Motorola 89FC3795 Users manual

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Operational or User’s Manual

The manual should include instruction, installation, operator, or technical manuals with required ‘information to the users’. This manual should include a statement that cautions the user that changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment. The manual shall include RF Hazard warning statements, if applicable.

The instruction and service manual for this base radio are not published at this time. However, draft copy of available manual information has been assembled and has been included as part of this filing package.

Upon request, published manuals will be sent to the commission and/or telecommunication certification body (TCB) as soon as they become available. All of the descriptions, block diagrams, and schematics that are included in this filing package are current as of the package submittal date.

EXHIBIT DESCRIPTION

D1-1 Manual Front Matter (Draft) D1-2 Specifications (Draft) D1-3 Field Replaceable Units and Orderable Parts (Draft) D1-4 Tune-Up Procedure (Draft) D1-5 Racking Configurations (Draft) D1-6 Functional Description / Operation of Modules (Draft)

EXHIBIT D

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Manual Front Matter (Draft)

EXHIBIT D1-1

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Manual Front Matter (Draft, Continued)

EXHIBIT D1-1

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Manual Front Matter (Draft, Continued)

EXHIBIT D1-1

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Manual Front Matter (Draft, Continued)

EXHIBIT D1-1

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Specifications (Draft)

General Performance

Model T3000 Number of Channels 16 Frequency Generation Synthesized H x W x D 5.25" x 19" x 16.5" (133x483x419mm) Weight 40 lbs (19 kg) Power Requirements

AC: 85-264 VAC, 47-63 Hz Standy 0.4A, Rated Power 3.3A @ 117 VAC DC: 21.6 - 32 Volts DC Standy 1.0A, Rated Power 11.5A @ 28 VDC

Temperature Range -30 to 60 °C (-22 to 140 °F) Input / Output Impedance 50 ohms Antenna Connectors Tx / Rx N-Type Modes of Operation Half-Duplex / Duplex

Frequency Band 136 - 174 MHz

Internal Frequency Stability 1.5 PPM External Reference Capable Yes Channel Spacing 12.5 kHz, 25 kHz

Transmitter

Frequency Range 136-174 MHz Rated Output Power 25 - 100 Watts, Variable Intermodulation Attenuation 55 dB Adjacent Channel Power -75 dBc (25 kHz) / -60 dBc (12.5 kHz) Wideband Noise (1 MHz) -152 dBc/Hz Rated System Deviation 5 kHz (25 kHz) / 2.5 kHz (12.5 kHz) Audio Distortion <3% FM Hum and Noise 50 dB (25 kHz) / 45 dB (12.5 kHz) Spurious Harmonic Emissions Attenuation

-90 dBc

FCC Type Acceptance

FCC Identifier: Frequency Range Type Power Output

ABZ89FC3795 136-174 MHz Transmitter Variable 25-100 W ABZ89FR3796 136-174 MHz Receiver N/A

EXHIBIT D1-2

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Field Replaceable Units and Orderable Parts (Draft)

Motorola provides the following approved accessories to improve the productivity of your base station / repeater. For a list of Motorola-approved accessories, visit the following web site:

http://www.motorola.com/governmentandenterprise

MOTOTRBO MTR3000 Ordering Guideline

Model Description

T3000 MTR3000 Base Station/Repeater X330MT VHF 100W Power (136–174 MHz) X340MT UHF 100W Power (403–470 MHz) X540MT UHF 100W Power (470–524 MHz) X450MT 800 MHz 100W Power (806–870 MHz) X460MT 900 MHz 100W Power (896–941 MHz)

X182VL Duplexer, UHF 136–146 MHz X182VM Duplexer, UHF 144–160 MHz X182VN Duplexer, UHF 158–174 MHz X182UL Duplexer, UHF 403–435 MHz X182UM Duplexer, UHF 435–470 MHz X182UN Duplexer, UHF 470–494 MHz X182UH Duplexer, UHF 494–512 MHz X182EB Duplexer, 800 MHz

X265VL Preselector, VHF 136–154 MHz X265VL Preselector, VHF 150–174 MHz X265UL Preselector, UHF 380–435 MHz X265UM Preselector, UHF 435–470 MHz X265UH Preselector, UHF 470–524 MHz

X676VL Circulator, VHF (136–146 MHz) X676VM Circulator, VHF (144–160 MHz) X676VH Circulator, VHF (158–1 74 MHz) X676UL Dual Circulator, UHF (403–470 MHz) X676UH Dual Circulator, UHF (470–524 MHz) X676EB Circulator, 800 MHz

X216AR 4-Wire Wireline X371BA Antenna Relay (

X189AA Power Cable, Europe X162AD Power Cable, UK X191AD Power Cable, Australia CA01520AA Power Cable, DC

U178AB Cabinet Mount Hardware X153BA Rack Mount Hardware

X244AF Auxiliary System Cable X244AG Community Base Station/Repeater Panel Cable X244AH Phone Patch Cable C540AD System Connector Cable

HKLN4439_ MTR3000 Capacity Plus Software Upgrade X347AF Manual Install and User CD

Customer Replaceable Power Cables for Standalone Base Radio

Part Number Description

TRN7663A Power Cable, North America TRN7755A Power Cable, Continental Europe TTN5049A Power Cable, UK / Ireland TTN5103A Power Cable, Australia

Note: Antenna Relay is not compatible if ordering X182, Duplexer)

EXHIBIT D1-3

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Field Replaceable Units and Orderable Parts (Draft) (Continued)

MOTOTRBO MTR3000 Field Replaceable Units

Model Description Model Description

DLN6710_ 100W PA, VHF 136-174 MHz DLN6701_ 100W PA, UHF 403–470 MHz DLN6712_ Exciter, VHF 136-174 MHz DLN6702_ 100W PA, UHF 470–5 24 MHz DLN6713_ Receiver, VHF 136-174 MHz DLN6703_ Exciter, UHF 4 03–470 MHz DLN6714_ 100W PA, 800/900 MHz DLN6704_ Exciter, UHF 450–524 MHz DLN6715_ Exciter, 800/900 MHz DLN6705_ Receiver, UHF 403–470 MHz DLN6716_ Receiver, 800/900 MHz DLN6706_ Receiver, UHF 450–524 MHz

DLN6707_ AC/DC Power Supply DLN6719_ Station Control TCXO DLN6718_ Station Control OCXO

CLN8629_ MOTOTRBO MTR3000 Installation and User CD X347AF Manual Install and User CD

Note The Manual Install and User CD contains:

• MOTOTRBO MTR3000 Installation and User Manual (Including MTR2000 to MTR3000 MOTOTRBO Upgrade Kit)

• MOTOTRBO MTR3000 Basic Service Manual

Microphones/Speakers Model Description

GMMN4063 Noise Cancelling Mic 0185180U01 Cable For Exte rnal Speaker HSN1006 Speaker

Miscellaneous Accessories Model Description

RRX4025 ISB50LNC2 Bulkhead Arrestor 125-100 RRX4032 T-1 ISB50 Series Round Member Mount RRX4021 Lightening / Surge Arrestor RRX4034 Lightening / Surge Arrestor (110/220V AC Line Surge Protector) TRN4589 Dual Line Suppressor 3083908X02 Cable, Field System Adapter

CLN1317* Antenna Relay CLN1316** Antenna Relay For Preselector

Note (*) Includes Antenna Relay and required cables for stations without X265, Preselector (**) Includes Antenna Relay and required cables for stations that include X265, Preselector

CKN1039* Preselector Cable Kit CKN1040** Preselector Cable For Antenna Relay

Note (*) Order this cable for stations without X371, Antenna Relay (**) Order this cable for stations with X371, Antenna Relay

Cabinets/Racks and Hardware Model Description Model Description

THN6700 12 inch Indoor Cabinet THN6752 30 inch Modular Rack (16 RK U) THN6701 30 inch Indoor Cabinet THN6753 45 inch Modular Rack (24 RK U) THN6702 46 inch Indoor Cabinet THN6754 52 inch Modular Rack (27 RK U) THN6788_ Slides Motorola Cabinet CLN6833_ Slides Non-Mo torola Cabinet CLN6679_ Rack Mount Hardware

EXHIBIT D1-3

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Tune-Up Procedure (Draft)

See the following manual excerpts (Chapter 10 and Chapter 13 of MOTOTRBO MTR3000 Base Station / Repeater, Basic Service Manual) for instruction on performing the field digital upgrade, operational verification,

and programming / tuning. All adjustments are software controlled and are pre-set at the factory. Certain station operating parameters can be

changed using Customer Programming Software (CPS), within predetermined limits. Examples include transmit / receiver operating frequencies and transmitter power level.

After the base station / repeater and ancillary equipment have been mechanically installed, properly cabled, and power applied, the equipment must then be optimized; that is, before placing the base station / repeater in operation. The cable required is a standard “USB A to B” cable. Optimization is performed through the Customer Programming Software (CPS), kit number RVN5115.

After the base station / repeater is operational, the base station / repeater’s codeplug data must be copied to a PC- compatible computer.

Optimization involves the following tasks:

1. Reading the base station / repeater codeplug from the base station / repeater (this ensure s a match between the base station / repeater serial number (resident in the codeplug) and the serial number (pa rt of the customized base station / repeater codeplug data) that is written back to the base station / repeater (see task

5).

