IP Mobilenet B64450G25 Users Manual

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16842 Von Karman Avenue, Suite 200  Irvine, CA 92606

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Date Released: March 16, 2006

Document #: 516-80541-POM

Copyright 2005 IPMobileNet, Inc.

Voice: (949) 417-4590  Fax: (949) 417-4591

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Version: B

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The term “IC”: before the radio certification number only signifies that Industry of Canada
technical specifications were met.

Operation is subject to the following two (2) conditions: (1) this devise may not cause
interference, and (2) this device must accept any interference, including interference that may
cause undesired operation of this device.

The following U.S. Patents apply to this product:

U.S. Patent numbers 5,640,695,6,018,647,6,243,393

Information contained in this document is subject to change without notice.

All rights reserved. Reproductions, adaptations, or translation without prior written permission is
prohibited, except as allowed under copyright laws.

637246.DOC Page 2

TABLE OF CONTENTS

SECTION 1: THEORY OF OPERATION .............................................................................................. 4

General Block Diagram.................................................................................................................. 4

General Block Diagram Definitions

Input/Output ........................................................................................................... 4

System Controller................................................................................................... 4

Modems
Diversity Reception

RX Injection............................................................................................................ 5

Transmitter ............................................................................................................. 5

Receiver 1/ 2/ 3...................................................................................................... 5

Power Supply......................................................................................................... 5

B64450G25 Base Station Section Descriptions.......................................................................... 6

System Controller
Input/Output
Modem Switching
Modem
Receive Signal Strength Indication Comparator
Baseband

Receiver Board ................................................................................................................... 8

IF Amplifier .......................................................................................................................... 8

Receiver Injection

Exciter Board....................................................................................................................... 9

Analog Modulation ............................................................................................................ 10

Phase Locked Loop

Power Amplifier................................................................................................................. 11

SECTION 2: FACTORY TEST PROCEDURE .......................................................................................... 12

Equipment List ............................................................................................................................. 12

Programming and Configuring the Base Station ..................................................................... 13

Adjustment / Alignment Procedure............................................................................................ 14

Receiver Injection

Receiver............................................................................................................................ 14

Diversity Reception ........................................................................................................... 15

Receive Data
Exciter

Power Amplifier................................................................................................................. 17

SECTION 3: FCC LABEL.......................................................................................................................... 18

B64450G25 Base Station FCC Label Placement....................................................................... 19

B64450G25 Base Station FCC Label.......................................................................................... 19

APPENDIX A: B64450G25 TEST DATA SHEET ...................................................................................... 59

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637246.DOC Page 3

SECTION 1: OVERVIEW

Product Description



The B64450G25 Base Station works within a frequency range of 450-507 MHz and requires 1/4-

wavelength antenna.

The IPSeries Base Stations are intelligent devices designed for stringent requirements of mobile data
communication systems. Intended for mounting in rack units, the base station requires very little room at
tower sites and may be connected via Serial Line Internet Protocol (SLIP) or Ethernet ports. At the
minimum, the unit requires a 13.8 VDC power supply, an antenna system, and a high-speed data
connection to an Internet Protocol Network Controller (IPNC) system to operate. The base station is
typically teamed up with a Power Amplifier (PA) and third-party system components such as antennae,
preamplifiers, preselectors, filters, and combiners.

Product Functionality

The base station utilizes a high-performance DSP to modulate/demodulate 4 to 16-level Frequency-Shift
Keying (FSK) modem for 25 kHz channel spacing, a multi-layered approach to signaling reliability,
including patented multi-receiver Intelligent Diversity Reception, dynamic scrambling, data interleaving
for burst error protection, Forward Error Correction (FEC), and Viterbi soft-decision algorithms.

The IPSeries High Speed Base Station technology includes IPMobileNet’s Diversity Reception (DR)
capability. Diversity Reception reduces the number of fades and the effects of multi-path reception. With
the use of three (3) antennae, mounted as far apart as possible on the base station tower, the Diversity
Reception System (DRS) minimizes the effects of fading. One of the antennae is likely to receive a viable
signal while the others may not. DRS minimizes fading effects by comparing the signal levels from the
three (3) antennae, and selecting the strongest signal.

 Diversity is most effective when the vehicle using an IPSeries Mobile Radio is in motion.

