carrier.

Parameter

numeric value in dB

Example

CALC:LIM:BURS:EVM:ALL –25.0

Average EVM for all carrier limit is set to –25.0 dB

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL[:AVERage]:RESult?

This command returns the average Error Vector Magnitude Limit result. This is a combined

figure that represents the pilot, data and the free carrier.

This command is a query only and thus has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:ALL:RES?

Average EVM for all carrier limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CALCulate:LIMit Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.679 E-11

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL:MAXimum

This command sets the maximum Error Vector Magnitude Limit. This is a combined figure that

represents the pilot, data and the free carrier.

Parameter

numeric value in dB

Example

CALC:LIM:BURS:EVM:ALL:MAX?

Maximum EVM for all carrier limit is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL:MAXimum:RESult?

This command returns the maximum Error Vector Magnitude Limit result. This is a combined

figure that represents the pilot, data and the free carrier.? (K91 / K91n)"

This command is a query only and thus has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:ALL:MAX:RES?

Maximum EVM for all carrier limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA[:AVERage]

This command sets the average Error Vector Magnitude limit summary for the data carrier.

Parameter

numeric value in dB

Example

CALC:LIM:BURS:EVM:DATA –30.0

Average EVM for data carrier limit is set to –30.0 dB

CALCulate:LIMit Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.680 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA[:AVERage]:RESult?

This command returns the average Error Vector Magnitude limit result summary for the data

carrier.

This command is a query only and thus has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:DATA:RES?

Average EVM for data carrier limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA:MAXimum

This command sets the maximum Error Vector Magnitude limit summary for the data carrier.

Parameter

numeric value in dB

Example

CALC:LIM:BURS:EVM:DATA:MAX?

Maximum EVM for data burst limit is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CALCulate:LIMit Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.681 E-11

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA:MAXimum:RESult?

This command returns the maximum Error Vector Magnitude limit result summary for the data

carrier.

This command is a query only and thus has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:DATA:MAX:RES?

Maximum EVM for data carrier limit result is returned Characteristics.

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:MAXimum

This command sets the maximum Error Vector Magnitude Limit for the IEEE 802.11b standard.

Parameter

numeric value in dB

Example

CALC:LIM:BURS:EVM:MAX?

Maximum EVM limit is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:MAXimum:RESult?

This command returns the maximum Error Vector Magnitude Limit result for the IEEE 802.11b

standard.

This command is a query only and thus has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:MAX:RES?

Maximum EVM limit result is returned

CALCulate:LIMit Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.682 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot[:AVERage]

This command sets the average Error Vector Magnitude limit summary for the pilot carriers.

Parameter

numeric value in dB

Example

CALC:LIM:BURS:EVM:PIL –8.0

Average EVM for pilot carrier limit is set to –8.0 dB

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot[:AVERage]:RESult?

This command returns the average Error Vector Magnitude limit result summary for the pilot

carriers.

This command is a query only and thus has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:PIL:RES?

Average EVM for pilot carrier limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CALCulate:LIMit Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.683 E-11

CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot:MAXimum

This command sets the maximum Error Vector Magnitude limit summary for the pilot carriers.

Parameter

numeric value in dB

Example

CALC:LIM:BURS:EVM:PIL:MAX?

Maximum EVM for pilot carrier limit is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot:MAXimum:RESult?

This command returns the maximum Error Vector Magnitude limit result summary for the pilot

carriers.

This command is a query only and thus has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:PIL:MAX:RES?

Maximum EVM for pilot carrier limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:FERRor[:AVERage]

This command sets the average frequency error limit.

Parameter

numeric value in Hertz

Example

CALC:LIM:BURS:FERR 10000

T h e a v e r a g e f r e q u e n c y e r r o r l i m i t i s s e t t o 1 0 k H z

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate:LIMit Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.684 E-11

CALCulate<1|2>:LIMit<1>:BURSt:FERRor[:AVERage]:RESult?

This command returns the average frequency error limit result.

This command is a query only and thus has no *RST value.

Example

CALC:LIM:BURS:FERR:RES?

Average frequency error limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:FERRor:MAXimum

This command sets the maximum frequency error limit.

Parameter

numeric value in Hertz

Example

CALC:LIM:BURS:FERR:MAX?

Maximum frequency error limit is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:FERRor:MAXimum:RESult?

This command returns the maximum frequency error limit result.

This command is a query only and thus has no *RST value.

Example

CALC:LIM:BURS:FERR:MAX:RES?

M a x i m u m f r e q u e n c y e r r o r l i m i t r e s u l t i s r e t u r n e d

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CALCulate:LIMit Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.685 E-11

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset[:AVERage]

This command sets the average IQ Offset error limit.

Parameter

numeric value in dB: –1000000 to 1000000

Example

CALC:LIM:BURS:IQOF –10.0

A v e r a g e I Q O f f s e t e r r o r l i m i t i s s e t t o – 1 0 . 0 d B

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset[:AVERage]:RESult?

This command returns the average IQ Offset error limit result.

Example

CALC:LIM:BURS:IQOF:RES?

Average IQ Offset error limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset:MAXimum

This command sets the maximum IQ Offset error limit.

Parameter

numeric value in dB: –1000000 to 1000000

Example

CALC:LIM:BURS:IQOF:MAX 15.0

M a x i m u m I Q O f f s e t e r r o r l i m i t i s s e t t o – 1 5 . 0 d B

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate:LIMit Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.686 E-11

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset:MAXimum:RESult?

This command returns the maximum IQ Offset error limit result.

Example

CALC:LIM:BURS:IQOF:MAX:RES?

Maximum IQ Offset error limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror[:AVERage]

This command sets the average symbol error limit.

Parameter

numeric value in Hertz

Example

CALC:LIM:BURS:SYMB 10000

The average symbol error limit is set to 10kHz

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror[:AVERage]:RESult?

This command returns the average symbol error limit result.

This command is a query only and thus has no *RST value.

Example

CALC:LIM:BURS:SYMB:RES?

Average symbol error limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CALCulate:LIMit Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.687 E-11

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror:MAXimum

This command sets the maximum symbol error limit.

Parameter

numeric value in Hertz

Example

CALC:LIM:BURS:SYMB:MAX?

Maximum symbol error limit is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror:MAXimum:RESult?

This command returns the maximum symbol error limit result.

This command is a query only and thus has no *RST value.

Example

CALC:LIM:BURS:SYMB:MAX:RES?

Maximum symbol error limit result is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:TFALl[:AVERage]

This command sets the average fall time limit.

Parameter

numeric value in seconds

Example

CALC:LIM:BURS:TFAL 0.000001

The average fall time limit is set to 1 µs

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate:LIMit Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.688 E-11

CALCulate<1|2>:LIMit<1>:BURSt:TFALl[:AVERage]:RESult?

This command returns the average fall time limit result.

This command is a query only and thus has no *RST value.

Example

CALC:LIM:BURS:TFALl:RES?

Average fall time limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:TFALl:MAXimum

This command sets the maximum fall time limit.

Parameter

numeric value in seconds

Example

CALC:LIM:BURS:TFALl:MAX 0.000001

The maximum fall time limit set to 1 µs.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:TFALl:MAXimum:RESult?

This command returns the maximum fall time limit result.

This command is a query only and thus has no *RST value.

Example

CALC:LIM:BURS:TRIS:MAX:RES?

Maximum fall time limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CALCulate:LIMit Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.689 E-11

CALCulate<1|2>:LIMit<1>:BURSt:TRISe[:AVERage]

This command sets the average rise time limit.

Parameter

numeric value in seconds

Example

CALC:LIM:BURS:TRIS 0.000001

The average rise time limit is set to 1 µs

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:TRISe[:AVERage]:RESult?

This command returns the average rise time limit result.

This command is a query only and thus has no *RST value.

Example

CALC:LIM:BURS:TRIS:RES?

The average rise time limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:BURSt:TRISe:MAXimum

This command sets the maximum rise time limit.

Parameter

numeric value in seconds

Example

CALC:LIM:BURS:TRIS:MAX 0.000001

Maximum rise time limit is set to 1 µs

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate:LIMit Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.690 E-11

CALCulate<1|2>:LIMit<1>:BURSt:TRISe:MAXimum:RESult?

This command returns the maximum rise time limit result.

This command is a query only and thus has no *RST value.

Example

CALC:LIM:BURS:TRIS:MAX:RES?

Maximum rise time limit result is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:SPECtrum:MASK:CHECk:X?

This command returns the X–value at the maximum overstepping of the spectrum mask limits.

This command is a query only and thus has no *RST value.

Example

CALC:LIM:SPEC:MASK:CHEC:X?

Returns the frequency at the maximum overstepping.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:LIMit<1>:SPECtrum:MASK:CHECk:Y?

This command returns the Y–value at the maximum overstepping of the spectrum mask limits.

This command is a query only and thus has no *RST value.

Example

CALC:LIM:SPEC:MASK:CHEC:Y?

Returns the power at the maximum overstepping.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CALCulate:MARKer Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.691 E-11

CALCulate:MARKer Subsystem (WLAN, K91 / K91n)

The CALCulate:MARKer subsystem checks the marker functions of the instrument.

The following subsystem is included:

•"CALCulate:MARKer:FUNCtion Subsystem (WLAN, K91 / K91n)" on page 6.696

Commands of the CALCulate:MARKer Subsystem

–CALCulate<1|2>:MARKer<1>[:STATe]

–CALCulate<1|2>:MARKer<1>:AOFF

–CALCulate<1|2>:MARKer<1>:BSYMbol

–CALCulate<1|2>:MARKer<1>:CARRier

–CALCulate<1|2>:MARKer<1>:MAXimum

–CALCulate<1|2>:MARKer<1>:MINimum

–CALCulate<1|2>:MARKer<1>:SYMBol

–CALCulate<1|2>:MARKer<1>:TRACe

–CALCulate<1|2>:MARKer<1>:X

–CALCulate<1|2>:MARKer<1>:Y

CALCulate<1|2>:MARKer<1>[:STATe]

This command switches the markers on or off.

Parameter

ON | OFF

Example

CALC1:MARK1:STATE ON

Switches the screen A marker ON.

CALC2:MARK1:STATE OFF

Switches the screen B marker OFF.

Characteristics

RST value: ON

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:MARKer<1>:AOFF

This command switches off all active markers in the specified measurement window. The

window is set by the numeric suffix of CALCulate<1|2>.

Example

CALC1:MARK:AOFF

Switches off all markers in the screen A window.

CALC2:MARK:AOFF

Switches off all markers in the screen B window.

CALCulate:MARKer Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.692 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:MARKer<1>:BSYMbol

This command positions the selected marker to the indicated symbol in the indicated burst. The

first numeric value is the burst number and the second numeric value is the symbol number.

This command only applies to 802.11b standard for the following result displays:

–Constellation vs Symbol

–EVM vs Symbol

This command is a query only and thus has no *RST value.

Parameter

<numeric_value>,<numeric_value>

Example

CALC:MARK1:BSYM 2,10

Positions marker 1 to symbol 10 of burst 2.

CALC:MARK1:BSYM?

Outputs the burst and symbol values of marker 1.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:MARKer<1>:CARRier

This command positions the selected marker to the indicated carrier.

This command is query only for the following result displays:

–Constellation vs Symbol

–Constellation vs Carrier

Parameter

<numeric_value>

Example

CALC:MARK:CARR –7

Positions marker 1 to carrier –7.

CALC:MARK:CARR?

Outputs the carrier value of marker 1.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CALCulate:MARKer Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.693 E-11

CALCulate<1|2>:MARKer<1>:MAXimum

This command sets the selected marker to the maximum peak value in the current trace. This

command is only available for the Spectrum Flatness result display.

This command is an event and therefore has no *RST value and no query.

Example

CALC2:MARK:MAX

Set marker 1 in screen B to maximum value in trace.

Characteristics

RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:MARKer<1>:MINimum

This command sets the selected marker to the minimum peak value in the current trace. This

command is only available for the Spectrum Flatnes result display.

This command is an event and therefore has no *RST value and no query.

Example

CALC2:MARK:MIN

Set marker 1 in screen B to minimum value in trace.

Characteristics

RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:MARKer<1>:SYMBol

This command positions the selected marker to the indicated symbol.

This command is query only for the following result displays:

–Constellation vs Symbol

–Constellation vs Carrier

Parameter

<numeric_value>

Example

CALC:MARK:SYMB 2

Positions marker 1 to symbol 2.

CALC:MARK:SYMB?

Outputs the symbol value of marker 1.

CALCulate:MARKer Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.694 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:MARKer<1>:TRACe

This command assigns the selected marker to the indicated measurement curve in the selected

measurement window.

This command is only available for the following result displays:

–Constellation versus Carrier

–EVM vs Symbol

–Frequency Error vs Preamble

–Phase Error vs Preamble

–PVT Full Burst

–PVT Rising / Falling

–Spectrum Flatness

–Spectrum Mask, if Max Hold trace is displayed

–Spectrum ACP/ACPR, if Max Hold trace is displayed

Example

"CALC2:MARK:TRAC 2

Assigns marker 1 in screen B to trace 2.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:MARKer<1>:X

This command positions the selected marker to the indicated inphase (Constellation vs

Symbol), frequency (Spectrum FFT, Spectrum Mask, Spectrum APCR), time (Magnitude

Capture Buffer, Auto level, PVT Full Burst, PVT Rising / Falling), power (CCDF), sub–carrier

(Constellation vs Carrier, EVM vs Carrier, Spectrum Flatness) or symbol (EVM vs Symbol) in

the selected measurement window.

This command is query only for the following result displays:

–Constellation vs Symbol

–Constellation vs Carrier

Parameter

<numeric_value> in Hz, s, dB

Example

CALC:MARK:X 2ms

Positions marker 1 to time 2ms.

R&S FSL CALCulate:MARKer Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.695 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:MARKer<1>:Y

This command positions the selected marker to the indicated quadrature (Constellation vs

Symbol), magnitude of I or Q (Constellation vs Carrier), EVM (EVM vs Carrier) or abs (Spectrum

Flatness) in the selected measurement window.

This command is query only for the following result displays:

–Auto Level

–Constellation vs Symbol

–Constellation vs Carrier

–EVM vs Symbol

–PVT Full

–PVT Rising / Falling

–Magnitude Capture Buffer

–Spectrum Mask

–Spectrum ACP/ACPR

–Spectrum FFT

–CCDF

Parameter

<numeric_value> in percent or dB

Example

CALC2:MARK:Y –2

Positions marker 1 in screen B to –2.

CALC:MARK:Y?

Outputs the measured value of marker 1.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate:MARKer Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.696 E-11

CALCulate:MARKer:FUNCtion Subsystem (WLAN, K91 / K91n)

The measurement window is selected by CALCulate 1 (screen A) or 2 (screen B).

Commands of the CALCulate:MARKer:FUNCtion Subsystem

–CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult[:CURRent]?

–CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult:MAXHold?

–CALCulate<1|2>:MARKer<1>:FUNCtion:ZOOM

CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult[:CURRent]?

This command queries the current result values of the adjacent channel power measurement.

An ACPR (Adjacent channel power relative) measurement must have previously been run, for

there to be summary data available.

Results are output separated by commas in the following order:

–Power of main channel

–Power of lower adjacent channel

–Power of upper adjacent channel

–Power of lower alternate adjacent channel 1

–Power of upper alternate adjacent channel 1

–Power of lower alternate adjacent channel 2

–Power of upper alternate adjacent channel 2

Adjacent channel power values are output in dB.

This command is a query only and thus has no *RST value.

Example

CALC:MARK:FUNC:POW:RES?

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult:MAXHold?

This command queries the maximum result values of the adjacent channel power

measurement. An ACPR (Adjacent channel power relative) measurement must have previously

been run with more than one sweep, for there to be maximum summary data available.

For details on the output refer to

"CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult[:CURRent]?" on page 6.696.

This command is a query only and thus has no *RST value.

Example

CALC:MARK:FUNC:POW:RES:MAXH?

R&S FSL CALCulate:MARKer Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.697 E-11

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CALCulate<1|2>:MARKer<1>:FUNCtion:ZOOM

This command sets the magnification factor for the zoom. It is only available for the following

result displays:

–Constellation vs Carrier

–Constellation vs Symbol

–PVT

–Magnitude Capture Buffer

Parameter

<numeric_value>

Example

INIT:CONT OFF

Switches to single sweep mode

CALC:MARK:FUNC:ZOOM 3;*WAI

Activates zooming and waits for its end.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.698 E-11

CONFigure Subsystem (WLAN, K91 / K91n)

The CONFigure subsystem contains commands for configuring complex measurement tasks. The

CONFigure subsystem is closely linked to the functions of the FETCH subsystem, where the

measurement results are queried.

Commands of the CONFigure Subsystem

–CONFigure:BURSt:CONSt:CARRier:SELect

–CONFigure:BURSt:CONSt:CCARrier[:IMMediate]

–CONFigure:BURSt:CONSt:CSYMbol[:IMMediate]

–CONFigure:BURSt:EVM:ECARrier[:IMMediate]

–CONFigure:BURSt:EVM:ESYMbol[:IMMediate]

–CONFigure:BURSt:PREamble[:IMMediate]

–CONFigure:BURSt:PREamble:SELect

–CONFigure:BURSt:PVT[:IMMediate]

–CONFigure:BURSt:PVT:AVERage

–CONFigure:BURSt:PVT:RPOWer

–CONFigure:BURSt:PVT:SELect

–CONFigure:BURSt:SPECtrum:ACPR[:IMMediate]

–CONFigure:BURSt:SPECtrum:FFT[:IMMediate]

–CONFigure:BURSt:SPECtrum:FLATness[:IMMediate]

–CONFigure:BURSt:SPECtrum:MASK[:IMMediate]

–CONFigure:BURSt:SPECtrum:MASK:SELect

–CONFigure:BURSt:STATistics:BSTReam[:IMMediate]

–CONFigure:BURSt:STATistics:CCDF[:IMMediate]

–CONFigure:BURSt:STATistics:SFIeld[:IMMediate]

–CONFigure:CHANnel

–CONFigure:POWer:AUTO

–CONFigure:POWer:AUTO:SWEep:TIME

–CONFigure:POWer:EXPected:RF

–CONFigure:STANdard

CONFigure:BURSt:CONSt:CARRier:SELect

This remote control command is only available when Constellation vs Symbol measurement is

selected. When the Constellation versus Symbol measurement is initiated, it will calculate the

results of the selected carrier.

Parameter

–26 to 26 | ALL | PILOTS

R&S FSL CONFigure Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.699 E-11

Example

CONF:BURS:CONS:CARR:SEL –26

Carrier –26 is selected.

CONF:BURS:CONS:CARR:SEL 10

Carrier 10 is selected.

CONF:BURS:CONS:CARR:SEL ALL

All carriers are selected.

CONF:BURS:CONS:CARR:SEL PIL

Pilots only.

Characteristics

*RST value: ALL

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:CONSt:CCARrier[:IMMediate]

This remote control command configures the measurement type to be Constellation vs Carrier.

After this command has been executed, the specified measurement will only be started when

the user issues the INITiate[:IMMediate] command.

Example

CONF:BURS:CONS:CCAR

Configures the Constellation versus Carrier measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:CONSt:CSYMbol[:IMMediate]

This remote control command configures the measurement type to be Constellation vs Symbol.

After this command has been executed, the specified measurement will only be started when

the user issues the INITiate[:IMMediate] command

Example

CONF:BURS:CONS:CSYM

Configures the Constellation versus Symbol measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.700 E-11

CONFigure:BURSt:EVM:ECARrier[:IMMediate]

This remote control command configures the measurement type to be EVM vs Carrier. After this

command has been executed, the specified measurement will only be started when the user

issues the INITiate[:IMMediate] command.

Example

CONF:BURS:EVM:ECAR

Configures the EVM vs Carrier measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:EVM:ESYMbol[:IMMediate]

This remote control command configures the measurement type to be EVM vs Symbol. After

this command has been executed, the specified measurement will only be started when the

user issues the INITiate[:IMMediate] command.

Example

CONF:BURS:EVM:ESYM

Configures the EVM vs Symbol measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:PREamble[:IMMediate]

This remote control command configures the measurement type to be Phase or Frequency vs

Preamble. After this command has been executed, the specified measurement will only be

started when the user issues the INITiate[:IMMediate] command.

Example

CONF:BURS:PRE

Configures the preamble measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CONFigure Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.701 E-11

CONFigure:BURSt:PREamble:SELect

This remote control command configures the interpretation of the preamble measurement

results.

Parameter

PHASe | FREQuency

Example

CONF:BURS:PRE:SEL PHAS

Configures the Phase vs Preamble measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:PVT[:IMMediate]

This remote control command configures the measurement type to be Power vs Time. After this

command has been executed, the specified measurement will only be started when the user

issues the INITiate[:IMMediate] command.

Example

CONF:BURS:PVT

Configures the Power vs Time measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:PVT:AVERage

This remote control command configures the measurement type to set the burst power

averaging length to the desired value. This command is only valid when the selected standard is

IEEE 802.11b.

Parameter

<numeric_value>

Example

CONF:BURS:PVT:AVER 31

Configures the burst power average length of 31.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.702 E-11

CONFigure:BURSt:PVT:RPOWer

This remote control command configures the use of either mean or maximum burst power as a

reference power for the 802.11b PVT measurement.

Parameter

MEAN | MAXimum

Example

CONF:BURS:PVT:RPOW MEAN

Configures to use mean burst power as a reference power.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:PVT:SELect

This remote control configures how to interpret the Power vs Time measurement results.

Parameter Description Wireless LAN standard

EDGE configures the measurement to be

rising and falling edge

all

FALL configures the measurement to be

falling edge only

IEEE 802.11b & g (CCK)

FULL configures the measurement to be full

burst

IEEE 802.11a, j & g, n (OFDM),

IEEE 802.11 Turbo Mode

RISE configures the measurement to be

rising edge only

IEEE 802.11b & g (CCK)

Example

CONF:BURS:PVT:SEL FULL

Interprets the measurement results as full burst

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CONFigure Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.703 E-11

CONFigure:BURSt:SPECtrum:ACPR[:IMMediate]

This remote control command configures the measurement type to be ACPR (adjacent channel

power relative) After this command has been executed, the specified measurement will only be

started when the user issues the INITiate[:IMMediate] command.

Example

CONF:BURS:SPEC:ACPR

Configures the ACPR measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:SPECtrum:FFT[:IMMediate]

This remote control command configures the measurement type to be FFT (Fast Fourier

Transform). After this command has been executed, the specified measurement will only be

started when the user issues the INITiate[:IMMediate] command.

Example

CONF:BURS:SPEC:FFT

Configures the FFT measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:SPECtrum:FLATness[:IMMediate]

This remote control command configures the measurement type to be Spectrum Flatness. After

this command has been executed, the specified measurement will only be started when the

user issues the INITiate[:IMMediate] command.

Example

CONF:BURS:SPEC:FLAT

Configures the Spectrum Flatness measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.704 E-11

CONFigure:BURSt:SPECtrum:MASK[:IMMediate]

This remote control command configures the measurement type to be Spectrum Mask. After

this command has been executed, the specified measurement will only be started when the

user issues the INITiate[:IMMediate] command

Example

CONF:BURS:SPEC:MASK

Configures the Spectrum Mask measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:SPECtrum:MASK:SELect

This remote control configures the interpretation of the Spectrum Mask measurement results.

This command is only available for IEEE 802.11a.

Parameter

IEEE | ETSI

Example

CONF:BURS:SPEC:MASK:SEL ETSI

Interprets the measurement results using the ETSI standard.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:STATistics:BSTReam[:IMMediate]

This remote control command configures the measurement type to be Bitstream. After this

command has been executed, the specified measurement will only be started when the user

issues the INITiate[:IMMediate] command.

Example

CONF:BURS:STAT:BSTR

Configures the Bitstream measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CONFigure Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.705 E-11

CONFigure:BURSt:STATistics:CCDF[:IMMediate]

This remote control command configures the measurement type to be CCDF (conditional

cumulative distribution functions.). After this command has been executed, the specified

measurement will only be started when the user issues the INITiate[:IMMediate]

command.

Example

CONF:BURS:STAT:CCDF

Configures the CCDF measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:BURSt:STATistics:SFIeld[:IMMediate]

This remote control command configures the measurement type to be Signal Field. After this

command has been executed, the specified measurement will only be started when the user

issues the INITiate[:IMMediate] command.

Example

CONF:BURS:STAT:SFIeld

Configures the Signal Field measurement type.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:CHANnel

This remote control command is used to specify the input channel for which measurements are

to be performed. This command will automatically cause the internal measurement frequency to

be re–calculated.

Parameter

<numeric_value>

Example

CONF:CHAN 9

Specifies channel 9 as frequency measurement.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

WLAN

CONFigure Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.706 E-11

CONFigure:POWer:AUTO

This remote control command is used to switch on or off automatic power level detection. When

switched on, power level detection is performed at the start of each measurement sweep.

Parameter

ONCE | ON | OFF

If this command is issued with the ONCE parameter then the auto level routine is performed

immediately one time.

Example

CONF:POW:AUTO ON

Configures the automatic detection of the input power level.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

CONFigure:POWer:AUTO:SWEep:TIME

This remote control command is used to specify the sweep time for the automatic power level

detection.

Parameter

numeric value in seconds

Example

CONF:POW:AUTO:SWE:TIME 200MS

Configures a 200 ms sweep time for the auto–level detection.

Characteristics

*RST value: 100ms

SCPI: device–specific

Mode

WLAN

CONFigure:POWer:EXPected:RF

This remote control command is used to specify the mean power level of the source signal as

supplied to the Analyzer RF input. This value will be overwritten if Auto Level is turned on.

Parameter

<numeric_value> in dBm

Example

CONF:POW:EXP:RF 9

Assumes an input signal strength of 9 dBm.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL CONFigure Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.707 E-11

CONFigure:STANdard

This remote control command specifies which Wireless LAN standard the option is configured to

measure.

Parameter

0IEEE 802.11a

1IEEE 802.11b

2IEEE 802.11j (10 MHz)

3IEEE 802.11j (20 MHz)

4IEEE 802.11g

5Turbo

6IEEE 802.11n

Example

CONF:STAN 0

Selects the IEEE 802.11a standard for the measurement.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

WLAN

CONFigure:WLAN:GTIMe:AUTO

This remote control command specifies wether the guard time of the IEEE 802.11n input signal

is automatically detected or specified manually.

Example

CCONF:WLAN:GTIM:AUTO ON

Sets automatic detection of the guard time of the input signal

Characteristics

*RST value: --

SCPI: device-specific

Mode

WLAN

CONFigure Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.708 E-11

CONFigure:WLAN:GTIMe:SELect

This remote control command specifies the guard time of the IEEE 802.11n input signal. If the

guard time is specified to be detected from the input signal using the

CONFigure:WLAN:GTIMe:AUTO command then this command is query only and allows the

detected guard time to be obtained.

Example

CCONF:WLAN:GTIM:SEL SHOR

Configures signal measurements with short guard times

Characteristics

*RST value: --

SCPI: device-specific

Mode

WLAN

R&S FSL DISPlay Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.709 E-11

DISPlay Subsystem (WLAN, K91 / K91n)

The DISPLay subsystem controls the selection and presentation of textual and graphic information as

well as of measurement data on the display. In contrast to the base unit, the WLAN TX Measurements

option supports the split screen modus.

Commands of the DISPlay Subsystem

–DISPlay:FORMat

–DISPlay[:WINDow<1|2>]:SSELect

–DISPlay[:WINDow<1|2>]:TABLe

–DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:AUTO

–DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:PDIVision

–DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel

–DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel:OFFSet

DISPlay:FORMat

This command sets the visible screen display type to full or split screen.

Parameter

SPLit | SINGle

Example

DISP:FORM SINGle

Sets the display to full screen.

Characteristics

*RST value: SPL

SCPI: device–specific

Mode

WLAN

DISPlay[:WINDow<1|2>]:SSELect

This command selects whether screen A or screen B is active. SSELect means Screen SELect.

Example

DISP:WIND1:SSEL

Sets the screen A active.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

WLAN

DISPlay Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.710 E-11

DISPlay[:WINDow<1|2>]:TABLe

This command selects whether the results table is displayed.

Parameter

ON | OFF

Example

DISP:WIND1:TABL ON

Hides the results table

Characteristics

*RST value: ON

SCPI: device–specific

Mode

WLAN

DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:AUTO

This command switches on or off automatic scaling of the Y–axis for the specified trace display.

Automatic scaling sets the Y–axis to automatically scale to best fit the measurement results.

This command is only available for the following result displays:

–EVM vs Carrier

–EVM vs Symbol.

–Frequency error vs Preamble

–Phase error vs Preamble

The numeric suffix at WINDow<1|2> must be 2 as the relevant results are always displayed in

screen B. The numeric suffix at TRACe<1...3> must be 1.

Parameter

ON | OFF

Example

DISP:WIND2:TRAC:Y:SCAL:AUTO ON

switches on automatic scaling of the Y–axis for the active trace

Characteristics

*RST value: ON

Mode

WLAN

DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:PDIVision

This command sets the size of each Y scale division for the specified trace display. Note that

this command has no affect if automatic scaling of the Y–axis is enabled. This command is only

available for the following result displays:

–EVM vs Carrier

–EVM vs Symbol.

–Frequency error vs Preamble

–Phase error vs Preamble

R&S FSL DISPlay Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.711 E-11

The numeric suffix at WINDow<1|2> must be 2 as the relevant results are always displayed in

screen B. The numeric suffix at TRACe<1...3> must be 1.

Parameter

<numeric_value>

Example

DISP:WIND2:TRAC:Y:SCAL:DPIV 2

Sets the Y scale division to size to 2.

Characteristics

*RST value: 3

Mode

WLAN

DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel

This remote control command can be used to set the current internal instrument reference level

used when performing measurements. The numeric suffix at WINDow<1|2> and TRACe<1...3>

are irrelevant.

Parameter

numeric value in dB

Example

DISP:TRAC:Y:RLEV?

returns the current reference level in use

Characteristics

*RST value: –

Mode

WLAN

DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel:OFFSet

For details refer to "DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel:OFFSet"on

page 6.135.

FETCh Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.712 E-11

FETCh Subsystem (WLAN, K91 / K91n)

The FETCh subsystem contains commands for reading out results of complex measurement tasks. This

subsystem is closely linked to the CONFigure and SENSe subsystems.

Commands of the DISPlay Subsystem

–FETCh:BURSt:ALL?

–FETCh:BURSt:COUNt?

–FETCh:BURSt:CRESt[:AVERage?]

–FETCh:BURSt:CRESt:MAXimum?

–FETCh:BURSt:CRESt:MINimum?

–FETCh:BURSt:EVM:[IEEE]:AVERage?

–FETCh:BURSt:EVM:[IEEE]:MAXimum?

–FETCh:BURSt:EVM:[IEEE]:MINimum?

–FETCh:BURSt:EVM:ALL:AVERage?

–FETCh:BURSt:EVM:ALL:MAXimum?

–FETCh:BURSt:EVM:ALL:MINimum?

–FETCh:BURSt:EVM:DATA:AVERage?

–FETCh:BURSt:EVM:DATA:MAXimum?

–FETCh:BURSt:EVM:DATA:MINimum?

–FETCh:BURSt:EVM:DIRect:AVERage?

–FETCh:BURSt:EVM:DIRect:MAXimum?

–FETCh:BURSt:EVM:DIRect:MINimum?

–FETCh:BURSt:EVM:PILot:AVERage?

–FETCh:BURSt:EVM:PILot:MAXimum?

–FETCh:BURSt:EVM:PILot:MINimum?

–FETCh:BURSt:FERRor:AVERage?

–FETCh:BURSt:FERRor:MAXimum?

–FETCh:BURSt:FERRor:MINimum?

–FETCh:BURSt:GIMBalance:AVERage?

–FETCh:BURSt:GIMBalance:MAXimum?

–FETCh:BURSt:GIMBalance:MINimum?

–FETCh:BURSt:IQOFfset:AVERage?

–FETCh:BURSt:IQOFfset:MAXimum?

–FETCh:BURSt:IQOFfset:MINimum?

–FETCh:BURSt:PAYLoad?

–FETCh:BURSt:PEAK?

–FETCh:BURSt:PREamble?

–FETCh:BURSt:QUADoffset:AVERage?

R&S FSL FETCh Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.713 E-11

–FETCh:BURSt:QUADoffset:MAXimum?

–FETCh:BURSt:QUADoffset:MINimum?

–FETCh:BURSt:RMS[:AVERage?]

–FETCh:BURSt:RMS:MAXimum?

–FETCh:BURSt:RMS:MINimum?

–FETCh:BURSt:SYMBolerror:AVERage?

–FETCh:BURSt:SYMBolerror:MAXimum?

–FETCh:BURSt:SYMBolerror:MINimum?

–FETCh:BURSt:TFALl:AVERage?

–FETCh:BURSt:TFALl:MAXimum?

–FETCh:BURSt:TFALl:MINimum?

–FETCh:BURSt:TRISe:AVERage?

–FETCh:BURSt:TRISe:MAXimum?

–FETCh:BURSt:TRISe:MINimum?

–FETCh:SYMBol:COUNt?

Further information

– ASCII formats for returned values

ASCII formats for returned values

The results are output as a list of result strings separated by commas.

Returned values for IEEE 802.11a, j, g(OFDM), n & Turbo Mode

<preamble power>,

<payload power>,

<min rms power>,<average rms power>,<max rms power>>,

<peak power>,

<min crest factor>,<average crest factor>,<max crest factor>,

<min frequency error>,<average frequency error>, <max frequency error>,

<min symbol error>, <average symbol error>, <max symbol error>,

<min IQ offset>, <average IQ offset>, <maximum IQ offset>,

<min gain imbalance>, <average gain imbalance>, <max gain imbalance>,

<min quadrature offset>, <average quadrature offset>, <max quadrature offset>,

<min EVM all bursts>, <average EVM all bursts>, <max EVM all bursts>,

FETCh Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.714 E-11

Returned values for IEEE 802.11b & g (CCK)

<min rise time>,<average rise time>,<max rise time>,

<min fall time>,<average fall time>,<max fall time>,

<min rms power>,<average rms power>,<max rms power>,

<min peak power>,<average peak power>,<max peak power>,

<min crest factor>,<average crest factor>,<max crest factor>,

<min frequency error>,<average frequency error>, <max frequency error>,

<min chip clock error>, <average chip clock error>, <max chip clock error>,

<min phase error>, <average phase error>, <max phase error>,

<min IQ offset>, <average IQ offset>, <maximum IQ offset>,

<min gain imbalance>, <average gain imbalance>, <max gain imbalance>,

<min quadrature offset>, <average quadrature offset>, <max quadrature offset>,

<min EVM IEEE>, <average EVM IEEE>, <max EVM IEEE>,

FETCh:BURSt:ALL?

This command returns all the results. The results are output as a list of result strings separated

by commas in ASCII format. For details on the format refer to "ASCII formats for returned

values" on page 6.713. The units for the EVM results are specified with the UNIT:EVM

command.

Example

FETC:BURS:ALL?

All calculated results are returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:COUNt?

This command returns the number of analyzed bursts.

This command is a query only and thus has no *RST value.

Example

FETC:BURS:COUN?

The analyzed number of bursts are returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL FETCh Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.715 E-11

FETCh:BURSt:CRESt[:AVERage?] / FETCh:BURSt:CRESt:MAXimum? /

FETCh:BURSt:CRESt:MINimum?

This command returns the average, minimum or maximum determined CREST factor (= ratio of

peak power to average power) in dB.]

This command is a query only and thus has no *RST value.

Example

FETC:BURS:CRES:MAX?

The maximum calculated crest factor from the most recent measurement is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:EVM:[IEEE]:AVERage? / FETCh:BURSt:EVM:[IEEE]:MAXimum? /

FETCh:BURSt:EVM:[IEEE]:MINimum?

This command returns the Error Vector Magnitude measurement results summary (average,

minimum or maximum value) in dB for the IEEE 802.11b standard. This result is the value

before filtering.???

This command is a query only and thus has no *RST value.

Example

FETC:BURS:EVM:MAX?

The maximum EVM recorded before filtering.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:EVM:ALL:AVERage? / FETCh:BURSt:EVM:ALL:MAXimum? /

FETCh:BURSt:EVM:ALL:MINimum?

This command returns the Error Vector Magnitude measurement results summary (average,

minimum or maximum value) in dB. This is a combined figure that represents the pilot, data and

the free carrier.

This command is a query only and thus has no *RST value.

Example

FETC:BURS:EVM:ALL:MAX?

The maximum EVM recorded for all measurement carrier is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.716 E-11

FETCh:BURSt:EVM:DATA:AVERage? / FETCh:BURSt:EVM:DATA:MAXimum? /

FETCh:BURSt:EVM:DATA:MINimum?

This command returns the Error Vector Magnitude measurement results summary for the data

carrier (average, minimum or maximum value) in dB.

This command is a query only and thus has no *RST value.

Example

FETC:BURS:EVM:DATA:MAX?

The maximum EVM recorded for the data carrier is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:EVM:DIRect:AVERage? / FETCh:BURSt:EVM:DIRect:MAXimum? /

FETCh:BURSt:EVM:DIRect:MINimum?

This command returns the Error Vector Magnitude measurement results summary (average,

minimum or maximum value) in dB for the IEEE 802.11b standard. This result is the value after

filtering.???

This command is a query only and thus has no *RST value.

Example

FETC:BURS:EVM:DIR:MAX?

The maximum EVM recorded after filtering.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:EVM:PILot:AVERage? / FETCh:BURSt:EVM:PILot:MAXimum? /

FETCh:BURSt:EVM:PILot:MINimum?

This command returns the Error Vector Magnitude measurement results summary for the EVM

pilot carrier (average, minimum or maximum value) in dB.???

This command is a query only and thus has no *RST value.

Example

FETC:BURS:EVM:PIL:MAX?

The maximum EVM recorded for the EVM pilot carrier is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL FETCh Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.717 E-11

FETCh:BURSt:FERRor:AVERage? / FETCh:BURSt:FERRor:MAXimum? /

FETCh:BURSt:FERRor:MINimum?

This command returns the measured average, minimum or maximum frequency errors in

Hertz.???

This command is a query only and thus has no *RST value.

Example

FETC:BURS:FERR:MAX?

The maximum frequency error from the most recent measurement is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:GIMBalance:AVERage? / FETCh:BURSt:GIMBalance:MAXimum? /

FETCh:BURSt:GIMBalance:MINimum?

This command returns the measured average, minimum or maximum IQ Imbalance errors in

dB.???

This command is a query only and thus has no *RST value.

Example

FETC:BURS:GIMB:MAX?

The maximum IQ Imbalance error from the most recent measurement is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:IQOFfset:AVERage? / FETCh:BURSt:IQOFfset:MAXimum? /

FETCh:BURSt:IQOFfset:MINimum?

This command returns the measured average, minimum or maximum IQ Offset errors in dB.???

This command is a query only and thus has no *RST value.

Example

FETC:BURS:IQOF:MAX?

The maximum IQ Offset error from the most recent measurement is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.718 E-11

FETCh:BURSt:PAYLoad?

This command returns the measured power in the payload of the burst.

This command is a query only and thus has no *RST value.

Example

FETC:BURS:PAYL?

The burst payload power is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:PEAK?

This command returns the Peak power in dBm measured during the measurement time.

Example

FETC:BURS:PEAK?

The calculated peak power from the most recent measurement is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:PREamble?

This command returns the measured power in the burst preamble.

This command is a query only and thus has no *RST value.

Example

FETC:BURS:PRE?

The burst preamble power is returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL FETCh Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.719 E-11

FETCh:BURSt:QUADoffset:AVERage? / FETCh:BURSt:QUADoffset:MAXimum? /

FETCh:BURSt:QUADoffset:MINimum?

This command returns the accuracy in terms of the phase error of symbols within a burst.???

This command is a query only and thus has no *RST value.

Example

FETC:BURS:QUAD:MAX?

The maximum angle error recorded for a symbol during the measurement.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:RMS[:AVERage?] / FETCh:BURSt:RMS:MAXimum? /

FETCh:BURSt:RMS:MINimum?

This command returns the average, minimum or maximum RMS burst power in dBm measured

during the measurement.]

This command is a query only and thus has no *RST value.

Example

FETC:BURS:RMS:MAX?

The maximum calculated RSM burst power from the most recent measurement is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:SYMBolerror:AVERage? / FETCh:BURSt:SYMBolerror:MAXimum? /

FETCh:BURSt:SYMBolerror:MINimum?

This command returns the percentage of symbols that were outside permissible de–modulation

range within a burst.???

Example

FETC:BURS:SYMB:MAX?

The maximum number of symbols that were out of range per burst.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.720 E-11

FETCh:BURSt:TFALl:AVERage? / FETCh:BURSt:TFALl:MAXimum? /

FETCh:BURSt:TFALl:MINimum?

This command returns the average, minimum or maximum burst fall time in seconds.

This command is a query only and thus has no *RST value.

Example

FETC:BURS:TFAL:MAX?

The maximum calculated fall time from the most recent measurement is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:BURSt:TRISe:AVERage? / FETCh:BURSt:TRISe:MAXimum? /

FETCh:BURSt:TRISe:MINimum?

This command returns the average, minimum or maximum burst rise time in seconds.

This command is a query only and thus has no *RST value.

Example

FETC:BURS:TRIS:MAX?

The maximum calculated rise time from the most recent measurement is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

FETCh:SYMBol:COUNt?

This command returns the number of symbols for each analyzed burst as a comma separated

list.

This command is a query only and thus has no *RST value.

Example

FETC:SYMB:COUN?

The analyzed number of symbols for each burst are returned

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL FORMat Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.721 E-11

FORMat Subsystem (WLAN, K91 / K91n)

The FORMat subsystem specifies the data format of the data transmitted from and to the instrument.

Commands of the FORMat Subsystem

–FORMat[:DATA]

FORMat[:DATA]

For details refer to the FORMat[:DATA] command description of the base unit on page 6.138.

INITiate Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.722 E-11

INITiate Subsystem (WLAN, K91 / K91n)

The INITiate subsystem configures the instrument prior to a measurement being carried out. It is

basically used to tell the instrument which measurement is to be performed and takes any necessary

step to set up the instrument for the measurement.

Commands of the INITiate Subsystem

–INITiate[:IMMediate]

–INITiate:CONTinuous

INITiate[:IMMediate]

For details refer to "INITiate<1|2>[:IMMediate]" on page 6.146.

INITiate:CONTinuous

For details refer to "INITiate<1|2>:CONTinuous" on page 6.147.

R&S FSL INPut Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.723 E-11

INPut Subsystem (WLAN, K91 / K91n)

The INPut subsystem controls the input characteristics of the RF inputs of the instrument.

Commands of the INPut Subsystem

–INPut<1|2>:ATTenuation

INPut:ATTenuation

For details refer to "INPut<1|2>:ATTenuation" on page 6.150.

INSTrument Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.724 E-11

INSTrument Subsystem (WLAN, K91 / K91n)

The INSTrument subsystem selects the operating mode of the unit either via text parameters or fixed

numbers.

Commands of the INSTrument Subsystem

–INSTrument[:SELect]

–INSTrument:NSELect

INSTrument[:SELect]

Parameter

WLAN (WLAN TX Measurements option, R&S FSL–K91)

For further details refer to the INSTrument subsystem of the base unit.

INSTrument:NSELect

Parameter

16 (WLAN TX Measurements option, R&S FSL–K91)

For further details refer to the INSTrument subsystem of the base unit.

R&S FSL MMEMory Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.725 E-11

MMEMory Subsystem (WLAN, K91 / K91n)

The MMEMory (mass memory) subsystem provides commands to store and load IQ data.

Commands of the MMEMory Subsystem

–MMEMory:LOAD:IQ:STATe

–MMEMory:STORe:IQ:STATe

MMEMory:LOAD:IQ:STATe

This command loads the IQ data from the specified .iqw file.

Parameter

1,<file_name>

Example

MMEM:LOAD:IQ:STAT 1,'C:\R_S\Instr\user\data.iqw'

Loads IQ data from the specified file.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

MMEMory:STORe:IQ:STATe

This command stores the IQ data to the specified .iqw file.

Parameter

1,<file_name>

Example

MMEM:STOR:IQ:STAT 1,'C:\R_S\Instr\user\data.iqw'

Stores IQ data to the specified file.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

SENSe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.726 E-11

SENSe Subsystem (WLAN, K91 / K91n)

The SENSe command is used to set and get the values of parameters in the remote instrument.

The get variant of the SENSe command differs from set in that it takes no parameter values

(unless otherwise stated) but is followed by the character '?' and will return the parameter's

value in the same format as it is set.

Commands of the SENSe Subsystem

–[SENSe:]BURSt:COUNt

–[SENSe:]BURSt:COUNt:STATe

–[SENSe:]DEMod:BANalyze:DURation:EQUal

–[SENSe:]DEMod:BANalyze:DURation:MAX

–[SENSe:]DEMod:BANalyze:DURation:MIN

–[SENSe:]DEMod:CESTimation

–[SENSe:]DEMod:FILTer:CATalog?

–[SENSe:]DEMod:FILTer:MODulation

–[SENSe:]DEMod:FORMat[:BCONtent]:AUTo

–[SENSe:]DEMod:FORMat:BANalyze

–[SENSe:]DEMod:FORMat:BANalyze:BTYPe

–[SENSe:]DEMod:FORMat:BANalyze:DBYTes:EQUal

–[SENSe:]DEMod:FORMat:BANalyze:DBYTes:MAX

–[SENSe:]DEMod:FORMat:BANalyze:DBYTes:MIN

–[SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal

–[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MAX

–[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MIN

–[SENSe:]DEMod:FORMat:BTRate

–[SENSe:]DEMod:FORMat:SIGSymbol

–[SENSe:]FREQuency:CENTer

–[SENSe:]POWer:ACHannel:MODE

–[SENSe:]SWAPiq

–[SENSe:]SWEep:COUNt

–[SENSe:]SWEep:EGATe

–[SENSe:]SWEep:EGATe:HOLDoff[:TIME]

–[SENSe:]SWEep:EGATe:HOLDoff:SAMPle

–[SENSe:]SWEep:EGATe:LENGth[:TIME]

–[SENSe:]SWEep:EGATe:LENGth:SAMPle

–[SENSe:]SWEep:EGATe:LINK

–[SENSe:]SWEep:TIME

–[SENSe:]TRACking:LEVel

–[SENSe:]TRACking:PHASe

R&S FSL SENSe Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.727 E-11

–[SENSe:]TRACking:TIME

Further information

–Analysis modulation format

Analysis modulation format

Parameter Standard Description

BPSK Alias for BI Phase shift keying at higher data rate for

selected standard

BPSK3 IEEE 802.11j (10 MHz) BI Phase shift keying at 3 Mbps

BPSK6 IEEE 802.11a, g (OFDM), j (20 MHz) & Turbo BI Phase shift keying at 6 Mbps

BPSK9 IEEE 802.11a, g (OFDM), j (20 MHz) & Turbo BI Phase shift keying at 9 Mbps

BPSK45 IEEE 802.11j (10 MHz) BI Phase shift keying at 6 Mbps

BPSK65 IEEE 802.11n BI Phase shift keying at 6.5 Mbps

BPSK72 IEEE 802.11n BI Phase shift keying at 7.2 Mbps

CCK11 IEEE 802.11b & g (Single Carrier) Complimentary Code Keying at 11 Mbps

CCK55 IEEE 802.11b & g (Single Carrier) Complimentary Code Keying at 5.5 Mbps

DBPSK IEEE 802.11b & g (Single Carrier) Differential BI Phase shift keying

DQPSK IEEE 802.11b & g (Single Carrier) Differential Quadrature phase shift keying

PBCC11 IEEE 802.11b & g (Single Carrier) PBCC at 11 Mbps

PBCC22 IEEE 802.11g (Single Carrier) PBCC at 11 Mbps

PBCC55 IEEE 802.11b & g (Single Carrier) PBCC at 5.5 Mbps

QAM16 Alias for Quadrature Amplitude Modulation at higher

data rate for selected standard

QAM64 Alias for Quadrature Amplitude Modulation at higher

data rate for selected standard

QAM1612 IEEE 802.11j (10 MHz) Quadrature Amplitude Modulation at 12 Mbps

QAM1618 IEEE 802.11j (10 MHz) Quadrature Amplitude Modulation at 18 Mbps

QAM1624 IEEE 802.11a, g (OFDM), j (20 MHz) & Turbo Quadrature Amplitude Modulation at 24 Mbps

QAM1626 IEEE 802.11n Quadrature Amplitude Modulation at 26 Mbps

QAM1636 IEEE 802.11a, g (OFDM), j (20 MHz) & Turbo Quadrature Amplitude Modulation at 36 Mbps

QAM1639 IEEE 802.11n Quadrature Amplitude Modulation at 39 Mbps

QAM6424 IEEE 802.11j (10 MHz) Quadrature Amplitude Modulation at 24 Mbps

QAM6427 IEEE 802.11j (10 MHz) Quadrature Amplitude Modulation at 27 Mbps

QAM6448 IEEE 802.11a, g (OFDM), j (20 MHz) & Turbo Quadrature Amplitude Modulation at 48 Mbps

QAM6452 IEEE 802.11n Quadrature Amplitude Modulation at 52 Mbps

QAM6454 IEEE 802.11a, g (OFDM), j (20 MHz) & Turbo Quadrature Amplitude Modulation at 54 Mbps

QAM6465 IEEE 802.11n Quadrature Amplitude Modulation at 65 Mbps

QAM16289 IEEE 802.11n Quadrature Amplitude Modulation at 28.9 Mbps

QAM16433 IEEE 802.11n Quadrature Amplitude Modulation at 43.3 Mbps

QAM64578 IEEE 802.11n Quadrature Amplitude Modulation at 57.8 Mbps

QAM64585 IEEE 802.11n Quadrature Amplitude Modulation at 58.5 Mbps

QAM64722 IEEE 802.11n Quadrature Amplitude Modulation at 72.2 Mbps

QPSK Alias for Quadrature phase shift keying at higher data

rate for selected standard

SENSe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.728 E-11

Parameter Standard Description

QPSK12 IEEE 802.11a, g (OFDM), j (20 MHz) & Turbo Quadrature phase shift keying at 12 Mbps

QPSK13 IEEE 802.11n Quadrature phase shift keying at 13 Mbps

QPSK18 IEEE 802.11a, g (OFDM), j (20 MHz) & Turbo Quadrature phase shift keying at 18 Mbps

QPSK6 IEEE 802.11j (10 MHz) Quadrature phase shift keying at 6 Mbps

QPSK9 IEEE 802.11j (10 MHz) Quadrature phase shift keying at 9 Mbps

QPSK144 IEEE 802.11n Quadrature phase shift keying at 14.4 Mbps

QPSK195 IEEE 802.11n Quadrature phase shift keying at 19.5 Mbps

QPSK217 IEEE 802.11n Quadrature phase shift keying at 21.7 Mbps

[SENSe:]BURSt:COUNt

This command defines the number of bursts that will be analyzed by the measurement. This

parameter is ignored if the setting for the [SENSe:]BURSt:COUNt:STATe parameter is off.

Parameter

<numeric_value>

Example

BURS:COUN 16

Sets the number of bursts to 16.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

WLAN

[SENSe:]BURSt:COUNt:STATe

When this command is set to on, the burst count parameter will be used by the measurement,

otherwise the burst count parameter will be ignored.

Parameter

ON | OFF

Example

BURS:COUN:STAT ON

Sets the burst count state to ON

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

WLAN

R&S FSL SENSe Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.729 E-11

[SENSe:]DEMod:BANalyze:DURation:EQUal

When this command is set to ON then only bursts of equal length will take part in the PVT

analysis. When this command is set to true the value specified by the

[SENSe:]DEMod:BANalyze:DURation:MIN command specifies the duration that a burst

must last in order to take part in measurement analysis.

Parameter

ON | OFF

Example

DEM:BAN:DUR:EQU ON

Only bursts of equal length will take part in the measurement analysis.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:BANalyze:DURation:MAX

This command specifies the maximum duration in microseconds required for bursts to qualify for

measurement analysis. Only bursts with the specified duration will be used in the measurement

analysis.

This value will not have any immediate effect if the

[SENSe:]DEMod:BANalyze:DURation:EQUal command has been set to true as in this

case no range of durations is allowed and only bursts with exactly the duration specified by the

[SENSe:]DEMod:BANalyze:DURation:MIN command shall take part in measurement

analysis

Parameter

<numeric_value>

Example

DEM:BAN:DUR:MAX 1300

Only bursts which have a maximum duration of 1300 microseconds are analyzed.

Characteristics

*RST value: 5464

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:BANalyze:DURation:MIN

This command specifies the duration in microseconds required for bursts to qualify for

measurement analysis. Only bursts with the specified duration will be used in the measurement

analysis. When the [SENSe:]DEMod:BANalyze:DURation:EQUal command has been set

to true then this command specifies the exact duration required for a burst to take part in

measurement analysis. When the [SENSe:]DEMod:FORMat:BANalyze:DBYTes:EQUal

command is set to false this command specifies the minimum duration required for a burst to

take part in measurement analysis.

SENSe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.730 E-11

Parameter

<numeric_value>

Example

DEM:BAN:DUR:MIN 45

Only bursts which last 48 microseconds are analyzed.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:CESTimation

This command defines whether channel estimation will be done in preamble and payload (if set

to 1) or only in preamble (if set to 0). The effect of this is most noticeable for the EVM

measurement results, where the results will be improved when this feature is enabled.

However, this functionality is not supported by the IEEE 802.11 standard and must be disabled

if the results are to be strictly measured against the standard.

Parameter

ON | OFF

Example

DEMod:CEST ON

Specifies that the IQ measurement results will use channel estimation in preamble & payload.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:FILTer:CATalog?

This command reads the names of all available filters. The file names are output without file

extension. Syntax of output format: filter_1,filter_2, … ,filter_n.

This command is a query only and thus has no *RST value.

Example

DEM:FILT:CAT?

Reads all filter names

Characteristics

*RST value: 0

SCPI: device–specific

Mode

WLAN

R&S FSL SENSe Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.731 E-11

[SENSe:]DEMod:FILTer:MODulation

This command selects the TX and RX filters. The names of the filters correspond to the file

names; a query of all available filters is possible by means of the

[SENSe:]DEMod:FILTer:CATalog? command.

Parameter

DEF_TX: default transmit filter, DEF_RX: default receive filter

Example

DEM:FILT:MOD 'DEF_TX','DEF_RX'

DEF_TX is selected for the TX filter and DEF_RX for the RX filter

Characteristics

*RST value: AUTO,AUTO

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:FORMat[:BCONtent]:AUTo

When this command is set to ON then the signal symbol field of the burst is analyzed to

determine the modulation scheme of the first burst. When this field is set to ON only bursts

which match the modulation scheme are considered in results analysis.

Parameter

ON | OFF

Example

DEM:FORM:AUT ON

Specifies that the signal symbol field should be decoded.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:FORMat:BANalyze

The remote control command sets the analysis modulation format that will be assumed when

the measurement is performed. If the [SENSe:]DEMod:FORMat:SIGSymbol parameter has

been set to ON, this command can be used to measure only certain burst types within a

measurement sequence.

Parameter

For details refer to "Analysis modulation format" on page 6.727.

Example

DEM:FORM:BAN 'QAM16'

Only bursts that are of the QAM16 modulation format are analyzed.

SENSe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.732 E-11

Characteristics

*RST value: QAM64

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:FORMat:BANalyze:BTYPe

This remote control command specifies the type of burst to be analyzed. Only bursts of the

specified type take part in measurement analysis.

Parameter

DIRECT IEEE 802.11a, IEEE 802.11j (10MHz), IEEE 802.11j (20MHz),

IEEE 802.11g, 802.11 OFDM Turbo – Direct Link Burst

LONG–OFDM IEEE 802.11g – Long DSSS OFDM

SHORT–OFDM IEEE 802.11g – Short DSSS OFDM

LONG IEEE 802.11b, IEEE 802.11g – Long PLCP Burst

SHORT IEEE 802.11b, IEEE 802.11g – Short PLCP Burst

MM20 IEEE 802.11n Mixed Mode 20 MHz sampling rate

GFM20 IEEE 802.11n Greenfield Mode 20 MHz sampling rate

Example

DEM:FORM:BAN:BTYPe 'DIRECT'

Only DIRECT bursts are analyzed.

Characteristics

*RST value: DIRECT

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:FORMat:BANalyze:DBYTes:EQUal

When this command is set to ON then only bursts of equal length will take part in the

measurement analysis. The number of data bytes that a burst must have in order to take part in

measurement analysis is specified by the [SENSe:]DEMod:FORMat:BANalyze:DBYTes:MIN

command.

Parameter

ON | OFF

Example

DEM:FORM:BAN:DBYTes:EQU ON

Only bursts of equal length will take part in the measurement analysis.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

WLAN

R&S FSL SENSe Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.733 E-11

[SENSe:]DEMod:FORMat:BANalyze:DBYTes:MAX

This command specifies the maximum number of data bytes required for bursts to qualify for

measurement analysis. Only bursts with the specified number of data bytes will be used in the

measurement analysis.

This value will not have any immediate effect if the

[SENSe:]DEMod:FORMat:BANalyze:DBYTes:EQUal command has been set to ON. In this

case, no range of symbols is allowed and only bursts with exactly the number of data bytes

specified by the [SENSe:]DEMod:FORMat:BANalyze:DBYTes:MIN command shall take part

in measurement analysis.

Parameter

<numeric_value>

Example

DEM:FORM:BAN:DBYTes:MAX 1300

Only bursts which contain a maximum of 1300 data bytes are analyzed.

Characteristics

*RST value: 64

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:FORMat:BANalyze:DBYTes:MIN

This command specifies the number of data bytes required for bursts to qualify for

measurement analysis. Only bursts with the specified number of data bytes will be used in the

measurement analysis.

If the [SENSe:]DEMod:FORMat:BANalyze:DBYTes:EQUal command has been set to ON,

this command specifies the exact number of data bytes required for a burst to take part in

measurement analysis. If the [SENSe:]DEMod:FORMat:BANalyze:DBYTes:EQUal

command is set to OFF, this command specifies the minimum number of data bytes required for

aburst to take part in measurement analysis.

Parameter

<numeric_value>

Example

DEM:FORM:BAN:DBYTes:MIN 16

Only bursts which contain 16 data bytes are analyzed.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

WLAN

SENSe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.734 E-11

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal

When this command is activated then only bursts of equal length will take part in the

measurement analysis. When this command is set to true the value specified by the

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MIN command specifies the number of

symbols that a burst must have in order to take part in analysis.

Parameter

ON | OFF

Example

DEM:FORM:BAN:SYM:EQU ON

Only bursts of equal length will take part in analysis.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MAX

This command specifies the maximum number of data symbols required for bursts to qualify for

measurement analysis. Only bursts with the specified number of symbols will be used in the

measurement analysis. The number of data symbols is defined as the uncoded bits including

service and tail bits.

This value will not have any immediate effect if the

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal command has been set to true as in

this case no range of symbols is allowed and only bursts with exactly the number of symbols

specified by the [SENSe:]DEMod:FORMat:BANalyze:SYMBols:MIN command shall take

place in measurement analysis.

Parameter

<numeric_value>

Example

DEM:FORM:BAN:SYM:MAX 1300

Only bursts which contain a maximum symbol count of 1300 are analyzed.

Characteristics

*RST value: 64

SCPI: device–specific

Mode

WLAN

R&S FSL SENSe Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.735 E-11

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MIN

This command specifies the number of data symbols required for bursts to qualify for

measurement analysis. Only bursts with the specified number of symbols will be used in the

measurement analysis. The number of data symbols is defined as the uncoded bits including

service and tail bits.

When the [SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal command has been set to

true then this command specifies the exact number of symbols required for a burst to take part

in measurement analysis. When the [SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal

command is set to false this command specifies the minimum number of symbols required for a

burst to take part in measurement analysis.

Parameter

<numeric_value>

Example

DEM:FORM:BAN:SYM:MIN 16

Only bursts which contain a symbol count of 16 are analyzed.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

WLAN

[SENSe:]DEMod:FORMat:BTRate

The remote control command is used to specify the bit rate for IEEE 802.11b signals. This

command can be used as an alternative to [SENSe:]DEMod:FORMat:BANalyze.The bit rate

can be set as follows:

Parameter

10 1 Mbit/s

20 2 Mbit/s

55 5.5 Mbit/s

110 11 Mbit/s

Example

DEM:FORM:BTR 20

Configures to demodulate 2 Mbit/s signals

Characteristics

*RST value: 10 (= 1mbit)

SCPI: device–specific

Mode

WLAN

SENSe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.736 E-11

[SENSe:]DEMod:FORMat:SIGSymbol

If this command is set to ON, the signal symbol field of the burst is analyzed to determine the

details of the burst. Only burst which match the supplied burst type and modulation are

considered in results analysis. For IEEE 802.11b this command can only be queried as the

decoding of the signal field is always performed for the IEEE 802.11b standard.

Parameter

ON | OFF

Example

DEM:FORM:SIGS ON

Specifies that the signal symbol field should be decoded.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

[SENSe:]FREQuency:CENTer

For details refer to "[SENSe<1|2>:]FREQuency:CENTer" on page 6.200.

[SENSe:]POWer:ACHannel:MODE

This command sets the ACP measurement mode for the IEEE 802.11j standard to either

absolute or relative.

Parameter

ABS Absolute measurement

REL Relative measurement

Example

POW:ACH:MODE ABS

Sets the ACP measurement to absolute mode

Characteristics

*RST value: REL

SCPI: device–specific

Mode

WLAN

R&S FSL SENSe Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.737 E-11

[SENSe:]SWAPiq

This command defines whether or not the recorded IQ pairs should be swapped (I<–>Q) before

being processed.

Parameter

ON | OFF

Example

SWAP ON

Specifies that IQ values should be swapped.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

WLAN

[SENSe:]SWEep:COUNt

This command specifies the number of sweeps for Spectrum Mask and Spectrum ACPR

measurements.

Parameter

<numeric_value>

Example

SWEep:COUNt 64

Sets the number of sweeps to 64.

Characteristics

*RST value: 1

SCPI: conform

Mode

WLAN

[SENSe:]SWEep:EGATe

For details refer to "[SENSe<1|2>:]SWEep:EGATe" on page 6.230.

[SENSe:]SWEep:EGATe:HOLDoff[:TIME]

This command defines the gate delay in the capture buffer in time units. The range of this value

is dependent on the last run measurement.

Parameter

<numeric_value>

Example

SWE:EGAT:HOLD 125us

Sets a delay of 125µsin the capture buffer.

SENSe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.738 E-11

Characteristics

*RST value: 100µs

SCPI: device–specific

Mode

WLAN

[SENSe:]SWEep:EGATe:HOLDoff:SAMPle

This command defines the gate delay in the capture buffer as a number of samples. The range

of this value is dependent on the last run measurement.

Parameter

<numeric_value>

Example

SWE:EGAT:HOLD:SAMP 2500

Sets a delay of 2500 samples in the capture buffer.

Characteristics

*RST value: 2000

SCPI: device–specific

Mode

WLAN

[SENSe:]SWEep:EGATe:LENGth[:TIME]

This command defines the gate time in the capture buffer in time units. The range of this value

is dependent on the last run measurement.

Parameter

<numeric_value>

Example

SWE:EGAT:LENG 20ms

Sets a gate length of 20 milliseconds between sweeps.

Characteristics

*RST value: 400µs

SCPI: device–specific

Mode

WLAN

[SENSe:]SWEep:EGATe:LENGth:SAMPle

This command defines the gate time in the capture buffer as a number of samples. The range of

this value is dependent on the last run measurement.

Parameter

<numeric_value>

Example

SWE:EGAT:LENG:SAMP 200000

Sets a gate length of 200000 samples in the capture buffer.

R&S FSL SENSe Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.739 E-11

Characteristics

*RST value: 8000

SCPI: device–specific

Mode

WLAN

[SENSe:]SWEep:EGATe:LINK

This command links together the movement of the gating lines and the capture buffer marker.

Parameter

ON | OFF

Example

SWE:EGAT:LINK ON

Links the gating lines as marker with the gating line delay and length are changed gate position.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

WLAN

[SENSe:]SWEep:TIME

The RST value for the WLAN TX Measurements option (K91 / K91n) is 1 ms.

For further details refer to "[SENSe<1|2>:]SWEep:TIME"on page 6.234.

[SENSe:]TRACking:LEVel

This command defines whether or not the measurement results should be compensated for

level.

Parameter

ON | OFF

Example

TRAC:LEV ON

Specifies that the measurement results should be compensated for level.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

WLAN

SENSe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.740 E-11

[SENSe:]TRACking:PHASe

This command defines whether or not the measurement results should be compensated for

phase.

Parameter

ON | OFF

Example

TRAC:PHAS ON

Specifies that the measurement results should be compensated for phase.

Characteristics

*RST value: ON

SCPI: device–specific

Mode

WLAN

[SENSe:]TRACking:TIME

This command defines whether or not the measurement results should be compensated for

time.

Parameter

ON | OFF

Example

TRAC:TIME ON

Specifies that the measurement results should be compensated for time.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

WLAN

R&S FSL STATus Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.741 E-11

STATus Subsystem (WLAN, K91 / K91n)

The STATus subsystem contains the commands for the status reporting system (for details refer to

chapter 5 "Remote Control – Basics"). For the STATus:QUEStionable:LIMit register, the measurement

window is selected by LIMit 1 (screen A) or 2 (screen B). *RST does not influence the status registers.

Commands of the STATus Subsystem

–STATus:QUEStionable:ACPLimit[:EVENt]?

–STATus:QUEStionable:ACPLimit:CONDition?

–STATus:QUEStionable:ACPLimit:ENABle

–STATus:QUEStionable:ACPLimit:PTRansition

–STATus:QUEStionable:ACPLimit:NTRansition

–STATus:QUEStionable:LIMit<1|2> [:EVENt]?

–STATus:QUEStionable:LIMit<1|2>:CONDition?

–STATus:QUEStionable:LIMit<1|2>:ENABle

–STATus:QUEStionable:LIMit<1|2>:PTRansition

–STATus:QUEStionable:LIMit<1|2>:NTRansition

–STATus:QUEStionable:POWer[:EVENt]?

–STATus:QUEStionable:POWer:CONDition?

–STATus:QUEStionable:POWer:ENABle

–STATus:QUEStionable:POWer:PTRansition

–STATus:QUEStionable:POWer:NTRansition

–STATus:QUEStionable:SYNC[:EVENt]?

–STATus:QUEStionable:SYNC:CONDition?

–STATus:QUEStionable:SYNC:ENABle

–STATus:QUEStionable:SYNC:PTRansition

–STATus:QUEStionable:SYNC:NTRansition

STATus:QUEStionable:ACPLimit[:EVENt]?

For details refer to "STATus:QUEStionable:ACPLimit[:EVENt]?" on page 6.242.

STATus:QUEStionable:ACPLimit:CONDition?

For details refer to "STATus:QUEStionable:ACPLimit:CONDition?"on page 6.242.

STATus:QUEStionable:ACPLimit:ENABle

For details refer to "STATus:QUEStionable:ACPLimit:ENABle"on page 6.243.

STATus Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.742 E-11

STATus:QUEStionable:ACPLimit:PTRansition

For details refer to "STATus:QUEStionable:LIMit<1|2>:PTRansition" on page 6.247.

STATus:QUEStionable:ACPLimit:NTRansition

For details refer to "STATus:QUEStionable:ACPLimit:NTRansition" on page 6.243.

STATus:QUEStionable:LIMit<1|2> [:EVENt]?

For details refer to "STATus:QUEStionable:LIMit<1|2>[:EVENt]?" on page 6.245.

STATus:QUEStionable:LIMit<1|2>:CONDition?

For details refer to "STATus:QUEStionable:LIMit<1|2>:CONDition?"on page 6.246.

STATus:QUEStionable:LIMit<1|2>:ENABle

For details refer to "STATus:QUEStionable:LIMit<1|2>:ENABle" on page 6.246.

STATus:QUEStionable:LIMit<1|2>:PTRansition

For details refer to "STATus:QUEStionable:LIMit<1|2>:PTRansition" on page 6.247.

STATus:QUEStionable:LIMit<1|2>:NTRansition

For details refer to "STATus:QUEStionable:LIMit<1|2>:NTRansition"on page 6.246.

STATus:QUEStionable:POWer[:EVENt]?

For details refer to "STATus:QUEStionable:POWer[:EVENt]?" on page 6.249.

STATus:QUEStionable:POWer:CONDition?

For details refer to "STATus:QUEStionable:POWer:CONDition?" on page 6.249.

STATus:QUEStionable:POWer:ENABle

For details refer to "STATus:QUEStionable:POWer:ENABle" on page 6.249.

STATus:QUEStionable:POWer:PTRansition

For details refer to "STATus:QUEStionable:POWer:PTRansition" on page 6.250.