2. Customizing the base station / repeater codeplug and saving the data to the base station / repeater.

3. Aligning the base station / repeater for:

- Modulation Limit

- Speaker Level

- Station Reference

- MTR2000 PA Calibration

- Receiver Squelch Adjust

4. Performing post-optimization procedures.

5. Writing the customized codeplug to the base station / repeater codeplug.

For details on these tasks, refer to the Customer Programming Software (CPS) Online Help.

EXHIBIT D1-4

Chapter 10 MTR2000 MOTOTRBO Digital Upgrade

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

10.1 Overview

The MTR3000 platform support s a digital upgrad e kit which allows fielded analog MTR2000 radios to be upgraded for enhanced system capability. The T2003 digital upgrade kit upgrades the station control module (SCM), Receiver, and Exciter modules in order to migrate the radio to a digital MOTOTRBO product. These modules are not assembled together when it is shipped. Rather, the T2003 digital upgrade kit is installed and optimized on site by authorized service personnel only.

An "upgraded base station/repeater" is comprised of a new front bezel, new Exciter module, new Receiver module, new SCM module, and utilizing the remaining components from the MTR2000 Base Station/Repeater (BR). Existing peripherals that are being utilized for the MTR2000 Base Station/Repeater can retrofit the MTR3000 Base Station/Repeater once it is upgraded. There is no need to purchase a new Duplexer, Preselector, External Dual Circulator or Antenna Relay.

The MTR2000 MOTOTRBO Digital Upgrade allows a MTR2000 customer to migrate from analog to digital. The available digital systems are:

• MOTOTRBO (2 slot TDMA digital over the air DMR standard)

• Capacity Plus

• IP Site Connect

The features that are upgradeable from MTR2000 are:

• Air Interface/Conventional – Analog Conventional

• Station Operation – Base Station Analog, Repeater Analog

• Channel Configuration – Half Duplex, Full Duplex

• Air Interface/Trunked – Anal og Trunking (LTR and Passport)

• Frequency

- Rx/Tx : 136–174 MHz (VHF)

- Rx/Tx : 403–470 MHz (UHF)

- Rx : 806–825 MHz (800 MHz), 896–902 MHz (900 MHz)

- Tx : 851–870 MHz (800 MHz), 935–941 MHz (900 MHz)

• Transmitter Capability

- VHF : 30 W (low power), 40 W (low power) or 100 W (high power)

- UHF : 30 W (low power), 40 W (low power) or 100 W (high power)

- 800/900 MHz : 75 W

• Hardware Peripheral Compatibility – Preselector, Duplexer, External Dual Circulator Tray, Antenna Relay, External Frequency Reference, Angus Battery Charger

10-2 MTR2000 MOTOTRBO Digital Upgrade: Unpacking

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

The information below is an overview for installing the base station/repeater and ancillary equipment.

• Unpacking and inspecting the equipment

• Mechanically install the equipment at the site

• Make necessary electrical and cabling connections:

- Audio

-GPIO

- Ethernet

• Perform Alignment

• Perform Configuration

• Perform a post-install functional checkout test to verify installation

Note

For the correct procedure in handling static-sensitive parts, refer to Section 14.4 on page 14-3.

Once the upgrade is performed, the Wireline and Auxiliary I/O board functionality will no longer be supported.

10.2 Unpacking

This section describes the procedures to unp ack the new front bezel, new SCM module, new Exciter and Receiver modules from the packaging prior to installing them.

To avoid damage to the parts, be sure to observe proper electrostatic discharge precautions when modules are removed from the base station/repeater.

10.2.1 Equipment Unpacking and Inspection

10.2.1.1 Introduction

The new front bezel, new Exciter module, new Receiver module and new SCM module may be shipped by either air freight or electronic van (as specified by customer), except where noted.

Thoroughly inspect the equipment as soon as possible after delivery. If any part of the equipment is damaged during transit, immediately report the extent of the damage to the transportation company and to Motorola.

10.2.1.2 Unpacking Equipment

The new front bezel, new Exciter Module, new Receiver Module and new Station Contro l Module are packed in four separate boxes which are packed together in a common box. The individual boxes are cushioned between corrugated cardboard in a common box.

MTR2000 MOTOTRBO Digital Upgrade: Unpacking 10-3

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

10.2.1.3 Analog to Digital Migration Path – Removal and Replacement

1. Remove the MTR2000 Base Station/Repeater front bezel from its chassis locking clip by carefully pulling the bezel forward (Refer to Figure 10-1).

Chassis locking clip

Cast knob

Figure 10-1 Removing Front Bezel

2. Disconnect the Exciter-to-PA Coaxial Cable and Rx Input Cable (Refer to Figure 10-2) . By disconnecting the cables, the Exciter Module, Receiver Module, Station Control Module (SCM) are accessible.

Figure 10-2 Removing RF cable

3. Remove the two screws securing the Transceiver (SCM, Exciter, and Receiver modules) to the bottom plate. Pull forward on the cast knobs, carefully slide the assembly out of the base station/repeater (Refer to Figure 10-3) and place it aside.

10-4 MTR2000 MOTOTRBO Digital Upgrade: Unpacking

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

Figure 10-3 Removing two screws securing the Transceiver Assembly

4. Remove the Wireline and Auxiliary I/O Card(s) (if any are installed) as the card(s) will not be supported in an upgraded MTR2000.

5. Secure the new Station Control Module (SCM), Exciter and Receiver Modules using the eight screws (Refer to Figure 10-4) supplied with the MTR2000 MOTOTRBO Digital Upgrade kit to form the new Transceiver Assembly.

6. Slide the new Transceiver Assembly into the MTR2000 Base Station/Repeater (along the guide rails) to mate with the connector on the backplane interface board.

Figure 10-4 Putting together new SCM, Exciter and Receiver

MTR2000 MOTOTRBO Digital Upgrade: New Connections 10-5

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EXHIBIT D1-4

7. Secure the Transceiver Assembly to the bottom plate by fastening the screws in Step 3 (Refer to Figure 10-3).

8. Affix the provided T2003 Digital Upgrade Kit label to the area noted in Figure 10-5.

Designated area

Figure 10-5 Location to affix the Digital Upgrade Kit l abel

Note

The label must not cover the serial number of the MTR2000 Base Station/Repeater.

9. Affix the provided Part 68 label to the area noted in Figure 10-6 (if not already present).

Figure 10-6 Location to affix the Part 68 label

The Part 68 label is supplied if the MTR3000 Wireline Card is or dered as an optio n with the MTR2000 MOTOTRBO Digital Upgrade Base Station/Repeater.

10. Reconnect the Exciter-to-PA Coaxial Cable and Rx Input Cable.

10.3 New Connections

Designated area

After the base station/repeater equipment has been mechanically installed, connections must be made. This involves making the following new connections to:

• J7 Backplane Connector to support th e follo win g an a log thir d party boxes (If applica ble )

- Community Repeater Panel

- Tone Remote Controller (Console Connection)

- LTR Trunking Controller

- Passport (NTS) Controller

- Phone Patch

- Deskset

10-6 MTR2000 MOTOTRBO Digital Upgrade: New Connections

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

• Ethernet to support the following MOTOTRBO features

- IP Site Connect

-RDAC

- Capacity Plus

- Connect Plus

Note

1. It is not recommended to perform a digital upgrade and use the upgraded base station/ repeater in analog mode as certain analog functionality will be lost. Refer to Product Planner for details.

2. 14.2 VDC power (Pin 20) and GPIO_10 (Pin 5) are not supported on an upgraded

MTR2000 J7 backplane connector. If 12 VDC power is required on an upgraded MTR2000, then it must be obtained from Pin32 of connector J5. Alternately the MTR 2000 backplane can be replaced with DLN6721 for full support of pin 5 and pin 20.

MTR2000 MOTOTRBO Digital Upgrade: New Connections 10-7

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

10.3.1 AUX Connector

The location of the AUX connector is located at the base station/repeater rear panel. The following cables are the reference cables used for this connector:

• Auxiliary System Cable, Part no. X244AJ

• System Connector Cable, Part no. C540AD

10.3.2 System Connector

For details on the system connectors, refer to "Chapter 6".

10.3.3 Telephone Line Connections

For details on the telephone line connections, refer to "Chapter 6".

10.3.4 Station Maintenance Connections

Table 10-1 provides a descr iption o f the ma inten ance con nections loca te d on the front of the Station Control Module.

Table 10-1 Station Maintenance Connections on the SCM

Connector Name Function Details

5/10 MHz External Reference (J3008)

Service Speaker (J3010)

Microphone (J3000)

For alignment and for receipt of external reference.

Output to Power Voice speaker

Local Microphone Input Use local microphone type GMN6147 (older model)

Achieved automatically and does not require configuration in the CPS. This is a 50 Ω input that is compatible with a 2Vpp (min) to 5Vpp (max) sine or square wave.

Adjustable between 0 to 500 mV across 50 kΩ @60% system deviation. Audio signal appears between Pins 3 and 4 on the connector. Must use speaker type HSN1000 (older model) or HSN1006 via adapter cable Part.No. 0185180U01.

Note : The Speaker port is only supported in analog mode regardless of the speaker used.

or GMMN4063. Modulation sensitivity for 60% system deviation is typically 56 mV rms.

