Radio Activity srl RA-160 DMR REPEATER – VHF BASE STATION User Manual use manual

Radio Activity srl DMR REPEATER – VHF BASE STATION use manual

Contents

use manual

DMRDIGITAL MOBILE RADIO ASSOCIATION    Radio Activity S.r.l.  Sede: Via Ponte Nuovo, 8 - 20128 Milano – email: radio.activity@fastwebnet.it - www.radioactivity-tlc.com Tel. 02.36514205 - FAX/Voicebox 1782242408  - Registrazione CCIAA Milano N° 1728248 - P.I./C.F.  04135130963                   DDMMRR  RReeppeeaatteerr  uusseerr  mmaannuuaall    VVeerrssiioonn  11vv22
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 2 / 31 Index 1 RADIO ACTIVITY DMR REPEATER AND EXPANDIBILITY TO SIMULCAST NETWORK......................4 2 PARAMETERS CONFIGURATION AND REMOTE CONTROL ..........................................................5 3 HARDWARE COMPOSITION OF A BASE STATION .......................................................................6 3.1 PSU: POWER SUPPLY UNIT MODULE.............................................................................................. 6 3.2 DSP: DIGITAL SIGNAL PROCESSOR ................................................................................................. 7 3.3 RECEIVER ...................................................................................................................................... 8 3.4 TRANSMITTER............................................................................................................................... 9 3.5 I/O AND SERVICES MODULE ........................................................................................................ 10 4 TECHNICAL DATA....................................................................................................................11 4.1 REGULATIONS COMPLIANCE........................................................................................................ 11 4.2 GENERAL CHARACTERISTICS ........................................................................................................ 11 4.3 IP interfacing .............................................................................................................................. 12 4.3.1 LAN protocol ................................................................................................................................... 12 4.3.2 LAN requirements ........................................................................................................................... 12 4.3.3 Ports and connectors ...................................................................................................................... 13 4.3.4 Codec VoIP ...................................................................................................................................... 13 4.4 Radio frequency.......................................................................................................................... 14 4.4.1 Transmitter...................................................................................................................................... 14 4.4.2 Receiver........................................................................................................................................... 15 4.4.3 Frequency bands ............................................................................................................................. 17 4.4.4 Commutation band (without duplexer).......................................................................................... 17 4.4.5 Branching requirements ................................................................................................................. 17 4.4.5.1 TX to antenna duplex isolation requirements @10W TX RF power ........................................ 17 4.4.5.2 Suggested RX max input limits on unwanted signals............................................................... 18 4.5 Other specifications .................................................................................................................... 18 4.5.1 Environmental parameters ............................................................................................................. 19 4.5.2 Power supply................................................................................................................................... 19 4.5.3 Mechanical characteristics.............................................................................................................. 19 4.5.4 Audio balanced interfaces............................................................................................................... 19 5 EQUIPMENT INSTALLATION AND MAINTENANCE ....................................................................20 5.1 CONNECTIONS AND PINOUTS...................................................................................................... 20 5.2 EQUIPMENT START UP, RUNNING AND ALARMS: INDICATOR LAMPS ........................................... 27 5.2.1 PSU .................................................................................................................................................. 27 5.2.2 DSP .................................................................................................................................................. 27
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 3 / 31 5.2.3 RX .................................................................................................................................................... 28 5.2.4 TX..................................................................................................................................................... 28 5.2.5 I/O ................................................................................................................................................... 28 5.3 GENERAL RECOMMENDATIONS AND NOTES ................................................................................ 29 5.3.1 Improper use................................................................................................................................... 29 5.3.2 Thermal dissipation......................................................................................................................... 29 5.3.3 Power supply system ...................................................................................................................... 29 5.3.4 Antenna........................................................................................................................................... 30 5.3.5 AF interface ..................................................................................................................................... 30 5.3.6 Manual settings............................................................................................................................... 30 5.3.7 Self-calibration process................................................................................................................... 31 5.3.8 PPS signal ........................................................................................................................................ 31
