Peninsula Engineering Solutions HR-11500 HR-11500 Microwave Linear Heterodyne Repeater User Manual HR 11500 MW Heterodyne Repeater

Peninsula Engineering Solutions, inc. HR-11500 Microwave Linear Heterodyne Repeater HR 11500 MW Heterodyne Repeater

UserManual.wiki >

Peninsula Engineering Solutions >

HR 11500 User Manual HTML Version

Users Manual

Corporate Headquarters

39 Grand Canyon Ln, San Ramon

California 94582 USA

Telephone: +1 925 901-0103

Facsimile: +1 925 901-0403

www.peninsulaengineering.com

HR-11500 Microwave Linear

Heterodyne Repeater

Operations Manual

550-0530-01

Revision A

December 2012

Revision A, December 2012

39 Grand Canyon Lane, San Ramon

California 94582

United States of America

Telephone: +1 925 901-0103

Facsimile: +1 925 901-0403

www.peninsulaengineering.com

The materials in this manual, the figures, tables and text, are the property of Peninsula Engineering Solutions,

Inc. Peninsula Engineering Solutions provides this manual to aid its customers in obtaining product, ordering,

installation, testing, maintenance, and application information for this product. This information is confidential; any

unauthorized duplication, distribution or electronic transfer of the materials to anyone other than Peninsula

Engineering Solutions authorized staff is forbidden.

By accepting this operations manual from Peninsula Engineering Solutions, you agree to hold, in strictest

confidence, and not to use or to disclose to any person, firm or corporation, without the express written

permission of Peninsula Engineering Solutions, the materials and information herein. “Confidential Information”

means any Peninsula Engineering Solutions proprietary information, technical data, know-how, product plans,

products, services, software, designs, drawings, hardware configuration information and tables featured in this

manual.

The information contained in this manual is subject to change.

Peninsula Engineering Solutions, Microwave Linear Heterodyne Repeater, and SmartPower are trademarks of

Peninsula Engineering Solutions, Inc. Other brands and their products are trademarks or registered trademarks

of their respective holders.

US FCC Identifier: ..... HR-11500, QFT-HR-11500 Rule Parts 101C and 15B

Document Change History

REV

DESCRIPTION

DATE

Initial Release

December 2012

R-

-1

HR-11500 Operations Manual Contents — i

Safety Precautions

Radio Frequency Radiation Hazard

This symbol indicates a risk of personal injury due to radio frequency exposure. The radio

equipment described in this guide uses radio frequency transmitters. Do not allow people to

come in close proximity to the front of the antenna while the transmitter is operating. The

antenna will be professional installed on fixed-mounted outdoor permanent structures to provide

separation from any other antenna and all persons.

WARNING: RF Energy Exposure Limits and Applicable Rules1 for 6-38 GHz. It is recommended that the radio

equipment operator refer to the RF exposure rules and precaution for each frequency band and other applicable

rules and precautions with respect to transmitters, facilities, and operations that may affect the environment due

to RF emissions for each radio equipment deployment site.

Worst case RF Energy Radiation occurs when maximum transmitter power and maximum antenna

gain are used. The referenced transmitter power is +33 dBm (2 Watts) and the antenna gain is

50.5 dBi (12 Ft diameter parabolic). The resulting EIRP is +83.5 dBm or +53.5 dBW. The minimum

separation distance for all persons from the antenna is 17 meters in this case. Refer to applicable rules1 for

lesser EIRP exposures.

Appropriate warning signs must be properly placed and posted at the equipment site and access entries.

Installation by Professionals

This product is intended to be installed, used and maintained by experienced telecommunications personnel only.

Personnel qualified to install or maintain Licensed Microwave Radio Transmitters and Antenna Systems in the

United States of America, Canada or the European Union are normally qualified to install or maintain the

HR-11500 Microwave Linear Heterodyne Repeater.

This product has been evaluated to the U.S. and Canadian (Bi-National) Standard for Safety of Information

Technology Equipment, Including Electrical Business Equipment, CAN/CSA C22.2, No. 950-95 * UL 1950, Third

Edition, including revisions through revision date March 1, 1998, which are based on the Fourth Amendment to

IEC 950, Second Edition. In addition, this product was also evaluated to the applicable requirements in UL 1950,

Annex NAE.

WARNING - This unit is intended for installation in a Restricted Access location in accordance with

Articles 110-18, 110- 26, and 110-27 of the United States National Electric Code ANSI/NFPA 70.

This equipment should be installed in accordance with Article 810 of the United States National Electrical Code.

When installed, this equipment is intended to be connected to a Lightning/Surge

Protection Device that meets all applicable national Safety requirements. TO AVOID

INJURY, RISK OF FIRE, AND DAMAGE, DO NOT CONNECT THIS PRODUCT

DIRECTLY TO AN ANTENNA, AND ENSURE THAT PROPER LIGHTNING

ISOLATION IS ALSO PROVIDED BETWEEN THIS UNIT AND OTHER EQUIPMENT.

Equipment is to be used and powered by the type of power source indicated on the marking label

only.

This product is intended to be connected to a 24 or 48 VDC power source that must be electrically

isolated from any AC sources and reliably grounded. Only a DC power source that complies with the

Safety Extra Low Voltage (SELV) requirements in the Standard for the Safety of Information

Technology Equipment, Including Electrical Business Equipment, CAN/CSA C22.2, No. 950-95 *

UL 1950, Third Edition, can be used with this product. A 15-Amp circuit breaker is required at the

power source. In addition, an easily accessible disconnect device should be incorporated into the

facility wiring. Always use copper conductors only for all power connections.

1 US FCC Office of Engineering and Technology Bulletin 65 provides guidance for radiation hazards.

2 SNMP: Simple Network Management Protocol; normally transmitted as packets (IP) over Ethernet,

R-

-1

— Contents HR-11500 Operations Manual

WARNING - This equipment is intended to be grounded. If you are not using the power supply

provided by Peninsula Engineering Solutions, you will need to connect the grounding conductor of

your power source to the grounding terminal located on the bottom of the unit; or, connect a

grounding conductor between the unit’s ground terminal and your ground point. For safe operation,

always ensure that the unit is grounded properly as described in this manual.

Do not connect or disconnect the power cable to the equipment when the other end of the cable is

connected to the dc power supply.

Servicing of this product should be performed by trained personnel only. Do not disassemble this

product. By opening or removing any covers, you may expose yourself to hazardous energy parts.

Incorrect re-assembly of this product can cause a malfunction, and/or electrical shock when the unit

is subsequently used.

Do not insert any objects of any shape or size inside this product while powered. Objects may contact

hazardous energy parts that could result in a risk of fire or personal injury.

Do not spill any liquids of any kind inside this product.

Rear heatsink fins are provided for cooling. To protect this product from overheating, do not cover or

block any of the fins except for the rear mounting bracket.

Always ensure sufficient amount of space is provided above and below this product.

Considerations should be given to the mechanical loading of the mounting supports and the

equipment to avoid potential hazards.

If this product is to be powered from the same source as other units, ensure that the power supply

circuit is not overloaded.

When installed in a rack, always ensure that proper airflow is provided for this product.

The maximum ambient temperature for this product is 50°C. When installed in a closed or multi-unit

rack, consideration should be given to installing this equipment in an environment compatible with the

maximum ambient temperature.

Protection from RF Burns

It may be hazardous to look into or stand in front of an active antenna aperture. Do not stand in front of or look

into an antenna without first ensuring that the associated radio transmitter or transmitters are switched off. Do not

look into open waveguides when the radio transmitter is active.

Risk of Personal Injury from Fiber Optics

DANGER: Invisible laser light radiation. Avoid direct eye exposure to the end of a fiber, fiber

cord, or fiber pigtail. The infrared light used in fiber optics systems is invisible, but can cause

serious injury to the eye.

WARNING: Never touch exposed fiber with any part of your body. Fiber fragments can enter the skin and are

difficult to detect and remove.

Warning – Parts of this device are classified as unintentional radiators

This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This

device may not cause harmful interference, and (2) this device must accept any interference received, including

interference that may cause undesired operation.

Proper Disposal

The manufacture of the equipment described herein has required the extraction and use of natural resources.

Improper disposal may contaminate the environment and present a health risk due to the release of hazardous

substances contained within. To avoid dissemination of these substances into our environment, and to lessen the

demand on natural resources, we encourage you to use the appropriate recycling systems for disposal. These

systems will reuse or recycle most of the materials found in this equipment in a sound way. Please contact your

supplier for more information on the proper disposal of this equipment.

R-

-1

HR-11500 Operations Manual Contents — iii

Contents

Safety Precautions ................................................................................................................................................. i

Radio Frequency Radiation Hazard .................................................................................................................. i

Installation by Professionals .............................................................................................................................. i

Protection from RF Burns ................................................................................................................................ ii

Risk of Personal Injury from Fiber Optics ......................................................................................................... ii

Warning – Parts of this device are classified as unintentional radiators ........................................................... ii

Proper Disposal ............................................................................................................................................... ii

Chapter 1. Overview .............................................................................................................................................. 1

General Information ......................................................................................................................................... 1

Applications .............................................................................................................................................. 1

Features ................................................................................................................................................... 1

Functional Description ..................................................................................................................................... 2

Basic Repeater ......................................................................................................................................... 2

Channel Selection ..................................................................................................................................... 2

Squelch Operation .................................................................................................................................... 3

Power Amplifier and ALC Adjustment ....................................................................................................... 3

Directional Coupler ................................................................................................................................... 3

Power Supply ............................................................................................................................................ 3

Alarm Reporting ........................................................................................................................................ 4

Licensing .......................................................................................................................................................... 5

Technical Specification Summary .................................................................................................................... 6

Channel Plans ........................................................................................................................................ 10

Ordering Information ............................................................................................................................... 13

System Options and Assembly Part Number .......................................................................................... 14

Technical Services ......................................................................................................................................... 24

Contacting Peninsula Engineering Solutions ................................................................................................. 24

Chapter 2. Installation Preparation ................................................................................................................... 25

Installation Overview ...................................................................................................................................... 25

Receipt and Inspection of the HR-11500 Heterodyne Repeater .................................................................... 25

Installation Equipment .................................................................................................................................... 27

Accessory Kit .......................................................................................................................................... 27

Pre-Installation Site Review ........................................................................................................................... 28

Chapter 3. Mounting the Antennas ................................................................................................................... 31

Mount Antennas ............................................................................................................................................. 31

Antenna Types ........................................................................................................................................ 31

Antenna Alignment ......................................................................................................................................... 31

Coarse Alignment ................................................................................................................................... 31

Fine Alignment using test radios ............................................................................................................. 31

Alternative Fine Alignment using heterodyne repeater level measurements........................................... 32

Antenna Feedlines ......................................................................................................................................... 32

Feedline Installation ................................................................................................................................ 33

Lightning Protection ................................................................................................................................ 34

Sweeping the Antenna Feedlines ........................................................................................................... 34

Chapter 4. Mounting the HR-11500 Repeater .................................................................................................. 35

Installation Overview ...................................................................................................................................... 35

Mounting Associated Equipment and Space Planning ................................................................................... 36

Mounting the Repeater .................................................................................................................................. 37

Earth, Ground, and Lightning Protection ........................................................................................................ 39

IF Connections ............................................................................................................................................... 41

R-

-1

— Contents HR-11500 Operations Manual

Chapter 5. Equipment Tests ............................................................................................................................... 43

Overview ........................................................................................................................................................ 43

Test Equipment Required .............................................................................................................................. 43

Configuring the Heterodyne RF Module ......................................................................................................... 43

Configuring DC Power ................................................................................................................................... 45

Applying Power to the Heterodyne Repeater ................................................................................................. 47

Transmit Power Adjustment ........................................................................................................................... 49

To measure and adjust PA output power: ............................................................................................... 49

Receive and Transmit Attenuator Pads ......................................................................................................... 51

Pad Installation: ...................................................................................................................................... 51

ACU – SNMP Network Configuration ............................................................................................................. 51

Radio Link Tests ............................................................................................................................................ 51

Chapter 6. ACU – SNMP Module Setup ............................................................................................................ 53

Network Setup ............................................................................................................................................... 53

Accessing the HR-ACU via the Web Page User Interface ............................................................................. 53

Settings Tabs ................................................................................................................................................. 55

Device Status Screen ............................................................................................................................. 56

General Settings Screen ......................................................................................................................... 57

Networking Settings Screen .................................................................................................................... 59

Events Screens ....................................................................................................................................... 60

Alerts Screen .......................................................................................................................................... 64

Administration Screen ............................................................................................................................. 67

Resetting Defaults .......................................................................................................................................... 68

Settings Keys ................................................................................................................................................. 68

Chapter 7. Maintenance and Troubleshooting ................................................................................................ 69

Routine Maintenance ..................................................................................................................................... 69

Administrative Requirements ......................................................................................................................... 70

Troubleshooting ............................................................................................................................................. 70

Heterodyne RF Module Replacement ............................................................................................................ 74

Reference Oscillator Replacement ................................................................................................................ 75

ACU – SNMP Module Replacement .............................................................................................................. 76

DC/DC Converter Power Supply Assembly Replacement ............................................................................. 77

Keeping Spares ............................................................................................................................................. 77

Returning the Heterodyne Repeater Equipment for Repair ............................................................................ 78

Product Warranty ........................................................................................................................................... 78

Appendix .............................................................................................................................................................. 81

R-

-1

HR-11500 Operations Manual Contents — v

Figures

Figure 1 Mechanical Layout, HR-11500 Front View Module Locations ....................................... 16

Figure 2 Mechanical Layout, HR-11500 Side View, Note: Base Skirt is included on 090-0294-04

enclosures. ............................................................................................................................ 17

Figure 3 Mechanical Layout, HR-11500 Bottom View I/O Connections, using 090-0294-03

Enclosure ............................................................................................................................... 18

Figure 4 Mechanical Layout, HR-11500 Bottom View I/O Connections, using 090-0294-04

Enclosure ............................................................................................................................... 19

Figure 5 Block Diagram, 1+0, Heterodyne Repeater.................................................................... 20

Figure 6 Block Diagram, 1+0, Heterodyne Terminal with External Modem ................................. 20

Figure 7 Block Diagram, RF Unit, 1+0 Single Channel Duplex, Un-Equalized ............................ 21

Figure 8 Block Diagram, RF Unit, 1+0 Single Channel Duplex, Equalized .................................. 21

Figure 9 Block Diagram, Alarm Control Unit – SNMP .................................................................. 22

Figure 10 Media Converter, Ethernet Copper - Multi-Mode Fiber Optic ....................................... 22

Figure 11 DC Power Connection Diagram, 24V or 48V ............................................................... 23

Figure 12 Typical Heterodyne Repeater Station Installation ........................................................ 26

Figure 13 Enclosure Mounting Dimensions HR-11500, Single Channel Duplex ......................... 29

Figure 14 Heterodyne Repeater Installation on pipe mount ......................................................... 35

Figure 15 Heterodyne Repeater on pipe mount, rear view ........................................................... 36

Figure 16 Example of Solar and Wind Power Installation ............................................................ 37

Figure 17 Mounting Bracket attached to 4.5-inch Pipe ................................................................. 38

Figure 18 Suggested Mounting H-Frame ..................................................................................... 38

Figure 19 Location of Ground Lug on Heterodyne Repeater Enclosure ...................................... 39

Figure 20 Typical System Ground Rod ......................................................................................... 40

Figure 21 Wiring and Ground Connections, Power Distribution Assembly, ............................... 40

Figure 22 Heterodyne RF Module ................................................................................................ 43

Figure 23 Configuration Switches and Jumper ............................................................................. 44

Figure 24 DC Distribution Assembly and Battery Input Blocks ..................................................... 47

Figure 25 ACU - SNMP Module, Front Panel ............................................................................... 48

Figure 26 Heterodyne RF Module Connector Ports ..................................................................... 50

Figure 27 Opening ACU Status Screen ........................................................................................ 54

Figure 28 ACU Status Screen – Door Open ................................................................................. 56

Figure 29 ACU General Settings Screen ...................................................................................... 57

Figure 30 ACU Time and Date Set ............................................................................................... 58

Figure 31 ACU Networking Settings Screen ................................................................................. 59

Figure 32 ACU Events - Temperature Sensor .............................................................................. 60

Figure 33 ACU Events - Analog Settings Screen (Top) ............................................................... 61

Figure 34 ACU Events - Analog Screen, Conversions (Bottom) .................................................. 62

Figure 35 ACU Events - Contacts Settings Screen ...................................................................... 63

Figure 36 ACU Alert Settings, General Settings Screen .............................................................. 64

Figure 37 ACU Alerts Settings, Email Alerts Screen .................................................................... 65

Figure 38 ACU Alert Settings, SNMP Alerts Screen..................................................................... 66

Figure 39 ACU Administration Screen .......................................................................................... 67

Figure 40 ACU Rear Panel ........................................................................................................... 68

R-

-1

— Contents HR-11500 Operations Manual

Tables

Table 1 ATCU Typical Branching Losses – HR-11500 Models ...................................................... 8

Table 2 Recommended Transmit and Receive Power Levels per Modulation Type ..................... 9

Table 3 *Reserved* ....................................................................................................................... 10

Table 4 Channel Plan, US-FCC, 11 GHz, 30 MHz, 11G-2 – Primary Plan .................................. 10

Table 5 Channel Plan, Industry Canada, 11 GHz, 30 MHz, 11G-2 – Alternate Plan 1 ................ 11

Table 6 *Reserved* ....................................................................................................................... 12

Table 7 *Reserved* ....................................................................................................................... 12

Table 8 HR-11500 Microwave Linear Heterodyne Repeater Models ........................................... 14

Table 9 Coaxial Attenuator Pads .................................................................................................. 15

Table 10 Spare and Accessory Equipment .................................................................................. 15

Table 11 Recommended Installation Equipment .......................................................................... 27

Table 12 Accessory Kit ................................................................................................................. 27

Table 13 IF Cable Types ............................................................................................................... 41

Table 14 Configuration Settings, Tx Power and Squelch levels ................................................... 45

Table 15 DC Battery Configurations, A & B .................................................................................. 46

Table 16 DC Battery Configuration, A-Only Positive Voltage ....................................................... 46

Table 17 DC Battery Configuration, A-Only Negative Voltage ..................................................... 46

Table 18 ACU Conditions at power-up ......................................................................................... 48

Table 19 Alarm Matrix ................................................................................................................... 70

Table 20 System Troubleshooting ................................................................................................ 72

Table 21 HR-11500 Maintenance Record .................................................................................... 79

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 1

Chapter 1. Overview

General Information

The HR-11500 Microwave Linear Heterodyne Repeater, hereafter referred to as the HR-11500 (or

the repeater), is a low latency, linear, duplex, frequency shifting IF repeater for microwave point-to-

point networks. The HR-11500 may be used with any manufacturer's compatible 11-GHz radio

operating in the 10.7~11.7 GHz frequency range to provide an intermediate repeater. The HR-11500

is intended for all capacity applications typically found in 30 MHz channel bandwidth.