R&S FSL STATus Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.743 E-11

STATus:QUEStionable:POWer:NTRansition

For details refer to "STATus:QUEStionable:POWer:NTRansition" on page 6.250.

STATus:QUEStionable:SYNC[:EVENt]?

This command queries the contents of the EVENt section of the STATus:QUEStionable:SYNC

Example

STAT:QUES:SYNC?

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

STATus:QUEStionable:SYNC:CONDition?

This command queries the contents of the CONDition section of the

STATus:QUEStionable:SYNC register. Readout does not delete the contents of the CONDition

section.

Example

STAT:QUES:SYNC:COND?

Characteristics

*RST value: –

SCPI: conform

Mode

WLAN

STATus:QUEStionable:SYNC:ENABle

This command sets the bits of the ENABle section of the STATus:QUEStionable:SYNC register.

The ENABle register selectively enables the individual events of the associated EVENt section

for the summary bit.

Parameter

0to 65535

Example

STAT:QUES:SYNC:ENAB 65535

All events bits will be represented in the SYNC summary bit.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

STATus Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.744 E-11

STATus:QUEStionable:SYNC:PTRansition

This command determines what bits in the STATus:QUEStionable:SYNC Condition register will

set the corresponding bit in the STATus:QUEStionable:SYNC Event register when that bit has a

positive transition (0 to 1). The variable <number> is the sum of the decimal values of the bits

that are to be enabled.

Parameter

0to 65535

Example

STAT:QUES:SYNC:PTR 65535

All condition bits will be summarized in the Event register when a positive transition occurs.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

STATus:QUEStionable:SYNC:NTRansition

This command determines what bits in the STATus:QUEStionable:SYNC Condition will set the

corresponding bit in the STATus:QUEStionable:SYNC Event register when that bit has a

negative transition (1 to 0). The variable <number> is the sum of the decimal values of the bits

that are to be enabled.

Parameter

0to 65535

Example

STAT:QUES:SYNC:NTR 65535 –

All condition bits will be summarized in the Event register when a positive transition occurs.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL TRACe Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.745 E-11

TRACe Subsystem (WLAN, K91 / K91n)

The TRACe subsystem controls access to the instrument's internal trace memory.

Commands of the TRACe Subsystem

–TRACe[:DATA]

–TRACe:IQ:DATA:MEMory?

–TRACe:IQ:SRATe

Further information

–IQ Measurements

–Constellation vs Symbol

–Constellation vs Carrier

–Power vs Time – Full Burst and Rising /Falling Data

–Spectrum Flatness

–Spectrum FFT

–Statistics Bitstream data

–Statistics CCDF – Complementary cumulative distribution function

–Statistics Signal Field data

–EVM vs Carrier

–EVM vs Symbol

–Error vs Preamble

–Frequency Sweep Measurements

–Spectrum Mask

–Spectrum ACPR

IQ Measurements

There are a number of measurements that can be performed in IQ mode. No data will be returned for

any of the following measurements, should it be requested, until such time as a measurement

belonging to the IQ group has been previously run.

Running a frequency sweep measurement for example, Spectrum Mask, will not generate results for

this measurement group.

Constellation vs Symbol

This measurement represents I and Q data. For IEEE 802.11a and j the data will be returned as a

repeating array of interleaved I and Q data in groups of selected carriers, until all the data is exhausted.

For IEEE 802.11b the data will be returned as a repeating array of interleaved I and Q data in symbol

order until all the data is exhausted.

Each I and Q point will be returned in floating point format. TRACE1 is used for this measurement

results.

TRACe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.746 E-11

IEEE 802.11a & j only

•If "All Carriers'' is selected, it will return 52 per of I and Q data per symbol.

•If "Pilots Only'' is selected, it will return 4 per of I and Q per symbol in the following order: Carrier –

21, Carrier –7, Carrier 7, Carrier 21.

•If a single carrier is selected, it will return 1 per of I and Q data per symbol.

Constellation vs Carrier

This measurement represents I and Q data. Data will be returned as a repeating array of interleaved I

and Q data in groups of 53 channels including the channel 0, until all the data is exhausted.

Each I and Q point will be returned in floating point format. TRACE1 is used for this measurement results.

Power vs Time – Full Burst and Rising /Falling Data

Both measurement results are once again simply slightly different views of the same results data.

All fully complete bursts within the capture time are analyzed into three master bursts. The three master

bursts relate to the minimum, maximum and average values across all complete bursts. This data is

returned in dBm values to the user on a per sample basis. Each sample will in some way relate to an

analysis of each corresponding sample within each processed burst.

The type of PVT data returned will be determined by the TRACE number passed as an argument to the

SCPI command, in addition to the graphic type that is selected.

If the graphic type selected is full burst, then the return data is as follows.

TRACE1 full burst, minimum burst data values

TRACE2 full burst, mean burst data values

TRACE3 full burst, maximum burst data values

If the graphic type selected is EDGe, then the return data is as follows.

TRACE1 rising edge, minimum burst data values

TRACE2 rising edge, mean burst data values

TRACE3 rising edge, maximum burst data values

TRACE4 falling edge, minimum burst data values

TRACE5 falling edge, mean burst data values

TRACE6 falling edge, maximum burst data values

For IEEE 802.11b only

•If the graphic type selected is RISing or FALLing then only 3 traces are available (1 to 3) and

represent the minimum, mean and maximum bursts data for the respective graph selection.

•The number of samples returned during full burst analysis will depend on the modulation type and

will typically be 5000.

•The number of samples returned when the rising and falling graphic type is selected will be less

than what is returned for full burst and will be approximately 400 samples.

•The samples will be returned in floating point format as a single sequence of comma delimited

values.

R&S FSL TRACe Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.747 E-11

Spectrum Flatness

There are four separate traces that are available with this measurement. Trace data for a particular

trace will only be returnable by querying the appropriate trace

Spectrum flatness provides two basic graph types. These are an absolute power value graph (ABS) and

arelative group delay graph, which are both plotted on a per carrier basis. All 52 carriers are drawn, in

addition to the unused 0 carrier. Both the absolute power and group delay graph groups will allow all the

data points to be returned as one trace and an average of all the channels as the other trace.

E.g. the return data will either be one single group of 53 carriers if the average trace is selected or a

repeating group of 53 carriers if all the data is requested.

TRACE1 ABS (all analyzed trains)

TRACE2 Group Delay (all analyzed trains)

TRACE3 ABS (average trace)

TRACE4 Group Delay (average trace)

Absolute power results are returned in dB and group delay results are returned in ns.

Spectrum FFT

All FFT points will be returned if the data for this measurement is requested. This will be an exhaustive

call, due to the fact that there are nearly always more FFT points than IQ samples. The number of FFT

points is the number presented by a power of 2 that is higher than the total number of samples.

E.g. if there were 20000 samples, then 32768 FFT points would be returned.

Data will be returned in floating point format in dBm. TRACE1 is used for this measurement results.

Statistics Bitstream data

IEEE 802.11a & j only

Data will be returned in repeating groups of 52 data channels where each symbol value will be

represented by an integer value within one byte. Channel 0 is unused and will therefore not have any

data associated with it, with no return data being provided.

The number of repeating groups that are returned will be equal to the number of measured symbols.

Currently, 64QAM has the highest data rate and it contains symbol values up to 63, making the

proposal of one byte sufficient in size to represent all symbol data values, regardless of the modulation

type in use.

Data will be returned in ASCII printable hexadecimal character format. TRACE1 is used for this

measurement results.

IEEE 802.11b only

Data will be returned in burst order. Each burst will be represented as a series of bytes. For each burst

the first 9 or 18 bytes represents the PLCP Preamble for Short and Long burst types respectively. The

next 6 bytes represents the PLCP Header. The remaining bytes represent the PSDU.

Data will be returned in ASCII printable hexadecimal character format. TRACE1 is used for this

measurement results.

TRACe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.748 E-11

Statistics CCDF – Complementary cumulative distribution function

Up to a maximum of 201 data points will be returned in addition to a data count value. The first value in the

return data will represent the quantity of probability values that follow. Each of the potential 201 data points will

be returned as probability value and will represent the total number of samples that are equal to or exceed the

corresponding power level. Probability data will be returned up to the power level that contains at least one

sample. It is highly unlikely that the full 201 data values will ever be returned.

Each probability value will be returned as a floating point number, with a value less than 1.

Statistics Signal Field data

IEEE 802.11a & j only

Data will be returned as an array of hexadecimal values, with each hexadecimal value representing the

24 bit long signal field for a single burst.

IEEE 802.11b only

Data will be returned as an array of hexadecimal values, with each hexadecimal value representing the

48 bit long signal field for a single burst

EVM vs Carrier

Two trace types are provided with this measurement. There is an average EVM value for each of the 53

channels or a repeating group of EVM values for each channel. The number of repeating groups will

correspond to the number of fully analyzed trains.

Each EVM value will be returned as a floating point number, expressed in units of dBm.

TRACE1 Average EVM values per channel

TRACE2 All EVM values per channel for each full train of the capture period

EVM vs Symbol

Three traces types are available with this measurement. The basic trace types show either the

minimum, mean or maximum EVM value, as measured over the complete capture period.

The number of repeating groups that are returned will be equal to the number of measured symbols.

Each EVM value will be returned as a floating point number, expressed in units of dBm.

IEEE 802.11a & j only

TRACE1 Minimum EVM values

TRACE2 Mean EVM values

TRACE3 Maximum EVM values

IEEE 802.11b only

TRACE1 EVM IEEE values

TRACE2 EVM Direct values

Error vs Preamble

Three traces types are available with this measurement. The basic trace types show either the

minimum, mean or maximum frequency or phase value as measured over the preamble part of the

burst.

R&S FSL TRACe Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.749 E-11

Frequency Sweep Measurements

No data will be returned for this type of measurement, should it be requested, until such time as a

measurement has been previously run.

Running an IQ measurement will not generate results for this type of measurement.

Spectrum Mask

Result data will be returned as 501 measurement points in floating point format. These trace points are

obtained directly from the base system via the measurement API and the quantity is therefore a fixed

value. Only an array of Y data will be returned. TRACE1 is used for this measurement results.

Spectrum ACPR

Result data will be returned as 501 measurement points in floating point format. These trace points are

obtained directly from the base system via the measurement API and the quantity is therefore a fixed

value. Only an array of Y data will be returned. TRACE1 is used for this measurement results.

TRACe[:DATA]

This command returns all the measured data that relates to the currently selected measurement

type. All results are returned in ASCII format. The returned data depends on the currently

selected measurement type. DISPlay:FORMat is not supported with this command.

The following measurement types are available:

–"IQ Measurements" on page 6.745

–"Constellation vs Symbol" on page 6.745

–"Constellation vs Carrier" on page 6.746

–"Power vs Time – Full Burst and Rising /Falling Data" on page 6.746

–"Spectrum Flatness" on page 6.747

–"Spectrum FFT" on page 6.747

–"Statistics Bitstream data" on page 6.747

–"Statistics CCDF – Complementary cumulative distribution function" on page 6.748

–"Statistics Signal Field data" on page 6.748

–"EVM vs Carrier" on page 6.748

–"EVM vs Symbol" on page 6.748

–"Error vs Preamble" on page 6.748

–"Frequency Sweep Measurements" on page 6.749

–"Spectrum Mask" on page 6.749

–"Spectrum ACPR" on page 6.749

This command is a query only and thus has no *RST value.

Parameter

Example

TRAC? TRACE2

The measurement data for the selected graph is returned.

TRACe Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.750 E-11

Characteristics

*RST value: –

SCPI: conform

Mode

WLAN

TRACe:IQ:DATA:MEMory?

For details refer to "TRACe<1|2>:IQ:DATA:MEMory?" on page 6.274.

TRACe:IQ:SRATe

This command allows the sample rate for IQ measurements to be specified.

Example

TRACe:IQ:SRAT 20000

Specifies a sample rate of 20 MHz.

Characteristics

*RST value: –

SCPI: device–specific

Mode

WLAN

R&S FSL TRIGger Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.751 E-11

TRIGger Subsystem (WLAN, K91 / K91n)

The trigger subsystem is used to synchronize device action(s) with events.

Commands of the TRIGger Subsystem

–TRIGger[:SEQuence]:HOLDoff

–TRIGger[:SEQuence]:MODE

–TRIGger[:SEQuence]:LEVel:POWer

–TRIGger[:SEQuence]:LEVel:POWer:AUTO

TRIGger[:SEQuence]:HOLDoff

This command defines the length of the trigger delay. A negative delay time (pretrigger) can be

set.

Parameter

<numeric_value>

Example

TRIG:HOLD 500us

Configures to use a holdoff period of 500 Usafter the trigger condition has been met.

Characteristics

*RST value: –10 µs

SCPI: Conform

Mode

WLAN

TRIGger[:SEQuence]:MODE

This command configures how triggering is to be performed.

Parameter

IMMediate automatically triggers the next measurement at the end of the previous

measurement. This corresponds to the FREE RUN setting.

EXTernal the next measurement is triggered by the signal at the external trigger input

e.g. a gated trigger

POWer triggering of the measurement via signals which are the measurement

channel.

Example

TRIG:MODE IMM

AUTO triggering will occur for the next measurement at the specified video percentage value.

Characteristics

*RST value: IMMediate

SCPI: device–specific

Mode

WLAN

TRIGger Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.752 E-11

TRIGger[:SEQuence]:LEVel:POWer

This command accepts the level of the input signal for which triggering will occur.

Parameter

<numeric_value>

Example

TRIG:LEV:POW 10 DBM

Set to 10 dBm for RF measurement.

Characteristics

*RST value: 0 DBM

SCPI: device–specific

Mode

WLAN

TRIGger[:SEQuence]:LEVel:POWer:AUTO

This command specifies whether or not an automatic power trigger level calculation is

performed before each main measurement. The setting of this command is ignored if the setting

for the TRIGger[:SEQuence]:MODE command is not POWer.

Parameter

ON | OFF

Example

TRIG:LEV:POW:AUTO ON

Specifies that an automatic power trigger level calculation should be performed before the start

of each main measurement.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

WLAN

R&S FSL UNIT Subsystem (WLAN, K91 / K91n)

1300.2519.12 6.753 E-11

UNIT Subsystem (WLAN, K91 / K91n)

The unit subsystem specifies the units for specific result types.

Commands of the UNIT Subsystem

–UNIT:EVM

–UNIT:GIMBalance

–UNIT:PREamble

UNIT:EVM

This command specifies the units for EVM results.

Parameter

DB EVM results returned in dB

PCT EVM results returned in %

Example

UNIT:EVM PCT

EVM results to be returned in %.

Characteristics

*RST value: DB

SCPI: device–specific

Mode

WLAN

UNIT:GIMBalance

This command specifies the units for Gain Imbalance results.

Parameter

DB Gain Imbalance results returned in dB

PCT Gain Imbalance results returned in %

Example

UNIT:GIMB PCT

Gain Imbalance results to be returned in %.

Characteristics

*RST value: DB

SCPI: device–specific

Mode

WLAN

UNIT Subsystem (WLAN, K91 / K91n) R&S FSL

1300.2519.12 6.754 E-11

UNIT:PREamble

This command specifies the units for Preamble error results.

Parameter

HZ Preamble error results returned in Hz

PCT Preamble error results returned in %

Example

UNIT:PRE PCT

Preamble error results to be returned in %.

Characteristics

*RST value: DB

SCPI: device–specific

Mode

WLAN

R&S FSL Remote Commands - WiMAX, WiBro Measurements Option (K92/K93)

1300.2519.12 6.755 E-11

Remote Commands of the WiMAX, WiBro

Measurements Option (K92/K93)

This section describes the remote commands for the WiMAX IEEE 802.16 OFDM, OFDMA

Measurements option (R&S FSL–K93). This option includes the functionality of the WiMAX 802.16

OFDM Measurements option (R&S FSL–K92). Accordingly both options are described together in this

section, differentiated by the corresponding standards:

•WiMAX 802.16 OFDM Measurements (R&S FSL–K92/K93)

–IEEE 802.16–2004/Cor 1–2005 OFDM physical layer mode

The corresponding remote control mode is OFDM.In chapter "Instrument Functions", the short

forms IEEE 802.16–2004 OFDM is used to reference this standard.

•WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K93)

–IEEE 802.16–2004/Cor 1–2005, IEEE 802.16e–2005 OFDMA physical layer mode

The corresponding remote control mode is OFDMA.In chapter "Instrument Functions", the

short form IEEE 802.16e–2005 OFDMA is used to reference this standard.

–IEEE 802.16–2004/Cor 1–2005, IEEE 802.16e–2005 based WiBro

The corresponding remote control mode is WiBro.In chapter "Instrument Functions", the short

form IEEE 802.16e–2005 WiBro is used to reference this standard.

For details on conventions used in this chapter refer to section "Notation" on page 6.2 at the beginning

of this chapter.

For further information on analyzer or basic settings commands, refer to the corresponding subsystem

in section "Remote Commands of the Base Unit" on page 6.5.

The options are available from firmware version 1.40 (R&S FSL–K92) and 1.50 (R&S FSL–K93).

Subsystems of the WiMAX, WiBro Measurements options (K92/K93)

–"ABORt Subsystem (WiMAX, K92/K93)" on page 6.757

–"CALCulate:BURSt Subsystem (WiMAX, K92/K93)" on page 6.758

–"CALCulate:LIMit Subsystem (WiMAX, K92/K93)" on page 6.759

–"CALCulate:MARKer Subsystem (WiMAX, K92/K93)" on page 6.775

–"CONFigure Subsystem (WiMAX, K92/K93)" on page 6.783

–"DISPlay Subsystem (WiMAX, K92/K93)" on page 6.811

–"FETCh Subsystem (WiMAX, K92/K93)" on page 6.816

–"FORMat Subsystem (WiMAX, K92/K93)" on page 6.828

– "INITiate Subsystem (WiMAX, K92/K93)" on page 6.829

– "INPut Subsystem (WiMAX, K92/K93)" on page 6.830

–"INSTrument Subsystem (WiMAX, K92/K93)" on page 6.831

–"MMEMory Subsystem (WiMAX, K92/K93)" on page 6.832

–"SENSe Subsystem (WiMAX, K92/K93)" on page 6.834

–"STATus Subsystem (WiMAX, K92/K93)" on page 6.851

–"SYSTEM Subsystem (WiMAX, K92/K93)" on page 6.855

–"TRACe Subsystem (WiMAX, K92/K93)" on page 6.856

Remote Commands - WiMAX, WiBro Measurements Option (K92/K93) R&S FSL

1300.2519.12 6.756 E-11

–"TRIGger Subsystem (WiMAX, K92/K93)" on page 6.864

–"UNIT Subsystem (WiMAX, K92/K93)" on page 6.867

R&S FSL ABORt Subsystem (WiMAX, K92/K93)

1300.2519.12 6.757 E-11

ABORt Subsystem (WiMAX, K92/K93)

Commands of the ABORt Subsystem

–ABORt

ABORt

For details refer to "ABORt" on page 6.10.

CALCulate:BURSt Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.758 E-11

CALCulate:BURSt Subsystem (WiMAX, K92/K93)

The CALCulate:BURSt subsystem checks the IQ measurement results.

Commands of the CALCulate:BURSt Subsystem

–CALCulate<1|2>:BURSt[:IMMediate]

CALCulate<1|2>:BURSt[:IMMediate]

This command forces the IQ measurement results of to be recalculated according to the current

settings.

The numeric suffixes <1|2> sets the measurement window for the calculation.

This command is an event and therefore has no *RST value and no query.

Example

CALC1:BURS

Starts the recalculation of the IQ measurement results.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CALCulate:LIMit Subsystem (WiMAX, K92/K93)

1300.2519.12 6.759 E-11

CALCulate:LIMit Subsystem (WiMAX, K92/K93)

The CALCulate:LIMit subsystem contains commands for the limit lines and the corresponding limit

checks.

Commands of the CALCulate:LIMit Subsystem

–CALCulate<1|2>:LIMit<1...8>:FAIL?

–CALCulate<1|2>:LIMit<1...8>:BURSt:ALL

–CALCulate<1|2>:LIMit<1...8>:BURSt:ALL:RESult?

–CALCulate<1|2>:LIMit<1..8>:BURSt:BERPilot[:AVERage]

–CALCulate<1|2>:LIMit<1...8>:BURSt:BERPilot[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:BERPilot:MAXimum

–CALCulate<1|2>:LIMit<1...8>:BURSt:BERPilot:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:ALL[:AVERage]

–CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:ALL[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:ALL:MAXimum

–CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:ALL:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:DATA[:AVERage]

–CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:DATA[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:DATA:MAXimum

–CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:DATA:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:FERRor[:AVERage]

–CALCulate<1|2>:LIMit<1...8>:BURSt:FERRor[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:FERRor:MAXimum

–CALCulate<1|2>:LIMit<1...8>:BURSt:FERRor:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:IQOFfset[:AVERage]

–CALCulate<1|2>:LIMit<1...8>:BURSt:IQOFfset[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:IQOFfset:MAXimum

–CALCulate<1|2>:LIMit<1...8>:BURSt:IQOFfset:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:SSTiming[:AVERage]

–CALCulate<1|2>:LIMit<1...8>:BURSt:SSTiming[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:SSTiming:MAXimum

–CALCulate<1|2>:LIMit<1...8>:BURSt:SSTiming:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:SYMBolerror[:AVERage]

–CALCulate<1|2>:LIMit<1...8>:BURSt:SYMBolerror[:AVERage]:RESult?

–CALCulate<1|2>:LIMit<1...8>:BURSt:SYMBolerror:MAXimum

–CALCulate<1|2>:LIMit<1...8>:BURSt:SYMBolerror:MAXimum:RESult?

–CALCulate<1|2>:LIMit<1...8>:SPECtrum:MASK:CHECk:X?

–CALCulate<1|2>:LIMit<1...8>:SPECtrum:MASK:CHECk:Y?

CALCulate:LIMit Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.760 E-11

CALCulate<1|2>:LIMit<1...8>:FAIL?

This command queries the limit check result of the limit line indicated in the selected

measurement window. To obtain a valid result, a complete sweep must be performed. A

synchronization with *OPC,*OPC? or *WAI is therefore recommended.

The numeric suffixes <1|2> sets the measurement window for the calculation. The numeric

suffixes <1...8> specify the limit lines as follows:

1to 2 not used

3ETSI Spectrum Mask limit line

4 IEEE Spectrum Mask limit line

5Spectrum Flatness (Upper) limit line

6Spectrum Flatness (Lower) limit line

7Spectrum Flatness Difference (Upper) limit line

8Spectrum Flatness Difference (Lower) limit line

Note: No limit lines are displayed in screen A. Therefore all commands with the suffix 1 for

CALCulate will return 0.

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

INIT;*WAI

Starts a new sweep and waits for its end.

CALC2:LIM1:FAIL?

Queries the result of the check for limit line 1 in screen B.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:ALL

This command sets or returns all the limit values.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

The results are input or output as a list of values separated by commas in the following (ASCII)

format:

Result input/output in ASCII format Description

<average EVM all bursts>,

dB or % depending on selected units (UNIT:TABLe)

<average EVM data carriers >,

dB or % depending on selected units (UNIT:TABLe)

<average Frequency Error>,

Down Link Mode: Hz; .Up Link Mode: %

R&S FSL CALCulate:LIMit Subsystem (WiMAX, K92/K93)

1300.2519.12 6.761 E-11

Result input/output in ASCII format Description

<average Symbol Error>,

Down Link Mode: ppm; Up Link Mode: %

<average SS Timing>,

only returned in Up Link mode

<average IQ Offset>,

dB or % depending on selected units (UNIT:TABLe)

Example

CALC:LIM:BURS:ALL?

All limit values are returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:ALL:RESult?

This command returns all the limit results.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

The results are output as a list of result strings separated by commas. For the output order see

CALCulate<1|2>:LIMit<1...8>:BURSt:ALL command.

Example

CALC:LIM:BURS:ALL:RES?

All limit values are returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1..8>:BURSt:BERPilot[:AVERage]

This command sets the average Bit Error Rate for pilot carriers limit.

Parameter

–1000000 to 1000000 %

Example

CALC:LIM:BURS:BERP –25.0

Average Bit Error Rate for pilot carriers limit is set to –25.0 dB.

CALCulate:LIMit Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.762 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:BERPilot[:AVERage]:RESult?

This command returns the Bit Error Rate for pilot carriers limit result.

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:BERP:RES?

Average EVM for all carrier limit result is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:BERPilot:MAXimum

This command sets the maximum Bit Error Rate Limit.

Parameter

–1000000 to 1000000 %

Example

CALC:LIM:BURS:EVM:ALL:MAX?

Maximum EVM for all carrier limit is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

R&S FSL CALCulate:LIMit Subsystem (WiMAX, K92/K93)

1300.2519.12 6.763 E-11

CALCulate<1|2>:LIMit<1...8>:BURSt:BERPilot:MAXimum:RESult?

This command returns the maximum Error Vector Magnitude Limit result. This is a combined

figure that represents the pilot, data and the free carrier.

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:ALL:MAX:RES?

Maximum EVM for all carrier limit result is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:ALL[:AVERage]

This command sets the average Error Vector Magnitude Limit. This is a combined figure that

represents the pilot, data and the free carrier.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

–1000000 to 1000000 dB or %

If no unit is specified the unit specified by the UNIT:TABLe command is used.

Example

CALC:LIM:BURS:EVM:ALL –25.0

Average EVM for all carrier limit is set to –25.0 dB.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:ALL[:AVERage]:RESult?

This command returns the average Error Vector Magnitude Limit result. This is a combined

figure that represents the pilot, data and the free carrier.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

CALCulate:LIMit Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.764 E-11

Example

CALC:LIM:BURS:EVM:ALL:RES?

Average EVM for all carrier limit result is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:ALL:MAXimum

This command sets the maximum Error Vector Magnitude Limit. This is a combined figure that

represents the pilot, data and the free carrier.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

–1000000 to 1000000 dB or %

If no unit is specified the unit specified by the UNIT:TABLe command is used.

Example

CALC:LIM:BURS:EVM:ALL:MAX?

Maximum EVM for all carrier limit is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:ALL:MAXimum:RESult?

This command returns the maximum Error Vector Magnitude Limit result. This is a combined

figure that represents the pilot, data and the free carrier.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:ALL:MAX:RES?

Maximum EVM for all carrier limit result is returned.

R&S FSL CALCulate:LIMit Subsystem (WiMAX, K92/K93)

1300.2519.12 6.765 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:DATA[:AVERage]

This command sets the average Error Vector Magnitude Limit for the data carrier.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

–1000000 to 1000000 dB or %

If no unit is specified the unit specified by the UNIT:TABLe command is used.

Example

CALC:LIM:BURS:EVM:DATA –30.0

Average EVM for data carrier limit is set to –30.0 dB.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:DATA[:AVERage]:RESult?

This command returns the average Error Vector Magnitude limit result summary for the data

carrier in dB.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:DATA:RES?

Average EVM for data carrier limit result is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate:LIMit Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.766 E-11

CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:DATA:MAXimum

This command sets the maximum Error Vector Magnitude Limit for the data carrier.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

–1000000 to 1000000 dB or %

If no unit is specified the unit specified by the UNIT:TABLe command is used.

Example

CALC:LIM:BURS:EVM:DATA:MAX?

Maximum EVM for data burst limit is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:EVM:DATA:MAXimum:RESult?

This command returns the maximum Error Vector Magnitude limit result summary for the data

carrier in dB.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:EVM:DATA:MAX:RES?

Maximum EVM for data carrier limit result is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:FERRor[:AVERage]

This command sets the average frequency error limit.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

–1000000 to 1000000 Hz or %

If no unit is specified the unit depends on the current Up/Down Link Mode: Hz in Down Link

mode, % in Up Link mode.

R&S FSL CALCulate:LIMit Subsystem (WiMAX, K92/K93)

1300.2519.12 6.767 E-11

Note: There is no relationship between the Down Link and Up Link values. Setting a Down

Link value in Up Link mode does not change the displayed limit value.

Example

CALC:LIM:BURS:FERR 10000

The average frequency error limit is set to 10000 Hz.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:FERRor[:AVERage]:RESult?

This command returns the average frequency error limit result.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:FERR:RES?

Average frequency error limit result is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:FERRor:MAXimum

This command sets the maximum frequency error limit.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

–1000000 to 1000000 Hz or %

If no unit is specified the unit depends on the current Up/Down Link Mode: Hz in Down Link

mode, % in Up Link mode.

Note: There is no relationship between the Down Link and Up Link values. Setting a Down

Link value in Up Link mode does not change the displayed limit value.

Example

CALC:LIM:BURS:FERR:MAX?

Maximum frequency error limit is returned.

CALCulate:LIMit Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.768 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:FERRor:MAXimum:RESult?

This command returns the maximum frequency error limit result.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:FERR:MAX:RES?

Maximum frequency error limit result is returned

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:IQOFfset[:AVERage]

This command sets the average IQ offset error limit.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

–1000000 to 1000000 dB or %

If no unit is specified the unit specified by the UNIT:TABLe command is used.

Example

CALC:LIM:BURS:IQOF –10.0

Average IQ offset error limit is set to –10.0 dB.

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CALCulate:LIMit Subsystem (WiMAX, K92/K93)

1300.2519.12 6.769 E-11

CALCulate<1|2>:LIMit<1...8>:BURSt:IQOFfset[:AVERage]:RESult?

This command returns the average IQ offset error limit result.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:IQOF:RES?

Average IQ offset error limit result is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:IQOFfset:MAXimum

This command sets the maximum IQ offset error limit.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

–1000000 to 1000000 dB or %

If no unit is specified the unit specified by the UNIT:TABLe command is used.

Example

CALC:LIM:BURS:IQOF:MAX 15.0DB

Maximum IQ offset error limit is set to 15.0 dB.

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:IQOFfset:MAXimum:RESult?

This command returns the maximum IQ offset error limit result.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

CALCulate:LIMit Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.770 E-11

Example

CALC:LIM:BURS:IQOF:MAX:RES?

Maximum IQ offset error limit result is returned.

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:SSTiming[:AVERage]

This command is only supported for reasons of compatibility with the FSP family. It sets the

average Subscriber Station Timing limit.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

0PCT

Example

CALC:LIM:BURS:SST 0

The average SS Timing limit is set to 0%.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:SSTiming[:AVERage]:RESult?

This command returns the average Subscriber Station Timing limit result.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:SST:RES?

Average SS Timing limit result is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CALCulate:LIMit Subsystem (WiMAX, K92/K93)

1300.2519.12 6.771 E-11

CALCulate<1|2>:LIMit<1...8>:BURSt:SSTiming:MAXimum

This command is only supported for reasons of compatibility with the FSP family. It sets the

maximum Subscriber Station Timing limit.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

0PCT

Example

CALC:LIM:BURS:SST:MAX?

Maximum SS Timing limit is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:SSTiming:MAXimum:RESult?

This command returns the maximum Subscriber Station Timing limit.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:SST:MAX:RES?

Maximum SS Timing limit result is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:SYMBolerror[:AVERage]

This command sets the average symbol error limit.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

<numeric_value> in ppm or %: –1000000 to 1000000

If no unit is specified the unit depends on the current Up/Down Link Mode: ppm in Down Link

mode, % in Up Link mode.

Note: There is no relationship between the Down Link and Up Link values. Setting a Down

Link value in Up Link mode does not change the displayed limit value.

CALCulate:LIMit Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.772 E-11

Example

CALC:LIM:BURS:SYMB 10000

The average symbol error limit is set to 10000 Hz.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:SYMBolerror[:AVERage]:RESult?

This command returns the average symbol error limit result.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:SYMB:RES?

Average symbol error limit result is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:SYMBolerror:MAXimum

This command sets the maximum symbol error limit.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

Parameter

<numeric_value> in ppm or %: –1000000 to 1000000

If no unit is specified the unit depends on the current Up/Down Link Mode: ppm in Down Link

mode, % in Up Link mode.

Note: There is no relationship between the Down Link and Up Link values. Setting a Down

Link value in Up Link mode does not change the displayed limit value.

Example

CALC:LIM:BURS:SYMB:MAX?

Maximum symbol error limit is returned.

R&S FSL CALCulate:LIMit Subsystem (WiMAX, K92/K93)

1300.2519.12 6.773 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:BURSt:SYMBolerror:MAXimum:RESult?

This command returns the maximum symbol error limit result.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Return values

0PASSED

1FAILED

Example

CALC:LIM:BURS:SYMB:MAX:RES?

Maximum symbol error limit result is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:LIMit<1...8>:SPECtrum:MASK:CHECk:X?

This command returns the x–value at the maximum overstepping of the spectrum mask limits.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Example

CALC:LIM:SPEC:MASK:CHEC:X?

Returns the frequency at the maximum overstepping.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate:LIMit Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.774 E-11

CALCulate<1|2>:LIMit<1...8>:SPECtrum:MASK:CHECk:Y?

This command returns the y–value at the maximum overstepping of the spectrum mask limits.

The numeric suffixes <1|2> sets the measurement window for the calculation and the suffixes

<1...8> specify the limit lines (see CALCulate<1|2>:LIMit<1...8>:FAIL? command).

This command is only a query and therefore has no *RST value.

Example

CALC:LIM:SPEC:MASK:CHEC:Y?

Returns the power at the maximum overstepping.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CALCulate:MARKer Subsystem (WiMAX, K92/K93)

1300.2519.12 6.775 E-11

CALCulate:MARKer Subsystem (WiMAX, K92/K93)

The CALCulate:MARKer subsystem checks the marker functions of the instrument.

Note: Currently there is only marker 1 available and it is always on.

The following subsystem is included:

•"CALCulate:MARKer:FUNCtion Subsystem (WiMAX, K92/K93)" on page 6.781

Commands of the CALCulate:MARKer Subsystem

–CALCulate<1|2>:MARKer<1>[:STATe]

–CALCulate<1|2>:MARKer<1>:AOFF

–CALCulate<1|2>:MARKer<1>:BURSt

–CALCulate<1|2>:MARKer<1>:CARRier

–CALCulate<1|2>:MARKer<1>:MAXimum[:PEAK]

–CALCulate<1|2>:MARKer<1>:MINimum[:PEAK]

–CALCulate<1|2>:MARKer<1>:SYMBol

–CALCulate<1|2>:MARKer<1>:TRACe

–CALCulate<1|2>:MARKer<1>:FUNCtion:TTCapture:TIME?

–CALCulate<1|2>:MARKer<1>:X

–CALCulate<1|2>:MARKer<1>:Y?

CALCulate<1|2>:MARKer<1>[:STATe]

This command switches the markers in the specified measurement window on or off.

Parameter

ON | OFF

Example

CALC1:MARK1 ON

Switches the screen A marker ON.

Characteristics

RST value: ON

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:MARKer<1>:AOFF

This command switches off all active markers in the specified measurement window. The

window is set by the numeric suffix of CALCulate<1|2>.

Example

CALC1:MARK:AOFF

Switches off all markers in the screen A window.

CALCulate:MARKer Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.776 E-11

CALC2:MARK:AOFF

Switches off all markers in the screen B window.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:MARKer<1>:BURSt

This command positions the selected marker in the specified measurement window to the

indicated burst. This command is only available for the Constellation vs Symbol result display.

Parameter

1to <number of captured bursts in capture buffer>

Example

CALC2:MARK:BURS 2

Positions marker 1 in screen B to burst 2.

CALC2:MARK:BURS?

Outputs the symbol value of marker 1 in screen B.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:MARKer<1>:CARRier

This command positions the selected marker in the specified measurement window to the

indicated carrier.

This command is only available for the following result displays:

–Constellation vs Symbol

–Constellation vs Carrier

Parameter

–100 to 100

Example

CALC2:MARK:CARR –7

Positions marker 1 in screen B to carrier –7.

CALC2:MARK:CARR?

Outputs the carrier value of marker 1 in screen B.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CALCulate:MARKer Subsystem (WiMAX, K92/K93)

1300.2519.12 6.777 E-11

CALCulate<1|2>:MARKer<1>:MAXimum[:PEAK]

This command sets the selected marker in the specified measurement window to the maximum

peak value in the current trace.

This command is only available for the following result display:

–Spectrum Flatness

This command is an event and therefore has no *RST value and no query.

Example

CALC2:MARK:MAX

Set marker 1 in screen B to maximum value in trace.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:MARKer<1>:MINimum[:PEAK]

This command sets the selected marker in the specified measurement window to the minimum

peak value in the current trace.

This command is only available for the following result display:

–Spectrum Flatness

This command is an event and therefore has no *RST value and no query.

Example

CALC2:MARK:MIN

Set marker 1 in screen B to minimum value in trace.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:MARKer<1>:SYMBol

This command positions the selected marker in the specified measurement window to the

indicated symbol.

This command is only available for the following result displays:

–Constellation vs Symbol

–Constellation vs Carrier

Parameter

1to <number of symbols in selected burst>

CALCulate:MARKer Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.778 E-11

Example

CALC2:MARK:SYMB 2

Positions marker 1 in screen B to symbol 2.

CALC2:MARK:SYMB?

Outputs the symbol value of marker 1 in screen B.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:MARKer<1>:TRACe

This command assigns the selected marker to the indicated measurement curve in the selected

measurement window.

This command is only available for the following result displays:

–Constellation vs Carrier

–EVM vs Symbol

–EVM vs Carrier

–Frequency Error vs Preamble

–Phase Error vs Preamble

–PVT Rising / Falling

–Spectrum Flatness

–Spectrum Flatness Difference

–Spectrum Mask – if Max Hold trace mode is activated

–Spectrum ACP/ACPR – if Max Hold trace mode is activated

Parameter

1to 3

Example

CALC2:MARK:TRAC 2

Assigns marker 1 in screen B to trace 2.

Characteristics

RST value: 1

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CALCulate:MARKer Subsystem (WiMAX, K92/K93)

1300.2519.12 6.779 E-11

CALCulate<1|2>:MARKer<1>:FUNCtion:TTCapture:TIME?

This command returns the time to the start of the first frame in the capture buffer.

This command is only a query and therefore has no *RST value.

Example

CALC:MARK:FUNC:TTC:TIME?

Returns the time to the start of the first frame in the capture buffer.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CALCulate<1|2>:MARKer<1>:X

This command positions the selected marker to the indicated in phase (Constellation vs

Symbol), frequency (Spectrum FFT, Spectrum Mask), time (Magnitude Capture Buffer, Auto

Level, PVT Full Burst, PVT Rising / Falling), power (CCDF), sub–carrier (Constellation vs

Carrier, EVM vs Carrier, Spectrum Flatness) or symbol (EVM vs Symbol) in the selected

measurement window.

For the following result displays, this command is a query only:

–Constellation vs Symbol

–Constellation vs Carrier

Parameter

1to <maximum range for selected measurement>

Example

CALC:MARK:X 2ms

Positions marker 1 in screen A to time 2 ms.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate:MARKer Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.780 E-11

CALCulate<1|2>:MARKer<1>:Y?

This command queries the marker value of the indicated quadrature (Constellation vs Symbol),

magnitude of I or Q (Constellation vs Carrier), EVM (EVM vs Carrier) or abs (Spectrum

Flatness) in the selected measurement window.

This command is only a query and therefore has no *RST value.

This command is only available for the following result displays:

–Auto Level

–Constellation vs Symbol

–Constellation vs Carrier

–EVM vs Symbol

–PVT Full

–PVT Rising / Falling

–Magnitude Capture Buffer

–Spectrum Mask

–Spectrum FFT

–CCDF

Example

CALC2:MARK:Y –2

Positions marker 1 in screen B to –2.

CALC:MARK:Y?

Outputs the measured value of marker 1 in screen A.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CALCulate:MARKer Subsystem (WiMAX, K92/K93)

1300.2519.12 6.781 E-11

CALCulate:MARKer:FUNCtion Subsystem (WiMAX, K92/K93)

The measurement window is selected by CALCulate 1 (screen A) or 2 (screen B).

Commands of the CALCulate:MARKer:FUNCtion Subsystem

–CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult[:CURRent]?

–CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult:MAXHold?

–CALCulate<1|2>:MARKer<1>:FUNCtion:ZOOM

CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult[:CURRent]?

This command queries the current result values of the adjacent channel power measurement.

An ACPR (Adjacent channel power relative) measurement must have previously been run to

provide the summary data.

The numeric suffix <1|2> at CALCulate specifies the measurement window.

This command is only a query and therefore has no *RST value.

Results are output separated by commas. Adjacent channel power values are output in dB. The

order is as follows:

–Power of main channel

–Power of lower adjacent channel

–Power of upper adjacent channel

–Power of lower alternate adjacent channel 1

–Power of upper alternate adjacent channel 1

–Power of lower alternate adjacent channel 2

–Power of upper alternate adjacent channel 2

–Power of lower alternate adjacent channel 3

–Power of upper alternate adjacent channel 3

–Power of lower alternate adjacent channel 4

–Power of upper alternate adjacent channel 4

Example

CALC2:MARK:FUNC:POW:RES?

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate:MARKer Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.782 E-11

CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult:MAXHold?

This command queries the maximum result values of the adjacent channel power

measurement. An ACPR (Adjacent channel power relative) measurement must have previously

been run with more than one sweep to provide the summary data.

For details on the result output refer to

CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult[:CURRent]?

The numeric suffix <1|2> at CALCulate specifies the measurement window.

Example

CALC2:MARK:FUNC:POW:RES:MAXH?

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CALCulate<1|2>:MARKer<1>:FUNCtion:ZOOM

This command defines the ratio to be zoomed around the marker 1 in the selected

measurement window. The default value is 1, where the full trace is shown.

This command is only available for the following result displays:

–Constellation vs Carrier

–Constellation vs Symbol

–PVT Full Burst

–PVT Rising / Falling

–Magnitude Capture Buffer

Parameter

1to 1000000

Example

CALC:MARK:FUNC:ZOOM 2

Zooms 50% in screen A.

CALC:MARK:FUNC:ZOOM 4

Zooms 25% in screen A.

CALC:MARK:FUNC:ZOOM 1

Deactivates zooming in screen A.

Characteristics

RST value: 1

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.783 E-11

CONFigure Subsystem (WiMAX, K92/K93)

The CONFigure subsystem contains commands for configuring complex measurement tasks. The

CONFigure subsystem is closely linked to the functions of the FETCH subsystem, where the

measurement results are queried.

Commands of the CONFigure Subsystem

–CONFigure:BURSt:BSTReam:BURSt:SELect

–CONFigure:BURSt:BSTReam:FORMat:SELect

–CONFigure:BURSt:BSTReam:SYMBol:SELect

–CONFigure:BURSt:CONSt:BURSt:SELect

–CONFigure:BURSt:CONSt:CARRier:SELect

–CONFigure:BURSt:CONSt:CCARrier[:IMMediate]

–CONFigure:BURSt:CONSt:CSYMbol[:IMMediate]

–CONFigure:BURSt:CONSt:FORMat:SELect

–CONFigure:BURSt:CONSt:SYMBol:SELect

–CONFigure:BURSt:EVM:ECARrier[:IMMediate]

–CONFigure:BURSt:EVM:ESYMbol[:IMMediate]

–CONFigure:BURSt:PREamble[:IMMediate]

–CONFigure:BURSt:PREamble:SELect

–CONFigure:BURSt:PVT[:IMMediate]

–CONFigure:BURSt:PVT:BURSt

–CONFigure:BURSt:PVT:SELect

–CONFigure:BURSt:SPECtrum:ACPR[:IMMediate]

–CONFigure:BURSt:SPECtrum:ACPR:SELect

–CONFigure:BURSt:SPECtrum:FFT[:IMMediate]

–CONFigure:BURSt:SPECtrum:FLATness[:IMMediate]

–CONFigure:BURSt:SPECtrum:FLATness:SELect

–CONFigure:BURSt:SPECtrum:MASK[:IMMediate]

–CONFigure:BURSt:SPECtrum:MASK:SELect

–CONFigure:BURSt:STATistics:BSTReam[:IMMediate]

–CONFigure:BURSt:STATistics:BSUMmary[:IMMediate]

–CONFigure:BURSt:STATistics:CCDF[:IMMediate]

–CONFigure:CHANnel

–CONFigure:POWer:AUTO

–CONFigure:POWer:AUTO:SWEep:TIME

–CONFigure:POWer:EXPected:RF

–CONFigure:STANdard

–CONFigure:WIMax:AVERaging

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.784 E-11

–CONFigure:WIMax:DLSFrame:IDCell

–CONFigure:WIMax:DLSFrame:PREamble:MOD

–CONFigure:WIMax:DLSFrame:PREamble:INDex

–CONFigure:WIMax:DLSFrame:SEGMent<1…3>

–CONFigure:WIMax:FBANd

–CONFigure:WIMax:IGRatio

–CONFigure:WIMax:LMODe

–CONFigure:WIMax:NFFT

–CONFigure:WIMax:TDDFrame:TTG

–CONFigure:WIMax:ULSFrame:FRAMe

–CONFigure:WIMax:ZONE<1…26>[:ANALyze]:STATe

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:CONTrol[:DATA]

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:COUNt?

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:DELete

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:FORMat

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:OFFSet:AUTO

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:POWer

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:SLOT:DURation

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:SUBChannel:COUNt

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:SUBChannel:OFFSet

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:SYMBol:COUNt

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:SYMBol:OFFSet

–CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:TYPE

–CONFigure:WIMax:ZONE<1…26>:CONTrol[:DATA]

–CONFigure:WIMax:ZONE<1…26>:COUNt?

–CONFigure:WIMax:ZONE<1…26>:DELete

–CONFigure:WIMax:ZONE<1…26>:IDSegment

–CONFigure:WIMax:ZONE<1…26>:PERMbase

–CONFigure:WIMax:ZONE<1…26>:PRBS

–CONFigure:WIMax:ZONE<1…26>:SYMB:COUNt

–CONFigure:WIMax:ZONE<1…26>:SYMB:OFFSet

–CONFigure:WIMax:ZONE<1…26>:TYPE

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.785 E-11

CONFigure:BURSt:BSTReam:BURSt:SELect

This command selects bursts and pilots. It is only available if the Bitstream measurement is

selected (see CONFigure:BURSt:STATistics:BSTReam[:IMMediate] command). (K93)

Parameter

0to 9999 burst number

ALL all bursts

PILOTS only pilots

Example

CONF:BURS:STAT:BSTR

Configures the Bitstream measurement type.

CONF:BURS:BSTR:BURS:SEL 1

Selects burst 1.

INIT

Starts a Bitstream measurement. The results of the selected burst (1) are calculated.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:BURSt:BSTReam:FORMat:SELect

This command selects the modulation format. It is only available if the Bitstream measurement

is selected (see CONFigure:BURSt:STATistics:BSTReam[:IMMediate] command).

Parameter

ALL |QPSK | QAM16 | QAM64

Example

CONF:BURS:STAT:BSTR

Configures the Bitstream measurement type.

CONF:BURS:BSTR:FORM:SEL QPSK

Selects the QPSK modulation formats.

INIT

Starts a Bitstream measurement. The results of the selected modulation formats (QPSK) are

calculated.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.786 E-11

CONFigure:BURSt:BSTReam:SYMBol:SELect

This command selects the symbol. It is only available if the Bitstream measurement is selected

(see CONFigure:BURSt:STATistics:BSTReam[:IMMediate] command).

Parameter

0to 9999 symbol number

ALL all symbols

Example

CONF:BURS:STAT:BSTR

Configures the Bitstream measurement type.

CONF:BURS:BSTR:SYMB:SEL 1

Selects symbol 1.

INIT

Starts a Bitstream measurement. The results of the selected symbol (1) are calculated.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:BURSt:CONSt:BURSt:SELect

This command selects bursts and pilots. It is only available if the Constellation vs Symbol

measurement is selected (see CONFigure:BURSt:CONSt:CSYMbol[:IMMediate]

command).

Parameter

0to 9999 burst number

ALL all bursts

PILOTS only pilots

Example

CONF:BURS:CONS:CSYM

Configures the Constellation vs Symbol measurement type.

CONF:BURS:CONS:BURS:SEL 1

Selects burst 1.

INIT

Starts a Constellation vs Symbol measurement. The results of the selected burst (1) are

calculated.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.787 E-11

CONFigure:BURSt:CONSt:CARRier:SELect

This command selects carriers and pilots. It is only available if the Constellation vs Symbol

measurement is selected (see CONFigure:BURSt:CONSt:CSYMbol[:IMMediate]

command).

Parameter

–100 to 100 carrier number

ALL all carriers

PILOTS only pilots

Example

CONF:BURS:CONS:CSYM

Configures the Constellation vs Symbol measurement type.

CONF:BURS:CONS:CARR:SEL –26

Carrier –26 is selected.

INIT

Starts a Constellation vs Symbol measurement. The results of the selected carrier (–26) are

calculated.

Characteristics

RST value: ALL

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:CONSt:CCARrier[:IMMediate]

This command configures the Constellation vs Carrier measurement type.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:CONS:CCAR

Configures the Constellation vs Carrier measurement type.

INIT

Starts a Constellation vs Carrier measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.788 E-11

CONFigure:BURSt:CONSt:CSYMbol[:IMMediate]

This command configures the Constellation vs Symbol measurement type.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:CONS:CSYM

Configures the Constellation vs Symbol measurement type.

INIT

Starts a Constellation vs Symbol measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:CONSt:FORMat:SELect

This command selects the modulation format. It is only available if the Constellation vs Symbol

measurement is selected (see CONFigure:BURSt:CONSt:CSYMbol[:IMMediate]

command).

Parameter

ALL |QPSK | QAM16 | QAM64

Example

CONF:BURS:CONS:CSYM

Configures the Constellation vs Symbol measurement type.

CONF:BURS:CONS:FORM:SEL QPSK

Selects the QPSK modulation formats.

INIT

Starts a Constellation vs Symbol measurement. The results of the selected modulation formats

(QPSK) are calculated.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:BURSt:CONSt:SYMBol:SELect

This command selects the symbol. It is only available if the Constellation vs Symbol

measurement is selected (see CONFigure:BURSt:CONSt:CSYMbol[:IMMediate]

command).

Parameter

0to 9999 symbol number

ALL all symbols

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.789 E-11

Example

CONF:BURS:CONS:CSYM

Configures the Constellation vs Symbol measurement type.

CONF:BURS:CONS:SYMB:SEL 1

Selects symbol 1.

INIT

Starts a Constellation vs Symbol measurement. The results of the selected symbol (1) are

calculated.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:BURSt:EVM:ECARrier[:IMMediate]

This command configures the EVM vs Carrier measurement type.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:EVM:ECAR

Configures the EVM vs Carrier measurement type.

INIT

Starts a EVM vs Carrier measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:EVM:ESYMbol[:IMMediate]

This command configures the EVM vs Symbol measurement type.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:EVM:ESYM

Configures the EVM vs Symbol measurement type.

INIT

Starts a EVM vs Symbol measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.790 E-11

CONFigure:BURSt:PREamble[:IMMediate]

This command configures the Phase or Frequency vs Preamble measurement type. The

selection between the both measurements is made via the

CONFigure:BURSt:PREamble:SELect command.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:PRE

Configures the Phase or Frequency vs Preamble measurement type.

CONF:BURS:PRE:SEL FREQ

The measurement results are interpreted as Frequency Error vs Preamble.

INIT

Starts a Frequency Error vs Preamble measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:PREamble:SELect

This command configures the interpretation of the preamble measurement results.

Parameter

PHASe | FREQuency

Example

CONF:BURS:PRE

Configures the Phase or Frequency vs Preamble measurement type.

CONF:BURS:PRE:SEL FREQ

The measurement results are interpreted as Frequency Error vs Preamble.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:PVT[:IMMediate]

This command configures the Power vs Time (PVT) measurement type. For further settings of

the Power vs Time measurement see the CONFigure:BURSt:PVT:BURSt and

CONFigure:BURSt:PVT:SELect commands.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:PVT

Configures the Power vs Time measurement type.

INIT

Starts a Power vs Time measurement.

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.791 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:PVT:BURSt

This command specifies the burst that is used for the Power vs Time measurement results.

Parameter

1to 10922

Example

CONF:BURS:PVT

Configures the Power vs Time measurement type.

CONF:BURS:PVT:BURS 1

Uses burst 1 for the Power vs Time measurement results.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM

CONFigure:BURSt:PVT:SELect

This command configures the interpretation of the Power vs Time (PVT) measurement results.

The available measurement types depend on the selected standard.

Parameter

FULL PVT Start and End OFDM

PVT Rsing / Falling OFDMA/WiBro

EDGE PVT Full Burst OFDM

PVT Full Subframe OFDMA/WiBro

Example

CONF:BURS:PVT

Configures the Power vs Time measurement type.

CONF:BURS:PVT:SEL FULL

The measurement results are interpreted as full burst.

Characteristics

RST value: FULL

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.792 E-11

CONFigure:BURSt:SPECtrum:ACPR[:IMMediate]

This command configures the ACPR (adjacent channel power relative) measurement type.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:SPEC:ACPR

Configures the ACPR measurement type.

INIT

Starts an ACPR measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:SPECtrum:ACPR:SELect

This command specifies the type of ACP measurement to be performed.

Parameter

ABSolute | RELative

Example

CONF:BURS:SPEC:ACPR:SEL ABS

Specifies the ACP measurement type absolute.

Characteristics

RST value: REL

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:SPECtrum:FFT[:IMMediate]

This command configures the FFT (Fast Fourier Transform) measurement type.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:SPEC:FFT

Configures the FFT measurement type.

INIT

Starts an FFT measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.793 E-11

CONFigure:BURSt:SPECtrum:FLATness[:IMMediate]

This command configures the Spectrum Flatness measurement type. For settings for the

Spectrum Flatness measurement see CONFigure:BURSt:SPECtrum:FLATness:SELect

command.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:SPEC:FLAT

Configures the Spectrum Flatness measurement type.

INIT

Starts a Spectrum Flatness measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:SPECtrum:FLATness:SELect

This command configures the interpretation of the Spectrum Flatness measurement results.

Parameter

FLATness spectrum flatness

GRDelay group delay

DIFFerence flatness difference

Example

CONF:BURS:SPEC:FLAT

Configures the Spectrum Flatness measurement type.

CONF:BURS:SPEC:FLAT:SEL GRD

Configures the group delay for the Spectrum Flatness measurement.

Characteristics

RST value: FLAT

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:SPECtrum:MASK[:IMMediate]

This command configures the Spectrum Mask measurement type. For settings for the Spectrum

Mask measurement see CONFigure:BURSt:SPECtrum:MASK:SELect command.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:SPEC:MASK

Configures the Spectrum Mask measurement type.

INIT

Starts a Spectrum Mask measurement.

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.794 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:SPECtrum:MASK:SELect

This command configures the interpretation of the Spectrum Mask measurement results..

Parameter

IEEE interpretation according to IEEE standard

ETSI interpretation according to ETSI standard

Example

CONF:BURS:SPEC:MASK

Configures the Spectrum Mask measurement type.

CONF:BURS:SPEC:MASK:SEL ETSI

The measurement results are interpreted using the ETSI standard.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:STATistics:BSTReam[:IMMediate]

This command configures the Bitstream measurement type.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:STAT:BSTR

Configures the Bitstream measurement type.

INIT

Starts a Bitstream measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.795 E-11

CONFigure:BURSt:STATistics:BSUMmary[:IMMediate]

This command configures the Burst Summary measurement type.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:STAT:BSUM

Configures the Burst Summary measurement type.

INIT

Starts a the Burst Summary measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:BURSt:STATistics:CCDF[:IMMediate]

This command configures the CCDF (conditional cumulative distribution functions)

measurement type.

This command is an event and therefore has no *RST value and no query.

Example

CONF:BURS:STAT:CCDF

Configures the CCDF measurement type.

INIT

Starts a CCDF measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:CHANnel

This command specifies the measurement input channel. This command will automatically

cause the internal measurement frequency to be recalculated.

Parameter

0to 3153

Example

CONF:CHAN 9

Defines the frequency of channel 9 as measurement range.

Characteristics

RST value: 0

SCPI: device–specific

Mode

OFDM

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.796 E-11

CONFigure:POWer:AUTO

This command switches on or off the automatic power level detection.

Parameter

ON | OFF | ONCE

Example

CONF:POW:AUTO ON

At the start of every measurement sweep the input power level is detected automatically.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:POWer:AUTO:SWEep:TIME

This command specifies the sweep time for the automatic power level detection.

Parameter

1ms to 1s

Example

CONF:POW:AUTO ON

At the start of every measurement sweep the input power level is detected automatically.

CONF:POW:AUTO:SWE:TIME 200MS

The sweep time is set to 200 ms power level.

Characteristics

RST value: 100 ms

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:POWer:EXPected:RF

This command specifies the input power level of the source signal that will be supplied at the

analyzer RF input.

Parameter

–999.99 dBm to 999.99 dBm

Example

CONF:POW:EXP:RF –20

Assumes an input signal strength of –20 dBm.

Characteristics

RST value: –30 dBm

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.797 E-11

CONFigure:STANdard

This command specifies the Wireless LAN standard to be measured.

Parameter

0IEEE 802.16–2004 OFDM

1IEEE 802.16e–2005 OFDMA

2IEEE 802.16e–2005 WiBro

Example

CONF:STAN 0

The measurements will be performed according to IEEE 802.16–2004.

Characteristics

RST value: 1

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:WIMax:AVERaging

This command specifies the RSSI, CINR averaging parameter.

Parameter

0.000001 to 0.999999

Example

CONF:WIM:AVER 0.1

Sets the value to 0.1

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:DLSFrame:IDCell

This command specifies the downlink IDCell number. The downlink IDCell number is used as

DL_PermBase parameter for the permutation equations to partly set the sub carrier randomizer

initialization vector.

Parameter

0to 31

Example

CONF:WIM:DLSF:IDC 0

Sets the downlink IDCell number to 0.

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.798 E-11

Characteristics

RST value: 0

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:DLSFrame:PREamble:MODE

This command specifies how the preamble index is calculated.

Parameter

AUTO The preamble index is automatically calculated according to the parameters set by

the CONFigure:WIMax:DLSFrame:IDCell and

CONFigure:WIMax:DLSFrame:SEGMent<1…3> commands.

USER The preamble index can be specified manually, i.e. the preamble pattern is chosen

by the CONFigure:WIMax:DLSFrame:PREamble:INDex command according to

the standard.

Example

CONF:WIM:DLSF:PRE:MODE AUTO

Activates the automatic calculation of the preamble index.

Characteristics

RST value: USER

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:DLSFrame:PREamble:INDex

This command specifies the preamble pattern (according to the standard) to be used.

Parameter

integer from 0 to 113

Example

CONF:WIM:DLSF:PMOD USER

Deactivates the automatic calculation of the preamble index.

CONF:WIM:DLSF:PRE:IND 31

Specifies the preamble pattern.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.799 E-11

CONFigure:WIMax:DLSFrame:SEGMent<1…3>

This command specifies the allowable logical subchannel usage of the transmission spectrum

for one of the three downlink PUSC segments.

Note that the indexes specified on the instrument are 0, whereas based under remote control

they are 1 based. This means, the first segment on the instrument is labeled segment 0 and

would be accessed with the command CONF:WIM:DLSF:SEGM1.

Parameter

0to 63

Example

CONF:WIM:DLSF:SEGM1 63

Specifies the logical subchannel usage of the transmission spectrum for the first downlink PUSC

segment to 63.

Characteristics

RST value: 0

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:FBANd

This command configures the Phase or Frequency vs Preamble measurement type.

Parameter

The suffix 1 can be omitted in the input (see list below) and is omitted in the output (see

example).

Selection Value Range in GHz Description

UNSPecified Unspecified

ETSI or ETSI1 ETSI 3.410–4.200 Licensed Band

ETSI2 ETSI 10.000–10.680 Licensed Band

MMDS or MMDS1 MMDS 2.150–2.162 Licensed Band

MMDS2 MMDS 2.500–2.690 Licensed Band

WCS or WCS1 WCS 2.305–2.320 Licensed Band

WCS2 WCS 2.345–2.360 Licensed Band

CEPT or CEPT1 CEPT 5.470–5.725 License Exempt Band

CEPT2 CEPT 5.725–5.875 License Exempt Band

UNII or UNII1 U–NII 5.250–5.350 License Exempt Band

UNII2 U–NII 5.725–5.825 License Exempt Band

Example

CONF:WIM:FBAN ETSI

Configures the frequency band to be ETSI 3.41GHz – 4.2GHz.

CONF:WIM:FBAN?

After frequency band is set to ETSI this will return "ETSI'' as the current frequency band.

CONF:WIM:FBAN ETSI1

Configures the frequency band to be ETSI 3.41GHz – 4.2GHz.

CONF:WIM:FBAN?

After frequency band is set to ETSI1 this will return "ETSI'' as the current frequency band.

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.800 E-11

CONF:WIM:FBAN ETSI2

Configures the frequency band to be ETSI 10.0GHz – 10.68GHz.

CONF:WIM:FBAN?

After frequency band is set to ETSI2 this will return "ETSI2'' as the current frequency band.

INIT

Starts a Phase or Frequency vs Preamble measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:WIMax:IGRatio

This command specifies the number of guard samples.

Parameter

valid range: 

T{1/32, 1/16, 1/8, 1/4}

The ration can be set to one of four values – 4, 8, 16 or 32. The table below shows the

relationship between these values and the number of guard samples.

Value Guard samples (T

g/Tb)

41/4

81/8

16 1/16

32 1/32

Example

CONF:WIM:IGR 16

Sets the number of guard samples to 1/16.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:WIMax:LMODe

This command specifies only to analyze the Down Link or Up Link bursts during a

measurement.

Parameter

UL | DL

Example

CONF:WIM:LMOD UL

Only the Up Link bursts are analyzed.

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.801 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

CONFigure:WIMax:NFFT

This command specifies the current FFT size.

Parameter

FFT128 FFT size of 128 carriers

FFT512 FFT size of 512 carriers

FFT1024 FFT size of 1024 carriers

FFT2048 FFT size of 2048 carriers

Example

CONF:WIM:NFFT FFT2048

Sets the FFT size to 2048 carriers.

Characteristics

RST value: FFT1024

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:TDDFrame:TTG

This command specifies the TDD frame TX Transition Gap (TTG).

Parameter

0to 2 seconds

Example

CONF:WIM:TDDF:TTG 10us

Specifies the TDD frame TX Transition Gap as 10 Us.

Characteristics

RST value: 5us

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.802 E-11

CONFigure:WIMax:ULSFrame:FRAMe

This command selects the frame number of the uplink frame in which the UL map that specifies

the uplink burst was transmitted.

Parameter

0to 10

Example

CONF:WIM:ULSF:FRAM 0

Selects frame number 0.

Characteristics

RST value: 0

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>[:ANALyze]:STATe

This command sets a zone for analysis. This will come into effect when the next measurement

is executed.

Parameter

ON | OFF

Example

CONF:WIM:ZONE1:ANAL ON

Sets zone 1 for analysis.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:CONTrol[:DATA]

This command associates a burst definition with a specific zone. A zone may have up to 32

bursts defined within it.

New bursts can only be appended to the end of the existing burst list. For example if 4 bursts

are already defined, then the suffix required to enter a new burst is 5.

Parameter

<Modulation>,<Subchannels>,<Symbols>,<Slot Duration>,<Subchannel Offset>,<Symbol

Offset>,<Burst Power>,<Burst Type>, with:

<Modulation> QPSK_1_2 | QPSK_3_4 |

QAM16_1_2 | QAM16_3_4 |

QAM64_1_2 | QAM64_2_3 |

QAM64_3_4

modulation scheme

<Subchannels> <numeric_value> number of subchannels used by the burst

<Symbols> <numeric_value> number of symbols used by the burst

<Slot Duration> <numeric_value> slot duration (only applies to uplink and ignored by

downlink bursts)

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.803 E-11

<Subchannel

Offset>

<numeric_value> subchannel offset of the burst

<Symbol Offset> <numeric_value> symbol offset of the burst

<Burst Power> <numeric_value> Defines the boosting power of the burst.

<Burst Type> FCH | DLMAP | ULMAP | DATA burst type

For further details refer to chapter "Instrument Functions", section "WiMAX, WiBro

Measurements (Options K92/K93)", Burst List description.

Example

CONF:WIM:ZONE1:BURS1:CONT QAM16_1_2,1D2,5,10,20,0,0,0, DATA

Defines a 16 QAM 1/2 burst using 5 subchannels and 10 symbols.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:COUNt?

This command returns the current count of user defined bursts within the specified zone.

This command is only a query and therefore has no *RST value.

Example

CONF:WIM:ZONE1:BURS1:COUN?

Returns the user defined bursts within zone 1.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:DELete

This command deletes a specific burst from within the specified zone.

Example

CONF:WIM:ZONE1:BURS1:DEL

Deletes burst 1 from zone 1.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.804 E-11

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:FORMat

This command specifies the burst modulation format for the specified zone.

Parameter

QPSK1D2 QPSK code rate 1/2

QPSK3D4 QPSK code rate 3/4

QAM16_1D2 16 QAM code rate 1/2

QAM16_3D4 16 QAM code rate 3/4

QAM64_1D2 64 QAM code rate 1/2

QAM64_2D3 64 QAM code rate 2/3

QAM64_3D4 64 QAM code rate 3/4

Example

CONF:WIM:ZONE1:BURS1:FORM QAM64_3D4

Sets the burst modulation format to QAM64_3D4.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:OFFSet:AUTO

This command allows, for the specified zone and burst, the logical subchannel and symbol

offsets to be automatically calculated so that they are contiguous. The command only applies to

uplink bursts.

Parameter

ON | OFF

Example

CONF:WIM:ZONE1:BURS1:OFFS:AUTO ON

Activates the automatic calculation of the logical subchannel and symbol offsets.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.805 E-11

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:POWer

This command specifies, for the specified zone and burst, the boosting power associated with

the burst.

Parameter

–80 to 10

Example

CONF:WIM:ZONE1:BURS1:POW 0

Sets the boosting power associated with the burst to 0.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:SLOT:DURation

This command defines, for the specified zone and burst, the duration of an uplink burst in slots

in seconds. The command has no effect on downlink bursts.

Parameter

1to 3000

Example

CONF:WIM:ZONE1:BURS1:SLOT:DUR 10

Sets the duration of uplink burst 1 to 10.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:SUBChannel:COUNt

This command defines, for the specified zone and burst, the number of logical subchannels

used by the burst.

Parameter

1to 60

Example

CONF:WIM:ZONE1:BURS1:SUBC:COUN 5

Sets the number of logical subchannels used by burst 1 to 5.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.806 E-11

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:SUBChannel:OFFSet

This command defines, for the specified zone and burst, the logical subchannels offset for the

burst. This, together with the symbol offset, can be used to specify the frequency bandwidth in

use by specific bursts.

Parameter

0to 60

Example

CONF:WIM:ZONE1:BURS1:SUBC:OFFS 5

Sets the subchannels offset for burst 1 to 5.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:SYMBol:COUNt

This command defines, for the specified zone and burst, the number of symbols used by the

burst.

Parameter

1to 1000

Example

CONF:WIM:ZONE1:BURS1:SYMB:COUN 5

Sets the number of symbols used by burst 1 to 5.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:SYMBol:OFFSet

This command defines, for the specified zone and burst, the symbol offset for the burst. This,

together with the logical subchannel offset, can be used to specify the frequency bandwidth in

use by specific bursts.

Parameter

0to 1000

Example

CONF:WIM:ZONE1:BURS1:SYMB:OFFS 5

Sets the symbol offset for burst 1 to 5.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.807 E-11

CONFigure:WIMax:ZONE<1…26>:BURSt<1...32>:TYPE

For the specified zone and burst, this command specifies the type of burst from the protocol

layer perspective, i.e. if the burst contains signaling information or if it is just a data burst.

Parameter

FCH frame control header

DLMAP downlink map

ULMAP uplink map

DATA data burst

Example

ONF:WIM:ZONE1:BURS1:TYPE DATA

Burst 1 is a data burst.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:CONTrol[:DATA]

This command adds a new zone. Up to 26 user zones can be defined.

New zones can only be appended to the end of the existing defined zones. For example, if 4

zones are already defined, then the suffix required to enter a new zone is 5.

Parameter

with:

<Analyze> ON | OFF Specifies whether the zone is too be marked for analysis.

<Type> DLFUSC | DLPUSC | ULPUSC zone type: downlink FUSC (Fully Used Subchanneliziation)

zone, downlink PUSC (Partial Used Subchanneliziation)

zone, or uplink PUSC zone

<Segment> 0 | 1 | 2 downlink PUSC zone segment

<Length> <numeric_value> zone symbol length

<Offset> <numeric_value> zone symbol offset

<Permbase> <numeric_value> permbase to be used for channel decoding

<PRBS_ID> <numeric_value> PRBS to be used for channel decoding

For further details refer to chapter "Instrument Functions", "WiMAX, WiBro Measurements

(Options K92/K93)", Zone/Segment List description.

Example

CONF:WIM:ZONE1:CONT ON,DLFUSC,0,10,0,0,0

Adds a DL_PUSC zone with a length of 10 symbols.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.808 E-11

CONFigure:WIMax:ZONE<1…26>:COUNt?