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 4 / 31  1 RADIO ACTIVITY DMR REPEATER AND EXPANDIBILITY TO SIMULCAST NETWORK  Radio Activity DMR repeater is designed to be modular from both HW and SW point of view, to maximize its flexibility and minimize costs, physical dimensions, consumptions. Basic model already has all the characteristics to work as a double standard repeater with all the features of analogical and digital service. It can be equipped with double receiver to counteract fading effects through diversity space reception. It is set to host communication and synchronization embedded devices to make the network expandable to a multi-frequency or iso-frequency multi-site system, with different type of links, operating with different transportation system topology, like microwave, UHF, fiber optics, generic TCP/IP connections. Privileged communication interface is ethernet standard type, maximally compatible with more diffused technology. This interface supports not only voice and data digital traffic, but also remote control management, which for Radio Activity equipment is very powerful: it is possible to have a complete monitor system of equipment status, it is possible to modify each parameter, to down-load each SW and configuration, launch self-test and calibration functions, to perform specific tests through internal embedded function generators and software analyzers of the station. For analogical voice traffic instead, a 2/4 wire and criteria line interface is available. Remote control service can be performed through an ethernet connection pre-existing in the site, or through GPRS modem which can be integrated into the station, or through the radio channel and another Radio Activity station. Fully modular structure allows to best configure the radio equipment, by adding and/or changing the required HW and SW functional blocks, to work as simple repeater, multi-frequency multi-site repeater, iso-frequency multi-site repeater. The basic structure of a base station is made of: ∞ PSU  module (not isolated 12Vdc from battery); ∞ DSP module; ∞ RX module; ∞ TX module. Optional modules and accessories are: ∞ I/O module with line interface with or without GSM/GPRS and GPS unit; ∞ PSU module for isolated power supply sources at 12V, 24V or 48V dc; ∞ RX module with diversity receiver; ∞ Duplexer, circulator or both;
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 5 / 31 ∞ Multi-receiver block for star-shaped network architectures with RF links; ∞ Antenna active splitter board. If a network architecture is needed, Radio Activity base stations can be connected through both a RF or ethernet link.   2 PARAMETERS CONFIGURATION AND REMOTE CONTROL Working parameter of the station are completely programmable through a SW package and a PC connection. The visible (and programmable) parameters set is very wide and extends from radio channel setting to tuning voltage measure of each local oscillator.  The software is called DMR_Manager for single base-stations or DMR_NetControl for network systems. Remote diagnostic of radio stations from PC can be performed through the Ethernet interface of the station. This interface is absolutely standard and very diffused, so relatively simple to be remoted. Radio Activity stations can be equipped with an embedded GPRS modem which will provide remote access to the station, if the installation site is covered by this service. Each operation can be remotely performed, exactly the same as in local connection, including FW down-loading, configuration Down-loading and up-loading, station check, parameters changing. Communication and supervision unit can spontaneously transmit diagnostic messages if defined “self-alarming” events happen. This is useful to automatically check the stations. Here following an example of remote control forms:
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 6 / 31   For further details about remote control software, refer to proper documentation (SW user manuals).  3 HARDWARE COMPOSITION OF A BASE STATION 33..11  PPSSUU::  PPOOWWEERR  SSUUPPPPLLYY  UUNNIITT  MMOODDUULLEE    Equipment is power supplied by nominal 13,8Vdc from battery with negative shorted to ground and with a maximum current absorption of 5 A. In case of other power supply sources, other PSU models are available, DC/DC (nominal 12-24-48V, isolated) or AC/DC (nominal 220V) with battery charger.  Input polarity and over-current protectionExternal I/O polarityIsolated external I/O power supplyDC/DC 6.5VccSpace for optional floating ground power supplyInput lightening protection
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 7 / 31   33..22  DDSSPP::  DDIIGGIITTAALL  SSIIGGNNAALL  PPRROOCCEESSSSOORR  The core of system’s “physical layer” is this unit which via software performs every function of signal processing inside radio station. What other equipments implement by adding boards (like synchronizers, phase and amplitude equalizers, signal decoders, modem, etc.), here are implemented by routines which can be freely matched, down-loaded and with superior performance. DSP and Processor coresVCTCXO reference D/A and A/D convertersand audio filtersEthernet LANRTCI/OAUDIO LAN This board can process up to 8 analogical duplex signals ensuring 70 dB of SNR; it can manage 16 logical signals which can be configured both as input and output. Communication and control functions of module are entrusted to a microprocessor which manages communications with external world and with other equipment modules. The microprocessor is based on LINUX operative system; it can manage a LAN ethernet 10/100 interface both for copper line and for fiber optic links, it is equipped with 4 serial ports to manage radio modules, GPS, auxiliary devices, external hosts; it is equipped with a Real Time Clock with tampon battery; it controls an embedded PLL to synchronize the entire station upon an internal (VCTCXO 0.5 ppm) or external temporal reference. DSP module is equipped with a synchronous serial port according RS485 standard levels, which can be programmed up to 16Mbit/s and can be used to interconnect together more transceiver or additional equipments. Main performed functions are the following:
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 8 / 31 ∞ Frequency self-tuning device ∞ Deviation self-calibration device   ∞ Analogical and digital demodulation ∞ RF circuits testing ∞ Phase modulator calibration ∞ RF output power control ∞ Low frequency lines management ∞ DMR protocols management ∞ Digital signals processing ∞ Management,  conditioning  and  routing  of  traffic  and  remote  control  signals  from  and  towards external world   33..33  RREECCEEIIVVEERR  Receiver can be supplied as single or double for space diversity reception.  Main and diversity channels are completely independent and coherent (sharing the same local oscillators) and they are designed according to a triple conversion heterodyne structure, with 45 MHz and 10.7 MHz intermediate frequencies and with vectorial conversion to base-band. Channel standard bandwidth is 12.5 KHz, but the receiver is prepared to accept also a settable channel bandwith of 25 KHz (with double funnel option) for  special applications. Vectorial receiver gives to the DSP input the electromagnetic field vector, as received from antennas, without performing any demodulation. By this way the DSP can sum with the appropriate phases the received signals to obtain a “soft diversity” reception. This corresponds to an electronic antennas alignment in order to receive the maximum available information along the incoming signal direction. III° LO 10.7MHz II° LO 34.3MHzI° LO Frx+45MHz (VHF)I° LO Frx-45MHz (UHF)Input filter and low noise amp.High IP3 MixerXTAL filter 45MHzXTAL filter 10.7MHz Micro-controllerIF system A further input (TX Test input), common for both receivers (main and diversity) is available,  for the receiver self-test and for modulator calibration. Through a DSP command, the receiver can switch its input onto test signal generated inside transmission synthesizer module. That signal, amplitude calibrated by Factory, is modulated at receiving frequency and received by DSP. A fundamental test loop is close by this way.
