RBS 884 Pico (1900 MHz) Radio Head Installation 8.2.2 Patch Antenna Installation Preparations 1. Verify that the monopole antenna brackets are removed from the Radio Head (Step 4 on page 4-25 and Step 5 on page 4-26). Attaching the External Duplexer Cables 2. Remove two (2) patch antenna cables from the RH Patch Antenna Kit NTM/KRE 101 1608, and attach the cables to the external duplexers as shown in Figure 4-13 on page 4-31.
RBS 884 Pico (1900 MHz) Radio Head Installation Attaching the Patch Antenna Assembly Caution ! Mount the Radio Head on the wall prior to installing the patch antenna assembly to guard against possible damage to the patch antenna assembly. 4. Attach the patch antenna assembly to the Radio Head using the six screws provided with the antenna. See Figure 4-14 on page 4-32 for an illustration of the six screw locations. Mounting Screw Locations Patch Antenna Cables Patch Antenna Assembly Figure 4-14.
RBS 884 Pico (1900 MHz) Radio Head Installation Attaching Antenna Cables 5. Warning! Use care when handling the antenna connectors. Connect the patch antenna cables from the external duplexer to the press-fit connectors on each end of the patch antenna. See Figure 4-14 on page 4-32 for the location of the patch antenna cables. 8.
RBS 884 Pico (1900 MHz) Radio Head Installation • • T1 – 100-ohm CAT5, UTP with RJ-45 connectors – Ferrites (included in Small Parts Kit NTM 201 2887/1) – Power Cord (The United States (US) 110 Vac power cord is included in Radio Head Hardware Kit NTM 201 1581/1. For other markets, the power cords are customer supplied.
RBS 884 Pico (1900 MHz) Radio Head Installation Route CRI to Radio Head Cable 3. DANGER! Do not install T1/E1 PCM cable close to fluorescent light fixtures, transformers, or electric motors. For cabling practices, see “Commercial Building Standard for Telecommunications Pathways and Spaces, EIA/TIA-569.” If the CRI is remote and the line to the CRI is leased, install a Channel Service Unit (CSU) and route a T1/E1 PCM cable from the CSU to the first Radio Head (Radio Head 1).
RBS 884 Pico (1900 MHz) Radio Head Installation PCM Cable Quarter-Plug Connector 1> + 2> 4> + 5> - White/Blue Blue
RBS 884 Pico (1900 MHz) Radio Head Installation 7. Attach RJ-45 connectors to each end of a short length of 120-ohm cable as specified in Table 4-10 on page 4-37. Note: Pin 1 is on the extreme left of the connector cable opening as you look into the back of an RJ-45 connector with the latch down. Table 4-10.
RBS 884 Pico (1900 MHz) Radio Head Installation Primary PCM Interface Connector Port Rear View of Radio Head PCM Pulse Code Modulation Figure 4-17. Primary PCM Interface Connector Location on Radio Head 11. Attach a spring-type ferrite to the incoming T1/E1 PCM cable (Figure 4-18 on page 4-39). Position the ferrite as close to the Radio Head as possible. Note: 4-38 The 120-ohm cable (E1) ferrite is larger than the 100-ohm cable (T1) ferrite. Select the ferrite that fits snugly on the cable.
RBS 884 Pico (1900 MHz) Radio Head Installation Front Ferrite Back Figure 4-18. Attaching Cable Ferrites Applying Power to Radio Head 1 12. Warning! Do not drape excess cables on top of the heat sink fins. Use the cable tray on top of the mounting bracket. Connect the AC power cord to the AC receptacle on the Radio Head. Plug the other end of the AC power cord into the AC outlet. See Figure 4-19 on page 4-40 for the location of the AC power cord and AC receptacle.
RBS 884 Pico (1900 MHz) Radio Head Installation AC Receptacle AC Power Cord PCM Interface Connnector Ports Tamper-Resistant Seal RHI Customer Interface Front View Power/Fault LED AC LED PCM RHI Alternating Current Light Emitting Diode Pulse Code Modulation Radio Head Interface Figure 4-19. Radio Head AC Power Cord and AC Receptacle 13. Attach a spring-type ferrite to the AC power cord and position the ferrite as close to the Radio Head as possible. 14.
RBS 884 Pico (1900 MHz) Radio Head Installation Route the T1/E1 cable from Radio Head 1 to Radio Head 2. Refer to Figure 4-20 on page 4-41 for a diagram of the Radio Head to Radio Head cabling.
RBS 884 Pico (1900 MHz) Radio Head Installation 18. Attach a spring-type ferrite to the downlink T1/E1 PCM cable (Figure 4-18 on page 4-39). Position the ferrite as close to the Radio Head as possible. Note: The 120-ohm cable (E1) ferrite is larger than the 100-ohm cable (T1) ferrite. Select the ferrite that fits snugly on the cable. 19. Plug the other end of the first PCM cable into the primary (PRI) port on the top of Radio Head 2. 20. Apply power to Radio Head 2. Refer to Step 12 on page 4-39. 21.
RBS 884 Pico (1900 MHz) Radio Head Installation 28. Attach a spring-type ferrite to the AC power cord and position the ferrite as close to the Radio Head as possible. 29. Proceed to Part 3 RBS 884 Pico (1900 MHz) CRI Installation “Equipment Start-Up” before installing the Radio Head cover.
RBS 884 Pico (1900 MHz) Radio Head Installation 4-44 2/1531-AE/LZB 119 3834 Uae Rev PA6 2001-04-04
Part 5 Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 1 Introduction . . . . . . . . . . . . . . . . . . 1.1 Typographical Conventions . . . . . . . . 5-3 5-3 2 Safety Regulations . . . . . . . . . . . . . . . 2.1 Voltage Hazards . . . . . . . . . . . . . 2.2 Radio Frequency Radiation . . . . . . . . 5-4 5-4 5-5 3 Product Handling . . . . . . . . . . . . . . . . 3.1 Storage and Transport . . . . . . . . . . 3.2 Electrostatic Discharge (ESD) . . . . . . . 5-5 5-5 5-5 4 Tools . . . . .
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 8.1 8.2 8.3 8.4 9 10 5-2 Check Programs in Device Data Store: Pico 850/1900 MHz . . . . . . . . . . . . . . Self-Test of TRX and MBTRAC/MBTRC Devices: Pico 850/1900 MHz . . . . . . . Measurement of TRX Output Power: Pico 850/1900 MHz . . . . . . . . . . . . . . Deblocking of Devices: Pico 850/1900 MHz Example Integration: Pico (850 MHz) . . . . 9.1 Hardware Overview . . . . . . . . . . 9.2 Software and Hardware Assignments and Connections . . . .
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 1 Introduction This part provides descriptions and selected examples of the integration and test procedures for the RBS 884 Pico system hardware and software. The RBS 884 Pico system operates automatically after the initial configuration of hardware and software is performed. Note: 1.1 Both Pico 850 and Pico 1900 integration and test procedures are included in this part. Product designations have been provided to clarify the differences.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) • – I = Initiate Commands – R = Reset/Restore Commands ! An exclamation mark signifies the start of a comment. Note: When using TRAB2 with magazine number BFDH 511 501/3, the devices are MBTRAC, the switching network terminal is MBTRACS (i.e. ROF 137 7994/1 R1A) and the board is MBTRAB.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 2.2 • Turn off the power supply before working on the equipment. • Do not touch high voltage connections when installing or operating the equipment. • Keep one hand away from the equipment to reduce the possibility of current flowing through vital body organs. Radio Frequency Radiation DANGER! Radio frequency (RF) from an antenna may be a danger to health, causing severe burns. Turn off the transmitter when working with or near antennas.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 4 • Follow the instructions for handling sensitive electronic components and circuit boards to avoid component damage caused by ESD. • Use ESD protection equipment when working with components and boards. • When working with circuit boards, use an ESD wrist strap to avoid ESD damage. Connect the wrist strap to the slots on the bottom of the subrack.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Leased T1/E1 MSC XLINK CRI with XLI Radio Head XLINK XLINK XLINK XLINK Radio Head Radio Head Radio Head CRI E1 MSC T1 XLI XLINK Figure 5-1. Radio Head Control and Radio Interface 2.048 Mbps Transmission Link Mobile Switching Center 1.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MSC Leased T1/E1 c Leased T1/E1 c c CRI Radio Head Non-leased T1/E1 Non-leased T1/E1 c Figure 5-2. Radio Head Radio Head Leased T1/E1 c CRI E1 MSC T1 Radio Head Leased T1/E1 Non-leased T1/E1 Long Haul T1/E1 Long Haul T1/E1 Long Haul T1/E1 Long Haul T1/E1 Radio Head Radio Head Radio Head Long Haul T1/E1 Radio Radio c Head Head Radio Head Channel Service Unit Control and Radio Interface 2.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.1 Software Structure: Pico 850/1900 MHz Software configuration of the RBS 884 Pico Base Station is performed at the terminal in the MSC. All configuration information needed by the base station is transferred automatically from the MSC to the base station. The software configuration for the RBS Pico involves the following: 5.1.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Each function block is divided into functional units. Functional units can consist of hardware and software. For example, the MBTRX function block consists of software located in the telephone switch and the base station, in addition to hardware in the base station. 5.1.2 MBS Function Blocks The function blocks of the MBS can be divided into four major groups: 5.1.2.1 • Common function blocks operate in the central processor in the MSC.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) administers connection and disconnection of channel functions to and from channel equipment. 5.1.2.2 MBLOADF The Mobile Telephony Base Station Device Program Function Change Loading function block handles function change loading. MBLOADM The Mobile Telephony Base Station Device Program Maintenance Loading function block is a command function for the administration of maintenance loading.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBCEQ-MBRFTL and MBCEQ-MBCTC individuals. The output power, the attenuation, the channel number, and the capability data for all individuals are also stored in the function block. 