This command returns the current count of the specified zone.

This command is only a query and therefore has no *RST value.

Example

CONF:WIM:ZONE1:COUN?

Returns the count of zone 1.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:DELete

This command deletes a specific zone. If the specified zone is within a larger list of zones, then

all following zones will be shuffled down to take up the space occupied by the deleted zone.

This command is an event and therefore has no *RST value and no query.

Example

CONF:WIM:ZONE1:DEL

Deletes zone 1.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:IDSegment

This command specifies the segment number associated with the zone. This is only valid for

PUSC zones and will have no effect on other zone types.

Parameter

0 | 1 | 2

Example

CONF:WIM:ZONE1:IDS 0

Sets the segment number for zone 1 to 0.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

R&S FSL CONFigure Subsystem (WiMAX, K92/K93)

1300.2519.12 6.809 E-11

CONFigure:WIMax:ZONE<1…26>:PERMbase

This command specifies the perm base which is used in the permutation equations for the

specified zone.

Parameter

0to 31

Example

CONF:WIM:ZONE1:PERM 0

For zone 1, perm base 0 is used in the permutation equations.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:PRBS

This command specifies a known PRBS (pseudo random binary sequence) modulated data

sequence that is in use by the DUT of the specified zone.

Parameter

0, 1, 2, 3

Example

CONF:WIM:ZONE1:PRBS 0

Sets the PRBS to 0.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:SYMB:OFFSet

This command specifies the symbol offset associated with the specified zone. This is used to

analyze signals which contain multiple zones and allows any zone in a subframe to be set up for

analysis.

Parameter

1to 1000

Example

CONF:WIM:ZONE1:SYMB:OFFS 0

Sets the symbol offset for zone 1 to 0.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.810 E-11

CONFigure:WIMax:ZONE<1…26>:SYMB:COUNt

This command specifies the number of symbols defined to the specified zone.

Parameter

1to 1000

Example

CONF:WIM:ZONE1:SYMB:COUNT 10

Sets the number of symbols for zone 1 to 10.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

CONFigure:WIMax:ZONE<1…26>:TYPE

This command specifies the zone type of the specified zone.

Parameter

DLFUSC downlink FUSC zone

DLPUSC downlink PUSC zone

ULPUSC uplink PUSC zone

Example

CONF:WIM:ZONE1:TYPE DLPUSC

Specifies zone 1 as downlink PUSC zone.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

R&S FSL DISPlay Subsystem (WiMAX, K92/K93)

1300.2519.12 6.811 E-11

DISPlay Subsystem (WiMAX, K92/K93)

The DISPlay subsystem controls the selection and presentation of textual and graphic information as

well as of measurement data on the display. In contrast to the base unit, the WiMAX IEEE 802.16

OFDM, OFDMA Measurements option supports the split screen modus.

Commands of the DISPlay Subsystem

–DISPlay:FORMat

–DISPlay[:WINDow<1|2>]:SELect

–DISPlay[:WINDow<1|2>]:SSELect

–DISPlay[:WINDow<1|2>]:TABLe

–DISPlay[:WINDow<1|2>]:TABLe:UNIT

–DISPlay[:WINDow<1|2>]:TRACe1:Y[:SCALe]:AUTO

–DISPlay[:WINDow<1|2>]:TRACe1:Y[:SCALe]:PDIVision

–DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel[:RF]

–DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel?

–DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel:OFFSet

DISPlay:FORMat

This command sets the screen display type to full or split screen.

Parameter

SPLit | SINGle

Example

DISP:FORM SING

Sets the display to full screen.

Characteristics

RST value: SPLit

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

DISPlay[:WINDow<1|2>]:SELect

This command selects whether screen A or screen B is active (see also

DISPlay[:WINDow<1|2>]:SSELect)

Example

DISP:WIND1 SEL

Sets screen A active.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

DISPlay Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.812 E-11

DISPlay[:WINDow<1|2>]:SSELect

This command selects whether screen A or screen B is active. The numeric suffix <1|2> defines

the active window.

Example

DISP:WIND1:SSEL

Sets screen A active.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

DISPlay[:WINDow<1|2>]:TABLe

This command shows or hides the results table.

The numeric suffix <1|2> defines the active window.

Parameter

ON | OFF

Example

DISP:TABL OFF

Hides the results table.

Characteristics

RST value: OFF

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

DISPlay[:WINDow<1|2>]:TABLe:UNIT

This command specifies the unit for the parameters listed in the results table.

The numeric suffix <1|2> defines the active window.

Parameter

DB results returned in dB

PCT results returned in percent

Example

DISP:TABL:UNIT DB

Results are returned in dB.

Characteristics

RST value: DB

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL DISPlay Subsystem (WiMAX, K92/K93)

1300.2519.12 6.813 E-11

DISPlay[:WINDow<1|2>]:TRACe1:Y[:SCALe]:AUTO

This command switches on or off automatic scaling of the y–axis for trace 1. If switched on, the

y–axis is scaled to best fit the measurement results automatically.

The numeric suffix <1|2> defines the active window.

This command is only available for the following result displays:

–EVM vs Carrier

–EVM vs Symbol

Parameter

ON | OFF

Example

DISP:WIND2:TRAC1:Y:AUTO ON

Switches on automatic scaling of the y–axis for the active trace.

Characteristics

RST value: ON

SCPI: conform

Mode

OFDM, OFDMA/WiBro

DISPlay[:WINDow<1|2>]:TRACe1:Y[:SCALe]:PDIVision

This command sets the size of each y scale division for trace 1. It has no affect if automatic

scaling of the y–axis is enabled.

The numeric suffix <1|2> defines the active window.

This command is only available for the following result displays:

–EVM vs Carrier

–EVM vs Symbol

Parameter

1E–6 to 10E12

Example

DISP:WIND2:TRAC1:Y:AUTO OFF

Switches off automatic scaling of the y–axis for the active trace.

DISP:WIND2:TRAC1:Y:PDIV 2

Sets the y scale division to size 2.

Characteristics

RST value: 3

SCPI: conform

Mode

OFDM, OFDMA/WiBro

DISPlay Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.814 E-11

DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel[:RF]

This command specifies the reference level applied to an RF measurements.

The numeric suffixes of WINDow<1|2> and TRACe<1 to 3> are irrelevant.

Parameter

<numeric_value> in dBm, range specified in data sheet

Example

DISP:TRAC:Y:RLEV 10

Reference level of the analyzer is 10 dB

DISP:TRAC:Y:RLEV:RF –10

Reference level of the analyzer is –10 dB

Characteristics

RST value: 0 dB

SCPI: conform

Mode

OFDM, OFDMA/WiBro

DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel?

This command queries the current internal instrument reference level used when performing

measurements.

The numeric suffixes of WINDow<1|2> and TRACe<1 to 3> are irrelevant.

This command is only a query and therefore has no *RST value.

Example

DISP:TRAC:Y:RLEV?

Returns the current reference level in use.

Characteristics

RST value: –

SCPI: conform

Mode

OFDM, OFDMA/WiBro

R&S FSL DISPlay Subsystem (WiMAX, K92/K93)

1300.2519.12 6.815 E-11

DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel:OFFSet

This command specifies the external attenuation/gain applied to measurements. The value

corresponds to the reference level offset in spectrum analyzer mode (see

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel:OFFSet command).

The numeric suffixes of WINDow<1|2> and TRACe<1 to 3> are irrelevant.

Parameter

–200 to 200 dB

Example

DISP:TRAC:Y:RLEV:OFFS 10

External attenuation (level offset) of the analyzer is 10 dB

DISP:TRAC:Y:RLEV:OFFS –10

External attenuation of the analyzer is –10 dB. i.e. a gain of 10 dB

Characteristics

RST value: 0 dB

SCPI: conform

Mode

OFDM, OFDMA/WiBro

FETCh Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.816 E-11

FETCh Subsystem (WiMAX, K92/K93)

The FETCh subsystem contains commands for reading out results of complex measurement tasks. This

subsystem is closely linked to the CONFigure and SENSe subsystems.

Commands of the FETCh Subsystem

–FETCh:BURSt:ALL?

–FETCh:BURSt:CINR?

–FETCh:BURSt:CINR:AVERage?

–FETCh:BURSt:CINR:MAXimum?

–FETCh:BURSt:CINR:MINimum?

–FETCh:BURSt:COUNt?

–FETCh:BURSt:CRESt:AVERage?

–FETCh:BURSt:CRESt:MAXimum?

–FETCh:BURSt:CRESt:MINimum?

–FETCh:BURSt:EVM:ALL:AVERage?

–FETCh:BURSt:EVM:ALL:MAXimum?

–FETCh:BURSt:EVM:ALL:MINimum?

–FETCh:BURSt:EVM:DATA:AVERage?

–FETCh:BURSt:EVM:DATA:MAXimum?

–FETCh:BURSt:EVM:DATA:MINimum?

–FETCh:BURSt:EVM:PILot:AVERage?

–FETCh:BURSt:EVM:PILot:MAXimum?

–FETCh:BURSt:EVM:PILot:MINimum?

–FETCh:BURSt:FERRor:AVERage?

–FETCh:BURSt:FERRor:MAXimum?

–FETCh:BURSt:FERRor:MINimum?

–FETCh:BURSt:GIMBalance:AVERage?

–FETCh:BURSt:GIMBalance:MAXimum?

–FETCh:BURSt:GIMBalance:MINimum?

– FETCh:BURSt:IQOFfset:AVERage?

–FETCh:BURSt:IQOFfset:MAXimum?

–FETCh:BURSt:IQOFfset:MINimum?

–FETCh:BURSt:QUADoffset:AVERage?

–FETCh:BURSt:QUADoffset:MAXimum?

–FETCh:BURSt:QUADoffset:MINimum?

–FETCh:BURSt:RMS:ALL:AVERage?

–FETCh:BURSt:RMS:ALL:MAXimum?

–FETCh:BURSt:RMS:ALL:MINimum?

R&S FSL FETCh Subsystem (WiMAX, K92/K93)

1300.2519.12 6.817 E-11

–FETCh:BURSt:RMS:AVERage?

–FETCh:BURSt:RMS:DATA:AVERage?

–FETCh:BURSt:RMS:DATA:MAXimum?

–FETCh:BURSt:RMS:DATA:MINimum?

–FETCh:BURSt:RMS:DLPReamble:AVERage?

–FETCh:BURSt:RMS:DLPReamble:MAXimum?

–FETCh:BURSt:RMS:DLPReamble:MINimum?

–FETCh:BURSt:RMS:MAXimum?

–FETCh:BURSt:RMS:MINimum?

–FETCh:BURSt:RMS:PILot:AVERage?

–FETCh:BURSt:RMS:PILot:MAXimum?

–FETCh:BURSt:RMS:PILot:MINimum?

–FETCh:BURSt:RSSI?

–FETCh:BURSt:RSSi:AVERage?

–FETCh:BURSt:RSSi:MAXimum?

–FETCh:BURSt:RSSi:MINimum?

–FETCh:BURSt:SYMBolerror:AVERage?

–FETCh:BURSt:SYMBolerror:MAXimum?

–FETCh:BURSt:SYMBolerror:MINimum?

–FETCh:BURSt:TDOMain:PREamble?

–FETCh:BURSt:TDOMain:SUBFrame?

–FETCh:BURSt:TDOMain:ZONE?

–FETCh:SYMBol:COUNt?

–FETCh:ZONE:COUNt?

Further information

–"ASCII formats for returned values" on page 6.817

ASCII formats for returned values

The results are output as a list of result strings separated by commas.

OFDM results

FETCh Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.818 E-11

OFMDA Uplink results

OFDMA Downlink results

R&S FSL FETCh Subsystem (WiMAX, K92/K93)

1300.2519.12 6.819 E-11

FETCh:BURSt:ALL?

This command returns all the results. The results are output as a list of result strings separated

by commas in ASCII format. For details on the format refer to "ASCII formats for returned

values" on page 6.817. The units for the EVM results are specified with the UNIT:EVM

command.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:ALL?

All calculated results are returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh:BURSt:CINR?

This command returns all the CINR results separated by commas. For details on the format

refer to "ASCII formats for returned values" on page 6.817.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:CINR?

The calculated CINR results from the most recent measurement are returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh:BURSt:CINR:AVERage? / FETCh:BURSt:CINR:MINimum? /

FETCh:BURSt:CINR:MAXimum?

This command returns the determined CINR (carrier to interference and noise ratio) standard

deviation value (average, minimum or maximum value). The result is returned in ASCII format.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:RSS:MAX?

The calculated maximum CINR value is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

FETCh Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.820 E-11

FETCh:BURSt:COUNt?

This command returns the number of bursts analyzed in the last sweep.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:COUN?

The number of analyzed bursts in the most recent measurement is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh:BURSt:CRESt:AVERage? / FETCh:BURSt:CRESt:MAXimum? /

FETCh:BURSt:CRESt:MINimum?

This command returns the determined crest factor (average, minimum or maximum value) in

dBm. The crest factor is the ratio of peak power to average power.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:CRES:MAX?

The calculated maximum crest factor from the most recent measurement is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh:BURSt:EVM:ALL:AVERage? / FETCh:BURSt:EVM:ALL:MAXimum? /

FETCh:BURSt:EVM:ALL:MINimum?

This command returns the Error Vector Magnitude (EVM) measurement results summary

(average, minimum or maximum value) in dB. The results summary is a combined figure that

represents the pilot, data and the free carrier.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:EVM:ALL:MIN?

The minimum Error Vector Magnitude value is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL FETCh Subsystem (WiMAX, K92/K93)

1300.2519.12 6.821 E-11

FETCh:BURSt:EVM:DATA:AVERage? / FETCh:BURSt:EVM:DATA:MAXimum? /

FETCh:BURSt:EVM:DATA:MINimum?

This command returns the Error Vector Management measurement results summary (average,

minimum or maximum value) for the data carrier in dB.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:EVM:DATA:MAX?

The maximum EVM recorded for the data carrier is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh:BURSt:EVM:PILot:AVERage? / FETCh:BURSt:EVM:PILot:MAXimum? /

FETCh:BURSt:EVM:PILot:MINimum?

This command returns the Error Vector Management measurement results summary for the

EVM pilot carrier in dB.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:EVM:PIL:MAX?

The maximum EVM recorded for the EVM pilot carrier is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh:BURSt:FERRor:AVERage? / FETCh:BURSt:FERRor:MAXimum? /

FETCh:BURSt:FERRor:MINimum?

This command returns the measured average, minimum or maximum frequency errors in

Hz.???

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:FERR:MAX?

The maximum frequency error from the most recent measurement is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.822 E-11

FETCh:BURSt:GIMBalance:AVERage? / FETCh:BURSt:GIMBalance:MAXimum? /

FETCh:BURSt:GIMBalance:MINimum?

This command returns the measured average, minimum or maximum IQ imbalance errors in dB.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:GIMB:MAX?

The maximum IQ Imbalance error from the most recent measurement is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh:BURSt:IQOFfset:AVERage? / FETCh:BURSt:IQOFfset:MAXimum? /

FETCh:BURSt:IQOFfset:MINimum?

This command returns the measured average, minimum or maximum IQ offset errors in dB.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:IQOF:MAX?

The maximum IQ Offset error from the most recent measurement is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh:BURSt:QUADoffset:AVERage? / FETCh:BURSt:QUADoffset:MAXimum? /

FETCh:BURSt:QUADoffset:MINimum?

This command returns the accuracy in terms of the phase error of symbols within a burst.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:QUAD:MAX?

The maximum angle error recorded for a symbol during the measurement.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL FETCh Subsystem (WiMAX, K92/K93)

1300.2519.12 6.823 E-11

FETCh:BURSt:RMS:ALL:AVERage? / FETCh:BURSt:RMS:ALL:MAXimum? /

FETCh:BURSt:RMS:ALL:MINimum?

This command returns the average, minimum or maximum RMS burst power in dBm for all

carriers measured during the measurement.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:RMS:ALL:MAX?

The maximum RMS burst power for all carriers recorded during the most recent measurement is

returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM

FETCh:BURSt:RMS:AVERage? / FETCh:BURSt:RMS:MAXimum? /

FETCh:BURSt:RMS:MINimum?

This command returns the average, minimum or maximum RMS burst power in dBm measured

during the measurement.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:RMS:MAX?

The maximum burst power recorded for the most recent measurement is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM

FETCh:BURSt:RMS:DATA:AVERage? / FETCh:BURSt:RMS:DATA:MAXimum? /

FETCh:BURSt:RMS:DATA:MINimum?

This command returns the average, minimum or maximum RMS burst power in dBm for data

carriers measured during the measurement.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:RMS:DATA:MAX?

The maximum RMS burst power for data carriers from the most recent measurement is

returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM

FETCh Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.824 E-11

FETCh:BURSt:RMS:DLPReamble:AVERage? / FETCh:BURSt:RMS:DLPReamble:MAXimum? /

FETCh:BURSt:RMS:DLPReamble:MINimum?

This command returns the average, minimum or maximum RMS burst power in dBm for the

downlink preamble measured during the measurement.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:RMS:DLPR:MAX?

The maximum RMS burst power for the downlink preamble from the most recent measurement

is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM

FETCh:BURSt:RMS:PILot:AVERage? / FETCh:BURSt:RMS:PILot:MAXimum? /

FETCh:BURSt:RMS:PILot:MINimum?

This command returns the average, minimum or maximum RMS burst power in dBm for pilot

carriers measured during the measurement.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:RMS:PIL:MAX?

The maximum RMS burst power for pilot carriers from the most recent measurement is

returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM

FETCh:BURSt:RSSI?

This command returns all the received signal strength indicator (RSSI) results separated by

commas. For details on the format refer to "ASCII formats for returned values" on page 6.817.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:RSSI?

The calculated RSSI results from the most recent measurement is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL FETCh Subsystem (WiMAX, K92/K93)

1300.2519.12 6.825 E-11

FETCh:BURSt:RSSi:AVERage? / FETCh:BURSt:RSSi:MAXimum? /

FETCh:BURSt:RSSi:MINimum?

This command returns the average, minimum or maximum RSSI (received signal strength

indicator) standard deviation value. This is an estimate of the total received power of the frame

preamble of the segment of the connected BS. For details on the format refer to "ASCII formats

for returned values" on page 6.817.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:RSS:MAX?

The maximum RSSI deviation value from the most recent measurement is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh:BURSt:SYMBolerror:AVERage? / FETCh:BURSt:SYMBolerror:MAXimum? /

FETCh:BURSt:SYMBolerror:MINimum?

This command returns the percentage of symbols that were outside permissible demodulation

range within a burst..

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:SYMB:MAX?

The maximum number of symbols that were out of range per burst is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

FETCh:BURSt:TDOMain:PREamble?

This command returns the minimum, average and maximum preamble time domain values. The

result is returned in (ASCII) format.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:TDOM:PRE?

Returns the minimum, average and maximum preamble time domain values.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

FETCh Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.826 E-11

FETCh:BURSt:TDOMain:SUBFrame?

This command returns the minimum, average and maximum subframe time domain values. The

result is returned in (ASCII) format.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:TDOM:SUBF?

Returns the minimum, average and maximum subframe time domain values.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

FETCh:BURSt:TDOMain:ZONE?

This command returns the minimum, average and maximum zone time domain values. The

result is returned in (ASCII) format.

This command is only a query and therefore has no *RST value.

Example

FETC:BURS:TDOM:ZONE?

Returns the minimum, average and maximum zone time domain values.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

FETCh:SYMBol:COUNt?

This command returns the number of symbol in each analyzed burst found in the last

measurement sweep. The results are output as a list of result strings separated by commas in

the following (ASCII) format:

This command is only a query and therefore has no *RST value.

Example

FETC:SYMB:COUN?

The calculated symbols in the analyzed bursts for the most recent measurement are returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL FETCh Subsystem (WiMAX, K92/K93)

1300.2519.12 6.827 E-11

FETCh:ZONE:COUNt?

This command returns the current number of zones found during measurement analysis.

This command is only a query and therefore has no *RST value.

Example

FETC:ZONE:COUN?

The current number of zones found during analysis is returned.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

FORMat Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.828 E-11

FORMat Subsystem (WiMAX, K92/K93)

The FORMat subsystem specifies the data format of the data transmitted from and to the instrument.

Commands of the FORMat Subsystem

–FORMat[:DATA]

FORMat[:DATA]

Parameter

ASCii | REAL| UINT [,8 | 32]

For details refer to the FORMat[:DATA] command description of the base unit on page 6.138.

R&S FSL INITiate Subsystem (WiMAX, K92/K93)

1300.2519.12 6.829 E-11

INITiate Subsystem (WiMAX, K92/K93)

The INITiate subsystem configures the instrument prior to a measurement being carried out. It is

basically used to tell the instrument which measurement is to be performed and takes any necessary

step to set up the instrument for the measurement.

Commands of the INITiate Subsystem

–INITiate[:IMMediate]

–INITiate:CONTinuous

–INITiate:REFResh

INITiate[:IMMediate]

For further details refer to "INITiate<1|2>[:IMMediate]" on page 6.146.

INITiate:CONTinuous

For further details refer to "INITiate<1|2>:CONTinuous" on page 6.147.

INITiate:REFResh

This command updates the current IQ measurement results to reflect the current measurement

settings. Note that no new IQ data is captured, i.e. the measurement settings apply to the IQ

data being currently in the capture buffer. The command applies exclusively to IQ

measurements. It requires available IQ data.

Example

INIT:REFR

Updates the IQ measurement results according to the current settings.

Characteristics

RST value: –

SCPI: conform

Mode

OFDM, OFDMA/WiBro

INPut Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.830 E-11

INPut Subsystem (WiMAX, K92/K93)

The INPut subsystem controls the input characteristics of the RF inputs of the instrument.

Commands of the INPut Subsystem

–INPut:ATTenuation

–INPut:SELect

INPut:ATTenuation

For details refer to "INPut<1|2>:ATTenuation" on page 6.150.

INPut:SELect

This command specifies the RF input as currently selected signal input.

Parameter

Example

INPut:SEL RF

Selects RF input.

Characteristics

RST value: RF

SCPI: conform

Mode

OFDM, OFDMA/WiBro

R&S FSL INSTrument Subsystem (WiMAX, K92/K93)

1300.2519.12 6.831 E-11

INSTrument Subsystem (WiMAX, K92/K93)

The INSTrument subsystem selects the operating mode of the unit either via text parameters or fixed

numbers.

Commands of the INSTrument Subsystem

–INSTrument[:SELect]

–INSTrument:NSELect

INSTrument[:SELect]

Parameter

WiMAX (WiMAX 802.16 OFDM Measurements option and WiMAX IEEE 802.16 OFDM,

OFDMA Measurements option, R&S FSL–K92/K93)

For further details refer to the INSTrument subsystem of the base unit.

INSTrument:NSELect

Parameter

23 (WiMAX 802.16 OFDM Measurements option, R&S FSL–K92)

6(WiMAX IEEE 802.16 OFDM, OFDMA Measurements option, R&S FSL–K92/K93)

For further details refer to the INSTrument subsystem of the base unit.

MMEMory Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.832 E-11

MMEMory Subsystem (WiMAX, K92/K93)

The MMEMory (mass memory) subsystem provides commands to store and load IQ data.

Commands of the MMEMory Subsystem

–MMEMory:LOAD:FRAMe:STATe

–MMEMory:LOAD:IQ:STATe

–MMEMory:STORe:IQ:STATe

MMEMory:LOAD:FRAMe:STATe

This command loads a zone frame setup from the specified *.xml file. This file is created by a

R&S SMU signal generator in accordance to the IEEE 80216e–2005 standard.

Parameter

1,<file_name>

Example

MMEM:STOR:FRAM:STAT 1,'C:\R_S\Instr\user\data.xml'

Loads the zone frame setup from the specified file.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

MMEMory:LOAD:IQ:STATe

This command loads the IQ data from the specified *.iqw file.

Parameter

1,<file_name>

Example

MMEM:LOAD:IQ:STAT 1,'C:\R_S\Instr\user\data.iqw'

Loads IQ data from the specified file.

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL MMEMory Subsystem (WiMAX, K92/K93)

1300.2519.12 6.833 E-11

MMEMory:STORe:IQ:STATe

This command stores the IQ data to the specified *.iqw file.

Parameter

1,<file_name>

Example

MMEM:STOR:IQ:STAT 1,'C:\R_S\Instr\user\data.iqw'

Stores IQ data to the specified file.

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

SENSe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.834 E-11

SENSe Subsystem (WiMAX, K92/K93)

The SENSe command is used to set and get the values of parameters in the remote instrument.

The get variant of the SENSe command differs from set in that it takes no parameter values

(unless otherwise stated) but is followed by the character '?' and will return the parameter's

value in the same format as it is set.

Commands of the SENSe Subsystem

–[SENSe:]BANDwidth:CHANnel

–[SENSe:]BURSt:COUNt

–[SENSe:]BURSt:COUNt:STATe

–[SENSe:]DEMod:CESTimation

–[SENSe:]DEMod:FILTer:CATalog?

–[SENSe:]DEMod:FILTer:MODulation

–[SENSe:]DEMod:FORMat[:BCONtent]:AUTo

–[SENSe:]DEMod:FORMat:BANalyze

–[SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal

–[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MAX

–[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MIN

–[SENSe:]FFT:OFFSet

–[SENSe:]FREQuency:CENTer

–[SENSe:]POWer:ACHannel:ACPairs

–[SENSe:]POWer:ACHannel:BANDwidth|BWIDth[:CHANnel]

–[SENSe:]POWer:ACHannel:BANDwidth|BWIDth:ACHannel

–[SENSe:]POWer:ACHannel:BANDwidth|BWIDth:ALTernate<1|4>

–[SENSe:]POWer:ACHannel:MODE

–[SENSe:]POWer:ACHannel:SPACing[:ACHannel]

–[SENSe:]POWer:ACHannel:SPACing:ALTernate<1|4>

–[SENSe:]POWer:NCORrection

–[SENSe:]POWer:SEM:CLASs

–[SENSe:]POWer:SEM:MODe

–[SENSe:]POWer:SEM:TTA

–[SENSe:]SUBChannel

–[SENSe:]SUBChannel:STATe

–[SENSe:]SUBChannel:ULPHysmod

–[SENSe:]SWAPiq

–[SENSe:]SWEep:ACPR:TIME

–[SENSe:]SWEep:ACPR:TIME:AUTO

–[SENSe:]SWEep:COUNt

–[SENSe:]SWEep:EGATe

R&S FSL SENSe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.835 E-11

–[SENSe:]SWEep:EGATe:HOLDoff[:TIME]

–[SENSe:]SWEep:EGATe:HOLDoff:SAMPle

–[SENSe:]SWEep:EGATe:LENGth[:TIME]

–[SENSe:]SWEep:EGATe:LENGth:SAMPle

–[SENSe:]SWEep:EGATe:LINK

–[SENSe:]SWEep:TIME

–[SENSe:]TRACking:LEVel

–[SENSe:]TRACking:PHASe

–[SENSe:]TRACking:PILot

–[SENSe:]TRACking:TIME

[SENSe:]BANDwidth:CHANnel

This command specifies the channel bandwidth for the signal to be measured. The channel is

selected via the CONFigure:CHANnel command.

Parameter

1.25 MHz to 28 MHz

Example

CONF:CHAN 9

Defines the frequency of channel 9 as measurement range.

BAND:CHAN 7MHZ

Sets a channel bandwidth value of 7 MHz.

Characteristics

RST value: 1.75 MHz

SCPI: conform

Mode

OFDM

[SENSe:]BURSt:COUNt

This command defines the number of bursts that will be analyzed by the measurement.

Parameter

1to 10922

Example

BURS:COUN 16

Sets the number of bursts to 16.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

SENSe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.836 E-11

[SENSe:]BURSt:COUNt:STATe

When this command is set to on, the burst count parameter will be used by the measurement,

otherwise the burst count parameter will be ignored.

Parameter

ON | OFF

Example

BURS:COUN:STAT ON

Sets the burst count state to ON

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]DEMod:CESTimation

This command defines how channel estimation is performed.

IEEE 802.16–2004 OFDM: The improved channel estimation is used for IQ measurements. The

effect of this is most noticeable for the EVM measurement results, where the results will be

improved if this feature is enabled. However, this functionality is not supported by the IEEE

802.16–2004 standard and must be disabled if the results are to be strictly measured against

the standard.

IEEE 802.16e–2005 OFDMA/WiBro: The channel estimation is performed for downlink signals.

Parameter

Standard Parameter Description

IEEE 802.16–2004 OFDM ON Improved channel estimation is performed.

OFF Improved channel estimation is not performed.

IEEE 802.16e–2005 OFDMA PAYLONLY Channel estimation is performed in the payload only.

PREAMONLY Channel estimation is performed in the preamble only.

PREAMPAYL Channel estimation is performed in both the preamble and the

payload.

Example

DEM:CEST ON

Specifies that the IQ measurement results will use improved channel estimation.

Characteristics

*RST value:

IEEE 802.16–2004 OFDM OFF

IEEE 802.16e–2005 OFDMA PREAMPAYL

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL SENSe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.837 E-11

[SENSe:]DEMod:FILTer:CATalog?

This command reads the names of all available filters. The file names are output without file

extension. Syntax of output format: filter_1,filter_2, … ,filter_n.

This command is a query only and thus has no *RST value.

Example

DEM:FILT:CAT?

Reads all filter names

Characteristics

*RST value: 0

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]DEMod:FILTer:MODulation

This command selects the TX and RX filters. The names of the filters correspond to the file

names; a query of all available filters is possible by means of the

[SENSe:]DEMod:FILTer:CATalog? command.

Parameter

DEF_TX: default transmit filter, DEF_RX: default receive filter

Example

DEM:FILT:MOD 'DEF_TX','DEF_RX'

DEF_TX is selected for the TX filter and DEF_RX for the RX filter

Characteristics

*RST value: AUTO,AUTO

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]DEMod:FORMat[:BCONtent]:AUTo

This command specifies how the signal should be demodulated.

Parameter

NONE Demodulation off (Brute force mode), the specified modulation is used for all

bursts.

FIRSt Retrieves the first valid payload modulation and analyzes all bursts with same

modulation.

USER Analyzes all bursts carrying the modulation specified.

ALL Retrieves all bursts individual payload modulation and analyzes accordingly.

Example

DEM:FORM:AUTO FIRS

Specifies that the first symbol field should be decoded.

SENSe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.838 E-11

Characteristics

*RST value: ALL

SCPI: device–specific

Mode

OFDM

[SENSe:]DEMod:FORMat:BANalyze

The remote control command sets the analysis modulation format that will be assumed for the

measurement.

If the standard is IEEE 802.16e–2005 OFDMA or WiBro, this command is query only and

returns the highest detected modulation format from the last measurement sweep.

Parameter

BPSK1/2 BI–Phase shift keying (OFDM only)

QPSK1/2 Quadrature phase shift keying

QPSK3/4 Quadrature phase shift keying

16QAM1/2 Quadrature Amplitude Modulation

16QAM3/4 Quadrature Amplitude Modulation

64QAM2/3 Quadrature Amplitude Modulation

64QAM3/4 Quadrature Amplitude Modulation

Example

DEM:FORM:BAN '16QAM1/2'

Only bursts that are of the QAM16 modulation format are analyzed.

Characteristics

*RST value: 16QAM1/2

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal

If this command is activated only bursts of equal length will take part in the PVT analysis. The

number of symbols that a burst must have in order to take part in the PVT analysis are specified

by the [SENSe:]DEMod:FORMat:BANalyze:SYMBols:MIN command.

Parameter

ON | OFF

Example

DEM:FORM:BAN:SYMB:EQU ON

Only bursts of equal length will take part in the PVT analysis.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

OFDM

R&S FSL SENSe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.839 E-11

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MAX

This command specifies the maximum number of data symbols required for bursts to qualify for

measurement analysis. Only bursts with the specified number of symbols will be used in the

measurement analysis. The number of data symbols is defined as the uncoded bits including

service and tail bits.

This value will not have any immediate effect if the

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal command has been set to ON. In

this case, no range of symbols is allowed and only bursts with exactly the number of symbols

specified by the [SENSe:]DEMod:FORMat:BANalyze:SYMBols:MIN command shall take

place in measurement analysis.

Parameter

1to 2425

Example

DEM:FORM:BAN:SYMB:MAX 1300

Only bursts which contain a maximum symbol count of 1300 are analyzed.

Characteristics

*RST value: 64

SCPI: device–specific

Mode

OFDM

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MIN

This command specifies the number of data symbols required for bursts to qualify for

measurement analysis. Only bursts with the specified number of symbols will be used in the

measurement analysis. The number of data symbols is defined as the uncoded bits including

service and tail bits.

If the [SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal command has been set to ON,

this command specifies the exact number of symbols required for a burst to take part in

measurement analysis. If the [SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal

command is set to OFF, this command specifies the minimum number of symbols required for a

burst to take part in measurement analysis.

Parameter

1to 2425

Example

DEM:FORM:BAN:SYMB:MIN 16

Only bursts which contain a symbol count of 16 are analyzed.

Characteristics

*RST value: 1

SCPI: device–specific

Mode

OFDM

SENSe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.840 E-11

[SENSe:]FFT:OFFSet

This command specifies the FFT start offset relative to the GP centre.

Parameter

–100 to 100

Example

FFT:OFF 0

Sets the FFT start offset to 0.

Characteristics

RST value: 0

SCPI: conform

Mode

OFDMA/WiBro

[SENSe:]FREQuency:CENTer

This command defines the center frequency of the analyzer or the measuring frequency for IQ

measurements.

Characteristics

RST value: 5 GHz

For further details refer to "[SENSe<1|2>:]FREQuency:CENTer" on page 6.200.

[SENSe:]POWer:ACHannel:ACPairs

This command sets the number of adjacent channels pairs (upper and lower channel pairs).

Parameter

0to 3

0stands for pure channel power measurement

Example

POW:ACH:ACP 3

Sets the number of adjacent channels to 3, i.e. the adjacent channel and alternate adjacent

channels 1 and 2 are switched on.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL SENSe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.841 E-11

[SENSe:]POWer:ACHannel:BANDwidth|BWIDth[:CHANnel]

This command sets the channel bandwidth of the system. The bandwidths of adjacent channels

are not influenced by this modification.

Parameter

0Hz to 100 GHz

Example

POW:ACH:BAND 30kHz

Sets the bandwidth of the TX channel to 30 kHz.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]POWer:ACHannel:BANDwidth|BWIDth:ACHannel

This command defines the channel bandwidth of the adjacent channel of the system.

Parameter

0Hz to 100 GHz

Example

POW:ACH:BAND:ACH 30kHz

Sets the bandwidth of the adjacent channel to 30 kHz.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]POWer:ACHannel:BANDwidth|BWIDth:ALTernate<1|4>

This command defines the channel bandwidth of the first to fourth alternate adjacent channel of

the system.

Parameter

0Hz to 100 GHz

Example

POW:ACH:BAND:ALT2 30kHz

Sets the bandwidth of the second alternate adjacent channel to 30 kHz.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

SENSe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.842 E-11

[SENSe:]POWer:ACHannel:MODE

This command sets the ACP measurement mode to either absolute or relative.

Parameter

ABS Absolute measurement

REL Relative measurement

Example

POW:ACH:MODE ABS

Sets the ACP measurement to absolute mode.

Characteristics

*RST value: REL

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]POWer:ACHannel:SPACing[:ACHannel]

This command defines the channel spacing of the adjacent channel to the TX channel.

Parameter

0Hz to 100 GHz

Example

POW:ACH:SPAC 33kHz

Sets the spacing between the carrier signal and the adjacent channel to 33 kHz

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]POWer:ACHannel:SPACing:ALTernate<1|4>

This command defines the channel spacing of the first to fourth alternate adjacent channel to

the TX channel..

Parameter

0Hz to 100 GHz

Example

POW:ACH:SPAC:ALT1 100kHz

Sets the spacing between TX channel and first alternate adjacent channel to 100 kHz.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL SENSe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.843 E-11

[SENSe:]POWer:NCORrection

This command activates or deactivates the noise correction for future spectrum ACP

measurements.

Parameter

ON | OFF

Example

POW:NCOR ON

Activates the noise correction.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]POWer:SEM:CLASs

This command sets the Spectrum Emission Mask (SEM) power class.

This command is available from firmware version 1.60.

Parameter

0 automatic selection

1(–INF, 23) dBm for uplink, (–INF, 29) dBm for downlink

2(23, INF) dBm for uplink, (29, 40) dBm for downlink

3(40, INF) dBm for downlink

Example

POW:SEM:CLAS 0

Sets the SEM power class to automatic.

Characteristics

RST value: 0

SCPI: device–specific

Mode

WiBro

[SENSe:]POWer:SEM:MODe

This command sets the Spectrum Emission Mask (SEM) analysis to be UL or DL (uplink or

downlink).This command only available for WiBro standard.

Parameter

DL | UL

Example

POW:SEM:MOD UL

Sets the Spectrum Emission Mask analysis to be UL.

SENSe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.844 E-11

Characteristics

RST value: –

SCPI: device–specific

Mode

WiBro

[SENSe:]POWer:SEM:TTA

This command sets the Spectrum Emission Mask (SEM) analysis according to TTA standard or

auser defined mask.

This command is available from firmware version 1.60.

Parameter

USER | STANDARD

Example

POW:SEM:TTA STANDARD

Sets the SEM analysis according to TTA standard.

Characteristics

RST value: STANDARD

SCPI: device–specific

Mode

WiBro

[SENSe:]SUBChannel

This command sets the subchannel to be used in the measurement. It is only available in Up

Link mode.

Parameter

1to 31

Example

SUBC 12

Sets the subchannel to 12.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

R&S FSL SENSe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.845 E-11

[SENSe:]SUBChannel:STATe

This command enables or disables the use of subchannels in the measurement analysis. It is

only available in Up Link mode.

Parameter

ON | OFF

Example

SUBC:STAT ON

Specifies that the measurement will be analyzed using the specified SUBChannel.

Characteristics

RST value: OFF

SCPI: conform

Mode

OFDMA/WiBro

[SENSe:]SUBChannel:ULPHysmod

This command sets the Up Link Physical Modifier to be used in the measurement. It is only

available in Up Link mode.

Parameter

0to 255

Example

SUBC:ULPH 1

Sets the UL Physical Modifier to 1.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

[SENSe:]SWAPiq

This command defines whether or not the recorded IQ pairs should be swapped (I<–>Q) before

being processed.

Parameter

ON | OFF

Example

SWAP ON

Specifies that IQ values should be swapped.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

SENSe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.846 E-11

[SENSe:]SWEep:ACPR:TIME

This command specifies the sweep time for the Spectrum Mask and Spectrum ACP/ACPR

measurements.

Parameter

10 ms to 16000 s

Example

SWE:ACPR:TIME:AUTO OFF

Deactivates the automatic calculation of the sweep time.

SWE:ACPR:TIME 100S

Sets the sweep time to 100 s.

Characteristics

RST value: 2s

SCPI: conform

Mode

OFDM, OFDMA/WiBro

[SENSe:]SWEep:ACPR:TIME:AUTO

This command activates or deactivates the automatic calculation of the sweep time for the

Spectrum Mask and Spectrum ACP/ACPR measurements.

Parameter

ON | OFF

Example

SWE:ACPR:TIME:AUTO OFF

Deactivates the automatic calculation of the sweep time.

Characteristics

RST value: ON

SCPI: conform

Mode

OFDM, OFDMA/WiBro

[SENSe:]SWEep:COUNt

This command specifies the number of sweeps for Spectrum Mask and Spectrum ACPR

measurements.

Parameter

1to 32767

Example

SWE:COUNt 64

Sets the number of sweeps to 64.

Characteristics

*RST value: 1

SCPI: conform

Mode

OFDM, OFDMA/WiBro

R&S FSL SENSe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.847 E-11

[SENSe:]SWEep:EGATe

For details refer to "[SENSe<1|2>:]SWEep:EGATe" on page 6.230.

[SENSe:]SWEep:EGATe:HOLDoff[:TIME]

This command defines the gate delay in the capture buffer in time units.

Parameter

0to 262.14 ms

Example

SWE:EGAT:HOLD 125us

Sets a delay of 125 µsin the capture buffer.

Characteristics

*RST value: 0 s

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]SWEep:EGATe:HOLDoff:SAMPle

This command defines the gate delay in the capture buffer as a number of samples.

Parameter

0to 50E6

Example

SWE:EGAT:HOLD:SAMP 2500

Sets a delay of 2500 samples in the capture buffer.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]SWEep:EGATe:LENGth[:TIME]

This command defines the gate time in the capture buffer in time units.

Parameter

0to 262.14 ms

Example

SWE:EGAT:LENG 100ms

Sets a gate length of 100 milliseconds between sweeps.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

SENSe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.848 E-11

[SENSe:]SWEep:EGATe:LENGth:SAMPle

This command defines the gate time in the capture buffer as a number of samples.

Parameter

0to 50E6

Example

SWE:EGAT:LENG:SAMP 2000000

Enforces a gate length of 2000000 samples in the capture buffer.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]SWEep:EGATe:LINK

This command links together the movement of the gating lines and the capture buffer marker.

Parameter

ON | OFF

Example

SWE:EGAT:LINK ON

Keeps the capture buffer marker on the centre of the gating lines if the gating line delay and

length are changed.

Characteristics

*RST value: 0

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

[SENSe:]SWEep:TIME

Parameter

24 Usto 15.5 ms

Characteristics

*RST value: 24 Us

For further details refer to "[SENSe<1|2>:]SWEep:TIME"on page 6.234.

R&S FSL SENSe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.849 E-11

[SENSe:]TRACking:LEVel

This command defines whether or not the measurement results should be compensated for

level.

Parameter

ON | OFF

Example

TRAC:LEV ON

Specifies that the measurement results should be compensated for level.

Characteristics

*RST value: OFF

SCPI: conform

Mode

OFDM

[SENSe:]TRACking:PHASe

This command defines whether or not the measurement results should be compensated for

phase.

Parameter

ON | OFF

Example

TRAC:PHAS ON

Specifies that the measurement results should be compensated for phase.

Characteristics

*RST value: ON

SCPI: conform

Mode

OFDM, OFDMA/WiBro

[SENSe:]TRACking:PILot

This command defines whether the measurement results should have predefined pilot tracking

or whether the tracking should be determined when the measurement is run.

Parameter

PRED Predefined pilot tracking is used.

DET Pilot tracking is determined when

the measurement is run.

Example

TRAC:PIL DET

Pilot tracking is determined when the measurement is run.

SENSe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.850 E-11

Characteristics

RST value: PRED

SCPI: conform

Mode

OFDMA/WiBro

[SENSe:]TRACking:TIME

This command defines whether or not the measurement results should be compensated for

time.

Parameter

ON | OFF

Example

TRAC:TIME ON

Specifies that the measurement results should be compensated for time.

Characteristics

*RST value: OFF

SCPI: conform

Mode

OFDM, OFDMA/WiBro

R&S FSL STATus Subsystem (WiMAX, K92/K93)

1300.2519.12 6.851 E-11

STATus Subsystem (WiMAX, K92/K93)

The STATus subsystem contains the commands for the status reporting system (for details refer to

chapter 5 "Remote Control – Basics"). For the STATus:QUEStionable:LIMit register, the measurement

window is selected by LIMit 1 (screen A) or 2 (screen B). *RST does not influence the status registers.

Commands of the STATus Subsystem

–STATus:QUEStionable:LIMit<1|2> [:EVENt]?

–STATus:QUEStionable:LIMit<1|2>:CONDition?

–STATus:QUEStionable:LIMit<1|2>:ENABle

–STATus:QUEStionable:LIMit<1|2>:PTRansition

–STATus:QUEStionable:LIMit<1|2>:NTRansition

–STATus:QUEStionable:POWer[:EVENt]?

–STATus:QUEStionable:POWer:CONDition?

–STATus:QUEStionable:POWer:ENABle

–STATus:QUEStionable:POWer:PTRansition

–STATus:QUEStionable:POWer:NTRansition

–STATus:QUEStionable:SYNC[:EVENt]?

–STATus:QUEStionable:SYNC:CONDition?

–STATus:QUEStionable:SYNC:ENABle

–STATus:QUEStionable:SYNC:PTRansition

–STATus:QUEStionable:SYNC:NTRansition

STATus:QUEStionable:LIMit<1|2> [:EVENt]?

For details refer to "STATus:QUEStionable:LIMit<1|2>[:EVENt]?" on page 6.245.

STATus:QUEStionable:LIMit<1|2>:CONDition?

For details refer to "STATus:QUEStionable:LIMit<1|2>:CONDition?"on page 6.246.

STATus:QUEStionable:LIMit<1|2>:ENABle

For details refer to "STATus:QUEStionable:LIMit<1|2>:ENABle" on page 6.246.

STATus:QUEStionable:LIMit<1|2>:PTRansition

For details refer to "STATus:QUEStionable:LIMit<1|2>:PTRansition" on page 6.247.

STATus:QUEStionable:LIMit<1|2>:NTRansition

For details refer to "STATus:QUEStionable:LIMit<1|2>:NTRansition"on page 6.246.

STATus Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.852 E-11

STATus:QUEStionable:POWer[:EVENt]?

For details refer to "STATus:QUEStionable:POWer[:EVENt]?" on page 6.249.

STATus:QUEStionable:POWer:CONDition?

For details refer to "STATus:QUEStionable:POWer:CONDition?" on page 6.249.

STATus:QUEStionable:POWer:ENABle

For details refer to "STATus:QUEStionable:POWer:ENABle" on page 6.249.

STATus:QUEStionable:POWer:PTRansition

For details refer to "STATus:QUEStionable:POWer:PTRansition" on page 6.250.

STATus:QUEStionable:POWer:NTRansition

For details refer to "STATus:QUEStionable:POWer:NTRansition" on page 6.250.

STATus:QUEStionable:SYNC[:EVENt]?

This command queries the contents of the EVENt section of the STATus:QUEStionable:SYNC

Example

STAT:QUES:SYNC?

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

STATus:QUEStionable:SYNC:CONDition?

This command queries the contents of the CONDition section of the

STATus:QUEStionable:SYNC register. Readout does not delete the contents of the CONDition

section.

Example

STAT:QUES:SYNC:COND?

Characteristics

*RST value: –

SCPI: conform

Mode

OFDM, OFDMA/WiBro

R&S FSL STATus Subsystem (WiMAX, K92/K93)

1300.2519.12 6.853 E-11

STATus:QUEStionable:SYNC:ENABle

This command sets the bits of the ENABle section of the STATus:QUEStionable:SYNC register.

The ENABle register selectively enables the individual events of the associated EVENt section

for the summary bit.

Parameter

0to 65535

Example

STAT:QUES:SYNC:ENAB 65535

All events bits will be represented in the SYNC summary bit.

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

STATus:QUEStionable:SYNC:PTRansition

This command determines what bits in the STATus:QUEStionable:SYNC Condition register will

set the corresponding bit in the STATus:QUEStionable:SYNC Event register when that bit has a

positive transition (0 to 1). The variable <number> is the sum of the decimal values of the bits

that are to be enabled.

Parameter

0to 65535

Example

STAT:QUES:SYNC:PTR 65535

All condition bits will be summarized in the Event register when a positive transition occurs.

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

STATus Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.854 E-11

STATus:QUEStionable:SYNC:NTRansition

This command determines what bits in the STATus:QUEStionable:SYNC Condition will set the

corresponding bit in the STATus:QUEStionable:SYNC Event register when that bit has a

negative transition (1 to 0). The variable <number> is the sum of the decimal values of the bits

that are to be enabled.

Parameter

0to 65535

Example

STAT:QUES:SYNC:NTR 65535

All condition bits will be summarized in the Event register when a positive transition occurs.

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL SYSTEM Subsystem (WiMAX, K92/K93)

1300.2519.12 6.855 E-11

SYSTEM Subsystem (WiMAX, K92/K93)

This subsystem contains a series of commands for general functions.

Commands of the SYSTEM Subsystem

–SYSTem:COMMunicate:TCPip:ADDRess

SYSTem:COMMunicate:TCPip:ADDRess

This command sets the lookup TCP/IP address of an external R&S SMU signal generator

connected via TCP/IP. This enables the instrument to download the frame zone setup directly.

Parameter

Example

SYST:COMM:TCP:ADDR 192.168.1.1

Sets the lookup TCP/IP address of the SMU to 192.168.1.1.

Characteristics

RST value: –

SCPI: device–specific

Mode

OFDMA/WiBro

TRACe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.856 E-11

TRACe Subsystem (WiMAX, K92/K93)

The TRACe subsystem controls access to the instrument's internal trace memory.

Commands of the TRACe Subsystem

–TRACe[:DATA]

–TRACe:IQ:DATA:MEMory?

–TRACe:IQ:SRATe

Further information

–Constellation vs Symbol

–Constellation vs Carrier

–Power vs Time – Full Burst and Start / End Data

–Power vs Time – Full Subframe and Rising/Falling Subframe

–Spectrum Flatness/Group Delay/Flatness Difference

–Spectrum FFT

–Statistics Bitstream data

–Statistics Burst Summary data

–Statistics CCDF – Complementary cumulative distribution function

–EVM vs Carrier

–EVM vs Symbol

–Frequency Sweep Measurements

–Spectrum Mask

–Spectrum ACPR

Constellation vs Symbol

This measurement represents I and Q data. Data will be returned as a repeating array of interleaved I

and Q data in groups of selected carriers, until all the data is exhausted.

Each I and Q point will be returned in floating point format. TRACE1 is used for this measurement

results.

•If All Carriers is selected, it will return 52 per of I and Q data per symbol.

•If Pilots Only is selected, it will return 4 per of I and Q per symbol in the following order:

Carrier –21, Carrier –7, Carrier 7, Carrier 21.

•If a single carrier is selected, it will return 1 per of I and Q data per symbol.

For the IEEE 802.16e–2005 OFDMA standard, the following rule applies: For all symbols, the results

are returned in repeating groups of the FFT size. For example, if the FFT size was 1024 and 12

symbols were found, then 12288 I/Q pairs worth of data would be returned. Carriers that do not exist or

are filtered out by the current filter settings are denoted by the keyword NAN.

R&S FSL TRACe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.857 E-11

Constellation vs Carrier

This measurement represents I and Q data. Data will be returned as a repeating array of interleaved I

and Q data in groups of 53 channels including the channel 0, until all the data is exhausted.

Each I and Q point will be returned in floating point format. TRACE1 is used for this measurement results.

Power vs Time – Full Burst and Start / End Data

This description applies to measurement results from the IEEE 802.16–2004 OFDM standard.

Both measurement results are once again simply slightly different views of the same results data.

All fully complete bursts within the capture time are analyzed. This data is returned in dBm values on a

per sample basis. Each sample will in some way relate to an analysis of each corresponding sample

within each processed burst.

The type of PVT data returned will be determined by the TRACE number passed as an argument to the

SCPI command, in addition to the graphic type that is selected.

If the graphic type selected is full burst, then the return data is as follows.

TRACE1 full burst, burst data values

If the graphic type selected is rising/falling, then the return data is as follows.

TRACE1 start, burst data values

TRACE2 end, burst data values

The number of samples returned during full burst analysis will depend on the modulation type and will

typically be 5000.

The number of samples returned when the rising and falling graphic type is selected will be less than

what is returned for full burst and will be approximately 400 samples. The samples will be returned in

floating point format as a single sequence of comma delimited values.

Power vs Time – Full Subframe and Rising/Falling Subframe

This description applies to measurement results from the IEEE 802.16e–2005 standard.

Both measurement results are once again simply slightly different views of the same results data.

All fully complete frames within the capture time are analyzed into three master frames. The three

master frames relate to the minimum, maximum and average values across all complete frames. This

data is returned in dBm values on a per sample basis. Each sample will in some way relate to an

analysis of each corresponding sample within each processed frame.

The type of PVT data returned will be determined by the TRACE number passed as an argument to the

SCPI command, in addition to the graphic type that is selected.

If the graphic type selected is full burst, then the return data is as follows.

TRACE1 full subframe, minimum frame data values

TRACE2 full subframe, mean frame data values

TRACE3 full subframe, maximum frame data values

TRACe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.858 E-11

If the graphic type selected is rising/falling, then the return data is as follows.

TRACE1 rising edge, minimum frame data values

TRACE2 rising edge, mean frame data values

TRACE3 rising edge, maximum frame data values

TRACE4 falling edge, minimum frame data values

TRACE5 falling edge, mean frame data values

TRACE6 falling edge, maximum frame data values

The number of samples returned during full frame analysis will depend on the modulation type and will

typically be 5000.

The number of samples returned when the start/end graphic type is selected will be less than what is

returned for full burst and will be approximately 400 samples. The samples will be returned in floating

point format as a single sequence of comma delimited values.

Spectrum Flatness/Group Delay/Flatness Difference

There are three separate traces that are available with this measurements. Trace data for a particular

trace will only be returnable by querying the appropriate trace.

The graph data returned is as follows:

•Spectrum Flatness

absolute power value (ABS)

•Group Delay

relative group delay

•Spectrum Difference

adjacent carrier power difference in the preamble part of the burst

All traces are all plotted on a per carrier basis. All carriers are drawn in addition to the unused 0 carrier.

The number of carriers depends on the measured standard:

•For the IEEE 802.16–2004 ODFM standard the number of carriers is 200.

•For the IEEE 802.16e–2005 ODFMA standard the number of carriers depends on the FFT size.

Carriers that are not used are denoted by the keyword NAN.

For example, the return data will be a repeating group of 201 carriers for the IEEE 802.16–2004 ODFM

standard.

TRACE1 Minimum absolute power value (ABS) or

Minimum group delay values

TRACE2 Mean absolute power value (ABS) or

Mean group delay values or

TRACE3 Maximum absolute power value (ABS) or

Maximum group delay values or

Absolute power results are returned in dB or dB difference and group delay results are returned in ns.

R&S FSL TRACe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.859 E-11

Spectrum FFT

All FFT points will be returned if the data for this measurement is requested. This will be an exhaustive

call, due to the fact that there are nearly always more FFT points than IQ samples. The number of FFT

points is the number presented by a power of 2 that is higher than the total number of samples.

E.g. if there were 20000 samples, then 32768 FFT points would be returned.

Data will be returned in floating point format in dBm. TRACE1 is used for this measurement results.

Statistics Bitstream data

Data will be returned depending on the selected standard from which the measurement was executed:

•For the IEEE 802.16–2004 OFDM standard, data is returned in repeating groups of 200 data

channels where each symbol value will be represented by an integer value within one byte.

Channel 0 is unused and will therefore not have any data associated with it, with no return data

being provided.

•For the IEEE 802.16e–2005 OFDMA standard, the data is returned in groups of the selected FFT

size, where each symbol value will be represented by an integer value within one byte. The FFT

size is either 128, 512, 1024, or 2048 sub carriers. Unused carriers, including the zero carrier, are

also returned. They are denoted by the string value NAN.

The number of repeating groups that are returned will be equal to the number of measured symbols.

64QAM has the highest data rate and it contains symbol values up to 63, making one byte sufficient in

size to represent all symbol data values, regardless of the modulation type in use.

Data will be returned in ASCII printable hexadecimal character format. TRACE1 is used for this

measurement results.

Statistics Burst Summary data

The return data depends on the current standard and measurement results.

For the IEEE 802.16–2004 OFDM standard, the data will be returned in repeating groups of 6 comma

separated values as follows:

•1st value – burst number

If this value is 0 then it is an FCH burst.

•2nd value – area with:

0 = preamble

1 = data

•3rd value – modulation with:

0 = BPSK

1 = QPSK

2 = 16QAM

3 = 64QAM

•4th value – symbol length

This is an integer value giving the number of symbols in the current area.

•5th value – power in dBm for the current area

This is returned as a float

•6th value – EVM in dB for the current area

This is returned as a float.

TRACe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.860 E-11

Example:

Burst Area Modulation Length Power EVM

FCH Preamble QPSK 1 –1.96 –43.75

Data BPSK 1 –2.96 –33.75

Burst 2 Preamble QPSK 1 –3.96 –23.75

Data 64QAM 26 –4.96 –13.75

SCPI would return the following:

B|A|M|L |P |E

u|r|o|e |o |V

r|e|d|n |w |M

s|a| | |e |

t| | | |r |

0,0,1, 1,–1.96,–43.75,

0,1,0, 1,–2.96,–33.75,

2,0,1, 1,–3.96,–23.75,

2,1,3,26,–4.96,–13.75

The number of repeating groups that are returned will be equal to the number of rows in the Burst

Summary results.

For the IEEE 802.16e–2005 OFDMA standard, the data will be returned in repeating groups of 7

comma separated values as follows:

•1st value – subframe number

•2nd value – burst number

•3rd value – burst type:

1 = FCH

2 = DL map

3 = UL map

4 = data

•4th value – modulation where:

1 = QPSK

2 = 16QAM

3 = 64QAM

•5th value – number of slots

This is an integer value giving the number of slots associated with the burst.

•6th value – power in dBm for the current area

This is returned as a float.

•7th value – EVM in dB for the current area

This is returned as a float.

The number of repeating groups that are returned will be equal to the number of rows in the Burst

Summary results.

Data will be returned in ASCII printable hexadecimal character format. TRACE1 is used for this

measurement results.

R&S FSL TRACe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.861 E-11

Statistics CCDF – Complementary cumulative distribution function

Up to a maximum of 201 data points will be returned in addition to a data count value. The first value in the

return data will represent the quantity of probability values that follow. Each of the potential 201 data points will

be returned as probability value and will represent the total number of samples that are equal to or exceed the

corresponding power level. Probability data will be returned up to the power level that contains at least one

sample. It is highly unlikely that the full 201 data values will ever be returned.

Each probability value will be returned as a floating point number, with a value less than 1.

EVM vs Carrier

Two trace types are provided with this measurement. There is an average EVM value for each of the 53

channels or a repeating group of EVM values for each channel. The number of repeating groups will

correspond to the number of fully analyzed trains.

Each EVM value will be returned as a floating point number, expressed in units of dBm.

TRACE1 Average EVM values per channel

TRACE2 All EVM values per channel for each full train of the capture period

For the IEEE 802.16e–2005 standard, the number of sub carriers returned varies according to the FFT

size.

Each EVM value will be returned as a floating point number, expressed in units of dBm or percentage.

TRACE1 Minimum EVM values

TRACE2 Mean EVM values

TRACE3 Maximum EVM values

EVM vs Symbol

Three traces types are available with this measurement. The basic trace types show either the

minimum, mean or maximum EVM value, as measured over the complete capture period.

The number of repeating groups that are returned will be equal to the number of measured symbols.

Each EVM value will be returned as a floating point number, expressed in units of dBm.

TRACE1 Minimum EVM values

TRACE2 Mean EVM values

TRACE3 Maximum EVM values

Frequency Sweep Measurements

Currently, there is only one measurement that is performed in frequency sweep mode. This is the

Spectrum Mask measurement. No data will be returned for this measurement, should it be requested,

until such time as a measurement has been previously run.

Running an IQ measurement will not generate results for this type of measurement.

Spectrum Mask

Result data will be returned as 501 trace points in floating point format. These trace points are obtained

directly from the base system via the measurement API and the quantity is therefore a fixed value. Only

an array of Y data will be returned.

TRACE1 Clear write values

TRACE2 Max hold values

TRACe Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.862 E-11

LIST Spectrum Emission Mask (SEM) summary results (in WiBro standard only):

SEM summary results formats:

1st value index into table of results (1 – 9)

2nd value start frequency band (Hz)

3rd value stop frequency band (Hz)

4th value RBW (Hz)

5th value limit fail frequency (Hz)

6th value power absolute (dBm)

7th value power relative (dBc)

8th value limit distance (dB)

9th value failure flag (1 = fail, 0 = pass)

There are 5 rows of results for downlink, and 9 rows for uplink.

Spectrum ACPR

Result data will be returned as 501 trace points in floating point format. These trace points are obtained

directly from the base system via the measurement API and the quantity is therefore a fixed value. Only

an array of Y data will be returned.

TRACE1 Clear write values

TRACE2 Max hold values

TRACe[:DATA]

This command returns all the measured data that relates to the currently selected measurement

type. All results are returned in ASCII format. The returned data depends on the currently

selected measurement type. DISPlay:FORMat is not supported with this command.

The following measurement types are available:

–"Constellation vs Symbol" on page 6.856

–"Constellation vs Carrier" on page 6.857

–"Power vs Time – Full Burst and Start / End Data" on page 6.857

–"Power vs Time – Full Subframe and Rising/Falling Subframe" on page 6.857

–"Spectrum Flatness/Group Delay/Flatness Difference" on page 6.858

–"Spectrum FFT" on page 6.859

–"Statistics Bitstream data" on page 6.859

–"Statistics Burst Summary data" on page 6.859

–"Statistics CCDF – Complementary cumulative distribution function" on page 6.861

–"EVM vs Carrier" on page 6.861

–"EVM vs Symbol" on page 6.861

–"Frequency Sweep Measurements" on page 6.861

–"Spectrum Mask" on page 6.861

–"Spectrum ACPR" on page 6.862

This command is a query only and thus has no *RST value.

R&S FSL TRACe Subsystem (WiMAX, K92/K93)

1300.2519.12 6.863 E-11

Parameter

For details on the parameters refer to the corresponding measurement type (see list above).

Example

TRAC? TRACE2

The measurement data for the selected graph is returned.

Characteristics

*RST value: –

SCPI: conform

Mode

OFDM, OFDMA/WiBro

TRACe:IQ:DATA:MEMory?

For details refer to "TRACe<1|2>:IQ:DATA:MEMory?" on page 6.274.

TRACe:IQ:SRATe

This command allows the sample rate for IQ measurements to be specified.

Parameter

1440000 to 32.248E6 Hz

Example

TRAC:IQ:SRAT 2000000

Specifies a sample rate of 20 MHz.

Characteristics

*RST value: –

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

TRIGger Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.864 E-11

TRIGger Subsystem (WiMAX, K92/K93)

The trigger subsystem is used to synchronize device action(s) with events.

Commands of the TRIGger Subsystem

–TRIGger[:SEQuence]:HOLDoff

–TRIGger[:SEQuence]:MODE

–TRIGger[:SEQuence]:LEVel[:EXTernal]

–TRIGger[:SEQuence]:LEVel:POWer

–TRIGger[:SEQuence]:LEVel:POWer:AUTO

TRIGger[:SEQuence]:HOLDoff

This command defines the length of the trigger delay. A negative delay time (pretrigger) can be

set in zero span only.

Parameter

–3.25 ms to 837.33 ms

Example

TRIG:HOLD 500us

Aholdoff period of 500 µs is used after the trigger condition has been met.

Characteristics

*RST value: 0 s

SCPI: conform

Mode

OFDM, OFDMA/WiBro

TRIGger[:SEQuence]:LEVel[:EXTernal]

This command defines the level of the external trigger input for which triggering will occur.

Parameter

0.5 V to 3.5 V

Example

TRIG:MODE EXT

Sets the power trigger mode.

TRIG:LEV 1 V

Sets the triggering level to 1 V.

Characteristics

RST value: 1.4 V

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL TRIGger Subsystem (WiMAX, K92/K93)

1300.2519.12 6.865 E-11

TRIGger[:SEQuence]:MODE

This command configures how triggering is to be performed.

Parameter

IMMediate No triggering is performed. This corresponds to the Free Run trigger mode.

EXTernal The next measurement is triggered by the signal at the external trigger input

e.g. a gated trigger.

POWer The next measurement is triggered by signals outside the measurement

channel.

Example

TRIG:MODE IMM

No triggering is performed.

Characteristics

*RST value: IMMediate

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

TRIGger[:SEQuence]:LEVel:POWer

This command sets the level of the input signal for which triggering will occur.

Parameter

–50 to 20 dBm

Example

TRIG:MODE POW

Sets the external trigger mode.

TRIG:LEV:POW 10 DBM

Sets the level to 10 dBm for RF measurement.

Characteristics

*RST value: –20 DBM

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

TRIGger Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.866 E-11

TRIGger[:SEQuence]:LEVel:POWer:AUTO

This command specifies whether or not an automatic power trigger level calculation is

performed before each main measurement. The setting of this command is ignored if the setting

for the TRIGger[:SEQuence]:LEVel[:EXTernal] command is not POWer.

Parameter

ON | OFF

Example

TRIG:LEV:POW:AUTO ON

Specifies that an automatic power trigger level calculation should be performed before the start

of each main measurement.

Characteristics

*RST value: OFF

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL UNIT Subsystem (WiMAX, K92/K93)

1300.2519.12 6.867 E-11

UNIT Subsystem (WiMAX, K92/K93)

The unit subsystem specifies the units for specific result types.

Commands of the UNIT Subsystem

–UNIT:EVM

–UNIT:PREamble

–UNIT:TABLe

UNIT:EVM

This command specifies the units for EVM results.

Parameter

DB EVM results returned in dB

PCT EVM results returned in %

Example

UNIT:EVM PCT

EVM results to be returned in %.

Characteristics

RST value: DB

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

UNIT:PREamble

This command specifies the units for Preamble error results.

Parameter

HZ Preamble error results returned in Hz

DEG Preamble error results returned in degrees

Example

UNIT:PRE HZ

Preamble error results to be returned in Hz.

Characteristics

RST value: Hz

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

UNIT Subsystem (WiMAX, K92/K93) R&S FSL

1300.2519.12 6.868 E-11

UNIT:TABLe

This command specifies the parameters of the result summary that can be displayed as dB or

degrees.

Parameter

DB results returned in dB

PCT results returned in %

Example

UNIT:TABL DB

Results to be returned in dB.

Characteristics

RST value: DB

SCPI: device–specific

Mode

OFDM, OFDMA/WiBro

R&S FSL Remote Control – Programming Examples

1300.2519.12 I-7.1 E-11

Contents of Chapter 7

7Remote Control – Programming Examples ...................................................... 7.1

Analyzer Measurements – Programming Examples .....................................................................7.1

Service Request .......................................................................................................................7.1

Initiate Service Request .................................................................................................7.1

Waiting for the Arrival of a Service Request ..................................................................7.2

Waiting Without Blocking the Keyboard and Mouse......................................................7.3

Service Request Routine ...............................................................................................7.4

Reading Out the Output Buffer ......................................................................................7.4

Reading Error Messages ...............................................................................................7.5

Evaluation of SCPI Status Registers..............................................................................7.5

Evaluation of Event Status Register...............................................................................7.6

Using Marker and Delta Marker ...............................................................................................7.6

Shape Factor Measurement (using n dB down) ............................................................7.6

Measuring the Third Order Intercept Point.....................................................................7.7

Measuring the AM Modulation Depth.............................................................................7.8

Limit Lines and Limit Test ........................................................................................................7.9

Measuring the Channel and Adjacent Channel Power...........................................................7.11

Occupied Bandwidth Measurement .......................................................................................7.13

Time Domain Power Measurement........................................................................................7.14

Fast Power Measurement on Power Ramps .........................................................................7.15

Power Measurement with Multi–Summary Marker ......................................................7.15

Multi–Burst Power Measurement.................................................................................7.17

Fast Level Measurement Using Frequency Lists ...................................................................7.19

Level Correction of Transducers ............................................................................................7.20

Measuring the Magnitude and Phase of a Signal...................................................................7.21

Averaging I/Q Data.................................................................................................................7.23

Reading and Writing Files ......................................................................................................7.24

Reading a File from the Instrument..............................................................................7.24

Creating a File on the Instrument.................................................................................7.25

Spectrum Emission Mask Measurement ...............................................................................7.26

Using Predefined Standard Wibro ...............................................................................7.26

Defining 5 Ranges with all Parameters........................................................................7.27

Spurious Emissions Measurement.........................................................................................7.30

WLAN TX Measurements – Programming Examples (Option K91/K91n).................................7.34

Synchronization Entry of Option .............................................................................................7.34

Selecting Measurements........................................................................................................7.34

Running Synchronized Measurements ..................................................................................7.35

WiMAX, WiBro Measurements – Programming Examples (Options K92/93) ...........................7.37

Synchronization Entry of Option .............................................................................................7.37

Selecting Measurements........................................................................................................7.37

Running Synchronized Measurements ..................................................................................7.38

R&S FSL Service Request

1300.2519.12 7.1 E-11

7Remote Control – Programming

Examples

The following programming examples have a hierarchical structure, i.e. subsequent examples are

based on previous ones. It is thus possible to compile very easily an operational program from the

modules of the given examples. VISUAL BASIC has been used as programming language. However,

the programs can be translated into other languages.

Note: In progamming languages as C, C++ or programmes as MATLAB, NI Interactive Control, a

backslash starts an escape sequence (e.g. "\n'' is used to start a new line). In these

progamming languages and programms, two backslashes instead of one must be used in

remote commands (for an example refer to the Quick Start Guide, chapter 6.)

Analyzer Measurements – Programming Examples

In this chapter, more complex programming examples are given. In the Quick Start Guide, chapter 6,

basic steps in remote control programming are provided.