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 9 / 31 The switching between normal and test input is implemented through PIN diodes. Receiver modules is managed by a microcontroller unit whose program is hosted inside internal e2prom flash memory to lower parasitic emissions. This FW can be loaded through serial connection. The microcontroller, in addition to managing internal function of the unit, transfers measured parameters to the control unit through 115.2 Kb/s serial line. The board is realized with surface mounting components (SMD) to maximally reduce dimensions. Modular unit is housed in a shielded, 4TE high box for 220mm Eurocards. On the frontal panel 2 LEDs are placed for monitoring internal PLLs lock status.  33..44  TTRRAANNSSMMIITTTTEERR  Transmitter module is realized with surface mounting components (SMD) and it is housed in a shielded, 8TE box for 220mm Eurocards, with an heatsink mounted on side, with a thermal resistance of about 1.2°K/W. The unit can be extracted from the front side of the rack. MOS power amplifierspower detecting strip linesmicrocontrollersynthesizer On the frontal panel two LEDs are placed to monitor the transmitter status. Base-band functions, equalizing, limiting, low-pass filtering end eventual emphasis functions are performed by the DSP unit, which provides also for nominal and maximum deviation calibration by looping modulator with receiver. Modulator is digital vectorial, then the synthesized signal by local oscillator implements the frequency shifting of the signal which has been directly modulated in base-band by DSP unit and transferred to transmitter through its I and Q components.
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 10 / 31 The amplifier is realized by three cascaded stages and RF output power regulation (between 1 and 25W) is implemented by controlling the gates voltages of MOSFET amplifier stages. Power amplifier works in C class and ensures a very high efficiency, lowering the needed power from supply system and lowering the thermal dissipation inside the cabinet. Direct  and reflected output power are measured by a directional coupler. Power control circuit acts in a closed loop and keeps constant the total power at MOSFET drain. Inside the module a thermal sensor is hosted and it is directly connected to the internal microcontroller which enables the command for air forced cooling fan of the cabinet if the temperature rises over 85°C. Anyway, if reflected power or mosfet temperature exceeds protection threshold, regulation circuit will lower output power up to safe levels for transmitter. The current flowing into final amplifier transistor is continuously monitored by microcontroller to verify the correct functioning and to reveal an eventual efficiency degradation. The module is equipped with an harmonic filter to lower spurious emissions under required levels by existing regulations.  33..55  II//OO  AANNDD  SSEERRVVIICCEESS  MMOODDUULLEE  I/O and Services module is a unit integrating different interfaces and functions, that for some applications can be optional but for others become essential.  For this reason the module can be differently equipped with its different logical blocks, according to the particular application. The embedded block are the following: ∞ Telephone line interface: 2/4W+E&M line interface to remote analogical audio and perform automatic routing through telephonic line ∞ Opto-isolated  I/O:  2  input  +  2  output  contacts  programmable  (both  N.O.  or  N.C.)  for  remote monitoring local sensors and remote controlling local actuators ∞ Opto-isolated alarms: two alarms output (1 warning + 1 fatal) ∞ Analogical input: 2 not isolated inputs, 1 for voltage sensing (0..20V referred to ground) + 1 for current sensing (4…20mA). These input can be connected the first in parallel and the latter in series with the analogous ones of other similar equipments ∞ GSM/GPRS  modem:  embedded  communication  module  for  remote  control  if  the  site  is  covered  by GSM or GPRS service. It requires only an external passive antenna ∞ GPS receiver: embedded receiver for GPS service, with  high precision Pulse Per Second (PPS) output function in order to synchronize the station. Only an external active antenna is required ∞ RS232 converter: 115.2Kbit/s serial interface for remote control I/O and services module is equipped with 8 LEDs on the frontal panel to monitor the status of opto-isolated I/O, the status of GPRS modem and the presence of PPS. Modular unit is housed in a shielded, 4TE high box for 220mm Eurocards.
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 11 / 31  GSM/GPRS - GPSBF line interfaceSIM HOLDERI/O contacts  4 TECHNICAL DATA 44..11  RREEGGUULLAATTIIOONNSS  CCOOMMPPLLIIAANNCCEE  Equipments are compliant with existing regulations, in particular: 1. EN 300 086-2: Technical characteristics and test conditions for radio equipment for analogue speech. 2. EN  300  113-2:  Technical  characteristics and  test  conditions  for  non  speech  radio  equipment  for the transmission of data. 3. ETSI  TS  102361:  Electromagnetic  compatibility  and  Radio  spectrum  Matters  (ERM);  Digital Mobile Radio (DMR) Systems. The equipment is able to manage OSI stack layers 1 – 2 – 3 of DMR protocol, making active interaction possible with mobile terminals.  44..22  GGEENNEERRAALL  CCHHAARRAACCTTEERRIISSTTIICCSS   Funnel  12.5 KHz (25KHz optional for special purpose) Maximum channels number  200 Operating mode  Dual-standard, analogical and digital Operating mode selection  Totally automatic Frequency stability  +/- 0.5 ppm I/O 4 opto-isolated OUT (2 alarms + 2 generic) 4 IN (2 digital opto-isolated + 2 analogical referred to ground) Voice/data digital interface  LAN 10/100 copper or fiber optic Analogical audio interface  2/4W + E/M (BCA-C/U optional)