Note : The Mic port is only supported in analog mode regardless of the Mic used. For older model of microphone (GMN6147), the 3 control buttons for speaker volume control, Rx monitor and Intercom control functions are not supported.

Note 1. Only work in analog mode.

10-8 MTR2000 MOTOTRBO Digital Upgrade: Operational Verification

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

10.4 Operational Verification

After the base station/repeater equipment has been mechanically installed and all electrical connections have been made, replace the new MTR3000 Base Station/Repeater front bezel by inserting one of the front bezel locking clip into corresponding latch on the base st ation/repeater housing, and carefully pressing the bezel on the opposite side until the second locking clip snap s into place.

10.4.1 Applying Power

Before applying power to the base station/repeater, make sure all modules are securely seated in the appropriate connectors on the backplane interface board and that all RF cables are securely connected.

Plug in the AC line cord that supplies power to the base station/repeater Power Supply, or switch on the DC-breaker to a base station/repeater with a DC power source to the Power Supply.

10.4.2 Alignment and Configuration

After the base station/repeater and ancillary equipment have been mechanically installed, properly cabled, and power applied, the equipment must be optimized before placing the base station/ repeater in operation. Align (refer "Chapter 13") with the Tuner application followed by configuration with the CPS application.

Note

1. The base station/repeater will be locked after alignment with the Tuner application. To unlock it, the codeplug must be read and then written to by the CPS application.

2. The base station/repeater reference must be aligned as shown in Section 14.3.3 on

page 14-2, before the base station/repeater is placed on the air.

10.4.3 Verifying Radio Operation

Refer to "Chapter 12" for procedures to verify Exciter and Receiver circuitry operation.

10.4.4 Verifying Proper Operation

For details in this section, refer to Table 1-9.

Chapter 13 MTR3000 Programming and Tuning

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

13.1 Introduction

This chapter provides an overview of the MOTOTRBO Customer Programming Software (CPS) for the MTR3000 and MTR2000 MOTOTRBO Digital Upgrade, as well as the MOTOTRBO Tuner application for use on Windows XP Edition

32 bit and 64 bit operating system.

, Windows Vista Home PremiumTM or Windows Vista Business

Note

Refer to the appropriate program on-line help files for the programming proced ures.

13.2 Customer Programming Software Setup

The Customer Programming Software setup, shown in Figure 13-1 is used to program the base station/repeater . Refer to Figure 13-2 and Figure 13-3 for the actual co nnectors on the front and rear panels of the base station/repeater.

Note

Refer to the appropriate program on-line help files for the programming proced ures.

Computer USB ports can be sensitive to Electronic Discharge. Employ proper ESD practices (wrist strap, grounding, etc.) and do not touch exposed contacts on cables when connected to a computer.

Station

Rear Panel

AUX (J7)

Front Panel

120 / 240 VAC

28 VDC

Tx Port (N-type Female)

Rx Port (N-type Female)

Figure 13-1 Customer Programming Software Setup from Rear Accessory Connector

Either One or Both

USB

Computer

Standard Type “A” to Type “B” USB cable

USB

13-2 MTR3000 Programming and Tuning: Customer Programming Software Setup

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

USB port

Figure 13-2 Front view (without front bezel) of MTR3000 Base Station/Repeater

Tx port

DC connector

Rx port

AC connector

Figure 13-3 Rear view of MTR3000 Base Station/Repeater

MTR3000 Programming and Tuning: Base Station/Repeater Tuning Setup 13-3

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

13.3 Base Station/Repeater Tuning Setup

A personal computer (PC), Windows TM operating system, and the MOTOTRBO Tune r application are required to tune the Station. To perform the tuning proced u res , th e b as e station/repe a te r mu st be connected to the PC and test equipment setup as shown in Figure 13-4.

Station

Front Panel

Computer

Either One or Both

120 / 240 VAC

28 VDC

Rear Panel

AUX (J7)

AC DC

Wattmeter

Service Monitor

or Counter

Transmit

20 dB Pad

Tx Port (N-type Female)

USB

Standard Type “A” to Type “B” USB cable

Figure 13-4 MTR3000 Base Station/Repeater Tuning Equipment Setup

13.4 Tuning Setup (MTR2000 MOTOTRBO Digital Upgrade)

Note

13.4.1 MTR2000 Calibration Coefficient Entry

This feature is used to allow entry of the transmitter (Tx) output power coefficients of an MTR2000 Power Amplifier (PA) into the MTR3000 tuning codeplug.

Since an upgraded MTR2000 Base Station/Repeater does not have its PA upgraded, its PA calibration coefficients must be e ntered into th e tuning codeplug, a s the non-upgr aded MTR2000 PA does not have an Electrically Erasable Programmable Read-only Memory (EEPROM). The calibration coefficients, which exist on a sticker on the face plate, consist of two 7 digit hexadecimal numbers and two 6 digit hexadecimal numbers. The sticker itself is created and applied at the factory in which the PA was calibrated.

Section 13.4 on page 13-3 only applies to an upgrad ed MTR2000 Base Station/Repeater.

USB

13-4 MTR3000 Programming and Tuning: Tuning Setup (MTR2000 MOTOTRBO Digital Upgrade)

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

13.4.1.1 Tuning Procedure

1. Power the Station from either an AC or DC source.

2. Launch the MOTOTRBO Tuner application on the computer.

Figure 13-5 Tx Menu tree (Tuning Procedure)

3. Click the “Read” button in the Tuner to read the current code values from the radio’ s tuning codeplug.

4. Select “Power” under the Tx menu in the tree view (Refer to Figure 13-5).

- If the returned codeplug values match the PA calibration sticker values, click the directory

tree to exit from the “Power” menu, or click the “Write” button to save the tuned power values into the radio’s codeplug.

- If the retuned codeplug values do not match the PA calibration sticker value, proceed to

Step 5 below. Otherwise, proceed to Step 9 to exit.

5. Enter the upper left code from the PA calibration sticker to Code 1.

6. Enter the upper right code from the PA calibration sticker to Code 2.

7. Enter the lower left code from the PA calibration sticker to Code 3.

8. Enter the lower right code from the PA calibration sticker to Code 4.

9. Click the “Write” button to save the tuned power values into the radio’s codeplug.

10. Exit from the Tuner application to reset the radio. After reset, the radio will be locked.

11. To unlock the radio, launch the CPS. Read the codeplug, then write to the codeplug.

- CPS can be used to configure the codeplug prior to the write procedure (e.g. setting up

frequency)

12. Alignment is complete.

MTR3000 Programming and Tuning: Tuning Setup (Wireline) 13-5

APPLICANT: MOTOROLA

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13.4.1.2 Verification or Test Procedure for Low/High Power

1. Power the Station from either an AC or DC source.

2. Connect the radio’s Tx antenna port, through an attenuation pad and calibrate the path loss, to the Communication Analyzer.

3. Via the CPS, program the radio with all user frequencies supported by the base station/ repeater in analog mode.

4. Enter the test frequency into the Communication Analyzer and set the analyzer in power meter mode.

5. Connect a Mic to the RJ45 connector at the front panel.

6. Press the PTT button on the Mic.

7. Measure the transmit power.

8. If the measured transmit power is not within the original MTR2000 specifications range, the PA must be replaced as it cannot be calibrated in the field.

9. Repeat Step 4 to Step 7 for the remaining frequencies.

13.5 Tuning Setup (Wireline)

13.5.1 Wireline Receive Level Tuning

The procedure outlined in this section is used to set the output level on the Wireline board’s Rx path for a given RF signal deviation on the received signal. Perform this procedure during initial Wireline installation or any time the Rx audio level needs adjustment.

13.5.1.1 Tuning Procedure

1. Connect the radio’s receiver antenna port to the Communication Analyzer.

2. Power the base station/repeater from either an AC or DC source.

3. Launch the Tuner application and click the “Read” button to read the softpot values.

4. Select “Wireline Receive Level” under the Rx menu in the tree view (Refer to Figure 13-6).

Figure 13-6 Rx Menu tree (Wireline Receive Level)

13-6 MTR3000 Programming and Tuning: Tuning Setup (Wireline)

APPLICANT: MOTOROLA

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EXHIBIT D1-4

5. Set the Communication Analyzer to output a -47 dBm RF signal modulated with a 1 kHz tone at 60% of full deviation on the tuning frequency. The tuning frequency is the value displayed

on the Tuner GUI under the heading of “Frequency Points”.

Note

The Tuner aligns this parameter in a 12.5 kHz channel spacing, so 60% is 1.5 kHz of deviation. If the CPS is set for 25 kHz operation, the base station/repeater will automatically scale the deviation by a factor of two when it is outside the Tuner environment.

Programmed TPL and DPL squelch requirements are automatically disabled for the tuning frequency while in the Tune r environment.

6. Adjust the softpot value until the desired receive audio level is achieved (-30 dBm to +7 dBm) across line two of the J6 Wireline backplane connector terminals.

It is imperative that the load the Wireline board is driving, matches that of the Wireline board’s source impedance setting noted in the Tuner environment. Optimally, it is recommended to use the actual load which is used during normal operation of the radio.

7. Click “Write” to save the new tuned softpot value into the radio’s codeplug.

13.5.2 Wireline Rx Equalization – 2800 Hz Tuning

The Rx Equalization feature allows the frequency response adjustment of the Rx Audio relative to a specified rated system deviation, to compensate (equalize) for the response of the wireline backhaul network itself. This section outlines the procedure for high frequency adjustment. Perform this procedure only after setting the Wireline Receive Level. Refer to Section 13.5.1 on page 13-5.

