Leidos NORMARC7031 User Manual Normarc 7050 General Description

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Document ID	103314
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Document Description	7031 General Description
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Document Type	User Manual
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Date Submitted	2000-06-06 00:00:00
Date Available	2000-06-28 00:00:00
Creation Date	1999-12-16 14:48:31
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Document Lastmod	1999-12-16 14:50:26
Document Title	Normarc 7050 General Description.book
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NORMARC 7050
MARKER BEACON
General Description
©1999 Navia Aviation AS
©1999 Navia Aviation AS
NORMARC 7050
USER MANUAL
MARKER BEACON
PART I INTRODUCTION
GENERAL INFORMATION
This paragraph gives a description of a typical ILS installation and the Normarc Marker Beacon system. Conventions and abbreviations used in this manual are also given.
1.1
Introduction
This is an overview of Normarc's NM 7050 ILS marker beacons systems.
1.1.1
ILS Overview
A complete Instrument Landing System comprises:
• A LOCALIZER SYSTEM, producing a radio course to furnish lateral guidance to the airport
runway.
• A GLIDE PATH SYSTEM, producing a radio course to furnish vertical guidance down the
correct descent angle to the runway.
• MARKER BEACONS, to provide accurate radio fixes along the approach course.
The layout of a typical ILS airport installation is shown below.
Localizer
110 MHz
Glide Path
330 MHz
Marker Beacon
75MHz
3°
HBK547-1
Figure 1-1Typical ILS airport installation
1.1.2
Marker Beacons Overview
The complete ILS marker beacons system comprises:
• A Marker Beacon transmitter/monitor cabinet
• A Marker Beacon antenna
• A remote control
• An Remote Maintenance Monitor (RMM) program to be installed on a PC
• Optional slave panel
• Optional backup battery
©1999 Navia Aviation AS
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GENERAL INFORMATION
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USER MANUAL
NORMARC 7050
MARKER BEACON
BEACON
ANTENNA
MARKER
BEACON
CABINET
TRANSMITTERS
AND
MODULATORS
DUAL ANTENNA SYSTEM
RF OUT
DISTRIBUTION
NETWORK
MONITOR
NETWORK
REMOTE
CONTROL
UNIT
MONITOR(S)
RF IN
SLAVE
PANEL
POWER
SUPPLY(S)
RMM
SYSTEM
MAINS INPUT
220V/110V AC
24V
BATTERY
HBK779/1
Figure 1-2 Marker beacon block diagram
1.1.3
Marker Beacons Description
The marker beacons are located vertically beneath the localizer course line at distance 150m
(inner marker), 1km (middle marker) and 7km (outer marker) from the runway threshold.
The beacons radiate a 75MHz radio signal with an audio Morse code. The Morse code and
modulation frequency differ for the outer, middle and inner marker. Outer marker transmits
dash code 400Hz, middle marker transmits dash dot code 1300Hz and inner marker dot code
3000Hz.
1.2
Product Type Numbers
The Normarc product numbering system is based on the following three levels:
• System
• Assembly
• Module
Systems have type numbers starting with NM, for example NM7050. Systems consist of
assemblies, modules and parts.
Assemblies have type numbers consisting of three letters, a three- or four- digit number and a
letter, for example CAA 1370A. CAA is an abbreviation of CAbinet Assembly, 1370 is a running number, and the last letter is the variant designator. Assemblies can consist of assemblies, modules and parts.
GENERAL INFORMATION
1-2
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NORMARC 7050
USER MANUAL
MARKER BEACON
Modules have type numbers consisting of two letters, a three- or four- digit number and a letter, for example MO 1374A. MO is an abbreviation of MOnitor, 1374 is a running number, and
the last letter is the variant designator. Modules consist of parts.
1.3
Abbreviations
AC
ADC
AGC
CPU
DAC
DC
DM
EEPROM
EMC
EMI
EPROM
FIFO
FPGA
I/F
ILS
IM
LED
LF
LRU
MCU
MM
NAV
NF
OM
PC
RAM
RF
RMM
RMS
ROM
RTC
SC
SRAM
STB
SW
TX
Alternating Current
Analog to Digital Converter
Automatic Gain Control
Central Processing Unit
Digital to Analog Converter
Direct Current
Depth of Modulation
Electrically Erasable Programmable Read Only Memory
Electro Magnetic Compatibility
Electro Magnetic Interference
Erasable Programmable Read Only Memory
First In First Out
Field Programmable Gate Array
Inter Face
Instrument Landing System
Inner Marker
Light Emitting Diode
Low Frequency
Line Replaceable Unit
Monitor Combiner Unit
Middle Marker
NAVigation signals
Near Field
Outer Marker
Personal Computer
Random Access Memory
Radio Frequency
Remote Maintenance Monitor
Remote Monitoring System
Read Only Memory
Real Time Clock
Station Control
Static Random Access Memory
STandBy
Soft Ware
Transmitter
©1999 Navia Aviation AS
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GENERAL INFORMATION
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USER MANUAL
NORMARC 7050
MARKER BEACON
GENERAL INFORMATION
1-4
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©1999 Navia Aviation AS
NORMARC 7050
USER MANUAL
MARKER BEACON
Physical organisation
This chapter describes the physical outline of the NM 7050
2.1
Configurations
2.1.1
Module and Assembly Location
The figures on the following pages show the locations of the modules in the main cabinet.