637246.DOC Page 4

SECTION 1: OVERVIEW

External Features

The base station technology is enclosed in a sturdy aluminum case. The external features consist of a
series of connectors in the rear of the base station and light emitting diodes in the front of the base
station, as described in this section.

S The product warranty becomes void if an uncertified or unauthorized individual removes the base

station cover.

The base station’s rear external features consist of the following connectors and ports:

TABLE 1: EXTERNAL FEATURES (Rear)

FEATURE DESCRIPTION

TX Transmitter antenna connection

RX1/RX2/RX3 Receivers 1, 2, and 3 antenna connections

GPS Port GPS antenna (SMA) connector

BNC

Power Connector 13.8 VDC base station power connector

Serial Port 1 (DB9M) RS232 Serial Line Internet Protocol (SLIP) interface port (115K)

Terminal Connection

(DB9F)

Ethernet Port RJ45 Ethernet 10 Base T interface port

Bayonet Neill Concelman connector used for measuring receiver
sensitivity.

ANSI/TTY Terminal Connection (used for programming)
(9600 bps, no parity, 8-databits, 1-stop bit)

637246.DOC Page 5

SECTION 1: OVERVIEW

The base station’s front external features consist of six (6) LED (light emitting diodes) indicators defined
as follows:

TABLE 2: EXTERNAL FEATURES (Front)

LED Name When lit….

TX Indicates that transmission is in progress

CD Carrier detect indicates an RF message is detected

RX1 Indicates that receiving is in progress on Receiver 1

RX2 Indicates that receiving is in progress on Receiver 2

RX3 Indicates that receiving is in progress on Receiver 3

POWER Indicates the base station is powered on

637246.DOC Page 6

SECTION 2: BASIC NETWORK CONFIGURATION

Basic Network Configurations

This section provides basic network connection samples to help the user better understand some of the
possibilities in setting up their respective systems. Each organization’s configuration will differ based on
its own system requirements, equipment, backhaul, etc.

Basic Network Connection to an Existing LAN

The following figure depicts a basic network connection for an existing Local Area Network (LAN)
inclusive of one (1) Internet Protocol Network Controller (IPNC), one (1) base station, and multiple mobile
radios, voice interface units (VIU), and mobile computers. It also includes other equipment such as a LAN
VIU and a messaging server.

Basic Network Connection with a Range of Base Stations

The following figure depicts a basic network connection for a network inclusive
Protocol Network Controller (IPNC) and a range

of base stations, mobile radios, mobile computers, and

of one (1) Internet

additional components that interface with this sample system setup.

 For serial connectivity to Ethernet only systems, please refer to the IPTurbo Converter Quick

Reference Guide (IPMN p/n: 516.80496.QR) on the Production Documentation CD (IPMN p/n:

480.0001.001).

637246.DOC Page 7

SECTION 3: PRODUCT SETUP AND PRELIMINARY TESTING

Base Station Setup

Intended for rack unit configuration, the base station can be installed in an existing rack or assembled into
a rack of its own.

Rack Unit Mounting

The table below lists the required components for a base station setup.

TABLE 3: BASE STATION COMPONENTS REQUIRED FOR INSTALLATION

QTY DESCRIPTION

1 Frequency appropriate IPSeries Base Station

1 Ethernet cable

1 5’ DC power input cable with connector

RF coaxial cables (may require an additional cable if connecting the base station to a

4

power amplifier)

637246.DOC Page 8

SECTION 3: PRODUCT SETUP AND PRELIMINARY TESTING

Preliminary Testing

This section provides a functional preliminary test for the base station prior to installation. It is used to
determine the condition of the new base station prior to placing into service. If the base station is non­functional after completing this test, refer to Chapter 6: Customer Support.



This section applies to all base station frequency ranges.

Checklist of Required Material

The following checklist provides a list of tools required to perform this preliminary test procedure.