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 12 / 31 Base Bandwidth  Audio 300-3400 Hz ±1dB Modulation 0-5 KHz Calibration and tests  Automatic at start-up and/or by remote control Remote control  Via ethernet / serial RS232 / GPRS  44..33  IIPP  IINNTTEERRFFAACCIINNGG  4.3.1 LAN PROTOCOL  4.3.2 LAN REQUIREMENTS Protocols for voice packets UDP/IP (ipv4), unicast (from RA-TI-XXX to master) and multicast (from master to RA-TI-XXX), with DSCP set to “EF” (Telephony service class), according to RFC 4594 Protocols  for  BS  “internal”  network control  UDP/IP (ipv4), unicast and multicast, with DSCP set to “CS6” (Network Control service class), according to RFC 4594 Protocols  for  remote  control,  setup and surveillance UDP/IP  and  TCP/IP (ipv4) unicast  and  broadcast with DSCP  set to “AF13”  (High-Throughput  Data  service  class),  according  to  RFC 4594 Audio format  Analog: 64 kb/s – 8 bit x 8 KHz linear coded DMR: AMBE II+TM (Advanced Multi-Band Excitation) Audio frame block net payload Analog: 60 ms – 480 bytes/samples DMR  selectable  single/double  timeslot:  60  ms  –  27  bytes  each timeslot
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 13 / 31  4.3.3 PORTS AND CONNECTORS UTP LAN Port  Ethernet 10BT/100TX (auto MDI/MDI-X) on an RJ45 socket Optical LAN Port (option)  Ethernet 100FX on SC-SC socket Serial control Port  RS232 V.24 asynchronous 600 ÷ 115200 bps on a DB9 female connector BUS control Port  TTL on a dual-in-line 10 pins male connector  4.3.4 CODEC VOIP Uncoded audio source  64 kbps – 8bitx8KHz Net bit-rate (1CH)  2450 bps FEC Coded bit-rate (1CH)  3600 bps Audio frame block  20ms Jitter  (deviation  of  averaged  packet time delay) The Base Station is able to compensate Jitter delay up to 200 ms. The total delay averaged + jitter must not exceeds 400ms (each way) Maximum delay The Base Station is able to compensate round trip delay less then 900ms (jitters included) Packet loss  < 0.1 % SLAVE: 70 kb/s in analog to/from Master 24 kb/s in DMR to/from Master (both timeslots) Minimum  bandwidth  (network signaling  and  remote  control  polling inclusive)  MASTER to serve N SLAVES (both timeslots): 70 kb/s in analog to Slaves, 70 kb/s x N from Slaves 24 kb/s in DMR to Slaves, 24 kb/s x N from Slaves
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 14 / 31 Coder algorithm  AMBE II+TM (Advanced Multi-Band Excitation) DMR compatibility  Motorola Mototrbo series   44..44  RRAADDIIOO  FFRREEQQUUEENNCCYY  Radio Transceiver model RA080, RA160, RA450, RA900, typical values.  4.4.1 TRANSMITTER Module output power  1/5/10/15/20/25 W RF final transistor protection  to high temperature   85°C +/- 5°C progressively reducing the RF power Available modulation  FM, PM, GFSK, 4FSK Modulation bandwidth  0 .. 5000 Hz Synthesis step  4/5/6,25/10 KHz Transmitting duty cycle  Continued 100% ROS protection  Min.10’ in short  circuit as well as in  open circuit Adjacent channel noise -75 dBc @25KHz -65 dBc @12.5KHz FM distortion  < 1.5 % Noise -56 dBp @25KHz -50 dBp @12.5KHz
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 15 / 31 Frequency stability  0.5 p.p.m. Max reverse input signal  -20dBm to avoid intermodulation +20dBm no damage  4.4.2 RECEIVER Maximum sensitivity -113 dBm @20 dBp SINAD -118dBm @5% BER without diversity -121dBm @5% BER with diversity Operating maximum input  -10 dBm Maximum input without permanent damages  +10 dBm Reception mode  Vectorial I e Q Received signal band  0..5000 Hz Synthesis step  6,25 KHz Co-channel protection 8 dB @25 KHz 12 dB @12.5KHz Adjacent channel selectivity 73 dB @25 KHz 62 dB @12.5 KHz Blocking protection  80 dB Intermodulation protection  75 dB Intercept  3° order IP3in  +15 dBm
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 16 / 31 Distortion  <2 % Noise -53 dBp @25 KHz -47 dBp @12.5 KHz -60 dBp (with voice search option) Frequency stability  0.5 p.p.m.
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 17 / 31  4.4.3 FREQUENCY BANDS Model  Frequency band RA-900   UHF – HH => 865-925 MHz RA-450   UHF – H => 410-440 MHz RA-450  UHF – L  => 430-470 MHz RA-160  VHF – H => 145-174 MHz RA-080  VHF – L => 68-88 MHz  4.4.4 COMMUTATION BAND (WITHOUT DUPLEXER) Band  TX  RX UHF – H  30 MHz  14 MHz UHF – L   30 MHz  12 MHz VHF – H  28 MHz  28 MHz VHF – L  20 MHz  20 MHz  4.4.5 BRANCHING REQUIREMENTS 4.4.5.1 TX to antenna duplex isolation requirements @10W TX RF power TXRX main
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 18 / 31  Band  +/-40MHz  +/-9MHz  +/-4.5MHz  +/-3MHz  +/-1.5MHz  +/-0.8MHz UHF – HH  75dB           UHF – H/L  75dB  75dB         VHF – H  75dB  75dB  75dB  78dB  81dB  85dB VHF – L  75dB  75dB  75dB  75dB  78dB  81dB   4.4.5.2 Suggested RX max input limits on unwanted signals  TXRX main  Band  +/-1MHz  +/-500KHz  +/-100KHz  +/-50KHz  +/-25KHz  +/-12.5KHz UHF – HH  -32dBm  -43dBm  -45dBm  -47dBm  -49dBm  -58dBm UHF – H/L   -32dBm  -41dBm  -43dBm  -44dBm  -48dBm  -56dBm VHF – H  -32dBm  -40dBm  -42dBm  -43dBm  -47dBm  -54dBm VHF – L  -32dBm  -36dBm  -38dBm  -40dBm  -43dBm  -50dBm  44..55  OOTTHHEERR  SSPPEECCIIFFIICCAATTIIOONNSS
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 19 / 31 4.5.1 ENVIRONMENTAL PARAMETERS Operating Temperature  -25 ÷ +55 °C Storage Temperature  -40 ÷ +70 °C Relative Humidity  Max 80% not condensed  4.5.2 POWER SUPPLY Nominal Voltage 11 - 15 Vcc (neg. ground) 19 – 36 Vcc (floating ground) 38 – 60 Vcc (floating ground) Max ripple  30 mVpp Polarity reversal protection  -70 V Short-circuit protection  Electronic protection with automatic restore and double fuse on input line Power consumption  TX: 55 W @20W RF RX: 8 W  4.5.3 MECHANICAL CHARACTERISTICS Dimensions  128 x 426 x 280 mm 1/2 rack 19” x 3TU x 280 mm mounting Weight  6.0 Kg  4.5.4 AUDIO BALANCED INTERFACES Interface type  2/4 wires isolated balanced line on RJ45 socket Line isolation  1500 V Used audio bandwidth  300÷3400 Hz Input/output Impedance   600 Ohm