Figure 2-1 shows the front panel of the cabinet, with the control panel, on/off switch and local
PC connection.
LC1377
MARKER BEACON SYSTEM
ESC
PREV
NEXT
TX1
SERVICE
PARAM
ENTER
TX2
DISAGR
ALARM
BATT
TX TO AIR
WARNING
MAINT
STBY
MAIN
NORMAL
ON/
CHANGE
TX1/
OFF
OVER
TX2
LOCAL RS232
LOCAL
MANUAL
REMOTE
AUTO
WRITE
PROTECT
ON
ON
POWER
OFF
OFF
24V DC
MAINS
HBK780/1
Figure 2-1 NM 7050 Front panel
Figure 2-2 shows the open cabinet in front view with indication of plug in board location.
©1999 Navia Aviation AS
21464-5
Physical organisation
2-1
USER MANUAL
NORMARC 7050
MARKER BEACON
CI 1376
PB 1378
MONITOR 1
MONITOR 2 **)
MO 1374
TRANSMITTER 1
TX 1373
TRANSMITTER 2
POWER SUPPLY 1
POWER SUPPLY 2 *)
PS 1375
I S
*) Only used in dual power systems (NM 7050 B/D)
**) Only used in dual monitor systems (NM 7050 C/D)
Antistatic socket
HBK781/1
Figure 2-2 NM 7050 Module Location
Notice the location of the different plug in boards. It is essential for the MB to function, that the
cards are placed in these locations. If your MB is configured with only one plugin board of
each type, they must be placed in the number one locations. The backplane is however ,
marked with notifications of where each boards place is..
Τ The electronic devices inside NM 7050 are sensitive to Electro Static Discharge
(ESD). Please follow the instructions given in the preface of this manual to avoid
damage during servicing and transportation.
Physical organisation
2-2
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NORMARC 7050
USER MANUAL
MARKER BEACON
System Description
3.1
Introduction / Overview
The system is housed in a compact cabinet. There are four models/configurations of the NM
7050.
Variant
NM7050A
NM7050B
NM7050C
NM7050D
Monitor
Power Supply
Table3-1 Models / Configurations
As shown in Table 3-1, the beacon can have one or two monitor units and one or two power
supply units. Figure 3-1 shows a block diagram of the MB system.
The monitor and transmitter control function is based on software. The system is based on
modern technology with extensive Remote Monitoring and Maintenance capabilities, and very
high reliability and integrity.
©1999 Navia Aviation AS
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System Description
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USER MANUAL
NORMARC 7050
MARKER BEACON
NM7050 - MARKER BEACON
OPTIONAL MONITOR 2
MONITOR RF
FRONTEND
MONITOR
TRANSMITTER 1
STATION
CONTROL
TX 1373
CPU
LF
GENERATOR
400 Hz
1.300 Hz
POWER
AMPLIFIER
3.000 Hz
BASEBAND+
RF LEVEL
MO 1374
RF
OSCILLATOR
MAINTENANCE +
RMM INTERFACE
SPLITTER ONLY PRESENT
IF TWO MONITORS
75 MHz
ON/
OFF
MONITORING
CHANGE
OVER
MODULATION DEPTH
OUTPUT RF LEVEL
KEYING NORMAL/OFF/CONT.
STATUS
MONITOR 2
DATA
TRANSMITTER 2
TX 1373
LF
GENERATOR
MONITOR 1
MONITOR RF
FRONTEND
MONITOR
POWER
AMPLIFIER
3.000 Hz
STATION
CONTROL
CPU
DUMMY
LOAD
400 Hz
1.300 Hz
RF
OSCILLATOR
CI 1376
75 MHz
ON/
OFF
BASEBAND+
RF LEVEL
MO 1374
TX1/TX2
CONNECTION
MAINTENANCE +
RMM INTERFACE
+20V
+/-15V
+5V
MONITORING
INTERFACE
OPTIONAL POWER
PS 1375
LOCAL
CONTROL
POWER
SUPPLY
KEYBOARD
DISPLAY
AC
DC
DC
DC
LC 1377
RMM
LINE+
MODEM
LINE+
MODEM
MAINS
LOCAL PC
BATTERY
SENSORS ETC.
RMM
HBK782/1
REMOTE PC
REMOTE
CONTROL
SLAVE
PANEL
Figure 3-1 MB block diagram
3.2
Transmitters / Modulators
The NM7050 consists of two TX1373A transmitters. The main transmitter is connected to the
antenna, while the standby transmitter is connected to dummy load. A failure in the main
transmitter will cause an automatic change over to the standby transmitter.
The audio signals are generated in the LF circuitry mainly by a Field Programmable Gate
Array (FPGA). A strap field selects Inner, Middle or Outer Marker settings.
An onboard oscillator generates a 75MHz carrier wave which is amplitude modulated with the
System Description
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NORMARC 7050
USER MANUAL
MARKER BEACON
audio signal in the Power Amplifier (PA). The PA is capable of delivering up to 4W power at
97% depth of modulation.