Line 2

The Rx Equalizer is adjusted relative to the response at 1 kHz. Note the 1 kHz response observed when performing the tuning procedure for Wireline Receive Level. Equalizer adjustments are approximate. Typical adjustments range from 0 dB to approximately +6 dB.

MTR3000 Programming and Tuning: Tuning Setup (Wireline) 13-7

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

13.5.2.1 Tuning Procedure

1. Connect the radio’s receiver antenna port to the Communication Analyzer.

2. Power the base station/repeater from either an AC or DC source.

3. Launch the Tuner application and click the “Read” button to read the softpot values.

4. Select “Wireline Rx Equalization – 2800 Hz” under the Rx menu in the tree view (Refer to Figure 13-7).

Figure 13-7 Rx Menu tree (Wireline Rx Equalization – 2800 Hz)

5. Set the Communication Analyzer to output a -47 dBm RF signal modulated with a 2800 Hz tone at 60% of full deviation on the tuning frequency. The tuning frequency is the value

displayed on the Tuner GUI under th e heading of “Frequency Points”.

Note

The emphasis setting of the Communication Analyzer must be turned off for this alignment procedure.

Programmed TPL and DPL squelch requirements are automatically disabled for the tuning frequency while in the Tuner environment.

13-8 MTR3000 Programming and Tuning: Tuning Setup (Wireline)

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

6. Adjust the softpot value until the best equalization is achieved across line two of the J6 Wireline backplane connector terminals. Best equalization is achieved when the far side of the Wireline cable measures a flat response across the upper region of the audio spectrum. Compare the response at 2800 Hz with the response measured at 1000 Hz. The values

should be approximately equal.

Line 2

Note

7. Click “Write” to save the new tuned softpot value into the radio’s codeplug.

MTR3000 Programming and Tuning: Tuning Setup (Wireline) 13-9

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

13.5.3 Wireline Rx Equalization – 400 Hz Tuning

The Rx Equalization feature allows the frequency response adjustment of the Rx Audio relative to a specified rated system deviation, to compensate (equalize) for th e response of the Wireline backha ul network itself. This section outlines the procedure for low frequency adjustment. Perfo rm this procedure only after setting the Wireline Receive Level. Refer to Section 13.5.1 on page 13-5.

13.5.3.1 Tuning Procedure

1. Connect the radio’s receiver antenna port to the Communication Analyzer.

2. Power the base station/repeater from either an AC or DC source.

3. Launch the Tuner application and click the “Read” button to read the softpot values.

4. Select “Wireline Rx Equalization – 400 Hz” under the Rx menu in the tree view (Refer to Figure 13-8).

5. Set the Communication Analyzer to output a -47 dBm RF signal modulated with a 400 Hz tone at 60% of full deviation on the tuning frequency. The tuning frequency is the value

displayed on the Tuner GUI under th e heading of “Frequency Points”.

Note

The emphasis setting of the Communication Analyzer must be turned off for this alignment procedure.

Programmed TPL and DPL squelch requirements are automatically disabled for the tuning frequency while in the Tuner environment.

Figure 13-8 Rx Menu tree (Wireline Rx Equalization – 400 Hz)

13-10 MTR3000 Programming and Tuning: Tuning Setup (Wireline)

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

6. Adjust the softpot value until the best equalization is achieved across line two of the J6 Wireline backplane connector terminals. Best equalization is achieved when the far side of the Wireline cable measures a flat response across the lower region of the audio spectrum. Compare the response at 400Hz with the response mea sured at 1000 Hz. The values should

be approximately equal.

Line 2

Note

7. Click “Write” to save the new tuned softpot value into the radio’s codeplug.

13.5.4 Wireline Transmit Level Tuning

The procedure outlined in this section is used to adjust the level the Wireline is expecting on the Tx pair of the J6 Wireline connector. Adjusting the expected level has the effect of increasing or decreasing RF signal deviation for a given Wireline Tx audio level. Perform this procedure during initial Wireline installation or any time the Tx audio level needs adjustment.

13.5.4.1 Tuning Procedure

1. Connect the radio’s transmitter antenna port to the Communication Analyzer.

2. Power the base station/repeater from either an AC or DC source.

3. Apply a 1 kHz signal at the desired input level (-36 dBm to +4 dBm) to the J6 Wireline backplane connector terminals. This signal is know n as “Test Tone” and corresponds with the level of average voice. Optimally, it is recommended to use the actual source which is used during normal operation of the radio to provide the signal.

Line 1

Line 2

Note

Most Motorola dispatch consoles can generate a 1 kHz tone at the corr ect level by using the “Alert Tone” featur e. Cons ult the ap p ropr i at e co ns ole manu al for mo re info rm at ion .

If the Wire Mode is set for 2 Wire operation, then inject the signal into the line two terminals of connector J6. Otherwise, inject the signal into the line one terminals of J6.

4. Launch the Tuner application and click the “Read” button to read the softpot values.

MTR3000 Programming and Tuning: Tuning Setup (Wireline) 13-11

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

5. Select “Wireline Transmit Level” under the Tx menu in the tree view (Refer to Figure 13-9).

Figure 13-9 Tx Menu tree (Wireline Transmit Level)

6. Enter the tuning frequency into the Communication Analyzer (the value displayed on the Tuner GUI under the heading of “Frequency Points”).

7. Click the “PTT Toggle” button within the Tuner environment to key up the radio.

Note

If enabled, the Wireline’s Automatic Level Control (ALC) and Wireline Squelch Hysteresis features are automatically turned off when the radio is keyed up from the “PTT Toggle” button within the Tuner environment. The features are automatically re-enabled when the radio is de-keyed by pressing the “PTT Toggle” button or when leaving the Tuner environment.

8. Adjust the softpot value until 60% of the rated system deviation (RSD) is achieved.

Note

9. Click the “PTT Toggle” button within the Tuner environment to de-key the radio.

10. Click “Write” to save the new tuned softpot value into the radio’s codeplug.

13-12 MTR3000 Programming and Tuning: Tuning Setup (Wireline)

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

13.5.5 Wireline Squelch Level Tuning

The Wireline Squelch feature is used to mute Wireline Tx audio when the audio level falls below a designated threshold. The procedure in this section is used to set the nominal squelch threshold. An additional hysteresis value can be added to the nom inal squelch threshold by adjusting the “Squelch Hysteresis” setting in the Wireline configuration options of the CPS tool.

Note

The Wireline Squelch level is adjusted relative to the expected audio level for High Level Guard Tone. This is true regardless of the Remote Control method selected. The expected level of High Level Guard Tone is 6 dB above the “T est Tone” level used during the Wireline Transmit Level tuning procedure of Section 13.5.4 on page 13-10.

Note

This calibration procedure should be performed after adjusting the Wireline Transmit Level. Refer to Section 13.5.4 on page 13-10.

It is possible to set the Wireline Squelch threshold higher than the level of average voice. Setting the Squelch threshold too high can result in unintended audio drop-outs or no audio at all.

13.5.5.1 Tuning Procedure

1. Connect the radio’s transmitter antenna port to the Communication Analyzer.

2. Power the base station/repeater from either an AC or DC source.

3. Apply a 1 kHz signal, at the desired squelch threshold, to the J6 Wireline backplane connector terminals. Optimally, it is recommended to use the actual source which is used

during normal operation of the radio to provide the signal.

Line 1

Line 2

Note

If the Wire Mode is set for 2 Wire operation, then inject the signal into the line two terminals of connector J6. Otherwise, inject the signal into the line one terminals of J6. In add ition, th e Wire Mode used must be the same configuration as that was used in the Wireline Transmit Level alignment in Section 13.5.4 on page 13-10.

4. Launch the Tuner application and click the “Read” button to read the softpot values.

MTR3000 Programming and Tuning: Tuning Setup (Wireline) 13-13

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

5. Select “Wireline Squelch Level” under the Tx menu in the tree view (Refer to Figure 13-10).

Figure 13-10 Tx Menu tree (Wireline Squelch Level)

6. Enter the tuning frequency into the Communication Analyzer (the value displayed on the Tuner GUI under the heading of “Frequency Points”).

7. Click the backplane “PTT Toggle” button within the Tuner environment to key up the radio.

Note

The Wireline's Automatic Level Control (ALC) alignment procedure can result in a dif ference between the Wireline Squelch Threshold set during this procedure and the actual value observed in normal operation. This difference can be eliminated or minimized, by carefully following the Wireline Transmit Level tuning proced ure fo und in Sec tion 13.5 .4 on page 13 10 to obtain an accurate alignment.

8. Adjust the softpot value until the Communication Analyzer indicates that the deviatio n has dropped out (< 100 Hz of deviation).

9. Click the “PTT Toggle” button within the Tuner environment to de-key the radio.

10. Click “Write” to save the new tuned softpot value into the radio’s codeplug.

13-14 MTR3000 Programming and Tuning: Modulation Limit Alignment

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

13.6 Modulation Limit Alignment

This feature is to set the modulation limit of the radio for MTR3000 and MTR2000 MOTOTRBO Digital Upgrade.

Note

A modulation limit alignment is not needed if the radio is used in repeat mode. This is always the case when the radio is in digital mode.