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 20 / 31 Side tone reflection  < - 20 dB Output nominal level  -20 .. 0 dBm Input nominal level  -20 .. 0 dBm Hang line current  10..50 mA Level adjust  software by 0.1dB step Ring detect  60..120 Vpp @25Hz Ring generator (option)  90Vpp @25Hz Release tone detection  3 pulses of 425Hz @50% duty 250ms/250ms     5 EQUIPMENT INSTALLATION AND MAINTENANCE  55..11  CCOONNNNEECCTTIIOONNSS  AANNDD  PPIINNOOUUTTSS  RA-XXX base-stations require a reduced set of connections for normal working conditions (power supply, with optional “power good” and “inhibit” controls, antennas, eventual ethernet link for remote control or for multi-site link). The transceiver is equipped with other sockets in order to connect it to auxiliary equipment, like other transceivers, multi-receivers, audio interfaces, remote site control devices, fan cooler, and so on. On the front side of the equipment there are only the 10BT/100TX ethernet connector for the remote control of the equipment and for data/audio packets communication, the power on/off switch  and the LEDs for monitoring the status of the equipment. All other connectors are placed on the back side of the transceiver. The following picture shows the fundamental connections in red color and the optional ones in blue color.
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 21 / 31 GPS antennaGSM / GPRS antennaMain RX / TX antennaDiversity RX antenna12Vcc PowersupplyInhibit / Power_goodcontactsAlarmoutputsI/O contactsAudio lineinterfaceAnaloginputs6V-12V output, max 200mAFAN activationRS232 portMain RX antennaMTCH synchronousserial interfacefusesExternalsynchronisminputMatrix connector The following connections are available (for each one, a picture of the connector and the related schematic diagram of back plane PCB are shown): ∞ Power Supply: 13.2Vdc with negative to ground, or optionally 24Vdc or 48Vdc isolated. The equipment is  protected  from  polarity  inversion.  Two  automotive  type  10A  fuses  work  against  accidental  short circuits. The connector has 3 poles (+Vin, rack ground, -Vin) with 5.08mm pitch 112233P123 - 5.08pitchF2FUS-AUTO-10AF1FUS-AUTO-10A-Vin+Vin ∞ Power  supply  control:  normally  closed  optically  isolated  “PG”  (Power  Good)  contact  ensures  the presence  of  internal  correct  supplies;  “INH”  (Inhibit)  contact  should  be  kept  closed/open  to  switch off/on the equipment. Input contact is internally polarized with +/-12V. 1324P6MCV 0,5/ 4-G-2,5PG_ACOM_OPTOPG_B/INHIBIT ∞ Antennas: up to 5 antenna connectors can be mounted according to the specifications of equipment.  1. A female N-type connector is connected to the output of the duplexer (if present) or to the output  of the TX (if branching is not mounted inside the equipment);  2. A  female  BNC-type  connector  (above  the  N-type  one)  is  present  if  duplexer  is  not mounted inside  the equipment. It is connected to main RX;
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 22 / 31 3. A  female  BNC-type  connector  (below  the  N-type  one)  is  present  if  the  base  station  is equipped with the diversity receiver. This connector is directly connected to the input of the  diversity  receiver,  without  any  cavity  filter/isolation  inside  the  equipment.  Care should be taken in designing external branching and radiant system; 4. A  female  SMA-type  connector    for    embedded  GPS  receiver.  The  equipment  supplies 5Vdc through this connector for the remote active antenna (which is requested with a minimum  gain  of  20dB  and  possibly  equipped  with  a  rejecting  filter  for  out-of-band spectral components); 5. A female SMA-type connector   for GSM/GPRS embedded transceiver. A passive antenna is required. (The SIM holder is mounted inside I/O module.). GPS antennaGSM / GPRS antennaDuplex antenna / TX antennaDiversity RX antennaMain RX antenna ∞ COM  port:  9  poles  D-SUB  type  socket,  connected  to  an  optional  RS232  serial  port  (115.2Kbit/sec, 8,N,1)  for  remote  controlling  the  equipment  by  a  PC.  This  is  a  secondary  access  port  to  the  base station, auxiliary/alternative respect to the main ethernet port. The RS232 driver is mounted on the I/O module. 594837261J4SJV9rts_232CTScts_232TX-PCRX-PCTX_232RX_232RTS  ∞ “Fan” and “Auxiliary power supply output”: the first is an active low, open collector type contact,  not isolated,  which  can  activate  an  optional  external  cooling  system  if  RF  power  amplifier  temperature would rise over 90°C. In normal ambient and working conditions, no cooling system is required. The second connector supplies 12Vdc 200mA and 6Vdc 200mA (not isolated) for eventual auxiliary devices . 12P2MCV 0,5/ 2-G-2,5HI-TEMP6V_SERV12V_SERV1324P1MCV 0,5/ 4-G-2,5
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 23 / 31 ∞ “MTCH”:  two  8  poles  RJ45  connectors  (connected  in  parallel)  give  access  to  internal  digital  audio multichannel  (synchronous,  TDMA,  4Mbit/s  speed,  serial  interface  with  custom  protocol).  These connectors are used to implement any particular system and network architectures which require the base station to be connected to other devices equipped with the same MTCH interface. DT0/DR0_BRFS0_ASCLK0_ADR0_A DR0_BRFS0_BDT0/DR0_ASCLK0_B135724681112J2RJ45  ∞ Analog inputs:  a 4 poles connector with 2 not isolated analog inputs, one for current (dc, from 0 to 20mA)  and  one  for  voltage  (dc,  from  0  to  20V  referred  to  GND).  Current  inputs  of  different equipments  ca  be  connected  in  series;  voltage  inputs  of  different  equipment  can  be  connected  in parallel.   AN_I_IN-1324P5MCV 0,5/ 4-G-2,5AN_V_INAN_I_IN_+  ∞ AF line interface: a 8 poles connector to connect the base station to a telephone or console line (both 2 or 4 wire lines, also with E and M criteria) to monitor analog traffic only or for synchronization aim. Starting from the top, the pinout is as following: output line (use this contacts in case of 2 wire line – bidirectional -), squelch input contact (optically isolated, normally open), PTT output contact (optically isolated, normally open, internally polarized with +/-12V), input line(only for 4 wire line). COM_SQ_OUT_013572468P9MCV 0,5/ 8-G-2,5COM_OPTOBF0-IN-BBF0-OUT-BBF0-IN-ABF0-OUT-ASQ_OUT_0PTT_IN_0  ∞ Digital I/O: a 8 poles connector with 4 optically isolated digital contacts, 2 outputs (in the upper part, normally  open)  and  2  inputs  (in  the  lower  part,  normally  closed).  Input  contacts  are  internally polarized with +/-12V.  COM_1_OUTCOM_2_OUT1_OUT2_OUT1_IN2_IN13572468P10MCV 0,5/ 8-G-2,5COM_OPTOCOM_OPTO  ∞ Alarm outputs: a 4 poles connector with 2 optically isolated digital contacts (normally open). Alarm 2 output will be closed if the base station undergoes a temporary out of service or if a slight problem happens (warning); alarm 1 output will be closed during power on of the station or if a heavy problem happens (stable out of service).  1324P13MCV 0,5/ 4-G-2,5COM_ALR_1_OUTCOM_ALR_2_OUTALR_1_OUTALR_2_OUT