Unwanted frequencies are removed by a lowpass filter after the PA.
3.3
Monitors / Transmitter Control
The marker beacon has one or two MO1374 monitor modules depending on model (Table 31).
The MO1374 is mainly a microprocessor based module. It contains the MB software and
forms the basis of the monitor, station control, system maintenance handling and RMS user
interface.
A detection of error in the transmitter signal causes change-over to the standby transmitter.
Failure of the standby transmitter leads to an alarm and optional shutdown of the standby
transmitter.
On a system with two monitor units, both must report error for alarm to be generated (2 of 2
voting). If the monitors disagree, the WARNING and DISAGR LEDs on the front panel is lit.
The MO1374 consists of two submodules:
The RF frontend receives a RF signal from the antenna (or recombining network for dual
antenna system). It demodulates the signal into analogue values propotional to the RF
power, the modulation depth and the morse code envelope. These parameters are digitized
and monitored by the CPU section.
The CPU section includes an 80CI88 CPU, memory, communication ports and an AD converter system.
3.4
Power Systems
The marker beacon can have either one or two PS1375 power modules depending on model
(Table 3-1). The PS1375 is 100W with 120V or 230V AC input voltage and +28V/3.5 A, +20/
2.5A, ±12V/1.25A and 5V/6A DC output voltages. Outputs are short circuit protected. On the
NM7050 B/D the two modules operate in parallel.
The 28V output is temperature compensated to ensure optimum battery charging. It gives
26.4V at 50°C and linearly increase to 29.6V at -30°C.
The backup battery is an external 24V battery. The battery gives a backup time of 6 hours,
and have external charging possibilities for longer backup time. This battery is automatically
brought into circuit on mains power failure. The charging time is approximately eight hours
with one PS1375 and five hours with two PS1375.
3.5
Remote control system
The remote control unit is used in the tower or in the technical control room. It has indicators
for operating status as well as detailed warnings and an aural alarm device with reset. It can
control equipment on/off and change over, and has an Access Grant switch to allow/inhibit
remote control from the RMM system.
©1999 Navia Aviation AS
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System Description
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USER MANUAL
NORMARC 7050
MARKER BEACON
The Remote Control Unit is connected to the MB by one pair telephone cable.
3.6
Remote Maintenance Monitoring (RMM)
The NM7000 series has a built-in Remote Maintenance Monitoring system. This system consists of the RMS system, remote PC terminals with the RMM program installed, and the local
keyboard/display. Figure 3-2 illustrates the RMM/RMS systems.
RMM
program
RMM
program
Modem
Modem
Local
Remote
RMS
data bus
Local
parameter
storages
Maintenance
data bus
Local
measuring
points
RMS
hardware
RMS
core
program
RMS system
Local
Keyboard/
Display
NM7050
RMM system
HBK783-1
Figure 3-2 The NM 7050 RMM/RMS systems
The centre of the RMM system is a CPU with the RMS core program. The RMS collects measurements and diagnostic data, and makes them available to the user. The collected information allows easy and cost effective maintenance, fault finding and routine reporting. In
addition, system settings are distributed and parameter readings are collected via the RMS/
CPU.
External Personal Computers are used for a user friendly interface to the RMM system. The
equipment has two serial output ports, typically used to connect a local PC and a connection
to a central maintenance facility.
System Description
3-4
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USER MANUAL
MARKER BEACON
The local keyboard/display allows readings and controls through an LCD display and a sevenbutton keypad. This gives access to the RMM functionality without the need for a PC.
3.7
RMM Access
Access to the RMM system is controlled by multiple hardware and software access controls.
One password is required for each access level, i.e. one password for level 1, two for level 2
and three for level 3. Optional hardware controls may inhibit writing in the upper access levels.
Access level 1
• Readout of all the monitor values, warning and alarm limits.
• Readout of all the maintenance values and warning limits.
• Readout of all the delays.
Access level 2
• TX1 and TX2 : morse normal, continuous or off.
• TX1 and TX2 : test signals 50% depth of mod. and 50% RF level.
• Diagnostics.
Access level 3
• Settings of all the monitor warning and alarm limits.
• Settings of all the maintenance warning limits.
• Settings of all the delays.
3.8
Local Keyboard/Display Functions
Through a menu based interface all main commands, adjustments and monitor limits are
accessible from the front panel keypad and LCD display. In addition a quick read function
gives readout of all main monitor parameters at a glance.
3.9
Document structure
In Figure 3-3 the document structure is shown. The upper tree is the contents of the cabinet,
©1999 Navia Aviation AS
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System Description
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USER MANUAL
NORMARC 7050
MARKER BEACON
while the lower tree is additional tower equipment.
NM7050A-D
Marker
Beacon
TX1373A
Transmitter
CAA1370A
Cabinet
Assembly
CI1376A
Connection
Interface
LC1377A
Local
Control
MO1374A
Monitor
PS1375A
Power
Supply
PB1378A
Piggy
Back
RCA124 0A
Remote
Control
Assembly
CH1385A/B
Cable
Harness
RC1241A
Remote
Control
RF1242A
Remote
Front
Additional
Tower
Equipment
MB1346/7A
Motherboard
SF1344A
Slave
Front
RFA1353
Remote
Frame
Assembly
CA1348A
Cabinet
PS635B
Power
Supply
HBK859/1
Figure 3-3 Document structure NM 7050 Marker Beacon system
System Description
3-6
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NORMARC 7050
USER MANUAL
MARKER BEACON
Technical Specifications
NM 7050 Marker Beacon Cabinet.