Service Request

The service request routine requires an extended initialization of the instrument in which the relevant

bits of the transition and enable registers are set. In addition the service request event must be enabled

in the VISA session.

Initiate Service Request

REM –––– Example of initialization of the SRQ in the case of errors –––––––

PUBLIC SUB SetupSRQ()

CALL InstrWrite(analyzer, "*CLS") 'Reset status reporting system

CALL InstrWrite(analyzer,"*SRE 168") 'Enable service request for

'STAT:OPER,STAT:QUES and ESR

'register

CALL InstrWrite(analyzer,"*ESE 60") 'Set event enable bit for

'command, execution, device–

'dependent and query error

CALL InstrWrite(analyzer,"STAT:OPER:ENAB 32767")

'Set OPERation enable bit for

'all events

CALL InstrWrite(analyzer,"STAT:OPER:PTR 32767")

'Set appropriate OPERation

'Ptransition bits

CALL InstrWrite(analyzer,"STAT:QUES:ENAB 32767")

'Set questionable enable bits

'for all events

CALL InstrWrite(analyzer,"STAT:QUES:PTR 32767")

'Set appropriate questionable

'Ptransition bits

Service Request R&S FSL

1300.2519.12 7.2 E-11

CALL viEnableEvent(analyzer, VI_EVENT_SERVICE_REQ, VI_QUEUE, 0)

'Enable the event for service

'request

Status = viWaitOnEvent(analyzer, VI_EVENT_SERVICE_REQ, SRQWaitTimeout,

VI_NULL, VI_NULL)

IF (status = VI_SUCCESS) THEN CALL Srq 'If SRQ is recognized =>

'subroutine for evaluation

END SUB

REM ***********************************************************************

Waiting for the Arrival of a Service Request

There are basically two methods of waiting for the arrival of a service request:

1. Blocking (user inputs not possible):

This method is appropriate if the waiting time until the event to be signalled by an SRQ is short

(shorter than the selected timeout), if no response to user inputs is required during the waiting time,

and if – as the main criterion – the event is absolutely certain to occur.

Reason:

From the time the viWaitOnEvent() function is called until the occurrence of the expected event, it

does not allow the program to respond to mouse clicks or key entries during the waiting time.

Moreover, it returns an error if the SRQ event does not occur within the predefined timeout period.

The method is, therefore, in many cases not suitable for waiting for measurement results,

especially when using triggered measurements.

The following function calls are required:

Status = viWaitOnEvent(analyzer, VI_EVENT_SERVICE_REQ, SRQWaitTimeout,

VI_NULL, VI_NULL)

'Wait for service request user

'inputs are not possible during

'the waiting time!

IF (status = VI_SUCCESS) THEN CALL Srq

'If SRQ is recognized =>

'subroutine for evaluation

2. Non–blocking (user inputs possible):

This method is recommended if the waiting time until the event to be signalled by an SRQ is long

(longer than the selected timeout), and user inputs should be possible during the waiting time, or if

the event is not certain to occur. This method is, therefore, the preferable choice for waiting for the

end of measurements, i.e. the output of results, especially in the case of triggered measurements.

The method necessitates a waiting loop that checks the status of the SRQ line at regular intervals

and returns control to the operating system during the time the expected event has not yet

occurred. In this way, the system can respond to user inputs (mouse clicks, key entries) during the

waiting time.

It is advisable to employ the Hold() auxiliary function, which returns control to the operating system

for a selectable waiting time (see section "Waiting Without Blocking the Keyboard and Mouse"), so

enabling user inputs during the waiting time.

result% = 0

For i = 1 To 10 'Abort after max. 10 loop

'iterations

Status = viWaitOnEvent(analyzer, VI_EVENT_SERVICE_REQ,

VI_TMO_IMMEDIATE, VI_NULL,

VI_NULL)

'Check event queue

R&S FSL Service Request

1300.2519.12 7.3 E-11

If (status = VI_SUCCESS) Then

result% = 1

CALL Srq 'If SRQ is recognized =>

'subroutine for evaluation

Else

CALL Hold(20) 'Call hold function with

'20 ms 'waiting time. User inputs

'are possible.

Endif

Next i

If result% = 0 Then

Debug.Print "Timeout Error; Program aborted"

'Output error message

STOP 'Stop software

Endif

Waiting Without Blocking the Keyboard and Mouse

Afrequent problem with remote control programs using Visual Basic is to insert waiting times without

blocking the keyboard and the mouse.

If the program is to respond to user inputs also during a waiting time, control over the program events

during this time must be returned to the operating system. In Visual Basic, this is done by calling the

DoEvents function. This function causes keyboard– or mouse–triggered events to be executed by the

associated elements. For example, it allows the operation of buttons and input fields while the user waits

for an instrument setting to be completed.

The following programming example describes the Hold() function, which returns control to the

operating system for the period of the waiting time selectable in milliseconds.

Rem ***********************************************************************

Rem The waiting function below expects the transfer of the desired

Rem waiting time in milliseconds. The keyboard and the mouse remain

Rem operative during the waiting period, thus allowing desired elements

Rem to be controlled

Rem ***********************************************************************

Public Sub Hold(delayTime As Single)

Start = Timer 'Save timer count on calling the

'function

Do While Timer < Start + delayTime / 1000 'Check timer count

DoEvents 'Return control to operating

'system to enable control of

'desired elements as long as

'timer has not elapsed

Loop

End Sub

Rem ***********************************************************************

The waiting procedure is activated simply by calling Hold(<Waiting time in milliseconds>).

Service Request R&S FSL

1300.2519.12 7.4 E-11

Service Request Routine

Aservice request is processed in the service request routine.

Note: The variables userN% and userM% must be pre–assigned usefully!

REM –––––––––––– Service request routine ––––––––––––––––––––––––––––––––––

Public SUB Srq()

ON ERROR GOTO noDevice 'No user existing

CALL viReadSTB(analyzer, STB%) 'Serial poll, read status byte

IF STB% > 0 THEN 'This instrument has bits set in

'the STB

SRQFOUND% = 1

IF (STB% AND 16) > 0 THEN CALL Outputqueue

IF (STB% AND 4) > 0 THEN CALL ErrorQueueHandler

IF (STB% AND 8) > 0 THEN CALL Questionablestatus

IF (STB% AND 128) > 0 THEN CALL Operationstatus

IF (STB% AND 32) > 0 THEN CALL Esrread

END IF

noDevice:

END SUB 'End of SRQ routine

REM ***********************************************************************

Reading out the status event registers, the output buffer and the error/event queue is effected in

subroutines.

Reading Out the Output Buffer

REM –––––––– Subroutine for the individual STB bits –––––––––––––––––––––––

Public SUB Outputqueue() 'Reading the output buffer

result$ = SPACE$(100) 'Make space for response

CALL InstrRead(analyzer, result$)

Debug.Print "Contents of Output Queue : "; result$

END SUB

REM ***********************************************************************

R&S FSL Service Request

1300.2519.12 7.5 E-11

Reading Error Messages

REM –––––––– Subroutine for reading the error queue –––––––––––––––––––––––

Public SUB ErrorQueueHandler()

ERROR$ = SPACE$(100) 'Make space for error variable

CALL InstrWrite(analyzer, "SYSTEM:ERROR?")

CALL InstrRead(analyzer, ERROR$)

Debug.Print "Error Description : "; ERROR$

END SUB

REM ***********************************************************************

Evaluation of SCPI Status Registers

REM –––––– Subroutine for evaluating Questionable Status Register –––––––––

Public SUB Questionablestatus()

Ques$ = SPACE$(20) 'Preallocate blanks to text

'variable

CALL InstrWrite(analyzer, "STATus:QUEStionable:EVENt?")

CALL InstrRead(analyzer, Ques$)

Debug.Print "Questionable Status: "; Ques$

END SUB

REM ***********************************************************************

REM –––––– Subroutine for evaluating Operation Status Register ––––––––––––

Public SUB Operationstatus()

Oper$ = SPACE$(20) 'Preallocate blanks to text

'variable

CALL InstrWrite(analyzer, "STATus:OPERation:EVENt?")

CALL InstrRead(analyzer, Oper$)

Debug.Print "Operation Status: "; Oper$

END SUB

REM ***********************************************************************

Using Marker and Delta Marker R&S FSL

1300.2519.12 7.6 E-11

Evaluation of Event Status Register

REM –––––– Subroutine for evaluating the Event Status Register ––––––––––––

Public SUB Esrread()

Esr$ = SPACE$(20) 'Preallocate blanks to text

'variable

CALL InstrWrite(analyzer, "*ESR?") 'Read ESR

CALL InstrRead(analyzer, Esr$)

IF (VAL(Esr$) AND 1) > 0 THEN Debug.Print "Operation complete"

IF (VAL(Esr$) AND 2) > 0 THEN Debug.Print "Request Control"

IF (VAL(Esr$) AND 4) > 0 THEN Debug.Print "Query Error"

IF (VAL(Esr$) AND 8) > 0 THEN Debug.Print "Device dependent error"

IF (VAL(Esr$) AND 16) > 0 THEN

Debug.Print "Execution Error; Program aborted"

'Output error message

STOP 'Stop software

END IF

IF (VAL(Esr$) AND 32) > 0 THEN

Debug.Print "Command Error; Program aborted"

'Output error message

STOP 'Stop software

END IF

IF (VAL(Esr$) AND 64) > 0 THEN Debug.Print "User request"

IF (VAL(Esr$) AND 128) > 0 THEN Debug.Print "Power on"

END SUB

REM **********************************************************************

Using Marker and Delta Marker

Shape Factor Measurement (using n dB down)

The n–dB–down function of the R&S FSL is used twice to determine the shape factor of a filter (ratio of

bandwidths at 60 dB and 3 dB below the filter maximum).

The following example is again based on a signal with a level of –30 dBm at 100 MHz. The shape factor

is determined for the 30 kHz resolution bandwidth. The default setting of the R&S FSL is used for

measurements (SetupInstrument).

REM ************************************************************************

Public Sub ShapeFactor()

result$ = Space$(100)

'––––––––– R&S FSL default setting ––––––––––––––––––––––––––––––––––––––––

CALL SetupInstrument 'Default setting

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Single sweep

R&S FSL Using Marker and Delta Marker

1300.2519.12 7.7 E-11

'––––––––– Set frequency –––––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"FREQ:SPAN 1MHz")

'Span

CALL InstrWrite(analyzer,"BAND:RES 30kHz")

'Resolution bandwidth

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep with sync

'––––––––– Measure 60 dB value –––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"CALC:MARK:PEXC 6DB")

'Peak excursion

CALL InstrWrite(analyzer,"CALC:MARK:STAT ON")

'Marker1 on

CALL InstrWrite(analyzer,"CALC:MARK:TRAC 1")

'Assign marker1 to trace1

CALL InstrWrite(analyzer,"CALC:MARK:MAX") 'Set marker1 to 100 MHz

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:NDBD 45dB")

'Read out bandwidth measured at

'45 dB

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:NDBD:RES?")

CALL InstrRead(analyzer,result$)

result60 = Val(result$)

'––––––––– Measure 3 dB down value–––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:NDBD 3dB")

'Read out bandwidth measured at

'3 dB

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:NDBD:RES?")

CALL InstrRead(analyzer,result$)

result3 = Val(result$)

'––––––––– Read out shape factor––––––––––––––––––––––––––––––––––––––––––––

Print "Shapefaktor 60dB/3dB: ";result60/result3

END SUB

REM ************************************************************************

Measuring the Third Order Intercept Point

The third order intercept point (TOI) is the (virtual) level of two adjacent useful signals at which the

intermodulation products of third order have the same level as the useful signals.

The intermodulation product at fS2 is obtained by mixing the first harmonic of the useful signal PN2 with

signal PN1,the intermodulation product at fS1 by mixing the first harmonic of the useful signal PN1 with

signal PN2.

fs1 = 2 x fn1 –fn2 (1)

fs2 = 2 x fn2 –fn1 (2)

The following example is based on two adjacent signals with a level of –30 dBm at 100 MHz and

110 MHz. The intermodulation products lie at 90 MHz and 120 MHz according to the above formula. The

frequency is set so that the examined mixture products are displayed in the diagram. Otherwise, the

default setting of the R&S FSL is used for measurements (SetupInstrument).

Using Marker and Delta Marker R&S FSL

1300.2519.12 7.8 E-11

REM ************************************************************************

Public Sub TOI()

result$ = Space$(100)

'––––––––– R&S FSL default setting ––––––––––––––––––––––––––––––––––––––––

CALL SetupStatusReg 'Set status registers

CALL InstrWrite(analyzer,"*RST") 'Reset instrument

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Single sweep

CALL InstrWrite(analyzer,"SYST:DISP:UPD ON")

'ON: display on

'OFF: off

'––––––––– Set frequency –––––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"FREQ:STARt 85MHz;STOP 125 MHz")

'Span

'––––––––– Set level –––––––––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"DISP:WIND:TRAC:Y:RLEV –20dBm")

'Reference level

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep with sync

'––––––––– TOI measurement –––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"CALC:MARK:PEXC 6DB")

'Peak excursion

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:TOI ON")

'Switch on TOI measurement

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:TOI:RES?")

'and read out results

CALL InstrRead(analyzer,result$)

'––––––––– Read out result ––––––––––––––––––––––––––––––––––––––––––––––––

Print "TOI [dBm]: ";result$

END SUB

REM ************************************************************************

Measuring the AM Modulation Depth

The example below is based on an AM–modulated signal at 100 MHz with the following characteristics:

•Carrier signal level: –30 dBm

•AF frequency: 100 kHz

•Modulation depth: 50 %

The default setting of the analyzer for measurements can be used for the measurements described

below (SetupInstrument).

REM ************************************************************************

Public Sub AMMod()

result$ = Space$(100)

CALL SetupInstrument 'Default setting

CALL InstrWrite(analyzer,"BAND:RES 30kHz") 'Set appropriate RBW

R&S FSL Limit Lines and Limit Test

1300.2519.12 7.9 E-11

'––––––––– Peak search –––––––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Single sweep

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep with sync

CALL InstrWrite(analyzer,"CALC:MARK:PEXC 6DB")

'Peak excursion

CALL InstrWrite(analyzer,"CALC:MARK:STAT ON")

'Marker 1 on

CALL InstrWrite(analyzer,"CALC:MARK:TRAC 1")

'Assign marker1 to trace1

'––––––––– Measure modulation depth–––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"CALC:MARK:MAX;FUNC:MDEP ON")

'Marker to Peak;

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:MDEP:RES?")

'Measure mod. depth

CALL InstrRead(analyzer, result$) 'Read out result

'––––––––– Read out result –––––––––––––––––––––––––––––––––––––––––––––––––

Print "AM Mod Depth [%]: ";result$

END SUB

REM ************************************************************************

Limit Lines and Limit Test

The example below shows the definition and use of a new limit line 5 for trace 1 with the following

characteristics:

•Upper limit line

•Absolute x–axis in the frequency range

•5reference values:

120 MHz / –70 dB, 126 MHz/–40 dB, 127 MHz/–40 dB, 128 MHz/–10 dB,

129 MHz/–40 dB, 130 MHz/–40 dB, 136 MHz / –70 dB

•Relative y–axis with unit dB

•Absolute threshold at –75 dBm

•No margin

The signal of the integrated calibration source (128 MHz, –30 dBm) is used to check the limit test.

REM ************************************************************************

Public Sub LimitLine()

result$ = Space$(100)

'––––––––– R&S FSL default setting ––––––––––––––––––––––––––––––––––––––––

CALL SetupInstrument 'Default setting

CALL InstrWrite(analyzer,"FREQUENCY:CENTER 128MHz;Span 10MHz")

'Span

CALL InstrWrite(analyzer,"Diag:Serv:Inp Cal;CSO –30dBm")

'Cal signal on

Limit Lines and Limit Test R&S FSL

1300.2519.12 7.10 E-11

'––––––––– Definition of limit lines –––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"CALC:LIM5:NAME 'TEST1'")

'Define name

CALL InstrWrite(analyzer,"CALC:LIM5:COMM 'Upper limit'")

'Define comment

CALL InstrWrite(analyzer,"CALC:LIM5:TRAC 1")

'Assign trace

CALL InstrWrite(analyzer,"CALC:LIM5:CONT:DOM FREQ")

'Define x–axis range

CALL InstrWrite(analyzer,"CALC:LIM5:CONT:MODE ABS")

'Define x–axis scaling

CALL InstrWrite(analyzer,"CALC:LIM5:UNIT DB")

'Define y–axis unit

CALL InstrWrite(analyzer,"CALC:LIM5:UPP:MODE REL")

'Define y–axis scaling

'––––––––– Definition of data points and threshold –––––––––––––––––––––––––

xlimit$ = "CALC:LIM5:CONT 120MHZ,126MHZ,127MHZ,128MHZ,129MHZ,130MHz,136MHz"

CALL InstrWrite(analyzer, xlimit$) 'Set values for x–axis

CALL InstrWrite(analyzer,"CALC:LIM5:UPP –70,–40,–40,–20,–40,–40,–70")

'Set values for y–axis

CALL InstrWrite(analyzer,"CALC:LIM5:UPP:THR –75DBM")

'Set y threshold (only

'possible for relative

'y–axis)

'––––––––– Definition of margin or x /y offset–––––––––––––––––––––––––––––

'A margin or an x /y offset can be defined here.

'––––––––––– Activate and evaluate the limit line –––––––––––––

CALL InstrWrite(analyzer,"CALC:LIM5:UPP:STAT ON")

'Activate line 5

CALL InstrWrite(analyzer,"CALC:LIM5:STAT ON")

'Activate limit check

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep with sync

CALL InstrWrite(analyzer,"CALC:LIM5:FAIL?")

'Query result of limit check

CALL InstrRead(analyzer, result$) 'Result: 1 (= FAIL)

'––––––––– Read out result –––––––––––––––––––––––––––––––––––––––––––––––––

Print "Limit Result Line 5: ";result$

'–––––– Evaluate limit line by means of status register –––––––

CALL InstrWrite(analyzer,"*CLS") 'Reset status register

'––––––––– Measure –––––––––––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"INIT;*OPC") 'Perform sweep with sync

CALL viEnableEvent(analyzer, VI_EVENT_SERVICE_REQ, VI_QUEUE, 0)

Status = viWaitOnEvent(analyzer, VI_EVENT_SERVICE_REQ, SRQWaitTimeout,

VI_NULL, VI_NULL)

IF (status = VI_SUCCESS) THEN CALL Srq 'If SRQ is recognized =>

'subroutine for evaluation

R&S FSL Measuring the Channel and Adjacent Channel Power

1300.2519.12 7.11 E-11

'––––––––– Read out result –––––––––––––––––––––––––––––––––––––––––––––––––

IF (status% = 1) THEN

CALL InstrWrite(analyzer,"STAT:QUES:LIM1:COND?")

'Read out STAT:QUES:LIMit

'register

CALL InstrRead(analyzer, result$)

IF ((Val(result$) And 16) <> 0) THEN

Print "Limit5 failed"

ELSE

Print "Limit5 passed"

END IF

END SUB

REM ************************************************************************

Measuring the Channel and Adjacent Channel Power

In the following example, the channel and adjacent channel power is first measured on a signal with a

level of 0 dBm at 800 MHz to IS95. Then the channel and adjacent channel power is measured on a

GSM signal at 935.2 MHz with fast ACP measurement (FAST ACP).

In addition, the limit test is activated.

REM ************************************************************************

Public Sub ACP()

result$ = Space$(100)

'––––––––– R&S FSL default setting ––––––––––––––––––––––––––––––––––––––––

CALL SetupStatusReg 'Set status register

CALL InstrWrite(analyzer,"*RST") 'Reset instrument

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Single sweep

CALL InstrWrite(analyzer,"SYST:DISP:UPD ON")

'ON: display on

'OFF: off

'––––––––– Set frequency –––––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"FREQ:CENT 800MHz")

'Set frequency

CALL InstrWrite(analyzer,"DISP:WIND:TRAC:Y:RLEV 10dBm")

'Reference level

'––––––––– Example 1: Configure CP/ACP for CDMA––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:POW:SEL ACP")

'ACP measurement on

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:POW:PRES F8CDMA")

'Select CDMA800 FWD

CALL InstrWrite(analyzer,"SENS:POW:ACH:ACP 2")

'Select 2 adjacent channels

Measuring the Channel and Adjacent Channel Power R&S FSL

1300.2519.12 7.12 E-11

CALL InstrWrite(analyzer,"SENS:POW:ACH:PRES ACP")

'Optimize settings

CALL InstrWrite(analyzer,"SENS:POW:ACH:PRES:RLEV")

'Optimize reference level

CALL InstrWrite(analyzer,"SENS:POW:ACH:MODE ABS")

'Absolute measurement

CALL InstrWrite(analyzer,"SENS:POW:HSP ON")

'Fast ACP measurement

'––––––––– Perform measurement and query results ––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep with sync

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:POW:RES? ACP") 'Query result

CALL InstrRead(analyzer, result$)

'––––––––– Read out result –––––––––––––––––––––––––––––––––––––––––––––––––

Print "Result (CP, ACP low, ACP up, Alt low, Alt up): "

Print result$

'––––––––– Example 2: Configure CP/ACP manually for GSM––––––––––––––––––––

result$ = Space$(100)

CALL InstrWrite(analyzer,"FREQ:CENT 935.2MHz")

'Set frequency

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:POW:SEL ACP")

'ACP measurement on

CALL InstrWrite(analyzer,"SENS:POW:ACH:ACP 1")

'1 adjacent channel

CALL InstrWrite(analyzer,"SENS:POW:ACH:BAND 200KHZ")

'Channel bandw. 200 kHz

CALL InstrWrite(analyzer,"SENS:POW:ACH:BAND:ACH 200KHZ")

'Adjacent channel band–

'width 200 kHz

CALL InstrWrite(analyzer,"SENS:POW:ACH:SPAC 200KHZ")

'Channel spacing 200 kHz

CALL InstrWrite(analyzer,"SENS:POW:ACH:PRES ACP")

'Optimize settings

CALL InstrWrite(analyzer,"SENS:POW:ACH:PRES:RLEV")

'Optimize reference level

CALL InstrWrite(analyzer,"SENS:POW:ACH:MODE ABS")

'Absolute measurement

'––––––––– Start measurement and query result ––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep with sync

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:POW:RES? ACP")

'Query result

CALL InstrRead(analyzer, result$)

'––––––––– Read out result –––––––––––––––––––––––––––––––––––––––––––––––––

Print "Result (CP, ACP low, ACP up): "

Print result$

R&S FSL Occupied Bandwidth Measurement

1300.2519.12 7.13 E-11

'––––––––– Active limit check ––––––––––––––––––––––––––––––––––––––––––––––

result$ = Space$(100)

CALL InstrWrite(analyzer,"CALC:LIM:ACP:ACH 30DB, 30DB")

'Set relative limit

CALL InstrWrite(analyzer,"CALC:LIM:ACP:ACH:ABS –35DBM,–35DBM")

'Set absolute limit

CALL InstrWrite(analyzer,"CALC:LIM:ACP:ACH:STAT ON")

'Rel. limit check on

CALL InstrWrite(analyzer,"CALC:LIM:ACP:ACH:ABS:STAT ON")

'Abs. limit check on

CALL InstrWrite(analyzer,"CALC:LIM:ACP ON")

'Limit check on

'––––––––– Start measurement and query result ––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep with sync

CALL InstrWrite(analyzer,"CALC:LIM:ACP:ACH:RES?")

'Query result of limit check

CALL InstrRead(analyzer, result$)

'––––––––– Read out result –––––––––––––––––––––––––––––––––––––––––––––––––

Print "Result Limit Check: ";result$

END SUB

REM ************************************************************************

Occupied Bandwidth Measurement

In the following example, the bandwidth is to be found in which 95% of the power of a GSM signal is

contained. Signal frequency is 935.2 MHz; channel bandwidth is 200 kHz.

REM ************************************************************************

Public Sub OBW()

result$ = Space$(100)

'––––––––– R&S FSL default setting ––––––––––––––––––––––––––––––––––––––––

CALL SetupStatusReg 'Set status register

CALL InstrWrite(analyzer,"*RST") 'Reset instrument

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Single sweep

CALL InstrWrite(analyzer,"SYST:DISP:UPD ON")

'ON: display on

'OFF: off

'––––––––– Configure R&S FSL for OBW for GSM––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"FREQ:CENT 935.2MHz")

'Set frequency

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:POW:SEL OBW")

'OBW measurement on

CALL InstrWrite(analyzer,"SENS:POW:ACH:BAND 200KHZ")

'Channel bandw. 200 kHz

CALL InstrWrite(analyzer,"SENS:POW:BWID 95PCT")

'Percentage of power

Time Domain Power Measurement R&S FSL

1300.2519.12 7.14 E-11

CALL InstrWrite(analyzer,"SENS:POW:ACH:PRES OBW")

'Set frequency and optimize

reference level

CALL InstrWrite(analyzer,"SENS:POW:ACH:PRES:RLEV")

CALL InstrWrite(analyzer,"SENS:POW:NCOR OFF")

'Noise correction

'OFF: switch off

'ON: switch on

'––––––––– Perform measurement and query results –––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep with sync

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:POW:RES? OBW")

'Query result

CALL InstrRead(analyzer, result$)

Print result$

END SUB

REM ************************************************************************

Time Domain Power Measurement

In the following example, the mean carrier power of a signal with 300 kHz bandwidth at 100 MHz is to be

determined. In addition, the peak power, the rms value and the standard deviation are measured. To do

this, the time–domain–power measurement functions are used.

REM ************************************************************************

Public Sub TimeDomainPower()

result$ = Space$(100)

'––––––––– R&S FSL default setting ––––––––––––––––––––––––––––––––––––––––

CALL SetupStatusReg 'Set status register

CALL InstrWrite(analyzer,"*RST") 'Reset instrument

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Single sweep

CALL InstrWrite(analyzer,"SYST:DISP:UPD ON")

'ON: display on

'OFF: off

'––––––––– Configure R&S FSL for time domain power measurement ––––––––––––

CALL InstrWrite(analyzer,"FREQ:CENT 100MHz;SPAN 0Hz")

'Set frequency

CALL InstrWrite(analyzer,"BAND:RES 300kHz")

'Resolution bandwidth

CALL InstrWrite(analyzer,"SWE:TIME 200US") 'Sweep time

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:SUMM:PPE ON")

'Peak measurement on

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:SUMM:MEAN ON")

'Mean measurement on

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:SUMM:RMS ON")

'RMS measurement on

CALL InstrWrite(analyzer,"CALC:MARK:FUNC:SUMM:SDEV ON")

'Standard deviation on

R&S FSL Fast Power Measurement on Power Ramps

1300.2519.12 7.15 E-11

'––––––––––––––––––– Perform measurement and query results ––––––––––––––––

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep with sync

'Query results:

query$ = " CALC:MARK:FUNC:SUMM:PPE:RES?;" 'Peak measurement

query$ = query$ + ":CALC:MARK:FUNC:SUMM:MEAN:RES?;"

'Mean measurement

query$ = query$ + ":CALC:MARK:FUNC:SUMM:RMS:RES?;"

'RMS measurement

query$ = query$ + ":CALC:MARK:FUNC:SUMM:SDEV:RES?"

'Standard deviation

CALL InstrWrite(analyzer, query$)

CALL InstrRead(analyzer, result$)

Print result$

END SUB

REM ************************************************************************

Fast Power Measurement on Power Ramps

Afrequent task in mobile radio tests is measurement of a DUT at various power control levels at the

highest possible speed. The R&S FSL offers two test functions for this task, which can be used

depending on the signal characteristics.

In the following, the two methods are presented by means of two examples.

Power Measurement with Multi–Summary Marker

The multi–summary marker function is suitable for measuring the power of a sequence of pulses with

the following characteristics:

•The pulses occur at identical time intervals, which is typical of GSM transmission in slots, for

example.

•The level of the first signal is reliably above threshold.

•The subsequent pulses may have any levels.

The function uses the first pulse as a trigger signal. The power of the subsequent pulses is determined

exclusively via the timing pattern selected for the pulse sequence. The function is, therefore, suitable for

adjustments where the DUT output power varies considerably and is not reliably above the trigger

threshold.

The measurement accuracy is determined by the ratio of pulse duration to total measurement time; this

should not be below 1:50.

The function always uses TRACE 1.

Fast Power Measurement on Power Ramps R&S FSL

1300.2519.12 7.16 E-11

Trace start

Time offset of

first pulse

Measurement

Time

Measurement

Time

Measurement

Time

Period Period

Trigger

Threshold

Fig. 7–1 Block diagram illustrating signal processing in analyzer

In the example below, a GSM puls sequence of 8 pulses is measured with an offset of 50 µsof the first

pulse, 450 µsmeasurement time/pulse and 576.9 µspulse period.

REM ************************************************************************

Public Sub MultiSumMarker()

result$ = Space$(200)

'––––––––– R&S FSL default setting–––––––––––––––––––––––––––––––––––––––

CALL SetupStatusReg 'Configure status register

CALL InstrWrite(analyzer,"*RST") 'Reset instrument

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Single sweep mode

CALL InstrWrite(analyzer,"SYST:DISP:UPD ON")

'ON: switch display on

'OFF: switch display off

'––––––––– Configure R&S FSL for power measurement in time domain –––––––––

CALL InstrWrite(analyzer,"FREQ:CENT 935.2MHz;SPAN 0Hz")

'Frequency setting

CALL InstrWrite(analyzer,"DISP:WIND:TRAC:Y:RLEV 10dBm")

'Set reference level to 10 dB

CALL InstrWrite(analyzer,"INP:ATT 30 dB") 'Set input attenuation to 30 dB

CALL InstrWrite(analyzer,"BAND:RES 1MHz;VID 3MHz")

'Bandwidth setting

CALL InstrWrite(analyzer,"DET RMS") 'Select RMS detector

CALL InstrWrite(analyzer,"TRIG:SOUR VID") 'Trigger source: video

CALL InstrWrite(analyzer,"TRIG:LEV:VID 50 PCT")

'Trigger threshold: 50%

CALL InstrWrite(analyzer,"SWE:TIME 50ms") 'Sweep time 1frame

R&S FSL Fast Power Measurement on Power Ramps

1300.2519.12 7.17 E-11

'––––––––– Perform measurement and query results ––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep with sync

'Query results:

cmd$ = "CALC:MARK:FUNC:MSUM? "

cmd$ = cmd$ + "50US," 'Offset of first pulse

cmd$ = cmd$ + "450US," 'Measurement time

cmd$ = cmd$ + "576.9US," 'Pulse period

cmd$ = cmd$ + "8" 'Number of bursts

CALL InstrWrite(analyzer,cmd$)

CALL InstrRead(analyzer, result$) 'Read results

Print result$

END SUB

REM ************************************************************************

Multi–Burst Power Measurement

The multi–burst power measurement function is suitable for measuring the power of a sequence of

pulses with the following characteristics:

•The pulses occur at variable time intervals.

•The levels of all pulses of the sequence are reliably above the trigger threshold, or an external

trigger signal is used.

The function requires one trigger event per pulse. This means that if the video trigger or the IF power

trigger is used, the levels of all pulses must be above the trigger threshold.

The function is, therefore, particularly suitable for re–measuring DUTs already adjusted and whose

output power is within the specified range. The measurement is optimized for minimum overhead

relative to the actual measurement time.

Trigger

Signal

Trigger

Offset

Measurement

Time

Trigger

Signal

Trigger

Offset

Measurement

Time

Trigger

Signal

Trigger

Offset

Measurement

Time

Trigger

Threshold

Fig. 7–2 Block diagram illustrating signal processing in analyzer

Either the root–mean–square power or the peak power is measured, depending on whether the RMS

detector or the PEAK detector is selected. The function always uses TRACE 1.

Fast Power Measurement on Power Ramps R&S FSL

1300.2519.12 7.18 E-11

The following parameters are to be set for this measurement:

•Analyzer frequency

•Resolution bandwidth

•Measurement time per single pulse

•Trigger source

•Trigger threshold

•Trigger offset

•Type of power measurement (PEAK, MEAN)

•Number of pulses to be measured

During the measurement, each pulse is mapped into a pixel of the screen, i.e. any change of the trace

can be detected only at the left–hand edge of the screen. Maximum measurement speed is as usual

achieved with the display switched off.

In the example below, a GSM pulse sequence of 8 pulses is measured with 5 µstrigger offset,

434 µsmeasurement time/pulse, video trigger with 50% trigger threshold, and peak detection:

REM ************************************************************************

Public Sub MultiBurstPower()

result$ = Space$(200)

'––––––––– R&S FSL default setting ––––––––––––––––––––––––––––––––––––––––

CALL SetupStatusReg 'Configure status register

CALL InstrWrite(analyzer,"*RST") 'Reset instrument

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Single sweep mode

CALL InstrWrite(analyzer,"SYST:DISP:UPD OFF")

'OFF: display off

'––––––––– Perform measurement and query results –––––––––––––––––––––

cmd$ = "MPOW? "

cmd$ = cmd$ + "935.2 MHZ," 'Center frequency

cmd$ = cmd$ + "1MHZ," 'Resolution bandwidth

cmd$ = cmd$ + "434US," 'Measurement time

cmd$ = cmd$ + "VID," 'Trigger source

cmd$ = cmd$ + "50PCT," 'Trigger threshold

cmd$ = cmd$ + "1US," 'Trigger offset, must be > 125 ns

cmd$ = cmd$ + "PEAK," 'Peak detector

cmd$ = cmd$ + "8" 'Number of bursts

CALL InstrWrite(analyzer, cmd$)

CALL InstrRead(analyzer, result$) 'Read results

Print result$

END SUB

REM ************************************************************************

R&S FSL Fast Level Measurement Using Frequency Lists

1300.2519.12 7.19 E-11

Fast Level Measurement Using Frequency Lists

Atypical task for the R&S FSL is power measurement at a number of frequency points, e.g. at multiples

of the fundamental (harmonics measurement), or at frequencies defined by a mobile radio standard

(e.g. spectrum due to transients at ± 200 kHz, ± 400 kHz, etc about the carrier frequency of a GSM

signal). In many cases, different level and/or bandwidth settings are required for the different frequency

points to match the channel spacing and meet the requirements of dynamic range.

Especially for this application, the R&S FSL offers a number of remote–control functions (commands

available in SENSe:LIST subsystem) that allow level measurement based on a frequency list with

different instrument settings assigned to different frequencies. Not only the frequency list can be

programmed, but also the measurement types (PEAK, RMS, AVG) to be performed simultaneously can

be selected.

The example below describes a harmonics measurement on a dual–band amplifier. The harmonics

level in general decreases as the frequency increases. To boost measurement sensitivity, therefore, the

reference level is lowered by 10 dB from the third harmonic.

The following settings are used:

Reference level: 10.00 dBm up to first harmonic, 0 dBm from 2nd harmonic

RF attenuation: 20 dB

Electronic attenuation: 0 dB (OFF)

Filter type: NORMal

RBW: 1 MHz

VBW: 3 MHz

Measurement time: 300 µs

Trigger delay: 100 µs

Trigger: video, 45 %

Frequency Type

935.2 MHz GSM 900 fundamental

1805.2 MHz GSM 1800 fundamental

1870.4 MHz GSM 900 2nd harmonic

2805.6 MHz GSM 900 3rd harmonic

3610.4 MHz GSM 1800 2nd harmonic

3740.8 MHz GSM 900 4th harmonic

5815.6 MHz GSM 1800 3rd Harmonic

The frequencies are selected in ascending order to minimize system–inherent waiting times resulting

from frequency changes.

At each frequency point the peak power and the rms power are measured. The peak power and the rms

power values are stored alternately in the results memory.

REM ************************************************************************

Public Sub FrequencyList()

result$ = Space$(500)

'––––––––– R&S FSL default setting ––––––––––––––––––––––––––––––––––––––––

CALL SetupStatusReg 'Configure status register

CALL InstrWrite(analyzer,"*RST") 'Reset instrument

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Single sweep mode

CALL InstrWrite(analyzer,"SYST:DISP:UPD OFF")

'Display off

Level Correction of Transducers R&S FSL

1300.2519.12 7.20 E-11

'–––––––––Configure R&S FSL for power measurement based on frequency list –

CALL InstrWrite(analyzer, "TRIG:LEV:IFP –20dBm")

'Set IF power trigger level

CALL InstrWrite(analyzer, "LIST:POWer:SET ON,ON,OFF,IFP,POS,100us,0")

'––––––––– Perform measurement and query results –––––––––––––––––––––––––––

cmd$ = "LIST:POWer?"

cmd$ = cmd$ + "935.2MHZ,10dBm,20dB,OFF,NORM,1MHz,3MHz,300us,0,"

cmd$ = cmd$ + "1805.2MHZ,10dBm,20dB,OFF,NORM,1MHz,3MHz,300us,0,"

cmd$ = cmd$ + "1870.4MHZ,10dBm,20dB,OFF,NORM,1MHz,3MHz,300us,0,"

cmd$ = cmd$ + "2805.6MHZ,0dBm,20dB,OFF,NORM,1MHz,3MHz,300us,0,"

cmd$ = cmd$ + "3610.4MHz,10dBm,20dB,OFF,NORM,1MHz,3MHz,300us,0,"

cmd$ = cmd$ + "3740.8MHz,0dBm,20dB,OFF,NORM,1MHz,3MHz,300us,0,"

cmd$ = cmd$ + "5815.6MHz,0dBm,20dB,OFF,NORM,1MHz,3MHz,300us,0"

CALL InstrWrite(analyzer, cmd$)

CALL InstrRead(analyzer, result$)

Print result$

END SUB

REM ************************************************************************

Level Correction of Transducers

In more complex test systems, the frequency response of the test setup must be taken into account in

all power measurements to avoid any measurement errors being introduced from sources other than the

DUT.

The R&S FSL offers the possibility of defining a frequency–dependent attenuation correction factor

(transducer factor).

In the example below, a factor with the following characteristics is defined:

Name: Transtest

Unit: dB

Scaling: lin

Comment: simulated cable correction

Frequency Level

10 MHz 0 dB

100 MHz 3 dB

1GHz 7 dB

3GHz 10 dB

The factor is defined and can be activated as required.

REM ************************************************************************

Public Sub TransducerFactor()

'––––––––– Define transducer factor –––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"CORR:TRAN:SEL 'TRANSTEST'")

'Define "Transtest"

'transducer factor

CALL InstrWrite(analyzer,"CORR:TRAN:UNIT 'DB'")

'Unit 'dB'

R&S FSL Measuring the Magnitude and Phase of a Signal

1300.2519.12 7.21 E-11

CALL InstrWrite(analyzer,"CORR:TRAN:SCAL LIN")

'Linear frequency–axis

CALL InstrWrite(analyzer,"CORR:TRAN:COMM 'Simulated cable correction'")

cmd$ = "CORR:TRAN:DATA " 'Enter frequency and level

cmd$ = cmd$ + "10MHz, 0," 'values. Level values without

cmd$ = cmd$ + "100MHz, 3," 'unit!

cmd$ = cmd$ + "1GHz, 7,"

cmd$ = cmd$ + "3GHz, 10"

CALL InstrWrite(analyzer,cmd$) 'Enter frequency and level values

'––––––––– Activate transducer –––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"CORR:TRAN:STAT ON")

'Activate transducer factor

END SUB

REM ************************************************************************

Measuring the Magnitude and Phase of a Signal

Due to the R&S FSL's internal architecture, it is capable of measuring and outputting the magnitude and

phase of a signal in addition to its power values. This opens up a variety of possibilities for more in–

depth analysis (FFT, demodulation, etc).

I/Q data is stored in memory areas each containing 512 k words. Hardware triggering controls the

memory.

The following example shows the steps necessary to collect data at a predefined sampling rate and

read it from the I/Q memory.

Data is output in the form of voltage values referred to the analyzer input. Data can be read in binary or

ASCII format.

In binary format, the length information carried in the message header is evaluated and used for

calculating the x–axis values.

In ASCII format, only a list of voltage values is output.

Binary data is read in three steps:

1. The number of digits carrying the length information is read.

2. The length information itself is read.

3. The trace data is read.

This procedure is necessary with programming languages like Visual Basic which support only

structures of identical data types (arrays), whereas the binary data format uses different data types in

the header and the data section.

Note: The arrays for measured data are dimensioned in such a way that they can accommodate the

I/Q data of the R&S FSL (2 x 512 k).

Measuring the Magnitude and Phase of a Signal R&S FSL

1300.2519.12 7.22 E-11

REM ************************************************************************

Public Sub ReadIQData()

'––––––––– Create variables –––––––––––––––––––––––––––––––––––––––––––––––

Dim IData(131072) As Single 'Buffer for floating–point

'I data (= 512*1024 bytes)

Dim QData(131072) As Single 'Buffer for floating–point

'Q data (= 512*1024 bytes)

'Note:

'Visual Basic cannot read in

'data volumes larger than

'512 k words!

Dim digits As Byte 'No. of digits as length

Dim IQBytes As Long 'Length of trace data in bytes

Dim IQValues As Long 'No. of meas. values in buffer

Dim retCount As Integer 'Return count from read

asciiResult$ = Space$(6553600) 'Buffer for ASCII I/Q data

'(= 25*2*1024 bytes)

result$ = Space$(100) 'Buffer for simple results

'––––––––– Default setting –––––––––––––––––––––––––––––––––––––––

CALL SetupInstrument 'Default setting

CALL InstrWrite(analyzer,"TRAC:IQ:STAT ON")

'Activate I/Q data

'acquisition mode; must be

'done before TRAC:IQ:SET !

'Select number of test points

'(= 512 * 1024 – 512) at

'RBW 10 MHz, 'sample rate 32 MHz,

'trigger free run, pos. trigger

'edge and 0 s trigger delay.

CALL InstrWrite(analyzer,"TRAC:IQ:SET NORM,10MHz,32MHz,IMM,POS,0,130560")

'––––––––– Read–out in binary format––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer, "FORMAT REAL,32")

'Set binary format

CALL InstrWrite(analyzer, "TRAC:IQ:DATA?")

'Measure + read out I/Q data

CALL viRead(analyzer, result$, 2, retCount)

'Read and store length for

digits = Val(Mid$(result$, 2, 1)) 'number of digits

result$ = Space$(100) 'Re–initialize buffer

CALL viRead(analyzer, result$, digits, retCount)

'Read and store length

IQBytes = Val(Left$(result$, digits))

IQBytes = IQBytes / 2 'Divide no. per buffer in half

CALL viRead(analyzer, IData(0), IQBytes, retCount)

'Read I data in buffer

CALL viRead(analyzer, QData(0), IQBytes, retCount)

'Read Q data in buffer

R&S FSL Averaging I/Q Data

1300.2519.12 7.23 E-11

CALL viRead(analyzer, result$, 1, retCount)

'Read in end character <NL>

'––––––––– Output of binary data as frequency/level pair –––––––––––––––––

IQValues = IQBytes/4 'Single Precision = 4 Bytes

For i = 0 To IQValues – 1

Print "I–Value["; i; "] = "; IData(i)

Print "Q–Value["; i; "] = "; QData(i)

Next i

'––––––––– Read–out in ASCII format ––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"FORMAT ASCII") 'Set ASCII format

CALL InstrWrite(analyzer, "TRAC:IQ:DATA?")

'Re–measure and read out

'I/Q data

CALL InstrRead(analyzer, asciiResult$)

CALL InstrWrite(analyzer,"TRAC:IQ:STAT OFF")

'Stop I/Q data aquisition

'mode if no further

'measurements are to be

'done

END SUB

REM ************************************************************************

Averaging I/Q Data

The R&S FSL has averaging capability also for I/Q measurements, i.e. I/Q data can be averaged over

several test runs. This is subject to the following conditions:

1. An external trigger signal must be available for data measurement, and the trigger signal must be

phase–locked to the signal measured.

2. The same reference–frequency signal must be used for the DUT and the R&S FSL.

3. The sampling rate must be 32 MHz, since only with this sampling frequency will the measurement

be performed phase–synchronous with the trigger signal.

If all of the above conditions are fulfilled, no phase shift will occur between consecutive test runs. Phase

shift may falsify the measured average so that in extreme cases a value of 0 is obtained.

The default setting of the instrument for data measurement without averaging has to be changed as

follows:

REM ************************************************************************

'––––––––– R&S FSL default setting ––––––––––––––––––––––––––––––––––––––––

CALL SetupInstrument 'Default setting

CALL InstrWrite(analyzer,"TRAC:IQ:STAT ON")

'Activate I/Q data acquisition

'mode; this must be

'done before TRAC:IQ:SET!

'Select max. number of test points (= 512 * 1024 – 512) at 10 MHz RBW,

'32 MHz sampling rate, external

'trigger, pos. trigger edge and

'0 s trigger delay.

CALL InstrWrite(analyzer,"TRAC:IQ:SET NORM,10MHz,32MHz,EXT,POS,0,130560")

Reading and Writing Files R&S FSL

1300.2519.12 7.24 E-11

CALL InstrWrite(analyzer,"TRAC:IQ:AVER ON") 'Switch on I/Q averaging

CALL InstrWrite(analyzer,"TRAC:IQ:AVER:COUN 10") 'Set 10 test runs

'––––––––– Read data in binary format ––––––––––––––––––––––––––––––––––––––

...

REM ************************************************************************

Reading and Writing Files

Reading a File from the Instrument

In the following example, the TEST1.FSL.DFL file stored under C:\R_S\Instr\user is read from the

instrument and stored in the controller.

REM ************************************************************************

Public Sub ReadFile()

'––––––––– Generate variables ––––––––––––––––––––––––––––––––––––––––––––––

Dim digits As Byte 'Number of digits of

'length information

Dim fileBytes As Long 'Length of file with trace data

'in bytes

result$ = Space$(100) 'Buffer for simple results

'––––––––– Default setting of status register ––––––––––––––––––––––––––––––

CALL SetupStatusReg 'Configure status register

'––––––––– Read out file –––––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer, "MMEM:DATA? 'C:\R_S\Instr\user\TEST1.FSL.DFL'")

'Select file

CALL ilrd(analyzer, result$, 2) 'Read and store number of

digits = Val(Mid$(result$, 2, 1)) 'digits of length information

CALL ilrd(analyzer, result$, digits) 'Read and store length

fileBytes = Val(Left$(result$, digits)) 'information

FileBuffer$ = Space$(fileBytes) 'Buffer for file

CALL ilrd(analyzer, FileBuffer, fileBytes)

'Read file into buffer

CALL ilrd(analyzer, result$, 1) 'Read terminator <NL>

'––––––––– Store file to controller –––––––––––––––––––––––––––––––––––––––

Open "TEST1.FSL.DFL" For Output As #1

Print #1, FileBuffer; ' ; to avoid linefeed at

'end of file

Close #1

END SUB

REM ************************************************************************

R&S FSL Reading and Writing Files

1300.2519.12 7.25 E-11

Creating a File on the Instrument

In the following example, the TEST1.FSL.DFL file available on the controller is stored in the instrument

under C:\R_S\Instr\user\DUPLICAT.FSL.DFL.

REM ************************************************************************

Public Sub WriteFile()

'––––––––– Generate variables ––––––––––––––––––––––––––––––––––––––––––––––

FileBuffer$ = Space$(100000) 'Buffer for file

Dim digits As Long 'Number of digits of

'length information

Dim fileBytes As Long 'Length of file in bytes

fileSize$ = Space$(100) 'Length of file as a string

result$ = Space$(100) 'Buffer for simple results

'––––––––– Default setting of status register ––––––––––––––––––––––––––––––

CALL SetupStatusReg 'Configure status register

'––––––––– Prepare the definite length block data ––––––––––––––––––––––––––

fileBytes = FileLen("H:\work\vb\TEST1.FSL.DFL")

'Determine length of file

fileSize$ = Str$(fileBytes)

digits = Len(fileSize$) – 1 'Determine number of digits of

fileSize$ = Right$(fileSize$, digits) 'length information

FileBuffer$ = "#" + Right$(Str$(digits), 1) + fileSize$

'Store length information in

'file buffer

'––––––––– Read file from controller –––––––––––––––––––––––––––––––––––––––

Open "H:\work\vb\TEST1.FSL.DFL" For Binary As #1

FileBuffer$ = FileBuffer$ + Left$(Input(fileBytes, #1), fileBytes)

Close #1

'––––––––– Write file ––––––––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer, "SYST:COMM:GPIB:RTER EOI") 'Set receive

'terminator on the

'instrument

CALL InstrWrite(analyzer, "MMEM:DATA 'DUPLICAT.FSL.DFL'," + FileBuffer$)

'Select file

END SUB

REM ************************************************************************

Spectrum Emission Mask Measurement R&S FSL

1300.2519.12 7.26 E-11

Spectrum Emission Mask Measurement

You can configure Spectrum Emission Mask measurements via XML files provided for different

standards or by defining ranges and parameters. For both ways an example is given.

Using Predefined Standard Wibro

In the following example, the Spectrum Emission Mask measurement is configured using a predefined

standard XML file.

REM ************************************************************************

'––––––––– General settings of the instrument ––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"*RST") 'Reset instrument

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Switch to single sweep

CALL InstrWrite(analyzer,":SENSe1:SWEep:MODE ESPectrum")

'Set measurement mode

Rem After preset 3 ranges are available where the middle one is

Rem the reference range for calculating the TX power

CALL InstrWrite(analyzer,":SENSe1:FREQuency:CENTer 2.2GHz")

'Center frequency 2.2 GHz

CALL InstrWrite(analyzer,":SENSe1:DETector1 RMS")

'Set RMS detector

'––––––––– Setting up the gated trigger ––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":SENSe1:SWEep:EGATe ON")

'Switch on the external gate mode

CALL InstrWrite(analyzer,":SENSe1:SWEep:EGATe:SOURce EXTernal")

'Set enternal gate source

CALL InstrWrite(analyzer,":SENSe1:SWEep:EGATe:HOLDoff 0s")

'Set delay time to 0 s

CALL InstrWrite(analyzer,":SENSe1:SWEep:EGATe:LENGth 200 US")

'Set time interval

'––––––––– Setting the standard ––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"SENSe1:ESPectrum:PRESet:STANdard

'WIBRO\DL\PowerClass_29_40.xml'")

'Set WiBro standard

'––––––––– Measuring –––––––––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep, wait for sweep

'end

'––––––––– Reading out results –––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":TRACe1:DATA? LIST")

'Query list results

CALL InstrWrite(analyzer,":CALCulate:LIMit:FAIL?")

'Query result of limit check

CALL InstrRead(analyzer, result$)

REM ************************************************************************

R&S FSL Spectrum Emission Mask Measurement

1300.2519.12 7.27 E-11

Defining 5 Ranges with all Parameters

In the following example, the Spectrum Emission Mask measurement is configured by defining ranges

and parameters.

REM ************************************************************************

'––––––––– General settings of the instrument ––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"*RST") 'Reset instrument

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Switch to single sweep

CALL InstrWrite(analyzer,":SENSe1:SWEep:MODE ESPectrum")

'Set measurement mode

Rem After preset 3 ranges are available where the middle one is

Rem the reference range for calculating the TX power

CALL InstrWrite(analyzer,":SENSe1:FREQuency:CENTer 2.2GHz")

'Center frequency 2.2 GHz

CALL InstrWrite(analyzer,":SENSe1:DETector1 RMS")

'Set RMS detector

CALL InstrWrite(analyzer,":TRIGger1:SEQuence:SOURce IMMediate")

'Trigger setup

'––––––––– Setting up the gated trigger ––––––––––––––––––––––––––––––––––––

Rem If a free run trigger is not appropriate a gated trigger can

Rem the be set up (just comment in the following lines).

Rem CALL InstrWrite(analyzer,":SENSe1:SWEep:EGATe ON")

Rem Switch on the external gate mode

Rem CALL InstrWrite(analyzer,":SENSe1:SWEep:EGATe:SOURce EXTernal")

Rem Set enternal gate source

Rem CALL InstrWrite(analyzer,":SENSe1:SWEep:EGATe:HOLDoff 0s")

Rem Set delay time to 0 s

Rem CALL InstrWrite(analyzer,":SENSe1:SWEep:EGATe:LENGth 200 US")

Rem Set time interval

'––––––––– Setting the span ––––––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":SENSe1:FREQuency:SPAN 8 MHZ")

'Set the span to 8 MHz

'––––––––– Inserting new ranges ––––––––––––––––––––––––––––––––––––––––––––

Rem Enlarge number of ranges to 5 by adding one at the end

Rem and one at the beginnig. This ensures that the reference range

Rem remains in the middle

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:INSert AFTer")

'Insert a range after range 2

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:INSert BEFore")

'Insert a range before range 1

'––––––––– Defining the limit check for all ranges –––––––––––––––––––––––––

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe:LIMit:STATe AND")

'Set check for absolute and

'relative limit

Spectrum Emission Mask Measurement R&S FSL

1300.2519.12 7.28 E-11

'––––––––– Defining the reference range settings –––––––––––––––––––––––––––

Rem The bandwith of the reference range limits the minimum span

Rem of the reference range definition later in the script.

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RTYPe CPOWer")

'Set power reference type

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:BWID 2 MHZ")

'Set bandwidth

'––––––––– Defining the settings of range 1 ––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:FREQuency:STARt –4MHz")

'Set the start frequency

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:FREQuency:STOP –2MHz")

'Set the stop frequency

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:BANDwidth:RESolution

1MHZ")

'Set the resolution bandwidth

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:FILTer:TYPE CFILter")

'Set the channel filters

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:BANDwidth:VIDeo 3 MHZ")

'Set the video bandwidth to 3 MHz

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:SWEep:TIME 20 ms")

'Set the sweep time to 20 ms

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:RLEVel 5 DBM")

'Set the reference level to 5 dBm

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:INPut:ATTenuation 20 DB")

'Set the attenuation to 20 dB

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:LIMit:ABSolute:STARt

–50")

'Set an absolute limit of –50 dBm

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:LIMit:ABSolute:STOP –50")

'Set an absolute limit of –50 dBm

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:LIMit:RELative:STARt

–70")

'Set a relative limit of –70 dBc

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe1:LIMit:RELative:STOP –60")

'Set a relative limit of –60 dBc

'––––––––– Defining the settings of range 2 ––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:FREQuency:STARt –2MHz")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:FREQuency:STOP –1MHz")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:BANDwidth:RESolution

100 kHz")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:FILTer:TYPE NORM")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:BANDwidth:VIDeo 300 kHZ")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:SWEep:TIME 50 ms")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:RLEVel 10 DBM")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:INPut:ATTenuation 30 DB")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:LIMit:ABSolute:STARt

–40")

R&S FSL Spectrum Emission Mask Measurement

1300.2519.12 7.29 E-11

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:LIMit:RELative:STARt

–60")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:LIMit:ABSolute:STOP –40")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe2:LIMit:RELative:STOP –40")

'––––––––– Defining the settings of range 3 ––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:FREQuency:STARt –1MHz")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:FREQuency:STOP 1MHz")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:BANDwidth:RESolution

30 kHZ")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:FILTer:TYPE NORM")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:BANDwidth:VIDeo 100 kHZ")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:SWEep:TIME 5 ms")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:RLEVel 20 DBM")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:INPut:ATTenuation 30 DB")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:LIMit:ABSolute:STARt

200")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:LIMit:ABSolute:STOP 200")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:LIMit:RELative:STARt

200")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe3:LIMit:RELative:STOP 200")

'––––––––– Defining the settings of range 4 ––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:FREQuency:STARt 1MHz")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:FREQuency:STOP 2MHz")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:BANDwidth:RESolution

100 kHz")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:FILTer:TYPE NORM")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:BANDwidth:VIDeo 300 kHZ")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:SWEep:TIME 50 ms")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:RLEVel 10 DBM")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:INPut:ATTenuation 30 DB")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:LIMit:ABSolute:STARt

–40")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:LIMit:ABSolute:STOP –40")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:LIMit:RELative:STARt

–40")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe4:LIMit:RELative:STOP –60")

'––––––––– Defining the settings of range 5 ––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:FREQuency:STARt 2MHz")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:FREQuency:STOP 4MHz")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:BANDwidth:RESolution

1MHZ")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:FILTer:TYPE CFILter")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:BANDwidth:VIDeo 3 MHZ")

Spurious Emissions Measurement R&S FSL

1300.2519.12 7.30 E-11

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:SWEep:TIME 20 ms")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:RLEVel 5 DBM")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:INPut:ATTenuation 20 DB")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:LIMit:ABSolute:STARt

–50")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:LIMit:ABSolute:STOP –50")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:LIMit:RELative:STARt

–60")

CALL InstrWrite(analyzer,":SENSe1:ESPectrum:RANGe5:LIMit:RELative:STOP –70")

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep, wait for sweep

'end

'––––––––– Reading out results –––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":TRACe1:DATA? LIST")

'Query list results

CALL InstrWrite(analyzer,":CALCulate:LIMit:FAIL?")

'Query result of limit check

CALL InstrRead(analyzer, result$)

REM ************************************************************************

Spurious Emissions Measurement

In the following example, the Spurious Emissions measurement is configured by defining ranges and

parameters.

REM ************************************************************************

'––––––––– General settings of the instrument ––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"*RST") 'Reset instrument

Rem After preset 4 ranges are available. Range settings can be questioned

Rem independent from the set measurement mode.

'––––––––– Deleting all ranges –––––––––––––––––––––––––––––––––––––––––––––

Rem Delete all ranges to prepare for setting up a new measurement

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe4:DELete")

'Delete range 4

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe3:DELete")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:DELete")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:DELete")

'––––––––– Defining the start frequency for all ranges –––––––––––––––––––––

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:FREQuency:STARt 1000000")

Rem Setting the start frequency of range 1 will create the ranges and

Rem every other range value will be set to the default value.

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:FREQuency:STARt 2000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe3:FREQuency:STARt 3000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe4:FREQuency:STARt 4000000")

R&S FSL Spurious Emissions Measurement

1300.2519.12 7.31 E-11

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe5:FREQuency:STARt 5000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe:COUNT?")

'Queries the number of defined

'ranges

'––––––––– Querying the parameters of range 1 ––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:FREQuency:STARt?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:FREQuency:STOP?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:FILTer:TYPE?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:BANDwidth:RESolution?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:BANDwidth:VIDeo?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:SWEep:TIME:AUTO?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:DETector?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:RLEVel?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:INPut:ATTenuation:AUTO?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:INPut:GAIN:STATe?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:BREak?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:TRANsducer?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:SWEep:TIME?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:INPut:ATTenuation?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:POINts?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:LIMit:STARt?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:LIMit:STOP?")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:LIMit:STATe?")

'––––––––– Changing into the Spurious Emissions measurement mode –––––––––––

CALL InstrWrite(analyzer,":SENSe1:SWEEP:MODE LIST")

Rem In continuous sweep mode, editing the ranges is not allowed.

Rem You have to stop the measurement first.

Rem In single sweep mode, you can edit the ranges at the end of the sweep.

'––––––––– Single sweep version ––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Switch to single sweep

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:FREQuency:STARt 500000")

'Change the start frequency

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep, wait for sweep

'end

'––––––––– Continuous sweep version ––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,"INIT:CONT ON") 'Switch to continuous sweep

CALL InstrWrite(analyzer,"ABORt") 'Stop the measurement

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:FREQuency:STARt 500000")

'Change the start frequency

CALL InstrWrite(analyzer,":INITiate1:SPURious") 'Restart the measurement

Spurious Emissions Measurement R&S FSL

1300.2519.12 7.32 E-11

'––––––––– Defining the range settings in single sweep mode ––––––––––––––––

CALL InstrWrite(analyzer,"INIT:CONT OFF") 'Switch to single sweep

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep, wait for sweep

'end

Rem Edit one range at a time. Make sure to edit the ranges in a correct

Rem order to prevent limit violations. Ranges cannot overlap.

Rem The best way is to start with range 1.

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:FREQuency:STARt 500000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:FREQuency:STOP 550000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:FILTer:TYPE NORM")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:BANDwidth:RESolution 3000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:BANDwidth:VIDeo 10000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:SWEep:TIME:AUTO ON")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:DETector RMS")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:RLEVel –10")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:INPut:ATTenuation:AUTO ON")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:POINts 8001")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:INPut:GAIN:STATe OFF")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:BREak OFF")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:LIMit:STARt –20")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:LIMit:STOP –20")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:LIMit:STATe ON")

Rem Proceed with range 2.

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:FREQuency:STARt 1000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:FREQuency:STOP 200000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:FILTer:TYPE CFILter")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:BANDwidth:RESolution 5000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:DETector POS")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:RLEVel –20")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:INPut:ATTenuation 0")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:POINts 32001")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe2:INPut:GAIN:STATe ON")

Rem Proceed with range 3.

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe3:FREQuency:STARt 250000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe3:FREQuency:STOP 1000000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe3:FILTer:TYPE RRC")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe3:POINts 32001")

Rem Proceed with range 4.

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe4:FREQuency:STARt 1200000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe4:FREQuency:STOP 4000000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe4:FILTer:TYPE PULSe")

R&S FSL Spurious Emissions Measurement

1300.2519.12 7.33 E-11

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe4:POINts 251")

Rem Proceed with range 5.

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe5:FREQuency:STARt 5000000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe5:FREQuency:STOP 6000000000")

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe5:POINts 7001")

'––––––––– Defining the limit check for all ranges –––––––––––––––––––––––––

CALL InstrWrite(analyzer,"SENSe1:LIST:RANGe1:LIMit:STATe ON")

'Activate the limit check

'––––––––– Setting the span to include all ranges ––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":SENSe1:FREQuency:STARt 500000")

CALL InstrWrite(analyzer,":SENSe1:FREQuency:STOP 6000000000")

CALL InstrWrite(analyzer,"INIT;*WAI") 'Perform sweep, wait for sweep

'end

'––––––––– Reading out results –––––––––––––––––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer,":TRACe1:DATA? LIST")

'Query list results

CALL InstrWrite(analyzer,":CALCulate1:PSEarch[:IMMediate]")

'Deactivate limit line and

'just look for peaks

Rem Or set margin to 200 in order to find all peaks

CALL InstrWrite(analyzer,":TRACe1:DATA? SPUR")

'Query just the peaks

CALL InstrWrite(analyzer,":CALCulate:LIMit:FAIL?")

'Query result of limit check

CALL InstrRead(analyzer, result$)

REM ************************************************************************

WLAN TX Measurements – Programming Examples (Option K91/K91n) R&S FSL

1300.2519.12 7.34 E-11

WLAN TX Measurements – Programming Examples

(Option K91/K91n)

The following section provides some examples of commonly performed operations when using the

WLAN TX Measurements option (K91/K91n). For more general remote control examples refer to the

programming examples in this chapter.

This option is available from firmware version 1.20.

Synchronization Entry of Option

The following example shows how to synchronize entering the WLAN TX Measurements option.

analyzer = 20 'Instrument address

CALL InstrWrite(analyzer, "INST:SEL WLAN;*OPC?")

'waits for 1 from *OPC?

Selecting Measurements

Measurements are selected using the command CONFigure:BURSt:<Meas Type> where <Meas

Type> is as follows:

<Meas Type> Measurement Type

PVT Power vs Time (PVT)

PVT:SELect EDGE PVT rising and falling edge

PVT:SELect FULL PVT full burst (802.11a only)

PVT:SELect RISE PVT rising burst (802.11b only)

PVT:SELect FALL PVT falling burst (802.11b only)

EVM:ECARrier EVM vs Carrier

EVM:ESYMbol EVM vs Symbol

SPECtrum:MASK Spectrum Mask

SPECtrum:MASK:SELect IEEE Spectrum Mask IEEE

SPECtrum:MASK:SELect ETSI Spectrum Mask ETSI

SPECtrum:FLATness Spectrum Flatness

SPECtrum:FFT Spectrum FFT

SPECtrum:ACPR Spectrum ACPR

CONstellation:CCARrier Constellation vs Carrier

CONstellation:CSYMbol Constellation vs Symbol

STATistics:CCDF CCDF

R&S FSL WLAN TX Measurements – Programming Examples (Option K91/K91n)

1300.2519.12 7.35 E-11

<Meas Type> Measurement Type

STATistics:BSTReam Bit Steam

STATistics:SFIeld Signal Field

The following example shows how to select a Spectrum Mark ETSI measurement:

REM select Spectrum Mask Select ETSI

CALL InstrWrite(analyzer, "SPECtrum:MASK:SELect:ETSI")

Running Synchronized Measurements

The following examples show how measurements can be synchronized. Synchronization is necessary to

ensure that the measurement has completed before the measurement results and markers are

requested.

PUBLIC SUB SweepSync()

REM The command INITiate[:IMMediate] starts a single sweep if the

REM command INIT:CONT OFF was previously sent. It should be ensured that

REM the next command is only then executed when the entire sweep is

REM complete.

CALL InstrWrite(analyzer, "INIT:CONT OFF")

REM –––––– First possibility: Use of *WAI ––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer, "INIT:IMM;*WAI")

REM –––––– Second possibility: Use of *OPC? ––––––––––––––––––––––––––––

OpcOk$ = SPACE$(2) 'Space for *OPC? 'Provide response

CALL InstrWrite(analyzer, "INIT:IMM;*OPC?")

REM –––––– Here the controller can service other instrument–––––––––––––

CALL InstrRead(analyzer, OpcOk$) 'Wait for "1" from *OPC?

REM ––––––– Third possibility: Use of *OPC –––––––––––––––––––––––––––––

REM In order to be able to use the service request function in

REM conjugation with a National Instruments GPIB driver, the setting

REM "Disable Auto Serial Poll" must be changed to "yes" by means of

REM the GPIB configuration

REM (e.g. Windows Start menu: Settings –> Control Panel –> GPIB)!

CALL InstrWrite(analyzer, "*SRE 32") 'Permit service request for ESR

CALL InstrWrite(analyzer, "*ESE 1") 'Set event–enable bit for

'operation–complete bit

CALL InstrWrite(analyzer, "INIT:IMM;*OPC") 'Start sweep and

'synchronize with OPC

status = viWaitOnEvent(vi, VI_EVENT_SERVICE_REQ, SRQWaitTimeout, VI_NULL,

VI_NULL) 'Wait for service request

WLAN TX Measurements – Programming Examples (Option K91/K91n) R&S FSL

1300.2519.12 7.36 E-11

REM ––––––– Fourth possibility: Use of INIT:IMM ––––––––––––––––––––––––

REM In order to be able to use the service request function in

REM conjugation with a National Instruments GPIB driver, the setting

REM "Disable Auto Serial Poll" must be changed to "yes" by means of

REM the GPIB configuration

REM (e.g. Windows Start menu: Settings –> Control Panel –> GPIB)!

CALL InstrWrite(analyzer, "*SRE 128") 'Permit service request for ESR

CALL InstrWrite(analyzer, "*ESE 0") 'Set event–enable bit for

'operation–complete bit

CALL InstrWrite(analyzer, "STATus:OPERation:ENABle 16")

'Enable bit 4 of status operation

'register'

CALL InstrWrite(analyzer, "STAT:OPERation:NTRansition 16")

'Set Negative transition to 1

CALL InstrWrite(analyzer, "STATus:OPERation:PTRansition 0")

'Set Positive transition to 0

CALL InstrWrite(analyzer, "INIT:IMM") 'Start sweep and synchronize with

'OPC

status = viWaitOnEvent(vi, VI_EVENT_SERVICE_REQ, SRQWaitTimeout, VI_NULL,

VI_NULL) 'Wait for service request

REM Continue main program here.

END SUB

REM ***********************************************************************

R&S FSLWiMAX, WiBro Measurements - Programming Examples (K92/93)

1300.2519.12 7.37 E-11

WiMAX, WiBro Measurements – Programming Examples

(Options K92/93)

The following section provides some examples of commonly performed operations when using the

WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K93). For more general remote

control examples refer to the other programming examples in this chapter.

The WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K93) includes the

functionality of the WiMAX 802.16 OFDM Measurements option (R&S FSL–K92). Accordingly both

options are described together in this section. The options are available from firmware version 1.40

(R&S FSL–K92) and 1.50 (R&S FSL–K93).

Synchronization Entry of Option

The following example shows how to synchronize entering the WiMAX IEEE 802.16 OFDM, OFDMA

Measurements option.

analyzer = 20 'Instrument address

CALL InstrWrite(analyzer, "INST:SEL WLAN;*OPC?")

'waits for 1 from *OPC?