5.1.2.3 MBCOC The Mobile Telephony Base Station Carrier Output Control function block administers the output power, attenuation, and channel number of the transceiver devices.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.1.2.4 MBLC/TC1 The Mobile Telephony Base Station Link Check function block sends and receives a 2–kHz tone over a speech circuit as a continuity check of the speech path during the call setup procedure. MBLT The Mobile Telephony Base Station Line Terminal function block handles the hardware interface for the line terminals to the base station.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5-14 RIDIPST The Radio Interface Digital Path Supervision and Test function block contains functions for connection or disconnection, setting or changing initial data, blocking or deblocking, fault supervision, and quality supervision of digital paths.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.1.3 RISPC The Radio Interface Semi Permanent Path Command function block contains functions for the administration of semipermanent paths and printout of semipermanent path data. Information about blocked and deblocked devices are received and processed. Paths are marked for forced release and disconnected in RITS at the loss of external synchronization reference or at the manual blocking of the EMRS.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) base station and RILT supervises the line terminals. RIDIPST supervises the digital paths in the base station. 5.2 Hardware Structure: 850 MHz/1900 MHz 5.2.1 RBS 884 Pico Common Equipment The Pico 850 MHz CRI can be equipped with up to 3 XLI boards to support a maximum of 11 Radio Heads and 11 EMRPSs. The Pico 1900 MHz CRI can be equipped with up to 4 ELI boards that support a maximum of 10 Radio Heads and 10 EMRPSs.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) the system for a total of 12 XLINK ports (1 XLINK port is not used). See Figure 5-1 on page 5-7 for an overview of the Pico 850 MHz configuration. 5.2.3 ELI Provisioning Guidelines– Pico 1900 MHz Each Pico 1900 MHz ELI provides a leased or non-leased T1/E1 connection between the CRI and the Radio Head.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.2.4.1 ETB24 Board: 850/1900 MHz The first ETB24 board (T1 connection) supports 24 time slots (0–23) with 1 time slot reserved for the Extension Module Group (EMG) control. The second ETB24 board (T1 connection) supports 24 time slots, and does not require the EMG control time slot. Using a second ETB24 board provides a total of 47 time slots between the two T1s that can be assigned to TRXs. 5.2.4.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.4 – Digital (K1/K0) – Analog (NI/N0) Pico 850 MHz • Voice Channel Device Routes (CI/CO) • Uncoded Transcoder Routes (I/O) – Digital (RO & RI) – Analog not applicable RBS to MSC Connection: Pico 850/1900 MHz A connection is used to relate two objects, for instance an MSC to the RBS 884 Pico system.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) RP Bus MSC CP RP=136 RP=137 RPM6A RP=160 RPs RP=168 RP=169 RPM6A STC2D Transcoder E1: EQM=MBLTET T1: EQM=ETMTS3 EM=0...7 CLC ETC DIPs Semipermanent SNT Connection SNT PCM LINE (1...24) T1 (0...31) E1 PSTN Group Switch GSS EMRPS 1 DEVSB Radio Heads XLI 1 . RS-232 V.24 EMs MBTRAC EQM=CLC-11 EM=1 MBLT86s (T1) MBLT861s (E1) CRIa EQM=MBTRAC EM=0 L1...L4 Radio Head 1...4 XLINK 1...
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) RP Bus MSC CP RP=136 RP=137 RPM6A RP=160 RPM6A STC2D RPs RP=168 RP=169 Transcoder E1: EQM=MBLTET T1: EQM=ETMTS3 EM=0...7 CLC ETC DIPs Semipermanent SNT Connection SNT PCM LINE (1...24) T1 (0...31) E1 PSTN Group Switch GSS DEVSB Radio Heads ELI 1 . . . EMRPS 1 RS-232 V.24 EMs MBTRAC EQM=CLC-11 EM=1 MBLT86s (T1) MBLT861s (E1) CRIa EQM=MBTRAC EM=0 Radio Head 1...
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) CLC CP CRI DEVCB DEVSB DIP ELI EM EMRP EMRPB EMRPS ETB ETC GSS MBLT MBLT86 MBLT861 MBTRAC MSC PCM PSTN RILT RITSW RP RPM RXLI SNT STR TLINK TRX XLI XLINK Control Link Central Processor Control and Radio Interface Device Control Bus Device Speech Bus Digital Path Enhanced Link Interface Extension Module Extension Module Regional Processor Extension Module Regional Processor Bus Extension Module Regional Processor with Device Speech Bus Access Exchang
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Terminal Remote (STR). The STR sends the control signal to the Extension Module Regional Processor Bus (EMRPB). • The command is now received by the EMRP, which processes and forwards the command to the appropriate device (for example the time switch). The speech signals sent between the RBS and MSC are: 5.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 3. Define the RP pair that controls the transcoder magazine (MBTRCs/MBTRC). 4. Assign software to the RP pair controlling the transcoders. Define EMs 5. Define the EM for ETCs. 6. Define the EMs for MBTRAC/MBTRC. 7. Define the EM that will control the CLC or path. Define SNT and Provide Allocation 8. Define Switching Network Terminal (SNT) for the ETC equipment to control the software/hardware connections through the Group Switch (GS).
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 16. Define the parameters needed to perform supervision of the DIP. 17. Define the CLC or path. Allocate STC-G as an Alternative for CLCs 18. Allocate STC-G as an alternative to inserting control signaling links.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Define MBTRAC/MBTRC Routes and Attach Devices 4. Define MBTRAC/MBTRC routes. 5. Attach the MBLT861/86/86N devices to signal channel routes. 6. Attach the MBLT861/86/86N devices to voice line routes. 7. Attach MBTRAC devices to MBTRAC routes (“Uncoded”). Bring Devices into Service 8. Bring signaling device into service. Note: 9. Use MBLT861 for E1 connection and MBLT86/MBLT86N for T1 connection. Bring the coded devices into service.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Connect the RILTs and the V24-TW 5.5.4 5. Connect the CRI RILTs to the equipment type (EQMTYPE). 6. Connect the V24-TW. Configure RBS Cell Structure: Pico 850/1900 MHz Define New Cells 1. Define new cells in the system. 2. Define the new cell identification data. Define Area and Data 3. Define the service area. 4. Define the analog control channel data. 5. Define the digital control channel data. 6.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Connect the MBTRAC/MBTRC Devices 13. Connect the MBTRAC/MBTRC devices to TRXs, which are digital. Note: 14. The MBLTI and the remaining integration work process, use the “true” address for the MBTRXs. The “true” address is the generic MBTRX address divided by four. Connect the MBLT861/86/86N devices to TRXs which are analog. Set Channel Capability, Number, and Output Power 15. Set the channel capability for the MBCEQ. 16.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 6. Define return DIP, CRI. 7. Deblock return DIP, CRI. Deblock the RILTs 5.5.6 8. Deblock RILTs/RILT1s, CRI. 9. RILT = T1 and RILT1 = E1 Make Semipermanent Connections: Pico 850/1900 MHz Make Semipermanent Connections in the Time Switch (TSW) or RITSW 1. 2. 5.5.7 Make the following semipermanent connections in the TSW: • CRI • XLI/ELI, CRI • XLI/ELI, CRI • XLI/ELI, CRI Deblock the EM for transcoder.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.5.8 Self Test RBS Devices: Pico 850/1900 MHz Check Programs and Load TRXs 1. Check programs in device data store. 2. Load each TRX device to ensure that the HW generation information is transferred to the MSC. Self-Test 3. 5.5.9 Self-test the TRX and MBTRAC/MBTRC coded devices. Link Channel Equipment: Pico 850/1900 MHz Connect the Channel Equipment and Define Backup Channels 1. Connect the channel equipment to the CFU. 2.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 6. Set blocking supervision for voice line routes. 7. Set blocking supervision for MBTRAC/MBTRC routes. 8. Set disturbance supervision for voice line routes. 9. Set disturbance supervision for MBTRAC/MBTRC routes. 10. Set seizure quality supervision for voice line routes. 11. Set seizure quality supervision for MBTRAC/MBTRC routes. 5.5.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.6 Background Information: Pico 850/1900 MHz 5.6.1 Global Number Plan: Pico 850/1900 MHz Ericsson recommends that addresses be reserved for maximum configuration at each site. Limited address space can cause problems for large systems. The following limitations are valid per MSC: 5.6.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) RBS 884 Pico Network Data PREPARED BY: REV: SITE NAME: DATE: DOCUMENT NUMBER: CELL: EMG: (CLC) MBLT: 1 STC RP: MTRAC RPs: EM # RADIO HEAD. 6 7 2 CLC: SLOT CEQ 8 9 :1 ROUTE: 5 Global Address CHANNEL FUNCTION UNIT 10 CO DIPR: 3 ROUTE: Voice Paths (RILT) IN OUT 11 DIP: CI MBLT 12 4 Signal Path IN OUT CODED UNCODED MBTRAC MBTRAC 13 :2 :3 :4 :5 :6 :7 :8 Figure 5-6.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 7. Radio Head identification number for each TRX Note: The Radio Head identification number is accessed through the rotary switch on the RXLI board (Pico 850 MHz) or through the alphanumeric display on the Radio Head customer interface (Pico 1900 MHz) depending on the Radio Head product number. 8. TRX position 9. Global address of the Channel Equipment (CEQ) 10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) – Analog Gateway Cell with Two Radio Heads and Two EMRPSs – A Dual Mode Cell with Two Radio Heads and Two EMRPSs The maximum cell radius for all cell types is approximately 60 m (200 ft). 5.6.3.1 Pico 850/1900 MHz Configurations A Digital-Only Cell with One Radio Head and One EMRPS: Pico 850/1900 MHz A digital-only cell with one Radio Head provides a Digital Control Channel (DCCH) and Digital Voice Channels (DVC).