4.1
Signal Requirements
4.1.1
Transmitter
Frequency range
Frequency tolerance
Output power range
75 MHZ
±0,005 %
0,005 – 4 W adjustable.
Fixed attenuator optional in lower range
2,5 UW maximum
25 UW maximum
±0.5DB
Preset adjustable RF level
Harmonic radiation
spurious radiation
OUTPUT POWER STABILITY
Test function
4.1.2
Modulator
AM
MODULATION TYPE
Modulation alternatives
KEYED
CONTINUOUS
OFF
MODULATION FREQUENCY AND IDENTIFICATION
INNER MARKER
MIDDLE MARKER
Outer marker
Modulation depth
adjustable range
MAX. STEP SIZE
stability
Frequency tolerance
Total harmonic dist.
Keying
Speed
PAUSE TO DOT RATIO
PAUSE TO DASH RATIO
Test function
©1999 Navia Aviation AS
3000 HZ
•Τ•Τ•Τ•Τ•Τ•Τ•
1300 HZ
ΤΤ•ΤΤΤΤ•
400 HZ
ΤΤΤΤΤΤ
95%
45-97 %
0,5 % Depth of Modulation
±4 % Depth of Modulation
±2,5 %
8 %maximum
125 MS/DOT APPROX.
1:1
1:3 dots/SEC
2 dashes/sec
Preset adjustable Depth of Modulation,
normal, continous or no keying
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Technical Specifications
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USER MANUAL
NORMARC 7050
MARKER BEACON
4.1.3
Monitoring
4.1.3.1 Alarm Functions
RF power reduction
Change of modulation depth
Keying absence
Alarm identification to automatic
transmitter change over
SENDERUMSCHALTUNG
LINE BREAK
1,5-3 DB adjustable
50-70 % Depth of Modulation
2-5 sec.
MB - Remote Control
(DISABLE OPTIONAL) Standby alarm identification
to transmitter shutdown shall be configurable.
4.1.3.2 Monitor input levels
Adjustment range, nominal level
+1 TO -25 DBM (strap settings for IM, MM
and OM sensitivity)
4.1.3.3 Monitor stability at nominal levels
RF POWER VALUES
MODULATION DEPTH VALUES
±0,5 DB
±1,0 % Depth of Modulation
@ 10 – 30 ºC
±3,0 % Depth of Modulation
@ full temp. range
±2,0 % Depth of Modulation
variation for 3dB RF
reduction @ 10-30°C.
4.1.3.4 Warning funktion
RF POWER REDUCTION
Change of modulation depth
Maintenance parameter outside limits
Mains failure
40-75 % of alarm limit
40-75 % of alarm limit
4.1.3.5 Protocols
Monitor 1 to monitor 2 communication
RMM DATA PROTOCOL
4.1.4
SERIAL DATA PROTOCOL (not RS 232)
RS232
Remote Control
Either
Technical Specifications
4-2
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NORMARC 7050
USER MANUAL
MARKER BEACON
Data Transmission Medium
Data modulation
Transmitter level
Receiver dynamic range
2-wire line, 600 ohm
SERIAL, FSK
-10 DBM ± 2 DB
-10 DBM... -34 DBM OR RS232
or
RS-232 interface in both Marker Beacon and remote control
4.2
Environmental characteristics
Operating temperature
-40 TO +55 ºC
(main cabinet except
display)
-10 TO +55 ºC
(display, remote control and slave panel)
Storage temperature
HUMIDITY
-40 TO +60 ºC
95% TO +35 °C
DECREASING LINEARLY
TO 60% AT +55 °C
VIBRATION
0.15MM OR 19.6M/S2 (2G)
VERTICAL,10Hz
to
500Hz
4.3
EMV-charakteristics
GENERAL SPECIFICATIONS FOR EMC
SPURIOUS AND HARMONICS
SAFETY
4.4
ETS 300 339
EN50081-1 (emmission)
EN50082-2 (immunity)
EN61000-3-2 (harmonic current emmission)
EN61000-3-3 (voltage fluctuations and flicker)
CISPR 22
EN 60950
Mechanical characteristics
Dimensions (hxwxd):
MB CABINET
REMOTE CONTROL
SLAVE PANELS
267 X 450 X 343 MM
71 X 132 X 200 MM
51 X 132 X 200 MM
The MB rack is wall mounted. The remote control and slave panel fit a 19" shelf.
©1999 Navia Aviation AS
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Technical Specifications
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NORMARC 7050
MARKER BEACON
4.5
Power supply
OPERATING VOLTAGE:
MAIN SUPPLY
OR
STAND-BY BATTERY
POWER CONSUMPTION:
MB CABINET:
REMOTE CONTROL
BATTERY CHARGER
Technical Specifications
4-4
230 V +15 %/-20 %, 45-65 HZ,
120 V +15 %/-20 %, 45-65 HZ
24 V DC NOMINAL,
float charged by the main Supply.