TABLE 4: CHECKLIST OF REQUIRED EQUIPMENT FOR PRELIMINARY TESTING OF A BASE
STATION

Calibrated Base Station System – Consisting of the following components:
(1) Frequency appropriate IPSeries Base Station
(2) Desktop or laptop configured as an Internet Protocol Network Controller (IPNC)
(3) Corresponding IPSeries Mobile Radio tuned to Base Station frequencies (i.e.: if an

1

2

IPB138 base, use IP138 mobile)

(4) Desktop or laptop with two (2) available serial ports with Microsoft Windows 98 or

higher, IPMobileNet Dial-Up Networking, IPMessage software, and HyperTerminal for
base station installed

(5) Base Station power cable
DC power supply with ammeter, with the appropriate volts, see page 7 Current Consumption

for each base station (Astron VS12M or equivalent)

Six (6) antennae (generic mag mounts) tuned to frequency of transceiver

3

Serial Base Station Interface

No. Requirement

DB9 RS232 serial cable

1

IPTurbo Converter (IPMN p/n: 900.00012.01)

2

IPTurbo Converter Reference Manual (IPMN p/n: 516.80496.REF)

3

Ethernet Base Stations Interface

No. Requirement

Ethernet RJ45 Cable

1

Ethernet Cable

2

9

9

637246.DOC Page 9

SECTION 3: PRODUCT SETUP AND PRELIMINARY TESTING

Preliminary Test Procedure

Perform the following initial setup to prepare the base station for preliminary test:

Step 1 Connect the antenna to the base station’s TX port.

Step 2 Connect the base station to the 13.8 VDC power supply.

Step 3 Power on the base station and verify that the LED’s illuminate and the power LED on the

front panel remains illuminated.

Step 4 Verify that the base station DC-supply current is <1.2 Amps.

Step 5 For the ideal Serial or Ethernet setup please refer to the IPTurbo Converter Reference

Manual (IPMN p/n: 516.80496.REF) available on the Product Documentation CD
enclosed with this product.

Step 6 Connect the antenna to the mobile radio.

Step 7 Power on the mobile radio.

Step 8 Recycle the base station power.

Step 9 Connect the antennae to the base station’s RX1.

Step 10 Verify that the RX1 and CD LED’s are illuminated when the mobile radio is attempting to

connect. Repeat steps 9 and 10 with RX2 and RX3.

Step 11 From the mobile PC, open the DOS prompt, then ping the IPNC with the following

command:

ping 172.16.23.200 (replacing with the appropriate IPNC IP address).

Press [ENTER] and verify that the IPNC responds to the ping request. Also verify that

the base station carrier detect (CD) LED is lit followed by the TX LED.

637246.DOC Page 10

SECTION 4: PRODUCT INSTALLATION

Installation Overview

This chapter provides the basic setup involved in the installation process of an IPSeries High Speed Base
Station. For backhaul requirements, refer to Appendix A of this document.

S Standard considerations such as air flow clearance above the base station for heat dissipation

and ensuring adequate space exists behind the base station for the routing of cables are of
primary importance.

A minimum clearance of 1 rack space is recommended for natural convection cooling.

Adjustment points are available through holes in the base station’s bottom cover. Sufficient
space below the base station should exist to facilitate adjustments.

Coax, power, and interface cabling service lengths with neat routing will make the removal and

replacement of the base station easier for functional testing and maintenance purposes.

To prevent injury and damage to the base station, exercise extreme caution throughout the
installation process and follow the reminders listed below.

 Follow safety precautions for handling rack unit installations.

 Do not

substituions are noted within this chapter.

alter the components listed in the Installation Requirements section, unless

637246.DOC Page 11

SECTION 4: PRODUCT INSTALLATION

Installation Instructions

 If setting up a new rack unit, make sure to complete the rack unit setup according to the

Manufacturers’ instructions.

Base Station Installation into the Rack Unit

Receiver and Transmitter Connections

To connect the base station, perform the following steps:

Step 1 Connect the RF coaxial cable to Receiver 1 (RX1) on the back of the base station.

Step 2 Route the cable neatly toward the top of the rack. Allow a little slack in the cable to avoid

accidental disconnection.

Step 3 Connect the RF coaxial cable to Receiver 2 (RX2) on the back of the base station.

Step 4 Route the cable neatly toward the top of the rack. Allow a little slack in the cable to avoid

accidental disconnection.

Step 5 Connect the RF coaxial cable to Receiver 3 (RX3) on the back of the base station.

Step 6 Route the cable neatly toward the top of the rack. Allow a little slack in the cable to avoid

accidental disconnection.