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) handoffs from a cell providing DVCs. The cell does not provide a locating function or presence verification for AVC. To support handoffs from a mobile using a DVC in an external cell (or from another indoor cell), the digital-only cell needs the mobile presence verification function. This requires the configuration of a TRX as a Mobile Location Verification (MVER) module in one of the Radio Heads.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) an analog Mobile Telephone Locating (MLOC) device. The MLOC device requires a TRX configured as an Signal Strength Receiver (SR). This cell also provides an AVC that is used for mobile station presence verification. An analog gateway cell provides very low traffic capacity (two analog voice channels). This cell is only recommended for use when analog cellular coverage must be provided and handoffs from an analog cell are required.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-7. Pico 850 MHz Analog-Only Two Radio Head Configuration (Analog Gateway) with Radio Head 1 TRX1 Channel Function MCC TRX2 Channel Function MVC TRX3 Channel Function MVC1 TRX4 Channel Function MLOC Time Slots Required 2 Total analog voice channels: 2 1 For maximum backup capability the control channel can be assigned to a voice channel during setup.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-9. Pico 850 MHz Analog-Only Two Radio Head Configuration (Analog Gateway) with Radio Head 1 and EMRPS 1 TRX1 Channel Function MCC TRX2 Channel Function MVC TRX3 Channel Function MVC1 TRX4 Channel Function MVC Time Slots Required 3 Total analog voice channels: 3 1 For maximum backup capability the control channel can be assigned to a voice channel during setup.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-11. Pico 850 MHz Dual Mode Radio Head Configuration with Radio Head 1 (Analog and Digital) and EMRPS 1 TRX1 Channel Function MDCC MDVC (2) TRX2 Channel Function MVC TRX3 Channel Function MDVC (3)1 TRX4 Channel Function MVER Time Slots Required 3 Total digital voice channels: 5 Total analog voice channels: 1 1 For maximum backup capability the control channel can be assigned to a voice channel during setup.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 1 EMRP EMRPS ETB STR XLI Figure 5-7. 5.6.4.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.6.4.3 Eleven EMRPS: Pico 850 MHz An 11-EMRPS Pico 850 MHz configuration uses 3 XLI boards. There is a maximum of 11 EMRPS slots in the CRI subrack. This configuration requires 3 XLI boards that provide link access for 11 Radio Heads. This configuration also requires 2 ETB24 or 2 ETB32 boards if the full traffic capacity of the cells is used. The CRI subrack layout for this configuration is shown in Figure 5-9 on page 5-42.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 1 ELI EMRP EMRPS ETB STR 2 S E T M R R P E T B 2 4 / 3 2 E E E E T M M M B R R R 2 P P P 4 S S S / 1 2 3 3 2 3 5 6 4 7 8 E L I 1 R I T S W 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 Enhanced Link Interface Extension Module Regional Processor EMRP with Device Speech Bus Access Exchange Terminal Board Signaling Terminal Regional Figure 5-10. CRI with a 3-EMRPS Pico1900 MHz Configuration 5.6.4.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.6.4.6 Ten EMRPS: Pico 1900 MHz A 10-EMRPS Pico 1900 MHz configuration uses 4 ELI boards. There is a maximum of 10 EMRPS slots in the CRI subrack. This configuration requires 4 ELI boards that provide link access for 10 Radio Heads. This configuration also requires 2 ETB24 or 2 ETB32 boards if the full traffic capacity of the cells is used. The CRI subrack layout for this configuration is shown in Figure 5-12 on page 5-44.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-13.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.7.1.2 Load Distribution Examples: Pico 850 MHz This section shows examples of load distribution for an RBS 884 Pico 850 MHz. Examples of load distribution for a CRI are shown in the following figures: • Table 5-15 on page 5-46 is an example of a TIA/EIA 553 compatible cell configuration with 2 T1 links or 1 E1 PCM link, 4 analog cells, 8 Radio Heads (32 TRXs), and 8 EMRPSs.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-16.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-17.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-18.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-19. Pico 850 MHz IS54B Compatible with 5 Dual-Mode Cells and 11 Radio Heads, Example (Continued) CRI Part Cell 5 5.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-21. Pico 1900 MHz EMRPS Load from Different CFUs CFU 5.8.1.1 EMRPS Load MDCC High MDVC Medium MVER Medium Maximum Configuration: Pico 1900 MHz The Pico 1900 MHz CRI can support a maximum of 10 Radio Heads with each containing 2 dual TRXs for a total of 40 TRXs. The CRI can contain a maximum of 10 EMRPSs, 4 ELIs, and 2 ETBs.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-22.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-23. Pico 1900 MHz with 1 T1 (or 1 E1) Link, 7 Digital Cells and 7 Radio Heads, Example 2 (Continued) CRI Part EM RILT EMRPS TRX1 TRX2 TRX3 TRX4 TS ELI Cell 5 RH5 05 06 5 DCCH DVC (2) DVC (3) VER 2 2 Cell 6 RH6 06 07 6 DCCH DVC (2) DVC (3) VER 2 2 Cell 7 RH7 07 08 7 DCCH DVC (2) DVC (3) VER 2 3 5.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.9.1 Addresses in Semipermanent Connections: Pico 850 MHz 5.9.1.1 Remote Interface Line Terminal (RILT) Addresses: Pico 850 MHz The Remote Interface Line Terminal (RILT) addresses enable the MSC to control the cross-connection of each time slot on an incoming PCM link to the appropriate destination device in the CRI. 5.9.1.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) • Speech Path • 01, 03, 05, 07, 09, 11, 13, 15, 17, 19, 21, 23, 25, 27, 29, and 31 The ETB for T1 (24 channels) has 24 time slots: 01 to 24, where 09 is used for CLC. The ETB for E1 (32 channels) has 32 time slots: 00 to 31, where 00 is used for frame synchronization and 16 is used for CLC. For additional information about T1 and E1 PCM links, see Section 5.11.1 on page 5-62. 5.9.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.9.2.4 Examples: Pico 850 MHz Pico 850 MHz Example 1: Semipermanent Connection of the Analog Control Channel (ACC) (TRX1Aa) Located in Radio Head 1, Cell A Device EMRPS-1 with RILT address RILT-02 and channel number 00 will be semipermanently connected with device XLI-1 with RILT address RILT-10 and channel number 16. The name of this semipermanent connection will be ‘TRX1Aa –CONTROL'.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) DBTSC: TAB=AXEPARS, SETNAME=CMS88MBSF, NAME=TRAPOOL, VALUE=1; DBTRE: COM; SAAII: BLOCK=MBTPH,SAE=700,NI=100; BLODI: DEV=MBTRAC-209&&-211; EXSCE: NAME=R4M1–MBCEQ776,DEV=MBTRAC-208; BLODI: DEV=MDVC-576&-577; BLODI: DEV=MDCC-49; BLODI: DEV=MBTRX-776; MBEQE: DEV=MDVC-576&&-577; MBLTE: CEQ=MBCEQ-776; EXDRE: DEV=MBTRAC-210&&-211; EXROI: R=TBPOOLO&TBPOOLI, DETY=MBTRAC,FNC=1; EXDRI: DEV=MBTRAC-209&&-211,R=TBPOOLO&TBPOOLI; MBPUI: DEV=MBTRAC-208; MPBPSI: LIM1=
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.10 Semipermanent Paths: Pico 1900 MHz The Pico 1900 MHz EMRPS Load Distribution is used as input for establishment of semipermanent paths in the Pico 1900 MHz. Another input is the available time slots on the PCM links (Table 5-25 on page 5-58 ). Table 5-25. Pico 1900 MHz PCM Link Data PCM Link Type Capacity T1 Channels Total Traffic Voice Channels Control Signaling Link (CLC) Frame Synchronization 1.544 Mbit/s 24 23 ts-9 - E1 2.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.10.1.2 Global RILT Addresses: Pico 1900 MHz The following Global RILT addresses are used for a CRI equipped with six Radio Heads: • 00: ETB1 (ETB Primary) • 02–07: EMRPS 1–6 • 10–11: ELI 1 and ELI 2 The following Global RILT addresses are used for a CRI equipped with ten Radio Heads (maximum configuration): • 00: ETB1 (ETB Primary) • 01: ETB2 (ETB Secondary) • 02–11: EMRPS 1–10 • 12–15: ELI 1–4 5.10.1.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.10.2.2 Parameters: Pico 1900 MHz TSLOT1=tslot1 A timeslot in a device. This is the first timeslot to be connected. TSLOT2=tslot2 A timeslot in a device. This is the second timeslot to be connected to TSLOT1. NAME=name A name for a semipermanent path. It should be a symbolic name consisting of 1–15 characters. 5.10.2.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) and channel number 25. The name for this semipermanent connection will be ‘TRX5A-SPEECH.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) BLODE: DEV=MDVC-576&&-577; MTBCI: DEV=MDCC-49, CEQ=MBCEQ-800; 5.11 EMRP Bus and PCM Links: Pico 850/1900 MHz 5.11.1 T1 and E1 PCM Links: Pico 850/1900 MHz The RBS 884 Pico system can use the following PCM links: • T1 PCM Link: The numbering for the speech time slots on a T1 PCM link starts at 01 and ends with 24 for a total of 24 time slots.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5.11.3 Allocation of EMRP Bus: Pico 850/1900 MHz From 1 to 11 EMRPSs can be connected to the Pico 850 MHz EMRP Bus. From 1 to 10 EMRPSs can be connected to the Pico 1900 MHz EMRP Bus. At the last EMRP on the bus cable, there is a bus terminating plug. 5.11.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) RBS 884 Pico (850 MHz) CRI EMRP address plugs RNV 99103/ EMRP Bus-A DC/DC STR STR EMRP ETB ETB EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS XLI (A1) /1 /2 /3 /4 /5 /6 /7 /8 /9 /10 /11 /12 (A2) (A3) (A4) Position A3 and A4 for the EMRP Bus+A (B1) (B2) T T (B3) (B4) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 PCM Link 1, position B3 for 100/120 ohm (position B3 for 75 ohm) DC/DC ELI EM EMRP EMRPS ETB PCM