Applications

 Highly reliable 11-GHz, IF heterodyne repeater for longer, multi-hop microwave routes.

 Congested routes where different frequencies per hop are desired for interference coordination.

 Low Latency, physical layer, linear repeater. Enables long distance, low latency microwave routes.

 Radio terminal with external IF modem.

 Excellent performance with digital, or video microwave radios; channel capacity to 2688 PCM

(4 DS3 or 180 Mb/s), OC-3, STS-3, STM-1 (155.52 Mb/s), Internet Protocol (185 Mb/s), multiple

video or mixed traffic.

 Compatible with most manufacturers’ 11-GHz radio terminals.

Features

 Low Latency, Propagation Delay: 200 nanoseconds, 0.20 microseconds per repeater pair.

 Greater Linear Gain, >100 dB.

 Independent from antenna isolation limitations typical of RF on-frequency homodyne repeaters.

 Linear Power Amplifier RF output power up to +34 dBm, 2.5 Watt in digital service.

 Power consumption 130 Watts, at -48 VDC per unit.

 Wide range DC power input, suitable for longer cable runs.

 Redundant DC power inputs and power supplies.

 Compact and weather protected -- ideally suited for tower mounting near antennas.

 Environmentally protected aluminum, weathertight, lockable cabinet. No extra environmental

shelter required in most installations. Suitable for use at unimproved sites anywhere in the world --

Alaska to Saudi Arabia.

 Flexible cable connections: External Connectors or Conduit Entry.

 Receive AGC provided to correct input fades and adjust for varying input levels. Up-Fade

protection included for abnormal propagation.

 Transmit ALC provided to regulate output power and reduce overload.

 Adaptable to new radio modulations and capacities as technology advances.

 Alarm system with SNMP over Ethernet remotely monitors the repeater.

 Equipped with directional couplers for in-service RF output power measurements.

 Conforms to standard frequency plans, US-FCC, CDN-IC, ITU-R.

 Very reliable, greater than 100,000 hours MTBF for duplex repeater pair.

 Available as a self-contained heterodyne repeater for use with customer-furnished antenna and

power equipment or as a complete package including repeater, antenna, photovoltaic modules,

battery charger and batteries.

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

Functional Description

1. The HR-11500 assembly is an IF through repeater designed for medium to heavy route tandem

applications that benefit from low latency. Little alignment is required, and the use of highly

reliable components and minimum active circuitry eliminates most subsequent maintenance. The

repeater assembly consists of an equipment mounting panel and heatsink, contained in an

aluminum, weatherproof, enclosure. In most applications, the complete assembly is pipe-frame

or tower-mounted. Front, side and bottom views of the repeater are shown in Figures 1, 2 and 3.

2. In addition to the HR-11500 repeater assembly, Peninsula Engineering Solutions offers

accessory equipment consisting of antennas and mounting hardware, waveguide, and complete

site power supply systems. The recommended antennas are solid or high performance types

chosen per application.

Basic Repeater

3. The HR-11500 heterodyne repeater receives 11 GHz microwave signals starting with an RF to

IF, double-conversion, low noise amplifier/down-converter unit. At 140 MHz 2nd IF, signals are

amplified and bandpass filtered. The IF includes automatic gain control, AGC, to compensate for

variable input levels and propagation fading. In repeater applications, the 140 MHz IF output

signal is connected to the IF input of the outbound HR unit via an external cable. In the transmit

section of the HR-11500, the 140 MHz IF signal is moved to 11 GHz in a double-conversion,

up-converter unit. A linear power amplifier follows the up-converter. The Level 4 linear power

amplifier is rated 10 Watts at 1 dB gain compression point, GCP.

4. Bandpass filters and circulators, which form a duplexer network, direct the received signal to the

LNA/down-converter and combine the power amplifier output with the received signal to a

common antenna port for transmission (see Figures 4 to 7). These filters are located in the

antenna coupling unit, ATCU, and mounted at the inside top of the enclosure. The heterodyne

repeater supports frequency division duplex, FDD, radio link systems where separate frequencies

are used in each direction.

5. A Delay Equalizer is added to the receive waveguide filter assembly to correct for slope and

parabolic group delay introduced by the bandpass filters and branching networks. Equalized

repeaters are recommended for high capacity systems and tandem repeater applications.

6. A CPR90G, waveguide flange, mounted on top of the enclosure, provides duplex 11 GHz RF

connection to antenna feedlines.

7. An attenuator pad may be added to reduce the receive signal to approximate the recommended

input level. An attenuator pad may be added to reduce transmit levels to less than can be

internally set (+17 dBm at flange). Transmit pads may be required for very short hops for

regulatory compliance. Pads are mounted on input of LNA/down-converter and output of the

power amplifier. Nominal input and output power levels for various repeater channel

configurations are listed at in Technical Summary following this section.

Channel Selection

8. Receive and transmit bandpass filters are fixed tuned to the assigned channels. These channels

are further selected using the rotary switches in the control section of the heterodyne RF module.

These settings program the synthesized local oscillators per the channel plan associated with

each heterodyne RF module. See Ordering Information and Spares for details on heterodyne RF

modules. Channel frequencies must be known when the factory order is placed.

9. When operating as an IF thru repeater, it is possible to have different frequency bands per radio

hop. The HR equipment at the repeater station may be mixed bands, i.e. 11 GHz and Upper

6 GHz or Lower 6 GHz and 11 GHz. The HR units interconnect at 140 MHz IF.

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 3

Squelch Operation

10. The heterodyne RF module includes a squelch function. This function will disable the following

transmit power amplifier and block all transmit signals when active. The squelch is driven by the

receive signal level, RSL. When the RSL is less than the set point, the squelch activates. The

squelch may be disabled or set in 15 each – 1 dB steps. Squelch control signal runs from the

140 MHz IF output to the 140 MHz IF input on the outbound transmit repeater unit. If the

connecting IF cable is disconnected or does not pass DC, the squelch will become active. The

squelch may be disabled if required.

Power Amplifier and ALC Adjustment

11. In digital radio applications, in order to maintain linearity over the entire signaling envelope, the

transmit power amplifier operates at a reduced average power level to meet the output power

level requirement as shown in Technical Summary. The power amplifier is part of the heterodyne

RF module. There is a field-adjustable switch for setting the transmit power amplifier level. The

settings are: 16 each - 1 dB steps. The recommended transmit power levels have adequate

margin for tandem repeater station applications. Single repeater applications may operate at 1 to

2 dB increased power levels.

Directional Coupler

12. A directional coupler, built into the power amplifier, provides a signal monitor point, “SAMPLE

PORT - RF MON”. This point allows in-service measurement of transmit output power. The

monitor point is calibrated for calculating the actual RF output power at the power amplifier and

then, at the antenna port flange. When measuring transmit power, the power meter reading

obtained, plus the loss (in dB) marked at the monitor point, minus the branching filter loss (in dB)

marked on the antenna coupling unit, ATCU, equals actual antenna port transmit output power.

Example 1 Amplifier Output

Example 2 Antenna Port Output

Power Meter indication

+15.0 dBm

Power Meter indication

+15.0 dBm

Cal Loss at RF MON

+19.0 dB

Cal Loss at RF MON

+19.0 dB

Power Amplifier Output =

+34.0 dBm

Tx ATCU Loss

- 2.5 dB

Antenna Port Output =

+31.5 dBm

Power Supply

13. External DC power supply operates the heterodyne repeater. Power supplies may be 24 VDC or

48 VDC. Either polarity is supported and is configured internal to the heterodyne repeater.

Redundant, “A & B” battery power supplies are supported. Redundant selection is automatic.

Operation from single “A” battery is permitted; internal power converters then share the single DC

power input.

14. In areas where commercial power is available, an AC power supply can be provided. Typical

power supplies are AC/DC rectifier/battery charger type with station battery. Although one AC

power supply will provide ample current to power the repeater station, dual AC power supplies

are recommended for greater reliability. The recommended dual AC power supply system also

contains two rectifier/chargers and two sets of standby battery to provide power during AC power

failures. Each battery is float charged while the power supply is on and has 100 Amp-hours as

standard capacity. Additional batteries can be purchased if needed. The size of the battery plant

is determined by station load and autonomy objective. System engineering will normally perform

this analysis during planning and design phase.

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

15. The heterodyne repeater station may be powered from alternative energy sources such as solar

photovoltaic arrays and wind turbine generators with battery plant. Storage batteries and

photovoltaic modules are selected on the basis of the capacity across the temperature range and

during periods when the output from the solar PV array is low or not available. Controllers are

used with the solar array to efficiently charge the batteries without overcharging. Peninsula

Engineering Solutions can determine the solar and battery capacity. The location of the site

should be specified when requesting assistance.

16. In locations where commercial power is not available and solar panel charging is impractical,

then alternative power sources such as thermal-electric generator, TEG, fuel cell or motor

generator are available. Power sources may be used in combination to create hybrid power

solutions capable of operating in very demanding applications. In such applications, the battery

installation should be given an environmental shelter according to the manufactures’

recommendations. Battery plant temperatures above and below nominal (+20C ~ +25C) can

reduce capacity and usable life. Contact Peninsula Engineering Solutions for assistance in

designing the best power supply system.

Alarm Reporting

17. The HR-11500 heterodyne repeater includes an alarm system to remotely monitor the repeater

station. Conditions that are typically monitored are listed below:

Standard Telemetry:

a) Heatsink Temperature

b) A Battery Voltage

c) B Battery Voltage

d) RSL, RSSI, dBm

e) Tx Power, Watts

Standard Alarm Points:

f) Heatsink Temperature Low and High

g) A and B Battery Low and High Voltage

h) Squelch Active

i) RSL Low and High Levels

j) Tx RF Output Low and High Power

k) Heterodyne RF Module DC Alarm

l) Enclosure Door Open

18. Alarm indications are sent as SNMP2 traps over Ethernet/IPv43 out-of-band data transport.

Ethernet connections can be either ETH on copper (standard) or ETH on multi-mode fiber optic

cable (optional). A standard MIB is provided that may be adapted to particular Network

Management System, (NMS) applications.

19. Status of each heterodyne repeater can be observed on a web-browser screen generated by the

ACU-SNMP unit. SNMP SETS and GETS are also supported and are defined in the MIB.

A duplex Ethernet/IP connection is required.

20. Alarm data concentration and transport is not included in the HR-11500 equipment. Such

equipment is typically configured for the project application. Contact Peninsula Engineering for

more information.

21. The ACU module includes an event sensor expansion port. Custom requirements such as

temperature and humidity sensor can be provisioned using this port.

2 SNMP: Simple Network Management Protocol; normally transmitted as packets (IP) over Ethernet,

(ETH) networks.

3 IP: Internet Protocol, packet data and addressing scheme.

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 5

Licensing

All owners of the HR-11500 should consult with the appropriate local and national agencies for

information about licensing.

US FCC ID

QFT-HR-11500

Applicable FCC Rule Parts

101 C; 2 C, I, J; 15 B

Applicable IC Regulations

SRSP 310.7

Emission Designator

Same as terminal radio or modem;

typically 30M0D7W for 30 MHz channel

bandwidth digital applications

Power Output

0.050 ~ 2.0 Watts (per modulation and

application)

Frequency Range

10,700.0 ~ 11,700.0 MHz

Frequency Stability (note 2)

0.0025% per unit, 0.010% per modulation

section with terminal equipment

Modulating Frequency, Data Rate

Dependant on terminal radio or modem

equipment

Licensing Notes:

1. The HR-11500 series can be used with any compatible 11-GHz radio or modem equipment.

2. The heterodyne repeater meets 0.0025% stability with zero error sources. In repeater

applications, US-FCC allows a maximum frequency tolerance of 0.010% to allow for

tolerance of the terminal equipment and accumulations of tandem repeater stations over a

modulation section. Modulation sections are typically limited to 5 hops, 4 tandem HR-11500

IF repeater stations plus 2 terminal stations.

MODEL: HR-11500

PENINSULA ENGINEERING SOLUTIONS, INC.

FCC ID: QFT-HR-11500

This transmitter complies with Part 101 of the FCC Rules.

This device complies with Part 15 of the FCC Rules. Operation is subject to the

following two conditions: (1) This device may not cause harmful interference,

and (2) this device must accept any interference received, including

interference that may cause undesired operation.

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

Technical Specification Summary

General

Frequency Range4

10.700 ~ 11.700 GHz

Receive Levels, Down Converter Input5

-75 dBm minimum rated, -80 dBm typical

-25 dBm maximum rated

Receive AGC

45 dB down fade, 5 dB up fade; minimums

Squelch Range

-75 dBm to -61 dBm in 1 dB steps, and [Disable]

Noise Figure, Down Converter Input

3.5 dB6 at weak signal, 20 dB at strong signal

Transmit Power, Level 4, Power Amplifier Output7

+34 dBm8 maximum rated, see Table 2

+19 dBm minimum rated

ATCU Branching Losses, Rx and Tx

See Table 1 for configurations

Frequency Stability

±0.0025% per repeater pair.

Typical ±0.000 050%

Antenna Connections, ATCU

Antenna Port, Duplex T/R

CPR90G, Contact, Gasket Flange. At top of unit.

Waveguide Type

WR90

Return Loss, Antenna Port

 24 dB across assigned channels

Intermediate Frequency Interface

Intermediate Frequency, Receive and Transmit

140.000 MHz

Connectors, Impedance

External Type N(f), 50 Ohm Coaxial

Internal SMA(f), 50 Ohm Coaxial (conduit entry)

Return Loss

> 10 dB, 140 MHz ± 20 MHz

Receive Output Level9

-2 dBm ± 2 dB for all modulations

Transmit Input Level

0 ~ -15 dBm for all modulations, auto adjust

Receiver to Transmitter IF Loss

0 ~ 10 dB, auto adjust

Frequency Plan

HR Equipment Channel Bandwidth, 30 MHz

28 MHz Flat, 40 MHz @ -6 dB

Assigned Channel Bandwidth

30 MHz

T-R Spacing

130 MHz minimum

T-T Spacing on common feeders

80 MHz minimum

T-T Spacing on separate feeders

30 MHz minimum

Channel Response: Delay Equalized, 30 MHz channel bandwidth

Amplitude

± 0.5 dB, f0 ± 14 MHz

Group Delay Variation

10 nsec P-P, f0 ± 14 MHz

Propagation Delay, Signal Latency, 1-Way10

200 ± 50 nsec at f0

4 See ordering information for specific configuration and channel plan part numbers.

5 Not including receive antenna coupling unit loss.

6 Guaranteed noise figure is 0.5 dB greater.

7 16QAM, not including transmit antenna coupling unit loss. See Table 3 for more levels.

8 Guaranteed transmit power is 1 dB less.

9 IF Output CW levels are typically 2 dB less than for QAM signals.

10 Measured in IF repeater configuration from equipment waveguide antenna port in to waveguide antenna port

out. Does not include external IF cables, feedlines or antennas.

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 7

Channel Response: Un-Equalized, 30 MHz channel bandwidth

Amplitude

± 2.0 dB, f0 ± 14 MHz

Group Delay Variation

20 nsec P-P, f0 ± 14 MHz

Propagation Delay, Signal Latency5

180 ± 50 nsec at f0

Alarms and Monitored Points, ACU-SNMP

Item Name

Short Name

Alarm Point

Clear

Power

POWER

12.5V DC Bus < 10V

LED Dark

12.5V DC Bus > 10V

Green w/ Blink @ 5 Sec

Sensor11

SENSOR

Event Sensor

Disconnected12 Dark

Event Sensor Connected.

Green

Ethernet

ETH

ETH Disconnected

LED Dark

ETH Active

Green w/ Flash @ PKT

Summary Alarm

ALARM

Any Alarm or OOR

Red

All Alarms Clear

LED Dark

Heatsink Temperature

5°C > T > 50°C

5°C < T < 50°C

Heterodyne Module Current

HET DC

-20% > I > +20%

Red

-20% < I < +20%

LED Dark

Squelch Condition

SQL

Active – PA OFF

Red

Inactive

LED Dark

Local Oscillator

Synthesizers UnLocked

Red

Synthesizers Locked

LED Dark

Enclosure Door

DOOR

Door Open

Red

Door Closed

LED Dark

Battery A, Volts

BATT A

21.0 V > VA24 > 28.5 V

42.0 V > VA48 > 57.0 V

Red

21.0 V < VA24 < 28.5 V

42.0 V < VA48 < 57.0 V

LED Dark

Battery B, Volts

BATT B

21.0 V > VB24 > 28.5 V

42.0 V > VB48 > 57.0 V

Red

21.0 V < VB24 < 28.5 V

42.0 V < VB48 < 57.0 V

LED Dark

Receive Signal Level, dBm13

RSL

-70 dBm > RSL > -30 dBm

Red

-70 dBm < RSL < -30 dBm

LED Dark

Transmit PA RF Power Level, W14

TX PWR

0.1 W > PWR > 2.5 W

Red

0.1 W < PWR < 2.5 W

LED Dark

Alarm Control Unit, ACU-SNMP, Communications

Event Notification Message Protocols

SNMPv1 Traps, SNMPv2c SETS, GETS

SMTP E-Mail

User Interface

Web Page Server, HTTP (not secure, SSL)

Ethernet Connections

(mating connectors and cables not included)

RJ-45 Copper, 10/100 Mb/s, 10/100BaseT to Bulgin

panel mounted connector: Buccaneer® IP68.