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 24 / 31  ∞ “Matrix”  connector:  a  20  poles  connector  (2x10,  pitch  2.54mm)  and  a  coaxial  MCX-type  connector with a set of signals which can be used to implement any particular system and network architectures which  require  the  base  station  to  be  connected  to  other  devices  equipped  with  the  same  MTCH interface.  52431J9JCOAXMINI90*LO_TEST12V_SERV6V_SERVSYNC_12M8URES6V_SERVRESERVEDRESERVEDON-LINE12V_SERVNOR/RISRX/TXPPS_GPSLINE_OPTO COM_OPTO1357911131517192468101214161820P4SP20COM_MS_RX COM_MS_TX  ∞ SYNC  IN:  a  MCX  coaxial  connector  for  eventual  external  synchronization  input  signal.  Normally  this input is unused, it is needed for special applications which require an external synchronization source (sinusoidal, at 12.8MHz, with level between -10 and 0 dBm).   52431J6JCOAXMCX90SYNC_IN
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 25 / 31 For example, the following picture shows how two repeaters should be connected to implement a simulcast network with ethernet links.   GPS and GSM/GPRS antennaEthernet SWITCHLAN cableLAN cableLAN cableRemote control PC “DMR Manager”GPSGSM/GPRSDMR masterDiversity RX antenna,    if neededMain RX / TX antenna GPS and GSM/GPRS antennaGPSGSM/GPRSDMR slaveDiversity RX antenna,    if neededMain RX / TX antenna   In case of UHF links, 2 transceivers are needed for each site, one for local broadcasting and the other for the link between master and satellite. They can be mounted into the same rack 19” 3U. The following picture shows the back side of a RF linked satellite.
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 26 / 31 GPS antennaGSM / GPRS antennaMain RX / TX antennaDiversity RX antenna12Vcc PowersupplyInhibit / Power_goodcontactsAlarmoutputsI/O contacts Audio lineinterfaceAnaloginputs6V-12V output, max 200mAFAN activationRS232 port Main RX / TX antenna6V-12V output, max 200mAFAN activationRS232 port12Vcc PowersupplyAlarmoutputsI/O contactsAudio lineinterfaceAnaloginputsInhibit / Power_goodcontactsMTCH terminations to be connectedtogether by an ethernet cord  For this example, the following picture shows how two repeaters should be connected to implement a simulcast network with UHF links. Two ethernet patch cord are needed to connect together the MTCH ports and the ethernet ports of the two radios; they are represented in pink color.  l GPS and GSM/GPRS antennaLAN cableGPSGSM/GPRSDMR masterDiversity RX antenna (broadcast),    if neededMain RX / TX antenna (link)Main RX / TX antenna (broadcast)MTCH cableGPS and GSM/GPRS antennaLAN cableGPSGSM/GPRSDMR slaveDiversity RX antenna (broadcast),    if neededMain RX / TX antenna (link)Main RX / TX antenna (broadcast)MTCH cable
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 27 / 31  55..22  EEQQUUIIPPMMEENNTT  SSTTAARRTT  UUPP,,  RRUUNNNNIINNGG  AANNDD  AALLAARRMMSS::  IINNDDIICCAATTOORR  LLAAMMPPSS   The base stations of RA-xxx series are designed to reduce as much as possible the maintenance work. To this aim, specific solutions have been implemented to prevent aging drifts. Each time the base station is switched on, a self-calibration process is performed in order to finely tune the modulation and the demodulation parameters. This process checks the total loop BF-TX-RX-BF by looping the synthesizer output of the TX on the input of the RX and the DSP unit can store the results into flash memory and update the older ones which have been previously saved. The correct results of a calibration process are symptom of an optimal tune of the radio transceiver. If the calibration process ends with errors, the transceiver can anyway work correctly by loading the older tuning parameters and the newer ones are not saved. On the frontal panel of the RA-xxx base stations, there are some LED lamps for monitoring the status of the equipment. They have different meanings, during power on process, respect to normal running condition. Here following, a description of the meaning of the LEDs, grouped module by module. In general, if the equipment works correctly, all leds are off or green; if a warning arises, one or more leds start flashing in red color; if a problem or an alarm arises, one or more leds are red. (An exception should be made for eventual leds which show the status of line output criteria: they are red if the corresponding criteria are enabled).  5.2.1 PSU When the base station is switched on, the 2 leds of PSU module should be green both: ∞ the  upper  led is  red if  the supplied input  voltage  is too low  or too  high;  it is  off  in  case of  inverted polarity of connection to power supply system; it is green if the supplied input voltage belong to the correct working range; ∞ the  lower  led  is  green  if  the  secondary  internal  voltages  are  correctly  supplied  by  PSU  module, otherwise it is off. 5.2.2 DSP When the base station is switched on, DSP module performs a booting process, during which the upper 4 leds are orange; the lower 2 leds respectively monitor the activity through ethernet connection (the 5th led flashes with orange color during data communication) and the connection to ethernet network (the 6th led is green if the connection is established), therefore they are independent from the logical status of the module.  At the end of the booting process, the DSP module executes the following steps in sequence, which are also visually indicated by leds:  ∞ FW uploading to clock generator (3rd led flashes in orange color); ∞ FW uploading to DSP and reset of peripheral modules (2nd led flashes in orange color) ∞ DSP startup (1st led flashes in orange color) ∞ RX self-calibration(2nd led flashes in red color) ∞ TX self-calibration (1st  led flashes in red color) ∞ TXRX loop self-calibration (3rd led flashes in red color)