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) RBS 884 Pico (1900 MHz) CRI EMRP address plugs RNV 99103/ EMRP Bus-A DC/DC STR STR EMRP ETB ETB EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS EMRPS ELII (A1) /1 /2 /3 /4 /5 /6 /7 /8 /9 (A2) /10 /11 (A3) (A4) Position A3 and A4 for the EMRP Bus+A (B1) (B2) T (B3) (B4) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 PCM Link 1, position B3 for 100/120 ohm (position B3 for 75 ohm) DC/DC ELI EM EMRP EMRPS ETB PCM RILT RITS
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 6 RBS 884 Pico CRI Test Procedure: Pico 850/1900 MHz 6.1 LED Indicators Several of the circuit boards in the CRI cabinet have Light Emitting Diodes (LEDs) for diagnostic purposes. Part 5, Operations and Maintenance describes the function of the LED types. 6.2 Test Procedure The CRI automatically performs a self-test when the system is powered on. Once the CRI is powered on, all LEDs light briefly for testing purposes.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) functions. The Radio Head Power/Fault LED flashes red at a 3-Hz rate during the self-test. When the self-test is complete, the LED is green if the self-test passed. A self-test failure causes the Radio Head Power/Fault LED to light a steady red. See Part 6, Troubleshooting for additional information on how to troubleshoot the Radio Head.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MOBILE TELEPHONY BASE STATION DEVICE PROGRAM INFORMATION DEV VER REV FUNC HWGEN CSUM MBTRX-48 40 20 VC CC SR DVC VER DCCH 5 5007 MBTRX-49 40 20 VC CC SR DVC VER DCCH 5 5007 FCODE Figure 5-15. Result Printout Example from Command MBDPP Table 5-26. MBDPP Printout Parameters 5-68 csum Checksum func Channel functions supported by the program.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 2. Check that the software version and the revision state reported corresponds to the information received from Project or MSC Manager. Note: 3. Check the printout and record the result in the Test Record. Note: 8.2 If an update is needed, check first if the new software version is available in the MSC Data Store (command MBDSP). If not, load the new software to the MSC, and then to the RBS.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MOBILE TELEPHONY BASE STATION DEVICE SELFTEST RESULT DEV MBTRX-3 END EMG BE EM 1 BLOCKRES 0 RESULT 0 FCODE 0 Figure 5-16. Result Printout Example from Command MBSDI Table 5-27. MBSDI Printout Parameters BLOCKRES Blocking reason, latest reason for automatic blocking of the device. The meaning of the value is depending on the type of device and is found in the Base Station Operation and Maintenance Documentation. 5-70 RESULT Result of test.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 8.3 Measurement of TRX Output Power: Pico 850/1900 MHz Prerequisites 1. Values must be assigned to MAXPOWER and TXatt/TXgain: MBECC The first digital example applies only to the Pico 1900 MHz product.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) TRX Maxpower Combiner Power TXATT TRX TXATT Transceiver Transceiver Attenuation/Gain Figure 5-17. Relationship between MAXPOWER, TXATT/TXGAIN and POWER. 2. The absolute output power in the antenna feeder must be set: MTCTC Example 5-6: MTCTC:DEV=MCC-0, CHNR=333, POWER=110, FIT=EF; This command sets the absolute output power in the antenna feeder to 11.0 dBm. Note: 5-72 POWER equals MAXPOWER-TXatt or +TXgain.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Check the hardware malfunction log 3. Check the hardware malfunction log for the EMG. The MBMLP command prints the Mobile Telephony Base Station Device Hardware Malfunction Log. MBMLP Example 5-7: MBMLP:emg=E001; 8.4 Deblocking of Devices: Pico 850/1900 MHz Deblock Devices 1. Deblock MBLT86/861/86N for analog devices, MBTRACS/MBTRCS, TRXs and channel function devices.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Check the hardware malfunction log 2. Check the hardware malfunction log for the EMGs being brought into operation. The MBMLP command prints the Mobile Telephony Base Station Device Hardware Malfunction Log. MBMLP Example 5-10: MBMLP:emg=E001; Set Supervision 3. Set blocking supervision for voice line routes: BLURC Example 5-11: BLURC:R=ANVALO, ACL=A2, LVB=2&3; 4.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5. Set disturbance supervision for voice line routes: DUDAC Example 5-13: DUDAC:R=KI1ALO, ADL=5, ACL=A2; 6. Set disturbance supervision for MBTRAC/MBTRC routes: DUDAC Example 5-14: DUDAC:R=MBTRACO&MBTRACI, ADL=5, ACL=A2; DUDAC:R=MBTRCO&MBTRCI, ADL=5, ACL=A2; 7. Set seizure quality supervision for voice line routes: SEQAC Example 5-15: SEQAC:R=KI1ALO&KI1ALI, ACL=A3,QUOS=40,QUOB=85; 8.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 9 Example Integration: Pico (850 MHz) This section contains an example of how to integrate an RBS 884 Pico system and an MSC. The RBS 884 Pico 850 MHz system in this example uses XLI boards with a T1 PCM link (24 channels or time slots). 9.1 Hardware Overview The RBS 884 Pico system is described in Part 2, System Description.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) G R O U P S W EXSCI I T C H MBLT86-24 Transcoder MBTRAC-11 MBTRAC-10 MBTRAC-9 MBTRAC-8 MBLTI MBEQI UNIT 2 UNIT 2 UNIT 1 MBCEQ- UNIT 1 11 UNIT 0 UNIT 0 MDVC-7 MDVC-6 MDVC-5 DTDII CRI E T B 1 RITSW (17) (#) CRI ELI ETB EMRPS MBCEQ MBLT MBTRX MDVC RILT RITSW TRX XLI Radio Head RISPI RIETI (00) Note: T R X 1 E M R P S 2 X L I (03) (13) Hardware device MBTRX-11 (represented by channel equipment MBCEQ-11), is shown to be configured as 3 M
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBEQI MBCEQ-0 T R X MCC-0 Radio Head Note: Hardware device MBTRX-0, (represented by channel equipment MBCEQ-0), is configured as an Mobile Analog Control Channel (MCC) MBCEQ MBTRX MCC TRX Mobile Telephony Base Station Channel Equipment Mobile Telephony Base Station Transceiver Mobile Analog Control Channel Radio Transceiver AXE Command Figure 5-19.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) G R O U P S W I T C H Transcoder MBLTI MBEQI UNIT 2 UNIT 1 MBCEQ64 UNIT 0 MBTRAC-23 MBTRAC-22 MBTRAC-21 UNIT 2 MDVC-16 UNIT 1 MDVC-15 UNIT 0 MDVC-14 MBTRAC-20 EXSCI MBLT861-3 DTDII CRI E T B 1 (00) Note: (#) CRI ELI ETB EMRPS MBCEQ MBLT MBTRX MDVC RILT RITSW TRX XLI RITSW (17) T R X 2 Radio Head RISPI RIETI E M R P S 2 X L I (03) (13) Hardware device MBTRX-64 (represented by channel equipment MBCEQ-64), is shown to be confi
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) G R O U P S W I T C H Transcoder MBEQI MBLTI MBTRAC-3 UNIT 2 UNIT 1 MBCEQ8 UNIT 0 MBTRAC-2 MBTRAC-1 UNIT 2 MDVC-1 UNIT 1 MDVC-0 UNIT 0 MDCC-0 MBTRAC-0 EXSCI MBLT86-0 DTDII CRI E T B 1 RITSW (17) (00) Note: (#) CRI ELI ETB EMRPS MBCEQ MBLT MBTRX MDVC RILT RITSW TRX XLI T R X Radio Head 3 RISPI RIETI E M R P S 2 X L I (00) (13) Hardware device MBTRX-8, (represented by channel equipment MBCEQ-8, is shown to be configured as
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBLTI MBCEQ80 MBLT86-5 MBEQI MVC-2 DTDII CRI E T B 1 (00) Note: (#) CRI ELI ETB EMRPS MBCEQ MBLT MBTRX MDVC RILT RITSW TRX XLI RITSW (17) T R X 4 Radio Head RISPI RIETI E M R P S 2 X L I (03) (13) Hardware device MBTRX-80, (represented by channel equipment MBCEQ-80), is shown to be configured as 1 Mobile Analog Voice Channel (MVC).