Mating Bulgin connectors: Buccaneer® IP68;

PX0836/(2-5m length) Patch Cord, PX0834/A for PUR,

shielded cable or PX0834/B for 3.5~8mm cables.

Fiber Optic, Multi-Mode with optional Media Converter

Module. Internal ST 62.5/125µm Connector Pair, Tx, Rx.

External LC 62.5/125 µm duplex panel mounted

connector: Siemon IP66/IP67.

Mating Siemon connector: XPLC2-MM.

100BaseFX 1300 nm, 2 km service distance rated.

11 Optional Event Sensors may be provisioned. External Temperature and Humidity Sensor is the only currently

available selection.

12 OOR: Out of Range. See specific sensor limit settings.

13 RSL Alarm limits can be changed to meet customer application requirements.

14 Tx Power Alarm limits can be changed to meet customer application requirements.

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

Controls

Receive Squelch Drive

20 mA current sink on IF OUT.

Transmit Power Amplifier Enable

500 Ohms maximum shunt to ground on IF IN.

Electric Power Requirements

Power Configuration

A & B Battery Inputs, Auto-Redundant

Nominal Voltage

24 or 48 VDC, see ordering options

Voltage Range

20 ~ 30 VDC

40 ~ 60 VDC

Polarity

Positive or Negative Ground, configurable

Power Consumption, Level 4

140 W typical, 165 W maximum per unit.

280 W typical, 330 W max per repeater station.

DC Connections

External Bulgin 3-Pin Jacks. Mating 3-socket Plug

provided. Wire range 14 ~ 12 AWG. Cord 6~8 mm

Internal 3-circuit compression Terminal Blocks.

Wire range 14 ~ 10 AWG. Conduit entry.

Environmental Conditions

Housing Type

Weather Tight Aluminum

Ambient Temperature

-20°C ~ +50°C

Relative Humidity

90% (housing internal)

100% (housing external)

Altitude

15,000 Feet, 4600 meters

Reliability

MTBF

200,000 hours per HR unit

100,000 hours per HR repeater station (pair)

MTTR

40 minutes, on-site

Dimensions: HR Unit

Height, without connectors

20.00 inches, 508 mm

Height, including antenna port and connectors

23.00 inches, 585 mm

Width, door closed

18.00 inches, 457 mm

Depth, including mounting bracket

21.55 inches, 547 mm

Weight, max with all options

72 lb, 33 kg

Table 1 ATCU Typical Branching Losses – HR-11500 Models

MODEL

MHz

Delay

Equalized

Receive Branch Loss,

Typical*, dB

Transmit Branch Loss,

Typical*, dB

HR-11500-41

HR-11500-42

2.8

HR-11500-51

HR-11500-52

Yes

3.7

2.8

Note: * Guaranteed branching losses are 1 dB greater.

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 9

Table 2 Recommended Transmit and Receive Power Levels per Modulation Type

Modulation Type15

Level 4

PA Output16

Minimum RSL17 at

Down-Converter Input

System

Gain18

FSK, MSK, BPSK

34.0 dBm

-75.0 dBm

102.5 dB

QPSK, OQPSK, 4PSK, 4QAM

34.0

-75.0

102.5

8PSK

34.0

-75.0

102.5

16QAM

32.0

-75.0

100.5

16APSK

32.0

-75.0

100.5

32APSK

30.0

-74.0

97.5

32QAM

30.0

-73.0

96.5

32TCM

29.0

-73.0

95.5

64QAM

28.0

-70.0

91.5

64TCM

28.0

-70.0

91.5

128QAM

26.0

-67.0

86.5

128TCM

26.0

-67.0

86.5

Note: Peninsula Engineering Solutions may change performance specifications where necessary to

meet industry requirements.

See Heterodyne Repeater System Applications Considerations for additional guidance.

15 Modulations listed are the most popular types. List is not exclusive. If a modulation is not listed, contact the

company for specific details.

16 Transmit power set point is reduced as the modulation becomes more complex.

This power level provides adequate linearity as required by the system performance objectives. Multi-hop

tandem applications may require additional power reduction to manage IMD summation depending on radio

characteristics. Single repeater applications may increase power by 1 to 2 dB depending on radio

characteristics. The ALC rotary switch is used to set the output power level. To calculate the repeater’s

output power at the antenna port flange, take the power amplifier level output listed in this table, then

subtract the transmit branch filter loss for the specific configuration from Table 1.

For Example: Level 4 Power Amplifier Output = +32 dBm for 16QAM, Tx Branch Filter Loss = 2.5 dB,

Output power at antenna port flange = +32.0 – 2.5 = +29.5 dBm.

17 RSL is typical for radio capacities found in 30 MHz channels, 21 ~ 27 MSymbols/sec. Actual RSL depends on

terminal radio noise figure and associated modulation and traffic capacity. RSL at antenna port is determined

by adding Rx Branch Filter Loss from Table 1 to value in this table. Recommended -75 dBm RSL minimum

considers resulting transmit noise density.

For Example: Down-Converter RSL = -75 dBm for 16QAM, Rx Branch Filter Loss = 3.5 dB, RSL at antenna port

flange = -75.0 + 3.5 = -71.5 dBm.

18 At Antenna Port, assumes 3.7 dB Rx Loss, 2.8 dB Tx Loss.

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

Channel Plans

Each HR-11500 is factory configured for the desired channel plan and frequency pair. The

Heterodyne RF Module is set to the assigned frequency pair using a pair of rotary switches

internal to the module. The switch positions for each channel pair, Go and Return, are shown in the

tables below.

Table 3 *Reserved*

*Reserved*

Table 4 Channel Plan, US-FCC, 11 GHz, 30 MHz, 11G-2 – Primary Plan

Channel Plan

11 GHz, 30 MHz

US-FCC 101, 30 MHz BW

Short Name

11G-2

Frequency Band

10,700 ~ 11,700 MHz

Alt Band Jumper

None

Regulatory

US-FCC

Channel

Bandwidth

30 MHz

T-R Separation

490.0 and 500.0 MHz

Channel

Separation

30.0 and 40.0 MHz

Channel

Setting

Channel Pairs, MHz

Channel

Setting

Channel Pairs, MHz

MSB

LSB

Receive

Transmit

MSB

LSB

Receive

Transmit

10715.00

11215.00

10715.00

10755.00

11245.00

10755.00

10795.00

11285.00

10795.00

10835.00

11325.00

10835.00

10875.00

11365.00

10875.00

10915.00

11405.00

10915.00

10955.00

11445.00

10955.00

10995.00

11485.00

10995.00

11035.00

11525.00

11035.00

11075.00

11565.00

11075.00

11115.00

11605.00

11115.00

11155.00

11645.00

11155.00

11185.00

11685.00

11185.00

Channels highlighted are the odd pairs with 500 MHz T-R and 30.0 MHz T-T separation.

Primary Plan Jumper Setting = NONE

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 11

Table 5 Channel Plan, Industry Canada, 11 GHz, 30 MHz, 11G-2 – Alternate Plan 1

Channel Plan

11 GHz, 30 MHz

IC SRSP 310.7, 30 MHz BW

Short Name

11G-2

Frequency Band

10,700 ~ 11,700 MHz

Alt Band Jumper

AltBand1

Regulatory

Industry Canada

Channel

Bandwidth

30 MHz

T-R Separation

490.0 MHz

Channel

Separation

30.0 MHz

Channel

Setting

Channel Pairs, MHz

Channel

Setting

Channel Pairs, MHz

MSB

LSB

Receive

Transmit

MSB

LSB

Receive

Transmit

10725.00

11215.00

10725.00

10755.00

11245.00

10755.00

10785.00

11275.00

10785.00

10815.00

11305.00

10815.00

10845.00

11335.00

10845.00

10875.00

11365.00

10875.00

10905.00

11395.00

10905.00

10935.00

11425.00

10935.00

10965.00

11455.00

10965.00

10995.00

11485.00

10995.00

11025.00

11515.00

11025.00

11055.00

11545.00

11055.00

11085.00

11575.00

11085.00

11115.00

11605.00

11115.00

11145.00

11635.00

11145.00

11175.00

11665.00

11175.00

Alternate Plan Jumper Setting = AltBand1

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

Table 6 *Reserved*

*Reserved*

Table 7 *Reserved*

*Reserved*

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 13

Ordering Information

The HR-11500 Heterodyne Repeater Assembly is ordered by specifying the system model number

HR-11500-XX and part number (Table 8). Attenuators (if required due to very strong input signal,

> -25 dBm) are provisioned by specifying their part numbers. Transmission engineering must be

completed before ordering because the necessary attenuator values are determined from the path

calculations. Part numbers are listed in Table 9.

When doing the initial system layout of a radio link which includes an HR-11500 Microwave

Heterodyne Repeater Assembly, several factors must be considered prior to ordering, to ensure

correct antenna connections and proper installation. Consider the following topics before ordering the

HR-11500 Microwave Heterodyne Repeater:

Repeater Transmit and Receive Frequencies

Repeater frequencies are coordinated with the adjacent terminal radios. See the block diagrams

for more detail. Orders cannot be accepted without firm frequencies. Peninsula Engineering can

assist in determining the frequencies and assignments.

Terminal Radio Modulation, Traffic Capacity and Repeater Transmit Power Level

Repeater transmit power levels are set based on the modulation and traffic capacity of the

adjacent terminal radios. Please include the modulation and traffic capacity details with the

purchase order. Peninsula Engineering will determine the proper transmit power level.

Modulations and traffic capacity beyond those listed in this manual may be possible to support,

contact Peninsula Engineering Solutions for more details.

Electric Power System

The repeater site power system should be detailed during the system design phase. Peninsula

Engineering Solutions can provide this design service and the power equipment. Power systems

may include: Solar, Wind, AC, TEG, Motor Generator, Fuel Cell or other power sources. All

power systems include a battery plant and associated charge control equipment. Battery capacity

must be adequate for the load, location and power source.

Antennas

The types and sizes of antennas required to meet the system requirements. Transmission

engineering can determine the antenna details. Transmission engineering and antennas are

available from Peninsula Engineering Solutions.

Feedlines

Type and length required for antenna connections (including jumper assemblies); note that

waveguide is available from Peninsula Engineering Solutions.

Mounting

Special requirements for the repeater and antennas specific to the intended tower or supporting

structure. The repeater normally mounts outdoors in its all-weather enclosure. Peninsula

Engineering Solutions can provide construction engineering support.

Alarm Components

The alarm equipment provides SNMP reporting over Ethernet on copper or multi-mode fiber.

It may be desirable to combine the reporting from multiple HR units or other equipment on site for

further transmission to a Network Operations Center, NOC. Please refer to Applications Notes on

alarm management.

When ordering, specify a shipping destination and a billing address. Peninsula Engineering Solutions

returns an order acknowledgment with the scheduled shipping date. Each shipment includes an

equipment list showing the equipment ordered and shipped, including details about system and

equipment options.

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

System Options and Assembly Part Number

Table 8 HR-11500 Microwave Linear Heterodyne Repeater Models

Standard

Assembly

Part

Number

Description

Battery

Voltage

Chan

Channel Plan19

HR-11500-41

900-0531-41

Single Channel Duplex Tx/Rx, 11G-2,

Un-Equalized, PA Level 4, 24VDC

24 VDC

30 MHz

BW, UE

11G-2: 11 GHz,

US-FCC, IC SRSP 310.7

10,700 ~ 11,700 MHz

30 MHz channel bandwidth

490/500/530 MHz

T-R spacing

30/40 MHz T-T spacing

HR-11500-42

900-0531-42

Single Channel Duplex Tx/Rx, 11G-2,

Un-Equalized, PA Level 4, 48VDC

48 VDC

HR-11500-51

900-0531-51

Single Channel Duplex Tx/Rx, 11G-2,

Delay Equalized, PA Level 4, 24VDC

24 VDC

30 MHz

BW, EQ

HR-11500-52

900-0531-52

Single Channel Duplex Tx/Rx, 11G-2,

Delay Equalized, PA Level 4, 48VDC

48 VDC

19 T-R, Transmit to Receive and T-T, Transmit to Transmit spacings represent the specific channel

plan raster. See HR-11500 equipment specifications for supported spacings and conditions.

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 15

Table 9 Coaxial Attenuator Pads

Part Number

Attenuation

Part Number

Attenuation

149-0128-01

1.0 dB

149-0128-11

11.0 dB

149-0128-02

2.0 dB

149-0128-12

12.0 dB

149-0128-03

3.0 dB

149-0128-13

13.0 dB

149-0128-04

4.0 dB

149-0128-14

14.0 dB

149-0128-05

5.0 dB

149-0128-15

15.0 dB

149-0128-06

6.0 dB

149-0128-16

16.0 dB

149-0128-07

7.0 dB

149-0128-17

17.0 dB

149-0128-08

8.0 dB

149-0128-18

18.0 dB

149-0128-09

9.0 dB

149-0128-19

19.0 dB

149-0128-10

10.0 dB

149-0128-20

20.0 dB

Coaxial Attenuator Pads: equipped with SMA male and female connectors and rated to 18 GHz and 1 Watt

average power. May be inserted in receive or transmit line for RF level coordination. Transmission engineering

will determine attenuator requirements.

Table 10 Spare and Accessory Equipment

Part Number

Description

090-1508-01

Heterodyne RF Module, Level 4, 11G-1

090-1508-02

Heterodyne RF Module, Level 4, 11G-2

090-1508-03

Heterodyne RF Module, Level 4, 11G-3

090-0410-01

Reference Oscillator Module, 10.000 MHz

090-0787-01

Alarm Control Unit (ACU) – SNMP, Ethernet

091-0501-02

Media Converter Kit, Ethernet to Fiber Optic Multi-Mode, ST-LC DX.

Kit includes: module, wiring harness, fiber cables, and installation materials.

090-0790-01

Media Converter Module, Ethernet to Fiber Optic Multi-Mode (module only)

090-0286-06

Power Supply, DC-DC Converter Assembly, 24VDC to +12.5VDC, 400W

090-0286-07

Power Supply, DC-DC Converter Assembly, 48VDC to +12.5VDC, 400W

087-1242-01

DC Distribution Sub-Assembly, 24V

087-1242-02

DC Distribution Sub-Assembly, 48V

142-0315-01

Connector, Circular, Plug, Flexible Cable Power 3 Pole, Socket, Screw, IP68

142-0317-02

Connector, Circular, Plug, Flexible Cable Ethernet CAT5E, IP68

142-0318-01

Connector, Plug, LC DX Fiber-Optic Multi-Mode, IP66/IP67

175-0025-05

Fuse, 15-Ampere, Blade Type, ATO, 32VDC (for 24V)

175-0025-04

Fuse, 7.5-Ampere, Blade Type, ATO, 80VDC (for 48V)

550-0530-01

Manual, Operations, HR-11500 Microwave Linear Heterodyne Repeater

Alarm information is in SNMP format and reports over ETH TCP/IP networks. Ethernet on copper may be

converted to Ethernet on fiber optic cables for transmission down a radio tower to a collection point.

Contact Peninsula Engineering Solutions for details and assistance.

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

Figure 1 Mechanical Layout, HR-11500 Front View

Module Locations

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 17

Figure 2 Mechanical Layout, HR-11500 Side View,

Note: Base Skirt is included on 090-0294-04 enclosures.