Selecting Measurements

Measurements are selected using the command CONFigure:BURSt:<Meas Type> where <Meas

Type> is as follows:

<Meas Type> Measurement Type

PVT Power vs Time (PVT)

PVT:SELect EDGE PVT Start and End (OFDM)

PVT Rsing / Falling (OFDMA & WiBro)

PVT:SELect FULL PVT Full Burst (OFDM)

PVT Full Subframe (OFDMA & WiBro)

EVM:ECARrier EVM vs Carrier

EVM:ESYMbol EVM vs Symbol

SPECtrum:MASK Spectrum Mask

SPECtrum:MASK:SELect IEEE Spectrum Mask IEEE

SPECtrum:MASK:SELect ETSI Spectrum Mask ETSI

SPECtrum:FLATness Spectrum Flatness

SPECtrum:FLATness:SELect FLATNESS Spectrum Flatness

SPECtrum:FLATness:SELect GRDELAY Spectrum Flatness – Group Delay

SPECtrum:FLATness:SELect DIFFERENCE Spectrum Flatness – Difference

SPECtrum:FFT Spectrum FFT

WiMAX, WiBro Measurements - Programming Examples (K92/93) R&S FSL

1300.2519.12 7.38 E-11

<Meas Type> Measurement Type

SPECtrum:ACPR Spectrum ACPR

SPECtrum:ACPR:SELect ABS Spectrum ACPR (Absolute)

SPECtrum:ACPR:SELect REL Spectrum ACPR (Relative)

CONSt:CCARrier Constellation vs Carrier

CONSt:CSYMbol Constellation vs Symbol

STATistics:CCDF CCDF

STATistics:BSTReam Bit Steam

STATistics:BSUMmary Burst Summary

PREamble Preamble Error

PREamble:SELect FREQ Frequency Error vs Preamble

PREamble:SELect PHASE Phase Error vs Preamble

The following example shows how to select a Spectrum Mask ETSI measurement:

REM select Spectrum Mask Select ETSI

CALL InstrWrite(analyzer, "SPECtrum:MASK:SELect:ETSI")

Running Synchronized Measurements

The following examples show how measurements can be synchronized. Synchronization is necessary to

ensure that the measurement has completed before the measurement results and markers are

requested.

PUBLIC SUB SweepSync()

REM The command INITiate[:IMMediate] starts a single sweep if the

REM command INIT:CONT OFF was previously sent. It should be ensured that

REM the next command is only then executed when the entire sweep is

REM complete.

CALL InstrWrite(analyzer, "INIT:CONT OFF")

REM –––––– First possibility: Use of *WAI ––––––––––––––––––––––––––––––

CALL InstrWrite(analyzer, "INIT:IMM;*WAI")

REM –––––– Second possibility: Use of *OPC? ––––––––––––––––––––––––––––

OpcOk$ = SPACE$(2) 'Space for *OPC? 'Provide response

CALL InstrWrite(analyzer, "INIT:IMM;*OPC?")

REM –––––– Here the controller can service other instrument–––––––––––––

CALL InstrRead(analyzer, OpcOk$) 'Wait for "1" from *OPC?

R&S FSLWiMAX, WiBro Measurements - Programming Examples (K92/93)

1300.2519.12 7.39 E-11

REM ––––––– Third possibility: Use of *OPC –––––––––––––––––––––––––––––

REM In order to be able to use the service request function in

REM conjugation with a National Instruments GPIB driver, the setting

REM "Disable Auto Serial Poll" must be changed to "yes" by means of

REM the GPIB configuration

REM (e.g. Windows Start menu: Settings –> Control Panel –> GPIB)!

CALL InstrWrite(analyzer, "*SRE 32") 'Permit service request for ESR

CALL InstrWrite(analyzer, "*ESE 1") 'Set event–enable bit for

'operation–complete bit

CALL InstrWrite(analyzer, "INIT:IMM;*OPC") 'Start sweep and

'synchronize with OPC

status = viWaitOnEvent(vi, VI_EVENT_SERVICE_REQ, SRQWaitTimeout, VI_NULL,

VI_NULL) 'Wait for service request

REM ––––––– Fourth possibility: Use of INIT:IMM ––––––––––––––––––––––––

REM In order to be able to use the service request function in

REM conjugation with a National Instruments GPIB driver, the setting

REM "Disable Auto Serial Poll" must be changed to "yes" by means of

REM the GPIB configuration

REM (e.g. Windows Start menu: Settings –> Control Panel –> GPIB)!

CALL InstrWrite(analyzer, "*SRE 128") 'Permit service request for ESR

CALL InstrWrite(analyzer, "*ESE 0") 'Set event–enable bit for

'operation–complete bit

CALL InstrWrite(analyzer, "STATus:OPERation:ENABle 16")

'Enable bit 4 of status operation

'register'

CALL InstrWrite(analyzer, "STAT:OPERation:NTRansition 16")

'Set Negative transition to 1

CALL InstrWrite(analyzer, "STATus:OPERation:PTRansition 0")

'Set Positive transition to 0

CALL InstrWrite(analyzer, "INIT:IMM") 'Start sweep and synchronize with

'OPC

status = viWaitOnEvent(vi, VI_EVENT_SERVICE_REQ, SRQWaitTimeout, VI_NULL,

VI_NULL) 'Wait for service request

REM Continue main program here.

END SUB

REM ***********************************************************************

R&S FSL Maintenance

1300.2519.12 I-8.1 E-11

Contents of Chapter 8

8Maintenance ........................................................................................................ 8.1

Storing and Packing.........................................................................................................................8.1

List of Power Cables Available .......................................................................................................8.1

R&S FSL Maintenance

1300.2519.12 8.1 E-11

8Maintenance

The following chapter contains information on the maintenance of the R&S FSL. The instrument does

not need a periodic maintenance. What is necessary is essentially the cleaning of the instrument.

However, it is recommended to check the rated data from time to time.

Follow the instructions in the service manual and the safety instructions when exchanging modules or

ordering spares. The order no. for spare parts is included in the service manual. The service manual

includes further information particularly on troubleshooting, repair, exchange of modules (including

battery exchange, adjustment of the OCXO oscillator) and alignment.

The address of our support center and a list of all Rohde & Schwarz service centers can be found at the

beginning of this manual.

Storing and Packing

The storage temperature range of the instrument is given in the data sheet. If the instrument is to be

stored for a longer period of time, it must be protected against dust.

Repack the instrument as it was originally packed when transporting or shipping. The two protective

foam plastic parts prevent the control elements and connectors from being damaged. The antistatic

packing foil avoids any undesired electrostatic charging to occur.

If you do not use the original packaging, provide for sufficient padding to prevent the instrument from

slipping inside the package. Wrap antistatic packing foil around the instrument to protect it from

electrostatic charging.

List of Power Cables Available

Table 8–1 List of power cables available

Stock No. Earthed–contact connector Preferably used in

DS 006.7013.00 BS1363: 1967' complying with

IEC 83: 1975 standard B2

Great Britain

DS 006.7020.00 Type 12 complying with SEV–regulation

1011.1059, standard sheet S 24 507

Switzerland

DS 006.7036.00 Type 498/13 complying with

US–regulation UL 498, or with IEC 83

USA / Canada

DS 006.7107.00 Type SAA3 10 A, 250 V,

complying with AS C112–1964 Ap.

Australia

DS 0025.2365.00

DS 0099.1456.00

DIN 49 441, 10 A, 250 V, angular

DIN 49 441, 10 A, 250 V, straight

Europe (except Switzerland)

R&S FSL Error Messages

1300.2519.12 I-9.1 E-11

Contents of Chapter 9

9Error Messages ................................................................................................... 9.1

SCPI–Specific Error Messages .......................................................................................................9.1

Device–Specific Messages ..............................................................................................................9.7

Noise Figure Measurements Option Messages (K30) ..................................................................9.8

3GPP Base Station Measurements Option Messages (K72) ........................................................9.9

WLAN TX Measurements Option Messages (K91/K91n)............................................................9.10

WiMAX IEEE 802.16 OFDM, OFDMA Measurements Option Messages (K92/K93) ..................9.11

R&S FSL SCPI–Specific Error Messages

1300.2519.12 9.1 E-11

9 Error Messages

Error messages are entered in the error/event queue of the status reporting system in the remote

control mode and can be queried with the command SYSTem:ERRor?.The answer format of R&S FSL

tothe command is as follows:

<error code>, "<error text with queue query>;

<remote control command concerned>"

The indication of the remote control command with prefixed semicolon is optional.

Example:

The command "TEST:COMMAND"generates the following answer to the query SYSTem:ERRor?

–113,"Undefined header;TEST:COMMAND"

The subsequent lists contain the description of error texts displayed on the instrument.

Distinction is made between error messages defined by SCPI, which are marked by negative error

codes, and the device–specific error messages for which positive error codes are used:

•SCPI–Specific Error Messages

•Device–Specific Messages

The right–hand column in the following tables contains the error text in bold which is entered in the

error/event queue and can be read out by means of query SYSTem:ERRor?. A short explanation of the

error cause is given below. The left–hand column contains the associated error code.

Additionally, option–specific warnings and error messages displayed in the status bar are explained.

SCPI–Specific Error Messages

Table 9–1 No Error

Error code Error text in the case of queue poll

Error explanation

0No error

This message is displayed if the error queue does not contain any entries.

Table 9–2 Command Error – Faulty command; sets bit 5 in the ESR register.

Error code Error text in the case of queue poll

Error explanation

–100 Command Error

The command is faulty or invalid.

–101 Invalid Character

The command contains an invalid sign.

Example: A header contains an ampersand, "SENSe&".

SCPI–Specific Error Messages R&S FSL

1300.2519.12 9.2 E-11

Error code Error text in the case of queue poll

Error explanation

–102 Syntax error

The command is invalid.

Example: The command contains block data the instrument does not accept.

–103 Invalid separator

The command contains an invalid sign instead of a separator.

Example: A semicolon is missing after the command.

–104 Data type error

The command contains an invalid value indication.

Example: ON is indicated instead of a numeric value for frequency setting.

–105 GET not allowed

AGroup Execute Trigger (GET) is within a command line.

–108 Parameter not allowed

The command contains too many parameters.

Example: Command SENSe:FREQuency:CENTer permits only one frequency indication.

–109 Missing parameter

The command contains too few parameters.

Example: The command SENSe:FREQuency:CENTer requires a frequency indication.

–110 Command header error

The header of the command is faulty.

–111 Header separator error

The header contains an invalid separator.

Example: the header is not followed by a "White Space", "*ESE255"

–112 Program mnemonic too long

The header contains more than 12 characters.

–113 Undefined header

The header is not defined for the instrument.

Example: *XYZ is undefined for every instrument.

–114 Header suffix out of range

The header contains an invalid numeric suffix.

Example: SENSe3 does not exist in the instrument.

–120 Numeric data error

The command contains a faulty numeric parameter.

–121 Invalid character in number

Anumber contains an invalid character.

Example: An "A" in a decimal number or a "9" in an octal number.

–123 Exponent too large

The absolute value of the exponent is greater than 32000.

–124 Too many digits

The number includes too many digits.

–128 Numeric data not allowed

The command includes a number which is not allowed at this position.

Example: The command INPut:COUPling requires indication of a text parameter.

–130 Suffix error

The command contains a faulty suffix.

R&S FSL SCPI–Specific Error Messages

1300.2519.12 9.3 E-11

Error code Error text in the case of queue poll

Error explanation

–131 Invalid suffix

The suffix is invalid for this instrument.

Example: nHz is not defined.

–134 Suffix too long

The suffix contains more than 12 characters.

–138 Suffix not allowed

Asuffix is not allowed for this command or at this position of the command.

Example: The command *RCL does not permit a suffix to be indicated.

–140 Character data error

The command contains a faulty text parameter

–141 Invalid character data

The text parameter either contains an invalid character or it is invalid for this command.

Example: Write error with parameter indication;INPut:COUPling XC.

–144 Character data too long

The text parameter contains more than 12 characters.

–148 Character data not allowed

The text parameter is not allowed for this command or at this position of the command.

Example: The command *RCL requires a number to be indicated.

–150 String data error

The command contains a faulty string.

–151 Invalid string data

The command contains a faulty string.

Example: An END message has been received prior to the terminating apostrophe.

–158 String data not allowed

The command contains an allowed string at an invalid position.

Example: A text parameter is set in quotation marks, INPut:COUPling "DC"

–160 Block data error

The command contains faulty block data.

–161 Invalid block data

The command contains faulty block data.

Example: An END message was received prior to reception of the expected number of data.

–168 Block data not allowed

The command contains allowed block data at an invalid position.

Example: The command *RCL requires a number to be indicated.

–170 Expression error

The command contains an invalid mathematical expression.

–171 Invalid expression

The command contains an invalid mathematical expression.

Example: The expression contains mismatching parentheses.

–178 Expression data not allowed

The command contains a mathematical expression at an invalid position.

SCPI–Specific Error Messages R&S FSL

1300.2519.12 9.4 E-11

Table 9–3 Execution Error – Error on execution of a command; sets bit 4 in the ESR register

Error code Error text in the case of queue poll

Error explanation

–200 Execution error

Error on execution of the command.

–201 Invalid while in local

The command is not executable while the device is in local due to a hard local control.

Example: The device receives a command which would change the rotary knob state, but the device is in

local so the command can not be executed.

–202 Settings lost due to rtl

Asetting associated with hard local control was lost when the device changed to LOCS from REMS or to

LWLS from RWLS.

–210 Trigger error

Error on triggering the device.

–211 Trigger ignored

The trigger (GET, *TRG or trigger signal) was ignored because of device timing considerations.

Example: The device was not ready to respond.

–212 Arm ignored

An arming signal was ignored by the device.

–213 Init ignored

Measurement initialization was ignored as another measurement was already in progress.

–214 Trigger deadlock

The trigger source for the initiation of measurement is set to GET and subsequent measurement is

received. The measurement cannot be started until a GET is received, but the GET would cause an

interrupted–error)

–215 Arm deadlock

The trigger source for the initiation of measurement is set to GET and subsequent measurement is

received. The measurement cannot be started until a GET is received, but the GET would cause an

interrupted–error.

–220 Parameter error

The command contains a faulty or invalid parameter.

–221 Settings conflict

There is a conflict between setting of parameter value and instrument state.

–222 Data out of range

The parameter value lies out of the allowed range of the instrument.

–223 Too much data

The command contains too many data.

Example: The instrument does not have sufficient storage space.

–224 Illegal parameter value

The parameter value is invalid.

Example: The text parameter is invalid , TRIGger:SWEep:SOURce TASTe

–230 Data corrupt or stale

The data are incomplete or invalid.

Example: The instrument has aborted a measurement.

–231 Data questionable

The measurement accuracy is suspect.

R&S FSL SCPI–Specific Error Messages

1300.2519.12 9.5 E-11

Error code Error text in the case of queue poll

Error explanation

–240 Hardware error

The command cannot be executed due to problems with the instrument hardware.

–241 Hardware missing

Hardware is missing.

Example: An option is not fitted.

–250 Mass storage error

Amass storage error occurred.

–251 Missing mass storage

The mass storage is missing.

Example: An option is not installed.

–252 Missing media

The media is missing.

Example: There is no floppy in the floppy disk drive.

–253 Corrupt media

The media is corrupt.

Example: The floppy is bad or has the wrong format.

–254 Media full

The media is full.

Example: There is no room on the floppy.

–255 Directory full

The media directory is full.

–256 File name not found

The file name cannot be found on the media.

–257 File name error

The file name is wrong.

Example: An attempt is made to copy to a duplicate file name.

–258 Media protected

The media is protected.

Example: The write–protect tab on the floppy is present.

–260 Expression error

The expression contains an error.

SCPI–Specific Error Messages R&S FSL

1300.2519.12 9.6 E-11

Table 9–4 Device Specific Error; sets bit 3 in the ESR register

Error code Error test in the case of queue poll

Error explanation

–300 Device–specific error

R&S FSL–specific error not defined in greater detail.

–310 System error

This error message suggests an error within the instrument. Please inform the R&S Service.

–313 Calibration memory lost

Loss of the non–volatile data stored using the *CAL? command. This error occurs when the correction

data recording has failed.

–330 Self–test failed

The self test could not be executed.

–350 Queue overflow

This error code is entered in the queue instead of the actual error code if the queue is full. It indicates

that an error has occurred but not been accepted. The queue can accept 5 entries.

Table 9–5 Query Error – Error in data request; sets bit 2 in the ESR register

Error code Error text in the case of queue poll

Error explanation

–400 Query error

General error occurring when data are requested by a query.

–410 Query INTERRUPTED

The query has been interrupted.

Example: After a query, the instrument receives new data before the response has been sent completely.

–420 Query UNTERMINATED

The query is incomplete.

Example: The instrument is addressed as a talker and receives incomplete data.

–430 Query DEADLOCKED

The query cannot be processed.

Example: The input and output buffers are full, the instrument cannot continue operation.

–440 Query UNTERMINATED after indefinite response

Aquery is in the same command line after a query which requests an indefinite response.

R&S FSL Device–Specific Messages

1300.2519.12 9.7 E-11

Device–Specific Messages

Error code Error text in the case of queue poll

Error explanation

1052 Frontend LO is Unlocked

This message is displayed when the phase regulation of the local oscillator fails in the RF front–end.

1060 Trigger–Block Gate Delay Error– gate length < Gate Delay

This message is displayed when the gate signal length is not sufficient for the pull–in delay with a

predefined gate delay.

1064 Tracking LO is Unlocked

This message is displayed when the phase regulation of the local oscillator fails on the tracking generator

module.

2028 Hardcopy not possible during measurement sequence

This message is displayed when a printout is started during scan sequences that cannot be interrupted.

Such sequences are for example:

•Recording the system error correction data (alignment)

•Instrument self test

In such cases synchronization to the end of the scan sequence should be performed prior to starting the

printout.

2033 Printer Not Available

This message is displayed when the selected printer is not included in the list of available output devices.

Apossible cause is that the required printer driver is missing or incorrectly installed.

2034 CPU Temperature is too high

This message is displayed when the temperature of the processor exceeds 70 °C.

Noise Figure Measurements Option Messages (K30) R&S FSL

1300.2519.12 9.8 E-11

Noise Figure Measurements Option Messages (K30)

The list of possible warning & error messages for the Noise Figure Measurements option (K30) is

shown below.

This option is available from firmware version 1.50.

Status bar message Description

Frequency list truncated, max 100 entries The settings for start, stop and step frequencies would require a

frequency list greater than 100 entries. The list calculated is

terminated at the 100th entry. Try using a larger step size of splitting

the test up into a series of frequency list tests.

Missing [ENR][,|&][LossIn][,|&][LossOut] for meas.freq. No ENR, loss input and/or loss output can be determined for one or

all of the measurement frequencies. This occurs when using tables

of ENR, loss input and/or loss output values. Check that the

frequency ranges of the tables covers the range of frequencies to be

measured. For each measurement frequency, where ENR, loss

input or loss output cannot be determined, 0 is used.

R&S FSL 3GPP Base Station Measurements Option Messages (K72)

1300.2519.12 9.9 E-11

3GPP Base Station Measurements Option Messages (K72)

The list of possible warning & error messages is shown below.

This option is available from firmware version 1.50.

Status bar message Description

Sync not found This message is displayed if synchronization is not possible.

Possible causes are that frequency, level, scrambling code, Invert Q

values are set incorrectly, or the input signal is invalid.

Sync OK This message is displayed if synchronization is possible.

Incorrect pilot symbols This message is displayed if one or more of the received pilot symbols

are not equal to the specified pilot symbols of the 3GPP standard.

Possible causes are:

Incorrectly sent pilot symbols in the received frame.

Low signal to noise ratio (SNR) of the WCDMA signal.

One or more code channels have a significantly lower power level

compared to the total power. The incorrect pilots are detected in these

channels because of low channel SNR.

One or more channels are sent with high power ramping. In slots with

low relative power to total power, the pilot symbols might be detected

incorrectly (check the signal quality by using the symbol constellation

display).

WLAN TX Measurements Option Messages (K91/K91n) R&S FSL

1300.2519.12 9.10 E-11

WLAN TX Measurements Option Messages (K91/K91n)

The list of possible warning & error messages is shown below.

This option is available from firmware version 1.20.

Status bar message Description

Gate length too small – must be greater than 1 This message is only displayed for the FFT measurement. This

message indicates that there are no samples contained within the

gating lines. Increase the Gate length and then, in the sweep menu,

press the Refresh softkey to remove this error.

No valid analyzed bursts within gating lines This message is only displayed for the PVT measurement. This

message indicates that there are no complete & valid bursts contained

within the gating lines. Increase the Gate length and then, in the sweep

menu, press the Refresh softkey to remove this error.

No bursts found This message is displayed if no valid burst was detected in the input

data. To correct this problem check the following:

The connections between the DUT and analyzer are correct.

The input signal is of a sufficient level.

The capture time is long enough to capture at least one complete burst.

If running with a Free Run trigger then the capture time must be greater

than the burst length (ideally at least twice the burst length) to ensure

that a complete burst is recorded.

Check that the demod settings are correct.

No bursts of desired type to analyze This message is displayed if bursts are found, but none of desired type

to analyse. Check that the setting for Burst Type is correct.

No signal found This message is displayed when an automatic level detection

measurement is executed and the measured signal level is lower the

permitted minimum value.

No power trigger for Spectrum Mask ETSI This message is displayed when the Spectrum Mask ETSI

measurement is selected whilst the trigger is set to power. No action is

required as the trigger is automatically set to Free Run in this case.

Signal overload detected This message is displayed when the OVLD enhancement label is

displayed and indicates that the input mixer is overloaded. If this

message is displayed then try increasing the setting for the Signal

Level parameter (or settings Auto Level). If this does not clear the

problem then an external attenuation may need to be applied.

R&S FSL

1300.2519.12 9.11 E-11

WiMAX IEEE 802.16 OFDM, OFDMA Measurements Option

Messages (K92/K93)

The list of possible warning & error messages for the WiMAX IEEE 802.16 OFDM, OFDMA

Measurements option (R&S FSL–K92/K93) is shown below.

The WiMAX IEEE 802.16 OFDM, OFDMA Measurements option (R&S FSL–K92/K93) includes the

functionality of the WiMAX 802.16 OFDM Measurements option (R&S FSL–K92). Accordingly both

options are described together in this section. The options are available from firmware version 1.40

(R&S FSL–K92) and 1.50 (R&S FSL–K93).

Status bar message Description

Gate length too small – must be greater than 1 This message is only displayed for the FFT measurement. This

message indicates that there are no samples contained within the

gating lines. Increase the Gate length and then, in the sweep menu,

press the Refresh softkey to remove this error.

No valid analyzed bursts within gating lines This message is only displayed for the PVT measurement. This

message indicates that there are no complete & valid bursts contained

within the gating lines. Increase the Gate length and then, in the sweep

menu, press the Refresh softkey to remove this error.

No bursts found This message is displayed if no valid burst was detected in the input

data. To correct this problem check the following:

The connections between the DUT and analyzer are correct.

The input signal is of a sufficient level.

The capture time is long enough to capture at least one complete burst.

If running with a Free Run trigger then the capture time must be greater

than the burst length (ideally at least twice the burst length) to ensure

that a complete burst is recorded.

Check that the demodulation settings are correct.

No bursts of desired type to analyze This message is displayed if bursts are found, but none of desired type

to analyze. Check that the setting for Burst Type is correct.

No signal found This message is displayed when an automatic level detection

measurement is executed and the measured signal level is lower the

permitted minimum value.

Signal overload detected This message is displayed when the OVLD enhancement label is

displayed and indicates that the input mixer is overloaded. If this

message is displayed then try increasing the setting for the Signal

Level parameter (or settings Auto Level). If this does not clear the

problem then an external attenuation may need to be applied.

The Zone marked for Analysis is not setup

correctly (R&S FSL–K93 only)

This message is displayed when there are configuration errors in the

frame setup. Check the zone/segment map and burst map for any

highlighted errors.

WiMAX OFDM, OFDMA Measurements Option Messages (K92/K93)

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 1 E-10

Alphabetical List of Remote Commands

*CAL? ..................................................................................................................................................... 6.6

*CLS ....................................................................................................................................................... 6.6

*ESE ....................................................................................................................................................... 6.6

*ESR? ..................................................................................................................................................... 6.7

*IDN? ...................................................................................................................................................... 6.7

*IST?....................................................................................................................................................... 6.7

*OPC....................................................................................................................................................... 6.7

*OPT? ..................................................................................................................................................... 6.7

*PCB ....................................................................................................................................................... 6.8

*PRE ....................................................................................................................................................... 6.8

*PSC ....................................................................................................................................................... 6.8

*RST ....................................................................................................................................................... 6.8

*SRE ....................................................................................................................................................... 6.8

*STB? ..................................................................................................................................................... 6.8

*TRG....................................................................................................................................................... 6.9

*TST?...................................................................................................................................................... 6.9

*WAI ....................................................................................................................................................... 6.9

ABORt................................................................................................................................................... 6.10

CALCulate<1|2>: UNIT:ANGLe (K7) .................................................................................................. 6.294

CALCulate<1|2>:ATV:LIMit:CARRiers:S1IFoffset:LOWer (K20)........................................................ 6.413

CALCulate<1|2>:ATV:LIMit:CARRiers:S1IFoffset:UPPer (K20)......................................................... 6.414

CALCulate<1|2>:ATV:LIMit:CARRiers:S1PRelative:LOWer (K20) .................................................... 6.414

CALCulate<1|2>:ATV:LIMit:CARRiers:S1PRelative:UPPer (K20) ..................................................... 6.415

CALCulate<1|2>:ATV:LIMit:CARRiers:S2IFoffset:LOWer (K20)........................................................ 6.415

CALCulate<1|2>:ATV:LIMit:CARRiers:S2IFoffset:UPPer (K20)......................................................... 6.415

CALCulate<1|2>:ATV:LIMit:CARRiers:S2PRelative:LOWer (K20) .................................................... 6.416

CALCulate<1|2>:ATV:LIMit:CARRiers:S2PRelative:UPPer (K20) ..................................................... 6.416

CALCulate<1|2>:ATV:LIMit:CARRiers:VCFoffse:LOWer (K20)......................................................... 6.416

CALCulate<1|2>:ATV:LIMit:CARRiers:VCFoffse:UPPer (K20) .......................................................... 6.417

CALCulate<1|2>:ATV:LIMit:CARRiers:VCPabsolute:LOWer (K20) ................................................... 6.417

CALCulate<1|2>:ATV:LIMit:CARRiers:VCPabsolute:UPPer (K20) .................................................... 6.417

CALCulate<1|2>:ATV:LIMit:CN:CN[:LOWer] (K20)............................................................................ 6.418

CALCulate<1|2>:ATV:LIMit:CSO:CSO[:LOWer] (K20) ...................................................................... 6.418

CALCulate<1|2>:ATV:LIMit:CTB:CTB[:LOWer] (K20)........................................................................ 6.418

CALCulate<1|2>:ATV:LIMit:HUM:HUM:LOWer (K20)........................................................................ 6.419

CALCulate<1|2>:ATV:LIMit:HUM:HUM:UPPer (K20)......................................................................... 6.419

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1IFoffset:LOWer? (K20) ......................................... 6.423

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1IFoffset:UPPer? (K20) .......................................... 6.424

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1PRelative:LOWer? (K20) ...................................... 6.424

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S1PRelative:UPPer? (K20) ....................................... 6.425

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2IFoffset:LOWer? (K20) ......................................... 6.425

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2IFoffset:UPPer? (K20) .......................................... 6.425

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2PRelative:LOWer? (K20) ...................................... 6.426

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:S2PRelative:UPPer? (K20) ....................................... 6.426

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCFoffse:LOWer? (K20)........................................... 6.427

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCFoffse:UPPer? (K20)............................................ 6.427

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCPabsolute:LOWer? (K20) ..................................... 6.427

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 2 E-10

CALCulate<1|2>:ATV:LIMit:RESult:CARRiers:VCPabsolute:UPPer? (K20) ...................................... 6.428

CALCulate<1|2>:ATV:LIMit:RESult:CN:CN[:LOWer]? (K20).............................................................. 6.428

CALCulate<1|2>:ATV:LIMit:RESult:CSO:CSO[:LOWer]? (K20) ........................................................ 6.429

CALCulate<1|2>:ATV:LIMit:RESult:CTB:CTB[:LOWer]? (K20) ......................................................... 6.429

CALCulate<1|2>:ATV:LIMit:RESult:HUM:HUM:LOWer? (K20).......................................................... 6.429

CALCulate<1|2>:ATV:LIMit:RESult:HUM:HUM:UPPer? (K20)........................................................... 6.430

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:MDEPth:LOWer? (K20) ....................................... 6.430

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:MDEPth:UPPer? (K20) ........................................ 6.431

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:RPC:LOWer? (K20) ............................................. 6.431

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:RPC:UPPer? (K20) .............................................. 6.432

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:VCPower:LOWer? (K20) ..................................... 6.432

CALCulate<1|2>:ATV:LIMit:RESult:VMODulation:VCPower:UPPer? (K20) ...................................... 6.433

CALCulate<1|2>:ATV:LIMit:VMODulation:MDEPth:LOWer (K20) ..................................................... 6.420

CALCulate<1|2>:ATV:LIMit:VMODulation:MDEPth:UPPer (K20) ...................................................... 6.420

CALCulate<1|2>:ATV:LIMit:VMODulation:RPC:LOWer (K20) ........................................................... 6.420

CALCulate<1|2>:ATV:LIMit:VMODulation:RPC:UPPer (K20) ............................................................ 6.421

CALCulate<1|2>:ATV:LIMit:VMODulation:VCPower:LOWer (K20).................................................... 6.421

CALCulate<1|2>:ATV:LIMit:VMODulation:VCPower:UPPer (K20)..................................................... 6.422

CALCulate<1|2>:ATV:RESult:CARRiers (K20) .................................................................................. 6.434

CALCulate<1|2>:ATV:RESult:CN (K20) ............................................................................................. 6.435

CALCulate<1|2>:ATV:RESult:CSO (K20)........................................................................................... 6.435

CALCulate<1|2>:ATV:RESult:CTB (K20) ........................................................................................... 6.436

CALCulate<1|2>:ATV:RESult:HUM (K20) .......................................................................................... 6.437

CALCulate<1|2>:ATV:RESult:VMODulation (K20) ............................................................................. 6.437

CALCulate<1|2>:ATV:UNIT:POWer:HUM (K20)................................................................................ 6.438

CALCulate<1|2>:ATV:UNIT:POWer:VCPabsolute (K20) ................................................................... 6.438

CALCulate<1|2>:BTOoth:ACLR[:LIST]? (K8)..................................................................................... 6.335

CALCulate<1|2>:BTOoth:ACLR:EXCeptions? (K8) ........................................................................... 6.335

CALCulate<1|2>:BTOoth:CFDRift[:MAXimum]? (K8) ........................................................................ 6.336

CALCulate<1|2>:BTOoth:CFDRift:RATE? (K8).................................................................................. 6.336

CALCulate<1|2>:BTOoth:CFStability:COUNt? ................................................................................... 6.337

CALCulate<1|2>:BTOoth:CFStability:DEVM:[RMS]? ......................................................................... 6.337

CALCulate<1|2>:BTOoth:CFStability:DEVM:D99Pct? ....................................................................... 6.338

CALCulate<1|2>:BTOoth:CFStability:DEVM:DPCT? ......................................................................... 6.338

CALCulate<1|2>:BTOoth:CFStability:DEVM:PEAK?.......................................................................... 6.339

CALCulate<1|2>:BTOoth:CFStability:FERRor:[TOTal]?..................................................................... 6.339

CALCulate<1|2>:BTOoth:CFStability:FERRor:BLOCk? ..................................................................... 6.340

CALCulate<1|2>:BTOoth:CFStability:FERRor:INITial? ...................................................................... 6.340

CALCulate<1|2>:BTOoth:DPENcoding:[TOTal]? ............................................................................... 6.341

CALCulate<1|2>:BTOoth:DPENcoding:BER?.................................................................................... 6.341

CALCulate<1|2>:BTOoth:DPENcoding:NERRor?.............................................................................. 6.342

CALCulate<1|2>:BTOoth:IBSemissions:[List]? .................................................................................. 6.342

CALCulate<1|2>:BTOoth:IBSemissions:EXCeptions? ....................................................................... 6.343

CALCulate<1|2>:BTOoth:IBSemissions:HADJacent?........................................................................ 6.343

CALCulate<1|2>:BTOoth:IBSemissions:TXReference?..................................................................... 6.344

CALCulate<1|2>:BTOoth:ICFTolerance? (K8) ................................................................................... 6.345

CALCulate<1|2>:BTOoth:MCHar:DF<1|2>:AVERage? (K8) .............................................................. 6.345

CALCulate<1|2>:BTOoth:MCHar:DF<1|2>:MAXimum? (K8) ............................................................. 6.346

CALCulate<1|2>:BTOoth:MCHar:DF2:PERCent? (K8)...................................................................... 6.347

CALCulate<1|2>:BTOoth:MCHar:RATio? (K8)................................................................................... 6.347

CALCulate<1|2>:BTOoth:OPOWer[:PEAK]? (K8).............................................................................. 6.348

CALCulate<1|2>:BTOoth:OPOWer:AVERage? (K8) ......................................................................... 6.348

CALCulate<1|2>:BTOoth:PLENgth? (K8)........................................................................................... 6.349

CALCulate<1|2>:BTOoth:PTYPe? (K8).............................................................................................. 6.350

CALCulate<1|2>:BTOoth:RTPower:[DPSK]? ..................................................................................... 6.350

CALCulate<1|2>:BTOoth:RTPower:GFSK? ....................................................................................... 6.351

CALCulate<1|2>:BTOoth:RTPower:RATio?....................................................................................... 6.351

CALCulate<1|2>:BTOoth:STATus? (K8) ............................................................................................ 6.352

CALCulate<1|2>:BURSt[:IMMediate] (K91)........................................................................................ 6.673

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 3 E-10

CALCulate<1|2>:BURSt[:IMMediate] (K92/K93) ................................................................................ 6.758

CALCulate<1|2>:DELTamarker<1...4>[:STATe] .................................................................................. 6.12

CALCulate<1|2>:DELTamarker<1...4>:AOFF ...................................................................................... 6.13

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:CPICh (K72) ............................................. 6.567, 6.573

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed[:STATe]....................................................... 6.13

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:MAXimum[:PEAK] .......................... 6.14

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:X ..................................................... 6.14

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:Y ..................................................... 6.15

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:FIXed:RPOint:Y:OFFSet........................................ 6.15

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PCCPch (K72) .......................................... 6.567, 6.574

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PNOise[:STATe] .................................................... 6.16

CALCulate<1|2>:DELTamarker<1...4>:FUNCtion:PNOise:RESult? .................................................... 6.16

CALCulate<1|2>:DELTamarker<1...4>:MAXimum[:PEAK] .................................................................. 6.17

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:LEFT ..................................................................... 6.17

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:NEXT .................................................................... 6.17

CALCulate<1|2>:DELTamarker<1...4>:MAXimum:RIGHt.................................................................... 6.18

CALCulate<1|2>:DELTamarker<1...4>:MINimum[:PEAK] ................................................................... 6.18

CALCulate<1|2>:DELTamarker<1...4>:MINimum:LEFT ...................................................................... 6.19

CALCulate<1|2>:DELTamarker<1...4>:MINimum:NEXT ..................................................................... 6.19

CALCulate<1|2>:DELTamarker<1...4>:MINimum:RIGHt ..................................................................... 6.19

CALCulate<1|2>:DELTamarker<1...4>:MODE..................................................................................... 6.20

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:FRAMe (K14) ................................................ 6.391

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:SARea (K14) ................................................. 6.391

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:XY:MAXimum[:PEAK] (K14) ......................... 6.391

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:XY:MINimum[:PEAK] (K14)........................... 6.392

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum[:PEAK] (K14)............................ 6.392

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum:ABOVe (K14) ........................... 6.393

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum:BELow (K14) ............................ 6.393

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MAXimum:NEXT (K14).............................. 6.393

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum[:PEAK] (K14) ............................. 6.394

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum:ABOVe (K14)............................. 6.394

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum:BELow (K14) ............................. 6.395

CALCulate<1|2>:DELTamarker<1...4>:SPECtrogram:Y:MINimum:NEXT (K14)............................... 6.395

CALCulate<1|2>:DELTamarker<1...4>:TRACe.................................................................................... 6.20

CALCulate<1|2>:DELTamarker<1...4>:TRACe (K20)........................................................................ 6.440

CALCulate<1|2>:DELTamarker<1...4>:X ............................................................................................. 6.21

CALCulate<1|2>:DELTamarker<1...4>:X:RELative?............................................................................ 6.21

CALCulate<1|2>:DELTamarker<1...4>:Y? ........................................................................................... 6.22

CALCulate<1|2>:DELTamarker<1...4>:Y? (K20) ............................................................................... 6.440

CALCulate<1|2>:DELTamarker<1...4>:Y? (K8) ................................................................................. 6.353

CALCulate<1|2>:DLINe<1|2> ............................................................................................................... 6.23

CALCulate<1|2>:DLINe<1|2>:STATe................................................................................................... 6.23

CALCulate<1|2>:DTV:RESult (K20) ................................................................................................... 6.459

CALCulate<1|2>:DTV:UNIT:POWer:EPATtern (K20) ........................................................................ 6.461

CALCulate<1|2>:DTV:UNIT:POWer:EVMPeak (K20)........................................................................ 6.461

CALCulate<1|2>:DTV:UNIT:POWer:EVMRms (K20)......................................................................... 6.462

CALCulate<1|2>:DTV:UNIT:POWer:MERPeak (K20)........................................................................ 6.462

CALCulate<1|2>:DTV:UNIT:POWer:MERRms (K20) ........................................................................ 6.463

CALCulate<1|2>:ESPectrum:PSEarch|:PEAKsearch:PSHow.............................................................. 6.25

CALCulate<1|2>:ESPectrum:PSEarch|PEAKsearch:AUTO................................................................. 6.24

CALCulate<1|2>:ESPectrum:PSEarch|PEAKsearch:MARGin ............................................................. 6.24

CALCulate<1|2>:FLINe<1|2>................................................................................................................ 6.25

CALCulate<1|2>:FLINe<1|2>:STATe ................................................................................................... 6.26

CALCulate<1|2>:FORMat (K7) ........................................................................................................... 6.287

CALCulate<1|2>:LIMit<1 ... 8>:CONTrol:SPACing............................................................................... 6.43

CALCulate<1|2>:LIMit<1 ... 8>:ESPectrum:PCLass<1…4>:COUNt .................................................... 6.45

CALCulate<1|2>:LIMit<1 ... 8>:ESPectrum:PCLass<1…4>:STATe .................................................... 6.45

CALCulate<1|2>:LIMit<1...6>:CONTrol[:DATA] (K30)........................................................................ 6.526

CALCulate<1|2>:LIMit<1...6>:CONTrol:SHIFt (K30) .......................................................................... 6.526

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 4 E-10

CALCulate<1|2>:LIMit<1...6>:COPY (K30) ........................................................................................ 6.524

CALCulate<1|2>:LIMit<1...6>:DELete (K30)....................................................................................... 6.524

CALCulate<1|2>:LIMit<1...6>:FAIL? (K30) ......................................................................................... 6.524

CALCulate<1|2>:LIMit<1...6>:LOWer[:DATA] (K30) .......................................................................... 6.527

CALCulate<1|2>:LIMit<1...6>:LOWer:SHIFt (K30)............................................................................. 6.527

CALCulate<1|2>:LIMit<1...6>:LOWer:STATe (K30)........................................................................... 6.527

CALCulate<1|2>:LIMit<1...6>:NAME (K30) ........................................................................................ 6.524

CALCulate<1|2>:LIMit<1...6>:STATe (K30) ....................................................................................... 6.524

CALCulate<1|2>:LIMit<1...6>:UPPer[:DATA] (K30) ........................................................................... 6.528

CALCulate<1|2>:LIMit<1...6>:UPPer:SHIFt (K30).............................................................................. 6.528

CALCulate<1|2>:LIMit<1...6>:UPPer:STATe (K30)............................................................................ 6.528

CALCulate<1|2>:LIMit<1...8>:ACPower[:STATe] ................................................................................. 6.33

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel[:RELative] ............................................................ 6.33

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel[:RELative]:STATe ................................................ 6.34

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:ABSolute.............................................................. 6.35

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:ABSolute:STATe.................................................. 6.35

CALCulate<1|2>:LIMit<1...8>:ACPower:ACHannel:RESult?................................................................ 6.36

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1|2>[:RELative]................................................... 6.37

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1|2>[:RELative]:STATe....................................... 6.37

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1|2>:ABSolute .................................................... 6.38

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1|2>:ABSolute:STATe ........................................ 6.39

CALCulate<1|2>:LIMit<1...8>:ACPower:ALTernate<1|2>:RESult? ...................................................... 6.40

CALCulate<1|2>:LIMit<1...8>:ACTive?................................................................................................. 6.29

CALCulate<1|2>:LIMit<1...8>:CLEar[:IMMediate] ................................................................................ 6.29

CALCulate<1|2>:LIMit<1...8>:COMMent .............................................................................................. 6.29

CALCulate<1|2>:LIMit<1...8>:CONTrol[:DATA].................................................................................... 6.41

CALCulate<1|2>:LIMit<1...8>:CONTrol:DOMain.................................................................................. 6.41

CALCulate<1|2>:LIMit<1...8>:CONTrol:MODE .................................................................................... 6.42

CALCulate<1|2>:LIMit<1...8>:CONTrol:OFFSet................................................................................... 6.42

CALCulate<1|2>:LIMit<1...8>:CONTrol:SHIFt...................................................................................... 6.43

CALCulate<1|2>:LIMit<1...8>:COPY .................................................................................................... 6.30

CALCulate<1|2>:LIMit<1...8>:DELete .................................................................................................. 6.30

CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE (K72)..................................................................... 6.570

CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE (K82)..................................................................... 6.599

CALCulate<1|2>:LIMit<1...8>:ESPectrum:MODE (K84)..................................................................... 6.636

CALCulate<1|2>:LIMit<1...8>:ESPectrum:RESTore (K72) ................................................................ 6.570

CALCulate<1|2>:LIMit<1...8>:ESPectrum:RESTore (K82) ................................................................ 6.599

CALCulate<1|2>:LIMit<1...8>:ESPectrum:RESTore (K84) ................................................................ 6.636

CALCulate<1|2>:LIMit<1...8>:ESPectrum:TRANsition (K72) ............................................................. 6.571

CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue (K72)..................................................................... 6.571

CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue (K82)..................................................................... 6.600

CALCulate<1|2>:LIMit<1...8>:ESPectrum:VALue (K84)..................................................................... 6.637

CALCulate<1|2>:LIMit<1...8>:FAIL?..................................................................................................... 6.31

CALCulate<1|2>:LIMit<1...8>:FAIL? (K91) ......................................................................................... 6.675

CALCulate<1|2>:LIMit<1...8>:FAIL? (K92/K93).................................................................................. 6.760

CALCulate<1|2>:LIMit<1...8>:LOWer[:DATA] ...................................................................................... 6.47

CALCulate<1|2>:LIMit<1...8>:LOWer:MARGin .................................................................................... 6.49

CALCulate<1|2>:LIMit<1...8>:LOWer:MODE ....................................................................................... 6.49

CALCulate<1|2>:LIMit<1...8>:LOWer:OFFSet ..................................................................................... 6.48

CALCulate<1|2>:LIMit<1...8>:LOWer:SHIFt......................................................................................... 6.49

CALCulate<1|2>:LIMit<1...8>:LOWer:SPACing ................................................................................... 6.50

CALCulate<1|2>:LIMit<1...8>:LOWer:STATe....................................................................................... 6.48

CALCulate<1|2>:LIMit<1...8>:LOWer:THReshold................................................................................ 6.50

CALCulate<1|2>:LIMit<1...8>:NAME .................................................................................................... 6.31

CALCulate<1|2>:LIMit<1...8>:STATe ................................................................................................... 6.31

CALCulate<1|2>:LIMit<1...8>:TRACe................................................................................................... 6.32

CALCulate<1|2>:LIMit<1...8>:TRACe (K30)....................................................................................... 6.525

CALCulate<1|2>:LIMit<1...8>:UNIT ...................................................................................................... 6.32

CALCulate<1|2>:LIMit<1...8>:UPPer[:DATA] ....................................................................................... 6.51

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 5 E-10

CALCulate<1|2>:LIMit<1...8>:UPPer:MARGin ..................................................................................... 6.52

CALCulate<1|2>:LIMit<1...8>:UPPer:MODE ........................................................................................ 6.52

CALCulate<1|2>:LIMit<1...8>:UPPer:OFFSet ...................................................................................... 6.52

CALCulate<1|2>:LIMit<1...8>:UPPer:SHIFt.......................................................................................... 6.53

CALCulate<1|2>:LIMit<1...8>:UPPer:SPACing .................................................................................... 6.53

CALCulate<1|2>:LIMit<1...8>:UPPer:STATe........................................................................................ 6.54

CALCulate<1|2>:LIMit<1...8>:UPPer:THReshold................................................................................. 6.54

CALCulate<1|2>:LIMit<1>:ACPower:ACHannel (K91) ....................................................................... 6.675

CALCulate<1|2>:LIMit<1>:ACPower:ALTernate? (K91)..................................................................... 6.676

CALCulate<1|2>:LIMit<1>:BURSt: BERPilot [:AVERage] (K93)......................................................... 6.761

CALCulate<1|2>:LIMit<1>:BURSt: BERPilot [:AVERage]:RESult? (K93) .......................................... 6.762

CALCulate<1|2>:LIMit<1>:BURSt:ALL (K91) ..................................................................................... 6.676

CALCulate<1|2>:LIMit<1>:BURSt:ALL (K92/K93).............................................................................. 6.760

CALCulate<1|2>:LIMit<1>:BURSt:ALL:RESUlt (K91) ........................................................................ 6.677

CALCulate<1|2>:LIMit<1>:BURSt:ALL:RESult? (K92/K93)................................................................ 6.761

CALCulate<1|2>:LIMit<1>:BURSt:BERPilot:MAXimum (K93)............................................................ 6.762

CALCulate<1|2>:LIMit<1>:BURSt:BERPilot:MAXimum:RESult? (K93) ............................................. 6.763

CALCulate<1|2>:LIMit<1>:BURSt:EVM[:AVERage] (K91) ................................................................. 6.677

CALCulate<1|2>:LIMit<1>:BURSt:EVM[:AVERage]:RESult? (K91)................................................... 6.677

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL[:AVERage] (K91).......................................................... 6.678

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL[:AVERage] (K92/K93) .................................................. 6.763

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL[:AVERage]:RESult? (K91)............................................ 6.678

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL[:AVERage]:RESult? (K92/K93) .................................... 6.763

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL:MAXimum (K91)........................................................... 6.679

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL:MAXimum (K92/K93) ................................................... 6.764

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL:MAXimum:RESult? (K91)............................................. 6.679

CALCulate<1|2>:LIMit<1>:BURSt:EVM:ALL:MAXimum:RESult? (K92/K93) ..................................... 6.764

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA[:AVERage] (K91) ...................................................... 6.679

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA[:AVERage] (K92/K93) ............................................... 6.765

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA[:AVERage]:RESult? (K91) ........................................ 6.680

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA[:AVERage]:RESult? (K92/K93)................................. 6.765

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA:MAXimum (K91) ....................................................... 6.680

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA:MAXimum (K92/K93) ................................................ 6.766

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA:MAXimum:RESult? (K91) ......................................... 6.681

CALCulate<1|2>:LIMit<1>:BURSt:EVM:DATA:MAXimum:RESult? (K92/K93).................................. 6.766

CALCulate<1|2>:LIMit<1>:BURSt:EVM:MAXimum (K91) .................................................................. 6.681

CALCulate<1|2>:LIMit<1>:BURSt:EVM:MAXimum:RESult? (K91).................................................... 6.681

CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot[:AVERage] (K91)........................................................ 6.682

CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot[:AVERage]:RESult? (K91).......................................... 6.682

CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot:MAXimum (K91)......................................................... 6.683

CALCulate<1|2>:LIMit<1>:BURSt:EVM:PILot:MAXimum:RESult? (K91)........................................... 6.683

CALCulate<1|2>:LIMit<1>:BURSt:FERRor[:AVERage] (K91)............................................................ 6.683

CALCulate<1|2>:LIMit<1>:BURSt:FERRor[:AVERage] (K92/K93) .................................................... 6.766

CALCulate<1|2>:LIMit<1>:BURSt:FERRor[:AVERage]:RESult? (K91).............................................. 6.684

CALCulate<1|2>:LIMit<1>:BURSt:FERRor[:AVERage]:RESult? (K92/K93) ...................................... 6.767

CALCulate<1|2>:LIMit<1>:BURSt:FERRor:MAXimum (K91)............................................................. 6.684

CALCulate<1|2>:LIMit<1>:BURSt:FERRor:MAXimum (K92/K93) ..................................................... 6.767

CALCulate<1|2>:LIMit<1>:BURSt:FERRor:MAXimum:RESult? (K91)............................................... 6.684

CALCulate<1|2>:LIMit<1>:BURSt:FERRor:MAXimum:RESult? (K92/K93) ....................................... 6.768

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset[:AVERage] (K91) .......................................................... 6.685

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset[:AVERage] (K92/K93)................................................... 6.768

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset[:AVERage]:RESult? (K91) ............................................ 6.685

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset[:AVERage]:RESult? (K92/K93)..................................... 6.769

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset:MAXimum (K91) ........................................................... 6.685

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset:MAXimum (K92/K93).................................................... 6.769

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset:MAXimum:RESult? (K91) ............................................. 6.686

CALCulate<1|2>:LIMit<1>:BURSt:IQOFfset:MAXimum:RESult? (K92/K93)...................................... 6.769

CALCulate<1|2>:LIMit<1>:BURSt:SSTiming[:AVERage] (K92/K93).................................................. 6.770

CALCulate<1|2>:LIMit<1>:BURSt:SSTiming[:AVERage]:RESult? (K92/K93).................................... 6.770

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 6 E-10

CALCulate<1|2>:LIMit<1>:BURSt:SSTiming:MAXimum (K92/K93)................................................... 6.771

CALCulate<1|2>:LIMit<1>:BURSt:SSTiming:MAXimum:RESult? (K92/K93)..................................... 6.771

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror[:AVERage] (K91) .................................................... 6.686

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror[:AVERage] (K92/K93)............................................. 6.771

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror[:AVERage]:RESult? (K91) ...................................... 6.686

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror[:AVERage]:RESult? (K92/K93)............................... 6.772

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror:MAXimum (K91) ..................................................... 6.687

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror:MAXimum (K92/K93).............................................. 6.772

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror:MAXimum:RESult? (K91) ....................................... 6.687

CALCulate<1|2>:LIMit<1>:BURSt:SYMBolerror:MAXimum:RESult? (K92/K93)................................ 6.773

CALCulate<1|2>:LIMit<1>:BURSt:TFALl[:AVERage] (K91) ............................................................... 6.687

CALCulate<1|2>:LIMit<1>:BURSt:TFALl[:AVERage]:RESult? (K91) ................................................. 6.688

CALCulate<1|2>:LIMit<1>:BURSt:TFALl:MAXimum (K91) ................................................................ 6.688

CALCulate<1|2>:LIMit<1>:BURSt:TFALl:MAXimum:RESult? (K91) .................................................. 6.688

CALCulate<1|2>:LIMit<1>:BURSt:TRISe[:AVERage] (K91)............................................................... 6.689

CALCulate<1|2>:LIMit<1>:BURSt:TRISe[:AVERage]:RESult (K91) .................................................. 6.689

CALCulate<1|2>:LIMit<1>:BURSt:TRISe:MAXimum (K91)................................................................ 6.689

CALCulate<1|2>:LIMit<1>:BURSt:TRISe:MAXimum:RESult? (K91) ................................................. 6.690

CALCulate<1|2>:LIMit<1>:SPECtrum:MASK:CHECk:X (K91)........................................................... 6.690

CALCulate<1|2>:LIMit<1>:SPECtrum:MASK:CHECk:X? (K92/K93) ................................................. 6.773

CALCulate<1|2>:LIMit<1>:SPECtrum:MASK:CHECk:Y (K91)........................................................... 6.690

CALCulate<1|2>:LIMit<1>:SPECtrum:MASK:CHECk:Y? (K92/K93).................................................. 6.774

CALCulate<1|2>:LIMit<1…8>:ESPectrum:LIMits ................................................................................. 6.46

CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>[:EXCLusive] ............................................. 6.44

CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:MAXimum ................................................ 6.45

CALCulate<1|2>:LIMit<1…8>:ESPectrum:PCLass<1…4>:MINimum.................................................. 6.44

CALCulate<1|2>:MARKer<1...4>[:STATe] ........................................................................................... 6.56

CALCulate<1|2>:MARKer<1...4>:AOFF ............................................................................................... 6.56

CALCulate<1|2>:MARKer<1...4>:COUNt ............................................................................................. 6.56

CALCulate<1|2>:MARKer<1...4>:COUNt:FREQuency? ...................................................................... 6.57

CALCulate<1|2>:MARKer<1...4>:COUNt:RESolution .......................................................................... 6.58

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CDPower[:BTS]:RESult? (K82) .................................... 6.601

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CENTer........................................................................... 6.70

CALCulate<1|2>:MARKer<1...4>:FUNCtion:CSTep............................................................................. 6.71

CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation[:STATe] ................................................... 6.69

CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation:CONTinuous ........................................... 6.69

CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation:HOLDoff .................................................. 6.69

CALCulate<1|2>:MARKer<1...4>:FUNCtion:DEModulation:SELect..................................................... 6.70

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks[:IMMediate] ....................................................... 6.71

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:COUNt? ............................................................ 6.72

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:SORT ................................................................ 6.72

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:X?...................................................................... 6.73

CALCulate<1|2>:MARKer<1...4>:FUNCtion:FPEaks:Y?...................................................................... 6.73

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics[:STATe] ...................................................... 6.82

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:BANDwidth:AUTO ...................................... 6.82

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:DISTortion?................................................. 6.83

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:LIST? .......................................................... 6.84

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:NHARmonics .............................................. 6.84

CALCulate<1|2>:MARKer<1...4>:FUNCtion:HARMonics:PRESet....................................................... 6.85

CALCulate<1|2>:MARKer<1...4>:FUNCtion:MDEPth:[:STATe] ........................................................... 6.74

CALCulate<1|2>:MARKer<1...4>:FUNCtion:MDEPth:RESult? ............................................................ 6.74

CALCulate<1|2>:MARKer<1...4>:FUNCtion:MDEPth:SEARchsignal ONCE ....................................... 6.75

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown ....................................................................... 6.75

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:FREQuency? ................................................ 6.76

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:QFACtor........................................................ 6.76

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:RESult?......................................................... 6.77

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:STATe........................................................... 6.77

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NDBDown:TIME? ........................................................... 6.78

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NOISe[:STATe]............................................................... 6.78

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 7 E-10

CALCulate<1|2>:MARKer<1...4>:FUNCtion:NOISe:RESult?............................................................... 6.79

CALCulate<1|2>:MARKer<1...4>:FUNCtion:PICH (K82) ................................................................... 6.601

CALCulate<1|2>:MARKer<1...4>:FUNCtion:REFerence...................................................................... 6.79

CALCulate<1|2>:MARKer<1...4>:FUNCtion:SUMMary:REFerence:AUTO........................................ 6.103

CALCulate<1|2>:MARKer<1...4>:FUNCtion:TDPIch (K82) ................................................................ 6.602

CALCulate<1|2>:MARKer<1...4>:FUNCtion:TOI[:STATe] ................................................................... 6.80

CALCulate<1|2>:MARKer<1...4>:FUNCtion:TOI:RESult?.................................................................... 6.80

CALCulate<1|2>:MARKer<1...4>:FUNCtion:TOI:SEARchsignal ONCE .............................................. 6.81

CALCulate<1|2>:MARKer<1...4>:FUNCtion:WCDPower[:BTS]:RESult? (K72)................................. 6.574

CALCulate<1|2>:MARKer<1...4>:FUNCtion:ZOOM............................................................................. 6.81

CALCulate<1|2>:MARKer<1...4>:LOEXclude ...................................................................................... 6.58

CALCulate<1|2>:MARKer<1...4>:MAXimum[:PEAK] ........................................................................... 6.58

CALCulate<1|2>:MARKer<1...4>:MAXimum:AUTO............................................................................. 6.59

CALCulate<1|2>:MARKer<1...4>:MAXimum:LEFT .............................................................................. 6.59

CALCulate<1|2>:MARKer<1...4>:MAXimum:NEXT ............................................................................. 6.60

CALCulate<1|2>:MARKer<1...4>:MAXimum:RIGHt............................................................................. 6.60

CALCulate<1|2>:MARKer<1...4>:MINimum[:PEAK]............................................................................. 6.60

CALCulate<1|2>:MARKer<1...4>:MINimum:AUTO .............................................................................. 6.61

CALCulate<1|2>:MARKer<1...4>:MINimum:LEFT ............................................................................... 6.61

CALCulate<1|2>:MARKer<1...4>:MINimum:NEXT .............................................................................. 6.62

CALCulate<1|2>:MARKer<1...4>:MINimum:RIGHt .............................................................................. 6.62

CALCulate<1|2>:MARKer<1...4>:PEXCursion..................................................................................... 6.63

CALCulate<1|2>:MARKer<1...4>:PEXCursion (K7) ........................................................................... 6.288

CALCulate<1|2>:MARKer<1...4>:PEXCursion (K8) ........................................................................... 6.354

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:FRAMe (K14) ......................................................... 6.396

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:SARea (K14) .......................................................... 6.397

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:XY:MAXimum[:PEAK] (K14) .................................. 6.397

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:XY:MINimum[:PEAK] (K14).................................... 6.397

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum[:PEAK] (K14)..................................... 6.398

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum:ABOVe (K14) .................................... 6.398

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum:BELow (K14) ..................................... 6.399

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MAXimum:NEXT (K14)....................................... 6.399

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum[:PEAK] (K14) ...................................... 6.400

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum:ABOVe (K14)...................................... 6.400

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum:BELow (K14) ...................................... 6.401

CALCulate<1|2>:MARKer<1...4>:SPECtrogram:Y:MINimum:NEXT (K14) ........................................ 6.401

CALCulate<1|2>:MARKer<1...4>:TRACe............................................................................................. 6.63

CALCulate<1|2>:MARKer<1...4>:TRACe (K20) ................................................................................. 6.465

CALCulate<1|2>:MARKer<1...4>:X ...................................................................................................... 6.64

CALCulate<1|2>:MARKer<1...4>:X (K91) .......................................................................................... 6.694

CALCulate<1|2>:MARKer<1...4>:X:SLIMits[:STATe] ........................................................................... 6.64

CALCulate<1|2>:MARKer<1...4>:X:SLIMits:LEFT ............................................................................... 6.65

CALCulate<1|2>:MARKer<1...4>:X:SLIMits:RIGHT ............................................................................. 6.65

CALCulate<1|2>:MARKer<1...4>:X:SSIZe ........................................................................................... 6.66

CALCulate<1|2>:MARKer<1...4>:Y? .................................................................................................... 6.66

CALCulate<1|2>:MARKer<1...4>:Y? (K7) .......................................................................................... 6.288

CALCulate<1|2>:MARKer<1...4>:Y? (K8) .......................................................................................... 6.354

CALCulate<1|2>:MARKer<1...4>:Y:PERCent ...................................................................................... 6.67

CALCulate<1|2>:MARKer<1>[:STATe] (K91)..................................................................................... 6.691

CALCulate<1|2>:MARKer<1>[:STATe] (K92/K93) ............................................................................. 6.775

CALCulate<1|2>:MARKer<1>:AOFF (K91) ........................................................................................ 6.691

CALCulate<1|2>:MARKer<1>:AOFF (K92/K93)................................................................................. 6.775

CALCulate<1|2>:MARKer<1>:BSYMbol (K91) ................................................................................... 6.692

CALCulate<1|2>:MARKer<1>:BURSt (K92/K93) ............................................................................... 6.776

CALCulate<1|2>:MARKer<1>:CARRier (K91).................................................................................... 6.692

CALCulate<1|2>:MARKer<1>:CARRier (K92/K93) ............................................................................ 6.776

CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult[:CURRent]? (K91) .................................... 6.696

CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult[:CURRent]? (K92/K93) ............................. 6.781

CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult:MAXHold? (K91)....................................... 6.696

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 8 E-10

CALCulate<1|2>:MARKer<1>:FUNCtion:POWer:RESult:MAXHold? (K92/K93) ............................... 6.782

CALCulate<1|2>:MARKer<1>:FUNCtion:ZOOM (K91) ...................................................................... 6.697

CALCulate<1|2>:MARKer<1>:FUNCtion:ZOOM (K92/K93)............................................................... 6.782

CALCulate<1|2>:MARKer<1>:MAXimum (K91) ................................................................................. 6.693

CALCulate<1|2>:MARKer<1>:MAXimum[:PEAK] (K92/K93) ............................................................. 6.777

CALCulate<1|2>:MARKer<1>:MINimum (K91) .................................................................................. 6.693

CALCulate<1|2>:MARKer<1>:MINimum[:PEAK] (K92/K93) .............................................................. 6.777

CALCulate<1|2>:MARKer<1>:SYMBol (K91)..................................................................................... 6.693

CALCulate<1|2>:MARKer<1>:SYMBol (K92/K93).............................................................................. 6.777

CALCulate<1|2>:MARKer<1>:TRACe (K91) ...................................................................................... 6.694

CALCulate<1|2>:MARKer<1>:TRACe (K92/K93)............................................................................... 6.778

CALCulate<1|2>:MARKer<1>:TTCapture? (K93) .............................................................................. 6.779

CALCulate<1|2>:MARKer<1>:X (K92/K93) ........................................................................................ 6.779

CALCulate<1|2>:MARKer<1>:Y (K91) ............................................................................................... 6.695

CALCulate<1|2>:MARKer<1>:Y? (K92/K93) ...................................................................................... 6.780

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:AFRequency[:RESult<1...4>]? (K7).......................... 6.289

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:AM[:RESult<1...4>]? (K7) ......................................... 6.290

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:CARRier[:RESult<1...6>]? (K7) ................................ 6.290

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:FERRor[:RESult<1...6>]? (K7) ................................. 6.291

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:FM[:RESult<1...6>]? (K7) ......................................... 6.291

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:PM[:RESult]? (K7) .................................................... 6.292

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:SINad:RESult<1...6>? (K7) ...................................... 6.293

CALCulate<1|2>:MARKer:FUNCtion:ADEMod:THD:RESult<1...6>? (K7) ......................................... 6.293

CALCulate<1|2>:MARKer:FUNCtion:MSUMmary?.............................................................................. 6.95

CALCulate<1|2>:MARKer:FUNCtion:POWer[:STATe]......................................................................... 6.87

CALCulate<1|2>:MARKer:FUNCtion:POWer:MODe]........................................................................... 6.87

CALCulate<1|2>:MARKer:FUNCtion:POWer:PRESet ......................................................................... 6.88

CALCulate<1|2>:MARKer:FUNCtion:POWer:RESult?......................................................................... 6.88

CALCulate<1|2>:MARKer:FUNCtion:POWer:RESult:PHZ................................................................... 6.91

CALCulate<1|2>:MARKer:FUNCtion:POWer:SELect .......................................................................... 6.91

CALCulate<1|2>:MARKer:FUNCtion:STRack[:STATe]........................................................................ 6.93

CALCulate<1|2>:MARKer:FUNCtion:STRack:BANDwidth................................................................... 6.93

CALCulate<1|2>:MARKer:FUNCtion:STRack:BWIDth ........................................................................ 6.93

CALCulate<1|2>:MARKer:FUNCtion:STRack:THReshold................................................................... 6.94

CALCulate<1|2>:MARKer:FUNCtion:STRack:TRACe ......................................................................... 6.94

CALCulate<1|2>:MARKer:FUNCtion:SUMMary[:STATe]..................................................................... 6.97

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:AOFF ........................................................................ 6.97

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:AVERage .................................................................. 6.97

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN[:STATe] ......................................................... 6.98

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN:AVERage:RESult?......................................... 6.98

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN:PHOLd:RESult?............................................. 6.99

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MEAN:RESult?.......................................................... 6.99

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:MODE ..................................................................... 6.100

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PHOLd .................................................................... 6.100

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak[:STATe]....................................................... 6.101

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak:AVERage:RESult? ...................................... 6.101

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak:PHOLd:RESult? .......................................... 6.102

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:PPEak:RESult?....................................................... 6.102

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS[:STATe].......................................................... 6.103

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS:AVERage:RESult? ......................................... 6.104

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS:PHOLd:RESult? ............................................. 6.104

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:RMS:RESult?.......................................................... 6.105

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation[:STATe] ............................................... 6.105

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation:AVERage:RESult?............................... 6.106

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation:PHOLd:RESult?................................... 6.106

CALCulate<1|2>:MARKer:FUNCtion:SUMMary:SDEViation:RESult?................................................ 6.107

CALCulate<1|2>:MATH[:EXPression][:DEFine] ................................................................................. 6.108

CALCulate<1|2>:MATH:MODE .......................................................................................................... 6.108

CALCulate<1|2>:MATH:POSition....................................................................................................... 6.109

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 9 E-10

CALCulate<1|2>:MATH:STATe.......................................................................................................... 6.109

CALCulate<1|2>:PMETer:RELative[:MAGNitude] (K9) ...................................................................... 6.378

CALCulate<1|2>:PMETer:RELative[:MAGNitude]:AUTO (K9) ........................................................... 6.378

CALCulate<1|2>:PMETer:RELative:STATe (K9) ............................................................................... 6.379

CALCulate<1|2>:PSEarch|PEAKsearch[:IMMediate] ......................................................................... 6.110

CALCulate<1|2>:PSEarch|PEAKsearch:AUTO.................................................................................. 6.110

CALCulate<1|2>:PSEarch|PEAKsearch:MARGin .............................................................................. 6.110

CALCulate<1|2>:PSEarch|PEAKsearch:PSHow................................................................................ 6.110

CALCulate<1|2>:PSEarch|PEAKsearch:SUBRanges ........................................................................ 6.111

CALCulate<1|2>:SPECtrogram[:STATe] (K14) .................................................................................. 6.402

CALCulate<1|2>:SPECtrogram:CLEar[:IMMediate] (K14) ................................................................. 6.402

CALCulate<1|2>:SPECtrogram:COLor (K14)..................................................................................... 6.403

CALCulate<1|2>:SPECtrogram:CONTinuous (K14) .......................................................................... 6.403

CALCulate<1|2>:SPECtrogram:FRAMe:COUNt (K14) ...................................................................... 6.404

CALCulate<1|2>:SPECtrogram:FRAMe:SELect (K14) ...................................................................... 6.404

CALCulate<1|2>:SPECtrogram:HDEPth (K14) .................................................................................. 6.405

CALCulate<1|2>:SPECtrogram:SIZE (K14) ....................................................................................... 6.405

CALCulate<1|2>:SPECtrogram:TSTamp[:STATe] (K14) ................................................................... 6.406

CALCulate<1|2>:SPECtrogram:TSTamp:DATA (K14)....................................................................... 6.406

CALCulate<1|2>:THReshold .............................................................................................................. 6.117

CALCulate<1|2>:THReshold:STATe .................................................................................................. 6.117

CALCulate<1|2>:TLINe<1|2>.............................................................................................................. 6.118

CALCulate<1|2>:TLINe<1|2>:STATe ................................................................................................. 6.118

CALCulate<1|2>:UNIT:POWer ........................................................................................................... 6.119

CALCulate<1|2>:UNIT:POWer (K20) ................................................................................................. 6.468

CALCulate:DTV:LIMit:CFOFfset:LOWer (K20) .................................................................................. 6.442

CALCulate:DTV:LIMit:CFOFfset:UPPer (K20) ................................................................................... 6.442

CALCulate:DTV:LIMit:CHPower:LOWer (K20)................................................................................... 6.443

CALCulate:DTV:LIMit:CHPower:UPPer (K20).................................................................................... 6.442

CALCulate:DTV:LIMit:CSUPpression[:LOWer] (K20) ........................................................................ 6.443

CALCulate:DTV:LIMit:EVMPeak:LOWer] (K20)................................................................................. 6.443

CALCulate:DTV:LIMit:EVMPeak:UPPer (K20) ................................................................................... 6.444

CALCulate:DTV:LIMit:EVMRms:LOWer (K20)................................................................................... 6.444

CALCulate:DTV:LIMit:EVMRms:UPPer (K20).................................................................................... 6.444

CALCulate:DTV:LIMit:IMBalance:LOWer (K20)................................................................................. 6.445

CALCulate:DTV:LIMit:IMBalance:UPPer (K20) .................................................................................. 6.445

CALCulate:DTV:LIMit:MERPeak:LOWer (K20).................................................................................. 6.446

CALCulate:DTV:LIMit:MERPeak:UPPer (K20)................................................................................... 6.446

CALCulate:DTV:LIMit:MERRms:LOWer (K20) .................................................................................. 6.446

CALCulate:DTV:LIMit:MERRms:UPPer (K20) ................................................................................... 6.447

CALCulate:DTV:LIMit:PJITter[:UPPer] (K20) ..................................................................................... 6.447

CALCulate:DTV:LIMit:QERRor:LOWer (K20) .................................................................................... 6.448

CALCulate:DTV:LIMit:QERRor:UPPer (K20) ..................................................................................... 6.448