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBEQI MBCEQ-1 Radio Head Note: MBCEQ MBTRX MLOC TRX MLOC-0 T R X Hardware device MBTRX-1, (represented by channel equipment MBCEQ-1), is configured as a Mobile Locating (MLOC) device. AXE Command Mobile Telephony Base Station Channel Equipment Mobile Telephony Base Station Transceiver Mobile Locating Radio Transceiver Figure 5-23.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBEQI MBCEQ-1 Radio Head Note: MBCEQ MBTRX MVER TRX MVER-0 T R X Hardware device MBTRX-1, (represented by channel equipment MBCEQ-1), is configured as a Mobile Verification (MVER) device . AXE Command Mobile Telephony Base Station Channel Equipment Mobile Telephony Base Station Transceiver Mobile Verification Radio Transceiver Figure 5-24. Software and Hardware Assignments for a TRX in a Radio Head, Configured as a MVER 9.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) • EM 9, EM 10, EM 11, XLI 1, XLI 2, and XLI 3 are shown in Table 5-30 on page 5-86. Note: The GNP and semipermanent paths for a CRI with ELI boards is the same as the those in Table 5-30 on page 5-86 with the exception of the ELI Control Path and Speech Path time slots. See Section 5.10.1.3 on page 5-59. • Control, EM control, Speech, and TSW are shown in Table 5-31 on page 5-87. • Radio Head 1 is shown in Table 5-32 on page 5-88.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-29.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-30.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-31.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-32. GNP RBS Devices for Radio Head 1 (Analog with XLI) Radio Head 1 MBTRX 3584 3585 3586 3587 MCC MLOC 224 MVC Pos.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-33. GNP for Radio Head 2 Radio Head 2 MBTRX 3592 3593 3594 3595 MCC MLOC 225 MVC Pos.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-34. GNP for Radio Head 3 Radio Head 3 MBTRX 3600 3601 3602 3603 MCC MLOC Pos.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-35. GNP for Radio Head 4 Radio Head 4 MBTRX 3608 3609 3310 3611 MCC MLOC 227 MVC Pos.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-36. GNP for Radio Head 5 Radio Head 5 MBTRX 3616 3617 3618 3619 MCC MLOC Pos.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-37. GNP for Radio Head 6 Radio Head 6 MBTRX 3624 MCC 229 3625 3626 MLOC 229 MVC Pos.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) • Support for digital and analog devices • Six Radio Heads • T1 PCM Link The following is an overview of the integration procedure. Note: The commands shown in this DT are entered as single-line entries, although the commands in this manual may be split on more than one line. Descriptive comments are included in the example DT.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-39. Integration Procedures for the Configuration of Cell and EMG Integration Procedure See Section Define New Cell in the System Section 9.4.2.1 on page 5-107 Define the New Cell SID Section 9.4.2.2 on page 5-107 Define Analog Control Channel Data Section 9.4.2.3 on page 5-108 Define Digital Control Channel Data Section 9.4.2.4 on page 5-108 Block EMs Section 9.4.2.5 on page 5-110 Block RPs Section 9.4.2.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-40. Integration Procedure to Assign Software Units to EMs (Continued) Integration Procedure See Section Define Equipment Positions (Optional) Section 9.4.3.5 on page 5-113 Define Remote Interface Equipment Types Section 9.4.3.6 on page 5-115 Define the Reverse Digital Path "DIP" Section 9.4.3.7 on page 5-116 Change Quality Supervision for Digital Path Section 9.4.3.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-42 on page 5-97 lists the integration procedures for deblocking and activating DIP, CLC, EMG, and RILTs. Table 5-42. Integration Procedures for Deblocking and Activating DIP, CLC, EMG, and RILTs Integration Procedure See Section Deblock STC Section 9.4.5.1 on page 5-129 Deblock STC EM Section 9.4.5.2 on page 5-129 Deblock the Digital Path "DIP" Section 9.4.5.3 on page 5-129 Deblock Control Signaling Link Section 9.4.5.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-44. Integration Procedures to Bring the Base Station Devices into Service Integration Procedure See Section Initiate Pre-Post Service for MBLT86 Devices Section 9.4.7.1 on page 5-134 Bring TRX’s into Service Section 9.4.7.2 on page 5-135 Table 5-45 on page 5-98 lists the integration procedures for the semipermanent connections of MBTRAC/MBTRC to MBLT/MBLT86N using the group switch. Table 5-45.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-47. Integration Procedures for the Deblocking/Checking of RBS Equipment Integration Procedure See Section Deblock/Check the MBTRAB/MBTRB Devices Section 9.4.10.1 on page 5-144 Measure the Output Section 9.4.10.2 on page 5-144 Deblock TW Port Section 9.4.10.3 on page 5-144 Deblock MBLT86 Devices Section 9.4.10.4 on page 5-144 Deblock Uncoded MBTRAC/MBTRC Devices Section 9.4.10.5 on page 5-145 Deblock MBTRX Devices Section 9.4.10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) Table 5-48. Integration Procedures for the Assignment of Supervision to Routes Integration Procedure See Section Set Disturbance Supervision for Analog Voice Line Routes Section 9.4.11.1 on page 5-154 Set Disturbance Supervision for MBTRAC/MBTRC Routes Section 9.4.11.2 on page 5-154 Set Seizure Quality Supervision for Analog Voice Line Routes Section 9.4.11.3 on page 5-155 Set Seizure Quality Supervision for MBTRAC/MBTRC Routes Section 9.4.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell B ! EXROI:R=P4P1BNO & P4P1BNI, DETY=MBLT86N, FNC=3; EXRBC:R=P4P1BNO, R2=TC1; EXRBC:R=P4P1BNI, R2=TC1, RO=0; ! Cell C ! ! No Analog Voice in Cell C ! ! Cell D ! EXROI:R=P4P1DNO & P4P1DNI, DETY=MBLT86N, FNC=3; EXRBC:R=P4P1DNO, R2=TC1; EXRBC:R=P4P1DNI, R2=TC1,RO=0; ! Cell E ! ! No Analog Voice in Cell E ! ! Cell F ! EXROI:R=P4P1FNO & P4P1FNI, DETY=MBLT86N, FNC=3; EXRBC:R=P4P1FNO, R2=TC1; EXRBC:R=P4P1FNI,R2=TC1, RO=0; 9.4.1.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell B ! EXROI:R=P4P1BDO & P4P1BDI, DETY=MBLT86N, FNC=3; ! Cell C ! EXROI:R=P4P1CDO & P4P1CDI, DETY=MBLT86N, FNC=3; ! Cell D ! EXROI:R=P4P1DDO & P4P1DDI, DETY=MBLT86N, FNC=3; ! Cell E ! EXROI:R=P4P1EDO & P4P1EDI, DETY=MBLT86N, FNC=3; ! Cell F ! ! No Digital Voice in Cell F ! 9.4.1.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) EXROI:R=P4P1DCO & P4P1DCI, DETY=MRCS, FNC=3; ! Cell E ! EXROI:R=P4P1ECO & P4P1ECI, DETY=MRCS, FNC=3; ! Cell F ! EXROI:R=P4P1FCO & P4P1FCI, DETY=MRCS, FNC=3; 9.4.1.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell D ! EXROI:R=P4P1DMO & P4P1DMI, DETY=MBTRAC, FNC=1; or EXROI:R=P4P1DMO & P4P1DMI, DETY=MBTRC, FNC=1; EXRBC:R=P4P1DMI, RO=0; ! Cell E ! EXROI:R=P4P1EMO & P4P1EMI, DETY=MBTRAC, FNC=1; or EXROI:R=P4P1EMO & P4P1EMI, DETY=MBTRC, FNC=1; EXRBC:R=P4P1EMI,RO=0; ! Cell F ! ! No Digital Voice in Cell F ! 9.4.1.6 Define MBTRC Routes (Pooled) EXROI:R=TBPOOLO & TBPOOLI, DETY=MBTRAC, FNC=1; 9.4.1.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) EXDRI:R=P4P1BNO & P4P1BNI, DEV=MBLT86N-1252; ! Cell C ! ! No Analog Voice in Cell C ! ! Cell D ! EXDRI:R=P4P1DNO & P4P1DNI, DEV=MBLT86N-1259; ! Cell E ! ! No Analog Voice in Cell E ! ! Cell F ! EXDRI:R=P4P1FNO & P4P1FNI, DEV=MBLT86N-1265; 9.4.1.