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

Figure 3 Mechanical Layout, HR-11500 Bottom View

I/O Connections, using 090-0294-03 Enclosure

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 19

Figure 4 Mechanical Layout, HR-11500 Bottom View

I/O Connections, using 090-0294-04 Enclosure

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

HR-11500 RFU HR-11500 RFU HETERODYNE

RF/IF MODULE

HETERODYNE

RF/IF MODULE

LNA,

DOWN CONVERTER,

IF SECTION

LNA,

DOWN CONVERTER,

IF SECTION

UP CONVERTER

POWER AMPLIFIER

UP CONVERTER

POWER AMPLIFIER

10 815.0 MHz

11 305.0 MHz

11 385.0 MHz

10 895.0 MHz

140 MHz IF

0-10 dB Loss

140 MHz IF

0-10 dB Loss

Figure 5 Block Diagram, 1+0, Heterodyne Repeater

EXTERNAL MODEM HR-11500 RFU HETERODYNE

RF/IF MODULE

LNA,

DOWN CONVERTER,

IF SECTION

UP CONVERTER

POWER AMPLIFIER

10 815.0 MHz

11 305.0 MHz

140 MHz IF

-2 dBm

140 MHz IF

0 ~ -15 dBm

DEMODULATOR

MODULATOR

ETH RJ-45

Figure 6 Block Diagram, 1+0, Heterodyne Terminal with External Modem

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 21

RECEIVER

LNA,

DOWN CONVERTER,

IF SECTION

TRANSMITTER

UP CONVERTER

POWER AMPLIFIER

10 815.0 MHz

11 305.0 MHz

140 MHz IF

RX OUT

140 MHz IF

TX IN

ANTENNA PORT

CPR-90G FLANGE

COMMON

FREQUENCY

REFERENCE

10 MHz

DC POWER

DISTRIBUTION

DC/DC

CONVERTER

DC/DC

CONVERTER

BATTERY A

BATTERY B

MEDIA CONVERTER

(OPTIONAL)

ACU - SNMP

4 2

FIBRE OPTIC

MULTI-MODE

CAT 5

COPPER

SUPERVISION

NMS

CHANNEL PAIR

SELECT

Figure 7 Block Diagram, RF Unit, 1+0 Single Channel Duplex, Un-Equalized

RECEIVER

LNA,

DOWN CONVERTER,

IF SECTION

TRANSMITTER

UP CONVERTER

POWER AMPLIFIER

10 815.0 MHz

11 305.0 MHz

140 MHz IF

RX OUT

140 MHz IF

TX IN

ANTENNA PORT

CPR-90G FLANGE

COMMON

FREQUENCY

REFERENCE

10 MHz

DC POWER

DISTRIBUTION

DC/DC

CONVERTER

DC/DC

CONVERTER

BATTERY A

BATTERY B

MEDIA CONVERTER

(OPTIONAL)

ACU - SNMP

4 2

FIBRE OPTIC

MULTI-MODE

CAT 5

COPPER

SUPERVISION

NMS

CHANNEL PAIR

SELECT

Figure 8 Block Diagram, RF Unit, 1+0 Single Channel Duplex, Equalized

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

ALARM CONTROL UNIT - SNMP

CONTACT

CLOSURE

POINTS

ANALOG

VOLTAGES

TEMPERATURE

TH SENSOR

(OPTIONAL)

PROCESSOR

SNMP

WEB UI

ETH RJ-45

DC REGULATORS +12V C

DC FAULT

SQUELCH

CONDITION

LO FAULT

DOOR SW

BATT A V

BATT B V

RSSI V

TX PWR V

Figure 9 Block Diagram, Alarm Control Unit – SNMP

MEDIA CONVERTER – ETHERNET COPPER : FIBER OPTIC MULTI-MODE

(OPTIONAL)

PROCESSOR

CONVERTER

TRANSCEIVER

ETH RJ-45

REGULATORS

+12V ± 0.5

POWER

A, B

STST

J3 TX

J4 RX

ALM

FAULT

ALARM

Figure 10 Media Converter, Ethernet Copper - Multi-Mode Fiber Optic

R-

-1

HR-11500 Operations Manual Chapter 1. Overview — 23

DC DISTRIBUTION ASSY

087-1242-01, -02

WHT/RED

ORN

BLK

GRN

TB-1

TB-2

1 2 3

P1 1 2 3 4

1 2 3 4

J7 P7

J8 P8

J9 P9

J10 P10

DC/DC

CONVERTER

S-

S+

DC/DC

CONVERTER

S+

S-

1 2 3 4

BATTERY A

24V

-or-

48V

BATTERY B

24V

-or-

48V

POS

NEG

GND

POS

NEG

GND

POS

NEG

GND

POS

NEG

GND

RED

WHT

BLU

P N

JP1

JP2

Figure 11 DC Power Connection Diagram, 24V or 48V

R-

-1

— Chapter 1. Overview HR-11500 Operations Manual

Technical Services

To supplement the manpower resources of service providers, Peninsula Engineering Solutions offers

the following technical services:

 Microwave Link design

 Power System design

 Site and construction surveys

 Project management

 Installation

 Providing accessories (antennas, waveguide, power equipment, and so on)

 Training

Quotations for technical services are available upon request.

Contacting Peninsula Engineering Solutions

Contact the Peninsula Engineering Solutions corporate headquarters for sales information or

technical assistance for the HR-11500 Microwave Linear Heterodyne Repeater, or any other of our

communications or related products.

Corporate Headquarters

Peninsula Engineering Solutions, inc.

39 Grand Canyon Lane

San Ramon, California 94582

United States of America

Telephone: +1 925 901-0103

Facsimile: +1 925 901-0403

Internet: http://www.peninsulaengineering.com/

E-Mail: info@peninsulaengineering.com

R-

-1

HR-11500 Operations Manual Chapter 2. Installation Instructions — 25

Chapter 2. Installation Preparation

Installation Overview

The HR-11500 is designed for indoor or outdoor installation and can be tower, wall or pole mounted.

The unit’s compact cabinet simplifies installation.

NOTE: Only qualified service or technical personnel should install and service the HR-11500.

Receipt and Inspection of the HR-11500 Heterodyne Repeater

Immediately upon receipt of the HR-11500 heterodyne repeater, unpack and inventory the contents

against the packing lists, including the contents of the accessory kit and any optional equipment

ordered with the unit—see Tables 8, 9, and 10. Contact Peninsula Engineering Solutions if any items

are missing.

Note: Retain the foam packing in place on the repeater to protect connections during movement,

rigging and mounting.

Inspect the unit and accessories thoroughly for shipping damage, especially for damage that may be

hidden by the packaging. Pay particular attention to the following:

 Bent or dented sheet metal

 Loose or broken components

 Damaged connectors and waveguide flanges

 Damaged or broken wiring or coaxial cables

 Missing or damaged contents of the accessory kit

 Missing or damaged optional equipment

Note any damage on the waybill and request that the delivery agent sign it for verification. Also, notify

the transfer company as soon as possible, submit a damage report to the carrier, and inform the

Customer Service Department of Peninsula Engineering Solutions in writing.

NOTE: Save original shipping crate and packing materials for any future transport of the unit.

If the HR-11500 repeater is to be stored for later installation or shipment, reseal the packaging of the

accessory kit and the repeater.

If power system batteries are to be stored for later installation, the batteries must be recharged

monthly and especially, prior to installation. Lead acid batteries stored without charging can degrade

to an un-usable condition and will not be covered under warranty.

R-

-1

— Chapter 2. Installation Instructions HR-11500 Operations Manual

The following figure illustrates a typical installation with external equipment.

A BATTERY

B BATTERY

SITE

GROUND

TWIST OR BEND

(IF NEEDED)

WAVEGUIDE

FEEDLINES

EAST

ANTENNA

WEST

ANTENNA

ALARM

FIBER PAIRS

UHF

TELEMETRY

ANTENNA

HR-11500HR-11500

A BATTERY

B BATTERY

DEHYDRATOR

IF COAX

SITE ALARM

MANAGEMENT

PRESSURE

WINDOW

Figure 12 Typical Heterodyne Repeater Station Installation

R-

-1

HR-11500 Operations Manual Chapter 2. Installation Instructions — 27

Installation Equipment

See the following table for a list of required installation equipment. Additional equipment may be

needed, depending on specific installation site requirements and optional accessories ordered.

Table 11 Recommended Installation Equipment

Equipment or Item

Function

Site Plan and Path Calculation documentation

To correctly configure the repeater to operate in the

microwave network.

1/8-inch small flat blade screwdriver

Used for wiring DC input power terminal blocks.

3/8-inch or ½-inch Ratchet

To drive sockets

7/16-inch or 3/8-inch socket or wrench

For repeater door clamp bolts.

Digital Voltmeter, 0 ~ 200 V

To test power connections and analog test points.

Clamp-On Current Meter or Probe, 0 ~ 100 ADC

To test power systems and loads.

Spectrum Analyzer, 10 MHz ~ 15 GHz†

For signal identification and alignment

Power Meter, Agilent (HP) 435B with 8481A Sensor*

To test RF power output.

Sweep test equipment, Anritsu SiteMaster™ S820D*

To test feedlines and antennas.

Antenna-Path Alignment Test Set, Pendulum

Instruments, XL Microwave Path Align-R™ 2241*

To align the antennas on path per hop.

Pressure Window, for CPR90G, 1 ea.

To seal HR for waveguide pressurization.

Coax Adapters, SMA M-F RT Angle, SMA(m) to N(f)

For power measurements at SMA ports.

Coax Adapters or cables, BNC(m) to DVM probes.

For Tx Power and RSSI Voltage measurements.

RF Test Jumper Cables, 50 Ohm, SMA(m), 2 ea.

For test equipment, length depends on application.

IF Test Jumper Cables, 50 Ohm, N(m), 2 ea.

For test equipment, length depends on application.

RJ-45 Ethernet Connectors, 2 ea†.

To build ACU Copper ETH cable (1 run per HR)

CAT-5 Ethernet Cable, 1 Run†.

To build ACU Copper ETH cable (1 run per HR)

Fiber Connectors, LC-MM Duplex, 2 ea†.

To build ACU F/O ETH cables (1 paired run per HR)

Multi-mode Fiber Optic cable, 1 Run†.

To build ACU F/O ETH cables (1 paired run per HR)

Mounting Hardware

To mount repeater and antennas.

Electrical Wiring Equipment (as needed)

To connect external systems to inputs and outputs.

Wrist Grounding Strap

To protect against static discharge.

*Equivalent substitutes may be used. †If necessary. Qty are per HR Unit, double for repeater station.

Note that the site plan and network engineering documentation is used during installation to refer to

the intended parameters of the project including gain settings, and antenna location. If necessary,

consult a network administrator for more information.

Accessory Kit Table 12 Accessory Kit

Part Number

Description

Quantity

550-0530-01

Heterodyne Repeater Operations and Maintenance Manual, CD-ROM

142-0315-01

Connector, Circular, Flex Cable 3 Socket, Screw Connections

175-0025-05

Fuse, 15-Amp, Blade Type ATO (included with 24V applications)

175-0025-04

Fuse, 7.5-Amp, Blade Type ATO (included with 48V applications)

137-0144-04

Cover, Waveguide, CPR90G

137-0166-03

Gasket, Half, Waveguide, CPR90G

137-0126-03

Cap, LDP 5/8-24 x .41 (IF Connector covers)

125-0002-02

Screw, FHP 82° Under Cut, 2-56 x .250 S/S (spares)

R-

-1

— Chapter 2. Installation Instructions HR-11500 Operations Manual

Pre-Installation Site Review

Each site should be thoroughly reviewed before any equipment is mounted. Site review should

include, but not necessarily be limited to, the following factors:

Weather

Determine whether environmental conditions necessitate special shielding of the repeater or

other equipment.

Security

Determine whether some type of barrier is needed to protect equipment and if a security light is

required.

Aviation

Review tower heights and obstruction lighting requirements as specified by the national aviation

authority, e.g. US-FAA, US Federal Aviation Administration or TC, Transport Canada. Normally

towers 200 Ft AGL and taller require obstruction lighting. Towers closer to airports have

additional lighting and marking requirements. See FAA AC 70/7460-1K. File NOTAM20 as

required during construction.

Optional Site Equipment

Determine whether additional site equipment, such as a convenience power outlet, pump,

generator, or light is required, and, if so, where equipment is to be located and whether special

enclosures for any equipment is required.

Wiring and Wiring Access

Determine if there are any special wiring requirements.

Cabinet Access

Determine whether there is enough room for the repeater door to open, once mounted.

The HR-11500 assembly can be mounted on a steel tower, on a steel pipe or square-rail frame, or on

a wall. The length of all power leads should be limited and the wire size adequate to minimize the

voltage drop. The repeater assembly, battery boxes, solar panels, and antennas should all be

mounted before any wiring is done. Mounting-hole dimensions for the repeater enclosure are shown

in Figure 13.

Prior to cutting to length and connecting the waveguide feedlines, verify which HR Unit’s frequencies

associates with each antenna port and associated terminal radio or repeater site. The heterodyne

repeater’s receiving frequency and transmitting frequency are marked on the top of repeater, near

waveguide antenna port. Coordinate site name is marked in the same location, when known.

The waveguide feedlines are terminated in CPR90G, Waveguide Flange. The heterodyne repeater is

not designed for pressurization. Use external pressure windows at the CPR90G, Waveguide Flanges

in all cases.

CAUTION: In an extremely hot and sunny environment, such as a desert, shading from direct

sunlight may be necessary to prevent the heterodyne repeater and associated

equipment from overheating. Locating battery enclosures in the shade is recommended.

20 NOTAM: Notice to Airmen, FAA or TC AIM

R-

-1

HR-11500 Operations Manual Chapter 2. Installation Instructions — 29

Figure 13 Enclosure Mounting Dimensions

HR-11500, Single Channel Duplex

Dimensions are in Inches [mm]

See block diagrams and Mounting Dimension drawing M900-0530-XX (Appendix) for more details.

R-

-1

— Chapter 2. Installation Instructions HR-11500 Operations Manual

THIS PAGE INTENTIONALLY LEFT BLANK

R-

-1

HR-11500 Operations Manual Chapter 3. Mounting the Antennas — 31

Chapter 3. Mounting the Antennas

Mount Antennas

Mount all antennas, antenna feedlines, grounding, dehydration and lightning protection. Test the

completed antenna system installation prior to heterodyne repeater equipment installation. Follow

details of the site plan if available.

Antenna Types

Microwave Linear Heterodyne Repeaters can use any one of four typical parabolic antenna types:

 Standard performance, single or dual polarized.

 Improved performance, single or dual polarized (Deep Dish, PAR, PAD).

 High Performance, single or dual polarized.

 Ultra-High Performance, single or dual polarized.

NOTE: Antenna type is normally determined by the system requirements. System path calculations,

path data sheet, are used to determine the antenna sizes and type.

Mount the antennas securely on adequate mounting structures. Mounting structures must meet

strength, twist and sway requirements for 11 GHz antenna systems. Provide means for alignment

adjustments.

Antenna Alignment

Coarse Alignment

To initially orient the antennas:

1. Align the “bore-sight” of the antenna to the calculated azimuth as shown in the site layout or path

calculations. Be sure to account for geomagnetic declination when using a magnetic compass.

Azimuths are normally shown as True North. Geomagnetic declination varies by site location and

typically drifts every year as the location of the earth’s magnetic pole moves.

2. Adjust the elevation to match the calculated elevation angle.

Fine Alignment using test radios

3. Peninsula Engineering recommends using test radios21 to do the alignment over the hop. This is much

easier than attempting to use the limited repeater level indications or measurements. The test radios

also provide a talk channel to allow the alignment teams to rapidly communicate with each other.

4. Identify the polarization determined for the hop. Consult the antenna manufacturer’s documentation on

identifying the vertical or horizontal antenna port on dual polarized antennas or how the feed assembly

is installed and oriented in single (plane) polarized antennas. Failure to properly identify polarizations

will result in antenna misalignment and violate the station license.

5. Attach the test radios to the proper antenna waveguide port at each end of the hop.

6. Consult the path data sheet calculations, PDS, for the net path loss calculated between the antennas.

Correct for feedline losses when connected directly to the antenna waveguide ports.

7. Begin aligning the antennas. It should be possible to meet the calculated net path loss ± 1 dB.

8. Record the alignment and loss details. Provide the records to the end customer or controlling authority.

21 Path Align-R™ is a popular test radio. Manufactured by: Spectracom Corp, XL-Microwave,

Pendulum

R-

-1

— Chapter 3. Mounting the Antennas HR-11500 Operations Manual

Alternative Fine Alignment using heterodyne repeater level measurements

9. This method requires the HR-11500 repeater to be installed, connected to the antenna feedlines

and powered up. See Chapter 4 for repeater installation details.

10. Connect the DVM to the RSSI BNC located on the bottom of the HR enclosure. The DC voltage

increases with stronger received signal level. The range is 0 to +10 VDC. Refer to the factory

Test Data Sheet, TDS, for calibration.

11. With a signal transmitted from the previous station, position the antenna for a maximum voltage

reading on the meter. Align the distant end antenna for maximum receive power.

12. Align any other antennas toward their coordinate station similarly.

13. To generate a transmit signal from a Heterodyne Repeater alone or used with a modem, apply a

CW carrier at 140 MHz, 0 dBm, thru a 3 to 6 dB attenuator pad to the HR IF IN Type N connector.

The attenuator is required to provide a DC path to ground and activate the transmitter.

14. After the antenna orientation has been completed at both terminals and the repeater, Receive

Signal Level (RSL) readings should be taken at all stations and logged for reference. Provide the

records to the end customer or controlling authority.

Antenna Feedlines

The HR-11500 repeater uses waveguide feedlines. For the 10.7 ~ 11.7 GHz band, typical feedlines

are elliptical waveguide such as EWP90 and EP105. The HR-11500 has CPR90G Waveguide

Flanges at the top antenna port. The equipment end of the waveguide feedline must have a matching

CPR90G flange installed. Two half height gaskets are used when a pressure window is installed. The

antenna end of the waveguide feedline must have a connector flange that matches the installed

antenna’s flange. Typical antenna flanges in this band are CPR90G and PDR100.

Waveguide feedlines require dehydration equipment to maintain a dry atmosphere within the

waveguide to prevent moisture accumulation which leads to corrosion and higher transmission

losses. For sites that have adequate electric power available, AC or DC powered dehydration and

pressurization equipment can be used. Mount the equipment at the tower base, or where convenient.

This equipment normally requires weather protection.

Tower mounted heterodyne repeater applications typically have shorter waveguide runs and thus, a

smaller volume of air within the waveguide. Static desiccators are ideal in this situation. A static

desiccator will passively dry air passed through its silica gel as daily temperature and pressure

changes gently move the air. These units do not require any power to operate and provide 1 to

2 years field lifetime before requiring replacement or service. Peninsula Engineering recommends

mounting static desiccators inside a weatherproof enclosure to protect against aging from direct

sunlight unless outside, UV rated desiccators are used. Peninsula can provide an assembled dual

static desiccator enclosure with pressure test ports. See manufacturer’s specifications and

recommendations when considering static desiccators.

Dry Nitrogen is another method to keep waveguides dry without using power. Nitrogen supplied in

high pressure bottles is reduced in pressure with a regulator and then passed to a gas pressurization

manifold with distribution to the feedlines. Nitrogen replaces the air within the waveguide (purged at

installation) and the positive pressure helps force moisture away from entering the waveguide. To

warn of an empty gas bottle, external alarm equipment can be optionally provisioned with a low

pressure switch that can be added to the pressurization manifold. When gas pressure drops below

1 psi, 7 kPa, a warning alarm is issued.