The battery is able to use an external
charger.
The equipment is able to operate
without battery.
< 50 W
<5W
ADAPTED TO 5 HOURS (NM 7050 B/D) or 8
hours (NM 7050 A/C) charging time to 90%
battery capacity for a battery giving 6 hours
operation.
External battery charges may be connected
for longer operation, and shorter charging
time.
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NORMARC 7050
USER MANUAL
MARKER BEACON
Electrical installation
5.1
Marker beacon cabinet
5.1.1
Connection Overview
All electrical connections except the local PC connection, the mains connection and the RF IN
and OUT connections are on the CI1376 connection interface board inside the cabinet.
CABINET UNDERSIDE
FRONT VIEW WITH FRONT PLATE
MARKER BEACON SYSTEM
P RE V NEXT
PARAM
SERVICETX1
DISAGR
ALARM
BATT
M AINT
STBY
TX2
W ARNING TX TO AIR
NORMAL
ON/
OFF
ENTER
GND
ESC
M AIN
CHANGE
OVER
TX1/
TX2
RF OUT
LOCAL M ANUAL
LOCAL RS232
REM OTE AUTO
ON
RF IN
W RITE
PROTECT
ON
POW ER
OFF
24V DC
OFF
M AINS
FRONT VIEW WITHOUT FRONT PLATE
RF IN AND OUT
LOCAL PC (RS 232)
MAINS POWER
REMOTE CONTROL (RS 232)
REMOTE PC (RS 232)
3 ANALOGUE CHANNELS
AC LEVEL
4 DIGITAL PORTS
TEMP. INDOOR AND OUTDOOR
AN
TISTA
BATTERY
HBK784/1
Figure 5-1 Marker Beacon main cabinet connection overview
5.1.2
RF In and Out
• The output signal RF OUT is connected to the antenna with N-connectors and 50 Ω coaxial
cable.
The input signal RF IN is connected to the antenna probe with N-connectors and 50 Ω coaxial
cable.
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Electrical installation
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USER MANUAL
NORMARC 7050
MARKER BEACON
RF OUT
RF IN
HBK785/1
Figure 5-2 RF cable connection
5.1.3
Battery
The external backup battery is connected between BATT GND (-) and BATT +24V (+) on the
connector marked BATTERY on CI 1376.
A 16Ah battery gives approximately six hours backup time with 5-8 hours charging time
dependent on model. For longer backup time an external charger is required to be able to
charge the battery within a reasonable time. An external battery protection circuit (like Normarcs BP 543) has to be connected between the EXT. CHARGER (+) and BATT GND (-) input.
In addition MAINS directly on NM 7050 has to be disconnected. Figure 5-4 shows the connections schematically.
Electrical installation
5-2
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MARKER BEACON
TEMP
OUTDOOR
REMOTE
CONTROL
LINE
CI 1376
AC LEVEL
ANA CHA1
ANA CHA2
ANA CHA3
TEMP
INDOOR
DIG PORT A
DIG PORT B
DIG PORT C
DIG PORT D
BATT GND
BATT +24V
EXT CHARGE
BATTERY
BATT GND
BATT +24V
EXT CHARGE
BATTERY
HBK786/1
Figure 5-3 Battery connection
EXTERNAL
CHARGER
MAINS
BATT GND
BATT +24V
AC
EXT.CHARGE
BATTERY
DC
BATTERY
PROTECTION
NM 7050
BP 543
HBK863/1
Figure 5-4 External charger connection
5.1.4
Mains
The mains power cable connections are underneath the cabinet. They are covered by a aluminium plate fastened with four screws. The cable itself is threaded through the cable gland
and the three wires are connected to the terminals N, L and GND shown below in figure 6-4.
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Electrical installation
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NORMARC 7050
MARKER BEACON
HBK787/1
GND
MAINS POWER
GROUND CABLE CONNECTION
Figure 5-5 Power connection
5.1.5
Modem Power
A DC powered modem or other external equipment designed for 22V-27V DC can be connected to the terminal block marked MODEM POWER. Maximum current consumption
should be 800 mA.
Electrical installation
5-4
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USER MANUAL
MARKER BEACON
TEMP
AC LEVEL
OUTDOOR
ANA CHA1
ANA CHA2
ANA CHA3
REMOTE
CI 1376
CONTROL
LINE
TEMP
INDOOR
DIG PORT A
DIG PORT B
DIG PORT C
DIG PORT D
MODEM POWER
BATT GND
BATT +24V
MODEM POWER
EXT CHARGE
BATTERY
-(GND)
+ (+24V DC)
H1116/1
Figure 5-6 Modem Power
5.1.6
Remote Control
The remote line and remote control is connected to the CI 1376 connection interface board as
illustrated in Figure 5-7.
• FSK_[A,B] is the modem line pair.
• GND is main cabinet ground
A suitable female connector for the remote line is Weidemüller BLZ-5.08/4 or equivalent.
Alternatively the remote control connection is done with a RS 232 interface. The mode is configured on MO 1374, refer to 7.2.3.
