IPSeries M1617-12 Mobile Radio Product Owner’s Manual Date: October 17, 2003 Document #: 516-80513-POM Revision: A Copyright 2003 IPMobileNet, Inc.
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.
TABLE OF CONTENTS SECTION 1: THEORY OF OPERATION ................................................................................. 4 General Block Diagram................................................................................................ 4 General Block Diagram Definitions..................................................................... 4 M1617-12 Mobile Radio Section Descriptions ........................................................... 6 Microcontroller ................................
SECTION 1: THEORY OF OEPRATION General Block Diagram General Block Diagram Definitions For increased data security, the modem supports the Federal Government developed Digital Encryption Standard (DES) data encryption and decryption protocols. This capability requires installation of third party, Internet Protocol (IP) compliant DES encryption and decryption software on the system. The M1617-12 mobile radio is comprised of two (2) circuit boards, the digital board and the RF board.
SECTION 1: THEORY OF OPERATION Modem Converts serial data into an analog audio waveform for transmission and analog audio from the receiver to serial data. Within a single chip it provides forward error detection and correction, bit interleaving for more robust data communications, and third generation collision detection and correction capabilities. Power Supply The power supply creates the various voltages required by the digital portion of the mobile radio.
SECTION 1: THEORY OF OPERATION M1617-12 Mobile Radio Section Descriptions The M1617-12 Mobile Radio works in a frequency range of 163-173 MHz and requires a 1/4-wavelength antenna. This section provides detailed descriptions of each of the sections within the M1617-12 Mobile Radio. Refer to Appendix A to view the M1617-12 Mobile Radio Circuit Board Diagram. Microcontroller The microcontroller (U30) is a major component of the radio as it manages the operation of the radio.
SECTION 1: THEORY OF OPERATION Modem The single-chip modem circuit converts parallel data to an analog audio waveform for transmission and analog audio from a receiver to parallel data. In addition to the modem functions, the chip provides forward error detection and correction (FEC), bit interleaving and Viterbi Soft Decision Algorithms for more robust data communications. The microcontroller section controls the modem operation. Address bus, address/data bus, and control lines operate the modem chip.
SECTION 1: THEORY OF OPERATION Receiver 1 Front-End This section contains components that include several RF Bandpass filters, a low-noise amplifier, and a MMIC mixer. Incoming signals pass through one (1) MMIC filter (FLT7) that selectively provides a high degree of outof-band signal rejection. A SAW amplifier (U3) amplifies the selected signals and is followed by another SAW filter (FLT8). The output from FLT8 passes through a mixer (U4).
SECTION 1: THEORY OF OPERATION The lower op amp (U9B) amplifies the signal from the low pass filter and applies it to the VCO via the VCOMOD output. Pot RV1 and RV2 are used to adjust maximum deviation. Injection Synthesizer The dual synthesizer chip (U38) is the major contributor of the receiver and transmitter injection oscillators. This device contains the key components of a phase locked loop (PLL), including a prescaler, programmable divider, and phase detector.
SECTION 1: THEORY OF OPERATION Equipment List The following table lists the equipment required to perform the M1617-12 Mobile Radio Factory Test Procedure: QTY 2 1 DESCRIPTION MANUFACTURER PC’s One for Mobile One for Base Service Monitor – Communication Test Set Windows 9X w/ IPMessage AVR MODEL HP HP8920B or equivalent Tektronix Fluke 77 or equivalent Astron RM35A Tektronix TDS 460A Pasternack PE7021-40 or equivalent 1 Digital multi-meter 1 DC power supply w/ ammeter, 13.
SECTION 1: THEORY OF OPERATION Programming and Configuring Mobile Radio Once the appropriate equipment for performing the factory test are gathered, perform the following steps to program and configure an M1617-12 Mobile Radio: Step 1 Enter the following information on the Test Data Sheet (see Appendix B): Radio Serial number Date test being performed Tester's Name Step 2 Program the radio to the current Firmware revision using the AVR programming utility.
SECTION 1: THEORY OF OPERATION Adjustment / Alignment Procedures Receiver Injection Perform the following steps to adjust the receiver injection and injection frequency: Step 1 While monitoring the receiver injection frequency at RXINJ1, adjust potentiometer R81 for minimum frequency error of +/- 100Hz. Record this value on the Test Data Sheet. Step 2 While monitoring the 44.545 MHz 2nd injection frequency at U34 pin 4, adjust trimmer capacitor CV4 for the maximum amplitude of this injection frequency.
SECTION 1: THEORY OF OPERATION Receiver 2 Perform the following steps to adjust receiver 2: Step 1 Inject an on-frequency carrier signal with an amplitude of -80 dBm, modulated with a 1 kHz test tone at +/- 5.0 kHz deviation into Receiver 2's antenna port. Step 2 While monitoring the voltage at RSSI2 Test Point with a DMM, adjust trimmer capacitor CV4 to midway between the points where the oscillation stops.