R-

-1

HR-11500 Operations Manual Chapter 3. Mounting the Antennas — 33

HR-11500 repeater station configurations require one feedline per equipment antenna port, typically:

 One for the primary West antenna

 One for the primary East antenna

 One per direction and polarization in Y-Junction applications

The allowable transmission loss for antenna feedlines is specified in the site plan or path calculation,

path data sheet documentation for the project. Do not install feedlines different than as specified.

Feedline Installation

To install waveguide feedlines:

1. Install the top connector (goes to the antenna). Use a flaring tool for best attachment and

impedance, Z0, match.

2. Raise the waveguide up the tower to the antenna. Use a hoisting grip.

3. Position the waveguide and secure the top section. Carefully bend the elliptical waveguide to

align with the antenna flange. Be mindful of the bend and twist specified limits of the waveguide.

If necessary, use rigid twist and bend sections to aid in alignment.

4. Connect the waveguide to the antenna.

5. Securely install the feedline so that it reaches to the installation site of the HR-11500, with

enough room to connect to the heterodyne repeater.

6. Secure the cable to the tower or structure about every 3 feet or 0.9 meters.

7. Carefully measure and cut to length the waveguide.

8. Terminate the waveguide with a CPR90G flange connector.

9. Position the waveguide and secure the bottom section. Carefully bend the elliptical waveguide to

align with the repeater equipment top flange. Be mindful of the bend and twist limits of the

waveguide. If necessary, use rigid twist and bend sections to aid in alignment.

10. Flexible twist-flex waveguide jumper may be used at either end if needed. These jumpers have

higher loss and shorter life than rigid twist and bend sections.

11. Trial fit the bottom connector to the repeater equipment top antenna port flange or intended

flange location. Do not permanently install until the feedlines are sweep tested.

12. Install waveguide grounding kits. Normally the waveguide is grounded at the top and bottom and

at the shelter entrance. Follow grounding practices prescribed by the controlling authority.

13. Pressure windows are recommended at the repeater equipment top antenna port.

14. Install dehydration equipment.

15. If gas ports are not available on the waveguide connectors, install a pressure inlet flange above

the pressure window.

R-

-1

— Chapter 3. Mounting the Antennas HR-11500 Operations Manual

Lightning Protection

Peninsula Engineering Solutions strongly recommends installing protection on the tower, structure

and on all feedlines to the heterodyne repeaters. A direct lightning strike can damage any electronic

equipment. Damage resulting from a lightning strike is not covered under the equipment warranty,

whether or not lightning protection is used. However, using lightning protection can minimize the risk

of damaging a repeater unit, and of losing equipment operation during thunderstorms.

Elliptical waveguides are protected by installing grounding kits, typically at the top, bottom and at

shelter entrance.

Lightning rods mounted adequately above the highest antenna or power equipment, provide a

diversion path for lightning strikes. Multiple lightning rods may be required.

Towers, shelters and all equipment must be bonded and grounded to minimize any potential

differences that can occur due to a lightning strike.

Follow grounding practices prescribed by the controlling authority.

Sweeping the Antenna Feedlines

Sweep testing of the installed feedlines and antennas is recommended. Sweep testing is the same as

performed at a terminal radio site. Measurement of impedance match and insertion loss over the

operating frequencies insures that the antenna system is installed properly and is ready to perform.

Most microwave operating companies have developed their own performance standards for antenna

systems. Use such standards if available. If company standards are not available, consider the

following:

 Sweep frequency range: 10,700 ~ 11,700 MHz or across assigned channel bandwidth.

 Impedance Match: 20 dB Return Loss or 1.2:1 VSWR across the channel bandwidth or

better. If tunable connectors are provisioned, adjust the tuning screws to optimize the match.

 Insertion Loss: Per calculated. Typical waveguide loss22 is 3.05 dB/100 Ft or 10.0 dB/100 m.

 Distance to Fault, DTF: Measure Return Loss of the antenna system components and isolate

troubles. Use DTF function of Anritsu Site Master™ (or equivalent) test equipment.

If the impedance match or insertion loss is not met, troubleshoot the feedlines and antennas for the

source of the problem. Use the “Distance to Fault” function to assist in localizing the trouble. Correct

as required before proceeding.

22 EWP90, EP105. Consult manufacturer’s specifications for loss at the intended frequencies.

R-

-1

HR-11500 Operations Manual Chapter 4. Mounting the HR-11500 — 35

Chapter 4. Mounting the HR-11500 Repeater

Installation Overview

The HR-11500 assembly can be mounted on a steel tower, on a steel pipe or square-rail frame, or on

a wall. The length of all power leads should be limited and the wire size adequate to minimize the

voltage drop. The heterodyne repeater assembly, electric power system, battery boxes, solar panels,

and antennas should all be mounted before any wiring is done.

NOTE: Only qualified service or technical personnel should install the repeater.

Figure 14 Heterodyne Repeater Installation on pipe mount

R-

-1

— Chapter 4. Mounting the HR-11500 HR-11500 Operations Manual

Figure 15 Heterodyne Repeater on pipe mount, rear view

Mounting Associated Equipment and Space Planning

Mount the site power system and any other associated equipment before mounting and wiring the

repeater. Plan the site equipment layout prior to beginning installation.

Recommended power system installation sequence:

1. Ground Ring or grounding provision

2. Battery Enclosures and Batteries

3. AC/DC Rectifier and Battery Charger

4. Photovoltaic Array, mounting frame and modules

5. Wind Turbine Generator, pipe mount and generator

6. PV Array Combiners

7. PV Controller

R-

-1

HR-11500 Operations Manual Chapter 4. Mounting the HR-11500 — 37

Figure 16 Example of Solar and Wind Power Installation

Mounting the Repeater

The HR-11500 has a detachable rear mounting bracket. The mounting holes fit 3/8-inch to 5/8-inch

hardware. Mounting-hole dimensions for the mounting bracket are shown in Figure 13. The HR

enclosure attaches to the mounting bracket using 3/8-inch hardware provided. The enclosure is first

aligned using the ½-inch alignment spacer and slot in the mounting bracket. The enclosure is

secured to the mounting bracket using the 3/8-inch hardware provided.

The HR unit may be lifted to a high mounting location using the lifting plates attached to the sides of

the enclosure. Use carabineers and a rope cable sling for balance. The top rear edge with the

alignment spacer will tip to the rear making attachment to the mounting plate easier. Avoid using a

rope cable across the top of the enclosure as this can damage the waveguide antenna port.

Once the HR unit is securely mounted, it is recommended to remove, invert and reattach the lifting

plates. Inverting the lifting plates reduces the chance of ice buildup on the top of the repeater from

causing damage to the waveguide entry boot. Make sure the bolts have sealant in the threads to

prevent water from propagating along the thread helix.

Pipe Mount

The mounting bracket may be attached to 4.5-inch OD pipes using the outer hole pattern or 2.375 ~

2.5-inch OD pipes using the inner hole pattern. Pipe saddle and U-bolt clamps23 can be used to

attach the bracket. Cut off excess U-bolt thread near the mounting nut. This provides clearance to the

HR heatsink fins.

Figures 14, 15 and 17 show the suggested pipe mounting.

23 Clamp sets are provided by others.

R-

-1

— Chapter 4. Mounting the HR-11500 HR-11500 Operations Manual

Figure 17 Mounting Bracket attached to 4.5-inch Pipe

H-Frame Mount

The HR-11500 may be mounted to an H-frame or wall using Unistrut™.

Fabricate a mounting frame using 3/8-inch square rail or Unistrut™ fastened to the tower members,

wall or monopole. The square rail sections directly attached to the mounting bracket are normally

best horizontal. Attach the mounting bracket first using 3/8-inch spring nuts and bolt, washer

hardware.

Attach the repeater to the mounting bracket using the 3/8-inch hardware provided.

See Figure 18 for a suggested mounting frame.

HR-11500

Figure 18 Suggested Mounting H-Frame

R-

-1

HR-11500 Operations Manual Chapter 4. Mounting the HR-11500 — 39

Earth, Ground, and Lightning Protection

When grounding the HR-11500 and associated equipment, follow the general guidelines in the

Peninsula Engineering Solutions application note, 650-0002-01: Installation Standards for Grounding

Requirements.

Note is available at www.peninsulaengineering.com Microwave RF Repeaters/Engineering Notes.

Installing the input power to the repeater includes installing the standard electrical service grounds.

However, you must also make sure that the heterodyne repeater enclosure is properly grounded to

an earth ground.

The enclosure includes an external grounding lug on the bottom surface as shown in the following

figure.

Figure 19 Location of Ground Lug on Heterodyne Repeater Enclosure

1. Connect the screw-compression ground lug to a suitable earth ground—copper ground rod,

copper pipe, ground ring, grounded steel building frame or similar ground point—using 2 to

4 mm, No. 12 to 6 AWG copper wire.

2. Carefully dress the wire along cabinet, and the mounting surface, to the Repeater Grounding

System or the Ground Rod. Recommend using CADWELD® to attach the ground wire to the

rod or ground point.

NOTE: When dressing the grounding wire, and forming it around corners; avoid making sharp bends

in the wire. Use a generous radius for each wire bend. Sharp bends will cause arc points for

lightning surges and strikes.

Ground Lug

R-

-1

— Chapter 4. Mounting the HR-11500 HR-11500 Operations Manual

Figure 20 Typical System Ground Rod

CAUTION: Ground all other cabinets, enclosures, antennas, waveguides, and coaxial cables used

for installation to reduce any damage from a lightning strike or power surge.

Figure 21 Wiring and Ground Connections, Power Distribution Assembly,

(Aluminum cover shown as transparent)

TB1

Battery A

+, - &

Ground

TB2

Battery B

+, - &

Ground

JP1, JP2

Battery

Polarity

Selection

R-

-1

HR-11500 Operations Manual Chapter 4. Mounting the HR-11500 — 41

IF Connections

In IF Heterodyne Through-Repeater applications, the IF 140 MHz ports are cross connected between

Heterodyne Repeater Unit pairs. See Figure 4.

 West IF OUT to East IF IN.

 East IF OUT to West IF IN.

Recommend using 50 Ohm Foam Dielectric coaxial cable for low loss, low latency and high isolation.

Maximum rated cable loss is 10 dB. Connectors are Type N(m) at each end to attach to external

IF ports.

 Return Loss should be 14 dB or better across 120 ~ 160 MHz.

 Cable must pass DC in order for the squelch to work and Tx PA to activate.

Table 13 IF Cable Types

Cable Type

Maximum Length

Signal Delay, Latency

Times Microwave LMR-200

250 Ft, 75 mtr

VP .83, 122 nsec/100 Ft, 402 nsec/100 m

Times Microwave LMR-400

650 Ft, 200 mtr

VP .85, 120 nsec/100 Ft, 392 nsec/100 m

Times Microwave LMR-600

1000 Ft, 300 mtr

VP .87, 117 nsec/100 Ft, 383 nsec/100 m

Times Microwave LMR-900

1450 Ft, 450 mtr

VP .87, 117 nsec/100 Ft, 383 nsec/100 m

Times Microwave LMR-1200

2000 Ft, 600 mtr

VP .88, 116 nsec/100 Ft, 379 nsec/100 m

Comscope/Andrew LDF1-50

650 Ft, 200 mtr

VP .86, 118 nsec/100 Ft, 388 nsec/100 m

Comscope/Andrew LDF2-50

775 Ft, 235 mtr

VP .88, 116 nsec/100 Ft, 379 nsec/100 m

Comscope/Andrew LDF4-50A

1200 Ft, 365 mtr

VP .88, 116 nsec/100 Ft, 379 nsec/100 m

Comscope/Andrew AVA5-50

2400 Ft, 730 mtr

VP .91, 112 nsec/100 Ft, 366 nsec/100 m

Comscope/Andrew AVA6-50

3200 Ft, 975 mtr

VP .92, 110 nsec/100 Ft, 363 nsec/100 m

For IF Terminal applications; the IF 140 MHz ports are connected to an external modem unit.

See Figure 5.

 Modem IF OUT to HR IF IN.

Heterodyne IF IN requires: -15 ~ 0 dBm and DC path to ground to activate Tx PA.

Maximum DC resistance, shunt to ground, is 500 Ohms.

 HR IF OUT to Modem IF IN.

Heterodyne IF OUT provides: -2 dBm and DC switched shunt to ground upon

Squelch activation.

Install Grounding Kits on the IF Cables for lightning protection.

Install weather protection boots, casings or sealing tape at the N connectors.

R-

-1

— Chapter 4. Mounting the HR-11500 HR-11500 Operations Manual

THIS PAGE INTENTIONALLY LEFT BLANK

R-

-1

HR-11500 Operations Manual Chapter 5. Repeater Tests — 43

Chapter 5. Equipment Tests

Overview

This chapter describes how to test the HR-11500 equipment, to configure settings and to verify that it

is operating properly.

Test Equipment Required

Table 11, in Chapter 2, lists test equipment and tools required for testing the HR-11500 repeater.

Equivalent equipment may be substituted.

Configuring the Heterodyne RF Module

The HR-11500 is configured in the factory to customer and project requirements. Normally it is not

necessary to change the configuration settings. Should it be necessary to change settings, proceed

as follows:

Figure 22 Heterodyne RF Module

1. Power down the heterodyne repeater unit for safety if possible. At this point the HR should be

OFF anyway.

2. Locate the Heterodyne RF Module inside the unit enclosure. See Figure 22.

3. Remove the Control Cover to expose the configuration switches. The screws are small 2-56

FHP x .250 and are easy to drop and loose. Spare screws are included in the accessory kit.

4. Identify the configuration switches. See Figure 23.

Control

Cover

R-

-1

— Chapter 5. Repeater Tests HR-11500 Operations Manual

Figure 23 Configuration Switches and Jumper

5. See the Channel Plans in Tables 3 to 7 for the Channel MSB and LSB settings. The channel

pair must match the filter frequencies in the antenna coupling unit, ATCU!

6. Set the Channel MSB and LSB switches (2 left switches, 0~9 BCD) for the desired channel

pair. Note the receive and transmit frequency directions when selecting the pair. Certain

channel plans have alternate T-R spacing capability. Set ALT BAND SELECT jumper as

listed in the channel plan table.

a. Note: to enable the channel settings, the heterodyne unit must be power cycled.

Power down the unit for at least 10 seconds and then restart.

7. Transmit Power Amplifier Power is set using the 0~F HEX switch, 3rd from the left or RF

input end. Table 14 lists the power settings. The power level is referenced to the module RF

output SMA connector. Subtract transmit branch filter loss from this value to calculate the

level at the waveguide antenna port. Transmit branch filter loss is marked on the ATCU

panel. See Table 1 for typical loss values.

8. Squelch level is set using the 0~F HEX switch 4th from the left or RF input end. Table 14 lists

the squelch level settings. The squelch level is referenced to the module RF input SMA

connector. Add receive branch filter loss to this value to calculate the level at the waveguide

antenna port. See Table 1 for typical loss values.

9. Changes to Transmit Power and Squelch levels will be immediately enabled if the heterodyne

unit is powered ON. Otherwise, the changes will be effective on next power up.

CHANNEL

MSB

CHANNEL

LSB

POWER

SQUELCH

ALT BAND

SELECT

JUMPER

R-

-1

HR-11500 Operations Manual Chapter 5. Repeater Tests — 45

Table 14 Configuration Settings, Tx Power and Squelch levels

Tx PA POWER LEVEL

SQUELCH LEVEL

HEX

dBm

HEX

dBm

+34

DISABLE

+33

-75

+32

-74

+31

-73

+30

-72

+29

-71

+28

-70

+27

-69

+26

-68

+25

-67

+24

-66

+23

-65

+22

-64

+21

-63

+20

-62

+19

-61

Configuring DC Power

Heterodyne Units are ordered for 24V or 48V battery power. If the battery polarity is known, the input

polarity will be set at the factory. Should it be necessary to change the polarity jumpers, proceed as

follows:

1. Open the Heterodyne Unit enclosure door. Locate the DC Distribution Subassembly circuit

board at the inside bottom.

2. Tables 15, 16 and 17 list the connections and jumper positions for the available

configurations. Figure 10 shows the DC power connection schematic. Figure 24 shows the

board layout.

3. Wire jumpers are used at JP1 and JP2.

4. In applications were a single battery supply is used, recommend combining the A and B

inputs to provide internal DC/DC power supply redundancy and to normal standing alarms.

See Tables 16 and 17 for connection details.

5. In applications were power is run to the heterodyne unit thru conduit; connections can be

made to TB1 and TB2 on top of the DC Distribution Subassembly. Knockouts for 2ea ½-inch

conduits and 1ea 1-1/2 inch conduit are available for terminating the conduit.

a. The maximum wire size is 10 AWG.

b. Minimum recommended wire size is 14 AWG.

c. Wire size is determined by run length and allowable voltage drop.

6. In applications were power is run to the heterodyne unit via cords and Bulgin 3-socket plugs;

connections are to the Bulgin 3-pin jacks J1 and J2 on the enclosure outside bottom.

a. The maximum wire size is 12 AWG, cord OD range is 6 ~ 8 mm, (0.24 ~ 0.32-in).

b. Minimum recommended wire size is 14 AWG.

c. Wire size is determined by run length and allowable voltage drop.