Note: The position of RXD and TXD is interchanged from the normal RS-232 layout in the
Remote Control connector. Therefore a special cable must be used for connection to external
equipment.
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Electrical installation
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USER MANUAL
NORMARC 7050
MARKER BEACON
PB 1378
RS232
REMOTE RMM
RS232
REMOTE CONTOL
CONFIGURATION
TEMP
OUTDOOR
AC LEVEL
ANA CHA1
ANA CHA2
ANA CHA3
REMOTE
CONTROL
LINE
CI 1376
TEMP
INDOOR
REMOTE
CONTROL
1 - GND
2 - RC_LINE A
2 - RC_LINE B
RS-232
1 - Not used
2 - TXD
3 - RXD
4 - Not used
5 - GND
6 - Not used
7 - Not used
8 - Not used
9 - Not used
REMOTE
CONTROL
LINE
4 - Not used
HBK788/3
Figure 5-7 Remote control connection
5.1.7
PC and Modem
Modem connections for remote PC are the standard pin out RS232, 9 pins DSUB connector
on the CI1376 connection interface board marked remote-rmm as illustrated in Figure 5-8.
For local PC connection use the RS232 on front panel Figure 5-9.
Electrical installation
5-6
21464-5
©1999 Navia Aviation AS
NORMARC 7050
USER MANUAL
MARKER BEACON
REMOTE RMM
RS232
PB1378
REMOTE CONTOL
RS232
CONFIGURATION
TEMP
OUTDOOR
REMOTE
CONTROL
LINE
AC LEVEL
ANA CHA1
ANA CHA2
ANA CHA3
TEMP
INDOOR
CI 1376
REMOTE RMM
DIG PORT A
DIG PORT B
DIG PORT C
1-CD
2-RXD
3-TXD
4-DTR
5-GND
6-Not used
7-RTS
9-CTS
9-Not used
DIG PORT D
HBK789/1
Figure 5-8 Modem and modem battery backup connection
©1999 Navia Aviation AS
21464-5
Electrical installation
5-7
USER MANUAL
NORMARC 7050
MARKER BEACON
1 - Not used
2 - RXD
3 - TXD
4 - Not used
5 - GND
6 - Not used
7 - RTS
8 - CTS
9 - Not used
HBK790-1
Figure 5-9 Local PC RS232 connection
5.1.8
Analogue Inputs
The analogue inputs are connected to the CI1376 connection interface board as illustrated in
Figure 5-10.
The inputs are:
• Analogue Channel 1-3 - three differential DC analogue inputs, P (pin-1) is the positive and
N (pin-3) is the negative terminal, and pin 2 is GND.
Maximum voltage: ±15V
Input impedance: 10kΩ
• Temp Indoor and Outdoor - temperature measurement inputs with interface to an LM35
temperature sensor.
Maximum voltage: ±15V
Input impedance: 10kΩ
• AC Level - AC level measurement input. Intended for use with a battery eliminator to monitor the mains voltage.
Maximum voltage: 24Vpp
Electrical installation
5-8
21464-5
©1999 Navia Aviation AS
NORMARC 7050
USER MANUAL
MARKER BEACON
Input impedance: 10 kΩ
PB 1378
RS232
REMOTE RMM
RS232
REMOTE CONTOL
CONFIGURATION
TEMP
OUTDOOR
AC LEVEL
ANA CHA1
ANA CHA2
ANA CHA3
REMOTE
CONTROL
CI 1376
LINE
TEMP
INDOOR
DIG PORT A
TEMP *
V+
Vtemp
GND
DIG PORT B
AC LEVEL
1-VDD
2-T*DOOR
3-GND
4-Not used
1-VACP
2-GND
3-VACN
4-Not used
DIG PORT C
DIG PORT D
ANALOGUE
CHANNEL 1-3
1-ANLG*P
2-GND
3-ANLG*N
4-Not used
LM 35
Bottom view
HBK791/1
Figure 5-10 Analogue input connections
5.1.9
Digital Inputs and Outputs
Eight bi-directional digital channels (numbered 0-7) are sited on the CI1376 connection interface board as illustrated in Figure 5-11.
Logical levels: TTL
Input impedance: 560Ω.
A suitable female connector is Weidemüller BLZ-5.08/4 or equivalent.
©1999 Navia Aviation AS
21464-5
Electrical installation
5-9
USER MANUAL
NORMARC 7050
MARKER BEACON
REMOTE RMM
RS232
PB 1378
REMOTE CONTOL
RS232
CONFIGURATION
TEMP
OUTDOOR
REMOTE
CONTROL
LINE
CI 1376
AC LEVEL
ANA CHA1
ANA CHA2
ANA CHA3
TEMP
INDOOR
DIG PORT A
DIG PORT B
DIG PORT C
DIG PORT D
DIGITAL PORTS
1- DIGIN 1
1- DIGIN 3
1- DIGIN 5
1- DIGOUT 0
2- GND
2- GND
2- GND
2- GND
3- DIGIN 0
3- DIGIN 2
3- DIGIN 4
3- DIGOUT 1
4-GND
4-GND
4-GND
4-GND
HBK792/1
Figure 5-11 Digital input/output connections
5.1.10
Power for Modem or other external devices
A DC powered modem or other external equipment designed for 22V - 27V DC can be connected to the screw terminal J30. Maximum current consumption should be 0.8A.