CALCulate:DTV:LIMit:RESult:CFOFfset:LOWer? (K20) .................................................................... 6.450

CALCulate:DTV:LIMit:RESult:CFOFfset:UPPer? (K20) ..................................................................... 6.451

CALCulate:DTV:LIMit:RESult:CHPower? (K20) ................................................................................. 6.451

CALCulate:DTV:LIMit:RESult:CSUPpression[:LOWer]? (K20) .......................................................... 6.451

CALCulate:DTV:LIMit:RESult:EVMPeak:LOWer? (K20).................................................................... 6.452

CALCulate:DTV:LIMit:RESult:EVMPeak:UPPer? (K20)..................................................................... 6.452

CALCulate:DTV:LIMit:RESult:EVMRms:LOWer? (K20) .................................................................... 6.453

CALCulate:DTV:LIMit:RESult:EVMRms:UPPer? (K20)...................................................................... 6.453

CALCulate:DTV:LIMit:RESult:IMBalance:LOWer? (K20)................................................................... 6.453

CALCulate:DTV:LIMit:RESult:IMBalance:UPPer? (K20).................................................................... 6.454

CALCulate:DTV:LIMit:RESult:MERPeak:LOWer? (K20).................................................................... 6.454

CALCulate:DTV:LIMit:RESult:MERPeak:UPPer? (K20)..................................................................... 6.455

CALCulate:DTV:LIMit:RESult:MERRms:LOWer? (K20) .................................................................... 6.455

CALCulate:DTV:LIMit:RESult:MERRms:UPPer? (K20) ..................................................................... 6.455

CALCulate:DTV:LIMit:RESult:PJITter[:UPPer]? (K20) ....................................................................... 6.456

CALCulate:DTV:LIMit:RESult:QERRor:LOWer? (K20) ...................................................................... 6.456

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 10 E-10

CALCulate:DTV:LIMit:RESult:QERRor:UPPer? (K20) ....................................................................... 6.457

CALCulate:DTV:LIMit:RESult:SROFfset:LOWer? (K20).................................................................... 6.457

CALCulate:DTV:LIMit:RESult:SROFfset:UPPer? (K20) ..................................................................... 6.458

CALCulate:DTV:LIMit:SROFfset:LOWer (K20) .................................................................................. 6.448

CALCulate:DTV:LIMit:SROFfset:UPPer (K20) ................................................................................... 6.449

CALCulate:MARKer:TRACe (K30) ..................................................................................................... 6.530

CALCulate:MARKer:Y? (K30)............................................................................................................. 6.530

CALCulate:STATistics:APD[:STATe] ................................................................................................. 6.112

CALCulate:STATistics:CCDF[:STATe]............................................................................................... 6.112

CALCulate:STATistics:NSAMples ...................................................................................................... 6.113

CALCulate:STATistics:PRESet .......................................................................................................... 6.113

CALCulate:STATistics:RESult<1...6>?............................................................................................... 6.114

CALCulate:STATistics:SCALe:AUTO................................................................................................. 6.114

CALCulate:STATistics:SCALe:X:RANGe........................................................................................... 6.115

CALCulate:STATistics:SCALe:X:RLEVel ........................................................................................... 6.115

CALCulate:STATistics:SCALe:Y:LOWer............................................................................................ 6.115

CALCulate:STATistics:SCALe:Y:UNIT............................................................................................... 6.116

CALCulate:STATistics:SCALe:Y:UPPer............................................................................................. 6.116

CALibration[:ALL]?.............................................................................................................................. 6.120

CALibration:ABORt............................................................................................................................. 6.121

CALibration:PMETer:ZERO:AUTO (K9)............................................................................................. 6.380

CALibration:RESult?........................................................................................................................... 6.121

CALibration:STATe............................................................................................................................. 6.121

CONFigure:ATV:CN:MEASurement (K20) ......................................................................................... 6.469

CONFigure:ATV:CSO:MEASurement (K20) ...................................................................................... 6.470

CONFigure:ATV:CTB:MEASurement (K20) ....................................................................................... 6.470

CONFigure:ATV:MEASurement (K20) ............................................................................................... 6.471

CONFigure:BTOoth:ACLR:ACPairs (K8) ........................................................................................... 6.356

CONFigure:BTOoth:BANDwidth|BWIDth[:RESolution] (K8)............................................................... 6.356

CONFigure:BTOoth:BANDwidth|BWIDth[:RESolution]:AUTO (K8) ................................................... 6.357

CONFigure:BTOoth:BANDwidth|BWIDth:VIDeo (K8) ........................................................................ 6.357

CONFigure:BTOoth:BANDwidth|BWIDth:VIDeo:AUTO (K8) ............................................................. 6.358

CONFigure:BTOoth:CFSTability:BCOunt (K8) ................................................................................... 6.358

CONFigure:BTOoth:CHANnel (K8) .................................................................................................... 6.359

CONFigure:BTOoth:DETector<1...6> (K8)......................................................................................... 6.359

CONFigure:BTOoth:IBSemissions:ACPairs (K8) ............................................................................... 6.360

CONFigure:BTOoth:IBSemissions:GATE:AUTO (K8) ....................................................................... 6.360

CONFigure:BTOoth:MEASurement (K8)............................................................................................ 6.360

CONFigure:BTOoth:PBSCo (K8)........................................................................................................ 6.361

CONFigure:BTOoth:PCLass (K8)....................................................................................................... 6.361

CONFigure:BTOoth:POWer:AVERage:STARt (K8)........................................................................... 6.362

CONFigure:BTOoth:POWer:AVERage:STOP (K8)............................................................................ 6.362

CONFigure:BTOoth:PRATe (K8)........................................................................................................ 6.363

CONFigure:BTOoth:PTYPe (K8)........................................................................................................ 6.363

CONFigure:BTOoth:RTPower:DAVerage:STARt (K8) ....................................................................... 6.364

CONFigure:BTOoth:RTPower:DAVerage:STOP (K8)........................................................................ 6.364

CONFigure:BTOoth:RTPower:GAVerage:STARt (K8)....................................................................... 6.364

CONFigure:BTOoth:RTPower:GAVerage:STOP (K8)........................................................................ 6.365

CONFigure:BTOoth:SWEep:COUNt (K8) .......................................................................................... 6.365

CONFigure:BTOoth:SWEep:TIME (K8) ............................................................................................. 6.366

CONFigure:BTOoth:SWEep:TIME:AUTO (K8) .................................................................................. 6.367

CONFigure:BTOoth:TRACe<1...6>:MODE (K8) ................................................................................ 6.367

CONFigure:BTOoth:TRACe<1...6>:SELect (K8)................................................................................ 6.368

CONFigure:BURSt:BSTReam:BURSt:SELect (K93) ......................................................................... 6.785

CONFigure:BURSt:BSTReam:FORMat:SELect (K93)....................................................................... 6.785

CONFigure:BURSt:BSTReam:SYMBol:SELect (K93)........................................................................ 6.786

CONFigure:BURSt:CONSt:CARRier:SELect (K91)............................................................................ 6.698

CONFigure:BURSt:CONSt:CCARrier[:IMMediate] (K91) ................................................................... 6.699

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 11 E-10

CONFigure:BURSt:CONSt:CCARrier[:IMMediate] (K92/K93)............................................................ 6.787

CONFigure:BURSt:CONSt:CSYMbol[:IMMediate] (K91) ................................................................... 6.699

CONFigure:BURSt:CONSt:CSYMbol[:IMMediate] (K92/K93) ............................................................ 6.788

CONFigure:BURSt:CONSt:FORMat:SELect (K93) ............................................................................ 6.788

CONFigure:BURSt:EVM:ECARrier[:IMMediate] (K91) ....................................................................... 6.700

CONFigure:BURSt:EVM:ECARrier[:IMMediate] (K92/K93)................................................................ 6.789

CONFigure:BURSt:EVM:ESYMbol[:IMMediate] (K91) ....................................................................... 6.700

CONFigure:BURSt:EVM:ESYMbol[:IMMediate] (K92/K93)................................................................ 6.789

CONFigure:BURSt:PREamble[:IMMediate] (K91).............................................................................. 6.700

CONFigure:BURSt:PREamble[:IMMediate] (K92/K93) ...................................................................... 6.790

CONFigure:BURSt:PREamble:SELect (K91) ..................................................................................... 6.701

CONFigure:BURSt:PREamble:SELect (K92/K93).............................................................................. 6.790

CONFigure:BURSt:PVT[:IMMediate] (K91) ........................................................................................ 6.701

CONFigure:BURSt:PVT[:IMMediate] (K92/K93)................................................................................. 6.790

CONFigure:BURSt:PVT:AVERage (K91) ........................................................................................... 6.701

CONFigure:BURSt:PVT:BURSt (K92/K93) ........................................................................................ 6.791

CONFigure:BURSt:PVT:RPOWer (K91) ............................................................................................ 6.702

CONFigure:BURSt:PVT:SELect (K91) ............................................................................................... 6.702

CONFigure:BURSt:PVT:SELect (K92/K93)........................................................................................ 6.791

CONFigure:BURSt:SPECtrum:ACPR[:IMMediate] (K91)................................................................... 6.703

CONFigure:BURSt:SPECtrum:ACPR[:IMMediate] (K92/K93)............................................................ 6.792

CONFigure:BURSt:SPECtrum:ACPR:SELect (K92/K93)................................................................... 6.792

CONFigure:BURSt:SPECtrum:FFT[:IMMediate] (K91) ...................................................................... 6.703

CONFigure:BURSt:SPECtrum:FFT[:IMMediate] (K92/K93)............................................................... 6.792

CONFigure:BURSt:SPECtrum:FLATness[:IMMediate] (K91) ............................................................ 6.703

CONFigure:BURSt:SPECtrum:FLATness[:IMMediate] (K92/K93) ..................................................... 6.793

CONFigure:BURSt:SPECtrum:FLATness:SELect (K92/K93) ............................................................ 6.793

CONFigure:BURSt:SPECtrum:MASK[:IMMediate] (K91)................................................................... 6.704

CONFigure:BURSt:SPECtrum:MASK[:IMMediate] (K92/K93) ........................................................... 6.793

CONFigure:BURSt:SPECtrum:MASK:SELect (K91) .......................................................................... 6.704

CONFigure:BURSt:SPECtrum:MASK:SELect (K92/K93)................................................................... 6.794

CONFigure:BURSt:STATistics:BSTReam[:IMMediate] (K91)............................................................ 6.704

CONFigure:BURSt:STATistics:BSTReam[:IMMediate] (K92/K93)..................................................... 6.794

CONFigure:BURSt:STATistics:BSUMmary[:IMMediate] (K92/K93)................................................... 6.795

CONFigure:BURSt:STATistics:CCDF[:IMMediate] (K91)................................................................... 6.705

CONFigure:BURSt:STATistics:CCDF[:IMMediate] (K92/K93) ........................................................... 6.795

CONFigure:BURSt:STATistics:SFIeld[:IMMediate] (K91) .................................................................. 6.705

CONFigure:CDPower[:BTS]:BCLass (K82)........................................................................................ 6.608

CONFigure:CDPower[:BTS]:BCLass (K84)........................................................................................ 6.648

CONFigure:CDPower[:BTS]:CTABle[:STATe] (K82).......................................................................... 6.604

CONFigure:CDPower[:BTS]:CTABle[:STATe] (K84).......................................................................... 6.644

CONFigure:CDPower[:BTS]:CTABle:CATalog? (K82)....................................................................... 6.605

CONFigure:CDPower[:BTS]:CTABle:CATalog? (K84)....................................................................... 6.645

CONFigure:CDPower[:BTS]:CTABle:COMMent (K82) ...................................................................... 6.605

CONFigure:CDPower[:BTS]:CTABle:COMMent (K84) ...................................................................... 6.645

CONFigure:CDPower[:BTS]:CTABle:COPY (K82)............................................................................. 6.606

CONFigure:CDPower[:BTS]:CTABle:COPY (K84)............................................................................. 6.645

CONFigure:CDPower[:BTS]:CTABle:DATA (K82) ............................................................................. 6.606

CONFigure:CDPower[:BTS]:CTABle:DATA (K84) ............................................................................. 6.646

CONFigure:CDPower[:BTS]:CTABle:DELete (K82)........................................................................... 6.607

CONFigure:CDPower[:BTS]:CTABle:DELete (K84)........................................................................... 6.647

CONFigure:CDPower[:BTS]:CTABle:NAME (K82)............................................................................. 6.607

CONFigure:CDPower[:BTS]:CTABle:NAME (K84)............................................................................. 6.647

CONFigure:CDPower[:BTS]:CTABle:SELect (K82) ........................................................................... 6.608

CONFigure:CDPower[:BTS]:CTABle:SELect (K84) ........................................................................... 6.648

CONFigure:CDPower[:BTS]:MCARier[:STATe] (K82) ....................................................................... 6.609

CONFigure:CDPower[:BTS]:MCARier[:STATe] (K84) ....................................................................... 6.649

CONFigure:CDPower[:BTS]:MEASurement (K82)............................................................................. 6.609

CONFigure:CDPower[:BTS]:MEASurement (K84)............................................................................. 6.649

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 12 E-10

CONFigure:CDPower[:BTS]:PVTime:BURSt ..................................................................................... 6.650

CONFigure:CDPower[:BTS]:PVTime:FREStart ................................................................................. 6.650

CONFigure:CDPower[:BTS]:PVTime:LIST[:STATe] .......................................................................... 6.651

CONFigure:CDPower[:BTS]:PVTime:LIST:RESult? .......................................................................... 6.651

CONFigure:CDPower[:BTS]:REVision ............................................................................................... 6.651

CONFigure:CDPower[:BTS]:RFSLot.................................................................................................. 6.652

CONFigure:CDPower:CTABle:RESTore (K82) .................................................................................. 6.610

CONFigure:CDPower:CTABle:RESTore (K84) .................................................................................. 6.648

CONFigure:CHANnel (K91)................................................................................................................ 6.705

CONFigure:CHANnel (K92/K93) ........................................................................................................ 6.795

CONFigure:CORRection (K30)........................................................................................................... 6.532

CONFigure:DTV:MEASurement (K20) ............................................................................................... 6.472

CONFigure:DTV:MEASurement:SATTenuation (K20)....................................................................... 6.472

CONFigure:LIST:CONTinuous (K30) ................................................................................................. 6.533

CONFigure:LIST:SINGle (K30)........................................................................................................... 6.533

CONFigure:POWer:AUTO (K91)........................................................................................................ 6.706

CONFigure:POWer:AUTO (K92/K93) ................................................................................................ 6.796

CONFigure:POWer:AUTO:SWEep:TIME (K91)................................................................................. 6.706

CONFigure:POWer:AUTO:SWEep:TIME (K92/K93) ......................................................................... 6.796

CONFigure:POWer:EXPected:RF (K91)............................................................................................ 6.706

CONFigure:POWer:EXPected:RF (K92/K93) .................................................................................... 6.796

CONFigure:SINGle (K30) ................................................................................................................... 6.533

CONFigure:STANdard (K91).............................................................................................................. 6.707

CONFigure:STANdard (K92/K93)....................................................................................................... 6.797

CONFigure:TV:CTABle:SELect (K20) ................................................................................................ 6.473

CONFigure:TV:MEASurement (K20).................................................................................................. 6.473

CONFigure:WCDPower:[BTS]:MEASurement (K72) ......................................................................... 6.576

CONFigure:WIMax:DLSFrame:PINDex (K93) ................................................................................... 6.798

CONFigure:WIMax:DLSFrame:PMODe (K93) ................................................................................... 6.798

CONFigure:WIMax:FBANd (K92/K93) ............................................................................................... 6.799

CONFigure:WIMax:IGRatio (K92/K93)............................................................................................... 6.800

CONFigure:WIMax:LMODe (K92/K93)............................................................................................... 6.800

DIAGnostic<1|2>:SERVice:BIOSinfo?................................................................................................ 6.122

DIAGnostic<1|2>:SERVice:HWINfo? ................................................................................................. 6.122

DIAGnostic<1|2>:SERVice:INPut[:SELect]......................................................................................... 6.123

DIAGnostic<1|2>:SERVice:INPut:PULSed[:STATe] .......................................................................... 6.123

DIAGnostic<1|2>:SERVice:INPut:PULSed:PRATe ............................................................................ 6.124

DIAGnostic<1|2>:SERVice:NSOurce ................................................................................................. 6.124

DIAGnostic<1|2>:SERVice:SFUNction............................................................................................... 6.125

DIAGnostic<1|2>:SERVice:STESt:RESult?........................................................................................ 6.125

DISPlay[:WINDow<1|2>]:SIZE............................................................................................................ 6.130

DISPlay[:WINDow<1|2>]:SIZE (K7).................................................................................................... 6.295

DISPlay[:WINDow<1|2>]:SSELect (K82)............................................................................................ 6.611

DISPlay[:WINDow<1|2>]:SSELect (K84)............................................................................................ 6.653

DISPlay[:WINDow<1|2>]:SSELect (K91)............................................................................................ 6.709

DISPlay[:WINDow<1|2>]:SSELect (K92/K93) .................................................................................... 6.812

DISPlay[:WINDow<1|2>]:TABLe (K91)............................................................................................... 6.710

DISPlay[:WINDow<1|2>]:TABLe (K92/K93) ....................................................................................... 6.812

DISPlay[:WINDow<1|2>]:TABLe:UNIT (K92/K93).............................................................................. 6.812

DISPlay[:WINDow<1|2>]:TEXT[:DATA].............................................................................................. 6.131

DISPlay[:WINDow<1|2>]:TEXT:STATe.............................................................................................. 6.131

DISPlay[:WINDow<1|2>]:TIME........................................................................................................... 6.132

DISPlay[:WINDow<1|2>]:TRACe<1...4>[:STATe] (K20) .................................................................... 6.474

DISPlay[:WINDow<1|2>]:TRACe<1...4>:MODE (K20)....................................................................... 6.474

DISPlay[:WINDow<1|2>]:TRACe<1...4>:MODE:FREeze[:STATe] .................................................... 6.474

DISPlay[:WINDow<1|2>]:TRACe<1...4>:MODE:HCONtinuous (K20)................................................ 6.475

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 13 E-10

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe] (K20)................................................................. 6.475

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:AUTO (K20)...................................................... 6.475

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:MODE (K20) ..................................................... 6.475

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:RLEVel (K20).................................................... 6.476

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:RLEVel:OFFSet (K20) ...................................... 6.476

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y[:SCALe]:RPOSition (K20) ............................................... 6.476

DISPlay[:WINDow<1|2>]:TRACe<1...4>:Y:SPACing (K20)................................................................ 6.476

DISPlay[:WINDow<1|2>]:TRACe<1...6>[:STATe] .............................................................................. 6.132

DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE................................................................................. 6.132

DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE (K72)....................................................................... 6.577

DISPlay[:WINDow<1|2>]:TRACe<1...6>:MODE:HCONtinuous ......................................................... 6.133

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]........................................................................... 6.134

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:MODE............................................................... 6.135

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:PDIVision (K7) .................................................. 6.295

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:PDIVision (K72) ................................................ 6.577

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:PDIVision (K8) .................................................. 6.369

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel.............................................................. 6.135

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RLEVel:OFFSet................................................ 6.135

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition ......................................................... 6.136

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition (K7) ................................................. 6.296

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RPOSition (K8) ................................................. 6.369

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue ............................................................ 6.136

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue (K7)..................................................... 6.296

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue (K8)..................................................... 6.369

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y[:SCALe]:RVALue:AUTO ................................................. 6.137

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y:SPACing.......................................................................... 6.134

DISPlay[:WINDow<1|2>]:TRACe<1...6>:Y:SPACing (K7).................................................................. 6.296

DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel? (K92/K93).......................................... 6.814

DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel[:RF] (K92/K93) .................................... 6.814

DISPlay[:WINDow<1|2>]:TRACe<1…3>:Y[:SCALe]:RLEVel:OFFSet (K92/K93) .............................. 6.815

DISPlay[:WINDow<1|2>]:TRACe<1…4>:Y[:SCALe]:AUTO (K91) ..................................................... 6.710

DISPlay[:WINDow<1|2>]:TRACe<1…4>:Y[:SCALe]:PDIVision (K91)................................................ 6.710

DISPlay[:WINDow<1|2>]:TRACe<1…4>:Y[:SCALe]:RLEVel (K91) ................................................... 6.711

DISPlay[:WINDow<1|2>]:TRACe<1…6>:X:SPACing......................................................................... 6.133

DISPlay[:WINDow<1|2>]:TRACe1:Y[:SCALe]:AUTO (K92/K93)........................................................ 6.813

DISPlay[:WINDow<1|2>]:TRACe1:Y[:SCALe]:PDIVision (K92/K93) .................................................. 6.813

DISPlay[:WINDow<1|2>]:ZOOM:EPATtern ........................................................................................ 6.476

DISPlay[:WINDow<1|2>]:ZOOM:EPATtern:STATe............................................................................ 6.477

DISPlay[:WINDow<1|2>]:ZOOM:MERRors ............................................................................. 6.477, 6.478

DISPlay[:WINDow<1|2>]:ZOOM:QUADrant ....................................................................................... 6.478

DISPlay[:WINDow<1>]:TABLe (K30).................................................................................................. 6.536

DISPlay[:WINDow<1>]:TRACe<1|2>[:STATe] (K30) ......................................................................... 6.536

DISPlay[:WINDow<1>]:TRACe<1|2>:SYMBols (K30) ........................................................................ 6.537

DISPlay[:WINDow<1>]:TRACe<1|2>:X[:SCALe] (K30)...................................................................... 6.537

DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:AUTO (K30)........................................................... 6.537

DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:BOTTom (K30) ...................................................... 6.538

DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:RLEVel (K30)......................................................... 6.539

DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:RLEVel:AUTO (K30).............................................. 6.539

DISPlay[:WINDow<1>]:TRACe<1|2>:Y[:SCALe]:TOP (K30) ............................................................. 6.539

DISPlay:ANNotation:FREQuency ....................................................................................................... 6.127

DISPlay:CMAP<1...26>:DEFault<1|2> ............................................................................................... 6.128

DISPlay:CMAP<1...26>:HSL .............................................................................................................. 6.128

DISPlay:CMAP<1...26>:PDEFined..................................................................................................... 6.128

DISPlay:DATA:TRACe<1> (K30) ....................................................................................................... 6.535

DISPlay:FORMat ................................................................................................................................ 6.129

DISPlay:FORMat (K30)....................................................................................................................... 6.535

DISPlay:FORMat (K82)....................................................................................................................... 6.611

DISPlay:FORMat (K84)....................................................................................................................... 6.653

DISPlay:FORMat (K91)....................................................................................................................... 6.709

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 14 E-10

DISPlay:FORMat (K92/K93) ............................................................................................................... 6.811

DISPlay:LOGO.................................................................................................................................... 6.129

DISPlay:PSAVe[:STATe] .................................................................................................................... 6.130

DISPlay:PSAVe:HOLDoff ................................................................................................................... 6.130

FETCh<1|2>:PMETer? (K9) ............................................................................................................... 6.381

FETCh:ARRay:MEMory<1...3>:NOISe:FIGure? (K30)....................................................................... 6.541

FETCh:ARRay:MEMory<1...3>:NOISe:GAIN? (K30) ......................................................................... 6.542

FETCh:ARRay:MEMory<1...3>:NOISe:TEMPerature? (K30) ............................................................ 6.542

FETCh:ARRay:NOISE:FIGure? (K30)................................................................................................ 6.543

FETCh:ARRay:NOISE:GAIN? (K30) .................................................................................................. 6.543

FETCh:ARRay:NOISE:TEMPerature? (K30)...................................................................................... 6.543

FETCh:BURSt:ALL? (K91) ................................................................................................................. 6.714

FETCh:BURSt:ALL? (K92/K93).......................................................................................................... 6.819

FETCh:BURSt:CINR? (K92/K93) ....................................................................................................... 6.819

FETCh:BURSt:COUNt? (K91)............................................................................................................ 6.714

FETCh:BURSt:COUNt? (K92/K93)..................................................................................................... 6.820

FETCh:BURSt:CRESt[:AVERage?] (K91).......................................................................................... 6.715

FETCh:BURSt:CRESt:AVERage? (K92/K93) .................................................................................... 6.820

FETCh:BURSt:CRESt:MAXimum (K91)............................................................................................. 6.715

FETCh:BURSt:CRESt:MAXimum? (K92/K93) ................................................................................... 6.820

FETCh:BURSt:CRESt:MINimum (K91) .............................................................................................. 6.715

FETCh:BURSt:CRESt:MINimum? (K92/K93)..................................................................................... 6.820

FETCh:BURSt:EVM:[IEEE]:AVERage? (K91).................................................................................... 6.715

FETCh:BURSt:EVM:[IEEE]:MAXimum? (K91)................................................................................... 6.715

FETCh:BURSt:EVM:[IEEE]:MINimum? (K91) .................................................................................... 6.715

FETCh:BURSt:EVM:ALL:AVERage (K91).......................................................................................... 6.715

FETCh:BURSt:EVM:ALL:AVERage? (K92/K93) ................................................................................ 6.820

FETCh:BURSt:EVM:ALL:MAXimum (K91)......................................................................................... 6.715

FETCh:BURSt:EVM:ALL:MAXimum? (K92/K93) ............................................................................... 6.820

FETCh:BURSt:EVM:ALL:MINimum (K91).......................................................................................... 6.715

FETCh:BURSt:EVM:ALL:MINimum? (K92/K93) ................................................................................ 6.820

FETCh:BURSt:EVM:DATA:AVERage (K91) ...................................................................................... 6.716

FETCh:BURSt:EVM:DATA:AVERage? (K92/K93) ............................................................................. 6.821

FETCh:BURSt:EVM:DATA:MAXimum (K91) ..................................................................................... 6.716

FETCh:BURSt:EVM:DATA:MAXimum? (K92/K93)............................................................................ 6.821

FETCh:BURSt:EVM:DATA:MINimum (K91)....................................................................................... 6.716

FETCh:BURSt:EVM:DATA:MINimum? (K92/K93) ............................................................................. 6.821

FETCh:BURSt:EVM:DIRect:AVERage? (K91) ................................................................................... 6.716

FETCh:BURSt:EVM:DIRect:MAXimum? (K91).................................................................................. 6.716

FETCh:BURSt:EVM:DIRect:MINimum? (K91) ................................................................................... 6.716

FETCh:BURSt:EVM:PILot:AVERage? (K91)...................................................................................... 6.716

FETCh:BURSt:EVM:PILot:AVERage? (K92/K93) .............................................................................. 6.821

FETCh:BURSt:EVM:PILot:MAXimum? (K91)..................................................................................... 6.716

FETCh:BURSt:EVM:PILot:MAXimum? (K92/K93) ............................................................................. 6.821

FETCh:BURSt:EVM:PILot:MINimum? (K91)...................................................................................... 6.716

FETCh:BURSt:EVM:PILot:MINimum? (K92/K93) .............................................................................. 6.821

FETCh:BURSt:FERRor:AVERage? (K91).......................................................................................... 6.717

FETCh:BURSt:FERRor:AVERage? (K92/K93) .................................................................................. 6.821

FETCh:BURSt:FERRor:MAXimum? (K91)......................................................................................... 6.717

FETCh:BURSt:FERRor:MAXimum? (K92/K93) ................................................................................. 6.821

FETCh:BURSt:FERRor:MINimum? (K91).......................................................................................... 6.717

FETCh:BURSt:FERRor:MINimum? (K92/K93)................................................................................... 6.821

FETCh:BURSt:GIMBalance:AVERage? (K91) ................................................................................... 6.717

FETCh:BURSt:GIMBalance:AVERage? (K92/K93)............................................................................ 6.822

FETCh:BURSt:GIMBalance:MAXimum? (K91).................................................................................. 6.717

FETCh:BURSt:GIMBalance:MAXimum? (K92/K93)........................................................................... 6.822

FETCh:BURSt:GIMBalance:MINimum? (K91) ................................................................................... 6.717

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 15 E-10

FETCh:BURSt:GIMBalance:MINimum? (K92/K93)............................................................................ 6.822

FETCh:BURSt:IQOFfset:AVERage? (K91) ........................................................................................ 6.717

FETCh:BURSt:IQOFfset:AVERage? (K92/K93)................................................................................. 6.822

FETCh:BURSt:IQOFfset:MAXimum? (K91) ....................................................................................... 6.717

FETCh:BURSt:IQOFfset:MAXimum? (K92/K93)................................................................................ 6.822

FETCh:BURSt:IQOFfset:MINimum? (K91) ........................................................................................ 6.717

FETCh:BURSt:IQOFfset:MINimum? (K92/K93)................................................................................. 6.822

FETCh:BURSt:PAYLoad? (K91) ........................................................................................................ 6.718

FETCh:BURSt:PEAK? (K91) .............................................................................................................. 6.718

FETCh:BURSt:PREamble? (K91) ...................................................................................................... 6.718

FETCh:BURSt:QUADoffset:AVERage? (K91) ................................................................................... 6.719

FETCh:BURSt:QUADoffset:AVERage? (K92/K93) ............................................................................ 6.822

FETCh:BURSt:QUADoffset:MAXimum? (K91) .................................................................................. 6.719

FETCh:BURSt:QUADoffset:MAXimum? (K92/K93) ........................................................................... 6.822

FETCh:BURSt:QUADoffset:MINimum? (K91).................................................................................... 6.719

FETCh:BURSt:QUADoffset:MINimum? (K92/K93) ............................................................................ 6.822

FETCh:BURSt:RMS[:AVERage?] (K91)............................................................................................. 6.719

FETCh:BURSt:RMS:DLPReamble:AVERage? (K92/K93)................................................................. 6.824

FETCh:BURSt:RMS:DLPReamble:MAXimum? (K92/K93)................................................................ 6.824

FETCh:BURSt:RMS:DLPReamble:MINimum? (K92/K93) ................................................................. 6.824

FETCh:BURSt:RMS:MAXimum (K91)................................................................................................ 6.719

FETCh:BURSt:RMS:MINimum? (K91) ............................................................................................... 6.719

FETCh:BURSt:RSSI (K92/K93).......................................................................................................... 6.824

FETCh:BURSt:SYMBolerror:AVERage? (K91) .................................................................................. 6.719

FETCh:BURSt:SYMBolerror:AVERage? (K92/K93)........................................................................... 6.825

FETCh:BURSt:SYMBolerror:MAXimum? (K91) ................................................................................. 6.719

FETCh:BURSt:SYMBolerror:MAXimum? (K92/K93).......................................................................... 6.825

FETCh:BURSt:SYMBolerror:MINimum? (K91) .................................................................................. 6.719

FETCh:BURSt:SYMBolerror:MINimum? (K92/K93) ........................................................................... 6.825

FETCh:BURSt:TDOMain:PREamble? (K93)...................................................................................... 6.825

FETCh:BURSt:TDOMain:SUBFrame? (K93) ..................................................................................... 6.826

FETCh:BURSt:TDOMain:ZONE? (K93) ............................................................................................. 6.826

FETCh:BURSt:TFALl:AVERage? (K91) ............................................................................................. 6.720

FETCh:BURSt:TFALl:MAXimum? (K91) ............................................................................................ 6.720

FETCh:BURSt:TFALl:MINimum? (K91) ............................................................................................. 6.720

FETCh:BURSt:TRISe:AVERage? (K91)............................................................................................. 6.720

FETCh:BURSt:TRISe:MAXimum? (K91)............................................................................................ 6.720

FETCh:BURSt:TRISe:MINimum? (K91)............................................................................................. 6.720

FETCh:SCALar:NOISE:FIGure? (K30) .............................................................................................. 6.544

FETCh:SCALar:NOISE:GAIN? (K30)................................................................................................. 6.544

FETCh:SCALar:NOISE:TEMPerature? (K30) .................................................................................... 6.544

FETCh:SYMBol:COUNt? (K91) .......................................................................................................... 6.720

FETCh:SYMBol:COUNt? (K92/K93)................................................................................................... 6.826

FORMat[:DATA].................................................................................................................................. 6.138

FORMat[:DATA] (K91)........................................................................................................................ 6.721

FORMat[:DATA] (K92/K93) ................................................................................................................ 6.828

FORMat:DEXPort:DSEParator........................................................................................................... 6.138

HCOPy[:IMMediate<1|2>]................................................................................................................... 6.139

HCOPy[:IMMediate<1|2>]:NEXT ........................................................................................................ 6.140

HCOPy:ABORt.................................................................................................................................... 6.140

HCOPy:CMAP<1...26>:DEFault1|2|3|4............................................................................................... 6.141

HCOPy:CMAP<1...26>:HSL ............................................................................................................... 6.141

HCOPy:CMAP<1...26>:PDEFined...................................................................................................... 6.142

HCOPy:DESTination<1|2> ................................................................................................................. 6.142

HCOPy:DEVice:COLor ....................................................................................................................... 6.143

HCOPy:DEVice:LANGuage<1|2>....................................................................................................... 6.143

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 16 E-10

HCOPy:ITEM:ALL............................................................................................................................... 6.144

HCOPy:ITEM:WINDow<1|2>:TEXT ................................................................................................... 6.144

HCOPy:ITEM:WINDow<1|2>:TRACe:STATe .................................................................................... 6.144

HCOPy:PAGE:ORIentation<1|2> ....................................................................................................... 6.145

HCOPy:TDSTamp:STATe<1|2>......................................................................................................... 6.145

INITiate[:IMMediate] (K30).................................................................................................................. 6.545

INITiate<1|2>[:IMMediate] .................................................................................................................. 6.146

INITiate<1|2>:CONMeas .................................................................................................................... 6.147

INITiate<1|2>:CONTinuous ................................................................................................................ 6.147

INITiate<1|2>:CONTinuous (K14) ...................................................................................................... 6.407

INITiate<1|2>:DISPlay ........................................................................................................................ 6.148

INITiate<1|2>:ESPectrum ................................................................................................................... 6.148

INITiate<1|2>:SPURious..................................................................................................................... 6.149

INPut<1|2>:ATTenuation .................................................................................................................... 6.150

INPut<1|2>:ATTenuation:AUTO ......................................................................................................... 6.151

INPut<1|2>:GAIN:STATe.................................................................................................................... 6.151

INPut<1|2>:IMPedance....................................................................................................................... 6.151

INPut<1|2>:UPORt[:VALue]?.............................................................................................................. 6.152

INPut<1|2>:UPORt:STATe ................................................................................................................. 6.152

INPut:SELect (K92/K93) ..................................................................................................................... 6.830

INSTrument[:NSELect] (K20) ............................................................................................................. 6.482

INSTrument[:NSELect] (K7) ............................................................................................................... 6.297

INSTrument[:NSELect] (K72) ............................................................................................................. 6.581

INSTrument[:NSELect] (K8) ............................................................................................................... 6.370

INSTrument[:NSELect] (K91) ............................................................................................................. 6.724

INSTrument[:NSELect] (K92/K93)...................................................................................................... 6.831

INSTrument[:SELect].......................................................................................................................... 6.153

INSTrument[:SELect] (K20)................................................................................................................ 6.482

INSTrument[:SELect] (K30)................................................................................................................ 6.547

INSTrument[:SELect] (K7).................................................................................................................. 6.297

INSTrument[:SELect] (K72)................................................................................................................ 6.581

INSTrument[:SELect] (K8).................................................................................................................. 6.370

INSTrument[:SELect] (K82)................................................................................................................ 6.613

INSTrument[:SELect] (K84)................................................................................................................ 6.655

INSTrument[:SELect] (K91)................................................................................................................ 6.724

INSTrument[:SELect] (K92/K93) ........................................................................................................ 6.831

INSTrument:NSELect ......................................................................................................................... 6.153

INSTrument:NSELect (K82) ............................................................................................................... 6.613

INSTrument:NSELect (K84) ............................................................................................................... 6.655

MMEMory:CATalog?........................................................................................................................... 6.155

MMEMory:CDIRectory........................................................................................................................ 6.156

MMEMory:CLEar:ALL......................................................................................................................... 6.156

MMEMory:CLEar:STATe .................................................................................................................... 6.156

MMEMory:COMMent .......................................................................................................................... 6.157

MMEMory:COPY ................................................................................................................................ 6.157

MMEMory:DATA................................................................................................................................. 6.157

MMEMory:DELete............................................................................................................................... 6.158

MMEMory:LOAD:AUTO...................................................................................................................... 6.159

MMEMory:LOAD:IQ:STATe (K91)...................................................................................................... 6.725

MMEMory:LOAD:IQ:STATe (K92/K93) .............................................................................................. 6.832

MMEMory:LOAD:STATe .................................................................................................................... 6.159

MMEMory:MDIRectory........................................................................................................................ 6.160

MMEMory:MOVE................................................................................................................................ 6.160

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 17 E-10

MMEMory:MSIS.................................................................................................................................. 6.161

MMEMory:NAME ................................................................................................................................ 6.161

MMEMory:NETWork:DISConnect ...................................................................................................... 6.162

MMEMory:NETWork:MAP.................................................................................................................. 6.161

MMEMory:NETWork:UNUSeddrives?................................................................................................ 6.162

MMEMory:NETWork:USEDdrives? .................................................................................................... 6.163

MMEMory:RDIRectory........................................................................................................................ 6.163

MMEMory:SELect[:ITEM]:ALL............................................................................................................ 6.163

MMEMory:SELect[:ITEM]:DEFault ..................................................................................................... 6.164

MMEMory:SELect[:ITEM]:FINal.......................................................................................................... 6.164

MMEMory:SELect[:ITEM]:HWSettings ............................................................................................... 6.164

MMEMory:SELect[:ITEM]:LINes:ALL ................................................................................................. 6.165

MMEMory:SELect[:ITEM]:NONE........................................................................................................ 6.165

MMEMory:SELect[:ITEM]:SCData...................................................................................................... 6.165

MMEMory:SELect[:ITEM]:TRACe[:ACTive]........................................................................................ 6.166

MMEMory:SELect[:ITEM]:TRANsducer:ALL ...................................................................................... 6.166

MMEMory:STORe<1|2>:LIST............................................................................................................. 6.166

MMEMory:STORe<1|2>:PEAK........................................................................................................... 6.167

MMEMory:STORe<1|2>:STATe:NEXT .............................................................................................. 6.168

MMEMory:STORe<1|2>:TRACe......................................................................................................... 6.168

MMEMory:STORe:IQ:STATe (K91).................................................................................................... 6.725

MMEMory:STORe:IQ:STATe (K92/K93) ............................................................................................ 6.833

OUTPut<1|2>[:STATe] ....................................................................................................................... 6.169

OUTPut<1|2>:IF[:SOURce] ................................................................................................................ 6.170

OUTPut:UPORt[:VALue]..................................................................................................................... 6.170

OUTPut:UPORt:STATe ...................................................................................................................... 6.171

READ<1|2>:PMETer? (K9)................................................................................................................. 6.382

[SENSe<1|2>:]ADEMod:ZOOM[:STATe>] (K7).................................................................................. 6.321

[SENSe<1|2>:]ADEMod:ZOOM[:STATe>] (K8).................................................................................. 6.371

[SENSe<1|2>:]ADEMod:ZOOM:STARt (K7) ...................................................................................... 6.322

[SENSe<1|2>:]ADEMod:ZOOM:STARt (K8) ...................................................................................... 6.372

[SENSe<1|2>:]ATV:CN:BWIDth (K20) ............................................................................................... 6.485

[SENSe<1|2>:]ATV:CN:CFRelative:NEXT (K20) ............................................................................... 6.486

[SENSe<1|2>:]ATV:CN:MEASurement:MODE (K20)......................................................................... 6.486

[SENSe<1|2>:]ATV:CN:POWer:NCORrection (K20) ......................................................................... 6.487

[SENSe<1|2>:]ATV:CN:POWer:REFerence:CHANnel:MANual (K20)............................................... 6.487

[SENSe<1|2>:]ATV:CN:POWer:REFerence:MANual (K20)............................................................... 6.487

[SENSe<1|2>:]ATV:CN:POWer:REFerence:MODE (K20)................................................................. 6.488

[SENSe<1|2>:]ATV:CN:TABle<1...10>:MFRequencies (K20)............................................................ 6.488

[SENSe<1|2>:]ATV:CSO:CFRelative:NEXT (K20)............................................................................. 6.489

[SENSe<1|2>:]ATV:CSO:MEASurement:MODE (K20) ...................................................................... 6.489

[SENSe<1|2>:]ATV:CSO:POWer:NCORrection (K20)....................................................................... 6.490

[SENSe<1|2>:]ATV:CSO:POWer:REFerence:CHANnel:MANual (K20) ............................................ 6.490

[SENSe<1|2>:]ATV:CSO:POWer:REFerence:MANual (K20) ............................................................ 6.491

[SENSe<1|2>:]ATV:CSO:POWer:REFerence:MODE (K20) .............................................................. 6.491

[SENSe<1|2>:]ATV:CSO:TABle<1...10>:MFRequencies (K20) ......................................................... 6.492

[SENSe<1|2>:]ATV:CTB:CFRelative:NEXT (K20) ............................................................................. 6.493

[SENSe<1|2>:]ATV:CTB:POWer:NCORrection (K20) ....................................................................... 6.493

[SENSe<1|2>:]ATV:CTB:POWer:REFerence:CHANnel:MANual (K20)............................................. 6.494

[SENSe<1|2>:]ATV:CTB:POWer:REFerence:MANual (K20)............................................................. 6.494

[SENSe<1|2>:]ATV:CTB:POWer:REFerence:MODE (K20)............................................................... 6.495

[SENSe<1|2>:]ATV:CTB:TABle<1...10>:MFRequencies (K20).......................................................... 6.495

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 18 E-10

[SENSe<1|2>:]AVERage[:STATe<1...4>]........................................................................................... 6.173

[SENSe<1|2>:]AVERage:COUNt........................................................................................................ 6.173

[SENSe<1|2>:]AVERage:COUNt:AUTO............................................................................................. 6.174

[SENSe<1|2>:]AVERage:TYPE.......................................................................................................... 6.174

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution] ............................................................................... 6.175

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:AUTO .................................................................... 6.175

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:RATio .................................................................... 6.176

[SENSe<1|2>:]BANDwidth|BWIDth[:RESolution]:TYPE..................................................................... 6.176

[SENSe<1|2>:]BANDwidth|BWIDth:DEMod (K7) ............................................................................... 6.323

[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo ......................................................................................... 6.177

[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:AUTO .............................................................................. 6.177

[SENSe<1|2>:]BANDwidth|BWIDth:VIDeo:RATio .............................................................................. 6.178

[SENSe<1|2>:]BANDwidth:VIDeo:TYPE ............................................................................................ 6.178

[SENSe<1|2>:]CDPower:ANTenna (K72)........................................................................................... 6.583

[SENSe<1|2>:]CDPower:ANTenna (K82)........................................................................................... 6.615

[SENSe<1|2>:]CDPower:ASEQuence (K72) ...................................................................................... 6.584

[SENSe<1|2>:]CDPower:AVERage.................................................................................................... 6.656

[SENSe<1|2>:]CDPower:CODE (K72) ............................................................................................... 6.584

[SENSe<1|2>:]CDPower:CODE (K82) ............................................................................................... 6.616

[SENSe<1|2>:]CDPower:CODE (K84) ............................................................................................... 6.657

[SENSe<1|2>:]CDPower:CTReshold.................................................................................................. 6.658

[SENSe<1|2>:]CDPower:CTYPe ........................................................................................................ 6.658

[SENSe<1|2>:]CDPower:HSDPamode (K72)..................................................................................... 6.584

[SENSe<1|2>:]CDPower:ICTReshold (K72)....................................................................................... 6.585

[SENSe<1|2>:]CDPower:ICTReshold (K82)....................................................................................... 6.616

[SENSe<1|2>:]CDPower:ICTReshold (K84)....................................................................................... 6.657

[SENSe<1|2>:]CDPower:IQLength..................................................................................................... 6.659

[SENSe<1|2>:]CDPower:IQLength (K82) ........................................................................................... 6.617

[SENSe<1|2>:]CDPower:IQLength (K84) ........................................................................................... 6.658

[SENSe<1|2>:]CDPower:LCODe[:VALue] (K72) ................................................................................ 6.585

[SENSe<1|2>:]CDPower:LCODe:DVALue (K72) ............................................................................... 6.586

[SENSe<1|2>:]CDPower:LCODe:SEARch[:IMMediate] (K72) ........................................................... 6.586

[SENSe<1|2>:]CDPower:LCODe:SEARch:LIST? (K72)..................................................................... 6.586

[SENSe<1|2>:]CDPower:LEVel:ADJust ............................................................................................. 6.659

[SENSe<1|2>:]CDPower:LEVel:ADJust (K72).................................................................................... 6.587

[SENSe<1|2>:]CDPower:LEVel:ADJust (K82).................................................................................... 6.617

[SENSe<1|2>:]CDPower:MAPPing..................................................................................................... 6.659

[SENSe<1|2>:]CDPower:MMODe ...................................................................................................... 6.660

[SENSe<1|2>:]CDPower:NORMalize ................................................................................................. 6.660

[SENSe<1|2>:]CDPower:NORMalize (K72) ....................................................................................... 6.587

[SENSe<1|2>:]CDPower:NORMalize (K82) ....................................................................................... 6.618

[SENSe<1|2>:]CDPower:ORDer (K82)............................................................................................... 6.618

[SENSe<1|2>:]CDPower:OVERview .................................................................................................. 6.661

[SENSe<1|2>:]CDPower:PNOFfset (K82) .......................................................................................... 6.619

[SENSe<1|2>:]CDPower:PNOFfset (K84) .......................................................................................... 6.661

[SENSe<1|2>:]CDPower:PREFerence (K72) ..................................................................................... 6.588

[SENSe<1|2>:]CDPower:PREFerence (K82) ..................................................................................... 6.619

[SENSe<1|2>:]CDPower:QINVert (K72)............................................................................................. 6.588

[SENSe<1|2>:]CDPower:QINVert (K82)............................................................................................. 6.620

[SENSe<1|2>:]CDPower:QINVert (K84)............................................................................................. 6.662

[SENSe<1|2>:]CDPower:RSUMmary (K72) ....................................................................................... 6.588

[SENSe<1|2>:]CDPower:SBANd (K84) .............................................................................................. 6.662

[SENSe<1|2>:]CDPower:SFACtor (K82) ............................................................................................ 6.620

[SENSe<1|2>:]CDPower:SLOT (K72) ................................................................................................ 6.589

[SENSe<1|2>:]CDPower:SLOT (K82) ................................................................................................ 6.621

[SENSe<1|2>:]CDPower:SLOT (K84) ................................................................................................ 6.662

[SENSe<1|2>:]CDPower:STYPe (K72) .............................................................................................. 6.589

[SENSe<1|2>:]CDPower:TPMeas (K82) ............................................................................................ 6.621

[SENSe<1|2>:]CORRection[:STATe] ................................................................................................. 6.179

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 19 E-10

[SENSe<1|2>:]CORRection:COLLect[:ACQuire]................................................................................ 6.180

[SENSe<1|2>:]CORRection:EGAin:INPut[:MAGNitude]..................................................................... 6.180

[SENSe<1|2>:]CORRection:EGAin:INPut[:MAGNitude] (K8)............................................................. 6.371

[SENSe<1|2>:]CORRection:METHod................................................................................................. 6.181

[SENSe<1|2>:]CORRection:RECall.................................................................................................... 6.181

[SENSe<1|2>:]CORRection:RVELocity .............................................................................................. 6.497

[SENSe<1|2>:]CORRection:TRANsducer[:STATe]............................................................................ 6.181

[SENSe<1|2>:]CORRection:TRANsducer:ADJust:RLEVel[:STATe].................................................. 6.182

[SENSe<1|2>:]CORRection:TRANsducer:COMMent......................................................................... 6.182

[SENSe<1|2>:]CORRection:TRANsducer:DATA ............................................................................... 6.182

[SENSe<1|2>:]CORRection:TRANsducer:DELete ............................................................................. 6.183

[SENSe<1|2>:]CORRection:TRANsducer:SCALing........................................................................... 6.183

[SENSe<1|2>:]CORRection:TRANsducer:SELect ............................................................................. 6.184

[SENSe<1|2>:]CORRection:TRANsducer:UNIT................................................................................. 6.184

[SENSe<1|2>:]CORRection:TRANsducer:VIEW................................................................................ 6.185

[SENSe<1|2>:]DDEMod:EQUalizer[:STATe]...................................................................................... 6.499

[SENSe<1|2>:]DDEMod:EQUalizer:FREeze[:STATe]........................................................................ 6.499

[SENSe<1|2>:]DDEMod:EQUalizer:RESet......................................................................................... 6.500

[SENSe<1|2>:]DDEMod:FILTer:ALPHa ............................................................................................. 6.500

[SENSe<1|2>:]DDEMod:FILTer:MEASurement (K8) ......................................................................... 6.373

[SENSe<1|2>:]DDEMod:SBANd......................................................................................................... 6.500

[SENSe<1|2>:]DDEMod:SEARch:PULSe[:STATe] (K8) .................................................................... 6.373

[SENSe<1|2>:]DDEMod:SEARch:PULSe:OFFSet (K8) ..................................................................... 6.374

[SENSe<1|2>:]DDEMod:SEARch:SYNC[:STATe] (K8)...................................................................... 6.374

[SENSe<1|2>:]DDEMod:SEARch:SYNC:LAP (K8) ............................................................................ 6.375

[SENSe<1|2>:]DDEMod:SEARch:SYNC:OFFSet (K8) ...................................................................... 6.375

[SENSe<1|2>:]DDEMod:SEARch:TIME (K8) ..................................................................................... 6.375

[SENSe<1|2>:]DDEMod:SEARch:TIME:AUTO (K8) .......................................................................... 6.376

[SENSe<1|2>:]DDEMod:SRATe......................................................................................................... 6.501

[SENSe<1|2>:]DETector<1...6>[:FUNCtion]....................................................................................... 6.186

[SENSe<1|2>:]DETector<1...6>[:FUNCtion]:AUTO............................................................................ 6.186

[SENSe<1|2>:]ESPectrum:BWID ....................................................................................................... 6.188

[SENSe<1|2>:]ESPectrum:FILTer[:RRC][:STATe]............................................................................. 6.188

[SENSe<1|2>:]ESPectrum:FILTer[:RRC]:ALPHa............................................................................... 6.189

[SENSe<1|2>:]ESPectrum:PRESet[:STANdard] ................................................................................ 6.189

[SENSe<1|2>:]ESPectrum:PRESet:RESTore .................................................................................... 6.190

[SENSe<1|2>:]ESPectrum:RANGe<1...20>[:FREQuency]:STARt..................................................... 6.192

[SENSe<1|2>:]ESPectrum:RANGe<1...20>[:FREQuency]:STOP...................................................... 6.193

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth.................................................................... 6.190

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth:RESolution................................................. 6.190

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:BANDwidth:VIDeo......................................................... 6.191

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:COUNt? ........................................................................ 6.191

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:DELete .......................................................................... 6.192

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:FILTer:TYPE ................................................................. 6.193

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:ATTenuation ....................................................... 6.193

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:ATTenuation:AUTO ............................................ 6.194

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INPut:GAIN:STATe ....................................................... 6.194

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:INSert ............................................................................ 6.195

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:ABSolute:STARt................................................... 6.195

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:ABSolute:STOP.................................................... 6.195

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:RELative:STARt ................................................... 6.196

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:RELative:STOP .................................................... 6.196

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:LIMit:STATe .................................................................. 6.197

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:RLEVel .......................................................................... 6.197

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:SWEep:TIME ................................................................ 6.198

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:SWEep:TIME:AUTO ..................................................... 6.198

[SENSe<1|2>:]ESPectrum:RANGe<1...20>:TRANsducer ................................................................. 6.198

[SENSe<1|2>:]ESPectrum:RRANge?................................................................................................. 6.199

[SENSe<1|2>:]ESPectrum:RTYPe ..................................................................................................... 6.199

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 20 E-10

[SENSe<1|2>:]ESPectrum:STORe.......................................................................................... 6.190, 6.623

[SENSe<1|2>:]FILTer:DEMPhasis (K7).............................................................................................. 6.324

[SENSe<1|2>:]FILTer:DEMPhasis:TCONstant (K7)........................................................................... 6.324

[SENSe<1|2>:]FILTer:HPASs[:STATE] (K7) ...................................................................................... 6.325

[SENSe<1|2>:]FILTer:HPASs:FREQuency (K7) ................................................................................ 6.325

[SENSe<1|2>:]FILTer:LPASs[:STATE] (K7)....................................................................................... 6.325

[SENSe<1|2>:]FILTer:LPASs:FREQuency[:ABSolute] (K7) ............................................................... 6.326

[SENSe<1|2>:]FILTer:LPASs:FREQuency:RELative (K7) ................................................................. 6.326

[SENSe<1|2>:]FREQuency:CENTer .................................................................................................. 6.200

[SENSe<1|2>:]FREQuency:CENTer:STEP ........................................................................................ 6.201

[SENSe<1|2>:]FREQuency:CENTer:STEP:AUTO ............................................................................. 6.201

[SENSe<1|2>:]FREQuency:CENTer:STEP:LINK ............................................................................... 6.201

[SENSe<1|2>:]FREQuency:CENTer:STEP:LINK (K7) ....................................................................... 6.327

[SENSe<1|2>:]FREQuency:CENTer:STEP:LINK:FACTor ................................................................. 6.202

[SENSe<1|2>:]FREQuency:CHANnel (K20)....................................................................................... 6.502

[SENSe<1|2>:]FREQuency:MODE..................................................................................................... 6.202

[SENSe<1|2>:]FREQuency:OFFSet................................................................................................... 6.203

[SENSe<1|2>:]FREQuency:RF (K20)................................................................................................. 6.502

[SENSe<1|2>:]FREQuency:SPAN...................................................................................................... 6.203

[SENSe<1|2>:]FREQuency:SPAN:FULL............................................................................................ 6.203

[SENSe<1|2>:]LIST:POWer[:SEQuence]........................................................................................... 6.206

[SENSe<1|2>:]LIST:POWer:RESult? ................................................................................................. 6.208

[SENSe<1|2>:]LIST:POWer:SET ....................................................................................................... 6.208

[SENSe<1|2>:]LIST:POWer:STATe ................................................................................................... 6.209

[SENSe<1|2>:]LIST:RANGe<1...20>[:FREQuency]:STARt................................................................ 6.212

[SENSe<1|2>:]LIST:RANGe<1...20>[:FREQuency]:STOP ................................................................ 6.212

[SENSe<1|2>:]LIST:RANGe<1...20>:BANDwidth .............................................................................. 6.210

[SENSe<1|2>:]LIST:RANGe<1...20>:BANDwidth:RESolution ........................................................... 6.210

[SENSe<1|2>:]LIST:RANGe<1...20>:BANDwidth:VIDeo ................................................................... 6.211

[SENSe<1|2>:]LIST:RANGe<1...20>:BREak...................................................................................... 6.211

[SENSe<1|2>:]LIST:RANGe<1...20>:COUNt? ................................................................................... 6.211

[SENSe<1|2>:]LIST:RANGe<1...20>:DELete..................................................................................... 6.211

[SENSe<1|2>:]LIST:RANGe<1...20>:DETector ................................................................................. 6.211

[SENSe<1|2>:]LIST:RANGe<1...20>:FILTer:TYPE............................................................................ 6.212

[SENSe<1|2>:]LIST:RANGe<1...20>:INPut:ATTenuation .................................................................. 6.212

[SENSe<1|2>:]LIST:RANGe<1...20>:INPut:ATTenuation:AUTO ....................................................... 6.212

[SENSe<1|2>:]LIST:RANGe<1...20>:INPut:GAIN:STATe.................................................................. 6.213

[SENSe<1|2>:]LIST:RANGe<1...20>:LIMit:STARt ............................................................................. 6.213

[SENSe<1|2>:]LIST:RANGe<1...20>:LIMit:STATe............................................................................. 6.214

[SENSe<1|2>:]LIST:RANGe<1...20>:LIMit:STOP .............................................................................. 6.214

[SENSe<1|2>:]LIST:RANGe<1...20>:POINts ..................................................................................... 6.213

[SENSe<1|2>:]LIST:RANGe<1...20>:RLEVel..................................................................................... 6.213

[SENSe<1|2>:]LIST:RANGe<1...20>:SWEep:TIME........................................................................... 6.213

[SENSe<1|2>:]LIST:RANGe<1...20>:SWEep:TIME:AUTO................................................................ 6.213

[SENSe<1|2>:]LIST:RANGe<1...20>:TRANsducer ............................................................................ 6.214

[SENSe<1|2>:]MPOWer[:SEQuence]................................................................................................. 6.216

[SENSe<1|2>:]MPOWer:FTYPe......................................................................................................... 6.218

[SENSe<1|2>:]MPOWer:RESult[:LIST]? ............................................................................................ 6.218

[SENSe<1|2>:]MPOWer:RESult:MIN? ............................................................................................... 6.219

[SENSe<1|2>:]PMETer[:STATe] (K9)................................................................................................. 6.383

[SENSe<1|2>:]PMETer:FREQuency (K9) .......................................................................................... 6.384

[SENSe<1|2>:]PMETer:FREQuency:LINK (K9) ................................................................................. 6.384

[SENSe<1|2>:]PMETer:MTIMe (K9)................................................................................................... 6.384

[SENSe<1|2>:]PMETer:MTIMe:AVERage[:STATe] ........................................................................... 6.385

[SENSe<1|2>:]PMETer:MTIMe:AVERage:COUNt ............................................................................. 6.385

[SENSe<1|2>:]PMETer:ROFFset[:STATe] (K9) ................................................................................. 6.386

[SENSe<1|2>:]PMETer:TRIGger:LEVel (K9) ..................................................................................... 6.387

[SENSe<1|2>:]PMETer:TRIGger:STATe (K9).................................................................................... 6.386

[SENSe<1|2>:]POWer:ACHannel:ACPairs ........................................................................................ 6.220

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 21 E-10

[SENSe<1|2>:]POWer:ACHannel:BANDwidth|BWIDth[:CHANnel].................................................... 6.221

[SENSe<1|2>:]POWer:ACHannel:BANDwidth|BWIDth:ACHannel .................................................... 6.221

[SENSe<1|2>:]POWer:ACHannel:BANDwidth|BWIDth:ALTernate<1...11>....................................... 6.222

[SENSe<1|2>:]POWer:ACHannel:MODE........................................................................................... 6.222

[SENSe<1|2>:]POWer:ACHannel:PRESet......................................................................................... 6.222

[SENSe<1|2>:]POWer:ACHannel:PRESet:RLEVel............................................................................ 6.223

[SENSe<1|2>:]POWer:ACHannel:REFerence:AUTO ........................................................................ 6.223

[SENSe<1|2>:]POWer:ACHannel:REFerence:TXCHannel:AUTO..................................................... 6.224

[SENSe<1|2>:]POWer:ACHannel:REFerence:TXCHannel:MANual.................................................. 6.224

[SENSe<1|2>:]POWer:ACHannel:SPACing:ALTernate<1...11> ........................................................ 6.225

[SENSe<1|2>:]POWer:ACHannel:SPACing:CHANnel<1...11>.......................................................... 6.226

[SENSe<1|2>:]POWer:ACHannel:TXCHannel:COUNt ...................................................................... 6.226

[SENSe<1|2>:]POWer:BANDwidth|BWIDth ....................................................................................... 6.226

[SENSe<1|2>:]POWer:HSPeed.......................................................................................................... 6.227

[SENSe<1|2>:]POWer:TRACe ........................................................................................................... 6.227

[SENSe<1|2>:]ROSCillator:SOURce.................................................................................................. 6.228

[SENSe<1|2>:]SWEep:COUNt ........................................................................................................... 6.229

[SENSe<1|2>:]SWEep:COUNt:CURRent?......................................................................................... 6.230

[SENSe<1|2>:]SWEep:EGATe........................................................................................................... 6.230

[SENSe<1|2>:]SWEep:EGATe:HOLDoff............................................................................................ 6.231

[SENSe<1|2>:]SWEep:EGATe:LENGth ............................................................................................. 6.231

[SENSe<1|2>:]SWEep:EGATe:POLarity............................................................................................ 6.231

[SENSe<1|2>:]SWEep:EGATe:SOURce............................................................................................ 6.232

[SENSe<1|2>:]SWEep:EGATe:TYPE ................................................................................................ 6.232

[SENSe<1|2>:]SWEep:MODE............................................................................................................ 6.233

[SENSe<1|2>:]SWEep:POINts ........................................................................................................... 6.233

[SENSe<1|2>:]SWEep:SPACing (K20) .............................................................................................. 6.505

[SENSe<1|2>:]SWEep:TIME .............................................................................................................. 6.234

[SENSe<1|2>:]SWEep:TIME (K7) ...................................................................................................... 6.327

[SENSe<1|2>:]SWEep:TIME:AUTO................................................................................................... 6.234

[SENSe<1|2>:]TV:MSTandard:FILTer:GDELay ................................................................................. 6.506

[SENSe<1|2>:]TV:MSTandard:NAME ................................................................................................ 6.506

[SENSe<1|2>:]TV:MSTandard:STYPe ............................................................................................... 6.507

[SENSe<1|2>:]TV:TILT:MSTandard:CDISable (K20)......................................................................... 6.507

[SENSe<1|2>:]TV:TILT:MSTandard:CENable (K20).......................................................................... 6.508

[SENSe:]ADEMod[:STATe] (K7)......................................................................................................... 6.301

[SENSe:]ADEMod:AF:CENTer (K7) ................................................................................................... 6.301

[SENSe:]ADEMod:AF:COUPling (K7) ................................................................................................ 6.302

[SENSe:]ADEMod:AF:SPAN (K7) ...................................................................................................... 6.302

[SENSe:]ADEMod:AF:SPAN:FULL (K7)............................................................................................. 6.303

[SENSe:]ADEMod:AF:STARt (K7)...................................................................................................... 6.303

[SENSe:]ADEMod:AF:STOP (K7) ...................................................................................................... 6.304

[SENSe:]ADEMod:AM[:TDOMain][:TYPE] (K7).................................................................................. 6.304

[SENSe:]ADEMod:AM[:TDOMain]:RESult? (K7)................................................................................ 6.305

[SENSe:]ADEMod:AM:RELative[:TDOMain][:TYPE] (K7) .................................................................. 6.305

[SENSe:]ADEMod:AM:RELative[:TDOMain]:RESult? (K7) ................................................................ 6.306

[SENSe:]ADEMod:AM:RELative:AFSPectrum[:TYPE] (K7) ............................................................... 6.307

[SENSe:]ADEMod:AM:RELative:AFSPectrum:RESult? (K7) ............................................................. 6.307

[SENSe:]ADEMod:BANDwidth | BWIDth:DEModulation (K7) ............................................................ 6.308

[SENSe:]ADEMod:FM[:TDOMain][:TYPE] (K7).................................................................................. 6.309

[SENSe:]ADEMod:FM[:TDOMain]:RESult? (K7) ................................................................................ 6.309

[SENSe:]ADEMod:FM:AFSPectrum[:TYPE] (K7)............................................................................... 6.310

[SENSe:]ADEMod:FM:AFSPectrum:RESult? (K7) ............................................................................. 6.310

[SENSe:]ADEMod:FM:OFFSet? (K7) ................................................................................................. 6.311

[SENSe:]ADEMod:MTIMe (K7)........................................................................................................... 6.312

[SENSe:]ADEMod:PM[:TDOMain][:TYPE] (K7).................................................................................. 6.313

[SENSe:]ADEMod:PM[:TDOMain]:RESult? (K7)................................................................................ 6.313

[SENSe:]ADEMod:PM:AFSPectrum[:TYPE] (K7)............................................................................... 6.314

[SENSe:]ADEMod:PM:AFSPectrum:RESult? (K7)............................................................................. 6.315

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 22 E-10

[SENSe:]ADEMod:PM:RPOint[:X] (K7) .............................................................................................. 6.316

[SENSe:]ADEMod:RLENgth? (K7) ..................................................................................................... 6.316

[SENSe:]ADEMod:SET (K7)............................................................................................................... 6.316

[SENSe:]ADEMod:SPECtrum[:TYPE] (K7) ........................................................................................ 6.318

[SENSe:]ADEMod:SPECtrum:BANDwidth|BWIDth[:RESolution] (K7) ............................................... 6.318

[SENSe:]ADEMod:SPECtrum:RESult? (K7)....................................................................................... 6.319

[SENSe:]ADEMod:SPECtrum:SPAN:ZOOM (K7) .............................................................................. 6.320

[SENSe:]ADEMod:SRATe? (K7) ........................................................................................................ 6.321

[SENSe:]BANDwidth:CHANnel (K92/K93).......................................................................................... 6.835

[SENSe:]BURSt:COUNt (K91)............................................................................................................ 6.728

[SENSe:]BURSt:COUNt (K92/K93) .................................................................................................... 6.835

[SENSe:]BURSt:COUNt:STATe (K91) ............................................................................................... 6.728

[SENSe:]BURSt:COUNt:STATe (K92/K93)........................................................................................ 6.836

[SENSe:]CONFigure:MODE:DUT (K30)............................................................................................. 6.554

[SENSe:]CONFigure:MODE:SYSTem:LOSCillator:FREQuency (K30).............................................. 6.555

[SENSe:]CORRection[:STATe] (K30)................................................................................................. 6.548

[SENSe:]CORRection:ENR[:MEASurement]:TABLe:DATA (K30) ..................................................... 6.549

[SENSe:]CORRection:ENR:MODE (K30)........................................................................................... 6.549

[SENSe:]CORRection:ENR:SPOT (K30)............................................................................................ 6.549

[SENSe:]CORRection:IREJection (K30)............................................................................................. 6.550

[SENSe:]CORRection:LOSS:INPut:MODE (K30)............................................................................... 6.550

[SENSe:]CORRection:LOSS:INPut:SPOT (K30)................................................................................ 6.551

[SENSe:]CORRection:LOSS:INPut:TABLe (K30) .............................................................................. 6.551

[SENSe:]CORRection:LOSS:OUTPut:MODE (K30) .......................................................................... 6.552

[SENSe:]CORRection:LOSS:OUTPut:SPOT (K30) ........................................................................... 6.552

[SENSe:]CORRection:LOSS:OUTPut:TABLe (K30) .......................................................................... 6.552

[SENSe:]CORRection:TEMPerature (K30)......................................................................................... 6.553

[SENSe:]DEMod:BANalyze:DURation:EQUal (K91) .......................................................................... 6.729

[SENSe:]DEMod:BANalyze:DURation:MAX (K91) ............................................................................. 6.729

[SENSe:]DEMod:BANalyze:DURation:MIN (K91) .............................................................................. 6.729

[SENSe:]DEMod:CESTimation (K91) ................................................................................................. 6.730

[SENSe:]DEMod:CESTimation (K92/K93).......................................................................................... 6.836

[SENSe:]DEMod:FILTer:CATalog? (K91)........................................................................................... 6.730

[SENSe:]DEMod:FILTer:CATalog? (K92/K93) ................................................................................... 6.837

[SENSe:]DEMod:FILTer:MODulation (K91)........................................................................................ 6.731

[SENSe:]DEMod:FILTer:MODulation (K92/K93) ................................................................................ 6.837

[SENSe:]DEMod:FORMat[:BCONtent]:AUTo (K91) ........................................................................... 6.731

[SENSe:]DEMod:FORMat[:BCONtent]:AUTo (K92/K93).................................................................... 6.837

[SENSe:]DEMod:FORMat:BANalyze (K91) ........................................................................................ 6.731

[SENSe:]DEMod:FORMat:BANalyze (K92/K93)................................................................................. 6.838

[SENSe:]DEMod:FORMat:BANalyze:BTYPe (K91)............................................................................ 6.732

[SENSe:]DEMod:FORMat:BANalyze:DBYTes:EQUal (K91) .............................................................. 6.732

[SENSe:]DEMod:FORMat:BANalyze:DBYTes:MAX (K91)................................................................. 6.733

[SENSe:]DEMod:FORMat:BANalyze:DBYTes:MIN (K91) .................................................................. 6.733

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal (K91)............................................................. 6.734

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:EQUal (K92/K93) ..................................................... 6.838

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MAX (K91) ............................................................... 6.734

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MAX (K92/K93) ........................................................ 6.839

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MIN (K91)................................................................. 6.735

[SENSe:]DEMod:FORMat:BANalyze:SYMBols:MIN (K92/K93) ......................................................... 6.839

[SENSe:]DEMod:FORMat:BTRate (K91) ........................................................................................... 6.735

[SENSe:]DEMod:FORMat:SIGSymbol (K91) ..................................................................................... 6.736

[SENSe:]FREQuency[:CW|:FIXed] (K30)........................................................................................... 6.555

[SENSe:]FREQuency:LIST:DATA (K30) ............................................................................................ 6.555

[SENSe:]FREQuency:STARt (K30) .................................................................................................... 6.556

[SENSe:]FREQuency:STEP (K30) ..................................................................................................... 6.556

[SENSe:]FREQuency:STOP (K30)..................................................................................................... 6.557