 For clear identification for troubleshooting and/or maintenance activities, avoid crossing the

coaxial cables.

Step 7 Connect the RF coaxial cable to the Transmitter (TX) connection on the back of the base

station.

Step 8 If connecting to a power amplifier (as shown in the figure below), connect the cable from the

base station to the power amplifier via the Transmitter (TX) connection.

If not connecting to a power amplifier, skip to Step 11.

Step 10 If a power amplifier is used, connect an RF coaxial cable to the output port of the power

amplifier.

Step 11 Route the cable neatly toward the top of the rack. Allow a little slack in the cable to avoid

accidental disconnection.

Step 12 To perform the RX1, RX2, RX3, and TX antenna connections, refer to the Typical Antenna

Configuration section in this chapter.

637246.DOC Page 12

SECTION 4: PRODUCT INSTALLATION

Figure 8: Base Station Mounting and Connection in the Rack Unit (Rear View)

637246.DOC Page 13

SECTION 4: PRODUCT INSTALLATION

Single Base Station Configuration

Figure 9: Base Station Ethernet Connection

To connect a single base station, perform the following steps:

Step 1 Plug in the Ethernet cable into the Ethernet port on the base station (as shown in the figure

above).

Step 2 Route and plug in the other end of the Ethernet cable to an Ethernet switch or router.

Step 3 Route and plug in another Ethernet cable from the Ethernet switch or router to the Ethernet

port of the Internet Protocol Network Controller (IPNC).

 If connecting to a Serial backhaul, an IPMobileNet IPTurbo Converter is required. For

connection instructions, refer to the IPTurbo Converter Reference Manual (IPMN p/n:

516.80496.REF) available on the Product Documentation CD provided with this product.

Multiple Base Station Configurations

To connect multiple base stations, perform the following steps:

Step 1 Plug in the Ethernet cables to the back of each base station (as shown in the figure above)

and route according to selected setup. Refer to the IPTurbo Converter Quick Reference
Guide (IPMN p/n: 516.80496.QR) for setup instructions and scenarios.

Step 2 Route and plug in the Ethernet cables to an IPMobileNet’s Internet Protocol Network

Controller (IPNC) via the hardware as defined by the organization’s configuration.

 If connecting to a serial backhaul, an IPMobileNet IPTurbo Converter is required. For

connection instructions, refer to the IPTurbo Converter Reference Manual (IPMN p/n:

516.80496.REF).

637246.DOC Page 14

SECTION 4: PRODUCT INSTALLATION

Typical Antenna Configuration

Base station antenna configurations may vary from site to site depending on the type of mounting
structure, the presence of existing antennae, mounting structure loading limitations, etc. The following
information is provided as a guideline for a typical scenario.

Figure 10: Typical Antenna Configuration

An optimal antenna mounting configuration is shown in the figure above. The transmit antenna and
receive antennae are located at different elevations. This vertical separation provides the greatest
degree of isolation between transmit and receive antennae. The three (3) receive antennae are mounted
at the same elevation and are oriented in a 120 degree triangular pattern. A triangular orientation of the
receive antennae provides optimal diversity performance in an omnidirectional pattern.

 The greater the separation between receive antennae, the greater the diversity gain; therefore,

the distance between antennae should be made as great as is practical.

In the event only two (2) receive antennae are used (i.e. a dual receiver diversity reception system), the
receive antennae should be mounted in a broadside orientation with respect to the radio coverage area.

 To prevent the antenna’s radiation pattern from becoming distorted, the immediate area

surrounding each antenna should be kept free from conductive objects (i.e. other antennae, guy
wires, or the tower structure itself). The amount of clear area required to prevent pattern distorion
is equal to the antenna’s near-field exclusion.

637246.DOC Page 15

SECTION 4: PRODUCT INSTALLATION

Near-Field Exclusion Zone

The near-field exclusion zone (NFEZ) is the required distance between antennae to any other surfaces to
improve transmit and receive performance. The large radio frequency field that builts up around the
antenna upon transmitting is essential for proper data transmission. It can be severely corrupted by metal
objects in the NFEZ. As seen in the previous figure, the transmitting antenna is placed at the very top of
the tower especially if the base station will be required to transmit in all directions (omni-directional).