R-

-1

— Chapter 5. Repeater Tests HR-11500 Operations Manual

Table 15 DC Battery Configurations, A & B

24V 087-1242-01

48V 087-1242-02

+24V A Battery, NEG GND

JP1: 2-3

+48V A Battery, NEG GND

JP1: 2-3

-24V A Battery, POS GND

JP1: 1-2

-48V A Battery, POS GND

JP1: 1-2

A Battery POS input

TB1-1

J1-1

A Battery POS input

TB1-1

J1-1

A Battery NEG input

TB1-2

J1-2

A Battery NEG input

TB1-2

J1-2

A Battery GND input

TB1-3

J1-3

A Battery GND input

TB1-3

J1-3

+24V B Battery, NEG GND

JP2: 2-3

+48V B Battery, NEG GND

JP2: 2-3

-24V B Battery, POS GND

JP2: 1-2

-48V B Battery, POS GND

JP2: 1-2

B Battery POS input

TB2-1

J2-1

B Battery POS input

TB2-1

J2-1

B Battery NEG input

TB2-2

J2-2

B Battery NEG input

TB2-2

J2-2

B Battery GND input

TB2-3

J2-3

B Battery GND input

TB2-3

J2-3

Table 16 DC Battery Configuration, A-Only Positive Voltage

+24V 087-1242-01

+48V 087-1242-02

+24V A Battery, NEG GND

JP1: 2-3

+48V A Battery, NEG GND

JP1: 2-3

A Battery POS input

TB1-1

J1-1

A Battery POS input

TB1-1

J1-1

A Battery NEG input

TB1-2

J1-2

A Battery NEG input

TB1-2

J1-2

A Battery GND input

TB1-3

J1-3

A Battery GND input

TB1-3

J1-3

+24V B Battery, NEG GND

JP2: 2-3

+48V B Battery, NEG GND

JP2: 2-3

A to B Combining Jumper

JP1-1 to TB2-1

A to B Combining Jumper

JP1-1 to TB2-1

Table 17 DC Battery Configuration, A-Only Negative Voltage

-24V 087-1242-01

-48V 087-1242-02

-24V A Battery, POS GND

JP1: 1-2

-48V A Battery, POS GND

JP1: 1-2

A Battery POS input

TB1-1

J1-1

A Battery POS input

TB1-1

J1-1

A Battery NEG input

TB1-2

J1-2

A Battery NEG input

TB1-2

J1-2

A Battery GND input

TB1-3

J1-3

A Battery GND input

TB1-3

J1-3

-24V B Battery, POS GND

JP2: 1-2

-48V B Battery, POS GND

JP2: 1-2

A to B Combining Jumper

JP1-3 to TB2-2

A to B Combining Jumper

JP1-3 to TB2-2

R-

-1

HR-11500 Operations Manual Chapter 5. Repeater Tests — 47

Figure 24 DC Distribution Assembly and Battery Input Blocks

Applying Power to the Heterodyne Repeater

1. Confirm the repeater is connected to the antenna feedlines, is grounded and that the power

system has been installed and tested. Confirm that battery polarity jumpers are in place and

correct. See Tables 15, 16, 17 and Figure 24.

2. When a single battery supply is used, parallel the DC inputs at the DC Power Distribution

Assembly. See Tables 16, 17 and Figure 24.

3. Apply primary DC power to battery connections, internal or external as required.

POS

NEG

GND

POS

NEG

R-

-1

— Chapter 5. Repeater Tests HR-11500 Operations Manual

4. Measure the DC voltage at TB1 1(+), 2(-) and TB2 1(+), 2(-).

Make sure that the voltage is within the operating parameters of the repeater:

 24 Volts DC: 20 ~ 30 VDC. Nominal lead acid battery voltage is 25.2 VDC when fully

charged and 27.0 VDC when being charged. Correct as necessary.

 48 Volts DC: 40 ~ 60 VDC. Nominal lead acid battery voltage is 50.4 VDC when fully

charged and 54.0 VDC when being charged. Correct as necessary.

5. If the ACU-SNMP alarm module is provisioned, it will start-up on power up. ACU start-up

takes about 5~10 seconds. Power LED should be ON and GREEN.

Figure 25 ACU - SNMP Module, Front Panel

6. On initial power-up, these ACU conditions should be present as displayed on front panel:

Table 18 ACU Conditions at power-up

Item

Condition

Alarm Point

Clear

POWER

ON - Green

12.5V DC Bus < 10V

12.5V DC Bus > 10V

SENSOR

OFF

Not Used

ETH

ON, FLASH - Green

Ethernet Disconnected

Ethernet Active

ALARM

ON – Red (Summary)

Any Alarm or Temperature

All Alarms Clear

HET DC

Clear

Current Out of Range

Squelch Active

LO Fail

Current Normal

SQL

Clear

Squelch Active

LO Fail

Squelch Inactive

Clear

Synthesizers UnLock

Loss of 10 MHz Ref.

Local Oscillators Normal

DOOR

Alarm, ON – Red

Door Open

Door Closed

BATT A

Clear

Battery A V < 21V, > 28.5V

Battery A V < 42V, > 57V

Battery A V Normal

BATT B

Clear

Battery B V < 21V, > 28.5V

Battery B V < 42V, > 57V

Battery B V Normal

RSL

Clear

RSL < -70 dBm, > -25 dBm

RSL Normal

TX PWR

Clear

PWR < 0.3 W, > 4W

PWR Normal

7. Once the Battery A and B alarms clear, then the repeater is powered and ready for testing.

8. Current Test: Measure the Battery A and B current flowing into the heterodyne repeater.

Each battery will normally supply close to half of the total current listed in the Technical

R-

-1

HR-11500 Operations Manual Chapter 5. Repeater Tests — 49

Summary. If either battery input has a low or zero current, check the battery source and

distribution system. A battery source with lower voltage will typically supply less current.

 Record A and B currents for reference.

9. The heterodyne repeater can operate on a single A or B battery input when needed. Each

module can draw power from both DC/DC converters and thus either battery input. When one

battery source is removed or failed, all the current will flow into the remaining working battery

feed. This can be observed by switching OFF one of the battery feeds, observe, then restore

this feed to ON and then switch OFF the other battery feed, observe.

Transmit Power Adjustment

At this point, the antennas should be mounted, feeders swept, and antennas aligned. The heterodyne

repeater’s power amplifier (PA) has been factory set to the specified output power level per the

system modulation, when known. Greater than recommended power levels can result in amplitude

distortion, increased error vector magnitude (EVM), radio and line errors (BER). Less than

recommended power levels may have been selected by transmission engineering (e.g. short hops or

tandem hops). Refer to system path calculations and path data sheets for details.

To measure and adjust PA output power:

1. Three methods may be used to measure PA output power:

A. Tx Power Voltage and factory Test Data Sheet calibration. (Easiest)

B. ACU Web Page user interface.

C. RF Power Meter at RF MON – SAMPLE PORT. (Most Accurate, Most Work!)

2. A signal source must be present:

2.1. Repeater Applications: The far end transmitter must be transmitting at this time.

2.2. Heterodyne Terminal Applications: An IF modem sending 140 MHz signal to IF IN.

2.3. Test: A suitable signal source sending 11 GHz RF or 140 MHz IF signals.

3. Confirm the Power Amplifier is active; no HET DC fault should be present.

4. Method A.

4.1. Use a DVM and BNC adapter to measure the Tx Power Voltage at the BNC connector on the

enclosure bottom.

4.2. See the factory test data sheet (TDS) for voltage to power (Watts) conversion.

4.3. Record the PA Output Power Level.

5. Method B.

5.1. Connect to the ACU Web Page and read the Tx Power value.

5.2. Record the PA Output Power Level.

5.3. Note: ACU network connections must be previously setup. See Section 6.

6. Method C.

6.1. Calibrate the RF Power Meter for 11 GHz operating frequencies.

6.2. Remove the SMA Termination and then connect the power meter to the RF MON – SAMPLE

PORT on the side of Power Amplifier. This is an SMA-female connector. A right-angle adapter

with a between series (e.g. SMA to N) adapter (if needed) to fit the power meter sensor are

needed to access the test port. See Figure 26.

R-

-1

— Chapter 5. Repeater Tests HR-11500 Operations Manual

6.3. Measure and record the power meter reading. Typically, this reading will be between -3 dBm and

+16 dBm at RF MON - SAMPLE PORT.

6.4. Replace the SMA Termination.

6.5. Add the Cal Loss marked near the RF MON (see Figure 26) to the power meter reading, the

result is the Power Amplifier Output Power.

6.6. Record the PA Output Power Level.

7. Power Adjustment

7.1. Compare the Power Amplifier Output Power reading to Table 2, using the listing for the radio

modulation type used.

7.2. Set the Tx Power Switch as required setting the power amplifier output level equal to the listing in

Table 2 and per Table 14.

 Note: Lower levels may have been selected by transmission engineering, please refer to

system path calculations and path data sheets for details.

7.3. Once the power levels have been set, confirm the ACU Transmitter Power alarm is clear. If the

Tx PWR alarm remains active and the transmit power is correct, then the ACU alarm point must

be reset. Please refer to the ACU section for details.

8. To determine the Antenna Port Output Power Level, subtract the Tx Branch Loss from the Power

Amplifier Output Level. The Tx Branch Loss is marked on the ATCU panel above the PA. Include

any transmit attenuator pad loss if equipped.

Figure 26 Heterodyne RF Module Connector Ports

RF MON -

SAMPLE PORT

PA OUTPUT

TX PAD

LOCATION

IF IN

IF OUT

RX RF IN

RX PAD

LOCATION

10 MHz

REFERENCE IN

RSL VOLTS

TX PWR

VOLTS

R-

-1

HR-11500 Operations Manual Chapter 5. Repeater Tests — 51

Receive and Transmit Attenuator Pads

Receive, Rx, pads attenuate input signals that are greater than can be compensated by the repeater

amplifier’s AGC circuits. Receive pads are installed on the RF Down-Converter input (RF IN) jack.

Transmit, Tx, pads attenuate output signals. Transmit signals can first be reduced by adjusting the

PA Power Set Switch. In cases of very short hops, more power reduction may be needed. In these

cases a Tx Pad is normally installed. Transmit pads are installed on the Power Amplifier output

(RF OUT) jack. Power Amplifier output should be reduced to between +19 and +30 dBm before

adding an attenuator pad.

Pad Installation:

1. If required in the field, the Rx/Tx attenuator pads should be installed at the RF input or output of

the heterodyne RF module.

2. To install the pad, turn OFF the DC power supply first.

3. Disconnect the input or output semi-rigid coax cable from the heterodyne RF module.

4. Connect the SMA male end of the pad to the module’s SMA female input or output; and then

connect input or output cable to the female end of the pad. Cable will require slight bending by

hand, use care when bending.

5. Check all coaxial connections for tightness (8 in-lbs).

6. Turn ON the DC power supply.

7. Set output power level by adjusting PA Power Switch.

ACU – SNMP Network Configuration

The ACU – SNMP module reports status and alarms via IP on Ethernet. Private IP Network or Public

Internet may be used for message transport. Each ACU must be configured for proper reporting.

Section 6 details ACU setup.

Radio Link Tests

Once the repeater levels have been set and confirmed and antenna alignment is accepted, then

confirm microwave signals are received at each terminal radio. Observe and record the receiver AGC

or RSL indications for reference.

End to end link tests can now be run. These tests may typically include un-faded BER, radio errors,

system thermal and intermodulation noise. Refer to the radio terminal equipment documentation and

system engineering requirements for the link test plan.

R-

-1

— Chapter 5. Repeater Tests HR-11500 Operations Manual

THIS PAGE INTENTIONALLY LEFT BLANK

R-

-1

HR-11500 Operations Manual Chapter 6. ACU – SNMP Module Setup — 53

Chapter 6. ACU – SNMP Module Setup

The ACU – SNMP module is factory configured. This module must be configured for the customer

network in order to communicate. This section describes network setup plus the procedure to change

alarm conditions.

Network Setup

Connect the local Ethernet to the Heterodyne Repeater Unit. Connect to the RJ-45 connector on the

enclosure bottom or Fiber LC duplex connector on the enclosure bottom. See Figures 3 and 4 for I/O

connection detail.

The ACU Copper Ethernet RJ-45 connector jack may be connected directly to a LAN switch or router.

The ACU Fiber Optic Ethernet LC connector jacks must be first connected to compatible multi-mode

fiber optic transceiver. The F/O transceiver may be part of a media converter, switch or other network

device.

The fiber optic pair is used as the supervisory communications path from a tower mounted

heterodyne unit to a ground mounted network switch or router. Fiber optic pair provides improved

immunity to electrical interference on such longer runs.

The LAN switch, router or similar network collection point plus transmission means from the

microwave site to a network operations center, is provided by the user. ACU – SNMP messages are

carried by “Out-of-Band” network transport.

Accessing the HR-ACU via the Web Page User Interface

1. Assign and IP address to the HR - ACU using one of these two methods:

A. OmniDiscover utility application (Best Method)

1) This is a small computer program included with the documentation CD.

2) Install OmniDiscover application on a Personal Computer (PC) and then connect the PC to

the local Ethernet.

3) Power on the HR-ACU and perform the following steps within 5 minutes. This is an

intentional limitation. If 5 minutes passes, network data cannot be modified without power-

cycling the HR-ACU.

4) Open the OmniDiscover application, and select Search on the top menu bar. The ACU will be

displayed in the main window including the MAC address, Site ID, and default Subnet Mask

(255.255.255.0)

5) Right click the ACU line, and select “Setup” from the menu that appears.

6) Enter the desired IP Address, Subnet mask (if not default) and Gateway router address you

want to assign to the ACU.

7) Press/click the “OK” button and you’ll be returned to the main OmniDiscover window where

you should see displayed the network address configurations just entered.

8) Right click the ACU line again, and select “Web”. The ACU login will be displayed.

9) Alternatively, open a Web Browser and type the ACU’s IP/URL in the address line:

http://nnn.nnn.nnn.nnn. The ACU login will be displayed.

R-

-1

— Chapter 6. ACU – SNMP Module Setup HR-11500 Operations Manual

B. ARP/Ping

1) Power ON the HR- ACU, no time limitation.

2) From a command prompt on the PC, issue the following two commands

Note: the ACU must have no IP address (0.0.0.0) configured for this to work:

ARP-S nnn.nnn.nnn.nnn xx-xx-xx-xx-xx-xx

Ping nnn.nnn.nnn.nnn

(where nnn.nnn.nnn.nnn is the desired ACU IP address, and xx-xx-xx-xx-xx-xx is the MAC

address)

3) Open a Web Browser and type the ACU’s IP/URL in the address line: http://nnn.nnn.nnn.nnn.

The ACU login will be displayed.

2. Login: Default login credentials are admin/password. These can be changed on the Network

Settings screen.

3. The Device Status screen is displayed next. All operational status information is shown on

this page.

4. You are now connected and ready to configure remaining settings.

Figure 27 Opening ACU Status Screen

R-

-1

HR-11500 Operations Manual Chapter 6. ACU – SNMP Module Setup — 55

Settings Tabs

1. The HR-ACU web user interface provides 6 tabs across the top of the main screen. Each tab

allows access to different settings. This section describes each tab and the settings contained.

Status ................. Displays the Device Status screen where current data about the HR-ACU

is displayed. This screen is informational only, with no user configurable

settings.

General .............. Displays the General Settings screen where Site Name, Equipment,

Current Date & Time, and Daylight Savings Time adjustment can be

configured.

Networking ......... Displays the Networking Settings screen where IP Address, Subnet Mask,

Router Address, SNMP Community names, and login credentials can be

configured.

Events ................ Displays Events Settings sub-tabs for configuring the On-Board Sensors

(internal Temperature Sensor and internal I/O) and any connected

EventSensors.

Alerts .................. Displays the Alert Settings screen where general alert settings, as well as

specific Email and SNMP alert settings can be configured.

Administration .... Displays the Administration Settings screen where general administrative

functions for the unit can be conducted. These include uploading a new

firmware file, resetting the unit, resetting all parameters to their default

settings, and uploading/download the Setting Keys file.

2. At the bottom of each screen where settings can be configured are a Submit button and a Cancel

Changes button. If you make changes and are satisfied with them, press the Submit button. New

configurations will be applied immediately. Press the Cancel Changes button before pressing the

Submit button to reset any configuration changes to what they were previously.

Note: Take care when making changes to Network Settings. Because these take effect

immediately, thus network connection to the HR-ACU will be lost and must be reconnected

using the new configurations.

R-

-1

— Chapter 6. ACU – SNMP Module Setup HR-11500 Operations Manual

Device Status Screen

Figure 28 ACU Status Screen – Door Open

General Information

Site Name

Identifier assigned to each HR-ACU.

This is entered in the Site Name field on the General tab.

Equipment

Type of Heterodyne Repeater equipment.

This is entered in the Equipment field on the General tab.

Firmware

Installed firmware version.

Unit Serial #

Unique serial number assigned to this HR-ACU. Serial number is fixed.

IP Address

Network IP address assigned to this HR-ACU. See the Network Administrator for IP

address information. An addressing scheme should be developed to manage these

network elements. Address is entered on the Networking tab.

MAC Address

Unique, hard coded, MAC address of the Ethernet interface for this HR-ACU. The

MAC address can also be found on the ACU serial number label. The MAC address

cannot be changed.

Subnet Mask

Network subnet mask assigned to this HR-ACU. See the Network Administrator for

mask information. Mask is entered on the Networking tab.

Router Address

IP address for the network gateway or router to which this HR-ACU is connected. See

the Network Administrator for this address. Address is entered on the Networking tab.

Date

Current Date in MM/DD/YY format. Date is set on the General tab.

Time

Current Time in HH.MM.SS format. Time and Daylight Savings adjustment are set on

the General tab.

R-

-1

HR-11500 Operations Manual Chapter 6. ACU – SNMP Module Setup — 57

On-Board

Heat Sink

Temperature

Current temperature of the Heterodyne Repeater unit’s rear heatsink in Celsius.

Alarm status is displayed next to the temperature reading.

HET DC

Displays current Open/Closed and Active/Inactive status for the Heterodyne RF

Module Current Alarm. Closed = Alarm Active

SQUELCH

Displays current Open/Closed and Active/Inactive status for the Heterodyne RF

Module Squelch Condition. Closed = Squelch Active.

Displays current Open/Closed and Active/Inactive status for the Heterodyne RF

Module Local Oscillator UnLock Alarm. Closed = Alarm Active.

DOOR

Displays current Open/Closed and Active/Inactive status for the Enclosure Door.

Closed = Door Open, Active.

BATT A

Displays the translated voltage reading for Battery A input. Reading is always Positive.