13.6.1 Tuning Procedure (with no Tx Data and no PL)

Note

1. Under the “Accessories” menu within the CPS, if the “Audio Type” is set to “Rx & Tx Filtered Squelch” and the “Analog Accessory Emphasis” is set to “De & Pre”, then a modulation limit alignment is not needed. In this configuration, the modulation limit is always set to 92% RSD by the base station/repeater software.

2. If data or PL signaling is applied to Pin 13 of the J7 connector, proceed to Section 13.6.3 on page 13-16.

1. Connect the radio’s antenna port to the attenuation pad, if necessary, before connecting to the Communication Analyzer.

2. Power the base station/repeater from either an AC or DC source.

3. Apply a 1 kHz signal at 1.2 Vrms to Pin 1 of the J7 backplane connector.

- Signal ground is Pin 9 of the J7 backplane connector.

4. Launch the Tuner application and click the “Read” button to read the softpot values.

5. Select “Modulation Limit” under the Tx menu in the tree view (Refer to Figure 13-11).

6. Enter the tuning frequency into the Communication Analyzer (the value displayed on the Tuner GUI).

7. Click the “PTT Toggle” button within the Tuner environment to key up the radio.

Figure 13-11 Tx Menu tree (Tuning Procedure with no Tx data)

MTR3000 Programming and Tuning: Modulation Limit Alignment 13-15

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

8. Adjust the softpot value until the maximum deviation is 92% of the rated system deviation (RSD). This will be tested in a 12.5 kHz channel spacing, so 92% of 2.5 kHz is 2.3 kHz.

Note

Set the modulation limit to 92% so that any additional deviation incurred by the transmitter VCOs over temperature is compensated for.

Channel Spacing RSD 92% of RSD Tolerance

12.5 kHz 2.5 kHz 2.3 kHz +0Hz / -50Hz

9. Click the “PTT Toggle” button within the Tuner environment to de-key the radio.

10. Click “Write” to save the new tuned softpot value into the radio’s codeplug.

13.6.2 Verification (with no Tx Data and no PL)

1. Connect the radio’s antenna port to the attenuation pad, if necessary, before connecting to the Communication Analyzer.

2. Power the base station/repeater from either an AC or DC source.

3. Via CPS, program the radio with any frequency within the specified ra ng e of the base station/ repeater under test, and set the radio for low power and disable the repe at path.

4. Apply a 1 kHz signal at 1.2 Vrms to Pin 1 of the J7 backplane connector.

- Signal ground is Pin 9 of the J7 backplane connector.

5. Key up the radio and measure the deviation

- Key the radio by grounding Pin 2 of the J7 backplane connector.

- CPS must have Pin 2 configured as an active low with the PTT function.

6. De-key the radio.

The deviation shall meet the limits shown in the table below.

Relative

Channel Spacing

Standard

Deviation

92% of RSD Tolerance

(RSD)

12.5 kHz 2.5 kHz 2.3 kHz +0Hz / -50Hz

20.0 kHz 4.0 kHz 3.68 kHz +0Hz / -80Hz

25.0 kHz 5.0 kHz 4.6 kHz +0Hz / -100Hz

Note The base station/repeater will be factory-tuned in accordance to the above procedure and

specification.

13-16 MTR3000 Programming and Tuning: Modulation Limit Alignment

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

13.6.3 Tuning Procedure (with Tx Data or PL)

1. Connect the radio’s antenna port to the attenuation pad, if necessary, before connecting to the Communication Analyzer.

2. Turn on the base station/repeater using an AC or DC source.

3. Click the “Read” button on the Tuner application to read the radio’s softpot values.

4. Select “Modulation Limit” under the Tx menu in the tree view.

5. Enter the tuning frequency into the Communication Analyzer (the value displayed by the Tuner application).

6. Click the “PTT Toggle” button within the Tuner environment to key up the radio.

7. Apply a 1 kHz signal at 1.2Vrms to Pin 22 of the J7 backplane connector.

- Signal ground is Pin 9 of the J7 backplane connector.

- If the manufacturer of the third party controller specifies that the Tx Audio is not to be pre-

emphasized, use Pin 1 instead of Pin 22.

8. Adjust the Modulation Limit softpot to a value that limits the maximum deviation to “X”% RSD, where “X” is equal to “92% RSD” minus “Tx Data’s % RSD”.

E.g. If Tx Data deviation is equal to 17%, X = 92% - 17% = 75% as the maximum deviation limit.

100%

%RSD

With Tx Data or PL

8% 17%

92%

75%

Figure 13-12 Example of maximum deviation limit calculation

9. Click the “PTT Toggle” button within the Tuner environment to de-key the radio.

10. Click “Write” to save the newly tuned softpot value into the radio’s codeplug.

11. Alignment is complete.

Note

Refer to Figure 5-2 for details regarding the audio and data flow. Set the modulation limit to 92% to compensate for any additional deviation incurred by the

transmitter VCOs over temperature.

Note

The Tuner application always aligns the Modulation Limit parameter in a 12.5 kHz channel spacing regardless of the CPS setting, so calculate th e tuning % RSD accordingly. If the CPS is set for 25 kHz operation, the base station/repeater will automatically scale the deviation by a factor of two when outside of the Tuner environment.

Buffer Data or PL Voice

MTR3000 Programming and Tuning: Modulation Limit Alignment 13-17

APPLICANT: MOTOROLA

EQUIPMENT TYPE: ABZ89FC3795

EXHIBIT D1-4

13.6.4 Verification (with Tx Data or PL)

Refer to Section 13.6.2 on page 13-15 with the following exceptions:

• The same Tx data signal level determined (obtained from Step 8 in Section 13.6.3 on page 13-

16), is applied to Pin 13 during the validation process.

• Pin 22 may be used instead of Pin 1, depend ing on the recommendation by the ma nufacturer of the third party controller.

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Racking Configurations (Draft)

There are various equipment racking configurations available to customers. The following section depicts some of the racking alternatives.

Floor-Mount Cabinet

The front, side and top views for all available floor-mount cabinets are shown below. Cabinet models and hardware are shown in the following table:

Model Description

THN6700 12 inch Indoor Cabinet THN6701 30 inch Indoor Cabinet THN6702 46 inch Indoor Cabinet THN6788 Motorola Cabinet Slides CLN6833 Non-Motorola Cabinet Slides

See the installation manual for recommended equipment ventilation clearances. For improved access to the unit, tray slides are available as shown in the table above.

EXHIBIT D1-5

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User / Operational Manual

Racking Configurations (Draft, Continued)

Modular Racks

The front, side and top views for all available floor-mount cabinets are shown below. The cabinet models and associated description are shown in the following table:

Rack Model Description

THN6752 30 inch Modular Rack (16 RK U) THN6753 45 inch Modular Rack (24 RK U) THN6754 52 inch Modular Rack (27 RK U)

The side, top and bottom views for all available modular racks are shown below. The top and bottom plates are identical, and all dimensions and clearances are common to all racks.

Recommended clearance front and rear is 91.44 cm (36 in) minimum for servicing access. Refer to Equipment Ventilation for recommended ventilation clearances.

FRU kit CLN6679 (Rack Mount Hardware) is included with each rack model. This allo ws proper installation of the MTR3000 base station / repeater within the rack’s center of gravity.

NOTE: This kit includes two rack mount standoffs and eight mounting screws.

EXHIBIT D1-5

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Functional Description / Operation of Modules (Draft) Base Radio Module Overview

The Motorola MTR3000 Base Station / Repeater (BR) provides a modular, flexible analog and digital station design for today's communication systems and of the future. The stations are available for use in Analog Conventi onal, Digital Conventional (MOTOTRBO), LTR Trunking, Passport Trunking, MOTOTRBO Capacity Plus Trunking, and MOTOTRBO Connect Plus Trunking configurations.

The MTR3000 BR can either be configured as a stand-alone base station / repeater or as a base station / repeater connected to a back-end network, as in the case of operating in IP Site Connect mode. As a base station / repeater, it listens on one uplink frequency, and then re-transmits on a downlink frequency thus providing th e RF interface to the field subscribers. When configured for analog station operation, the BR is designed to operate with most existing analog systems, therefore making a smooth migration to the MOTOTRBO system.

When configured for digital operation, the BR offers additional services. The digital BR operates in TDMA mode, which essentially divides one channel into two virtual channels using time slots; therefore the user capa city is doubled. The BR utilizes embedded signaling to inform the field radios of the busy/idle status of each channel (time slot), the type of traffic, and even the source and destination information.

Note: When configured in Digital Mode, the BR can only be used as a repeater. Note: At any given time, the BR either operates as a digital repeater or as an analog repeater. The MTR3000 BR is divided into functional modules that separate the frequency band specific and transmitter

power specific circuits from other circuits and has separate modules for the con t rol interface. These modules are self contained functional blocks with module-specific alarms. This design facilitates the field replaceable unit (FRU) concept of field repair to maximize system uptime.

Indicators and Connections

This section describes the LED indicators and connectors provided on the base station / repe ater. The set of LEDs indicate the operational status of the base station / repeater. There are two sets of connectors for devices external to the base station / repeater:

• One set connects to external devices to enable full operation of the base station / repeater. These are located at the back of the base station / repeater.

• Another set connects to external devices for servicing the base station / repeater. These are located on the Station Control Module.