 If the transmitting antenna cannot be positioned on the top of the tower and must be placed on

a tower arm, then it is important to realize that coverage will be shaded in the area behind the
tower from the anetnna. The installer must be certain that the area of desired coverage is
away from the tower and not behind it.

Receiving and transmitting antennae should not be on the same plane, especially VHF and
UHF systems where the frequency splits are relatiely small. An antenna in the near-field
exclusion zone that is tuned for the same frequency as the transmitting antenna will reradiate
the signal and create unwanted effects on the transmittal signal. The receivers will be
inundated by high levels of radio frequency energy from the transmitting antenna. This is
why it is important to include vertical separation in the plan for the base station installation.
The isolation provided by 30 feet of vertical spearation can dramatically improve the
performance of the base station.

An antenna’s NFEZ can be calculated as follows:

D = 2d2

λ

Where: D is the distance to the anenna’s near field boundary

d is the antenna’s longest linear dimension (in the same units as D)

Maximizing the distance between the receive antennae will provide maximum diversity gain and

will minimize antenna radiation pattern distortion.

637246.DOC Page 16

λ is the wavelength (in the same units as D)

SECTION 4: PRODUCT INSTALLATION

Power Connection

Figure 11: Base Station Power Connection

To connect the base station power connector, perform the following steps:

Step 1 Connect the power cable to the base station power supply connection (as shown in the figure

Step 2 Connect the wires to the appropriate output (+ and -) output posts on the power supply (as

above).

shown in the figure above).

637246.DOC Page 17

SECTION 4: PRODUCT INSTALLATION

Post Installation Checklist

The following table lists the tasks that should be performed upon completing installation.

TABLE 5: POST INSTALLATION CHECKLIST

NO. CHECKLIST ITEM

1 Scope out the entire area setup to locate any obvious problem areas.

2 Check antenna routing for safety concerns and near-field boundary setup.

Use tie wraps, where possible to ensure that all cables routed in parallel are

3

bundled together.

4 Perform appropriate testing to ensure base station works properly.

;









 Once installation is complete make sure the area is clear of debris that would prevent proper

airflow and ventilation.

637246.DOC Page 18

SECTION 5: FACTORY TEST PROCEDURE

Equipment List

The following table lists the equipment required to perform the B64450G25 Base Station Factory Test
Procedure.

TABLE 6: EQUIPMENT REQUIRED TO PERFORM FACTORY TEST PROCEDURE

QTY DESCRIPTION MANUFACTURER MODEL

Windows 9X w/

2 PC’s (one for mobile, one for base)

IPMessage

AVR

1 IPSeries High Speed Base Station IPMobileNet B64450G25

1 IPSeries High Speed Mobile Radio IPMobileNet M64450G25

1 Service Monitor – Communication Test Set HP

8920A or B or

equivalent

1 High Frequency Probe HP 85024A

1 Power Supply for 85024A Probe HP HP1122A

4 Channel Scope Tektronix TDS 460A

1 General Purpose Probe Scope

1 Digital Multi-Meter Fluke Tektronix Dmm91277

1

DC power supply with ammeter, 13.8V, 12
Amps or more

Astron

1 100 watt dummy load/attenuator Pasternack

VS12M or
equivalent

PE7021-40 or

equivalent

4 UHF Antennae (generic mag mount)

1

Serial Cable DB9M – DB9F connectors
(generic)

IPMobileNet 156.0245.020

1 Input/Output (I/O) Board IPMobileNet 502.80081

1 IPSeries High Speed Base Station power cable

3 Serial DB9F-DB9M Null Modem cables

637246.DOC Page 19

SECTION 5: FACTORY TEST PROCEDURE

Programming and Configuring the Base Station

This section applies to the 450 to 507 MHz frequency range of the IPSeries Base Station. Important!



The programming procedure should be performed when it is necessary to upgrade a base station’s
Firmware or to change the operating parameters to suit client needs.

Viewing the Base Station’s Configuration Data

Step 1 At the HyperTerminal window, type in the appropriate password and press [ENTER].