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 28 / 31 ∞ Frequency  setup  of  working  channel  (1st    led  flashes  in  red  color  in  case  of  fine  calibration  of parameters) At this point the DSP reaches its normal running status and the leds behave as follows: ∞ 1st upper led: it flashes in green color if calibration of TX failed; it is green during transmission on TS1; it  flashes  in  red  color  if  multichannel  is  enabled  but  the  DSP  cannot  receive  data  correctly  (this function will be assigned to the 2nd led in future SW version); otherwise it is off; ∞ 2nd  led:  it  flashes  in  green  color  if  calibration  of  RX  failed;  it  is  green  during transmission  on  TS2;  it flashes in red color if multichannel is enabled but the DSP cannot receive clock correctly (this function will be assigned to the 3rd led in future SW version); otherwise it is off; ∞ 3rd led: it flashes in green color if calibration of TXRX loop failed; it is green during reception from TS1; otherwise it is off; ∞ 4th  led:  it  flashes  in  green  color  if  the  system  clock  is  locked  to  the  synchronism  source;  it  is  green during reception from TS2; it flashes in red color if the DSP is not locked to the synchronism source as set in “AFC” routine; otherwise it is off; ∞ 5th led: it flashes in orange color during data communication through ethernet port; otherwise it is off; ∞ 6th led: it is green if the ethernet connection is established; otherwise it is off. During analog transmission (or reception), both the leds related to transmission (or reception) on TS1 and TS2 are green, because both the timeslot are busy during analog communication. 5.2.3  RX RX module is equipped with two leds: ∞ the upper led flashes very fast in green-red color during data reception-transmission through control serial port of the module (during FW upload process on peripheral microprocessor); it is red in case of unlock of the upper local oscillator which is used to tune the RX; otherwise it is off; ∞ the  lower  led  flashes  in  red  color  if  there  is  no  application  (main)  FW  uploaded  to  peripheral microprocessor; it flashes in green color during start-up booting process; it is red in case of unlock of at least one of the IF local oscillators; otherwise it is off. 5.2.4 TX TX module is equipped with two leds: ∞ the upper led flashes very fast in green-red color during data reception-transmission through control serial port of the module (during FW upload process on peripheral microprocessor); it is red in case of unlock of the local oscillator or during transmission if the generated RF power is less than a half of its set value; it is green during transmission with a greater RF power than 10W; otherwise it is off; ∞ the  lower  led  flashes  in  red  color  if  there  is  no  application  (main)  FW  uploaded  to  peripheral microprocessor; it flashes in green color during start-up booting process; it is red in case of excessive SWR and consequent forced interruption of transmission; it is green during transmission with a lower (or equal) RF power than 10W; otherwise it is off. 5.2.5 I/O I/O module is equipped with eight leds, of which the upper 6 reflect the status of corresponding digital I/O contacts that are present on the back side of the equipment, while the lower 2 reflect the status of the embedded GSM/GPRS-GPS device. They behave as follows:
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 29 / 31 ∞ the  upper  led  is  red  if  a  heavy  problem  happens  to  the  base  station  or  during  its  booting  process (meaning a stable out of service status); the corresponding alarm 1 is active; otherwise the led is off; ∞ the 2nd led is red if the base station undergoes a temporary out of service (example during a channel change) or if a slight problem happens (warning); the corresponding alarm 2 is active; otherwise the led is off; ∞ the 3rd led is green if the output contact 1 is active (normally open); ∞ the 4th led is green if the output contact 2 is active (normally open); ∞ the 5th led is green if the input contact 1 is active (normally closed); ∞ the 6th led is green if the input contact 2 is active (normally closed); ∞ the 7th led flashes in green color if PPS signal is generated (Attention: after the first reception of a valid GPS  signal  for  generating  PPS  signal,  this  signal  is  always  generated  by  the  module,  it  is  eventually locked to  local  clock of the divice in case of  temporary  unlock with GPS reference. The DSP module checks its effective validity); otherwise it is off; ∞ the 8th led flashes in green color if embedded GSM/GPRS module is enabled; it flashes fast if the SIM card  is  missing,  slower  if  the  SIM    card  is  present;  it  is  red  during  transmission  of  GSM  bursts; otherwise it is off.   55..33  GGEENNEERRAALL  RREECCOOMMMMEENNDDAATTIIOONNSS  AANNDD  NNOOTTEESS   5.3.1 IMPROPER USE It is recommended to install the equipments in closed cabinet, to allow only authorized people to access to them, in order to avoid handling or improper use of equipments and to avoid accidental contact with hot surfaces. 