Alarm status is displayed next to the voltage, (Normal).

BATT B

Displays the translated voltage reading for Battery B input. Reading is always Positive.

Alarm status is displayed next to the voltage, (Normal).

RSL

Displays the receive signal level in dBm. RSSI Voltage is measured and translated to

dBm. Alarm status is displayed next to the level, (Normal).

TX PWR

Displays the Power Amplifier output level in Watts. Tx PA Voltage is measured and

translated to Watts. Alarm status is displayed next to the level. (Normal)

General Settings Screen

Figure 29 ACU General Settings Screen

R-

-1

— Chapter 6. ACU – SNMP Module Setup HR-11500 Operations Manual

Settings: Click “Submit” to send the settings to the HR-ACU.

Site Name

Enter the HR-ACU identifier. Typically this is the site name.

Maximum length is 40 characters.

Equipment

Enter the Heterodyne Repeater nomenclature, such as HR-11500-52 11G-1.

Maximum length is 40 characters.

Current

Date, Time

Displays the current Date and Time. Click on the “Set Date/Time” button to open a

pop-up dialog where the date and time can be reset.

Adjust for DST

A drop-down selection menu where Daylight Savings Time function can be turned ON

or OFF.

Notes: Date and Time settings are maintained in an internal clock. An internal backup battery will

maintain the time when power is removed from the HR-ACU. Daylight Savings Time is

not automatically changed at the beginning and end of DST season.

Figure 30 ACU Time and Date Set

R-

-1

HR-11500 Operations Manual Chapter 6. ACU – SNMP Module Setup — 59

Networking Settings Screen

Figure 31 ACU Networking Settings Screen

Settings: Click “Submit” to send the settings to the HR-ACU.

IP Address

Sets the IP Address to this HR-ACU. Default is 0.0.0.0 upon reset.

MAC Address

HR-ACU’s hard coded Ethernet Interface MAC address. Address is fixed.

Subnet Mask

Sets the network subnet mask provided by the network administrator.

Default is 255.255.255.0 upon reset.

Router Address

Sets the router or gateway IP address provided by the network administrator.

Default is 0.0.0.0 upon reset.

SNMP

Trap/Read/Write

Community

Sets the SNMP trap community name for each. Default is “public”.

Sets the SNMP Read and Write Community names for GETS and SETS. Default is

“public”.

Web Login

Username,

Password

Sets the login credentials required by the Web User Interface. Default is: Username:

admin and Password: password. The password is always masked. For security

reasons it is highly recommended that this password be changed. Record all

configured passwords in a secure location. If locked out of the HR-ACU because the

password has been forgotten, it is possible to reset the unit to its default login

credentials. Refer to the Resetting Defaults section.

Note: Take care when making changes to Network Settings. Because these take effect

immediately, thus network connection to the HR-ACU will be lost and must be reconnected

using the new configurations (IP Address, etc.).

R-

-1

— Chapter 6. ACU – SNMP Module Setup HR-11500 Operations Manual

Events Screens

Each Sensor has been factory configured for each specific HR-11500 model. It is strongly

recommended that existing settings are recorded before making any changes. Factory settings

are included in the Test Data Sheet, TDS provided with each Heterodyne Repeater Unit. A

“settings file” can be downloaded and saved for reference, see the Administration screen.

Alarm State enables or disables alarm actions. Normal setting is ON.

Alarm Actions are set to T1 or SNMP manager #1 by default. Alarm actions are configured as

Tn where n corresponds to the SNMP Manager index number on the SNMP Alerts tab. Email

actions are configured as En where n corresponds to the Email Address index number on the

Email Alerts tab. Multiple actions are listed with no delimiters, for example: T1T2E1E3. These can

be changed as required. See Alerts screen.

Deadband sets the range (translated units) on either side of a temperature or analog reading that

prevents the event from repeatedly going in and out of alarm or “event state”, also known as

hysteresis.

Severity selection name will appear in SNMP Trap Alerts, but does not appear in Email Alerts.

Figure 32 ACU Events - Temperature Sensor

Temperature

Units

Alarm State

Alarm Actions

Deadband

Heat Sink Temperature

Celsius

Temp Threshold

Very Low

Low

High

Very High

Temperature Value

0 C

5 C

50 C

60 C

Severity

Minor

Info

Minor

Major

R-

-1

HR-11500 Operations Manual Chapter 6. ACU – SNMP Module Setup — 61

Figure 33 ACU Events - Analog Settings Screen (Top)

R-

-1

— Chapter 6. ACU – SNMP Module Setup HR-11500 Operations Manual

Figure 34 ACU Events - Analog Screen, Conversions (Bottom)

Analog voltages are set in hundredths of a volt. 100 = 1.00V, 1000 = 10.00V.

Maximum rated voltage is ± 60.00V (6000).

Analog Calibration24

Low V

Low Unit

High V

High Unit

Enable

Alarm Actions

Battery A (POS V)

6000

Battery B (POS V)

6000

Battery A (NEG V)

-6000

6000

Battery B (NEG V)

-6000

6000

RSSI V / RSL25

V = -70 dBm

-7000

V = -40 dBm

-4000

Tx PWR V / TX PWR26

V = 0.1 W

V = 1.8 W

140

Analog Threshold

Very Low

Low

High

Very High

Deadband

Battery A or B (24V)

2000

2100

2850

3000

Battery A or B (48V)

4000

4200

5700

6000

Severity

Critical

Minor

Major

RSSI V / RSL Value

-7500

-7000

-3000

-2500

Severity

Major

Minor

Info

Minor

Tx PWR V Value

160

500

Severity

Major

Info

Minor

24 Analog Calibrations use ACU Real-World Values™ conversion or translation to change measured voltages

into more meaningful values. Conversions use a 2-point match and then interpolate and extrapolate resultant

values. RSL and PWR voltages have some deviation from linear curves and thus, there is some amount of error

at other than the Low V and High V matching points.

25 RSSI / RSL values are derived from the Test Data Sheet.

26 Tx PWR values are derived from the Test Data Sheet.

R-

-1

HR-11500 Operations Manual Chapter 6. ACU – SNMP Module Setup — 63

Figure 35 ACU Events - Contacts Settings Screen

Contact

Closures

Alarm

State

Active

State

Severity

In-Active

Alias

Active

Alias

Alarm

Actions

HET DC

CLOSED

MAJOR

SQUELCH

CLOSED

MINOR

CLOSED

CRITICAL

Locked

UnLocked

DOOR27

CLOSED

INFO

Cerrado

Abierto

27 DOOR alias names are used to reduce confusion between Active State (Door Switch Closed) and physical

Door Open condition. Other favorite alias names may be used.

R-

-1

— Chapter 6. ACU – SNMP Module Setup HR-11500 Operations Manual

Alerts Screen

Figure 36 ACU Alert Settings, General Settings Screen

General Settings: “Submit” to send the settings to the HR-ACU.

System Alert

Actions

Sets the action(s) taken when the Power-Up Alert is triggered, if enabled.

Alarm actions are configured as Tn where n corresponds to the SNMP Manager index

number on the SNMP Alerts tab. Email actions are configured as En where n

corresponds to the Email Address index number on the Email Alerts tab. Multiple

actions are listed with no delimiters, for example: T1T2E1E3. These can be changed

as required. See Alerts screen.

Power-Up Alert

An ON/OFF toggle to enable an alert to be sent whenever the HR-ACU goes from

powered-down to power-up state. Default setting is OFF.

Individual Alert

Repeat

Frequency

Sets the number of minutes (0 – 65535) between repeat alert notifications. This applies

to ALL alerts for ALL enabled events. 0 means no repeat alert notifications are sent.

Default setting is 0.

Send Return to

Normal Alerts

This is an ON/OFF toggle to send an alert when an event returns to it’s "normal“ or

"inactive“ state. The alert is sent via the same alert or alarm actions that are configured

for the event itself. Default setting is ON.

R-

-1

HR-11500 Operations Manual Chapter 6. ACU – SNMP Module Setup — 65

Figure 37 ACU Alerts Settings, Email Alerts Screen

Email Alerts Settings: “Submit” to send the settings to the HR-ACU.

SMTP Server IP

Address

IP Address of the outbound mail server.

Email Domain

Name

Sets the @domain_name.com to use when the HR-ACU sends an Email Alert.

Maximum length is 48 characters.

SMTP

Authentication

This is an ON/OFF toggle to allow Emails to be sent to SMTP servers that require

authentication. The Username and Password fields below set the credentials for

successfully logging into the SMTP server.

Username,

Password

Sets the login credentials for SMTP Authentication. Maximum length is 32 characters.

Email Add n

Sets the Email address of the person or entity receiving Email Alerts. The number

(1~4) corresponds to the “index” number for Email Alerts used when configuring alarm

actions.

Send Test

Click the Test button to send a test Email to each configured Email address.

R-

-1

— Chapter 6. ACU – SNMP Module Setup HR-11500 Operations Manual

Figure 38 ACU Alert Settings, SNMP Alerts Screen

SNMP Alerts Settings: “Submit” to send the settings to the HR-ACU.

SNMP

Manager n

Sets the IP address of the device(s) receiving SNMP Traps when the HR-ACU sends a

trap as an alarm action.

Sent Test Trap

Click the Test button to send a test SNMP Trap to each configured SNMP Manager.

R-

-1

HR-11500 Operations Manual Chapter 6. ACU – SNMP Module Setup — 67

Administration Screen

Figure 39 ACU Administration Screen

Firmware

Update

The Firmware File field allows the user to set, via direct entry or the Browse button, the

path to the firmware update file (i.e. ACU_1.00.111.udf). Once the path has been set,

press the Upload button to begin the immediate upload and processing of the update

file. Note that all LEDs are turned on after the update file is transferred; they stay on

until after the update completes, which is normally about 15 seconds.

Reset Unit

Clicking the Reset button immediately resets the ACU.

All configurations are preserved.

Reset

Parameters

Clicking the Reset Parameters button immediately resets all configurations except

Networking Settings to their default settings.

Reset ALL

Parameters

Clicking the Reset ALL Parameters button immediately resets all configurations,

including Networking Settings, to their default settings. Since the web session will be

disconnected, the IP address must be reset using OmniDiscover or the ARP/Ping

method, as described in the Accessing the unit via the Web Interface section

previously. See Resetting Defaults section for more information on resetting all

parameters using DIP switches and the physical Reset button.

Upload Settings

to Unit

Allows the user to upload the “Setting Keys” file to the ACU. Use the Browse button to

specify the path to the file. (i.e. Setting Keys.txt). Once the path has been set, click the

Upload button to begin the immediate upload of the Setting Keys file.

Download

Settings from

Unit

Allows the user to download the “Setting Keys” file from the ACU. Right-click the

“Get Settings Now” link and choose “Save Target As” from the menu to select the

location where the Setting Keys file should be saved. See the section on Setting Keys

for an example of a default Setting Keys file.

R-

-1

— Chapter 6. ACU – SNMP Module Setup HR-11500 Operations Manual

Resetting Defaults

Refer to Figure 40, ACU Rear Panel. The ACU must be removed from the Heterodyne Repeater to

adequately access the rear panel.

All settings, including network settings, can be set to their default values using this procedure:

 Set all DIP switches to the OFF (down) position

 Briefly press the Reset button until the front-panel LEDs start flashing. Let go of the button as

soon as the LEDs start flashing; if the button is pressed in too long, the unit will reset and the

default settings operation may not complete.

The web login username and password settings can be reset to their defaults (admin/password),

without affecting any other settings, by using a similar procedure:

 Counting from left to right, set the first three DIP switches to the OFF (down) position, and set

the fourth DIP switch to the ON (up) position.

 Briefly press the Reset button until the front-panel LEDs start flashing. Let go of the button as

soon as the LEDs start flashing; if the button is pressed in too long, the unit will reset and the

operation may not complete.

Figure 40 ACU Rear Panel

Settings Keys

Setting Keys (SK) provide a flat file, human readable means of setting and retrieving settings within

the unit. Setting Keys are commonly used to clone settings across multiple units or in automated

processes. The SK file can be downloaded from an S420, settings changed and saved. Then the file

can be uploaded to the same or other HR-ACU’s. Settings that are changed to invalid values or to

settings that are ‘read-only’ will not be applied then uploaded to the HR-ACU.

R-

-1

HR-11500 Operations Manual Chapter 7. Maintenance and Troubleshooting — 69

Chapter 7. Maintenance and Troubleshooting

The HR-11500 active components are the linear heterodyne RF module, 10 MHz reference oscillator,

Alarm Control Unit, DC/DC converters and the optional media converter equipment if equipped.

Heterodyne Repeaters provide long field operating life, often 15 to 20 years. Technologies and traffic

needs often drive upgrades or replacement rather than old age.

Routine maintenance checks of the heterodyne repeater and its supporting equipment will ensure

reliable operation and early detection of problems.

Routine Maintenance

Peninsula Engineering Solutions recommends an annual maintenance schedule for the heterodyne

repeater. The following is a procedure for routine maintenance:

1. Observe the general condition of the installation site and correct any problems.

2. Verify that the heterodyne repeaters and all associated hardware, including antennas, are

securely mounted and properly in place.

3. Check input electrical wiring and power system for damage and ensure that connections are

tight. Replace any wiring that is suspect.

4. Check any battery terminals for corrosion; clean terminals, if necessary.

5. Check the battery storage capacity condition. Battery impedance testers are recommended.

Battery life expectancy is typically 5 to 10 years in an outdoor environment. Replace any weak

batteries or cells.

6. Clean solar panels and remove obstructions, if applicable. A mild detergent

and water are recommended. Clean solar panels when they are cool, avoid

putting cold water on hot panels, this may cause damage. Dirt, thick dust

and bird droppings can reduce the output by 30%. Shadows from antennas,

lightning rods or trees reduce PV output. Life expectancy of PV arrays is

20 years or more. Horizontally tilted panels collect more soils than if tilted 45° or more. Lower tilt

panels should be cleaned annually. Greater tilt panels may be cleaned every 3 years.

CAUTION: Follow manufacturer’s instructions when cleaning solar panels. Abrasive or acetone-

based solutions can cause damage.

7. Look for lightning strike damage. Solar panels with “holes” punched in

the backing material indicate a lightning strike. Damaged solar panels

or equipment should be replaced.

8. Check antennas and feedlines for damage and ensure that connections

are tight.

9. If the feedlines are pressurized, check that pressure is holding correctly, dehydrators are working

or Nitrogen gas tanks are full.

10. If static desiccators are used to dry the feedlines, check the desiccant color. Blue or Orange is

normal, Pink indicates the desiccant is full of water and needs changing. Static desiccators

should be changed typically, about every 1 to 2 years.

11. If feedline pressure is zero or desiccants are very pink, it’s best to check the feedlines for water.

Drain and dry as required. Inspect for corrosion, correct or replace as required.

12. Check the alarm control unit, ACU, for indications of alarms or trouble.

13. Observe the Receive Signal Level by measuring the RSSI / RSL Voltage at its BNC connector.

Refer to HR-11500 Test Data Sheet for signal level value. Compare to records.

R-

-1

— Chapter 7. Maintenance and Troubleshooting HR-11500 Operations Manual

14. Observe the Transmit Power Level by measuring the Tx PWR Voltage at its BNC connector.

Refer to HR-11500 Test Data Sheet for power value. Compare to records.

15. Measure the DC battery load currents. Compare to records.

Administrative Requirements

The US FCC, Federal Agency or other local Telecommunications Administrations may require

measurement of the output power of the heterodyne repeater at installation or when any changes are

made which cause the output power to change. Using the power meter method, measure and log the

output power as directed in Chapter 5.

Troubleshooting

Reported alarms may appear in combination due to the root cause. The alarm matrix, Table 19

provides information about the probable cause. Assumes an IF repeater configuration of

2 heterodyne units.

Table 19 Alarm Matrix

IDX

ALARM

HET

SQL

DOOR

BATT

RSL

PWR

CAUSE

Squelch disables PA and causes HET

DC, TX PWR. RSL if low signal level.

Very low RSL or far end transmitter

OFF will cause Squelch to activate.

LO fault causes mixer fault thus RSL,

SQL, HET DC, and TX PWR. Check

10 MHz reference signal.

No DC path on IF IN, IF Cable Fault

Detect, thus HET DC and TX PWR.

See #13.

Heterodyne RF Module – Current out

of range. Most likely PA section fault.

LO UnLocked. Possibly off frequency.

Het RF Module has 4 synthesized

LOs. Any LO can cause alarm.

Enclosure door open, door switch

closed. No other alarms should be

caused.

Battery A voltage out of range but not

to failure point. HR operating on

Battery B.

Battery B voltage out of range but not

to failure point. HR operating on

Battery A.

Battery A & B voltage out of range but

not to failure point. Single Battery

supply. HR close to failure.

R-

-1

HR-11500 Operations Manual Chapter 7. Maintenance and Troubleshooting — 71

Table 19 Alarm Matrix, continued

IDX

ALARM

HET

SQL

DOOR

BATT

RSL

PWR

CAUSE

Battery A & B voltage very low.

DC/DC converter power supply output

low. HR failing now due to

low voltage.

Receive signal level out of range, low

or high. Possible signal fade if low.

Transmit power level out of range, low

or high.

Possible PA fail. If Low: no or low IF

IN signal level.

Transmit power level low but not zero.

PA current out of range. Possible PA

section failure.

Heatsink Temperature out of range,

low or high.

If the received signal at the terminals is low but does not indicate a complete failure on heterodyne

repeater, then, the most likely cause is low voltage from the batteries. Low voltage is an indication of

a possible DC/DC converter power supply failure, battery failure, or a failure of the charging system.

Check the batteries and all power lead connections. If solar panels are used, be sure they are not

obstructed from sunlight and that the surfaces are clean. If an AC power supply is used, low voltage

is probably the result of a power failure, the duration of which exceeded the reserve power limits of

the standby battery. Check the standby battery in accordance with the instructions given by the

manufacturer of the power supply.