LED Indicators A set of eight LEDs is located on the base station / repeater front bezel. The position of the eight LEDs on the

front bezel is shown below. These LEDs indicate the status of the base station / repeater during normal operation.

Front Bezel LEDs and Connectors

After booting up the base station / repeater, the six LEDs (Power/Status, TX Slot 1, TX Slot 2, RX Slot 1, RX Slot 2 and the Mode LEDs) flashes in unison. The general status and condition of the MTR3000 Base Station / Repeater can be obtained by observing the eight LED indicators on the front bezel. The following tables show the LED symbols and their meaning and identify the information conveyed via the LED indicators.

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Functional Description / Operation of Modules (Draft)

Front Bezel LED Indicators

External Connections - Electrical Connections for the base station / repeater external connectors and line cord are located on the back panel and are shown below.

Location of External Connectors at Rear of Base Station / Repeater

The connection to external devices on the back panel is the J7 Auxiliary System Connector. The connector is a 25-pin connector used for connecting to an external device such as a trunking controller, tone remote adaptor, or phone patch.

Service ports and LEDs are located on the front of the Station Control Module (SCM). The connection to external devices on the front of the station control module is the BNC connector. The connector allows the base station / repeater to be connected to a 5 MHz or 10 MHz external reference signal. The service ports include connectors for:

• 5/10 MHz External Reference Signal

• Ethernet Connector

• Service Speaker Connector

• USB Connector

• Service Microphone Connector

EXHIBIT D1-6

APPLICANT: MOTOROLA EQUIPMENT TYPE: ABZ89FC3795

User / Operational Manual

Functional Description / Operation of Modules (Draft)

The locations of the connectors on the front of the station control module are shown below.

Control Overview

The Station Control Module (SCM) is described in this section. A general description, identification of controls, indicators, and inputs/outputs, a functional block diagram, and functional theory of operation are provided. The information provided is sufficient to give service personnel a functional understanding of the module, allowing maintenance and troubleshooting to the module level.

General Description The SCM circuitry performs the digital signal processing, data formatting and audio routing for the base station /

repeater (BR) and provides the external interfaces to the rest of the site. The SCM uses two TI OMAP1710 processors:

- One for transmit and overall BR control functionalities

- One for all receive functionalities

Both OMAP1710 processors have independent boot Flash and RAM and, therefore can boot independently. General SCM functionality includes:

• Data and Control interface to the Receiver’s Abacus III devices

• Data and Control interface to the Exciter’s Trident chip set

• Audio Codec interface with MAKO IC

• Host memory size, speed, and types supported

• External ports (Ethernet, USB, speaker and microphone)

• External physical interfaces (switches, connectors, LEDs, external references etc.)

• TX/RX DSP Multi-Channel Buffered Serial Port (MCBSP) interfaces

• Intermodule communication (using SPI)

• Internal station reference generation

Functional Theory of Operation The following theory of operation describes the operation of the SCM at a functional level. The information is

presented to give the service technician a basic understanding of the functions performed by the module in orde r to facilitate maintenance and troubleshooting to the module level.

TX OMAP - The TX DSP is a TI OMAP Multimedia Processor. The OMAP1710 consists of a microprocessor unit (MPU) subsystem and a digital signal processor (DSP) subsystem.

OMAP1710 has dedicated external memory interface that allow point-to-point connection to standard mobile SDRAM/DDR and mobile flash devices. It is a low-power device (1.4V Core and 1.8V I/O supply). TX OMAP handles all transmit tasks of the SCM.

External Memory - Both transmit and receive DSP’s support independent external memory banks. RAM - The SCM supports Mobile Double Data Rate SDRAM. It has the following basic characteristics: The

maximum external clock rate for the DDR is 90 MHz. Since data is transferred on both clock edges, the effective data rate is 180 Mwords/s.

Flash - The SCM supports 256 MB external flash memory. Serial Peripheral Interface (SPI) - The station local and Intermodule SPI Bus is controlled by both TX and RX

OMAP1710 processors, which has an on-chip SPIF (fast SPI) interface. The OMAP1710 SPIF supports master

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Functional Description / Operation of Modules (Draft)

and slave modes, programmable clock rate, phase, polarity, programmable word size, programmable bit ordering, and loopback.

Before an SPI data transfer can take place, the SPI master (initiator) must assert the select line of the slave (target) device. The OMAP1710 is always the SPI master for MTR3000 BR. To simplify overall SPI architecture for MTR3000 BR, address decoding is used instead of individual device chip signals. This approach not onl y minimizes the number of GPIOs needed for device chip select, it also provides flexibility for future expansion. This device address decoding is handled by a Field Programmable Gate Array (FPGA) on the SCM and a Customer Programmable Logic Device (CPLD) on each FRU’s, except the power supply.

The FPGA SPI module performs address and chip select decoding, level shifting, and signal mixing for both the TX OMAP SPI bus and the RX OMAP SPI bus. Simultaneous RX and TX SPI accesses are allowed. The TX and RX SPI are 100% independent.

Station Reference RX - A TCXO provides the frequency reference for the BR. The TCXO is 16.8 MHz. The FPGA is used to create other clocks locked to the TCXO which are needed by various devices on the Control Board.

The clocks are summarized in the following table:

Station Control Module (SCM) FPGA output Frequencies

Frequency Destination 12 MHz TX OMAP, RX OMAP

24.576 MHz MAKO

32.768 kHz TX OMAP, RX OMAP, MAKO RX OMAP The RX DSP is a TI OMAP Multimedia Processor. The OMAP1710 consists of a microprocessor unit (MPU)

subsystem and a digital signal processor (DSP) subsystem. OMAP1710 has dedicated external memory interface that allows point-to-point connection to standard mobile SDRAM/DDR and mobile flash devices. It is a low-power device (1.4V Core and 1.8V I/O supply). The RX OMAP handles receiving tasks of the SCM only.

MAKO - MAKO IC is a customized IC and the SCM uses this device to leverage some unique functionality that it provides.

Most of the MAKO functionalities are not used on the SCM. Only the MAKO codec, USB driver, ADC, DAC, and some voltage regulators are used for MTR3000. The 9 channel general purpose ADC is u sed for various controller metering.

Field Programmable Gate Array (FPGA) - The SCM FPGA includes the following major functions:

• External reference watchdog

• SPI Address decoding and buffering

• TCXO Phase detection and compensation

• Clock generation

• Reset controller

• External Interface (Wireline SSI, LED, etc.) FPGA field upgrade capability is also supported on MTR3000. Audio - There are four transmit inputs: TX Audio, TX Audio-Pre & TX Data on the backplane 25-Pin connector, and

the microphone input on a front panel RJ45 connector. TX Audio is a flat (not pre-emphasized) input which is used if the incoming transmit audio signal is already pre-

emphasized or if pre-emphasis is not needed. The TX Audio-Pre input provides a hardware pre-emphasis filter. The TX Data input is used for low speed data, Private-Line (PL) and Digital Private Line (DPL) signals. Th e TX Audio, TX Audio-Pre and microphone inputs pass through a hardware modulation limiter and splatter filter before being summed with TX Data, with the TX Data bypassing the limiter and splatter filter. This summed signal is applied to the MAKO codec “mic” input. The audio signal without TX Data is provided on the MAKO codec “aux_mic” input.

There are three receive outputs: RX Audio & Aux RX Audio on the backplane 25-Pin connector and speaker audio on a front panel RJ11. The speaker audio is the sum of the MAKO codec output (demodulated audio) and transmit audio. A high pass filter removes any data, PL or DPL from the speaker audio. A programmable attenuator is used to adjust the speaker audio level before being output on the RJ11 connector. Aux RX Audio is the output of

EXHIBIT D1-6

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User / Operational Manual

Functional Description / Operation of Modules (Draft)

the MAKO codec (demodulated audio), and RX Audio is the sum of the MAKO codec output and the microphone audio.

A block diagram of the audio paths follows:

Ethernet Interface - Since OMAP1710 does not support a direct Ethernet interface, a bridge device is needed to support Ethernet on the SCM. The bridge device is a high performance hi-speed USB2.0 to 10/100 Ethernet controller. The device contains an integrated 10/100 Ethernet PHY, USB PHY, Hi-Speed USB 2.0 device controller, 10/100 Ethernet MAC, TAP controller, EEPROM controller and a FIFO controller with a total of 30 KBytes of internal packet buffering. The following is a list for functionality that the Ethernet Interface can provide:

• Fully Compliant with IEEE 802.3 and 802.3u Compatible Ethernet Controller

• 10Base-T and 100Base-TX support

• Integrated Media Access Control (MAC) and PHYsical (PHY)

• Supports one 10BT port with automatic polarity detection and correction

• Supports full and half duplex mode and flow control

• Universal Serial Bus (USB) and Joint Test Action Group (JTAG) parameters Backplane - The connector that connects the controller to the backplane is a right angle, 96-Pin Connecto r. It

provides connectivity between the MTR3000 controller and other station FRU, such as the Wireline card, the AUX IO card as well as, third party equipments.

Exciter - The connector used to connect the controller to the Exciter and Receiver is a dual row, right angle, early entry receptacle, without flange, 30-Pin Connector. It provides 16.8 MHz reference clock, 14.2V, 10V and 8V supply voltage, SPI, Trident SSI and other digital handshake signals with the Exciter.