SECTION 1: THEORY OF OPERATION Transmit Data Perform the following steps to adjust transmit data: Step 1 Use IPMessage to set the transmit power to 0. Step 2 Using the x=2000,n command of IPMessage to generate transmit data messages while observing the transmitted signal on the HP RF communications test set, adjust pot R33 for minimum frequency error while transmitting data messages. Step 3 Turn potentiometer RV1 fully counterclockwise. Step 4 Adjust RV2 for deviation of 4.9 kHz.
SECTION 1: THEORY OF OPERATION Receive Data Perform the following steps to verify the receive data performance: Step 1 Using the DOS ping command on the PC connected to the radio, ping the network controller to generate uplink and downlink data messages. The following command will generate one Hundred 500 character messages: >;Ping 192.168.3.
SECTION 1: THEORY OF OPERATION Step 5 Verify the timing characteristics are identical to the plots in the next section, Uplink Hardware Timing Verification. Step 6 At the base station monitor PC, verify that all the data quality readings are 240 and higher. Step 7 Move the scope probes to monitor the timing at the mobile radio as described in Downlink Hardware Timing Verification. Generate test messages by pinging the IPNC from the PC attached to the radio.
SECTION 1: THEORY OF OPERATION Uplink Hardware Timing Verification Figure 2-1 below displays an oscilloscope plot of an uplink data message from the mobile to the base station. Channel 1 is connected to the base station's RSSI (XXX-12), channel 2 is connected to the base station's recovered modulation, and channel 3 is connected to the base station's modem chip select line. The scopes acquisition mode is high-resolution.
SECTION 1: THEORY OF OPERATION Figure 2-2 displays another oscilloscope plot of an up-link data message from the mobile to the base station. As in the last plot, channel 1 is connected to the base station's RSSI (J5-12), channel 2 is connected to the base station's recovered modulation test point, and channel 3 is connected to the base station's modem chip select line (U16-13). The scope's acquisition mode is now in the peak detect mode.
SECTION 1: THEORY OF OPERATION Downlink Hardware Timing Verification Figure 2-3 displays a plot of the downlink timing characteristics. Channel 1 is connected to RSSI, channel 2 is connected to recovered audio, and channel 3 is connected to the modem CS pin. The scope is in the high-resolution acquisition mode. There is a very short period of quiet time (no modulation) followed by approximately 12 milliseconds of modem synchronization time (sync time).
SECTION 1: THEORY OF OPERATION The plot in Figure 2-4 is the same as before but now the scope is in the peak detect acquisition mode. After the mobile radio detects a step response in the RSSI (caused by a down-link transmission), the radio's microcontroller waits an amount of time equal to the programmed value of the "carrier detect delay time" then instructs the modem to look for frame sync. When the microcontroller instructs the modem to look for frame sync, it asserts the modem's CS line (active low).
SECTION 3: FCC LABEL AND LABEL PLACEMENT M1617-12 Mobile Radio FCC Label Placement M1617-12 Mobile Radio FCC Label M1617-12_FCCRpt.
APPENDIX A: CIRCUIT BOARD DIAGRAMS M1617-12 Mobile Radio Digital Circuit Board + + + + + + + M1617-12 Mobile Radio RF Circuit Board + + + + + + + + + + + + + M1617-12_FCCRpt.
APPENDIX B: IPM1 TEST DATA SHEET Program and Configure Radio Date Serial Number Firmware Revision Tester Adjustment / Alignment Procedures Receiver Injection Parameter Spec Injection Frequency Error at RXINJ1(within +/- 100 Hz of exact injection frequency) U34 pin 4 power level Measured +/- 100 Hz -3 to -5 dBm Receiver 1& 2 Parameter Spec Audio DC Amplitude (1 kHz Test tone @ 5.0 kHz Deviation) 2.5 VDC +/- 1mV Audio AC Amplitude (1 kHz Test tone @ 5.
APPENDIX B: IPM1 TEST DATA SHEET Transmit Section Parameter Spec Transmit Modulation Deviation (4.9 kHz while transmitting 2000 character test message) 4.9 kHz Transmit Data Quality (While transmitting 2000 character test messages to the base station) 240 > Transmit Frequency Error (Transmitting 2000 character test message) Measured +/- 100Hz Transmit Power Control Caution: Do not to exceed 40-Watts RF output power during this test.
APPENDIX B: IPM1 TEST DATA SHEET Data Quality Parameter Receiver 1 Data Quality (While receiving 500 character “pings” from base station, 100 pings min, no errors allowed, CRC errors enabled) Receiver 2 Data Quality (While receiving 500 character “pings” from base station, 100 pings min, no errors allowed, CRC errors enabled) Spec Measured 240> 240> Final Tests Uplink Final Parameter Transmit Frequency Error Transmit Modulation Deviation Spec Measured +/- 100 Hz (Transmitting 19, 2000 character test
APPENDIX B: IPM1 TEST DATA SHEET Downlink Final Parameter Spec Measured Downlink Hardware Timing Verification Sync start (RSSI to CS first going low) Recovered Modulation Levels Frame Sync (From end of Sync to CS second time going low) Receiver 1 Data Quality (While receiving 500 character "pings" from base station, 100 pings min, no errors allowed, CRC errors enabled) LED Receiver 1 Receiver 2 Data Quality (While receiving 500 character "pings" from base station, 100 pings min, no errors allowed, CRC