NOTE: Contact the Customer Service Department of Peninsula Engineering Solutions whenever

problems with the unit cannot be resolved.

R-

-1

— Chapter 7. Maintenance and Troubleshooting HR-11500 Operations Manual

Table 20 System Troubleshooting

Problem

Cause

Solution

Overheating

Inefficient Cooling

 Clear any airflow obstructions.

 Shade the unit if it is in an extremely hot

environment.

Low Voltage or

No Voltage

(Low Battery

Alarm)

Improper Solar Charging

 Clean solar panels or remove obstructions.

 Do not use an acetone-based solution for cleaning.

Power Supply Failure

 Check the condition of the power source.

 Check all wiring and power leads to the power

source.

 Check any fuses or circuit breakers in power supply

equipment.

 Check condition of battery plant.

 Check AC power service for outages or other service

problems.

Overload, blown fuse

 Determine the cause of failure.

 Correct the failure.

 Replace fuse with a spare.

Internal DC/DC Converter

Failure

 Cycle the DC Battery input power to reset and restart

the converter. The converter has built-in safety

shutdown circuits. Output bus is 12.5 VDC.

 Contact Peninsula Engineering Solutions to

replace unit.

Heterodyne

Repeater fails

overnight and

then restarts the

next day

(Solar Powered)

Improper PV Charging

 Check the PV array for damage, obstructions or dirt.

PV Array wired to wrong

voltage

 Check the PV open circuit voltage, Voc.

 Typically the Voc will be 1.5 to 2 x the battery nominal

voltage. If Voc is more than 3 x the battery nominal

voltage and PWM28 type PV controllers are used, the

array is mis-wired.

 Voc may be greater only if MPPT29 type PV controllers

are used.

Alarm Conditions

 Check for alarm conditions and resolve, if necessary.

Battery capacity low

 Batteries may be worn out or undersized, replace and

correct as necessary.

Prolonged storms

 Storms or series of storms can reduce battery recharging for

days. Batteries may be fully discharged causing the system

to fail. Re-evaluate the power source capacity, increase the

PV array or add wind turbine generators, increase the

battery plant Ah capacity.

28 PWM: Pulse Width Modulator. PV Controller type that uses a rapid switch to reduce the average

charging current when batteries are fully charged. PV Array Voc should be 1.25 to 2.0 x the

nominal battery voltage. Higher Voc can indicate the array is mis-wired (series instead of

parallel) resulting in less charging current and power.

29 MPPT: Maximum Power Point Tracking. PV controller type includes a DC/DC converter to

“step down” higher voltage PV arrays. Maximum Voc is limited to the maximum rating of the

MPPT controller, typically 150 to 200 VDC.

R-

-1

HR-11500 Operations Manual Chapter 7. Maintenance and Troubleshooting — 73

Table 20 System Troubleshooting, continued

Problem

Cause

Solution

Low RF Output

- or –

No RF Output

Power Amplifier power level

not set

 Set the power amplifier output power level per radio

modulation.

Antennas Oriented or

Polarized Incorrectly

 Check antenna orientation and re-align, if necessary.

 Confirm the correct polarizations are used.

Alarm Conditions

 Check for alarm conditions and resolve, if necessary.

Power Amplifier Failure

 Replace the Heterodyne RF Module.

Terminal radio OFF

 Confirm the terminal radio is transmitting.

Improper gain setting

 Check gains and re-set, if necessary.

RF Output

cannot be set

IF Input level LOW

 Confirm the terminal radio or previous repeater is

transmitting.

 Confirm frequencies and polarizations match. Refer

to path calculations for expected levels.

RF or IF Amplifier low gain

failure

 Damage to an amplifier can cause low gain which in

turn will reduce the available RF output power.

 Replace the Heterodyne RF Module.

No Receive

Signals at

both ends

Problem Common to both

directions.

 Check items in common with both directions of

transmission. Antennas, Feedlines, Site Power or

Multiple Failures.

 Check Feedline connections; confirm correct

heterodyne unit to antenna direction. Feedline

reversal will result in no signals at the ends and input

to the heterodyne repeater amplifiers due to the

bandpass channel filters.

Antennas Oriented or

Polarized Incorrectly

 Check antenna orientation and re-align, if necessary.

 Confirm the correct polarizations are used.

Radio Errors and

Distortion, BER,

high EVM or

low S/N, SNR

Active Alarm

 Resolve alarm.

Improper Gain Settings

 Correctly adjust Tx Power level.

Power Amplifier level

too high

 Adjust the Tx Power level to recommended levels.

 If errors persist, try reducing the power by 1 dB more.

MW Radio terminal power

too high

 Check radio transmit power level, adjust to

recommended levels.

 If errors persist, try reducing the power by 1 dB more.

Radio Adaptive Equalizer

setting or disabled

 Enable adaptive equalizer. Check settings.

Radio Forward Error

Correction, FEC,

setting or disabled

 Enable FEC. Check settings on FEC bit length. FEC

can correct low error rates but will add latency.

R-

-1

— Chapter 7. Maintenance and Troubleshooting HR-11500 Operations Manual

Heterodyne RF Module Replacement

Heterodyne Repeater RF Modules are band segment and channel plan specific. These modules

must be configured for the channel pair assigned to the heterodyne repeater and must match the

bandpass filters in the Antenna Coupling Unit. Modules with the same part number can be used as

replacements. Configure the replacement module’s frequency, Tx power level and squelch before

installing in the heterodyne unit if possible. See Chapter 5: Configuring the Heterodyne RF Module.

When a heterodyne RF module must be replaced, do the following:

a) Power down the heterodyne repeater unit.

b) Unplug module’s power connector.

c) Disconnect input and output SMA semi-rigid cables.

d) Disconnect the IF input and output SMA flexible cables.

e) Disconnect the Reference Oscillator SMA flexible cable.

f) Disconnect the BNC cables from RF Out Level and RSSI (ALC) monitor points.

g) Remove mounting hardware (8 ea #6-32 screws and washers). Hardware uses Socket Head

Cap screws. The socket head cap screw hardware takes a 3/32 or 7/64-inch Hex Allen

Wrench.

h) Remove module.

To install the replacement module:

a) Apply heat sink compound to the mounting surface of the amplifier. Use a very thin layer.

b) Mount the module on the heatsink panel, secure with mounting hardware.

c) Connect the two BNC cables to DC monitor points.

d) Connect input and output SMA flexible and semi-rigid coax cables. Use care to align the SMA

connector. Misaligned connectors can destroy the center pins.

e) Check all coax connections for tightness (8-inch/lbs)

f) Plug-in the module's power connector.

g) Power up the heterodyne repeater unit.

h) Verify operation by measuring power at SMA power monitor, PWR MON.

i) Set output power by adjusting Tx Power Level switch per Chapter 5.

j) Confirm the Transmitter power alarm clears. Adjust the Tx Power calibration as required.

ii) Power Amplifier’s RF Detector DC sensitively and output can vary, thus requiring

calibration adjustment.

k) Receiver RSSI V typically varies somewhat, thus RSSI V calibration is required. Calibrate the

ACU readings at -40 dBm and -70 dBm. For best results, use QAM signals. See Chapter 6,

ACU-SNMP Module Setup.

R-

-1

HR-11500 Operations Manual Chapter 7. Maintenance and Troubleshooting — 75

Reference Oscillator Replacement

Reference oscillators are all 10 MHz modules with four equal primary outputs and one monitor port.

Modules with the same part number can be used as replacements. No configuration is required.

Removing the Reference Oscillator Module:

a) Power down the heterodyne repeater unit.

b) Unplug the module’s DC power connector.

c) Disconnect the SMA flexible cable from the output used.

d) Remove the mounting screws (4 ea #6-32 pan head Philips screws and washers.)

e) Remove module.

To install the replacement module:

a) Orient the module with the power connector cable on top.

b) Mount the module on the heatsink panel, secure with mounting hardware.

c) Connect the SMA flexible cable. Normally the cable connects to J4. Use care to align the

SMA connector. Misaligned connectors can destroy the center pins.

d) Check the coax connection for tightness (8-inch/lbs)

e) Plug-in the module's power connector.

f) Power up the heterodyne repeater unit.

g) Verify operation by measuring frequency and level at SMA Monitor “MON”. Frequency30

should be 10.000 000 00 MHz ± 2 Hz. Level at monitor is between 0 and -6 dBm.

a. Level at the primary outputs J1 ~ J4 is between +3 and +8 dBm.

30 Frequency Counter must be capable of at least 1 Hz precision and have a frequency standard

reference sufficiently accurate to measure the reference oscillator output.

R-

-1

— Chapter 7. Maintenance and Troubleshooting HR-11500 Operations Manual

ACU – SNMP Module Replacement

Alarm Control Modules are the same physical unit for all HR-11500 repeaters. Each module is

program configured for the particular heterodyne repeater unit. If the settings file was saved from the

previous ACU, it may be uploaded to the replacement module. Otherwise, follow the instructions in

Chapter 6 for configuring the HR-ACU module.

Removing the ACU – SNMP Module:

a) Power down the heterodyne repeater unit.

b) Reach behind the ACU module and remove the power plug and 16-position plug-in connector

strip. Both pull out to the rear.

c) Remove the mounting screws holding the left and right brackets to the heatsink panel.

Hardware used is 4 ea #8-32 pan head Philips screws and washers. Note the location of the

ground lug.

d) Remove the support brackets from the bottom of the ACU module. Hardware used is 6 ea

#4-40 pan head Philips screws and washers.

e) Remove the ground lug from the side of the module.

f) Unplug the Ethernet cable from the jack on the rear of the module.

g) Remove the temperature sensor probe from the heatsink panel. The probe is secured with an

adhesive strip. Epoxy may also secure the temperature probe, use a knife to carefully cut the

adhesive strip or shrink sleeve around the probe.

To install the replacement module:

a) Attach the left and right mounting brackets to the module using #4-40 hardware.

b) Attach the ground lug to the side of the module.

c) Plug-in the Ethernet cable, 16-position connector and power plug to sockets on the rear.

d) Mount the module’s mounting brackets to the heatsink panel using #8-32 hardware.

Remember to include the ground lug.

e) Locate and mount the temperature sensor probe on the heatsink panel using the adhesive

strip provided. Epoxy may be added to secure the temperature probe. The adhesive can

otherwise loosen at higher temperatures.

f) Power up the heterodyne repeater unit.

g) Verify operations by observing the front panel LEDs.

h) Configure the replacement ACU if required per Chapter 6 or load the previous settings file.

R-

-1

HR-11500 Operations Manual Chapter 7. Maintenance and Troubleshooting — 77

DC/DC Converter Power Supply Assembly Replacement

The DC/DC converter power supply assemblies are available in 4 types based on input voltage and

power rating. Assemblies with the same part number can be used as replacements. There are two

power supply assemblies in standard heterodyne repeater units, A on left and B on right.

Removing the Power Supply Assembly

a) Power down the heterodyne repeater unit.

b) The B power supply is blocked by the door switch. Remove the door switch first. The switch

assembly is secured to the enclosure using 2 ea #6-32 screws and washer hardware.

c) Unplug the input and output cables from the DC Power Distribution PCB assembly.

d) Remove the nuts securing the assembly to the inside wall of the enclosure. Hardware is 6 ea

#10-32 nuts with nylon patch.

e) Slide the power supply assembly off the studs and remove from the enclosure.

Installing the replacement assembly

a) Slide the power supply assembly over the 6 studs on the enclosure wall and then secure with

#10-32 nuts.

b) Plug-in the input and output cables to the DC Power Distribution PCB assembly. The plugs

are size and orientation keyed.

c) Replace the door switch assembly over the B power supply.

d) Power up the heterodyne repeater unit.

e) Verify operation by measuring the power supply’s output voltage. Voltage at the output

connector, (DC Power Distribution J5, J6), should be 12.5 VDC ± 0.2V.

Keeping Spares

Because microwave heterodyne repeaters are often used to provide critical coverage, customers are

advised to follow a sparing policy. While most telecommunications carriers or system operators have

internal policies relative to equipment sparing, in the event that one does not exist, Peninsula

Engineering Solutions recommends maintaining a minimum of one (1) spare unit for every increment

of 8 units or fraction thereof. This assumes that all spares are immediately available to the technician

in need for installation. Remember that heterodyne RF modules are band plan specific.

When travel time to a site is long or access is difficult (helicopter, hike or horse), then, more spares

located close to or at the repeater site are recommended. Maintain stored spares in anti-static

packaging. Storage locations should be dry and protected from salt air or corrosive atmospheres.

Each organization should develop a company-specific, equipment-specific policy that meets their

needs, taking into account geographic considerations and the quantity of repeaters used in the

network.

R-

-1

— Chapter 7. Maintenance and Troubleshooting HR-11500 Operations Manual

Returning the Heterodyne Repeater Equipment for Repair

If a repair or return of the HR-11500, or its components, is necessary, contact the Peninsula

Engineering Solutions Customer Service Department for instructions. When calling, include the

following information:

 Nature of the problem

 Model name

 Part Number

 Unit serial number

For equipment returns, a representative issues an RMA (Return Material Authorization) and shipping

and packaging instructions. When returning the repeater to Peninsula Engineering Solutions, always

use the original shipping carton and packaging materials or suitable equivalents. If the original

shipping materials are unavailable, Peninsula Engineering Solutions can send replacement materials

at your cost.

CAUTION: If equipment is not returned to Peninsula Engineering Solutions in the original packaging

materials, possible damage could result. Peninsula Engineering Solutions is not liable for

any damage resulting from improper shipment.

The telephone number and email for the Customer Service Department follows:

 Telephone: +1 925 901-0103

 E-mail RMA Administrator: rma_admin@peninsulaengineering.com

 Internet, Online RMA Form: http://www.peninsulaengineering.com/sup_rma.html

Product Warranty

A one-year, limited warranty is provided with the repeater. A copy of the product warranty is included

with the Standard Terms and Conditions. Extended warranties are available for continued protection.

For more information, contact the Peninsula Engineering Solutions Customer Service Department.

Peninsula Engineering Solutions, inc.

39 Grand Canyon Lane

San Ramon, California 94582

United States of America

http://www.peninsulaengineering.com/

R-

-1

HR-11500 Operations Manual Maintenance Record — 79

Table 21 HR-11500 Maintenance Record

Date

PV-A Voltage, Voc

PV-A Voltage, Vcharge

PV-B Voltage, Voc

PV-B Voltage, Vcharge

Rectifier/Charger-A Current

Rectifier/Charger-B Current

Battery-A Voltage

Battery-A Temperature

Battery-A Charge Current

Battery-A Load Current

Battery-B Voltage

Battery-B Temperature

Battery-B Charge Current

Battery-B Load Current

Power Amplifier PWR MON

Tx PWR VOLTS

Receive RSSI VOLTS

Reference Oscillator FREQ

ACU Tx PWR, WATTS

ACU RSL, dBm

R-

-1

— Chapter 7. Maintenance and Troubleshooting HR-11500 Operations Manual

THIS PAGE INTENTIONALLY LEFT BLANK

R-

-1

HR-11500 Operations Manual Appendix — 81

Appendix

1. M900-0530-XX HR-11500 Mounting Dimensions Drawing

508

20.0

3.2

3.0

457

18.0

1.5

1.1

547

21.6

457

18.0

2 3

POWER CONDUIT (2)

1/2 INCH, 13 mm

AUX "N" HOLE

229

9.0

289

11.4

WAVEGUIDE ANTENNA PORT

CPR90G

.7 18

THRU

4 PLACES

.5 13

THRU

4 PLACES

NOTES:

CONNECTORS ON TOP AND BOTTOM HAVE PROTECTIIVE COVERS INSTALLED

WHEN READY TO SHIP. MAXIMUM DIMENSIONS INCLUDE COVERS.

LIFTING PLATES MAY BE MOUNTED INVERTED FOR SHIPMENT.

LIFTING PLATES SHOULD BE INVERTED AFTER INSTALLATION ON TOWER.

WEIGHT IS APPROX 70 LBS, 32 KG.

HR-11500

900-0530-XX

900-0531-XX

900-0532-XX

PROPRIETARY AND CONFIDENTIAL

NEXT ASSY

USED ON

APPLICATION

DIMENSIONS ARE IN INCHES

TOLERANCES:

FRACTIONAL

ANGULAR: MACH

BEND

TWO PLACE DECIMAL

THREE PLACE DECIMAL

INTERPRET GEOMETRIC

TOLERANCING PER:

MATERIAL

FINISH

PER SPEC

DRAWN

CHECKED

ENG APPR.

MFG APPR.

Q.A.

COMMENTS:

DATE

NAME

TITLE:

SIZE

DWG. NO.

REV

WEIGHT: 69.39

SCALE: 1:12

UNLESS OTHERWISE SPECIFIED:

ERJ

12/24/12

HR-11500 HET RF UNIT

MOUNTING DIMENSIONS

SHEET 1 OF 1

M900-0530-XX

DO NOT SCALE DRAWING

THE INFORMATION CONTAINED IN THIS

DRAWING IS THE PROPERTY OF

PENINSULA ENGINEERING SOLUTIONS.

ANY USE OR DISCLOSURE IN WHOLE OR IN

PART WITHOUT THE WRITTEN PERMISSION

OF PENINSULA ENGINEERING SOLUTIONS

IS PROHIBITED.

www.peninsulaengineering.com

PENINSULA ENGINEERING SOLUTIONS, INC.

SAN RAMON, CALIFORNIA, USA

Peninsula Engineering Solutions HR-11500 HR-11500 Microwave Linear Heterodyne Repeater User Manual HR 11500 MW Heterodyne Repeater

Peninsula Engineering Solutions, inc. HR-11500 Microwave Linear Heterodyne Repeater HR 11500 MW Heterodyne Repeater

Users Manual

Navigation menu

Namespaces

Views

Navigation