[SENSe:]POWer:ACHannel:ACPairs (K92/K93) ................................................................................ 6.840

[SENSe:]POWer:ACHannel:MODE (K91) .......................................................................................... 6.736

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 23 E-10

[SENSe:]POWer:ACHannel:MODE (K92/K93)................................................................................... 6.842

[SENSe:]POWer:NCORrection (K92/K93) ......................................................................................... 6.843

[SENSe:]POWer:SEM:MODe (K93) ................................................................................................... 6.843

[SENSe:]SWAPiq (K91)...................................................................................................................... 6.737

[SENSe:]SWAPiq (K92/K93) .............................................................................................................. 6.845

[SENSe:]SWEep:ACPR:TIME (K92/K93)........................................................................................... 6.846

[SENSe:]SWEep:ACPR:TIME:AUTO ................................................................................................. 6.846

[SENSe:]SWEep:COUNt (K30) .......................................................................................................... 6.557

[SENSe:]SWEep:COUNt (K91) .......................................................................................................... 6.737

[SENSe:]SWEep:COUNt (K92/K93)................................................................................................... 6.846

[SENSe:]SWEep:EGATe:HOLDoff[:TIME] (K91) ............................................................................... 6.737

[SENSe:]SWEep:EGATe:HOLDoff[:TIME] (K92/K93)........................................................................ 6.847

[SENSe:]SWEep:EGATe:HOLDoff:SAMPle (K91)............................................................................. 6.738

[SENSe:]SWEep:EGATe:HOLDoff:SAMPle (K92/K93)...................................................................... 6.847

[SENSe:]SWEep:EGATe:LENGth[:TIME] (K91)................................................................................. 6.738

[SENSe:]SWEep:EGATe:LENGth[:TIME] (K92/K93) ......................................................................... 6.847

[SENSe:]SWEep:EGATe:LENGth:SAMPle (K91) .............................................................................. 6.738

[SENSe:]SWEep:EGATe:LENGth:SAMPle (K92/K93)....................................................................... 6.848

[SENSe:]SWEep:EGATe:LINK (K91) ................................................................................................. 6.739

[SENSe:]SWEep:EGATe:LINK (K92/K93).......................................................................................... 6.848

[SENSe:]SWEep:TIME (K91) ............................................................................................................. 6.739

[SENSe:]SWEep:TIME (K92/K93)...................................................................................................... 6.848

[SENSe:]TRACking:LEVel (K91) ........................................................................................................ 6.739

[SENSe:]TRACking:LEVel (K92/K93)................................................................................................. 6.849

[SENSe:]TRACking:PHASe (K91) ...................................................................................................... 6.740

[SENSe:]TRACking:PHASe (K92/K93)............................................................................................... 6.849

[SENSe:]TRACking:TIME (K91) ......................................................................................................... 6.740

[SENSe:]TRACking:TIME (K92/K93).................................................................................................. 6.850

SOURce<1|2>:EXTernal<1|2>:ROSCillator[:SOURce] ...................................................................... 6.235

SOURce<1|2>:POWer[:LEVel][:IMMediate][:AMPLitude]................................................................... 6.236

SOURce<1|2>:POWer[:LEVel][:IMMediate]:OFFSet.......................................................................... 6.236

SOURce:TEMPerature:APRobe?....................................................................................................... 6.235

STATus:ERRor ................................................................................................................................... 6.257

STATus:OPERation[:EVENt]? ............................................................................................................ 6.237

STATus:OPERation:CONDition?........................................................................................................ 6.237

STATus:OPERation:ENABle .............................................................................................................. 6.238

STATus:OPERation:NTRansition....................................................................................................... 6.238

STATus:OPERation:PTRansition ....................................................................................................... 6.238

STATus:PRESet ................................................................................................................................. 6.239

STATus:QUESionable:CORRection[:EVENt]? (K30) ......................................................................... 6.558

STATus:QUESionable:CORRection:CONDition? (K30)..................................................................... 6.559

STATus:QUESionable:CORRection:ENABle (K30) ........................................................................... 6.559

STATus:QUESionable:CORRection:NTRansition (K30) .................................................................... 6.559

STATus:QUESionable:CORRection:PTRansition (K30) .................................................................... 6.560

STATus:QUEStionable[:EVENt]? ....................................................................................................... 6.240

STATus:QUEStionable:ACPLimit[:EVENt]? ....................................................................................... 6.242

STATus:QUEStionable:ACPLimit:CONDition?................................................................................... 6.242

STATus:QUEStionable:ACPLimit:ENABle ......................................................................................... 6.243

STATus:QUEStionable:ACPLimit:NTRansition .................................................................................. 6.243

STATus:QUEStionable:ACPLimit:PTRansition .................................................................................. 6.243

STATus:QUEStionable:CONDition?................................................................................................... 6.240

STATus:QUEStionable:ENABle ......................................................................................................... 6.241

STATus:QUEStionable:FREQuency[:EVENt]?................................................................................... 6.244

STATus:QUEStionable:FREQuency:CONDition? .............................................................................. 6.244

STATus:QUEStionable:FREQuency:ENABle..................................................................................... 6.244

STATus:QUEStionable:FREQuency:NTRansition.............................................................................. 6.245

STATus:QUEStionable:FREQuency:NTRansition (K30).................................................................... 6.560

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 24 E-10

STATus:QUEStionable:FREQuency:PTRansition.............................................................................. 6.245

STATus:QUEStionable:FREQuency:PTRansition (K30) .................................................................... 6.561

STATus:QUEStionable:LIMit<1|2> [:EVENt]? .................................................................................... 6.245

STATus:QUEStionable:LIMit<1|2>:CONDition?................................................................................. 6.246

STATus:QUEStionable:LIMit<1|2>:ENABle........................................................................................ 6.246

STATus:QUEStionable:LIMit<1|2>:NTRansition ................................................................................ 6.246

STATus:QUEStionable:LIMit<1|2>:NTRansition (K30) ...................................................................... 6.561

STATus:QUEStionable:LIMit<1|2>:PTRansition ................................................................................ 6.247

STATus:QUEStionable:LIMit<1|2>:PTRansition (K30)....................................................................... 6.562

STATus:QUEStionable:LMARgin<1|2>[:EVENt]? .............................................................................. 6.247

STATus:QUEStionable:LMARgin<1|2>:CONDition?.......................................................................... 6.247

STATus:QUEStionable:LMARgin<1|2>:ENABle................................................................................. 6.248

STATus:QUEStionable:LMARgin<1|2>:NTRansition ......................................................................... 6.248

STATus:QUEStionable:LMARgin<1|2>:PTRansition ......................................................................... 6.248

STATus:QUEStionable:NTRansition .................................................................................................. 6.241

STATus:QUEStionable:POWer[:EVENt]? .......................................................................................... 6.249

STATus:QUEStionable:POWer:CONDition?...................................................................................... 6.249

STATus:QUEStionable:POWer:ENABle ............................................................................................ 6.249

STATus:QUEStionable:POWer:NTRansition ..................................................................................... 6.250

STATus:QUEStionable:POWer:PTRansition ..................................................................................... 6.250

STATus:QUEStionable:PTRansition .................................................................................................. 6.241

STATus:QUEStionable:SYNC[:EVENt]? ............................................................................................ 6.250

STATus:QUEStionable:SYNC[:EVENt]? (K91) .................................................................................. 6.743

STATus:QUEStionable:SYNC[:EVENt]? (K92/K93) ........................................................................... 6.852

STATus:QUEStionable:SYNC:CONDition?........................................................................................ 6.251

STATus:QUEStionable:SYNC:CONDition? (K91).............................................................................. 6.743

STATus:QUEStionable:SYNC:CONDition? (K92/K93)....................................................................... 6.852

STATus:QUEStionable:SYNC:ENABle .............................................................................................. 6.251

STATus:QUEStionable:SYNC:ENABle (K91)..................................................................................... 6.743

STATus:QUEStionable:SYNC:ENABle (K92/K93) ............................................................................. 6.853

STATus:QUEStionable:SYNC:NTRansition ....................................................................................... 6.251

STATus:QUEStionable:SYNC:NTRansition (K91) ............................................................................. 6.744

STATus:QUEStionable:SYNC:NTRansition (K92/K93)...................................................................... 6.854

STATus:QUEStionable:SYNC:PTRansition ....................................................................................... 6.252

STATus:QUEStionable:SYNC:PTRansition (K91).............................................................................. 6.744

STATus:QUEStionable:SYNC:PTRansition (K92/K93) ...................................................................... 6.853

STATus:QUEue.................................................................................................................................. 6.242

SYSTem:COMMunicate:GPIB[:SELF]:ADDRess ............................................................................... 6.254

SYSTem:COMMunicate:GPIB[:SELF]:RTERminator......................................................................... 6.254

SYSTem:COMMunicate:PRINter:ENUMerate:FIRSt? ....................................................................... 6.255

SYSTem:COMMunicate:PRINter:ENUMerate:NEXT? ....................................................................... 6.254

SYSTem:COMMunicate:PRINter:SELect <1|2>................................................................................. 6.255

SYSTem:CONFigure:DUT:GAIN (K30) .............................................................................................. 6.563

SYSTem:CONFigure:DUT:STIMe (K30) ............................................................................................ 6.563

SYSTem:DATE................................................................................................................................... 6.256

SYSTem:DISPlay:FPANel .................................................................................................................. 6.256

SYSTem:DISPlay:UPDate.................................................................................................................. 6.256

SYSTem:ERRor:CLEar:ALL ............................................................................................................... 6.257

SYSTem:ERRor:LIST?....................................................................................................................... 6.257

SYSTem:FIRMware:UPDate .............................................................................................................. 6.258

SYSTem:FORMat:IDENt .................................................................................................................... 6.258

SYSTem:LANGuage........................................................................................................................... 6.258

SYSTem:LXI:INFo? ............................................................................................................................ 6.259

SYSTem:LXI:LANReset...................................................................................................................... 6.259

SYSTem:LXI:MDEScription ................................................................................................................ 6.259

SYSTem:LXI:PASSword..................................................................................................................... 6.260

SYSTem:PASSword[:CENable].......................................................................................................... 6.260

SYSTem:PASSword:RESet]............................................................................................................... 6.260

R&S FSL Alphabetical List of Remote Commands

1300.2519.12 Index 25 E-10

SYSTem:PRESet................................................................................................................................ 6.261

SYSTem:SPEaker:VOLume............................................................................................................... 6.262

SYSTem:TIME.................................................................................................................................... 6.261

SYSTem:VERSion?............................................................................................................................ 6.261

TRACe[:DATA] (K91).......................................................................................................................... 6.749

TRACe[:DATA] (K92/K93) .................................................................................................................. 6.862

TRACe<1|2>[:DATA] .................................................................................................... 6.263, 6.516, 6.665

TRACe<1|2>[:DATA] (K7) .................................................................................................................. 6.328

TRACe<1|2>[:DATA] (K72) ................................................................................................................ 6.593

TRACe<1|2>[:DATA]? LIST................................................................................................................ 6.665

TRACe<1|2>:IQ[:STATe].................................................................................................................... 6.272

TRACe<1|2>:IQ:AVERage[:STATe] ................................................................................................... 6.272

TRACe<1|2>:IQ:AVERage:COUNt..................................................................................................... 6.273

TRACe<1|2>:IQ:DATA? ..................................................................................................................... 6.273

TRACe<1|2>:IQ:DATA:MEMory? ....................................................................................................... 6.274

TRACe<1|2>:IQ:SET .......................................................................................................................... 6.275

TRACe<1|2>:IQ:SRATe 15.625kHz to 32MHz................................................................................... 6.276

TRACe<1<2>[:DATA] (K82) ............................................................................................................... 6.624

TRACe:COPY..................................................................................................................................... 6.264

TRACe:COPY (K20) ........................................................................................................................... 6.516

TRACe:IQ:SRATe (K91)..................................................................................................................... 6.750

TRACe:IQ:SRATe (K92/K93) ............................................................................................................. 6.863

TRACe1:DATA? SPECtrogram (K14) ................................................................................................ 6.409

TRIGger[:SEQuence]:HOLDoff (K91)................................................................................................. 6.751

TRIGger[:SEQuence]:HOLDoff (K92/K93) ......................................................................................... 6.864

TRIGger[:SEQuence]:LEVel:POWer (K91) ........................................................................................ 6.752

TRIGger[:SEQuence]:LEVel:POWer (K92/K93)................................................................................. 6.865

TRIGger[:SEQuence]:LEVel:POWer:AUTO (K91) ............................................................................. 6.752

TRIGger[:SEQuence]:LEVel:POWer:AUTO (K92/K93)...................................................................... 6.866

TRIGger[:SEQuence]:MODE (K91).................................................................................................... 6.751

TRIGger[:SEQuence]:MODE (K92/K93) ............................................................................................ 6.865

TRIGger<1|2[:SEQuence]:LEVel[:EXTernal]...................................................................................... 6.279

TRIGger<1|2>[:SEQuence]:HOLDoff ................................................................................................. 6.277

TRIGger<1|2>[:SEQuence]:IFPower:HOLDoff................................................................................... 6.278

TRIGger<1|2>[:SEQuence]:IFPower:HYSTeresis.............................................................................. 6.278

TRIGger<1|2>[:SEQuence]:LEVel:AM[:ABSolute] (K7)...................................................................... 6.329

TRIGger<1|2>[:SEQuence]:LEVel:AM:RELative (K7) ........................................................................ 6.329

TRIGger<1|2>[:SEQuence]:LEVel:FM (K7)........................................................................................ 6.330

TRIGger<1|2>[:SEQuence]:LEVel:IFPower........................................................................................ 6.279

TRIGger<1|2>[:SEQuence]:LEVel:PM (K7)........................................................................................ 6.330

TRIGger<1|2>[:SEQuence]:LEVel:VIDeo........................................................................................... 6.279

TRIGger<1|2>[:SEQuence]:SLOPe.................................................................................................... 6.280

TRIGger<1|2>[:SEQuence]:SOURce ................................................................................................. 6.280

TRIGger<1|2>[:SEQuence]:SOURce (K7) ......................................................................................... 6.330

TRIGger<1|2>[:SEQuence]:SOURce (K72) ....................................................................................... 6.595

TRIGger<1|2>[:SEQuence]:TIME:RINTerval...................................................................................... 6.280

TRIGger<1|2>[:SEQuence]:VIDeo:BFIeld[:NUMBer] ......................................................................... 6.517

TRIGger<1|2>[:SEQuence]:VIDeo:BLINe[:NUMBer].......................................................................... 6.517

TRIGger<1|2>[:SEQuence]:VIDeo:BLINe:TYPE ................................................................................ 6.518

TRIGger<1|2>[:SEQuence]:VIDeo:CONTinuous................................................................................ 6.281

TRIGger<1|2>[:SEQuence]:VIDeo:FIELd:NUMBer (K20) .................................................................. 6.518

TRIGger<1|2>[:SEQuence]:VIDeo:FIELd:SELect .............................................................................. 6.281

TRIGger<1|2>[:SEQuence]:VIDeo:FORMat:LPFRame...................................................................... 6.281

TRIGger<1|2>[:SEQuence]:VIDeo:LINE:NUMBer................................................................... 6.282, 6.519

TRIGger<1|2>[:SEQuence]:VIDeo:QFIeld[:NUMBer]......................................................................... 6.519

TRIGger<1|2>[:SEQuence]:VIDeo:QLINe[:NUMBer] ......................................................................... 6.519

Alphabetical List of Remote Commands R&S FSL

1300.2519.12 Index 26 E-10

TRIGger<1|2>[:SEQuence]:VIDeo:SSIGnal:POLarity ........................................................................ 6.282

UNIT<1|2>:PMETer:POWer (K9) ....................................................................................................... 6.388

UNIT<1|2>:PMETer:POWer:RATio (K9) ............................................................................................ 6.388

UNIT<1|2>:POWer ............................................................................................................................. 6.283

UNIT<1|2>:POWer (K20) ................................................................................................................... 6.520

UNIT:ANGLe (K7)............................................................................................................................... 6.331

UNIT:EVM (K91)................................................................................................................................. 6.753

UNIT:EVM (K92/K93) ......................................................................................................................... 6.867

UNIT:GIMBalance (K91)..................................................................................................................... 6.753

UNIT:PREamble (K91) ....................................................................................................................... 6.754

UNIT:PREamble (K92/K93)................................................................................................................ 6.867

UNIT:TABLe (K92/K93) ...................................................................................................................... 6.868

R&S FSL Index

1300.2519.12 Index 27 E-10

Index

*(enhancement label)..................................4.41

1xEV-DO BTS Analyzer mode (K84).........4.130

3G FDD BTS mode (K72)..........................4.130

abbreviations

3GPP Base Station measurements (K72)

............................................................4.273

cable TV terms (K20) .............................4.213

CDMA2000 BTS Analyzer (K82)............4.305

WiMAX measurements (K92/K93).........2.145

absolute grant channel (K72).....................4.274

Active Channels (K82) ...............................4.326

addressed command...................................5.35

adjacent–channel power

number of channels .................................4.95

Adjacent–Channel Power measurement (K8)

...............................................................4.162

adjustment

attenuation (K20)....................................4.211

AF trigger (K7) ...........................................4.142

alias power (K82)............................4.323, 4.329

alignment results........................................4.268

AM demodulation.........................................4.61

AM modulation depth...................................4.92

amplifier measurement (K30) ....................2.103

amplitude imbalance (K20)..........................2.69

amplitude menu

base unit...................................................4.14

K20 option ..............................................4.228

K7 option ................................................4.153

K72 option ..............................................4.280

K8 option ................................................4.173

K82 option ..............................................4.336

K84 option ..............................................4.389

K91 option ..............................................4.411

K92/K93 option.......................................4.446

AMPT key ....................................................4.13

analog demodulation

AF trigger (K7)........................................4.142

bandwidth (K7) .......................................4.142

circuit description (K7)............................4.141

measurement results (K7)......................4.142

measurement time (K7) .........................4.143

sample rate (K7).....................................4.143

trigger offset (K7) ...................................4.143

analog demodulation (K7) ......................... 4.140

analog demodulation menu (K7).... 4.140, 4.144

Analog Demodulation mode (K7).............. 4.129

analog TV basics (K20)............................... 2.47

Analog TV Settings dialog box (K20) ........ 4.239

analysis of measurement variables (K93). 2.157

analysis steps (K92/K93) .......................... 2.149

annotation ................................................. 4.273

antenna gain (K8)...................................... 4.168

APICH ....................................................... 4.305

ASCII #........................................................ 5.10

ASCII file export .......................................... 4.51

ATDPCH ................................................... 4.305

attenuation

adjustment (K20) ................................... 4.211

automatic................................................. 4.16

manual.......................................... 4.15, 6.150

auto level detection

K92/K93 option ...................................... 2.144

Auto Peak detector...................................... 4.42

Average detector......................................... 4.42

average or peak values (K8) ....................... 2.43

Average trace mode.................................... 4.41

averaging

continuous sweep.................................... 4.41

single sweep............................................ 4.41

sweep count ............................................ 4.41

AWGN noise (K20) ..................................... 2.70

bandwidth

K8 option ................................................. 2.41

occupied .................................................. 4.78

occupied (K20) ........................................ 2.89

resolution................................................. 4.22

resolution (K7) ....................................... 4.155

video ........................................................ 4.22

bandwidth menu

base unit .................................................. 4.22

K7 option ............................................... 4.155

K8 option ............................................... 4.175

K82 option ............................................. 4.338

K84 option ............................................. 4.391

base station measurements (K72)............ 2.108

base station measurements (K82)............ 2.116

base station tests

basic settings (K72) ............................... 2.115

test setup (K72) ..................................... 2.115

test setup (K82) ..................................... 2.127

BCH........................................................... 4.305

BD_ADDR (K8) ......................................... 4.169

Bit Reverse Code Order (K82) .................. 4.320

Bitstream (K84) ......................................... 4.382

Blank trace mode ........................................ 4.41

block data...................................................... 5.9

Bluetooth device address (K8) .................. 4.169

Bluetooth measurement

average or peak values (K8) ................... 2.43

bandwidths (K8)....................................... 2.41

Index R&S FSL

1300.2519.12 Index 28 E-10

data packet structure (K8)........................2.38

filter (K8)...................................................2.41

functional description (K8)........................2.40

oversampling (K8)....................................2.42

supported tests (K8).................................2.38

transmitter tests (K8)................................2.39

trigger concept (K8)..................................2.44

Bluetooth menu (K8).......................4.158, 4.167

Bluetooth mode (K8)..................................4.129

menus ....................................................4.158

Boolean parameter ........................................5.9

BTS (K72) ..................................................4.273

BW key ........................................................4.18

C/N Setup dialog box (K20) .......................4.235

Cable TV Analyzer menu (K20) ......4.203, 4.223

Cable TV Analyzer mode (K20) .................4.130

menus ....................................................4.203

cable TV measurement

analog TV basics (K20)............................2.47

analog TV measurement examples (K20)2.48

analog TV settings (K20)..........................2.48

analog TV test setup (K20) ......................2.49

APD – digital TV (K20) ...........................4.221

APD (K20) ................................................2.80

C/N – analog TV (K20)...........................4.214

Carriers – analog TV (K20) ....................4.214

Carriers (K20)...........................................2.51

CCDF – digital TV (K20) ........................4.222

CCDF (K20) .............................................2.81

Channel Power – digital TV (K20)..........4.221

Channel Power (K20)...............................2.79

Constellation Diagram – digital TV (K20)

............................................................4.219

Constellation Diagram (K20) ....................2.75

CSO – analog TV (K20) .........................4.215

CTB – analog TV (K20)..........................4.216

digital TV basics (K20) .............................2.65

digital TV measurement examples (K20).2.70

digital TV settings (K20) ...........................2.71

digital TV test setup (K20)........................2.72

display labels (K20) ................................4.212

Echo Pattern – digital TV (K20)..............4.220

Echo Pattern (K20)...................................2.78

Hum – analog TV (K20) .........................4.218

Hum (K20)................................................2.55

measurement overview (K20) ..................2.46

measurement with channel table (K20) ...2.98

measurement without channel table (K20)

..............................................................2.96

Modulation Errors – digital TV (K20) ......4.220

Modulation Errors (K20) ...........................2.76

Overview – digital TV (K20) ...................4.219

Overview (K20) ........................................2.73

Spectrum – analog TV (K20) .................4.213

Spectrum – digital TV (K20) ...................4.218

Spectrum (K20)...............................2.50, 2.72

status bar information (K20)...................4.209

Tilt – TV analyzer (K20)......................... 4.222

Tilt (K20) .................................................. 2.82

TVanalyzer measurement examples (K20)

............................................................. 2.82

Video Scope – analog TV (K20) ............ 4.217

Video Scope (K20) .................................. 2.52

Vision Modulation – analog TV (K20) .... 4.217

Vision Modulation (K20) .......................... 2.53

with channel table (K20) ........................ 4.208

without channel table (K20) ................... 4.209

CACH ........................................................ 4.305

calibration

transmission measurement ................... 4.138

calibration (K30) ............................. 2.102, 4.248

Carr Freq Error (K82)................................ 4.326

Carrier Frequency Drift measurement (K8)

............................................................... 4.164

carrier frequency error (K20)....................... 2.70

Carrier Frequency Stability and Modulation

Accuracy measurement (K8)................. 4.166

carrier suppression ..................................... 2.69

CATV network (K20) ................................... 2.84

CCCH........................................................ 4.305

CCIR 473–4 ................................................ 4.37

CDEP ........................................................ 4.305

CDMA2000 BTS Analyzer mode (K82)..... 4.130

CDP........................................................... 4.305

center frequency ........................................... 4.7

K8 option ............................................... 4.167

step size .................................................... 4.8

channel

active (K72) ........................................... 4.278

active (K82) ........................................... 4.315

active (K84) ........................................... 4.369

bandwidth ............................ 4.94, 4.96, 4.101

inactive (K82)......................................... 4.315

inactive (K84)......................................... 4.369

K20 option ............................................... 2.84

number .................................................... 4.95

spacing .................................................... 4.96

threshold (K82)...................................... 4.315

threshold (K84)...................................... 4.369

channel (K72)............................................ 4.274

channel assignment table (K72) ............... 4.285

parameters ............................................ 4.285

Channel Bitstream (K82)........................... 4.333

Channel Constellation (K82) ..................... 4.331

channel estimation (K93) .......................... 2.156

channel filter, list of ..................................... 4.20

channel number (K8) ................................ 4.167

Channel Power Rel / Abs (K82) ................ 4.327

Channel Results (K84) .............................. 4.379

channel results (K92/K93)......................... 2.150

channel table

result display(K82)................................. 4.323

channel table (K20) .......................... 2.83, 4.210

creating.................................................... 2.90

default...................................................... 2.96

measurement with channel table............. 2.98

R&S FSL Index

1300.2519.12 Index 29 E-10

measurement without channel table ........2.96

channel table (K82)

Add Channel ..........................................4.317

auto search ............................................4.314

Cancel ....................................................4.318

Copy.......................................................4.315

Delete.....................................................4.315

delete channel........................................4.317

Edit .........................................................4.316

Meas ......................................................4.317

name ......................................................4.315

New ........................................................4.315

predefined ..............................................4.314

Reload....................................................4.318

Restore default channel tables...............4.318

Save .......................................................4.318

Sort.........................................................4.318

channel table (K84)

Add Channel ..........................................4.370

auto search ............................................4.369

Cancel ....................................................4.371

Copy.......................................................4.371

Delete.....................................................4.371

delete channel........................................4.370

Edit .........................................................4.372

Meas ......................................................4.371

name ......................................................4.369

New ........................................................4.370

predefined ..............................................4.369

Reload....................................................4.371

Restore default channel tables...............4.373

Save .......................................................4.371

Sort.........................................................4.371

Channel Table (K84)..................................4.382

Channel Table dialog box (K20) ................4.205

Channel Table Settings (K84)....................4.368

Channel Table Settings dialog (K82) .........4.314

Channel Tables dialog box (K20) ..............4.210

channel width (K20) .....................................2.84

characters

special ........................................................6.3

Chip Rate Error (K82) ................................4.326

CINR (K92/K93).........................................2.153

CINR (K93) ................................................2.157

Clear Write trace mode................................4.40

clock offset (K92/K93) ...............................2.151

Code Domain Analyzer menu (K82) ..........4.295

Code Domain Error (K82)..........................4.328

Code Domain Error (K84)..........................4.384

Code Domain Power (K82)........................4.322

Code Domain Power (K84)........................4.377

colon ............................................................5.10

color printout ..............................................4.275

color settings

default ....................................................4.274

Color Setup dialog box ..............................4.274

comma.........................................................5.10

command

#5.10

addressed................................................ 5.35

colon ........................................................ 5.10

comma..................................................... 5.10

description ................................................. 6.2

header ....................................................... 5.5

line ............................................................. 5.7

long form ................................................... 5.6

overlapping execution.............................. 5.13

programming examples............................. 7.1

query.......................................................... 5.8

question mark................................... 5.8, 5.10

quotation mark......................................... 5.10

recognition............................................... 5.11

sequence................................................. 5.13

short form .................................................. 5.6

structure..................................................... 5.5

suffix .......................................................... 5.7

syntax elements....................................... 5.10

univeral .................................................... 5.34

white space.............................................. 5.10

command tracking..................................... 4.272

common commands ..................................... 6.6

common pilot channel (K72) ..................... 4.273

Composite Constellation (K82) ................. 4.332

Composite Constellation (K84) ................. 4.385

Composite EVM ............................. 4.305, 4.381

Composite EVM (K82) ................... 4.327, 4.329

CONDition register part............................... 5.14

continuous sweep ....................................... 4.25

control

output level ............................................ 4.137

coupling

resolution bandwidth................................ 4.22

sweep time .............................................. 4.23

video bandwidth....................................... 4.23

CPCCH ..................................................... 4.305

CPICH (K72) ............................................. 4.273

create folder .............................................. 4.286

Crest factor ............................................... 4.305

CSO Setup dialog box (K20)..................... 4.237

CTB Setup dialog box (K20) ..................... 4.238

data packet

structure (k8) ........................................... 2.38

date ........................................................... 4.273

DCL ............................................................. 5.11

dedicated physical channel (K72) ............. 4.274

default color settings ................................. 4.274

default scalings of x– and y–axis .............. 4.103

definition of transducer factors.................... 7.20

delay

gate signal ............................................... 4.36

delimiter....................................................... 5.11

delta marker ................................................ 4.53

Demod Settings (K84)............................... 4.366

Demod Settings dialog (K82) .................... 4.311

Demod Settings dialog box

K91 option ............................................. 4.412

Index R&S FSL

1300.2519.12 Index 30 E-10

K92/K93 option.......................................4.447

demodulation bandwidth (K7) ....................4.142

detector

Auto Peak.................................................4.45

auto select................................................4.45

Average....................................................4.46

IF overload (K20) ...................................4.211

Negative Peak..........................................4.46

Positive Peak ...........................................4.46

Quasi Peak...............................................4.46

RF overload (K20)..................................4.211

RMS .........................................................4.46

Sample .....................................................4.46

detector overview.........................................4.42

diagram title ...............................................4.273

dialog

Channel Table Settings (K84) ................4.368

Demod Settings (K84)............................4.366

Frontend Settings (K84) .........................4.364

IQ Capture Settings (K84)......................4.365

Result Settings (K84) .............................4.373

dialog box

Edit Power Classes (remote control) .......6.45

Differential Phase Encoding measurement (K8)

...............................................................4.166

digital TV basics (K20).................................2.65

Digital TV Settings dialog box (K20) ..........4.243

direct measurement (K30) ..............2.101, 4.263

display

date ........................................................4.273

power-save mode...................................4.276

time ........................................................4.273

display lines ....................................4.122, 4.126

display range

frequency ...................................................4.7

level..........................................................4.14

distance–to–fault measurement (K20).........2.78

double dagger..............................................5.10

DPCH (K72)...............................................4.273

echo (K20) ...................................................2.78

Edit Limit Line dialog box................4.120, 4.121

ENABle register part ....................................5.15

ENR dialog box (K30) ................................4.258

EOI (command line).......................................5.7

equalization (K93) ......................................2.156

equalizer (K20).............................................2.66

equipment under test (K8) .........................4.169

error messages..............................................9.1

3GPP Base Station measurements (K72) .9.9

device–specific...........................................9.7

noise figure measurements (K30)..............9.8

SCPI–specific.............................................9.1

WiMAX, WiBro measurements (K92/K93)

..............................................................9.11

WLAN TX measurements (K91) ..............9.10

error queue query ........................................5.26

error reporting

K30 option ............................................... 5.38

K91 option ............................................... 5.43

K92/K93 option ........................................ 5.46

error variable – iberr.................................... 5.32

ESR (event status register) ......................... 5.18

EUT (K8) ................................................... 4.169

EVENt register part ..................................... 5.15

event status enable register (ESE) ............. 5.18

event status register (ESR) ......................... 5.18

EVM (K20)................................................... 2.70

EVM (K92/K93) ......................................... 2.151

EVM (K93)................................................. 2.157

EVM vs Symbol (K82) ............................... 4.331

EVM vs Symbol (K84) ............................... 4.385

external noise source ................................ 4.267

external trigger ............................................ 4.31

FDD (K72) ................................................. 4.273

file

copying .................................................. 4.286

deleting .................................................. 4.287

renaming................................................ 4.286

FILE key .................................................... 4.280

File Manager dialog box............................ 4.286

file menu.................................................... 4.282

filter

K8 option ................................................. 2.41

root raised cosine (K20) .......................... 2.66

RX (K20).................................................. 2.66

TX (K20) .................................................. 2.66

firmware

update.................................................... 4.276

version ................................................... 4.277

fixed reference ............................................ 4.59

FM demodulation ........................................ 4.61

folder

renaming................................................ 4.286

FREQ key...................................................... 4.5

frequency

axis ............................................................ 4.5

band (K8)............................................... 4.167

center......................................................... 4.7

display.................................................... 4.273

line ......................................................... 4.126

offset........................................................ 4.10

power meter........................................... 4.188

specify frequency axis ............................... 4.5

start............................................................ 4.8

stop............................................................ 4.8

frequency menu

base unit .................................................... 4.7

K20 option ............................................. 4.226

K30 option ............................................. 4.253

K7 option ............................................... 4.150

K72 option ............................................. 4.279

K8 option ............................................... 4.172

K82 option ............................................. 4.334

K84 option ............................................. 4.387

R&S FSL Index

1300.2519.12 Index 31 E-10

K91 option ..............................................4.411

K92/K93 option.......................................4.446

frequency offset (K92/K93) ........................2.151

frequency plan (K20) ...................................2.83

Frequency Settings dialog box (K30).........4.253

frequency–converting measurement (K30)

....................................................2.104, 4.263

Frontend Settings (K84).............................4.364

Frontend Settings dialog (K82) ..................4.309

functional description (K8) ...........................2.40

gate

delay.........................................................4.36

external/internal........................................4.35

length .......................................................4.36

mode ........................................................4.35

General Results (K84) ...............................4.378

General Settings dialog box

K91 option ..............................................4.411

K92/K93 option.......................................4.446

GET (Group Execute Trigger) .....................5.11

GPIB

interface ...................................................5.33

interface functions....................................5.34

Graphic dialog box (K30) ...........................4.255

Hadamard Code Order (K82) ....................4.320

Hardware Information dialog box...............4.277

harmonics measurement...........................4.116

header............................................................5.5

high speed physical downlink shared channel

(K72) ......................................................4.274

high speed shared control channel (K72) ..4.274

horizontal sync signal...................................4.37

hybrid acknowledgement indicator channel

(K72) ......................................................4.274

I/Q data acquisition ......................................7.21

I/Q imbalance (K93)...................................2.158

IEC/IEEE bus

command description.................................6.2

image–frequency rejection (K30)...............2.104

impedance

cable TV networks (K20)........................4.229

input .........................................................4.17

Inactive Channel Threshold .......................4.305

Initial Carrier Frequency Tolerance

measurement (K8) .................................4.163

initial configuration .........................................4.4

spectrum analyzer......................................4.4

initial configuration (K82)

Code Domain Analyzer ..........................4.299

instrument functions ...........................4.1, 4.260

interface functions

GPIB.........................................................5.34

interference

inter–symbol K20..................................... 2.66

intermodulation product................................. 2.7

interrupt ....................................................... 5.25

inter–symbol interference K20 .................... 2.66

IQ Capture Settings (K84)......................... 4.365

IQ Capture Settings dialog (K82) .............. 4.310

IQ Imbal / Offset (K82) .............................. 4.327

IQ impairments (K92/K93) ........................ 2.152

IST flag........................................................ 5.18

IVI driver........................................................ 5.2

key

AMPT....................................................... 4.13

BW........................................................... 4.18

ESC ......................................................... 6.29

FILE....................................................... 4.280

FREQ......................................................... 4.5

LINES .................................................... 4.118

MEAS ...................................................... 4.75

MENU .................................................... 4.131

MKR......................................................... 4.54

MKR–>..................................................... 4.66

MODE.................................................... 4.129

MODE (remote control) ......................... 6.153

PRESET .................................. 4.3, 6.8, 6.261

PRINT.................................................... 4.290

SETUP................................................... 4.262

SPAN....................................................... 4.11

SWEEP ................................................... 4.24

TRACE .................................................... 4.39

TRIG........................................................ 4.28

LAN ............................................................. 5.28

interface................................................... 5.28

RSIB protocol .......................................... 5.30

VXI protocol ............................................. 5.28

LAP (K8).................................................... 4.169

level

axis .......................................................... 4.16

display range ........................................... 4.14

range ....................................................... 4.14

reference ................................................. 4.14

trigger ...................................................... 4.34

level detection

K92/K93 option ...................................... 2.144

limit

ACP measurement .................................. 4.98

evaluation range ...................................... 4.93

limit check

ACP measurement .................................. 4.98

Limit Check (remote control)....................... 6.45

limit line ..................................................... 4.123

copying .................................................. 4.126

deleting .................................................. 4.126

editing .................................................... 4.126

new ........................................................ 4.124

Index R&S FSL

1300.2519.12 Index 32 E-10

scaling..................................................... 4.120

shift.........................................................4.122

span setting............................................4.120

unit.......................................................... 4.120

Limit Lines dialog box (K30) ......................4.248

line

display ....................................................4.122

frequency (Frequency Line 1, 2) ............4.126

limit.........................................................4.123

system......................................................4.38

threshold ..................................................4.73

time (Time Line 1, 2) ..............................4.127

linear averaging ...........................................4.50

LINES key..................................................4.118

lines menu

base unit.................................................4.123

K30 option ..............................................4.268

K91 option ..............................................4.435

K93 option ..............................................4.484

literature

K93 option ..............................................2.158

LO exclude...................................................4.73

local menu .................................................4.289

logarithmic averaging...................................4.49

logo ............................................................4.273

Loss dialog box (K30) ................................4.259

lower–case (commands) ........................5.6, 6.2

maintenance ..................................................8.1

manual operation .......................................4.289

changing to.............................................4.289

return to......................................................5.4

marker .........................................................4.53

center frequency to ..................................4.71

peak .........................................................4.71

reference level to......................................4.71

search limit...............................................4.72

signal track ...............................................4.10

to trace .....................................................4.61

zoom ........................................................4.62

marker field

base unit...................................................4.53

K14 option ..............................................4.193

K72 option ..............................................4.274

marker menu

base unit...................................................4.57

K14 option ..............................................4.197

K30 option ..............................................4.267

K72 option ..............................................4.281

K82 option ..............................................4.341

K84 option ..............................................4.394

K91 option ..............................................4.433

K92/K93 option.......................................4.483

marker–> menu

base unit...................................................4.70

K14 option ..............................................4.197

K30 option ..............................................4.268

K72 option ..............................................4.282

K82 option ............................................. 4.343

K84 option ............................................. 4.395

K91 option ............................................. 4.434

K92/K93 option ...................................... 4.484

Max Hold trace mode.................................. 4.40

maximum search ........................................ 4.71

maximum value........................................... 4.92

MC1........................................................... 4.305

MC2........................................................... 4.305

mean power (GSM burst)............................ 4.92

MEAS key ................................................... 4.75

measurement

Adjacent–Channel Power (K72) ............ 4.292

Adjacent–Channel Power (K8) .............. 4.162

Bitstream (K84) ..................................... 4.382

Bluetooth (K8)........................................ 4.159

cable TV (K20)....................................... 4.204

Carrier Frequency Drift (K8) .................. 4.164

Carrier Frequency Stability and Modulation

Accuracy (K8) .................................... 4.166

Channel Bitstream (K82) ....................... 4.333

Channel Bitstream (remote control, K84)

........................................................... 6.635

Channel Constell (K82) ......................... 4.331

Channel Constell (remote control, K84) 6.635

Channel Results (K84) .......................... 4.379

Channel Table (K82) ............................. 4.323

Channel Table (K84) ............................. 4.382

Channel Table (remote control, K84) .... 6.635

Code Dom Power (K72) . 4.285, 4.286, 4.287,

4.288

Code Domain Analyzer (K82)..... 4.321, 4.345

Code Domain Analyzer (K84)..... 4.376, 4.397

Code Domain Error (K82)...................... 4.328

Code Domain Error (K84)...................... 4.384

Code Domain Error (remote control, K84)

........................................................... 6.635

Code Domain Power (K82).................... 4.322

Code Domain Power (K84).................... 4.377

Code Domain Power (remote control, K84)

........................................................... 6.635

Composite Constell (K82) ..................... 4.332

Composite Constell (remote control, K84)

........................................................... 6.635

Composite Constellation (K84).............. 4.385

Composite EVM..................................... 4.381

Composite EVM (K82)........................... 4.329

Composite EVM (remote control, K84).. 6.635

Differential Phase Encoding (K8) .......... 4.166

distance–to–fault (K20)............................ 2.78

EVM vs Symbol (K82) ........................... 4.331

EVM vs Symbol (K84) ........................... 4.385

EVM vs Symbol (remote control, K84) .. 6.635

functions .................................................. 4.52

General Results (K84) ........................... 4.378

Initial Carrier Frequency Tolerance (K8) 4.163

Modulation Characteristics (K8) ............ 4.162

Occupied Bandwidth (K82).................... 4.349

Occupied Bandwidth (K84).................... 4.401

R&S FSL Index

1300.2519.12 Index 33 E-10

Output Power (K8) .................................4.161

parameters.................................................4.2

Peak Code Domain Error (K82) .............4.330

Peak Code Domain Error (K84) .............4.383

Peak Code Domain Error (remote control,

K84) ....................................................6.635

Power (K72) ...........................................4.289

Power vs Chip (K84) ..............................4.380

Power vs PCG (K82)..............................4.324

Power vs PCG (remote control, K84).....6.635

Power vs Symbol (K82)..........................4.332

Power vs Symbol (K84)..........................4.381

reflection.................................................4.135

Relative Transmit Power (K8) ................4.164

Result Summary (K82)...........................4.325

Result Summary (remote control, K84)..6.635

Signal Channel Power (K82)..................4.345

Signal Channel Power (K84)..................4.398

Spectrum Emission Mask (K72).............4.292

Spectrum Emission Mask (K82).............4.347

Spectrum Emission Mask (K84).............4.399

Spurious Emissions (K8)........................4.165

Symbol Constellation (K84)....................4.384

time ........................................................4.188

transmission...........................................4.135

WiMAX 802.16 OFDM/OFDMA/WiBro

(K92/K93) ...........................................4.438

WLAN TX (K91) .....................................4.406

measurement example

amplitude distribution ...............................2.33

analog TV (K20) .......................................2.48

analog TV settings (K20)..........................2.48

APD (K20) ................................................2.80

basic (K30) .............................................2.101

basic (K92/K93)......................................2.142

Carriers (K20)...........................................2.51

CCDF (K20) .............................................2.81

Channel Power (K20)...............................2.79

Code Domain Power measurement (K72)

............................................................2.113

Composite EVM measurement (K82) ....2.124

Constellation Diagram (K20) ....................2.75

digital TV (K20) ........................................2.70

digital TV settings (K20) ...........................2.71

Echo Pattern (K20)...................................2.78

harmonics...................................................2.2

Hum (K20)................................................2.55

intermodulation...........................................2.7

modulated signals ....................................2.25

Modulation Errors (K20) ...........................2.76

noise.........................................................2.17

Overview (K20) ........................................2.73

Peak Code Domain Error measurement

(K82)...................................................2.126

relative Code Domain Power measurement

(K72)...................................................2.111

relative Code Domain Power measurement

(K82)...................................................2.119

relative Code Domain Power measurement

triggered (K82)................................... 2.122

RHO factor (K82)................................... 2.126

Signal Channel Power measurement (K72)

........................................................... 2.108

Signal Channel Power measurement (K82)

........................................................... 2.116

signals in the vicinity of noise .................. 2.13

spectra of complex signals ........................ 2.6

Spectrum (K20) .............................. 2.50, 2.72

Spectrum Emission Mask measurement

(K72) .................................................. 2.110

Spectrum Emission Mask measurement

(K82) .................................................. 2.118

test setup ................................................... 2.2

Tilt (K20) .................................................. 2.82

TV analyzer (K20).................................... 2.82

Video Scope (K20) .................................. 2.52

Vision Modulation (K20) .......................... 2.53

with channel table (K20) .......................... 2.98

without channel table (K20) ..................... 2.96

measurement forms (K30) ........................ 4.249

measurement menu

base unit .................................................. 4.88

K20 option ............................................. 4.230

K30 option ............................................. 4.260

K72 option ............................................. 4.283

K8 option ............................................... 4.181

K82 option ............................................. 4.344

K84 option ............................................. 4.397

K91 option ............................................. 4.410

K92/K93 option ...................................... 4.444

measurement mode

1xEV-DO BTS Analyzer (K84)............... 4.130

3G FDD BTS (K72) ............................... 4.130

Analog Demodulation (K7) .................... 4.129

available modes..................................... 4.129

Bluetooth (K8)........................................ 4.129

Cable TV Analyzer (K20)....................... 4.130

CDMA2000 BTS Analyzer (K82) ........... 4.130

changing................................................ 4.129

displaying main menus.......................... 4.131

K30 option ............................................. 4.248

Noise (K30)............................................ 4.130

Spectrum Analyzer ................................ 4.129

WiMAX/WiBro (K92/92)......................... 4.130

WLAN (K91) .......................................... 4.130

measurement result

Active Channels (K82)........................... 4.326

Carr Freq Error (K82) ............................ 4.326

Channel Power Rel / Abs (K82)............. 4.327

Chip Rate Error (K82)............................ 4.326

Composite EVM (K82)........................... 4.327

IQ Imbalance (K82) ............................... 4.327

Modulation (K82) ................................... 4.327

Offset (K82) ........................................... 4.327

Phase Offset (K82)................................ 4.327

Pilot PWR (K82) .................................... 4.326

RHO (K82)............................................. 4.326

Index R&S FSL

1300.2519.12 Index 34 E-10

Symbol EVM rms / Pk (K82) ..................4.327

Timing Offset (K82)................................4.327

Total PWR (K82)....................................4.326

Trg to Frame (K82) .................................4.326

measurement results (K30) .......................4.250

Measurement Settings dialog box (K30)....4.260

measurement variables

CINR (K92/K93) .....................................2.153

CINR (K93).............................................2.157

EVM (K92/K93) ......................................2.151

EVM (K93)..............................................2.157

I/Q imbalance (K93) ...............................2.158

IQ impairments (K92/K93) .....................2.152

K93 option ...................................2.157, 2.158

RSSI (K92/K93)......................................2.152

RSSI (K93) .............................................2.158

amplitude..................................................4.14

amplitude (K20)......................................4.228

amplitude (K7)........................................4.153

amplitude (K72)......................................4.280

amplitude (K8)........................................4.173

amplitude (K82)......................................4.336

amplitude (K84)......................................4.389

amplitude (K91)......................................4.411

amplitude (K92/K93) ..............................4.446

analog demodulation (K7) ...........4.140, 4.144

bandwidth.................................................4.22

bandwidth (K7) .......................................4.155

bandwidth (K8) .......................................4.175

bandwidth (K82) .....................................4.338

bandwidth (K84) .....................................4.391

Bluetooth (K8) .............................4.158, 4.167

Cable TV Analyzer (K20).............4.203, 4.223

Code Domain Analyzer (K82).................4.295

file...........................................................4.282

frequency ...................................................4.7

frequency (K20)......................................4.226

frequency (K30)......................................4.253

frequency (K7)........................................4.150

frequency (K72)......................................4.279

frequency (K8)........................................4.172

frequency (K82)......................................4.334

frequency (K84)......................................4.387

frequency (K91)......................................4.411

frequency (K92/K93) ..............................4.446

lines........................................................4.123

lines (K30) ..............................................4.268

lines (K91) ..............................................4.435

lines (K92/K93).......................................4.484

marker......................................................4.57

marker (K14) ..........................................4.197

marker (K30) ..........................................4.267

marker (K72) ..........................................4.281

marker (K82) ..........................................4.341

marker (K84) ..........................................4.394

marker (K91) ..........................................4.433

marker (K92/K93)...................................4.483

marker–>..................................................4.70

marker–> (K14) ..................................... 4.197

marker–> (K30) ..................................... 4.268

marker–> (K72) ..................................... 4.282

marker–> (K82) ..................................... 4.343

marker–> (K84) ..................................... 4.395

marker–> (K91) ..................................... 4.434

marker–> (K92/K93).............................. 4.484

measurement (K14)............................... 4.194

measurement (K20)............................... 4.230

measurement (K30)............................... 4.260

measurement (K7)................................. 4.144

measurement (K72)............................... 4.283

measurement (K8)................................. 4.181

measurement (K82)............................... 4.344

measurement (K84)............................... 4.397

menu...................................................... 4.131

noise figure measurements (K30) ........ 4.247,

4.252

power measurement................................ 4.88

power meter (K9)........................ 4.186, 4.187

print........................................................ 4.290

settings (K72) ............................. 4.271, 4.275

setup...................................................... 4.262

span......................................................... 4.11

span (K7) ............................................... 4.152

span (K82) ............................................. 4.335

span (K84) ............................................. 4.388

spectrogram (K14)...................... 4.191, 4.194

sweep ...................................................... 4.25

sweep (K14) .......................................... 4.195

sweep (K30) .......................................... 4.265

sweep (K7) ............................................ 4.155

sweep (K8) ............................................ 4.177

sweep (K82) .......................................... 4.339

sweep (K84) .......................................... 4.392

sweep (K91) .......................................... 4.432

sweep (K92/92) ..................................... 4.482

trace......................................................... 4.43

trace (K20)............................................. 4.229

trace (K30)............................................. 4.266

trace (K82)............................................. 4.340

trace (K84)............................................. 4.393

trace (K91)............................................. 4.435

trace (K92/K93) ..................................... 4.485

tracking generator ................................. 4.137

trigger ...................................................... 4.33

trigger (K7)............................................. 4.156

trigger (K72)........................................... 4.281

trigger (K8)............................................. 4.180

trigger (K82)........................................... 4.340

trigger (K84)........................................... 4.393

trigger (K91)........................................... 4.411

trigger (K92/K93) ................................... 4.446

WiMAX (K92/K93) ...................... 4.438, 4.444

WLAN (K91) ............................... 4.405, 4.410

MENU key ................................................. 4.131

menu menu ............................................... 4.131

MER (K20) .................................................. 2.70

Min Hold trace mode ................................... 4.40

R&S FSL Index

1300.2519.12 Index 35 E-10

minimum search ..........................................4.72

MKR key ......................................................4.54

MKR–> key ..................................................4.66

mode

see also measurement mode.................4.129

trigger .......................................................4.33

MODE key .................................................4.129

model.........................................................4.133

13, 16 and 28 – tracking generator ........4.134

Modulation (K82) .......................................4.327

Modulation Characteristics measurement (K8)

...............................................................4.162

modulation depth .........................................4.92

modulation standard (K20) ......2.84, 2.85, 4.210

<unused > ...............................................2.85

Modulation Standard Options dialog box (K20)

...............................................................4.207

modulation standards (K20)

analog TV.................................................2.86

assigning ..................................................2.95

creating ....................................................2.92

digital TV ..................................................2.88

Negative Peak detector ...............................4.42

noise

measurement (K30) ...............................4.247

source, external......................................4.267

noise figure measurements menu (K30) ..4.247,

4.252

Noise mode (K30)......................................4.130

normalization .............................................4.138

NTRansition register part.............................5.15

numerical values (command) ........................5.8

occupied bandwidth .....................................4.78

K20 option ................................................2.89

offset

frequency .................................................4.10

gate signal................................................4.36

reference level..........................................4.16

trigger .......................................................4.34

option .........................................................4.133

1xEV-DO Base Station Test (K84).........4.354

3GPP Base Station Measurements (K72)

............................................................4.271

Additional Interfaces (B5).......................4.186

Analog Demodulation (K7) .....................4.140

Bluetooth Measurements (K8) ...............4.158

Gated Sweep (B8)....................................4.29

Noise Figure Measurements (K30) ........4.247

Power Meter (K9) ...................................4.186

RF Preamplifier (B22) ..............................4.15

Spectrogram Measurement (K14)..........4.191

TV Trigger (B6) ........................................4.32

WiMAX IEEE 802.16e, WiBro Measurements

(K92/K93) ...........................................4.437

WLAN TX Measurements (K91) ............4.405

options

installed ................................................. 4.277

OTD........................................................... 4.305

output level

control.................................................... 4.137

Output Power measurement (K8) ............. 4.161

overlapping execution ................................. 5.11

oversampling (K8)....................................... 2.42

oversampling factor (K8)........................... 4.171

overview

Bluetooth measurements (K8)................. 2.36

overwrite mode............................................ 4.40

p0 bit (K8)......................................... 2.44, 4.160

packing.......................................................... 8.1

paging indication channel (K72)................ 4.274

parallel poll .................................................. 5.25

enable register (PPE) .............................. 5.18

parameter

block data .................................................. 5.9

boolean...................................................... 5.9

numerical values........................................ 5.8

string.......................................................... 5.9

technical (K8)........................................... 2.37

text............................................................. 5.9

path ........................................................... 4.283

PCCPCH (K72) ......................................... 4.273

PCG .......................................................... 4.305

PCH........................................................... 4.305

PDCCH ..................................................... 4.305

PDCH ........................................................ 4.305

Peak Code Domain Error (K82) ................ 4.330

Peak Code Domain Error (K84) ................ 4.383

peak envelope power (K20) ........................ 2.69

peak search ................................................ 4.71

phase jitter (K20)......................................... 2.70

physical layer (K20)..................................... 2.84

PICH.......................................................... 4.305

PICH (K72)................................................ 4.273

Pilot PWR (K82)........................................ 4.326

polarity

external trigger/gate................................. 4.34

trigger edge ............................................. 4.34

video ........................................................ 4.38

Positive Peak detector ................................ 4.42

power

3GPP FDD signal (K72) ........................ 4.289

bandwidth percentage ........................... 4.101

mean........................................................ 4.92

power cables ................................................. 8.1

power classes

bluetooth (K8) .......................................... 2.37

power measurement ................................... 4.75

occupied bandwidth................................. 4.78

trace......................................................... 4.99

zero span................................................. 4.78

power measurement menu

base unit .................................................. 4.88

Index R&S FSL

1300.2519.12 Index 36 E-10

power meter (K9).......................................4.186

frequency ...............................................4.188

menu ...........................................4.186, 4.187

power sensor support (K9) ........................4.186

Power vs Chip (K84)..................................4.380

Power vs PCG (K82) .................................4.324

Power vs Symbol (K82) .............................4.332

Power vs Symbol (K84) .............................4.381

PPE (parallel poll enable register) ...............5.18

preset instrument...........................................4.3

PRESET key..................................................4.3

preset spectrum analyzer ..............................4.3

pre–trigger ...................................................4.34

primary common control physical channel (K72)

...............................................................4.273

primary synchronization channel (K72)......4.273

screen ....................................................4.290

PRINT key .................................................4.290

print menu..................................................4.290

Printers and Faxes window........................4.292

programming examples

averaging I/Q data....................................7.23

channel power measurement...................7.11

I/Q data ....................................................7.21

level measurement...................................7.19

limit lines and limit test ...............................7.9

occupied bandwidth measurement ..........7.13

power ramp measurement.......................7.15

reading files..............................................7.24

service request...........................................7.1

Spectrum Emission Mask measurement .7.26

Spurious Emissions measurement ..........7.30

time domain power measurement............7.14

transducers ..............................................7.20

WiMAX, WiBro measurements (K92/K93)

..............................................................7.37

WLAN TX measurements (K91) ..............7.34

writing files ...............................................7.25

protocol

RSIB.........................................................5.30

VXI ...........................................................5.28

PTRansition register part.............................5.15

QAM (K20)...................................................2.88

quadrature error (K20) .................................2.69

query............................................5.8, 5.26, 5.36

question mark .......................................5.8, 5.10

quotation mark .............................................5.10

RC..............................................................4.305

Recall dialog box .......................................4.285

reference

external ..................................................4.264

fixed..........................................................4.59

internal ...................................................4.264

level to marker level .................................4.71

value ...................................................... 4.189

reference level............................................. 4.14

channel power ....................................... 4.101

offset........................................................ 4.16

to marker level......................................... 4.71

reference noise bandwidth (K20) ................ 2.56

reference point

frequency................................................. 4.60

level ......................................................... 4.60

peak search............................................. 4.60

time.......................................................... 4.60

reflection measurement ............................ 4.135

relative grant channel (K72) ...................... 4.274

Relative Transmit Power measurement (K8)

............................................................... 4.164

remote control

basics ........................................................ 5.1

changing to ............................................ 4.289

IP address ................................................. 5.3

programming examples............................. 7.1

starting....................................................... 5.4

reset

status reporting system ........................... 5.27

switch on or off ........................................ 4.47

resolution bandwidth ................................... 4.22

K7 option ............................................... 4.155

result display

Code Dom Channel Table (K72) ........... 4.285

Code Dom Power Diagram (K72).......... 4.286

Code Dom Result Summary (K72)....... 4.287,

4.288

Result Settings dialog (K82)...................... 4.318

Result Summary (K82).............................. 4.325

RHO (K82) ................................................ 4.326

RMS detector .............................................. 4.42

RMS value................................................... 4.92

roll–off factor (K20) ..................................... 2.66

root raised cosine........................................ 2.89

filter (K20) ................................................ 2.66

RSIB protocol .............................................. 5.30

RSSI (K92/K93)......................................... 2.152

RSSI (K93) ................................................ 2.158

RX filter (K20).............................................. 2.66

Sample detector .......................................... 4.42

sample number ......................................... 4.102

Save dialog box......................................... 4.283

scalar reflection measurement.................. 4.135

scaling ......................................................... 4.15

level axis.................................................. 4.16

x– and y–axis (signal statistic)............... 4.102

SCH (K72)................................................. 4.273

SCPI

conformity information..................................6.2

introduction ................................................ 5.5

version ....................................................... 5.1

bandwidth ................................................ 4.10

R&S FSL Index

1300.2519.12 Index 37 E-10

minimum ..................................................4.72

peak .........................................................4.71

range ........................................................4.72

secondary common control physical channel

(K72) ......................................................4.273

secondary synchronization channel (K72) .4.273

Select Limit Line dialog box .......................4.121

Select Screen Color Set dialog box ...........4.274

self test ......................................................4.279

sensitivity

APD measurement.................................4.104

CCDF measurement ..............................4.104

serial poll......................................................5.25

service request (SRQ) ........................5.17, 5.25

service request enable register (SRE).........5.17

setting command .........................................5.36

Settings (K82) ............................................4.307

Settings (K84) ............................................4.363

settings menu (K72)........................4.271, 4.275

Settings Overview dialog (K82)..................4.308

Settings Overview dialog (K84)..................4.363

setup

general ...................................................4.268

SETUP key ................................................4.262

setup menu................................................4.262

SF ..............................................................4.305

sideband suppression (K30) ......................2.104

signal count..................................................4.60

signal level (K20) .......................................4.211

signal processing

block diagram (K93)...............................2.155

IEEE 802.11a (K91) ...............................2.129

IEEE 802.11b (K91) ...............................2.135

IEEE 802.16 OFDMA (K93) ...................2.155

IEEE 802.16–2004 OFDM (K92/K93) ....2.145

signal tracking..............................................4.10

search bandwidth .....................................4.10

softkey

#of Adj Chan ...........................................4.95

#of Adj Chan (remote control)...............6.220

#of Samples ..........................................4.102

#of Samples (K82) ................................4.350

#of Samples (K84) ................................4.402

#of Samples (remote control)................6.113

#of TX Chan............................................4.95

#of TX Chan (remote control) ...............6.226

%Power Bandwidth ...............................4.101

%Power Bandwidth (K82) .....................4.349

%Power Bandwidth (remote control).....6.226

(remote control, K14) .......6.391, 6.392, 6.393

*IDN Format Legacy...............................4.272

=Center .....................................................4.9

=Chan Spacing (K8)..............................4.172

=Marker.....................................................4.9

=Marker (remote control) ........................6.71

0.1 * RBW ..................................................4.8

0.1 * RBW (remote control).........6.201, 6.202

0.1 * Span ..................................................4.8

0.1 * Span (remote control).........6.201, 6.202

0.1*Chan Spacing (K8).......................... 4.172

0.1*Demod BW (K7).............................. 4.151

0.5 * RBW.................................................. 4.9

0.5 * RBW (remote control) ........ 6.201, 6.202

0.5 * Span.................................................. 4.9

0.5 * Span (remote control) ........ 6.201, 6.202

0.5*Demod BW (K7).............................. 4.151

30kHz/1MHz Transition (K72) ............... 4.294

30kHz/1MHz Transition (remote control, K72)

........................................................... 6.571

ACP (K72) ............................................. 4.292

ACP (remote control, K72) .................... 6.576

ACP Abs/Rel.......................................... 4.100

ACP Abs/Rel (remote control) ............... 6.222

ACP Ref Setting (remote control).......... 6.224

ACP Ref Settings..................................... 4.98

ACP Ref Spacing (remote control) ........ 6.224

ACP Rel/Abs (K91)................................ 4.429

ACP Rel/Abs (remote control, K91)...... 6.696,

6.703

ACP Settings (K92/K93) ........................ 4.477

ACP Settings (remote control, K92/K93)

..................................... 6.840, 6.841, 6.842

ACPR Abs/Rel (K92/K93)...................... 4.476

ACPR Abs/Rel (remote control, K92/K93)

..................................... 6.781, 6.782, 6.792

Activate (K20) ........................................ 4.223

Activate (remote control, K20)............... 6.473

Active On/Off ......................................... 4.265

Active On/Off (remote control).... 6.181, 6.184

Add Channel (K82) ................................ 4.317

Add Channel (K84) ................................ 4.370

Adjacent Channel Power (K82) ............. 4.345

Adjacent Channel Power (K84) ............. 4.398

Adjacent Channel Power (remote control,

K82) ................................................... 6.609

Adjacent Channel Power (remote control,

K84) ................................................... 6.649

Adjust Attenuation (K20)........................ 4.226

Adjust Gate (K8) .................................... 4.178

Adjust Gate (remote control, K8)........... 6.360

Adjust Ref Level .................................... 4.101

Adjust Ref Level (K72)................ 4.278, 4.294

Adjust Ref Level (K82).... 4.334, 4.336, 4.347,

4.349

Adjust Ref Level (K84)..... 4.387, 4.389, 4.399

Adjust Ref Level (remote control).......... 6.223

Adjust Ref Level (remote control, K72) 6.584,

6.587

Adjust Ref Level (remote control, K82) . 6.617

Adjust Ref Lvl ........................................ 4.102

Adjust Settings.......... 4.94, 4.99, 4.104, 4.117

Adjust Settings (K82).................. 4.349, 4.350

Adjust Settings (K84).................. 4.402, 4.403

Adjust Settings (remote control) . 6.114, 6.222

Adjust X-Axis ......................................... 4.115

AF Center (K7) ...................................... 4.151

AF Center (remote control, K7) ............. 6.301

AF Coupling AC/DC (K7)....................... 4.147

Index R&S FSL

1300.2519.12 Index 38 E-10

AF Coupling AC/DC (remote control, K7)

............................................................6.302

AFFilter (K7)..........................................4.148

AF Full Span (K7)...................................4.152

AF Full Span (remote control, K7)..........6.303

AF Range (K7) .......................................4.146

AF Span Manual (K7).............................4.152

AF Span Manual (remote control, K7)....6.302

AF Spectrum (K7) ..................................4.145

AF Start (K7) ..........................................4.151

AF Start (remote control, K7) .................6.303

AF Stop (K7) ..........................................4.151

AF Stop (remote control, K7) .................6.304

AF Time Domain (K7) ............................4.145

Alignment ...............................................4.268

All Functions off........................................4.91

All Functions off (remote control) .............6.97

All Marker Off ...........................................4.62

All Marker Off (K30) ...............................4.268

All Marker Off (remote control, K30) ......6.529

AM............................................................4.61

AM (remote control) .................................6.70

AM Mod Depth .........................................4.92

AM Mod Depth (remote control)...............6.74

Analog TV (K20).....................................4.232

Analog TV (remote control, K20) ...........6.471

Analog TV Settings (K20).......................4.239

Analog TV Settings (remote control, K20)

...........................6.506, 6.517, 6.518, 6.519

Annotation On/Off ..................................4.273

Annotation On/Off (remote control)........6.127

Antenna Diversity (K82) .........................4.312

Antenna Diversity On/Off (K72)..............4.278

Antenna Diversity On/Off (remote control,

K72) ....................................................6.583

Antenna Gain (K8) .................................4.168

Antenna Gain (remote control, K8) ........6.371

Antenna Number 1/2 (K72) ....................4.278

Antenna Number 1/2 (remote control, K72)

............................................................6.583

APD........................................................4.102

APD (K20) ..............................................4.244

APD (remote control) ..................6.112, 6.114

ASCII File Export..................4.47, 4.64, 4.113

ASCII File Export (remote control) ........6.166,

6.167

Auto Level (K91) ....................................4.433

Auto Level (K92/K93) .............................4.482

Auto Level (remote control, K92/K93) ....6.796

Auto Level&Code (K72) .........................4.284

Auto Level&Code (remote control, K72) 6.584

Auto Lvl (remote control, K91) ...............6.706

Auto Max Peak.........................................4.74

Auto Max Peak (remote control) ..............6.59

Auto Min Peak..........................................4.74

Auto Min Peak (remote control) ...............6.61

Auto Range (K20) .......................4.241, 4.246

Auto Range (remote control, K20) .........6.475

Auto Scale Once (K82) ...............4.337, 4.341

Auto Scale Once (K84).......................... 4.390

Average ................................................... 4.45

Average Length (K91) ........................... 4.422

Average Length (remote control, K91) .. 6.701

Average Mode ......................................... 4.48

Average Mode (remote control)............. 6.108

Band Class (K82) ....................... 4.346, 4.348

Band Class (K84) ....................... 4.398, 4.400

Band Class (remote control, K82) ......... 6.608

Band Class (remote control, K84) ......... 6.648

Base SF (K82) ....................................... 4.311

Bit Selection (K93)................................. 4.481

Bit Selection (remote control, K93)....... 6.785,

6.786

Bitstream (K91) ..................................... 4.430

Bitstream (K92/K93) .............................. 4.479

Bitstream (remote control, K91) ............ 6.704

Bitstream (remote control, K92/K93) ..... 6.794

Blank........................................................ 4.45

Block Count (K8) ................................... 4.178

Block Count (remote control, K8) .......... 6.358

Build Tbl (K30)....................................... 4.264

Burst Fit On/Off (K84)............................ 4.404

Burst Offset (K8).................................... 4.170

Burst Offset (remote control, K8) .......... 6.374

Burst Selection (K92/K93) ..................... 4.462

Burst Selection (remote control, K92/K93)

........................................................... 6.791

Burst Summary (K92/K93) .................... 4.480

Burst Summary (remote control, K92/K93)

........................................................... 6.795

C/N .......................................................... 4.93

C/N (K20)............................................... 4.234

C/N (remote control).............. 6.87, 6.88, 6.91

C/N (remote control, K20) ..................... 6.435

C/N Setup (K20) .................................... 4.235

C/N Setup (remote control, K20)6.485, 6.486,

6.487, 6.488

C/N, C/No ................................................ 4.93

C/No ........................................................ 4.94

C/No (remote control)............ 6.87, 6.88, 6.91

Cal (K30) ............................................... 4.265

Cal (remote control, K30) ...................... 6.532

Cal Refl Open ........................................ 4.138

Cal Refl Open (remote control) .. 6.180, 6.181

Cal Refl Short ........................................ 4.138

Cal Refl Short (remote control).............. 6.181

Cal Trans ............................................... 4.138

Cal Trans (remote control) .................... 6.181

Cal Type Sine/Comb ............................. 4.279

Cal Type Sine/Comb (remote control)... 6.123

Cancel (K82).......................................... 4.318

Cancel (K84).......................................... 4.371

Capture Length (K82) ............................ 4.310

Capture Length (K84) ............................ 4.365

Carr Freq Drift (K8)................................ 4.184

Carr Freq Drift (remote control, K8)....... 6.336

Carr Freq Stability (K8).......................... 4.184

R&S FSL Index

1300.2519.12 Index 39 E-10

Carr Freq Stability (remote control, K8) 6.337,

6.338, 6.339, 6.340

Carrier Selection (K91)...........................4.427

Carrier Selection (K92/K93) ...................4.470

Carrier Selection (remote control, K91) .6.698

Carrier Selection (remote control, K92/K93)

............................................................6.787

Carriers (K20).........................................4.233

Carriers (remote control, K20) ...............6.434

CCDF .....................................................4.104

CCDF (K20) ...........................................4.245

CCDF (K82) ...........................................4.349

CCDF (K84) ...........................................4.402

CCDF (K91) ...........................................4.430

CCDF (K92/K93) ....................................4.478

CCDF (remote control)................6.112, 6.114

CCDF (remote control, K82) ..................6.609

CCDF (remote control, K84) ..................6.649

CCDF (remote control, K91) ..................6.705

CCDF (remote control, K92/K93)...........6.795

CDP Average (K84) ...............................4.375

Center ........................................................4.7

Center (K8).............................................4.172

Center (remote control)..........................6.200

Center =Mkr Freq.....................................4.71

Center =Mkr Freq (remote control) ..........6.70

CF Stepsize................................................4.8

CF Stepsize (remote control) .................6.201

CF–Stepsize (K8)...................................4.172

Chan Pwr/Hz ............................................4.97

Chan Pwr/Hz (remote control)..................6.91

Chan Type (K84)....................................4.385

Channel (Code) Number (K82) ..............4.319

Channel (K20) ........................................4.227

Channel (K8) ..........................................4.167

Channel (remote control, K20)...............6.502

Channel (remote control, K8).................6.359

Channel Analysis (K20)..........................4.242

Channel Bandwidth ..............4.94, 4.96, 4.101

Channel Bandwidth (K82) ......................4.349

Channel Bandwidth (remote control).....6.221,

6.222

Channel Bitstream (K82)........................4.333

Channel Bitstream (remote control, K82)