Step 2 Type ? and press [ENTER]. The following example displays in the HyperTerminal

The base station’s IP address must be known prior to performing the procedures in this section.

window:

Host serial = 115200,N,8,1, timeout=200
Host framing = SLIP, no split frames no status messages
tunnel = 0
TX format = new
Injection = LOW SIDE, 45MHz
channel spacing = 25000
Channel = 0
Channel Tx freq Rx freq Inj freq
Frequency=0 , 450.000000, 463.000000, 418.000000
Serial number: yyyyyyyyy
RIM address = 1
Frequency group = 1
TX quiet time = 5
Symbol sync time = 12 milliseconds, 0 extra inter-split-frame count
TX tail time = 5
Radio data rate = 19200
Max data tx time = 60 seconds
Carrier detect delay time = 1 millisecond
Station ID = ABC123
Station ID time =10 minutes
Polarity = TX+, RX+
Allow crc errors = 0
Suppress keep alive = 0
Allow base to base = 0
Timeslot status = 0
Duplicate time = 10 milliseconds
Control head grant delay = 50 milliseconds
RIM DD delay = 0 milliseconds
Retry interval = 0 milliseconds
Retry time limit = 0 milliseconds
RSSI step = 25 (=19dBm)
IPNC = 192.168.3.3
SLIP Address = 192.168.4.6
RF IP Address = 192.168.3.1
SNTP interval = 60 seconds
num timeslots = 16
timeslot period = 992ms
timeslots per voice packet = 4
noise = -128dBm
Fixed TX Delay = 0 milliseconds
Scale TX Delay = 0 microseconds

637246.DOC Page 20

SECTION 5: FACTORY TEST PROCEDURE

Adjustment / Alignment Procedures

Make appropriate notations of any items that require attention during this procedure. This information is
needed later during the repair process.

Startup

Step 1 Remove the base station cover placing the screws in a location where they will not be

Step 2 Connect the base station to the appropriate components.

Step 3 Power up the base station and computer. The power supply ammeter must read 1.2

Receiver Injection

Step 1 Using the HP high frequency probe verify that the receiver injection frequency is present

Step 2 Adjust R23 on the receiver injection circuit board to set the injection frequency within 10

Receiver

Step 1 Using the high frequency probe, monitor the 44.545 MHz second injection frequency

Step 2 Inject an on-frequency signal at a level of –80 dBm, modulated with a 1 KHz test tone at

Step 3 Check the receiver’s sensitivity, verifying that the SINAD is 12 dB or better at a maximum

misplaced.

amps or less with a 13.8 VDC input.

at each of the three (3) receivers by monitoring the receivers R24 surface mount pad
which lies on the 50 ohm track between P1 and C43.

Hz of the exact injection frequency. The amplitude of the injection frequency should read
approximately +5 dBm ±1 dBm.

at U6 pin 3, adjust trimmer capacitor (C22) to the center of the oscillator’s oscillation
range. The amplitude level of pin 3 of U6 should read between +5 and +10 dBm.

±5.0 KHz deviation into the receiver under test.

level of –119 dBm (-120 is typical).

637246.DOC Page 21

SECTION 5: FACTORY TEST PROCEDURE

Diversity Reception

Step 1 Inject an on-frequency signal at a level equal to Receiver 1 12dB SINAD level, modulated

with a 1 KHz test tone at ±5.0 KHz deviation into Receiver 1.

Step 2 While monitoring TP1 with the digital multi-meter, adjust RSSI1 low adjust potentiometer

(R12) for a reading of 0.750 VDC ±10 mV.

Step 3 Increase the amplitude of the signal by 50 dBm.

Step 4 While monitoring TP1 with the digital multi-meter, adjust RSSI1 high adjust potentiometer

(R11) for a reading of 2.75 VDC ±10 mV.

Adjustments R11 and R12 are interactive adjustments, therefore continue adjustments until the DC voltage

at TP1 is 0.750 VDC for the receiver’s 12 dB SINAD level and 2.75 VDC for a 50 dBm increase from the



Step 5 Inject an on-frequency signal at a level equal to Receiver 2 12dB SINAD level, modulated

Step 6 While monitoring TP2 with the digital multi-meter, adjust RSSI1 low adjust potentiometer

Step 7 Increase the amplitude of the signal by 50 dBm.