The terminal marked OUT+ is 22V - 27V DC, OUT- is ground
5.1.11
Remote Control Interface (MB rack)
The transmission medium (telephone line (FSK modem) or RS 232) to the Remote Control
can be selected by plugs and link straps S700 and S701 on the MO1374 module:
Electrical installation
5-10
21464-5
©1999 Navia Aviation AS
NORMARC 7050
USER MANUAL
MARKER BEACON
S700 pins
connected
1-2
3-4
5-6
S701 pins
connected
1-2
3-4
5-6
Function
Connector on CI 1376:
Telephone line
RS 232
Not used
P3 Remote Control Line
P4 Remote Control RS232
Not used
5.2
Tower equipment
5.2.1
Remote Control Connection
The remote control is connected to the corresponding MB by connecting the REMOTE CONTROL connector on CI1376 to P9 on MB1346, as shown in Figure 5-12.
Suitable female connectors are Weidemüller BLZ-5.08/4 or equivalent. 600 Ω cable should
be used.
REMOTE
CONTROL
P9
MB1346
1 - GND
1 - TXOFF
2 - FSK_P
2 - ALARM
TXOFF
3 - FSK_N
3 - LINE_A
ALARM
4 - GND
4 - LINE_B
J2
P3
P9
J1
C B A
LINE A
LINE B
P10
RX A
RX B
CI1376
on
corresponding
MB
10
TX A
TX B
SLAVE RS485
15
P8
INTERLOCK
ALT.LINK
SLAVE
DIRECT
20
AUX IN/OUT
P6
P7
25
P5
OPTO OUT
P4
GND
1-ALARM (C)
GND
5V
2-ALARM (E)
3-NORM (C)
5V
30
4-NORM (E)
24V
5-WARN (C)
24V
6-WARN (E)
7-STBAL (C)
V_DIM
V_DIM
8-STBAL (E)
POWER OUT
POWER IN
HBK793-1
Figure 5-12 Remote control to MB connection
The power supply to the remote control is connected according to Figure 5-13. The battery
charger is connected to P2 on the MB1347 - power supply motherboard. Output connector P3
on MB1347 is connected to input connector P4 on MB1346 - remote control motherboard.
Several MB1346's are serial linked by connecting P5 on one board to P4 on the next.
©1999 Navia Aviation AS
21464-5
Electrical installation
5-11
USER MANUAL
NORMARC 7050
MARKER BEACON
Suitable female connectors are Weidemüller BLZ-5.08/4 or equivalent.
NORMARC
NORMARC
MB1346
MB1346
J2
P3
P9
J2
P3
P9
J1
TXOFF
ALARM
ALARM
NORMARC
LINE A
LINE B
LINE B
P10
P10
RX A
MB1347
LINE A
RX A
RX B
RX B
10
TX A
TX B
TX B
P2
GND
SLAVE RS485
15
15
15
P8
INTERLOCK
10
10
TX A
SLAVE RS485
ALT.LINK
J1
J1
TXOFF
P8
SLAVE
INTERLOCK
ALT.LINK
DIRECT
24V
SLAVE
From
24VDC
power
supply
DIRECT
AUX IN/OUT
20
AUX IN/OUT
P6
20
20
P6
POWER IN
S1
P7
25
P7
25
25
V_DIM=24V
P5
GND
OPTO OUT
P4
P5
GND
1-ALARM (C)
30
OPTO OUT
GND
2-ALARM (E)
24V
6-WARN (E)
7-STBAL (C)
V_DIM
8-STBAL (E)
POWER OUT
30
30
GND
5V
5V
4-NORM (E)
5-WARN (C)
V_DIM
3-NORM (C)
5V
4-NORM (E)
24V
GND
2-ALARM (E)
5V
3-NORM (C)
5V
P3
P4
1-ALARM (C)
5-WARN (C)
24V
POWER IN
24V
6-WARN (E)
7-STBAL (C)
V_DIM
V_DIM
8-STBAL (E)
POWER OUT
POWER IN
24V
V_DIM
POWER OUT
HBK794/1
Figure 5-13 Remote control power supply connections
5.2.2
Remote Slave Connection
The remote slave panel SF1344 is connected to the corresponding remote control's motherboard by connecting P3 on MB1346 to P1 on SF1344. P10 on MB1346 is not used. See Figure 5-14.
Suitable connectors are standard 25 pins female DSUB (Harting 0967 025 0442 and 0967
225 4704 or equivalent), connected by a 10 wire 1:1 cable.