.................................................6.597, 6.624

Channel Constell (K82) ..........................4.331

Channel Constell (remote control, K82) 6.597,

6.624

Channel List Start (K8)...........................4.179

Channel No (K20) ..................................4.233

Channel Power (K20).............................4.244

Channel Settings......................................4.95

Channel Setup (K20)..............................4.223

Channel Spacing......................................4.96

Channel Spacing (remote control) ........6.225,

6.226

Channel Table (K82) ..............................4.323

Channel Table (remote control, K82)....6.597,

6.604, 6.605, 6.607, 6.608, 6.616, 6.624

Channel Table (remote control, K84) ... 6.644,

6.645, 6.647, 6.648, 6.657

Channel Table settings (K82) ................ 4.314

Channel Table Settings (K84) ............... 4.368

Channel Type (K84) .............................. 4.374

Channel Width (K20) ............................. 4.227

Clear All Messages................................ 4.278

Clear All Messages (remote control) ..... 6.257

Clear Write .............................................. 4.44

Clear/Write .............................................. 4.99

Close Sweep List................................... 4.110

Code Dom Channel Table (K72) ........... 4.285

Code Dom Channel Table (remote control,

K72) ........................................ 6.569, 6.576

Code Dom Overview (K84).................... 4.375

Code Dom Power Diagram (K72).......... 4.286

Code Dom Power Diagram (remote control,

K72) ........................................ 6.569, 6.576

Code Dom Result Summary (K72)........ 4.287

Code Dom Result Summary (remote control,

K72) ............................. 6.569, 6.574, 6.576

Code Domain Analyzer (K82)................ 4.345

Code Domain Analyzer (K84)................ 4.397

Code Domain Analyzer (remote control, K82)

........................................................... 6.609

Code Domain Analyzer (remote control, K84)

........................................................... 6.649

Code Domain Error (K82)...................... 4.328

Code Domain Error (remote control, K82)

........................................................... 6.597

Code Domain Power (K82).................... 4.322

Code Domain Power (remote control, K82)

................................................ 6.597, 6.624

Code Order (K82) .................................. 4.320

Code Power (K82) ................................. 4.320

Code Power Abs Rel (K84) ................... 4.375

Code Power Abs/Rel (K72) ................... 4.276

Code Power Abs/Rel (remote control, K72)

........................................................... 6.569

Color (K14) ............................................ 4.194

Color (remote control, K14) ................... 6.403

Color On/Off .................... 4.274, 4.275, 4.291

Color On/Off (remote control)................ 6.143

Colors ......................................... 4.273, 4.291

Comment............................................... 4.292

Composite Constell (K82) ..................... 4.332

Composite Constell (remote control, K82)

........................................................... 6.597

Composite EVM (K82)........................... 4.329

Composite EVM (remote control, K82). 6.597,

6.624

Computer Name .................................... 4.269

Const Diagram (K20)............................. 4.242

Constell Selection (K93) ........................ 4.470

Constell Selection (remote control, K93)

................................................ 6.786, 6.788

Constell vs Symbol/Carrier (K91) .......... 4.426

Constell vs Symbol/Carrier (K92/K93)... 4.469

Index R&S FSL

1300.2519.12 Index 40 E-10

Constell vs Symbol/Carrier (remote control,

K91) ....................................................6.699

Constell vs Symbol/Carrier (remote control,

K92/K93)..................................6.787, 6.788

Cont Demod .............................................4.61

Cont Demod (remote control) ..................6.69

Cont Meas (remote control) ........6.146, 6.147

Continue Frame On/Off (K14)................4.196

Continue Frame On/Off (remote control, K14)

............................................................6.403

Continue Single Sweep............................4.26

Continue Single Sweep (remote control)

.................................................6.146, 6.147

Continue Test (K8) .................................4.178

Continuous Sweep ...................................4.25

Continuous Sweep (K8) .........................4.178

Continuous Sweep (remote control)......6.146,

6.147

Continuous Sweep Start/Stop (remote

control, K14) .......................................6.407

Copy.......................................................4.286

Copy (K20) .............................................4.225

Copy (K82) .............................................4.315

Copy (K84) .............................................4.371

Copy (remote control) ............................6.157

Copy (remote control, K82) ....................6.606

Copy (remote control, K84) ....................6.645

Copy Channel (K20)...............................4.224

Copy to ........................................4.126, 4.266

Copy to (remote control) ..........................6.30

Copy Trace...............................................4.47

Copy Trace (remote control) ..................6.264

Copy Trace (remote control, K20)..........6.516

Copy Zone/Burst (K93) ..........................4.460

Corr Data On/Off....................................4.268

Corr Data On/Off (remote control) .........6.121

CP / ACP Config ......................................4.95

CP / ACP Standard ..................................4.94

CP / ACP Standard (remote control)........6.88

CP, ACP, MC–ACP..................................4.94

CP, ACP, MC–ACP (remote control) ......6.87,

6.88, 6.91

CPICH (K72) ..........................................4.283

CPICH (remote control, K72) ......6.567, 6.573

CSO (K20)..............................................4.237

CSO (remote control, K20) ....................6.435

CSO Setup (K20) ...................................4.237

CSO Setup (remote control, K20) .........6.489,

6.490, 6.492

CTB (K20) ..............................................4.238

CTB (remote control, K20) .....................6.436

CTB Setup (K20)....................................4.238

CTB Setup (remote control, K20)6.493, 6.495

Current File List 1/2................................4.287

Cut..........................................................4.286

Data –> Mem1 (K30)..............................4.267

Data –> Mem1 (remote control, K30).....6.532

Data –> Mem2 (K30)..............................4.267

Data –> Mem2 (remote control, K30).....6.532

Data –> Mem3 (K30) ............................. 4.267

Data –> Mem3 (remote control, K30).... 6.532

Data On/Off (K30) ................................. 4.267

Data On/Off (remote control, K30) ....... 6.535,

6.536

Date ....................................................... 4.287

dB per Division (K7)............................... 4.146

dB per Division (K72)............................. 4.280

dB per Division (remote control, K7) ..... 6.295

dB per Division (remote control, K72) ... 6.577

Decim Sep ............................................... 4.48

Decim Sep (remote control) .................. 6.138

Deemphasis (K7)................................... 4.149

Deemphasis (remote control, K7).......... 6.324

Default All (K91) .................................... 4.435

Default All (K92/K93) ............................. 4.484

Default Colors 1 (remote control) .......... 6.128

Default Colors 2 (remote control) .......... 6.128

Default Current (K91) ............................ 4.435

Default Current (K92/K93) ..................... 4.484

Default Settings ..................................... 4.103

Default Settings (remote control) 6.113, 6.115

Delete .............................. 4.126, 4.267, 4.287

Delete (K20) ............................... 4.224, 4.225

Delete (K30) ............................... 4.264, 4.270

Delete (K82) .......................................... 4.315

Delete (K84) .......................................... 4.371

Delete (remote control)..... 6.30, 6.158, 6.163,

6.183

Delete (remote control, K82) ................. 6.607

Delete (remote control, K84) ................. 6.647

Delete Channel (K20) ............................ 4.224

Delete Channel (K82) ............................ 4.317

Delete Channel (K84) ............................ 4.370

Delete File ............................................. 4.285

Delete File (remote control)................... 6.156

Delete Line ............................................ 4.265

Delete Line (K20)................................... 4.236

Delete Range......................................... 4.110

Delete Range (remote control) .............. 6.192

Delete Value .......................................... 4.125

Delete Zone/Burst (K93)........................ 4.460

Demod Bandwidth (K7) ......................... 4.152

Demod BW (K7) .................................... 4.146

Demod BW (remote control, K7)........... 6.323

Demod Settings (K7) ............................. 4.147

Demod Settings (K82) ........................... 4.311

Demod Settings (K84) ........................... 4.366

Demod Settings (remote control, K82) . 6.615,

6.619, 6.620, 6.621

Demod Settings (remote control, K84) .. 6.661

Demod Settings (remote control, K91) . 6.729,

6.730, 6.731, 6.732, 6.733, 6.734, 6.735,

6.736, 6.739, 6.740

Description............................................. 4.271

Deselect All............................................ 4.124

Details On/Off ........................................ 4.116

Detector Auto Peak ................................. 4.45

Detector Auto Select................................ 4.45

R&S FSL Index

1300.2519.12 Index 41 E-10

Detector Auto Select (remote control)....6.186

Detector Average .....................................4.46

Detector Manual Select............................4.45

Detector Manual Select (remote control)6.186

Detector Manual Select (remote control, K8)

............................................................6.359

Detector Negative Peak ...........................4.46

Detector Positive Peak.............................4.46

Detector Quasi Peak ................................4.46

Detector RMS...........................................4.46

Detector Sample ......................................4.46

Dev per Division (K7) .............................4.146

Deviation Lin/Log (K7)............................4.147

Deviation Lin/Log (remote control, K7)...6.296

Device 1/2 ..............................................4.291

Device 1/2 (remote control)....................6.161

Device Setup..........................................4.291

Device Setup (remote control) ...6.142, 6.143,

6.145, 6.254, 6.255

DHCP On/Off .........................................4.269

Diagram Full Size (K7) ...........................4.145

Diagram Full Size (remote control, K7)..6.295

Diff Phase (K8).......................................4.185

Diff Phase (remote control, K8)...6.341, 6.342

Digital TV (K20)......................................4.241

Digital TV (remote control, K20)..6.472, 6.473

Digital TV Settings (K20)........................4.243

Digital TV Settings (remote control, K20)

......................................6.499, 6.500, 6.501

Disable all Items.....................................4.285

Disable all Items (remote control) ..........6.165

Discard Changes (K20)..........................4.225

Disconnect Network Drive......................4.288

Disconnect Network Drive (remote control)

............................................................6.162

Display Graph/Display List (K92/K93)....4.461

Display Graph/Display List (remote control,

K92/K93).............................................6.812

Display Line 1.........................................4.126

Display Line 1 (remote control) ................6.23

Display Line 2.........................................4.126

Display Line 2 (remote control) ................6.23

Display Lines ..........................................4.126

Display List/Graph (K30) ........................4.255

Display List/Graph (K91) ........................4.420

Display List/Graph (remote control, K30)

............................................................6.536

Display List/Graph (remote control, K91)

............................................................6.710

Display Pwr Save ...................................4.276

Display Pwr Save (remote control).........6.130

Display Settings (K30)............................4.255

Display Settings (remote control, K30)..6.535,

6.537, 6.538, 6.539

Display Update On/Off ...........................4.272

DPSK Start (K8) .....................................4.180

DPSK Start (remote control, K8)............6.364

DPSK Stop (K8) .....................................4.180

DPSK Stop (remote control, K8) ............6.364

Echo Pattern (K20) ................................ 4.242

Edit ............................................. 4.126, 4.265

Edit (K20)............................................... 4.225

Edit (K30)............................................... 4.270

Edit (K82)............................................... 4.316

Edit (K84)............................................... 4.372

Edit (remote control).... 6.29, 6.32, 6.41, 6.42,

6.43, 6.49, 6.50, 6.51, 6.52, 6.53, 6.182

Edit ACP Limit ......................................... 4.98

Edit ACP Limit (remote control)..... 6.33, 6.34,

6.35, 6.37, 6.38, 6.39

Edit Comment............................. 4.124, 4.284

Edit File Name ....................................... 4.284

Edit Margin ............................................ 4.125

Edit Name................................... 4.124, 4.266

Edit Name (remote control) ................... 6.184

Edit Path ................................................ 4.286

Edit Path (remote control) .......... 6.156, 6.161

Edit Power Classes ............................... 4.113

Edit Reference Range ........................... 4.111

Edit Reference Range (remote control) 6.188,

6.189, 6.199

Edit Table (K20)..................................... 4.233

Edit Table (remote control, K20) 6.413, 6.414,

6.415, 6.416, 6.417, 6.418, 6.419, 6.420,

6.421, 6.422, 6.442, 6.443, 6.444, 6.445,

6.446, 6.447, 6.448, 6.449

Edit Unit ................................................. 4.266

Edit Unit (remote control) ...................... 6.184

Edit Values ............................................ 4.266

Edit Values (remote control).................. 6.182

EDR (K8) ............................................... 4.184

Enable all Items ..................................... 4.284

Enable all Items (remote control) .......... 6.163

Enable/Disable (K30)............................. 4.270

ENR Settings (K30) ............................... 4.258

ENR Settings (remote control, K30) ..... 6.549,

6.553

Error Frequency/Phase (K91)................ 4.425

Error Frequency/Phase (K92/K93) ........ 4.468

Error Frequency/Phase (remote control, K91)

................................................ 6.700, 6.701

Error Frequency/Phase (remote control,

K92/K93) ............................................ 6.790

EVM Constell (K91) ............................... 4.424

EVM Constell (K92/K93)........................ 4.466

EVM vs Symbol (K82) ........................... 4.331

EVM vs Symbol (remote control, K82) . 6.597,

6.624

EVM vs Symbol/Carrier (K91) ............... 4.424

EVM vs Symbol/Carrier (K92/K93) ........ 4.466

EVM vs Symbol/Carrier (remote control, K91)

........................................................... 6.700

EVM vs Symbol/Carrier (remote control,

K92/K93) ............................................ 6.789

Exclude LO .............................................. 4.73

Exclude LO (remote control) ................... 6.58

Exit (K30).................................... 4.264, 4.270

Export .................................................... 4.288

Index R&S FSL

1300.2519.12 Index 42 E-10

Export (K91) ...........................................4.423

Export (K92/K93)....................................4.466

Export (remote control, K91)..................6.725

Export (remote control, K92/K93) ..........6.833

Ext Att (remote control, K91)..................6.723

Ext Att (remote control, K92/K93) ..........6.815

Ext Power Trigger (K9)...........................4.189

Ext Power Trigger (remote control, K9) 6.386,

6.387

Extension ...............................................4.287

Fast ACP On/Off ....................................4.100

Fast ACP On/Off (remote control)..........6.227

Field 1/2 (K20)........................................4.240

Field 1/2 (remote control, K20)...............6.518

File Lists 1/2 ...........................................4.287

File Manager ..........................................4.286

File Manager (K93) ................................4.481

Filter Type ................................................4.23

Filter Type (K8) ......................................4.176

Filter Type (remote control)....................6.176

Find Burst On/Off (K8) ...........................4.169

Find Burst On/Off (remote control, K8) ..6.373

Find Sync (K8)........................................4.168

Find Sync On/Off (K8)............................4.168

Find Sync On/Off (remote control, K8)...6.374

Firmware Update....................................4.276

Firmware Update (remote control) .........6.258

Fix Freq (K30) ........................................4.265

Fix Freq (remote control, K30) ....6.533, 6.555

FM ............................................................4.61

FM (remote control) .................................6.70

Format Hex/Dec (K72) ...........................4.277

Format Hex/Dec (remote control, K72).6.585,

6.586

F-PICH (K82) .........................................4.344

F-PICH (remote control, K82) ................6.601

Frame Count (K14) ................................4.196

Frame Count (remote control, K14) .......6.404

Freeze (K20) ..........................................4.242

Freeze (remote control, K20) .................6.474

Freq Axis Lin/Log (remote control).........6.133

Freq Settings (K30) ................................4.253

Freq Settings (remote control, K30)......6.550,

6.554, 6.555, 6.556, 6.557

Frequency Abs/Rel (K20).......................4.227

Frequency Abs/Rel (remote control, K20)

............................................................6.505

Frequency Coupling (K9) .......................4.188

Frequency Coupling (remote control, K9)

............................................................6.384

Frequency Line 1....................................4.126

Frequency Line 1 (remote control) ..6.25, 6.26

Frequency Line 2....................................4.126

Frequency Line 2 (remote control) ..6.25, 6.26

Frequency Manual (K9)..........................4.188

Frequency Manual (remote control, K9).6.384

Frequency Offset......................................4.10

Frequency Offset (remote control) .........6.203

Frontend Settings (K82) .........................4.309

Frontend Settings (K84) ........................ 4.364

F-TDPICH (K82).................................... 4.344

F-TDPICH (remote control, K82)........... 6.602

Full Burst (K91)...................................... 4.421

Full Burst (K92/K93) .............................. 4.461

Full Burst (remote control, K91) ............ 6.702

Full Burst (remote control, K92/K93) ..... 6.791

Full Size Diagram .................................. 4.117

Full Size Diagram (remote control)........ 6.130

Full Span ................................................. 4.12

Full Span (K7)........................................ 4.152

Full Span (remote control)..................... 6.203

Full Span (remote control, K7) .............. 6.320

Full Subframe (K93) .............................. 4.463

Gate Delay............................................... 4.36

Gate Delay (K8)..................................... 4.179

Gate Delay (remote control) .................. 6.231

Gate Length............................................. 4.36

Gate Length (K8) ................................... 4.180

Gate Length (remote control) ................ 6.231

Gate Mode Lvl/Edge................................ 4.35

Gate Mode Lvl/Edge (remote control) ... 6.232

Gate Settings........................................... 4.35

Gated Trigger .......................................... 4.35

Gated Trigger (remote control)... 6.230, 6.232

Gating Settings On/Off (K91) ................ 4.422

Gating Settings On/Off (K92/K93) ......... 4.464

Gating Settings On/Off (remote control, K91)

..................................... 6.737, 6.738, 6.739

Gating Settings On/Off (remote control,

K92/K93)................................. 6.847, 6.848

General Settings (remote control, K91) 6.705,

6.706, 6.707, 6.711, 6.723, 6.728, 6.736,

6.737, 6.739, 6.750, 6.751, 6.752

General Setup ....................................... 4.268

GFSK Start (K8) .................................... 4.180

GFSK Start (remote control, K8) ........... 6.364

GFSK Stop (K8)..................................... 4.180

GFSK Stop (remote control, K8) ........... 6.365

GPIB...................................................... 4.271

GPIB Address........................................ 4.271

GPIB Address (remote control) ............. 6.254

GPIB Language ..................................... 4.272

GPIB Terminator LFEOI/EOI................. 4.272

GPIB Terminator LFEOI/EOI (remote control)

........................................................... 6.254

Grid Abs / Rel .......................................... 4.16

Grid Abs / Rel (remote control).............. 6.135

Grid Abs / Rel (remote control, K20) ..... 6.475

Hardcopy ............................................... 4.288

Hardware Info ........................................ 4.277

Hardware Info (remote control) ...... 6.7, 6.122

Harmonic Distort.................................... 4.116

Harmonic On/Off ................................... 4.116

Harmonic RBW Auto ............................. 4.117

Harmonic Sweep Time .......................... 4.117

High Pass AF Filter (K7)........................ 4.148

High Pass AF Filter (remote control, K7)6.325

History Depth (K14) ............................... 4.194

R&S FSL Index

1300.2519.12 Index 43 E-10

History Depth (remote control, K14).......6.405

Hold/Cont .................................................4.47

Hor Sync...................................................4.37

Hor Sync (remote control) ......................6.282

HSDPA/HSUPA On/Off (K72)................4.279

HSDPA/HSUPA On/Off (remote control, K72)

............................................................6.584

Hum (K20)..............................................4.240

Hum (remote control, K20).....................6.437

I/O Logging On/Off .................................4.272

ID String Factory ....................................4.271

ID String User.........................................4.271

IF Output IF/Video..................................4.267

IF Output IF/Video (remote control) .......6.170

IF Power Retrigger Holdoff.......................4.36

IF Power Retrigger Holdoff (remote control)

............................................................6.278

IF Power Retrigger Hysteresis .................4.37

IF Power Retrigger Hysteresis (remote

control)................................................6.278

Import.....................................................4.288

Import (K91) ...........................................4.423

Import (K92/K93)....................................4.465

Import (remote control, K91) ..................6.725

Import (remote control, K92/K93)...........6.832

Inactive Channel Threshold (K72)..........4.278

Inactive Channel Threshold (remote control,

K72) ....................................................6.585

Info (LXI) ................................................4.270

Init Carr Freq Tol (K8) ............................4.183

Input 50 M/75 M......................................4.17

Input 50 M/75 M(remote control) .........6.151

Input RF/Cal/TG .....................................4.278

Input RF/Cal/TG (remote control) ..........6.123

Insert (K30) .................................4.264, 4.270

Insert after Range ..................................4.110

Insert after Range (remote control)........6.195

Insert before Range ...............................4.110

Insert before Range (remote control).....6.195

Insert Line ..............................................4.265

Insert Line (K20).....................................4.236

Insert Value ............................................4.125

Insert Zone/Burst (K93)..........................4.460

Install Option ..........................................4.277

Install Printer ..........................................4.292

Installed Options (remote control)...6.7, 6.122

Interpolation Lin/Log...............................4.266

Interpolation Lin/Log (remote control) ....6.183

Invert Q On/Off (K72).............................4.278

Invert Q On/Off (remote control, K72)....6.588

IP Address..............................................4.269

IQ Capture Settings (K82)......................4.310

IQ Capture Settings (K84)......................4.365

IQ Capture Settings (remote control, K82)

.................................................6.617, 6.620

IQ Capture Settings (remote control, K84)

.................................................6.658, 6.662

LAN Reset..............................................4.271

LAN Status On/Off .................................4.270

LAP (K8) ................................................ 4.169

LAP (remote control, K8)....................... 6.375

Last Span ................................................ 4.12

Left Limit......................................... 4.72, 4.93

Left Limit (remote control) ....................... 6.65

Limit Checking......................................... 4.98

Limit Chk On/Off...................................... 4.98

Limit Chk On/Off (remote control) . 6.33, 6.36,

6.40

Limit Line Auto (K72)............................. 4.293

LIMIT LINE AUTO (K82) ....................... 6.599

LIMIT LINE AUTO (K84) ....................... 6.636

Limit Line Auto (remote control, K72).... 6.570

Limit Line Manual (K72)......................... 4.293

LIMIT LINE MANUAL (K82)................... 6.599

LIMIT LINE MANUAL (K84)................... 6.636

Limit Line Manual (remote control, K72)

................................................ 6.570, 6.571

Limit Line Manual (remote control, K82) 6.600

Limit Line Manual (remote control, K84) 6.637

Limit Line Select dialog box (remote control)

.................................................... 6.48, 6.54

Limit Line User (K72)............................. 4.294

LIMIT LINE USER (K82)........................ 6.599

LIMIT LINE USER (K84)........................ 6.636

Limit Line User (remote control, K72).... 6.570

Limits On/Off ........................................... 4.93

Limits On/Off (remote control)................. 6.64

Lin (Average Mode) ................................. 4.49

Line (K20) .............................................. 4.240

Line (remote control) ............................. 6.519

Lines 625/525 .......................................... 4.38

Lines 625/525 (remote control) ............. 6.281

List Down............................................... 4.112

List Evaluation ....................................... 4.111

List Evaluation On/Off............................ 4.112

List Evaluation On/Off (remote control) ... 6.24

List Full Screen...................................... 4.112

List Up ................................................... 4.112

List Zone/Burst (K93)............................. 4.458

Local ...................................................... 4.289

Log (Average Mode)................................ 4.49

Logo On/Off ........................................... 4.273

Logo On/Off (remote control) ................ 6.129

Loss Settings (K30) ............................... 4.259

Loss Settings (remote control, K30) ..... 6.550,

6.551, 6.552

Low Pass AF Filter (K7)......................... 4.148

Low Pass AF Filter (remote control, K7)

................................................ 6.325, 6.326

LXI ......................................................... 4.270

Manual....................................................... 4.9

Manual (remote control) ........................ 6.201

Manual Reference Power (K20) ............ 4.235

Manual Reference Power (remote control,

K20) ............................. 6.487, 6.491, 6.494

Map Network Drive ................................ 4.288

Map Network Drive (remote control) .... 6.161,

6.162, 6.163

Index R&S FSL

1300.2519.12 Index 44 E-10

Mapping Auto (K84) ...............................4.375

Mapping Complex (K84) ........................4.375

Margin ....................................................4.112

Margin (remote control)............................6.24

Marker 1...................................................4.59

Marker 1 (K30) .......................................4.267

Marker 1 (K82) .......................................4.342

Marker 1 (K84) .......................................4.395

Marker 1 (K91) .......................................4.433

Marker 1 (K92/K93)................................4.483

Marker 1 (remote control) ........................6.12

Marker 1 (remote control, K30)...6.529, 6.530

Marker 1 (remote control, K91)..6.691, 6.692,

6.693, 6.694, 6.695

Marker 1 (remote control, K92/K93)......6.775,

6.776, 6.777, 6.779, 6.780

Marker 1 to 4 (remote control) .......6.21, 6.22,

6.56, 6.64, 6.66

Marker 2...................................................4.59

Marker 2 (K82) .......................................4.342

Marker 2 (K84) .......................................4.395

Marker 2 (remote control) ........................6.12

Marker 3...................................................4.59

Marker 3 (K82) .......................................4.342

Marker 3 (K84) .......................................4.395

Marker 3 (remote control) ........................6.12

Marker 4...................................................4.59

Marker 4 (K82) .......................................4.342

Marker 4 (K84) .......................................4.395

Marker 4 (remote control) ........................6.12

Marker Demod .........................................4.61

Marker Demod Volume ..........................4.132

Marker List (remote control).....................6.71

Marker Norm/Delta...................................4.59

Marker Norm/Delta (K82).......................4.342

Marker Norm/Delta (K84).......................4.395

Marker Norm/Delta (remote control) ........6.12

Marker Off (K91) ....................................4.434

Marker Off (K92/K93).............................4.483

Marker Off (remote control, K91) ...........6.691

Marker Off (remote control, K92/K93)....6.775

Marker Peak List ......................................4.63

Marker Search Type (K14).....................4.200

Marker Stepsize .......................................4.64

Marker Stepsize (remote control).............6.66

Marker to Trace........................................4.61

Marker to Trace (K30)............................4.268

Marker to Trace (remote control) ....6.20, 6.63

Marker to Trace (remote control, K20)..6.440,

6.465

Marker to Trace (remote control, K30)...6.530

Marker Zoom............................................4.62

Marker Zoom (K72)................................4.282

Marker Zoom (K91)................................4.434

Marker Zoom (K92/K93) ........................4.483

Marker Zoom (remote control) .................6.81

Marker Zoom (remote control, K91).......6.697

Marker Zoom (remote control, K92/K93)6.782

Max Hold .........................................4.44, 4.99

Maximize Size (K14).............................. 4.194

Maximize Size (remote control, K14)..... 6.405

Mean........................................................ 4.92

Mean (remote control) .................... 6.98, 6.99

Meas (K82) ............................................ 4.317

Meas (K84) ............................................ 4.371

Meas Carrier (K20) ................................ 4.234

Meas Carrier (remote control, K20)...... 6.469,

6.470

Meas Display ......................................... 4.273

Meas Filter (K8) ..................................... 4.176

Meas Filter (remote control, K8)............ 6.373

Meas Settings (K30) .............................. 4.260

Meas Settings (remote control, K30).... 6.539,

6.548, 6.557, 6.563

Meas Single/Cont (K91) ........................ 4.433

Meas Single/Cont (remote control, K91) 6.722

Meas Start/Stop..................................... 4.115

Meas Start/Stop (remote control) 6.148, 6.149

Meas Time (K7)..................................... 4.146

Meas Time (remote control, K7). 6.312, 6.327

Meas Time Auto (K8) ............................ 4.175

Meas Time Manual (K8) ........................ 4.175

Meas Time/Average (K9) ...................... 4.188

Meas Time/Average (remote control, K9)

................................................ 6.384, 6.385

Meas to Ref (K9) ................................... 4.189

Meas to Ref (remote control, K9) .......... 6.378

Mem1 On/Off (K30) ............................... 4.267

Mem1 On/Off (remote control, K30)...... 6.534

Mem2 On/Off (K30) ............................... 4.267

Mem2 On/Off (remote control, K30)...... 6.534

Mem3 On/Off (K30) ............................... 4.267

Mem3 On/Off (remote control, K30)...... 6.534

Min........................................................... 4.72

Min (K14) ............................................... 4.201

Min (K30) ............................................... 4.268

Min (K91) ............................................... 4.434

Min (remote control) ....................... 6.18, 6.60

Min (remote control, K14)6.392, 6.394, 6.397,

6.400

Min (remote control, K30)...................... 6.531

Min (remote control, K91)...................... 6.693

Min Hold .................................................. 4.44

MKR –> Trace (K91) ............................. 4.434

MKR –> Trace (K92/K93) ...................... 4.484

MKR –> Trace (remote control, K91) .... 6.694

MKR –> Trace (remote control, K92/K93)

........................................................... 6.778

Mkr Demod On/Off .................................. 4.61

Mkr Demod On/Off (remote control)........ 6.69

Mkr List On/Off (remote control).............. 6.71

Mkr Stop Time ......................................... 4.61

Mkr Stop Time (remote control) .............. 6.69

Modulation AM/FM/PM (remote control, K7)

........................................................... 6.286

Modulation Analysis (K20)..................... 4.241

Modulation Char (K8) ............................ 4.183

R&S FSL Index

1300.2519.12 Index 45 E-10

Modulation Char (remote control, K8)...6.345,

6.346, 6.347

Modulation Errors (K20) .........................4.242

Modulation FM/PM/AM (K7)...................4.144

Modulation Options (K20) ......................4.224

Modulation Options (remote control, K20)

.....6.500, 6.501, 6.506, 6.507, 6.509, 6.510

Monitor Int/Ext ........................................4.276

Multi Carrier (K82)..................................4.312

Multi Carrier (K84)..................................4.367

Multi-Carrier Filter Settings (remote control,

K82) ....................................................6.609

Multi-Carrier Filter Settings (remote control,

K84) ....................................................6.649

ndB down ................................................4.62

n dB down (remote control)...6.75, 6.76, 6.77,

6.78

Name......................................................4.287

Name (remote control) .............................6.31

Name (remote control, K30)...................6.524

Network Address....................................4.269

Network Drive.........................................4.287

New .............................................4.124, 4.266

New (K20) ..............................................4.224

New (K30) ..............................................4.269

New (K82) ..............................................4.315

New (K84) ..............................................4.370

New (remote control)....6.29, 6.32, 6.41, 6.42,

6.43, 6.49, 6.50, 6.51, 6.52, 6.53

New (remote control, K30) .....................6.525

New (remote control, K82) .....................6.606

New (remote control, K84) .....................6.646

New Folder.............................................4.286

New Folder (remote control) ..................6.160

New Search..............................................4.63

New Segment (K93)...............................4.460

New Zone/Burst (K93)............................4.460

Next Meas Frequency (K20) ..................4.236

Next Meas Frequency (remote control, K20)

......................................6.486, 6.489, 6.493

Next Min ...................................................4.72

Next Min (K14) .......................................4.201

Next Min (remote control) ......6.19, 6.61, 6.62

Next Min Mode < abs > ............................4.72

Next Min X Search < abs > (K14) ..........4.199

Next Min Y Search up/abs/dn (K14).......4.200

Next Min Y Search up/abs/dn (remote

control, K14) ......6.394, 6.395, 6.400, 6.401

Next Peak.................................................4.71

Next Peak (K14).....................................4.198

Next Peak (remote control) ...6.17, 6.18, 6.19,

6.59, 6.60, 6.61, 6.62

Next Peak Mode < abs >..........................4.71

Next Peak Y Search up/abs/dn (K14) ....4.199

Next Peak Y Search up/abs/dn (remote

control, K14) .................6.393, 6.398, 6.399

No of Halfslots (K84)..............................4.403

No. of ACP Chan (K8)............................4.179

No. of ACP Chan (remote control, K8) . 6.356,

6.360

No. of Harmonics................................... 4.116

Noise Meas On/Off.................................. 4.59

Noise Meas On/Off (remote control) ...... 6.78,

6.79

Noise Src On/Off ................................... 4.267

Noise Src On/Off (remote control)......... 6.124

Normalize .............................................. 4.138

Normalize (K82)..................................... 4.321

Normalize (K84)..................................... 4.376

Normalize (remote control).................... 6.179

Normalize On/Off (K72)......................... 4.278

Normalize On/Off (remote control, K72) 6.587

Number of Readings (K9)...................... 4.189

Number of Readings (remote control, K9)

........................................................... 6.385

OBW...................................................... 4.101

OBW (remote control) .................... 6.87, 6.91

Occupied Bandwidth (K82).................... 4.349

Occupied Bandwidth (K84).................... 4.401

Occupied Bandwidth (remote control, K82)

........................................................... 6.609

Occupied Bandwidth (remote control, K84)

........................................................... 6.649

Option expiry ......................................... 4.277

Option Licenses..................................... 4.277

Other LAN Settings................................ 4.269

Output Power (K8)................................. 4.183

Output Power (remote control, K8)........ 6.348

Overview (K20)...................................... 4.241

Packet Bytes SCO (K8) ......................... 4.168

Packet Bytes SCO (remote control, K8) 6.361

Packet Type (K8)................................... 4.167

Packet Type (remote control, K8).......... 6.363

Password.................................... 4.270, 4.279

Password (remote control) .................... 6.260

Paste ..................................................... 4.286

PCCPCH (K72)...................................... 4.283

PCCPCH (remote control, K72) . 6.567, 6.574

Peak ............................................... 4.71, 4.92

Peak (K14)............................................. 4.198

Peak (K30)............................................. 4.268

Peak (K91)............................................. 4.434

Peak (remote control)6.17, 6.58, 6.101, 6.102

Peak (remote control, K14) ....... 6.391, 6.392,

6.397, 6.398

Peak (remote control, K30) ................... 6.531

Peak (remote control, K91) ................... 6.693

Peak Code Domain Error (K82) ............ 4.330

Peak Code Domain Error (remote control,

K82) ........................................ 6.597, 6.624

Peak Excursion ....................................... 4.73

Peak Excursion (remote control)............. 6.63

Peak List Off............................................ 4.63

Peak Search ............................................ 4.60

Peak Search (remote control) ....... 6.14, 6.71,

6.72, 6.73

Peaks per Range................................... 4.116

Index R&S FSL

1300.2519.12 Index 46 E-10

Percent Marker.......................................4.102

Percent Marker (K82)..................4.342, 4.350

Percent Marker (K84)..................4.395, 4.402

Percent Marker (remote control) ..............6.67

Ph Noise On/Off (remote control) ...6.13, 6.16

Ph Noise/Ref Fixed (remote control).......6.13,

6.16

Phase Noise 1 2 3 4.................................4.60

Phase Noise On/Off .................................4.59

Phase Noise/Ref Fixed ............................4.59

Phase Unit Rad/Deg (K7).......................4.149

Phase Unit Rad/Deg (remote control, K7)

............................................................6.331

Phase Wrap On/Off (K7)........................4.149

Phase Wrap On/Off (remote control, K7)

............................................................6.287

PLCP Header (remote control, K91) ......6.705

PN Offset................................................4.368

PN Offset (K82)......................................4.313

Points / Symbol (K8) ..............................4.171

Points / Symbol (remote control, K8) .....6.363

Power (Average Mode) ............................4.50

Power (K72) ...........................................4.289

Power (K82) ...........................................4.345

Power (K84) ...........................................4.398

Power (remote control, K72) ..................6.576

Power (remote control, K82) ..................6.609

Power (remote control, K84) ..................6.649

Power Avg Start (K8) .............................4.178

Power Avg Stop (K8)..............................4.179

Power Class (K8) ...................................4.168

Power Control Group (K82)....................4.319

Power Level (remote control, K91).........6.752

Power Meter...........................................4.131

Power Mode .............................................4.99

Power Mode (remote control)...................6.87

Power Offset ...............................4.138, 6.236

Power Ref TOT/CPICH (K72) ................4.276

Power Ref TOT/CPICH (remote control, K72)

............................................................6.588

Power Reference (K82)..........................4.320

Power vs PCG (K82)..............................4.324

Power vs PCG (remote control, K82)....6.597,

6.624

Power vs Symbol (K82)..........................4.332

Powermeter On/Off (K9) ........................4.188

Powermeter On/Off (remote control, K9)

............................................................6.383

Preamp On/Off.........................................4.15

Preamp On/Off (remote control) ............6.151

Predefined Colors .......................4.274, 4.292

Predefined Colors (remote control).......6.128,

6.142

Print Colors ............................................4.275

Print Screen ...........................................4.290

Print Screen (remote control).....6.139, 6.140,

6.144, 6.161

PvT (K84) ...............................................4.403

PVT (K91) ..............................................4.420

PVT (K92/K93) ...................................... 4.461

PVT (remote control, K91)..................... 6.701

PVT (remote control, K92/K93) ............. 6.790

R&S Support (K91)................................ 4.423

R&S Support (K92/K93) ........................ 4.466

Ramp Up/Down/Up & Down (K91) ........ 4.422

Ramp Up/Down/Up & Down (remote control,

K91) ................................................... 6.702

Range (K8) ............................................ 4.173

Range (remote control, K8) ................... 6.369

Range Lin. Unit........................................ 4.15

Range Lin. Unit (remote control) ........... 6.134

Range Linear ........................................... 4.15

Range Linear %....................................... 4.15

Range Linear % (remote control) .......... 6.134

Range Linear (K7) ................................. 4.153

Range Log ............................................... 4.14

Range Log (K7) ..................................... 4.153

Range Log (remote control) .................. 6.134

Range Log (remote control, K20) .......... 6.475

Recall.......................................... 4.139, 4.285

Recall (remote control) .......................... 6.181

Recall File.............................................. 4.283

Recall File (remote control) ................... 6.159

Ref Level ................................................. 4.14

Ref Level (K8)........................................ 4.173

Ref Level (remote control).......... 6.115, 6.135

Ref Level (remote control, K20) ............ 6.476

Ref Level Adjust Man/Auto .................... 4.267

Ref Level Adjust Man/Auto (remote control)

........................................................... 6.182

Ref Level Offset....................................... 4.16

Ref Level Offset (remote control) .......... 6.135

Ref Level Offset (remote control, K20).. 6.476

Ref Level Position.................................... 4.16

Ref Level Position (remote control) ....... 6.136

Ref Level Position (remote control, K20)6.476

Ref Lvl =Mkr Lvl....................................... 4.71

Ref Lvl =Mkr Lvl (remote control) ............ 6.79

Ref Point Frequency................................ 4.60

Ref Point Frequency (remote control) ..... 6.14

Ref Point Level ........................................ 4.60

Ref Point Level (remote control).............. 6.15

Ref Point Time (remote control) .............. 6.14

Ref Pow Max/Mean (K91) ..................... 4.422

Ref Pow Max/Mean (remote control, K91)

........................................................... 6.702

Ref Value............................................... 4.139

Ref Value (remote control) .................... 6.136

Ref Value Position ................................. 4.139

Ref Value Position (remote control) ...... 6.136

Ref Value Position (remote control, K20)

........................................................... 6.476

Reference Channel (K20)...................... 4.234

Reference Channel (remote control, K20)

..................................... 6.487, 6.490, 6.494

Reference Fixed ...................................... 4.60

Reference Fixed On/Off .......................... 4.60

Reference Int/Ext................................... 4.264

R&S FSL Index

1300.2519.12 Index 47 E-10

Reference Int/Ext (remote control)........6.228,

6.235

Reference Manual..................................4.404

Reference Mean Power (K84)................4.404

Reference Mean Power (remote control, K84)

............................................................6.650

Reference Position (K7) .........................4.147

Reference Position (K8) .........................4.173

Reference Position (remote control, K7)6.296

Reference Position (remote control, K8)6.369

Reference Power (K20)..........................4.234

Reference Power (remote control, K20)6.488,

6.491, 6.495

Reference Value (K7).............................4.147

Reference Value (K8).............................4.174

Reference Value (K9).............................4.189

Reference Value (remote control, K7) ...6.296

Reference Value (remote control, K8) ...6.369

Reference Value (remote control, K9) ...6.378

Refresh (K91).........................................4.433

Refresh (K92/K93) .................................4.482

Refresh (remote control, K92/K93) ........6.829

Rel TX Power (K8) .................................4.184

Rel TX Power (remote control, K8) .......6.350,

6.351

Reload (K82) ..........................................4.318

Reload (K84) ..........................................4.371

Rename..................................................4.286

Rename (remote control) .......................6.160

Repetition Intervall....................................4.35

Res BW ..................................................4.102

Res BW (K7) ..........................................4.155

Res BW (K82) ........................................4.350

Res BW (K84) ........................................4.402

Res BW (remote control) .......................6.175

Res BW (remote control, K7).................6.318

Res BW Auto ...........................................4.22

Res BW Auto (K8)..................................4.176

Res BW Auto (remote control)....6.175, 6.176

Res BW Auto (remote control, K8) ........6.357

Res BW Manual .......................................4.22

Res BW Manual (K8) .............................4.176

Res BW Manual (remote control) ..........6.175

Res BW Manual (remote control, K8) ....6.356

Reset Password .....................................4.279

Restart on Fail (K84) ..............................4.404

restart on Fail (remote control, K84) ......6.650

restor STD Lines (K84) ..........................4.404

Restore Default Tables (K20) ................4.225

Restore Default Tables (K82) ................4.318

Restore Default Tables (K84) ................4.373

Restore Default Tables (remote control, K82)

............................................................6.610

Restore Default Tables (remote control, K84)

............................................................6.648

Restore FSL K82 Files (K82) .................4.348

Restore FSL K82 Files (remote control, K82)

............................................................6.599

Restore FSL K84 Files (K84) .................4.401

Restore FSL K84 Files (remote control, K84)

........................................................... 6.636

Restore Standard Files.......................... 4.114

Restore Std Lines (K72) ........................ 4.294

Restore Std Lines (remote control, K72)6.570

Result (remote control, K82) ..... 6.616, 6.618,

6.619, 6.621

Result (remote control, K84) ................. 6.657

Result Display (K7)................................ 4.145

Result Settings (K82)............................. 4.318

Result Settings (K84)............................. 4.373

Result Summary (K82) .......................... 4.325

Result Summary (remote control, K82) 6.597,

6.601, 6.624

Result Summary Extended (K72).......... 4.288

Result Summary Extended (remote control,

K72) ................................................... 6.588

Result Summary Normal (K72) ............. 4.287

Revision 0 A (remote control, K84) ....... 6.651

Revision 0/A (K84)................................. 4.366

SLOT (remote control, K84)............... 6.652

RF (K20) ................................................ 4.226

RF (remote control, K20)....................... 6.502

RF Atten Auto .......................................... 4.16

RF Atten Auto (remote control) ............. 6.151

RF Atten Manual...................................... 4.15

RF Atten Manual (K20).......................... 4.229

RF Atten Manual (remote control) ......... 6.150

RF Slot Full Idle (K84) ........................... 4.403

RF Spectrum (K7) ................................. 4.145

RF Stepsize (K20) ................................. 4.227

RF Time Domain (K7) ........................... 4.145

Right Limit....................................... 4.73, 4.93

Right Limit (remote control) ..................... 6.65

Rising & Falling (K91)............................ 4.421

Rising & Falling (remote control, K91)... 6.702

Rising/Falling (K93) ............................... 4.463

RMS......................................................... 4.92

RMS (remote control) ................. 6.103, 6.105

Run Single/Cont (K92/K93) ................... 4.482

Same as Meas Channel (K20) .............. 4.235

Save ...................................................... 4.283

Save (K82)............................................. 4.318

Save (K84)............................................. 4.371

Save (remote control)............................ 6.168

Save As Standard.................................. 4.114

Save Changes (K20) ............................. 4.225

Save Evaluation List .............................. 4.112

Save Evaluation List (remote control).... 6.166

Save Factor ........................................... 4.266

Save File................................................ 4.283

Save File (remote control) .......... 6.167, 6.168

Save Limit Line ...................................... 4.125

Scaling................................................... 4.102

Scaling (K82) ................... 4.337, 4.341, 4.350

Scaling (K84) .............................. 4.389, 4.402

Schematic (K30).................................... 4.263

Scrambling Code (K72) .............. 4.276, 4.277

Index R&S FSL

1300.2519.12 Index 48 E-10

Scrambling Code (remote control, K72)6.585,

6.586

Scrambling Code Autosearch (K72) ......4.277

Scrambling Code Autosearch (remote

control, K72) .......................................6.586

Screen A/B (K91) ...................................4.435

Screen A/B (remote control, K82) ..........6.611

Screen A/B (remote control, K84) ..........6.653

Screen A/B (remote control, K91) ..........6.709

Screen Colors (remote control)...6.128, 6.141

Screen Focus A/B (K82) ........................4.321

Screen Focus A/B (K84) ........................4.376

Screen Focus A/B (K92/K93) .................4.485

Screen Focus A/B (remote control, K92/K93)

.................................................6.811, 6.812

Screen Full/Split (K91) ...........................4.436

Screen Full/Split (remote control, K91) ..6.709

Screen Size (remote control, K82) .........6.611

Screen Size (remote control, K84) .........6.653

Screen Size Full/Split (K82) ...................4.321

Screen Size Full/Split (K84) ...................4.376

Screen Size Full/Split (K92/K93)............4.485

Screen Size Full/Split (remote control,

K92/K93).............................................6.811

Screen Title ............................................4.273

Screen Title (remote control) .................6.131

Search Len Auto (K8).............................4.170

Search Len Manual (K8) ........................4.171

Search Len Manual (remote control, K8)

.................................................6.375, 6.376

Search Lim Off .........................................4.73

Search Lim Off (remote control) ...6.64, 6.117

Search Limits ...........................................4.72

Search Limits (remote control).................6.64

Search Mode (K14) ................................4.198

Search Signals .........................................4.91

Select 1 2 3 4 ...........................................4.70

Select 1 2 3 4 (K14) ...............................4.198

Select 1 2 3 4 (K82) ...............................4.343

Select 1 2 3 4 (K84) ...............................4.396

Select 1 2 3 4 (remote control)........6.56, 6.66

Select 1 2 3 4 (remote control, K14) .....6.391,

6.396

Select Ch/PCG (K82) .............................4.327

Select Channel (K72) .............................4.275

Select Channel (remote control, K72)....6.584

Select Code Slot (K84)...........................4.373

Select Color Set ..........................4.274, 4.275

Select CPICH Slot (K72) ........................4.276

Select CPICH Slot (remote control, K72)

............................................................6.589

Select Directory......................................4.267

Select Directory (remote control) ...........6.184

Select File ..............................................4.283

Select Frame (remote control, K14).......6.404

Select Items ...........................................4.284

Select Items (remote control).....6.164, 6.165,

6.166

Select Meas (K82)..................................4.321

Select Meas (K84) ................................. 4.376

Select Object .............................. 4.274, 4.292

Select Path ............................................ 4.283

Select Print Color Set ............................ 4.291

Select Print Color Set (remote control).. 6.141

Select Search Area (K14)...................... 4.200

Select Search Area (remote control, K14)

................................................ 6.391, 6.397

Select Slot (remote control, K84) .......... 6.662

Select Trace ................................... 4.10, 4.99

Select Trace (K7) .................................. 4.145

Select Trace (K8) .................................. 4.171

Select Trace (remote control)....... 6.94, 6.227

Select Traces to check .......................... 4.124

Select Traces to check (remote control) 6.31,

6.32

Self Align ............................................... 4.268

Self Align (remote control)..................... 6.120

Selftest................................................... 4.279

Selftest (remote control) ............................ 6.9

Selftest Results...................................... 4.279

Selftest Results (remote control) ........... 6.125

SEM Settings (K92/K93)........................ 4.465

Service................................................... 4.278

Service Function.................................... 4.279

Service Function (remote control) ......... 6.125

Set Mean To Manual (K84) ................... 4.404

Set Standard.......................................... 4.114

Set Standard (remote control) ............... 6.189

Set to Default.............................. 4.275, 4.292

Set to Default (remote control) ... 6.128, 6.141

Settings (K82)........................................ 4.307

Settings (K84)........................................ 4.363

Settings General/Demod (K91) ............. 4.411

Settings General/Demod (K92/K93)...... 4.446

Settings General/Demod (remote control,

K92/K93)6.791, 6.795, 6.796, 6.797, 6.798,

6.799, 6.800, 6.801, 6.802, 6.803, 6.804,

6.805, 6.806, 6.807, 6.808, 6.809, 6.810,

6.814, 6.835, 6.836, 6.837, 6.838, 6.839,

6.840, 6.845, 6.846, 6.848, 6.849, 6.850,

6.855, 6.863, 6.864, 6.865, 6.866, 6.868

Settings General/Demod (remote control,

K93) ........................................ 6.844, 6.845

Settings Overview (K82)........................ 4.308

Settings Overview (K84)........................ 4.363

Shift X Limit Line (remote control) ........... 6.43

Shift Y Limit Line (remote control) .. 6.49, 6.53

Shoulder Atten On/Off (K20) ................. 4.233

Show Align Results................................ 4.268

Show Align Results (remote control) ..... 6.121

Show List (K72) ..................................... 4.277

Show List (remote control, K72) ............ 6.586

Show Peaks........................................... 4.112

Show Peaks (remote control) .................. 6.25

Shutdown Off/Standby........................... 4.277

Sig Count On/Off ..................................... 4.60

Sig Count On/Off (remote control).. 6.56, 6.57

Signal Field (K91) .................................. 4.431

R&S FSL Index

1300.2519.12 Index 49 E-10

Signal Field (remote control, K91)..........6.705

Signal Level (K20)..................................4.228

Signal Track .............................................4.10

Signal Track (remote control)...................6.93

Single Meas (remote control)......6.146, 6.147

Single Sweep ...........................................4.25

Single Sweep (K8)..................................4.178

Single Sweep (remote control)....6.146, 6.147

Size ........................................................4.287

Soft Frontpanel.......................................4.276

Soft Frontpanel (remote control) ............6.256

Sort (K82)...............................................4.318

Sort (K84)...............................................4.371

Sort Mode...............................................4.287

Sort Mode Freq/Lvl...................................4.63

Sort Mode Freq/Lvl (remote control) ........6.72

Source Cal .............................................4.138

Source On/Off ........................................4.137

Source On/Off (remote control)..............6.169

Source Power..............................4.137, 6.236

Span Manual ............................................4.12

Span Manual (K7) ..................................4.152

Span Manual (remote control)................6.203

Span Manual (remote control, K7) .........6.320

Spectrogram...........................................4.132

Spectrogram Clear (K14) .......................4.197

Spectrogram Clear (remote control, K14)

............................................................6.402

Spectrogram On/Off (K14).....................4.194

Spectrogram On/Off (remote control, K14)

............................................................6.402

Spectrum (K20)...........................4.232, 4.241

Spectrum (K91)......................................4.427

Spectrum (K92/K93)...............................4.471

Spectrum ACPR (K91)...........................4.429

Spectrum ACPR (remote control, K91).6.696,

6.703

Spectrum Emission Mask ......................4.104

Spectrum Emission Mask (K72).............4.292

Spectrum Emission Mask (K82).............4.347

Spectrum Emission Mask (K84).............4.399

Spectrum Emission Mask (remote control,

K72) ....................................................6.576

Spectrum Emission Mask (remote control,

K82) ....................................................6.609

Spectrum Emission Mask (remote control,

K84) ....................................................6.649

Spectrum ETSI/IEEE (K91)....................4.428

Spectrum ETSI/IEEE (K92/K93) ............4.473

Spectrum FFT (K91) ..............................4.428

Spectrum FFT (K92/K93).......................4.475

Spectrum FFT (remote control, K91) .....6.703

Spectrum FFT (remote control, K92/K93)

............................................................6.792

Spectrum Flat./Diff./Group Delay (K92/K93)

............................................................4.471

Spectrum Flat./Diff./Group Delay (remote

control, K92/K93)................................6.793

Spectrum Flatness (K91) .......................4.427

Spectrum Flatness (remote control, K91)

........................................................... 6.703

Spectrum IEEE/ETSI (remote control, K91)

........................................................... 6.704

Spectrum IEEE/ETSI (remote control,

K92/K93)................................. 6.793, 6.794

Spectrum Mask (K91)............................ 4.428

Spectrum Mask (remote control, K91) .. 6.704

Spurious Emissions............................... 4.115

Spurious Emissions (K8) ....................... 4.184

Spurious Emissions (remote control, K8)

..................................... 6.342, 6.343, 6.344

Start .................................................. 4.8, 4.12

Start (K82) ............................................. 4.335

Start (K84) ............................................. 4.387

Start End (K92/K93) .............................. 4.462

Start End (remote control, K92/K93) ..... 6.791

Start Test (K8) ....................................... 4.177

Startup Recall ........................................ 4.285

Startup Recall (remote control) ............. 6.159

Startup Recall Setup.............................. 4.285

Statistics (K91) ...................................... 4.429

Statistics (K92/K93) ............................... 4.478

Std Dev.................................................... 4.93

Std Dev (remote control) ............ 6.105, 6.107

Stepsize Standard ................................... 4.64

Stepsize Standard (remote control)......... 6.66

Stepsize Sweep Points............................ 4.65

Stepsize Sweep Points (remote control) . 6.66

Stop .................................................. 4.8, 4.12

Stop (K82) ............................................. 4.335

Stop (K84) ............................................. 4.387

Subnet Mask.......................................... 4.269

Swap IQ (K82) ....................................... 4.310

Swap IQ (K84) ....................................... 4.365

Sweep Count .................................. 4.26, 4.47

Sweep Count (K8) ................................. 4.178

Sweep Count (remote control) .............. 6.229

Sweep Count (remote control, K8) ........ 6.365

Sweep List ............................................. 4.105

Sweep List (remote control) ...... 6.190, 6.191,

6.192, 6.193, 6.194, 6.195, 6.196, 6.197,

6.198, 6.210, 6.211, 6.212, 6.213, 6.214

Sweep Points........................................... 4.27

Sweep Points (remote control) .............. 6.233

Sweep Single/Cont (K30) ...................... 4.265

Sweep Single/Cont (remote control, K30)

........................................................... 6.533

Sweep Time.................................. 4.36, 4.100

Sweep Time (remote control) ................ 6.234

Sweeptime Auto ............................. 4.23, 4.26

Sweeptime Auto (K8)............................. 4.175

Sweeptime Auto (K82.............................. 4.23

Sweeptime Auto (remote control).......... 6.234

Sweeptime Auto (remote control, K8) ... 6.367

Sweeptime Manual ......................... 4.23, 4.26

Sweeptime Manual (K20) ...................... 4.240

Sweeptime Manual (K8) ........................ 4.175

Sweeptime Manual (remote control) ..... 6.234

Index R&S FSL

1300.2519.12 Index 50 E-10

Sweeptime Manual (remote control, K8)6.366

Sync Offset (K8).....................................4.169

Sync Offset (remote control, K8)............6.375

Sync Type CPICH/SCH (K72)................4.279

Sync Type CPICH/SCH (remote control, K72)

............................................................6.589

System Info ............................................4.277

System Messages..................................4.278

System Messages (remote control) .......6.257

Threshold .................................................4.73

Threshold (remote control).....................6.117

Tilt (K20).................................................4.245

Tilt Setup (K20) ......................................4.246

Tilt Setup (remote control, K20) ..6.507, 6.508

Time / Phase Estimation (K82) ..............4.313

Time / Phase Estimation (K84) ..............4.367

Time Domain Power ................................4.92

Time Domain Power (remote control)......6.97

Time Line 1 ............................................4.127

Time Line 1 (remote control)..................6.118

Time Line 2 ............................................4.127

Time Line 2 (remote control)..................6.118

Time Stamp On/Off (K14) ......................4.195

Time Stamp On/Off (remote control, K14)

............................................................6.406

Time+Date .............................................4.272

Time+Date (remote control)........6.256, 6.261

Time+Date On/Off..................................4.273

Time+Date On/Off (remote control) .......6.132

TOI ...........................................................4.91

TOI (remote control).................................6.80

Trace 1 2 3 4 5 6......................................4.44

Trace 1 2 3 4 5 6 (remote control) .........6.132

Trace 1 2 3 4 5 6 (remote control, K20) .6.474

Trace 1 2 3 4 5 6 (remote control, K8) ...6.368

Trace Math...............................................4.48

Trace Math (remote control) .......6.108, 6.109

Trace Math Position .................................4.48

Trace Mode..............................................4.44

Trace Mode (K82) ..................................4.340

Trace Mode (K84) ..................................4.393

Trace Mode (remote control) 6.97, 6.98, 6.99,

6.100, 6.101, 6.102, 6.104, 6.106, 6.132,

6.135

Trace Mode (remote control, K20) ........6.474,

6.475

Trace Mode (remote control, K8) ...........6.367

Track BW .................................................4.10

Track BW (remote control).......................6.93

Track On/Off ............................................4.10

Track On/Off (remote control)..................6.93

Track Threshold.......................................4.10

Track Threshold (remote control) ............6.94

Tracking Generator ................................4.131

Transducer.............................................4.265

Trg / Gate Level .......................................4.34

Trg / Gate Level (remote control)...........6.279

Trg / Gate Polarity Pos/Neg .....................4.34

Trg / Gate Polarity Pos/Neg (remote control)

................................................ 6.231, 6.280

Trg / Gate Source.................................... 4.33

Trg / Gate Source (remote control) ...... 6.232,

6.279, 6.280

Trg/Gate Level (K8) ............................... 4.181

Trigger Level (K9).................................. 4.190

Trigger Offset .......................................... 4.34

Trigger Offset (K20)............................... 4.240

Trigger Offset (K7)................................. 4.157

Trigger Offset (remote control).............. 6.277

Trigger Polarity (K82) ............................ 4.311

Trigger Polarity (K84) ............................ 4.366

Trigger Polarity Pos/Neg (K82).............. 4.340

Trigger Polarity Pos/Neg (K84).............. 4.393

Trigger Source (K7)............................... 4.156

Trigger Source (K72)............................. 4.281

Trigger Source (K8)............................... 4.181

Trigger Source (K82).................. 4.310, 4.340

Trigger Source (K84).................. 4.365, 4.393

Trigger Source (remote control, K7)...... 6.330

Trigger Source (remote control, K72).... 6.595

TV Analyzer (K20) ................................. 4.245

TV Free Run On/Off ................................ 4.38

TV Free Run On/Off (remote control).... 6.281

TV Trig Settings....................................... 4.37

TX Spec ACP (K8) ................................ 4.183

TX Spec ACP (remote control, K8) ....... 6.335

Unit .......................................................... 4.16

Unit (K20) ................................... 4.229, 4.243

Unit (remote control)................... 6.119, 6.283

Unit (remote control, K20) ......... 6.438, 6.461,

6.462, 6.463, 6.468, 6.520

Unit/Scale (K9) ...................................... 4.188

Unit/Scale (remote control, K9) .. 6.379, 6.388

Unzoom (K91) ....................................... 4.434

Unzoom (K92/K93) ................................ 4.483

Unzoom (remote control, K91) .............. 6.697

Unzoom (remote control, K92/K93)....... 6.782

Update Path (remote control) ................ 6.258

Use Ref Lev Offset (K9) ........................ 4.189

Use Ref Lev Offset (remote control, K9)6.386

User Def'd Colors .................................. 4.292

User Defined Colors .............................. 4.274

User Defined Colors (remote control).... 6.141

Value ..................................................... 4.125

Value (remote control)........... 6.41, 6.47, 6.51

Velocity Factor (K20) ............................. 4.243

Velocity Factor (remote control, K20).... 6.497

Versions+Options .................................. 4.277

Versions+Options (remote control) ........... 6.7

Vert Sync ................................................. 4.37

Vert Sync (remote control)..................... 6.281

Vert Sync Even Field ............................... 4.37

Vert Sync Even Field (remote control)... 6.281

Vert Sync Odd Field ................................ 4.37

Vert Sync Odd Field (remote control).... 6.281

Video BW Auto ........................................ 4.23

Video BW Auto (K8) .............................. 4.176

R&S FSL Index

1300.2519.12 Index 51 E-10

Video BW Auto (remote control) .6.177, 6.178

Video BW Auto (remote control, K8)......6.358

Video BW Manual ....................................4.22

Video BW Manual (K8) ..........................4.176

Video BW Manual (remote control)........6.177

Video BW Manual (remote control, K8) .6.357

Video Pol Pos/Neg ...................................4.38

Video Pol Pos/Neg (remote control).......6.282

Video Scope (K20) .................................4.239

View..........................................................4.45

Vision Modulation (K20) .........................4.240

Vision Modulation (remote control, K20) 6.437

Volume .....................................................4.61

Volume (remote control) ........................6.262

X * RBW .....................................................4.9

X * RBW (remote control) ...........6.201, 6.202

X * Span .....................................................4.9

X * Span (remote control) ...........6.201, 6.202

xOffset (remote control) ..........................6.42

x*Demod BW (K7)..................................4.151

x–Axis Range .........................................4.103

x–Axis Range (remote control) ..............6.115

x–Axis Ref Level ....................................4.103

x–Axis Ref Level (remote control)..........6.115

XML Export (K82)...................................4.348

XML Export (K84)...................................4.401

XML Export (remote control).......6.190, 6.623

XML Import (K82)...................................4.348

XML Import (K84)...................................4.400

yOffset (remote control) .................6.48, 6.52

y–Axis Max Value...................................4.103

y–Axis Max Value (remote control) ........6.116

y-Axis Maximum (K82)................4.337, 4.341

y-Axis Maximum (K84)...........................4.390

y–Axis Min Value....................................4.103

y-Axis Minimum (K82) .................4.337, 4.341

y-Axis Minimum (K84) ............................4.390

Y–Axis/Div (K91) ....................................4.424

Y–Axis/Div (K92/K93).............................4.470

Y–Axis/Div (remote control, K91)...........6.710

Y–Axis/Div (remote control, K92/K93)....6.813

y-Unit %/Abs...........................................4.103

y–Unit %/Abs (remote control) ...............6.116

Zero (K9) ................................................4.188

Zero (remote control, K9).......................6.380

Zero Phase Reference Point (K7)..........4.149

Zero Phase Reference Point (remote control,

K7) ......................................................6.316

Zero Span ................................................4.12

Zero Span (remote control)....................6.203

Zoom (K20) ......................4.241, 4.242, 4.243

Zoom (K7) ..............................................4.150

Zoom (K8) ..............................................4.179

Zoom (remote control, K20).......6.476, 6.477,

6.478

Zoom (remote control, K7)..........6.321, 6.322

SPAN key.....................................................4.11

span menu

base unit...................................................4.11

K7 option ............................................... 4.152

K82 option ............................................. 4.335

K84 option ............................................. 4.388

special characters ......................................... 6.3

spectrogram (K14)

menu...................................................... 4.191

spectrogram menu (K14) .......................... 4.194

Spectrum Analyzer mode.......................... 4.129

Spurious Emissions measurement (K8) ... 4.165

SRE (service request enable register) ........ 5.17

SRQ (service request) ....................... 5.17, 5.25

start frequency .............................................. 4.8

status bar

K30 option ............................................. 4.252

K91 option ............................................. 4.410

K92/K93 option ...................................... 4.444

status byte (STB) ........................................ 5.17

STATus OPERation register ....................... 5.19

STATus QUEStionable register .................. 5.19

ACPLimit register..................................... 5.20

FREQuency register ................................ 5.21

LIMit register............................................ 5.22

LMARgin register..................................... 5.22

POWer register........................................ 5.23

SYNC....................................................... 5.24

status register

CONDition part ........................................ 5.14

ENABle part............................................. 5.15

ESE ......................................................... 5.18

ESR ......................................................... 5.18

EVENt part............................................... 5.15

NTRansition part...................................... 5.15

overview .................................................. 5.16

PPE ......................................................... 5.18

PTRansition part...................................... 5.15

SRE ......................................................... 5.17

STATus OPERation ................................ 5.19

STATus QUEStionable............................ 5.19

STATus QUEStionable ACPLimit............ 5.20

STATus QUEStionable FREQuency ....... 5.21

STATus QUEStionable LIMit................... 5.22

STATus QUEStionable LMARgin............ 5.22

STATus QUEStionable POWer............... 5.23

STATus QUEStionable SYNC................. 5.24

STB.......................................................... 5.17

structure................................................... 5.14

sum bit..................................................... 5.15

status reporting system ............................... 5.14

resetting values ....................................... 5.27

WiMAX, WiBro measurements (K92/K93)

............................................................. 5.44

STB (status byte) ........................................ 5.17

step size

center frequency........................................ 4.8

stop frequency............................................... 4.8

storing ........................................................... 8.1

string ............................................................. 5.9

subchannelization (K92/K93) .................... 2.150

suffix.............................................................. 5.7

Index R&S FSL

1300.2519.12 Index 52 E-10

sum bit .........................................................5.15

supply voltage, external noise source........4.267

supported tests (K8) ....................................2.38

sweep

continue single sweep..............................4.26

continuous................................................4.25

count ...............................................4.26, 4.47

Free Run ..................................................4.31

gated ...............................................4.29, 4.35

single........................................................4.25

time ..........................................................4.26

SWEEP key .................................................4.24

sweep menu

base unit...................................................4.25

K14 option ..............................................4.195

K30 option ..............................................4.265

K7 option ................................................4.155

K8 option ................................................4.177

K82 option ..............................................4.339

K84 option ..............................................4.392

K91 option ..............................................4.432

K92/92 option .........................................4.482

sweep time

coupling....................................................4.23

Symbol Constellation (K84) .......................4.384

Symbol EVM rms / Pk (K82) ......................4.327

symbols

WiMAX, WiBro measurements (K93) ....2.154

SYNC.........................................................4.305

sync signal ...................................................4.37

sync word (K8) ..................................2.44, 4.168

synchronization

K92/K93 option.......................................2.150

K93 option ..............................................2.156

syntax elements of commands....................5.10

System Messages dialog box ....................4.278

TD..............................................................4.305

TDPICH .....................................................4.305

test

self test...................................................4.279

supported (K8) .........................................2.38

transmitter (K8) ........................................2.39

test setup

analog TV (K20) .......................................2.49

base station tests (K72) .........................2.115

base station tests (K82) .........................2.127

digital TV (K20) ........................................2.72

text parameter................................................5.9

threshold

line............................................................4.73

signal tracking ..........................................4.10

Tilt Setup dialog box (K20) ........................4.246

time ............................................................4.273

line..........................................................4.127

Timing Offset (K82) ...................................4.327

title

diagram ..................................................4.273

title bar

K91 option ............................................. 4.410

K92/K93 option ...................................... 4.444

Total PWR (K82)....................................... 4.326

trace ............................................................ 4.44

Clear Write .............................................. 4.40

power measurement................................ 4.99

signal tracking.......................................... 4.10

TRACE key ................................................. 4.39

trace menu

base unit .................................................. 4.43

K20 option ............................................. 4.229

K30 option ............................................. 4.266

K82 option ............................................. 4.340

K84 option ............................................. 4.393

K91 option ............................................. 4.435

K93 option ............................................. 4.485

trace mode .................................................. 4.44

Average .......................................... 4.41, 4.45

Blank............................................... 4.41, 4.45

Clear Write ..................................... 4.40, 4.44

Max Hold ........................................ 4.40, 4.44

Min Hold ......................................... 4.40, 4.44

View................................................ 4.41, 4.45

tracking generator ..................................... 4.134

menu........................................... 4.134, 4.137

transducer ................................................. 4.265

activating ............................................... 4.265

transmission measurement....................... 4.135

transmitter tests (K8)................................... 2.39

Trg to Frame (K82) .................................... 4.326

TRIG key..................................................... 4.28

trigger

concepts (K8) .......................................... 2.44

extern (K8)............................................... 2.44

external.................................................... 4.31

external gate............................................ 4.35

gated sweep ............................................ 4.35

level ......................................................... 4.34

offset........................................................ 4.34

slope ........................................................ 4.34

trigger menu

base unit .................................................. 4.33

K7 option ............................................... 4.156

K72 option ............................................. 4.281

K8 option ............................................... 4.180

K82 option ............................................. 4.340

K84 option ............................................. 4.393

K91 option ............................................. 4.411

K92/K93 option ...................................... 4.446

trigger mode................................................ 4.33

External ................................................... 4.31

Free Run.................................................. 4.31

IF power................................................... 4.31

TV............................................................ 4.32

Video ....................................................... 4.31

TV trigger .................................................... 4.37

TX filter (K20).............................................. 2.66

R&S FSL Index

1300.2519.12 Index 53 E-10

unit .............................................................4.188

universal command .....................................5.34

upper–case (commands)........................5.6, 6.2

velocity factor (K20) .....................................2.78

Versions/Options dialog box......................4.277

vertical sync signal.......................................4.37

video bandwidth ...........................................4.22

video polarity................................................4.38

video triggering ............................................4.31

View trace mode ..........................................4.41

VXI interface messages...............................5.30

VXI protocol................................................. 5.28

Walsh code ............................................... 4.305

white space ................................................. 5.10

WiMAX menu (K92/K93)................ 4.438, 4.444

WiMAX mode (K92/92) ............................. 4.130

WLAN menu (K91)......................... 4.405, 4.410

WLAN mode (K91).................................... 4.130

zero span .................................................... 4.12

zeroing (K9)............................................... 4.187

zoom ........................................................... 4.62

amplitude ................................................. 4.41

Operating Manual For The R&S FSL R&S/R&S Operating_Manual_FSL_v11 V11

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