Step 8 While monitoring TP2 with the digital multi-meter, adjust RSSI1 high adjust potentiometer

Adjustments R9 and R10 are interactive adjustments, therefore continue adjustments until the DC voltage

Step 9 Inject an on-frequency signal at a level equal to Receiver 3 12dB SINAD level, modulated

Step 10 While monitoring TP3 with the digital multi-meter, adjust RSSI1 low adjust potentiometer

Step 11 Increase the amplitude of the signal by 50 dBm.

Step 12 While monitoring TP3 with the digital multi-meter, adjust RSSI1 high adjust potentiometer

Adjustments R33 and R35 are interactive adjustments, therefore continue adjustments until the DC voltage

receiver’s 12 dB SINAD level.

with a 1 KHz test tone at ±5.0 KHz deviation into Receiver 2.

(R10) for a reading of 0.750 VDC ±10 mV.

(R9) for a reading of 2.75 VDC ±10 mV.

at TP2 is 0.750 VDC for the receiver’s 12 dB SINAD level and 2.75 VDC for a 50 dBm increase from the



receiver’s 12 dB SINAD level.

with a 1 KHz test tone at ±5.0 KHz deviation into Receiver 3.

(R33) for a reading of 0.750 VDC ±10 mV.

(R35) for a reading of 2.75 VDC ±10 mV.

at TP3 is 0.750 VDC for the receiver’s 12 dB SINAD level and 2.75 VDC for a 50 dBm increase from the



receiver’s 12 dB SINAD level.

637246.DOC Page 22

SECTION 5: FACTORY TEST PROCEDURE

Step 13 Inject on-frequency signal at a level of –80 dBm, modulated with a 1 KHz test tone at

±5.0 KHz deviation into Receiver 1.

Step 14 While monitoring the AC voltage at TP6 adjust audio 1 AC adjustment potentiometer

(R72) for 350 mVRMS (±1 mV).

Step 15 While monitoring the DC voltage at TP6 adjust audio 1 DC adjustment potentiometer

(R57) for 2.500 VDC (±1 mV).

The audio AC and DC adjustments are interactive, therefore continue adjusting R72 for 350 mVRMS and

R57 for 2.500 VDC until further adjustments are no longer required.



Step 16 Inject on-frequency signal at a level of –80 dBm, modulated with a 1 KHz test tone at

±5.0 KHz deviation into Receiver 2.

Step 17 While monitoring the AC voltage at TP6 adjust audio 1 AC adjustment potentiometer

(R71) for 350 mVRMS (±1 mV).

Step 18 While monitoring the DC voltage at TP6 adjust audio 1 DC adjustment potentiometer

(R58) for 2.500 VDC (±1 mV).

The audio AC and DC adjustments are interactive, therefore continue adjusting R71 for 350 mVRMS and

R58 for 2.500 VDC until further adjustments are no longer required.



Step 19 Inject on-frequency signal at a level of –80 dBm, modulated with a 1 KHz test tone at

±5.0 KHz deviation into Receiver 3.

Step 20 While monitoring the AC voltage at TP6 adjust audio 1 AC adjustment potentiometer

(R53) for 350 mVRMS (±1 mV).

Step 21 While monitoring the DC voltage at TP6 adjust audio 1 DC adjustment potentiometer

(R59) for 2.500 VDC (±1 mV).

The audio AC and DC adjustments are interactive, therefore continue adjusting R53 for 350 mVRMS and

R59 for 2.500 VDC until further adjustments are no longer required.



Step 22 Adjust the carrier detect potentiometer (R74) to illuminate a level of –116 dBm.

Receive Data

Step 1 Using a calibrated mobile radio, generate uplink data messages using the X=1400,19

Step 2 Attach an antenna to one of the base station’s receiver ports and verify on the base

command in the IPMessage Utility program.

station monitor screen (HyperTerminal) that the received message data quality are
consistently 240 and higher for 1400 character messages. Repeat test for each receiver.

637246.DOC Page 23

SECTION 5: FACTORY TEST PROCEDURE

Exciter

Step 1 Using the X=1400,19 command, generate data messages so the transmit power and

frequency can be checked.

Step 2 Note the power level and then on the power amplifier circuit board adjust the

potentiometer (R3) fully counterclockwise (this will enable low power transmit operation).

Step 3 Connect the base stations’ transmit port to the HP communication test set.