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) EXDRI:R=P4P1DKO & P4P1DKI, DEV=MBLT86N-1258; ! Cell E ! EXDRI:R=P4P1EKO & P4P1EKI, DEV=MBLT86N-1261&&-1263; ! Cell F ! ! No Digital Voice in Cell F ! 9.4.1.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) EXDRI:R=P4P1DMO & P4P1DMI, DEV=MBTRAC-294&-295; or EXDRI:R=P4P1DMO & P4P1DMI, DEV=MBTRC-294&-295; ! Cell E ! EXDRI:R=P4P1EMO & P4P1EMI, DEV=MBTRAC-306&-307&-309&&-311&-313&&-315; or EXDRI:R=P4P1EMO & P4P1EMI, DEV=MBTRC-306&-307&-309&&-311&-313&&-315; ! Cell F ! ! No Digital Voice in Cell F ! 9.4.2 Configuration of Cell and EMG 9.4.2.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MTSIC:CELL=P4P1D, SID=157; MTSIC:CELL=P4P1E, SID=157; MTSIC:CELL=P4P1F, SID=157; 9.4.2.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MTDDC:CELL=P4P1A, BURST=NORMAL, HYREG=3, PLC=3, SSACC=14, SSREG=14; MTDDC:CELL=P4P1A, SSDIL=10, SSDIH=30, SSSEL=30; ! Cell B ! MTDDC:CELL=P4P1B, BURST=NORMAL, HYREG=3, PLC=3, SSACC=14, SSREG=14; MTDDC:CELL=P4P1B, SSDIL=10, SSDIH=30, SSSEL=30; ! Cell C ! MTDDC:CELL=P4P1C, BURST=NORMAL, HYREG=3, PLC=3, SSACC=14, SSREG=14; MTDDC:CELL=P4P1C, SSDIL=10, SSDIH=30, SSSEL=30; ! Cell D ! MTDDC:CELL=P4P1D, BURST=NORMAL, HYREG=3, PLC=3, SSACC=14, SSREG=14; MT
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 9.4.2.5 Block EMs ! MAY BE NECESSARY IF EM HAS BEEN DEBLOCKED FOR TESTING ! BLEMI:RP=134, EM=1; 9.4.2.6 Block RPs ! MAY BE NECESSARY IF RP HAS BEEN DEBLOCKED FOR TESTING ! BLRPI:RP=134; 9.4.2.7 Bring MBLT86 CLC Devices into Service EXDAI:DEV=MBLT86-1256; 9.4.2.8 Insert Control Signaling Link EXCLI:DEV=MBLT86-8, EQM=CLC-14; or if STC-G is used EXCPI:EMG=00AA, DEVA=MBLT86N-08; 9.4.2.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 9.4.2.12 Define EMs and Processor Control EXEPI:EMG=P4P1, EM=0, CONTROL=SINGLE, TYPE=EMRP3; EXEPI:EMG=P4P1, EM=1, TYPE=EMRPD1; EXEPI:EMG=P4P1, EM=2, TYPE=EMRPD1; EXEPI:EMG=P4P1, EM=3, TYPE=EMRPD1; EXEPI:EMG=P4P1, EM=4, TYPE=EMRPD1; EXEPI:EMG=P4P1, EM=5, TYPE=EMRPD1; EXEPI:EMG=P4P1, EM=6, TYPE=EMRPD1; EXEPI:EMG=P4P1, EM=7, TYPE=EMRPD1; EXEPI:EMG=P4P1, EM=8, TYPE=EMRPD1; 9.4.3 Assign Software Units to EMs 9.4.3.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) EXEUI:EMG=P4P1, EM=0, SUID="1885/CAA 117 2403/525J R1A03"; !RILTR! EXEUI:EMG=P4P1, EM=8, SUID="9000/CAA 140 215/1K R2B06"; !TWR! EXEUI:EMG=P4P1, EM=1&&8, SUID="9000/CAA 140 027 R3A02"; !ESEXR! EXEUI:EMG=P4P1, EM=1&&8, SUID="9000/CAA 140 018 R2A01"; !EMGFDR! EXEUI:EMG=P4P1, EM=1&&8, SUID="9000/CAA 140 206/842B R1L02"; !MBTRXR! 9.4.3.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) EXEEI:EMG=P4P1, EM=6, EQM=MBTRX-14496&&-14527; !MBCEQ 3624 && 3631 ! EXEEI:EMG=P4P1, EM=7, EQM=MBTRX-14528&&-14559; !MBCEQ 3632 && 3639 ! EXEEI:EMG=P4P1, EM=8, EQM=TW-56; EXEEI:EMG=P4P1, EM=8, EQM=MBTRX-14560&&-14591; !MBCEQ 3640 && 3647 ! 9.4.3.4 Insert Typewriter Terminal (TW) Equipment IOIOI:IO=TW-56, DET; IOFOC:IO=TW-56, FORMFEED=NO; 9.4.3.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) EXPOI:EMG=E001, EM=7, POS=EMG-P4P1&CRI-A&POSITION-13; EXPOI:EMG=E001, EM=8, POS=EMG-P4P1&CRI-A&POSITION-14; ! RH 1 ! EXPOI:DEV=MBTRX-3484, POS=EMG-P4P1&RH-1&POSITION-1; EXPOI:DEV=MBTRX-3485, POS=EMG-P4P1&RH-1&POSITION-2; EXPOI:DEV=MBTRX-3486, POS=EMG-P4P1&RH-1&POSITION-3; EXPOI:DEV=MBTRX-3487, POS=EMG-P4P1&RH-1&POSITION-4; ! RH 2 ! EXPOI:DEV=MBTRX-3592, POS=EMG-P4P1&RH-2&POSITION-1; EXPOI:DEV=MBTRX-3593, POS=EMG-P4P1&RH-2&POSITION-2; EXPOI:DEV=MBTRX
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) EXPOI:DEV=MBTRX-3616, POS=EMG-P4P1&RH-5&POSITION-1; EXPOI:DEV=MBTRX-3617, POS=EMG-P4P1&RH-5&POSITION-2; EXPOI:DEV=MBTRX-3618, POS=EMG-P4P1&RH-5&POSITION-3; EXPOI:DEV=MBTRX-3619, POS=EMG-P4P1&RH-5&POSITION-4; ! RH 6 ! EXPOI:DEV=MBTRX-3624, POS=EMG-P4P1&RH-6&POSITION-1; EXPOI:DEV=MBTRX-3625, POS=EMG-P4P1&RH-6&POSITION-2; EXPOI:DEV=MBTRX-3626, POS=EMG-P4P1&RH-6&POSITION-3; EXPOI:DEV=MBTRX-3627, POS=EMG-P4P1&RH-6&POSITION-4; 9.4.3.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 9.4.3.7 Define the Reverse Digital Path (DIP) DTDII:DIP=R448, DEV=RILT-448; DTIDC:DIP=R448, MULTFS=01, LC=1, FRS=1,MODE=1; ! CLC ON DIP ! 9.4.3.8 Change Quality Supervision for DP ! BIT FAULT FREQUENCY ! DTQSC:DIP=R448, BFF, BFFL1=100, ACL1=O1, BFFL2=800, ACL2=A2; ! SLIP FREQUENCY ! DTQSC:DIP=R448, SF, SFL=5, ACL=O1, TI=24; ! DISTURBANCE FREQUENCY ! DTQSC:DIP=R448, DF, DFL=5000, ACL=O1, TI=24; 9.4.3.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 9.4.3.11 Initiate Fault Supervision for DP DTFSI:DIP=R448, FAULT=2&&4&8; 9.4.3.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MTAVC:CELL=P4P1F, PLVM=1, PLV=1, SSD=46, SSI=38, SSH=43, SSV=12; MTAVC:CELL=P4P1F, SSB=22, SNH=33, SNR=10, SUH=6, CIH=19, SSMIN=5; 9.4.3.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 9.4.3.14 Define Digital Locating Data MTDLC: CELL=C002A, MCHNR=330, PSMB=38, PSVB=38, REALTIME=0; 9.4.3.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MTCCI:CELL=P4P1D, DEV=MVC-2690; MTCCI:CELL=P4P1D, DEV=MDVC-2712&-2713; MTCCI:CELL=P4P1D, DEV=MLOC-227; MTCCI:CELL=P4P1D, DEV=MVER-227; ! Cell E ! MTCCI:CELL=P4P1E, DEV=MDCC-228; MTCCI:CELL=P4P1E, DEV=MDVC-2720&&-2727; MTCCI:CELL=P4P1E, DEV=MVER-228; ! Cell F ! MTCCI:CELL=P4P1F, DEV=MCC-229; MTCCI:CELL=P4P1F, DEV=MLOC-229; MTCCI:CELL=P4P1F, DEV=MVC-2691; 9.4.4 Configuration of Channel Equipment 9.4.4.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBLTI:CEQ=MBCEQ-3593, MODE=ANA, DEV=MBLT86-1252; MBLTI:CEQ=MBCEQ-3592, MODE=DIG, UNIT=1&2, DEV=MBTRAC-270&-271; or MBLTI:CEQ=MBCEQ-3592, MODE=DIG, UNIT=1&2, DEV=MBTRC-270&-271; MBLTI:CEQ=MBCEQ-776, MODE=POOL,DEV=MBLT86-144; ! Cell C ! MBLTI:CEQ=MBCEQ-3600, MODE=DIG, UNIT=1&2, DEV=MBTRAC-282&-283; or MBLTI:CEQ=MBCEQ-3600, MODE=DIG, UNIT=1&2, DEV=MBTRC-282&-283; MBLTI:CEQ=MBCEQ-3601, MODE=DIG, UNIT=0&&2, DEV=MBTRAC-285&&-287; or MBLTI:CEQ=MBCEQ-360
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) or MBLTI:CEQ=MBCEQ-3608, MODE=DIG, UNIT=1&2, DEV=MBTRC-294&-295; ! Cell E ! MBLTI:CEQ=MBCEQ-3616, MODE=DIG, UNIT=1&2, DEV=MBTRAC-306&-307; or MBLTI:CEQ=MBCEQ-3616, MODE=DIG, UNIT=1&2, DEV=MBTRC-306&-307; MBLTI:CEQ=MBCEQ-3617, MODE=DIG, UNIT=0&&2, DEV=MBTRAC-309&&-311; or MBLTI:CEQ=MBCEQ-3617, MODE=DIG, UNIT=0&&2, DEV=MBTRC-309&&-311; MBLTI:CEQ=MBCEQ-3618, MODE=DIG, UNIT=0&&2, DEV=MBTRAC-313&&-315; or MBLTI:CEQ=MBCEQ-3618, MODE=DIG, UNIT=0&&2, DEV
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBECC:CEQ=MBCEQ-3584, TRCAP=BOTH; MBECC:CEQ=MBCEQ-3585, MAXPOWER=200; MBECC:CEQ=MBCEQ-3586, TRCAP=RX; MBECC:CEQ=MBCEQ-3587, TRCAP=RX; ! Cell B ! MBECC:CEQ=MBCEQ-3592,MAXPOWER=200; MBECC:CEQ=MBCEQ-3593, MAXPOWER=200; MBECC:CEQ=MBCEQ-3594, TRCAP=RX; MBECC:CEQ=MBCEQ-3595, TRCAP=RX; ! Cell C ! MBECC:CEQ=MBCEQ-3600, MAXPOWER=200; MBECC:CEQ=MBCEQ-3601, MAXPOWER=200; MBECC:CEQ=MBCEQ-3602, MAXPOWER=200; MBECC:CEQ=MBCEQ-3603, TRCAP=RX; ! Cell D ! MBECC:CEQ
