bs240it.pdf

Installation Test

Base Transceiver Station Equipment

ITMN:BTSEBS-240 / 240 II / 240XL / 240XL II

A30808-X3247-K356-4-7630

2 A30808-X3247-K356-4-7630


Installation TestBase Transceiver Station Equipment

f Important Notice on Product Safety

DANGER - RISK OF ELECTRICAL SHOCK OR DEATH - FOLLOW ALL INSTALLATION INSTRUCTIONS.

The system complies with the standard EN 60950 / IEC 60950. All equipment connected to the system mustcomply with the applicable safety standards.Hazardous voltages are present at the AC power supply lines in this electrical equipment. Some components mayalso have high operating temperatures.Failure to observe and follow all installation and safety instructions can result in serious personal injuryor property damage.Therefore, only trained and qualified personnel may install and maintain the system.

The same text in German:

Wichtiger Hinweis zur Produktsicherheit

LEBENSGEFAHR - BEACHTEN SIE ALLE INSTALLATIONSHINWEISE.

Das System entspricht den Anforderungen der EN 60950 / IEC 60950. Alle an das System angeschlossenenGeräte müssen die zutreffenden Sicherheitsbestimmungen erfüllen.In diesen Anlagen stehen die Netzversorgungsleitungen unter gefährlicher Spannung. Einige Komponentenkönnen auch eine hohe Betriebstemperatur aufweisen.Nichtbeachtung der Installations- und Sicherheitshinweise kann zu schweren Körperverletzungen oderSachschäden führen.Deshalb darf nur geschultes und qualifiziertes Personal das System installieren und warten.

Caution:This equipment has been tested and found to comply with EN 301489. Its class of conformity is defined in tableA30808-X3247-X910-*-7618, which is shipped with each product. This class also corresponds to the limits for aClass A digital device, pursuant to part 15 of the FCC Rules.These limits are designed to provide reasonable protection against harmful interference when the equipment isoperated in a commercial environment.This equipment generates, uses and can radiate radio frequency energy and, if not installed and used in accor-dance with the relevant standards referenced in the manual “Guide to Documentation”, may cause harmful inter-ference to radio communications.For system installations it is strictly required to choose all installation sites according to national and local require-ments concerning construction rules and static load capacities of buildings and roofs.For all sites, in particular in residential areas it is mandatory to observe all respectively applicable electromagneticfield / force (EMF) limits. Otherwise harmful personal interference is possible.

Trademarks:

All designations used in this document can be trademarks, the use of which by third parties for their own purposescould violate the rights of their owners.

Copyright (C) Siemens AG 2002.

Issued by the Information and Communication Mobile GroupHofmannstraße 51D-81359 München

Technical modifications possible.Technical specifications and features are binding only insofar asthey are specifically and expressly agreed upon in a written contract.

A30808-X3247-K356-4-7630 3



Reason for UpdateSummary:

Fourth edition for release BR 6.0

Details:

Chapter/Section Reason for Update

3.9 Chapter ECU added

Issue HistoryIssue

Number

Date of issue Reason for Update

1 6/2002 New release BR 6.0

2 7/2002 Offline Tests Update

3 9/2002 Revised subchapters

4 11/2002 Chapter ECU added

4 A30808-X3247-K356-4-7630



A30808-X3247-K356-4-7630 5



This document consists of a total of 194 pages. All pages are issue 4.

Contents

1 BS-240 / 240 II / 240XL / 240XL II Installation Test . . . . . . . . . . . . . . . . . . 111.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111.1.1 Aims of Installation and Commissioning . . . . . . . . . . . . . . . . . . . . . . . . . . . 111.1.2 Pre-Commissioning and Pre-Acceptance . . . . . . . . . . . . . . . . . . . . . . . . . . 111.1.3 Optional Measurements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121.1.4 Test Strategy. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121.1.5 Principle of BTSE Testing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121.1.6 Using the ITMN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121.1.7 Safety Instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 151.1.8 Technical Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171.2 Visual Inspection of BTSE Mechanics . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171.2.1 Racks of BS-240 / 240 II / 240XL / 240XL II . . . . . . . . . . . . . . . . . . . . . . . . 171.2.2 Mounting and Installation of BTSE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 201.2.3 Check of BTSE Modules. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 201.2.4 Antenna and Feeder Cable. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 221.2.5 Module HW Coding. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 221.3 Visual Inspection of BTSE Electrics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 221.3.1 Polarity of DC Input and Tolerance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 221.3.2 Circuit Breakers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 221.3.3 External Alarms. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 261.3.4 DC Connector for Network Termination (NT) . . . . . . . . . . . . . . . . . . . . . . . 271.4 Visual Inspection of BTSE Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 271.4.1 STAR/LOOP/MULTIDROP/CROSS CONNECT Connection . . . . . . . . . . . 271.4.2 Antenna Connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 281.4.3 RF System Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 291.4.4 Antenna Combining . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 321.4.5 Antenna Multicoupling. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 351.4.6 Adjustable Modules. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 391.5 Preparation for Offline Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 481.5.1 Recommended Test Equipment and Tools. . . . . . . . . . . . . . . . . . . . . . . . . 491.5.2 Preparation and Presetting of Test Equipment . . . . . . . . . . . . . . . . . . . . . . 511.5.3 BTSE Power ON . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52

2 Task List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54

3 Procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 553.1 SW Download and Activation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 573.2 Rack . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 623.3 Hardware Related Managed Objects . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 643.4 ACDCP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 663.5 ACT. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 683.6 Battery. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 703.7 COSA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 723.8 CU. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 743.9 ECU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76