Step 4 While transmitting data messages using the X=1400,19 command, adjust the following:

 TCXO Y1 for minimum frequency error
 R42 for ±5 KHz deviation

Transmit output power should be approximately 1mWatt. The REFMOD adjustment needs to be made



while the base station is transmitting real data messages to and from a mobile radio. This is most easily
done using the ping command to ping the IPNC from a mobile radio. This will cause the base station to
repeatedly send data messages and will facilitate the REFMOD adjustment.

Step 5 Connect the base station to the IPNC.

Step 6 Using a calibrated mobile radio operating on the base station’s channel, adjust R30 for

consistent data quality readings of 248 (as observed on the mobile radio’s attached PC
IPMessage window). Access the MSDOS prompt and ping using the following command:

>;ping 192.168.3.3 –t –l 500 –w 2000

This command will ping the IPNC continuously with a 500-character test message. Press [Ctrl]+C to



stop the ping.

Power Amplifier

Step 1 Connect the base station’s transmit port to the communication test set.

Step 2 Using the X=1400,19 command, generate data messages.

Step 3 Slowly increase the base station output power by turning the power control potentiometer

clockwise until the power noted in Step 2.

Do not exceed 40 watts output power, as this will reduce the life of the amplifier module. If the base



station uses a power amplifier, output power must be set to achieve power output specified for the
specific base station installation.

Step 4 Perform a close visual inspection of the base station paying close attention to

manufacturing related problems such as loose screws, solder practices, etc.

637246.DOC Page 24

B64450G25 Base Station FCC Label Placement

SECTION 6: FCC LABEL

16842 Von Karman Ave S uite 200, CA 92606

Model

SNMAC ID

B64450G25 Base Station FCC Label

U.S. PATENT Nos.

5,640,695

6,018,647

6,243,393

Made in U.S.A

637246.DOC Page 25

Program and Configure the Base Station

Date

Serial Number

Firmware Revision

End User

Tester

Adjustment / Alignment Procedures

Receiver Injection

APPENDIX A: B64450G25 TEST DATA SHEET

Parameter

Injection Frequency Error at RXINJ1(within +/- 10
Hz of exact injection frequency)

P1 & C39

Receiver Diversity Reception Controller 1, 2 & 3

Parameter

U6 Pin 4

RSSI Test Point TB1-4

Distortion
(1 kHz Test Tone @ 5.0 kHz)

SINAD 12 dB
(1 kHz Test Tone @ 5 kHz)

SINAD 12 dB TP1

Spec Measured

Spec

+10 to +5 dBm

2.8 to 3.0 VDC

3%<

-119dBm >

0.75 VDC
+/- 1 mV

+/- 100 Hz

5 +/- 1 dBm

Receiver 1

Measured

Receiver 2

Measured

Receiver 3

Measured

SINAD +50 dB TP1

Audio AC Amplitude
(1 kHz Test Tone @ 5 kHz
Deviation)

Audio DC Amplitude
(1 kHz Test Tone @ 5 kHz
Deviation)

Carrier Detect Light Set

637246.DOC Page 26

2.75 +/- 1 mV

350 mVRMS

+/- 1mV

2.5 VDC
+/1 1mV

-116 dBm

Data Quality

APPENDIX A: B64450G25 TEST DATA SHEET

Parameter

Receiver 1 Data Quality
(x=1400, 19 Command IPMessage Utility)

Receiver 2 Data Quality
(x=1400, 19 Command IPMessage Utility)

Receiver 3 Data Quality
(x=1400, 19 Command IPMessage Utility)

Exciter

Parameter

Transmit Frequency Error
(Transmitting 1400 character test message)

Transmit Modulation Deviation
(5.3 kHz while transmitting 1400 character test
message)

Transmit Data Quality
(While transmitting 1400 character test message
to the base station)

Transmit Power Control

Warning: Do Not exceed 40 Watts RF output power during this test

Spec Measured

240>

240>

240>

Spec Measured

+/- 500 Hz

5.1 kHz to 5.3 kHz

240>

Parameter

Output Power
(Use x=1400,19 command)

Test Check List

Test Task

Attached copy of Base Station’s Firmware Settings

Visual Inspection

Copy Base Station Settings Below:

Spec RF Out RF Out Max Level set to

40 +/- 1 Watt

Completed

(9)

637246.DOC Page 27