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBECC:CEQ=MBCEQ-3617,MAXPOWER=200; MBECC:CEQ=MBCEQ-3618, MAXPOWER=200; MBECC:CEQ=MBCEQ-3619, TRCAP=RX; ! Cell F ! MBECC:CEQ=MBCEQ-3624, TRCAP=BOTH, MAXPOWER=200, TXATT=0, RXGAIN=0; MBECC:CEQ=MBCEQ-3625, TRCAP=BOTH, MAXPOWER=200, TXATT=0, RXGAIN=0; MBECC:CEQ=MBCEQ-3626, TRCAP=RX; 9.4.4.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MTCTC:DEV=MDVC-2705, CHNR=991, POWER=200, FIT=EF; MTCTC:DEV=MDVC-2706, CHNR=1, POWER=200, FIT=EF; MTCTC:DEV=MDVC-2707, CHNR=1, POWER=200, FIT=EF; MTCTC:DEV=MDVC-2708, CHNR=1, POWER=200, FIT=EF; MTCTC:DEV=MDVC-2709, CHNR=670, POWER=200, FIT=EF; MTCTC:DEV=MDVC-2710, CHNR=670, POWER=200, FIT=EF; MTCTC:DEV=MDVC-2711, CHNR=670, POWER=200, FIT=EF; ! Cell D ! MTCTC:DEV=MDCC-227, CHNR=1022, POWER=110, FIT=EF; MTCTC:DEV=MVC-2690, CHNR=73, POWER=110, FIT=EF;
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell F ! MTCTC:DEV=MCC-229, CHNR=94, POWER=200, FIT=EF; MTCTC:DEV=MVC-2691, CHNR=115, POWER=200, FIT=EF; 9.4.4.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MTCLC:DEV=MCC-229, COL=D-0; MTCLC:DEV=MVC-2691, COL=A-0; 9.4.4.5 Link Channel Equipment with Channel Function Units Note: For additional information about the speech and control channels, see Section 5.9.1.3 on page 5-54.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBEQI:CEQ=MBCEQ-3603, DEV=MVER-226; ! Cell D ! MBEQI:CEQ=MBCEQ-3608, DEV=MDCC-227, UNIT=0, RATE=1; MBEQI:CEQ=MBCEQ-3608, DEV=MDVC-2712&-2713, UNIT=1&2, RATE=1; MBEQI:CEQ=MBCEQ-3609, DEV=MVC-2690; MBEQI:CEQ=MBCEQ-3610, DEV=MLOC-227; MBEQI:CEQ=MBCEQ-3611, DEV=MVER-227; ! Cell E ! MBEQI:CEQ=MBCEQ-3616, DEV=MDCC-228, UNIT=0, RATE=1; MBEQI:CEQ=MBCEQ-3616, DEV=MDVC-2720&-2721, UNIT=1&2, RATE=1; MBEQI:CEQ=MBCEQ-3617, DEV=MDVC-2722&&-2724, UNIT=0&&2, RATE=
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 9.4.5 Deblock and Activate DIP, CLC, EMG, and RILTs 9.4.5.1 Deblock STC BLRPE:RP=134; 9.4.5.2 Deblock STC EM BLEME:RP=134, EM=1; 9.4.5.3 Deblock the Digital Path "DIP" DTBLE:DIP=52MTS3; DTSTP:DIP=52MTS3; 9.4.5.4 Deblock Control Signaling Link BLCLE:EQM=CLC-14; EXCLP:EQM=CLC-14; 9.4.5.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 9.4.5.6 Deblock Reverse DIP DTBLE:DIP=R448; DTSTP:DIP=R448; 9.4.5.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! (EM-RTT) CONTROL ! RISPI:TSLOT1=RILT-450-00, TSLOT2=RILT-461-00, NAME=CEQ3584CTRL; !DCCH ! RISPI:TSLOT1=RILT-450-01, TSLOT2=RILT-461-02, NAME=CEQ3585CTRL; !MVC ! RISPI:TSLOT1=RILT-450-02, TSLOT2=RILT-461-04, NAME=CEQ3586CTRL; !MLOC ! RISPI:TSLOT1=RILT-450-03, TSLOT2=RILT-461-06, NAME=CEQ3587CTRL; !MVER ! ! (ETB-RTT) SPEECH ! Note: The numbering for the speech timeslots on a T1 PCM link starts at 01 and ends with 24 for a total of 24 timeslots.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) RISPI:TSLOT1=RILT-451-03, TSLOT2=RILT-461-14, NAME=CEQ3595CTRL; !MVER ! ! (ETB-RTT) SPEECH ! RISPI:TSLOT1=RILT-448-04, TSLOT2=RILT-461-09, NAME=CEQ3592MBLT1251; RISPI:TSLOT1=RILT-448-05, TSLOT2=RILT-461-11, NAME=CEQ3593MBLT1252; ! RH-3 ! ! (EM-RTT) CONTROL ! RISPI:TSLOT1=RILT-452-00, TSLOT2=RILT-461-16, NAME=CEQ3600CTRL; !DCCH ! RISPI:TSLOT1=RILT-452-01, TSLOT2=RILT-461-18, NAME=CEQ3601CTRL; !DVC ! RISPI:TSLOT1=RILT-452-02, TSLOT2=RILT-461-20, NAME=
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) RISPI:TSLOT1=RILT-453-00, TSLOT2=RILT-461-24, NAME=CEQ3608CTRL; !DCCH ! RISPI:TSLOT1=RILT-453-01, TSLOT2=RILT-461-26, NAME=CEQ3609CTRL; !MVC ! RISPI:TSLOT1=RILT-453-02, TSLOT2=RILT-461-28, NAME=CEQ3610CTRL; !MLOC ! RISPI:TSLOT1=RILT-453-03, TSLOT2=RILT-461-30, NAME=CEQ3611CTRL; !MVER ! ! (ETB-RTT) SPEECH ! RISPI:TSLOT1=RILT-448-11, TSLOT2=RILT-461-25, NAME=CEQ3608MBLT1258; RISPI:TSLOT1=RILT-448-12, TSLOT2=RILT-461-27, NAME=CEQ3609MBLT1259; ! RH-5 !
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! RH-6 ! ! (EM-RTT) CONTROL ! RISPI:TSLOT1=RILT-455-00, TSLOT2=RILT-462-08, NAME=CEQ3624CTRL; !MCC ! RISPI:TSLOT1=RILT-455-01, TSLOT2=RILT-462-10, NAME=CEQ3625CTRL; !MVC ! RISPI:TSLOT1=RILT-455-02, TSLOT2=RILT-462-12, NAME=CEQ3626CTRL; !MLOC ! ! (ETB-RTT) SPEECH ! RISPI:TSLOT1=RILT-448-17, TSLOT2=RILT-462-09, NAME=CEQ3624MBLT1264; RISPI:TSLOT1=RILT-448-18, TSLOT2=RILT-462-11, NAME=CEQ3625MBLT1265; ! CHECK STATUS OF RILTs AND EMRSs ! RISPP:EMG=P4P1,
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell D ! EXDAI:DEV=MBLT86-1258&-1259; ! Cell E ! EXDAI:DEV=MBLT86-1261&&-1263; ! Cell F ! EXDAI:DEV=MBLT86-1264&-1265; 9.4.7.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) EXDAI:DEV=MBTRX-3602; EXDAI:DEV=MBTRX-3603; ! Cell D ! EXDAI:DEV=MBTRX-3608; EXDAI:DEV=MBTRX-3609; EXDAI:DEV=MBTRX-3610; EXDAI:DEV=MBTRX-3611; ! Cell E ! EXDAI:DEV=MBTRX-3616; EXDAI:DEV=MBTRX-3617; EXDAI:DEV=MBTRX-3618; EXDAI:DEV=MBTRX-3619; ! Cell F ! EXDAI:DEV=MBTRX-3624; EXDAI:DEV=MBTRX-3625; EXDAI:DEV=MBTRX-3626; 9.4.8 Semipermanent Connections of MBTRAC/MBTRC to MBLT86 Using the Group Switch 9.4.8.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) EXSCI:DEV1=MBTRAC-256, DEV2=MBLT86N-1248, NAME=P4P1-CEQ3584-01; or EXSCI:DEV1=MBTRC-256, DEV2=MBLT86N-1248, NAME=P4P1-CEQ3584-01; ! Cell B ! EXSCI:DEV1=MBTRAC-268, DEV2=MBLT86N-1251, NAME=P4P1-CEQ3592-04; or EXSCI:DEV1=MBTRC-268, DEV2=MBLT86N-1251, NAME=P4P1-CEQ3592-04; ! Cell C ! EXSCI:DEV1=MBTRAC-280, DEV2=MBLT86N-1254, NAME=P4P1-CEQ3600-07; or EXSCI:DEV1=MBTRC-280, DEV2=MBLT86N-1254, NAME=P4P1-CEQ3600-07; EXSCI:DEV1=MBTRAC-284, DEV2=MBLT86N-1
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell D ! EXSCI:DEV1=MBTRAC-292, DEV2=MBLT86N-1258, NAME=P4P1-CEQ3608-11; or EXSCI:DEV1=MBTRC-292, DEV2=MBLT86N-1258, NAME=P4P1-CEQ3608-11; ! Cell E ! EXSCI:DEV1=MBTRAC-304, DEV2=MBLT86N-1261, NAME=P4P1-CEQ3616-14; or EXSCI:DEV1=MBTRC-304, DEV2=MBLT86N-1261, NAME=P4P1-CEQ3616-14; EXSCI:DEV1=MBTRAC-308, DEV2=MBLT86N-1262, NAME=P4P1-CEQ3616-15; or EXSCI:DEV1=MBTRC-308, DEV2=MBLT86N-1262, NAME=P4P1-CEQ3616-15; EXSCI:DEV1=MBTRAC-312, DEV2=MBLT86N-12
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 9.4.9 Loading/Self-Testing of RBS Equipment 9.4.9.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBDPP:DEV=MBTRX-3609; MBDPP:DEV=MBTRX-3610; MBDPP:DEV=MBTRX-3611; MBDPL:DEV=MBTRX-3608&&-3611, FILE=RCSUFILE-RU40R6B; ! Cell E ! MBDPP:DEV=MBTRX-3616; MBDPP:DEV=MBTRX-3617; MBDPP:DEV=MBTRX-3618; MBDPP:DEV=MBTRX-3619; MBDPL:DEV=MBTRX-3616&&-3619, FILE=RCSUFILE-RU40R6B; ! Cell F ! MBDPP:DEV=MBTRX-3624; MBDPP:DEV=MBTRX-3625; MBDPP:DEV=MBTRX-3626; MBDPL:DEV=MBTRX-3624&&-3626, FILE=RCSUFILE-RU40R6B; 9.4.9.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) or EXDAI:DEV=MBTRB-18; EXDAI:DEV=MBTRAB-19; or EXDAI:DEV=MBTRB-19; 9.4.9.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBDPL:DEV=MBTRAB/MBTRB-19, FILE=RCSUFILE-RCSU60; or MBDPP:DEV=MBTRB-19; MBDPL:DEV=MBTRB-19, FILE=RCSUFILE-RCSU60; 9.4.9.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell D ! MBSDI:DEV=MBTRX-3608; MBSDI:DEV=MBTRX-3609; MBSDI:DEV=MBTRX-3610, TCASE=1; MBSDI:DEV=MBTRX-3611, TCASE=1; ! Cell E ! MBSDI:DEV=MBTRX-3616; MBSDI:DEV=MBTRX-3617; MBSDI:DEV=MBTRX-3618; MBSDI:DEV=MBTRX-3619, TCASE=1; ! Cell F ! MBSDI:DEV=MBTRX-3624; MBSDI:DEV=MBTRX-3625; MBSDI:DEV=MBTRX-3626, TCASE=1; 9.4.9.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) MBSDI:DEV=MBTRAB-19; or MBSDI:DEV=MBTRB-19; 9.4.10 Deblocking/Checking of RBS Equipment 9.4.10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) STDEP:DEV=MBLT86N-1249; ! Cell B ! BLODE:DEV=MBLT86N-1252; STDEP:DEV=MBLT86N-1252; ! Cell C ! ! No Analog Voice in Cell C ! ! Cell D ! BLODE:DEV=MBLT86N-1259; STDEP:DEV=MBLT86N-1259; ! Cell E ! ! No Analog Voice in Cell E ! ! Cell F ! BLODE:DEV=MBLT86N-1265; 9.4.10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell B ! BLODE:DEV=MBTRAC-270&-271; STDEP:DEV=MBTRAC-270&-271; or BLODE:DEV=MBTRC-270&-271; STDEP:DEV=MBTRC-270&-271; ! Cell C ! BLODE:DEV=MBTRAC-282&-283&-285&&-287&-289&&-291; STDEP:DEV=MBTRAC-282&-283&-285&&-287&-289&&-291; or BLODE:DEV=MBTRC-282&-283&-285&&-287&-289&&-291; STDEP:DEV=MBTRC-282&-283&-285&&-287&-289&&-291; ! Cell D ! BLODE:DEV=MBTRAC-294&-295; STDEP:DEV=MBTRAC-294&-295; or BLODE:DEV=MBTRC-294&-295; STDEP:DEV=MBTRC-294&-295;