Electrical installation
5-12
21464-5
©1999 Navia Aviation AS
NORMARC 7050
USER MANUAL
MARKER BEACON
NORMARC
MB1346
J2
P3
P9
J1
TXOFF
ALARM
LINE A
To P1
on
SF1344
LINE B
P10
1:1
RX A
RX B
10
TX A
TX B
SLAVE RS485
15
P8
INTERLOCK
ALT.LINK
SLAVE
DIRECT
AUX IN/OUT
20
P6
P7
25
P5
GND
OPTO OUT
13
25
14
P4
GND
1-ALARM (C)
30
2-ALARM (E)
5V
3-NORM (C)
5V
4-NORM (E)
5-WARN (C)
24V
24V
6-WARN (E)
7-STBAL (C)
V_DIM
V_DIM
8-STBAL (E)
POWER OUT
1 - GND
2 - ALARM
3 - WARNING
4 - NORMAL
7 - GND
15 - V24P
19 - ON_OFF
21 - SILENCE
23 - INTERLOCK (if used)
25 - BUZZER
POWER IN
HBK795/1
Figure 5-14 Remote slave connection
©1999 Navia Aviation AS
21464-5
Electrical installation
5-13
USER MANUAL
NORMARC 7050
MARKER BEACON
Electrical installation
5-14
21464-5
©1999 Navia Aviation AS
NORMARC 7050
USER MANUAL
MARKER BEACON
Antenna
Normarc supplies single and dual antennas, NM 3561 and NM 3562 respectively. The single
antenna may be used for inner, middle and outer marker, while the dual antenna is specially
designed for outer markers. The advantage of the dual antenna is a lower spread in FLYING
THROUGH TIME inside the localizer coverage area. In addition to two antenna elements, the
monitor and distribution network DI 726 is included in NM 3562.
SINGLE ANTENNA SYSTEM
DUAL ANTENNA SYSTEM
50
RF OUT
RF IN
RF OUT
50
RF IN
NETWORK
DI 726
HBK914-1
Figure 6-1 Antenna block diagram
Figure6-2 shows the field strength of the radiated signal directly above the middle marker
antenna. Figure6-3 and Figure6-4 illustrate the field strength above the outer marker
antenna, using single and dual antenna, respectively. The localizer course sector is scetched.
Along an elliptical curve, the field strength is constant. If you look at the diagrams as ordinary
geographical maps, you will see that the dual antenna "field-strength-mountain" is steaper
and more stretched sideways than the single antenna "mountain". This corresponds to a
sharper on/off response on the aircraft's marker beacon instruments.
©1999 Navia Aviation AS
21464-5
Antenna
6-15
USER MANUAL
NORMARC 7050
MARKER BEACON
Figure 6-2 Equi-signal-contours for Middle Marker Beacon, single antenna
Figure 6-3 Equi-signal-contours for Outer Marker Beacon, Single Antenna
Antenna
6-16
21464-5
©1999 Navia Aviation AS
NORMARC 7050
USER MANUAL
MARKER BEACON
Figure 6-4 Equi-signal-contours for Outer Marker Beacon, Dual Antenna
6.1
Antenna NM 3561 / NM 3562 For Ils Marker Beacon
The NM 3561/NM 3562 Marker Beacon Antennas are log-periodic dipoles possessing properties of high gain and directivity, and low side lobes. The performances og the antennas conform to ICAO Annex 10 item 3.1.6, and are such that they are largely independent of
environment factors such as rain, snow and ice, and they can therefore be located at «difficult» sites. The directivity of the antennas can, if required, be even further increased by adding additional elements to the array.
The radiation patterns for the antennas are almost unaffected by the surrondings, and the
antennas are therefore suitable for offset location where tilting of the antennas is necessary in
order to obtain the required signal coverage. (Refer to figure A-1)
Figure12-3, 12-4 and 12-5 shows constant field strenght lines through points in the glide path
(GP angle 3º). The marker beacons are located vertically beneath the localizer course line at
distance of 1050 m (middle marker) and 3.9 nautical miles (outer marker) from the threshold.
The field strengths specified are relative to the maximum level directly above the antenna.
The figures show that for an aircraft travelling at a speed of 50 m/s (96 knots) within the maximum allowable course sector of 6º the duration of the visual indication will be within the prescribes limits. The instrument panel lamp should be adjusted so as to switch on or off at the
levels indicated in the figures i.e. -27 dB to -33 dB for Figure12-3, -11 dB to Figure12-4, and 13 dB to -25 dB for Figure12-5.
The marker beacon antennas are mounted on poles, with the dipoles parallel to the course
line. The rear end of an antenna should be at least 2 metres above the ground.
The NM 3562 antenna comprises two elements, and is fed via a distribution network (DIA 726)
which splits the transmitter power into two equal parts. The network is a coaxial cable hybrid
housed in silumine box together with the monitor network which is used to combine the signal
from the two monitor probes.
©1999 Navia Aviation AS
21464-5
Antenna
6-17
USER MANUAL
NORMARC 7050
MARKER BEACON
Specifications:
NM 3561:
NM 3562:
Antenna construction
1 LPDA
2 LPDAs
Frequency
75 MHz
75 MHz
Gain
8,2 dB
11 dB
VSWR 50 Ohm
1,2 dB
1,2 dB
Required RF power
0,5W
0,4W
Dimensions
3,3 x 2,2 m
3,3 x 4,7 m
Weight
50 kg
110 kg
Mounting
Both types: 2.2 metres above ground
Temperature
Both types: -40ºC to +70ºC
Wind velocity
Both types: up to 180 km/h
Antenna
6-18
21464-5
©1999 Navia Aviation AS

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