5.3.2 THERMAL DISSIPATION Outlet cabinet containing the equipments should be designed to ensure a good internal air flux for heating dissipation. A free slot of at least 1UT is recommended between two near equipments. In case RF transmitter is set for its maximum power, it is active with a duty-cycle near to 100% and ambient temperature could be above 40°C, a larger respect area must be considered around the rack and an air forced cooling system  should be eventually designed (“FAN” contact of the equipment can be used to switch on and off cooling system). The transmitter is protected against over-temperature: if the RF mosfet temperature arises over 90°C, the microprocessor will automatically decrease the generated RF power in order to make the amplifier work in safety conditions. The nominal RF power will be restored as soon as the mosfet temperature will decrease below 60°C. 5.3.3 POWER SUPPLY SYSTEM Internal power supply voltage is nominally set to 13.2V dc from battery, with negative pole connected to ground, and it is protected against polarity inversion, over-voltage, under-voltage, short-circuits. Isolated PSU modules can be optionally supplied for 12V/24V/48V dc input voltage.
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 30 / 31 The equipment is designed to be powered by a safe supply source which grants a double insulation of output voltage from dangerous voltages. The electric plant must contain a switch to cut off power supply lines, according to national law and directives. It is recommended to use power supply sources with low impedance output stage to make the hot swap controller of PSU properly work. For example, if power supply has an output filter with an inductive equivalent impedance, a capacitor can be added in parallel in order to reduce the resulting output impedance. Power supply cable dimensions must be calculated for a maximum current absorption of 7A @13.2V DC, or 4A @24V, or 2A @48V, in order to avoid significant voltage drop, especially after fast transient. They should be protected by a fuse or a short circuit protection system which should be placed as near as possible to power supply source. The transceiver is equipped with a couple of automotive type fuses, placed near power supply input connector, for short circuits protection. This type of fuses is designed for battery up to 55 Ah; for bigger battery power, other more effective devices should be placed before the transceiver to grant a correct power cut off.   It is also recommended to connect a good ground reference to the rack and to its metal components, by using both central pin of power supply connector and the screw on the right side of the rack. A second screw for ground connection is place on the back side of the rack.  5.3.4 ANTENNA Antenna discharger are recommended to prevent damages due to eventual atmospheric discharges. These devices should be placed on antenna connection cable, just before equipments installation shelter, and they must be connected to an optimum ground reference.  Attention must be paid also to connect the eventual diversity receiver to the radiant system: the input of this receiver is directly connected to BNC connector on the back side of the rack, without any filter. The corresponding antenna must be placed far enough from the transmitting antenna in order to avoid receiver desensitization and to get the correct isolation. To avoid any problem, it is recommended to insert a notch or a pass-band cavity to protect the receiver. If an external branching is connected to the equipment, it must be designed to ensure the needed isolations between transmitter and receivers. 5.3.5 AF INTERFACE If a 2/4W telephone line is connected to the equipment, external primary discharges are recommended to prevent damages due to eventual atmospheric discharges on the line. The internal AF interface is protected only by secondary dischargers.  5.3.6 MANUAL SETTINGS The equipments of RA-xxx series are designed to minimize the set of needed hardware settings. Before installing the equipments the following manual settings must be verified if digital I/O and AF interface are used respectively:
DMR repeater  24/01/2011                  Versione 1.3   Documento Riservato - non divulgabile senza autorizzazione Pag. 31 / 31 ∞ voltage  polarity,  used  to  supply  the  optically  isolated  digital  input  contacts:  inside  PSU  module,  a 4 poles dip-switch allows to set the polarity, according the following table: 1 ON 2 ON 3 OFF 4 OFF +12V 1 OFF 2 OFF 3 ON 4 ON -12V ∞ AF line interface characteristics: inside I/O module, a 2 pole dip-switch allows to set the line type (2W or 4W) and the input impedance of eventual 4W line (600 ohm or high), according the following table: 1 ON  Zin (4W) = 600 ohm 1 OFF  Zin (4W) = High 2 ON  2W 2 OFF  4W  5.3.7 SELF-CALIBRATION PROCESS  During self-calibration process internal parameters of modulator and demodulators are tuned by generating a signal through the synthesizer of the transmitter, by automatically connecting its output to the input of the receiver and by analyzing the received signal. If a strong signal is received by the external antenna during self-calibration, it is possible that the process ends with errors (a corresponding “warning” alarm will be displayed on both frontal leds and monitor of PC for remote control). In this case the DSP will load from flash memory the previously saved  parameters without any problem for the transceiver. To obtain better results from self-calibration process, it is recommended to set the calibration frequency as near as possible to the transmitter frequency; if there is a range of allowed frequencies for transmission, it is recommended to set the centre of this range as the calibration frequency. 5.3.8 PPS SIGNAL For applications in simulcast networks where the source of synchronization is the PPS signal by GPS, if this signal is missing, the radio coverage of the areas which are reached by several repeaters with the same field strength, is not ensured.  Attention must be paid in choosing and placing the GPS antenna.

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