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) or BLODE:DEV=MBTRC-306&-307&-309&&-311&-313&&-315; STDEP:DEV=MBTRC-306&-307&-309&&-311&-313&&-315; ! Cell F ! ! No Digital Voice in Cell F ! 9.4.10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) BLODE:DEV=MBTRX-3603; STDEP:DEV=MBTRX-3600&&-3603; ! Cell D ! BLODE:DEV=MBTRX-3608; BLODE:DEV=MBTRX-3609; BLODE:DEV=MBTRX-3610; BLODE:DEV=MBTRX-3611; STDEP:DEV=MBTRX-3608&&-3611; ! Cell E ! BLODE:DEV=MBTRX-3616; BLODE:DEV=MBTRX-3617; BLODE:DEV=MBTRX-3618; BLODE:DEV=MBTRX-3619; STDEP:DEV=MBTRX-3616&&-3619; ! Cell F ! BLODE:DEV=MBTRX-3624; BLODE:DEV=MBTRX-3625; BLODE:DEV=MBTRX-3626; STDEP:DEV=MBTRX-3624&&-3626; 9.4.10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) STDEP:DEV=MVC-2688; ! Cell B ! BLODE:DEV=MVC-2689; STDEP:DEV=MVC-2689; ! Cell C ! ! No Analog Voice in Cell C ! ! Cell D ! BLODE:DEV=MVC-2690; STDEP:DEV=MVC-2690; ! Cell E ! ! No Analog Voice in Cell E ! ! Cell F ! BLODE:DEV=MVC-2691; STDEP:DEV=MVC-2691; 9.4.10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell C ! BLODE:DEV=MDVC-2704&&-2711; STDEP:DEV=MDVC-2704&&-2711; ! Cell D ! ! No Digital Voice in Cell D ! ! Cell E ! BLODE:DEV=MDVC-2720&&-2727; STDEP:DEV=MDVC-2720&&-2727; ! Cell F ! ! No Digital Voice in Cell F ! 9.4.10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! No Analog Control Channel in Cell D ! ! Cell E ! BLODE:DEV=MCC-229; STDEP:DEV=MCC-229; ! Cell F ! ! No Analog Control Channel in Cell F ! 9.4.10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell E ! BLODE:DEV=MDCC-228; STDEP:DEV=MDCC-228; ! Cell F ! ! No Digital Control Channel in Cell F ! 9.4.10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! Cell F ! BLODE:DEV=MLOC-229; STDEP:DEV=MLOC-229; 9.4.10.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) ! No MVER in Cell F ! 9.4.10.13 Check Cell Status MTCCP:CELL=P4P1A; MTCCP:CELL=P4P1B; MTCCP:CELL=P4P1C; MTCCP:CELL=P4P1D; MTCCP:CELL=P4P1E; MTCCP:CELL=P4P1F; 9.4.11 Assignment of Supervision to Routes 9.4.11.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) DUDAC:R=P4P1BMO, ADL=5, ACL=A2; DUDAC:R=P4P1BMI, ADL=5, ACL=A2; DUDAC:R=P4P1CMO, ADL=5, ACL=A2; DUDAC:R=P4P1CMI, ADL=5, ACL=A2; DUDAC:R=P4P1DMO, ADL=5, ACL=A2; DUDAC:R=P4P1DMI, ADL=5, ACL=A2; DUDAC:R=P4P1EMO, ADL=5, ACL=A2; DUDAC:R=P4P1EMI, ADL=5, ACL=A2; 9.4.11.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) SEQAC:R=P4P1DMO & P4P1DMI, ACL=A3, QUOS=40, QUOB=85; SEQAC:R=P4P1EMO & P4P1EMI, ACL=A3, QUOS=40, QUOB=85; 9.4.11.5 Set Blocking Supervision for Analog Voice Line Routes BLURC:R=P4P1ANO & P4P1ANI, ACL=A2, LVB=1; BLURC:R=P4P1BNO & P4P1BNI, ACL=A2, LVB=1; BLURC:R=P4P1DNO & P4P1DNI, ACL=A2, LVB=1; BLURC:R=P4P1FNO & P4P1FNI, ACL=A2, LVB=1; 9.4.11.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 9.4.11.10 Connection of Cell to Location Area MTLCC: CELL=P4P1A, LOCAREA=LOC1A; MTLCC: CELL=P4P1B, LOCAREA=LOC1A; MTLCC: CELL=P4P1D, LOCAREA=LOC1A; 10 Example Integration: Pico (1900 MHz) The Pico 1900 Mhz integration example is the same as the Pico 850 MHz integration example (see Section 9 on page 5-76) with the following exceptions: • The Pico 1900 MHz is a digital base station and the Pico 850 MHz analog integration procedures are ignored.
Integration and Test, RBS 884 Pico (850 MHz and 1900 MHz) 5-158 1532-AE/LZB 119 3834 Uae Rev PA4 2001-04-04
Part 6 Operations and Maintenance 1 Introduction . . . . . . . . . . . . . . . . . . 6-3 2 Maintenance Overview . . . . . . . . . . . . . 2.1 General Recommendations . . . . . . . . 2.2 Maintenance Log . . . . . . . . . . . . . 6-3 6-3 6-4 3 Safety Regulations . . . . . . . . . . . . . . . 3.1 Voltage Hazards . . . . . . . . . . . . . 3.2 Radio Frequency Radiation . . . . . . . . 6-4 6-4 6-5 4 Product Handling . . . . . . . . . . . . . . . . 4.1 Storage and Transport . . . . . . . . . . 4.
Operations and Maintenance 6-2 1/1541-AE/LZB 119 3834 Uae Rev PA6 2001-04-04
Operations and Maintenance 1 Introduction This part of the manual describes operations and maintenance procedures for the RBS 884 Pico (1900 MHz) system. These procedures include instructions for identifying faults and replacing faulty equipment, when necessary. 2 Maintenance Overview RBS 884 Pico (1900 MHz) maintenance includes general maintenance, such as those identified in Section 2.1 on page 6-3, and hardware replacement procedures.
Operations and Maintenance 2.2 Maintenance Log A record of all routine maintenance performed at the site should be maintained in a separate maintenance log at the RBS site. Fault data is automatically recorded in the system malfunction log. 3 Safety Regulations Before starting any installation, test, or maintenance procedures, review the safety regulations provided in this section.
Operations and Maintenance 3.2 Radio Frequency Radiation DANGER! Radio frequency (RF) from an antenna can be a danger to health, causing severe burns. Turn off the transmitter when working with or near the antennas. 4 Product Handling 4.1 Storage and Transport Store and transport components and printed circuit boards (units) in the original packaging.
Operations and Maintenance bottom of the CRI rack mount (subrack) or to the collection bar located in the CRI floor mount (cabinet). 5 Fault Detection and Alarms Reporting Fault detection is implemented through routine monitoring and fault and alarm reporting. 5.1 Routine Monitoring The RBS 884 Pico (1900 MHz) normally supervises and removes faulty hardware from service when a fault is detected. The operator can manually remove (block) hardware from service and manually test it if needed.
Operations and Maintenance • Extension Module Regional Processor with Speech Bus Access (EMRPS) unit • Enhanced Link Interface (ELI) unit See Table 6-1 on page 6-7 for a description of the LED indicators in the CRI. See Part 7, Troubleshooting for troubleshooting procedures and recommendations for specific faults identified by the LEDs. Table 6-1. CRI LED Indicators Unit CID Unit Indicator Power Color Green Description OFF: The CRI is not receiving power. ON: The CRI is receiving power.
Operations and Maintenance Table 6-1. CRI LED Indicators (Continued) ELI Unit Power Green OFF: The ELI unit is not receiving power. ON: The ELI unit is receiving power. Error Red OFF: No error is indicated Steady ON: An error is indicated. 1 Hz Flashing: There is a clock or PLL fault 3 Hz Flashing: Self test is in progress. Note: Status Red The Error and Status LEDs are lit briefly during the power-on sequence. Steady ON: There is no received signal on the PCM link.