Receiver - The connector used to connect the controller to the Exciter and Receiver is a dual row, right angle, early entry receptacle, without flange, 30-Pin Connector. It provides 16.8 MHz reference clock, 14.2V, 10V and 8V supply voltage, SPI, Abacus SPI/SSI and other digital handshake signals with the Receiver.

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Functional Description / Operation of Modules (Draft)

Receiver Overview

The Receiver Module consists of a Receiver RF board in a clamshell housing assembly. It provides the Receiver functionality for the MTR3000 Base Station/Repeater and performs highly-selective bandpass filtering and d ual down-conversion of the desired RF signal. A custom Receiver IC then performs an analog-to-digital conversion of the desired received signal and outputs a differential data signal to the Station Control Module (SCM).

Overview of Circuitry The Receiver Module contains the following circuitry:

• Frequency Synthesizer Circuitry – consists a phase-locked loop and Voltage-Controlled Oscillator (VCO), generates the first LO injection signal

• Varactor-tuned Preselector Filter – provides bandpass filtering of the station Receiver RF input

• Receiver Front End Circuitry – performs filtering, amplification, and the first down conversion of the

Receiver RF signal

• Custom Receiver IC Circuitry – consists a custom IC which performs the second down conversion, filtering, amplification, and analog-to-digital conversion of the receive signal

• Analog to Digital Converter (ADC) Converter Circuitry – converts analog Receiver status sign als to digital format for transfer, upon request, to the SCM

• Local Power Supply Regulation – accepts +8V, +10V and +14.2V inputs and outputs +2.775V , +3.3V, +5V, +10V, and +14.2V operating voltages

Input and Output Connections The following shows the Receiver module input and output external connections.

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Specifications The following table shows the specifications of MTR3000 Base Station / Repeater’s Receiver.

Parameter Specification

Frequency Ranges 136–174 MHz Electronic Bandwidth Full Bandwidth Analog Sensitivity 12 dB SINAD 0.257 μV (-118.8 dBm) Intermodulation Rejection 85 dB Adjacent Channel Rejection* 75 dB at 12 kHz, 80 dB at 25 kHz Spurious and Image Response Rejection 85 dB Intermediate Frequencies 1st: 44.85 MHz 2nd: 2.25 MHz Intermod Rejection 85 dB RF Impedance 50 Ω Current Draw (Maximum) 0.05A from 14.2 VDC supply

0.5A from 10 VDC supply

0.13A from 8 VDC supply

Receiver Front End Circuitry The RF signal enters the Receiver through a BNC-type RF connector, located on the bottom side of the Receiver.

The signal is then low-pass filtered, and the 1/2 IF and image frequency are filtered through the tunable preselector. This signal is then amplified using a low-noise amplifier (LNA), and then further filtered to remove the image signal.

Receiver Back End Circuitry The signal after the image filter is then mixed down to the first IF, via a high performance (high IIP3) mixer, driven

by the low-phase noise, voltage-controlled Colpitts oscillator (VCO). The mixed-down signal then passes through a 3-pole, crystal IF bandpass filter and an IF amplifier. The amplifier output signal passes through an other 3-pole crystal bandpass filter, and the resultant signal passes through a digital step attenuator. The desired signal is then applied to the RF input of the custom backend Receiver IC.

Voltage Controlled Oscillator (VCO) The Receiver Voltage Controlled Oscillator (VCO) generates a sinusoidal output signal that ranges from 180.85

MHz to 218.85 MHz. The Receive Voltage-Controlled Oscillator (RXVCO) line-up consists of four sub-circuits: a Voltage-Controlled Oscillator (VCO), an attenuator, a buffer-amplifier, and a low pass filter (LPF).

The active device is from oscillator topology, utilizing a high-Q resonator, and four anti-parallel configured, hyperabrupt, tuning varactors.

The attenuator provides a broadband RF load for the VCO. The buffer-amplifier provides power leveling and isolation. The LPF provides VCO harmonic attenuation.

Synthesizer Circuitry The Receiver synthesizer is a subcircuit within a custom IC, which when connected with a loop filter, VCO, buffer

amplifier, lowpass filter, driver amplifier, unequal splitter, and feedback attenuator forms a phase-locked loop. The frequency and phase of the VCO is locked to a highly-stable external Temperature Compensated Crystal Oscillator (TCXO) reference (16.8 MHz). The custom IC contains the following integrated Phase locked loop (PLL) components: prescaler, fractional-N divider, reference divider, phase detector, and charge-pump (for the ex ternal loop-filter). The reference divider frequency is selected depending on the frequency band of operation, and will range from 3.36 MHz to 16.8 MHz.

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Custom Backend Receiver IC Circuitry The custom backend Receiver IC provides additional amplification, filtering, and a second do wnconversion. The

second IF signal is converted to a digital signal, and output via either a differential or single-ended driver to the digital signal processor (DSP) in the SCM.

Memory Circuitry The memory circuitry consists of an Electrically Erasable Programmable Read-Only Memory (EEPROM), located

in the Receiver. The SCM performs memory read and write operations via the SPI bus. The RX Front-End Filter tuning calibration is stored in the EEPROM. Therefore, no field tuning is ever required for the Receiver.

Analog to Digital (ADC) Converter Metering Circuitry Analog signals from points throughout the Receiver are applied to the ADC converter. These analog signals are

converted to digital signals and then sent to the SCM, via the Serial Peripheral Interface (SPI) lines, upon request of the SCM.

Communications with Station Control Module Data communications between the Receiver and the Station Control Module microprocessor (μP) is performed via

a Serial Peripheral Interface (SPI) bus. This bus allows the SCM μP to send data to the synthesizer PLL IC (to select frequency) and to read the ADC Converter IC.

ADC Converter Circuitry Analog signals from various strategic operating points throughout the Receiver board are fed to an ADC converter,

which converts them to a digital signal and, upon request by the Station Control Module, outputs the signal to the Station Control Module via the Serial Peripheral Interface (SPI) bus.

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Exciter Overview

The Exciter Modules (in conjunction with the Power Amplifier Module) provides the transmitter functions for the station. Contained within a metal clamshell housing, the Exciter board generates a low-level modulated Radio Frequency (RF) signal which is input to the power amplifier module for further amplification and output to the transmit antenna. The Exciter Modules interfaces directly with the Station Control Module (SCM), which provides control signals and monitoring, and routes transmit audio to the Exciter.

The RF carrier is generated by a frequency synthesizer consisting of synthesizer circuitry and Voltage-Controlled Oscillator (VCO) circuitry. Exciter module control signals, monitoring, and audio processing are handled by the Station Control Module (SCM).

The Exciter board contains the following circuitry:

• Frequency Synthesizer Circuitry – consists of a phase-locked loop and Voltage-Controlled Oscillator (VCO), generates a modulated RF signal at the transmitter carrier frequency

• RF Isolation Switch – allows the SCM to turn on/off the Exciter RF output signal to the power amplifier module

• Analog to Digital Converter (ADC) Converter Circuitry – converts the analog Exciter status signals to the digital format for transfer, upon request, to the SCM

• Local Power Supply Regulation/Filtering – accepts +8V, +10V and +14.2V inputs and provides +5V, +10V, and +12V operating voltages

• Low Level Amplifiers – amplify and buffer the modulated RF signal from the VCO for delivery to the power amplifier module

Input and Output Connections - The following shows the Exciter module input and output external connections.

Specifications of Exciter Module

Parameter Specification

Frequency Ranges 136–174 MHz Electronic Bandwidth Full Bandwidth Output Power 12–16 dBm Current Draw (Maximum) 0.05A from 14.2 VDC supply

0.15A from 10 VDC supply

0.1A from 8 VDC supply Harmonics -20 dBc

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Functional Theory of Operation The following theory of operation describes the operation of the Exciter circuitry at a functional level. The

information is presented to give the service technician a basic understanding of the functions performed by the module in order to facilitate maintenance and troubleshooting to the module level. Refer to a block diagram of the Exciter module.

Functional Overview Synthesizer and VCO Circuitry Phase-Locked Loop The phase-locked loop (PLL) IC receives frequency selection data from the SCM microprocessor (via the SPI bus).

Once programmed, the PLL IC compares a reference frequency signal with a divided-down feedback sample of the VCO output. The reference frequency is selected depending on the frequency band of operation, and will range from 3.36 MHz to 16.8 MHz. Depending on whether the feedback signal is higher or lower in frequency than the reference, up/down correction pulses are generated. The width of these correction pulses depends on the quantitative difference between the reference and the VCO feedback.

The up/down pulses from the PLL IC are fed to a charge pump which outputs a DC voltage proportional to the pulse widths. This DC voltage is then low-pass filtered and fed to the VCO as the control voltage.

Voltage Controlled Oscillator (VCO) The DC control voltage from the synthesizer is fed to dual VCOs which generate the RF carrier signal. Within each

band, one VCO generates signals in the upper half of the band, while the other VCO generates signals in the lower half of the band. Only one VCO is active at a time. Selection of the active VCO is provided by a VCO_SELECT signal from the PLL IC.

The active VCO responds to the DC control voltage and generates the appropriate RF signal. This signal is fed through impedance matching, amplification, and filtering and is output to the RF Switch Circuitry. A sample of the output is returned to the PLL IC to serve as a VCO feedback signal.

Modulation The Exciter uses dual-port FM modulator consisting of Digital Signal Processor (DSP), PLL low-port and high port

blocks, fractional-N PLL, loop filter and the VCO. The modulator is calibrated once during factory test and its values are stored in the EEPROM. The modulator does not require any further tuning or maintenance.

Amplifiers The amplifiers consist of a driver amplifier and the final amplifier. The driver amplifier operates from a nominal 5V

supply and the final amplifier operates from a nominal 10V supply. The driver amplifier amplifies the VCO output signal and provides the output signal to the final amplifier. There are fixed attenuators at the output of the driver and final amplifier to set the Exciter output power level. The final amplifier amplifies the signal and provides a constant signal level to the PA.

RF Switch Circuitry The modulated RF signal from the VCO is fed through a buffer, driver, and attenuator and finally to an RF switch

circuit. Signal EX_ENABLE from the SCM controls the switch and final amplifier. The RF signal is passed through a LPF and to a BNC connector mounted in one corner of the module, just outside the module cover. A short coaxial cable connects the Exciter output to the power amplifier module.

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Communications with Station Control Module Data communications between the Exciter and the Station Control Module microprocesso r (μP) is performed via a

Serial Peripheral Interface (SPI) bus. This bus allows the SCM μP to send data to the synthesizer PLL IC (to select frequency) and to read the ADC Converter IC.

ADC Converter Circuitry Analog signals from various strategic operating points throughout the Exciter board are fed to an ADC converter,

which converts them to a digital signal and, upon request by the Station Control Module, outputs the signal to the Station Control Module via the Serial Peripheral Interface (SPI) bus.

Voltage Regulation/Filtering Circuitry The voltage regulator circuitry consists of a +5V, +3.3V and +2.775V regulators that supplies power to the digital

circuitry and the PLL. The +12V regulator is used to supply power to the VCO and the +10V supplies power to the final device.

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Power Amplifier Module Overview

The Power Amplifier (PA) is a forced convection-cooled RF power amplifier. It accepts a low-level modulated RF signal from the Exciter Module and amplifies the signal for transmission via the site transmit antenna. The output power is continually monitored and regulated by a feedback and control loop, with a power output cont rol voltage being generated by the transmitter control circuitry located on the PA Input/Output boards.

Overview of Circuitry The Power Amplifier contains the following sub-circuits:

• Intermediate Power Amplifier (IPA) – hybrid substrate amplifier stage which accepts low-level input from Exciter Module, amplifies the signal, and outputs a 0 W to 10 Watt RF signal

• Final Module – hybrid substrate amplifier stage which accepts output from IPA Hybrid and provides final amplification to 100 Watts (maximum)

• Directional Coupler/Power Detector/Low Pass Filter – couples amplified RF signal to transmit antenna connector; also generates dc voltages proportional to forward and reflected power for use in TX power control loop; provides harmonic suppression for the station

• Single Circulator – provides isolation between Power Amplifier output and transmit antenna

• Temperature Sense Circuitry – provides variable resistance signal proportional to heat sink temperature;

signal is monitored by the PA power control circuitry

Input and Output Connections The following shows the PA input and output external connections.

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The following table shows the specifications of MTR2000 Power Amplifier (PA).

Specifications of Power Amplifier

Parameter Specification

Operational Frequency Range 136–174 MHz Minimum Input Return Loss (TX mode) 10 dB Rated RF Output Power Range 25–100 W Rated RF Input Power Range 11.8–16 dBm

28.6V Supply Nominal Voltage (AC Power) 28.6V (+/- 4%)

14.2V Supply Nominal Voltage 14.2V (+/- 3%)

28.6V Supply Maximum Current Draw 12.6A

14.2V Supply Maximum Current Draw 2.0A Maximum Standby Power Consumption 1.5 W

Functional Theory of Operation A low-level modulated RF signal (approximately +13 dBm) from the Exciter Module enters the PA Input board via a

coax cable. The signal is input to the IPA and amplified to approximately 0 to 10 W (depending on the dc power control voltage (V_CNTL) from the PA output board). The IPA output is then fed to the Dual Device Module for further amplification.

The output of the DDM is then transferred to the circulator and then to the harmonic filter/coupler via the PA output board. The signal then exits from the Power Amplifier Module via an N-type coax connector.

A single circulator is built into the Power Amplifier Module to provide isolation between the PA module and the transmit antenna.

A thermistor mounted on the PA printed circuit board outputs a variable resistance proportional to the heat sink temperature. This signal is fed to the power control circuitry on the PA output board, which monitors the signal and reduces the PA output power (and enables a fan) if the PA temperature exceeds set limits.

A feedback and control loop configuration is used to regulate the PA output power. The Directional Coupler generates a dc voltage proportional to the PA Module output power. This voltage is fed to power control circuitry on the PA output board where it is compared to reference voltages to generate a dc power control voltage. The Station Control Module sends current and power limit signals to a D/A converter (via the SPI bus) to control the maximum current/control voltage levels. The control voltage is fed to the IPA module where it controls the IPA output, thus controlling the overall output from the PA Module.

Analog signals from various strategic operating points throughout the PA module are fed to an A/D converter, which converts them to a digital signal and, upon request by the Station Control Module, outputs the signal to the Station Control Module via the SPI bus.

For example, the directional coupler generates a dc voltage proportional to the reflected power. This signal is converted to a digital signal and sent to the SCM. If the sense line indicates an impedance mismatch (high VSWR), the PA is either cut back in power or shut down completely.

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Power Supply Module Overview

The Power Supply is described in this section. The information provided is sufficient to give service personnel a functional understanding of the module, allowing maintenance and troubleshooting to the module level. Refer to the service manual for Maintenance and Disassembly/Reassembly Procedures for detailed removal or installation procedures for all modules in the station.

Over-current conditions on either the 28.6 VDC or 14.2 VDC outputs cause the total supply to shutdown and try to restart. If the over-current continues to exist, the power supply will ‘hiccup’ until the overload condition is removed, and will not be damaged by the overload. The 28.6 VDC output is protected by a primary current sense method such that its current limit point varies depending on the load on the other outputs at the time. The trip point for the

14.2 V and 5.1 V outputs is greater than 115% of the maximum current specified for the outputs. The power supply recovers automatically after the removal of the overload condition.

The 28.6 V and 14.2 V outputs are protected from continuous over-voltages by detection circuits that cause the supply to shutdown and then try to restart itself. If the over-voltage condition continues to occur, the supply goes into a ‘hiccup’ mode of shutting down and trying to restart. If the over-voltage condition is removed, the supply automatically recovers. In addition, the 14.2 V and the 5 V outputs are protected by crowbar circuits.

An AC Fail detect signal is provided to indicate (when used with battery backup option) that the power supply is operating from an external dc source rather than the ac mains. This signal is a TTL compatible output capable of sinking 1 mA, and is routed to the Station Control Module. The active-low state indicates ac operation. For the nominal 120 VAC operation, the signal is active-high impedance (indicating an ac mains failure) when the ac voltage is less than 85 Vrms, but more than the minimum voltage that guarantees that all outputs will be in regulation at full load. For the nominal 240 AC operation, the detect point is less than 170 Vrms but more than the minimum ac input voltage that guarantees that all outputs be in regulation at full load.

The supply incorporates temperature sense/fan enable circuitry for controlling a 12VDC fan mounted on the surface of the heatsink assembly. The power supply circuitry senses the internal temperature of the power supply. When the internal temperature exceeds +60°C (± 5°C), +12 V is enabled at J1–1 to turn on the fan. The +12 V fan supply is derived from the +14.2 V output. Power to the fan is off when the temperature is below the set limit. The fan turns for approximately 5 seconds when power is first applied as a diagnostic indicator that the fan is functional.

The power supply will turn off all outputs when an operational ambient temperature of +80°C (±2°C) has been reached with the supply operating at any input within its operating input voltage range (dc and ac).

The following shows the electrical performance specifications for the power supply.

Power Supply Module AC Performance Specifications:

Parameter Value or Range Input Voltage Range 85 VAC to 264 VAC Operating Temperature –30° to +60° C (–22° to +140° F) Input Frequency Range 47 to 63 Hz Steady State Output Voltage

28.6 V @ 13 A,

14.2 V @ 8 A,

5.1 V @ 2 A Output Power (Rated) 500 W Output Ripple: +28.6 VDC +14.2 VDC +5.1 VDC

50 mV p-p, @ 25°C (77°F) 50 mV p-p, @ 25°C (77°F) 100 mV p-p, @ 25°C (77°F)

Efficiency Greater than 75% (Full Load)

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Power Supply Module DC Performance Specifications:

Parameter Value or Range Input Voltage Range 21.6 - 32 VDC Operating Temperature –30° to +60° C (–22° to +140° F) Steady State Output Voltage

28.6 V @ 13 A, Input Voltage Dependent

14.2 V @ 8 A, Regulated

5.1 V @ 2 A, Regulated Output Power (Rated) 500 W Output Ripple: +28.6 VDC +14.2 VDC +5.1 VDC

Input Voltage Dependent, 0-0.5V below input 50 mV p-p, @ 25°C (77°F) 100 mV p-p, @ 25°C (77°F)

Efficiency Greater than 75% (Full Load)

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Motorola 89FC3795 Users manual

Specifications and Main Features

Frequently Asked Questions

User Manual

Power Amplifier Module Overview

Power Supply Module Overview