6 A30808-X3247-K356-4-7630



3.10 FAN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 773.11 DIAMCO. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 793.12 DUAMCO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 833.13 FICOM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 883.14 TMA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 913.15 LMU (optional) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 933.16 Creating the Alarm Configuration (ENVABTSE) . . . . . . . . . . . . . . . . . . . . . 993.17 Setting Attributes for the BTSE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1023.18 BPORT. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1043.19 XCONNECT. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1063.20 Set BTSM. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1083.21 LAPDLE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1103.22 CORE Redundancy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1123.23 Checking the State of all Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1173.24 Replacing Failed HW . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1183.25 External Alarm Check . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1193.26 BTS Backup Files Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1203.27 Remote Inventory. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1223.28 BTSE Phase 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1313.29 Execution of Offline Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1333.29.1 RF and Function Tests. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1333.29.2 Purpose of the Abis Simulation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1343.29.3 Preparation of the Abis Simulation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1343.29.4 Connection of Test equipment (TE) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1353.29.5 Check BTSE Phase . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1353.30 Starting the Abis Simulation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1363.31 Database Alignment. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1423.32 Local Test Loop . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1443.33 Bit Error Rate Test (BERT) with MS-Loop (optional) . . . . . . . . . . . . . . . . . 1463.34 Mobile Controlled Test Sequence (optional) . . . . . . . . . . . . . . . . . . . . . . . 1493.35 Key Functions of the Mobile Phone During Test Sequence. . . . . . . . . . . . 1533.36 Setup for Optional RF-Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1553.36.1 Measuring Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1553.37 Channel Activation/Deactivation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1573.38 Spectrum Analyzer Measurements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1633.39 VSWR Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1663.40 RFI-Confirmation: Unit ATMN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 166

4 Tables, Lists and Figures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1674.1 Frequency/Channel Conversion Table. . . . . . . . . . . . . . . . . . . . . . . . . . . . 1694.1.1 GSM Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1694.1.2 DCS Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1734.1.3 PCS Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 177

5 Appendix . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1815.1 Possible Configurations for Offline Tests . . . . . . . . . . . . . . . . . . . . . . . . . . 1815.1.1 Possible Test Configurations for DUAMCO . . . . . . . . . . . . . . . . . . . . . . . . 1815.1.2 DUAMCO Test Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 183

A30808-X3247-K356-4-7630 7



5.1.3 FICOM Test Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1855.2 Power/Level Conversion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1865.3 Used Expressions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1865.4 Module Identification by Inventory Data and Label . . . . . . . . . . . . . . . . . . 187

6 Abbreviations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 189

7 Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 193

8 A30808-X3247-K356-4-7630



IllustrationsFig. 1.1 Installation Test Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14

Fig. 1.2 ESD Symbol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15

Fig. 1.3 CE Symbol / UL Symbol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

Fig. 1.4 Example for BS-240 / 240 II (front view) . . . . . . . . . . . . . . . . . . . . . . . . . 19

Fig. 1.5 DC Panel (Example BS-240XL Base Rack) . . . . . . . . . . . . . . . . . . . . . . 23

Fig. 1.6 Star/Loop/Multidrop/Cross Connect Configuration . . . . . . . . . . . . . . . . . 28

Fig. 1.7 TMA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29

Fig. 1.8 RF System Cabling CU–DUAMCO (Example) . . . . . . . . . . . . . . . . . . . . 31

Fig. 1.9 RF System cabling CU - FICOM and DIAMCO - CU (example) . . . . . . . 32

Fig. 1.10 FICOM Modules for 8 Carriers in 1-Cell Configuration . . . . . . . . . . . . . . 34

Fig. 1.11 FICOM Modules in 2-Cell Configuration . . . . . . . . . . . . . . . . . . . . . . . . . 35

Fig. 1.12 DIAMCO Antenna Connection and DIP Switches. . . . . . . . . . . . . . . . . . 36

Fig. 1.13 View of DIP Switch (factory setting) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37

Fig. 1.14 DUAMCO DIP Switch and Antenna Connection. . . . . . . . . . . . . . . . . . . 38

Fig. 1.15 View of DIP Switch (factory setting) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

Fig. 1.16 COBA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42

Fig. 1.17 Switch Settings of Port 1 and Port 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43

Fig. 1.18 External Clock Synchronization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43

Fig. 1.19 COSA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44

Fig. 1.20 Switch Settings of Port 1 to Port 6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45

Fig. 1.21 DIP Switches for Battery Manufacturer, Battery Capacities and Slot-ID. 46

Fig. 1.22 Battery Manufacturer DIP Switch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47

Fig. 1.23 Battery Capacity DIP Switch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47

Fig. 1.24 DCBCTRL Slot-ID DIP Switch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48

Fig. 3.1 Configuration for Offline Test with FICOM and DIAMCO . . . . . . . . . . . 133

Fig. 3.2 Configuration for Offline Test with DUAMCO . . . . . . . . . . . . . . . . . . . . 134

Fig. 3.3 Measurement Set-Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155

Fig. 3.4 Used Trigger Adapter (TAD-L) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155

Fig. 3.5 Trigger Adapter (TAD-L) with Housing and Adapter (TADADPT). . . . . 156

Fig. 3.6 Spectrum Analyzer HP8954A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 163

Fig. 5.1 DUAMCO 2:2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 181

Fig. 5.2 DUAMCO 4:2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 182

Fig. 5.3 DUAMCO 8:2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 182

Fig. 5.4 Testconfiguration for DUAMCO 2:2 Serving 1 Cell with 1 Carrier . . . . 183

Fig. 5.5 Testconfiguration for DUAMCO 2:2 Serving 1 Cell with 2 Carriers. . . . 184

Fig. 5.6 Testconfiguration for FICOM Test. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 185

Fig. 5.7 Labels and Inventory Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 187

A30808-X3247-K356-4-7630 9



TablesTab. 1.1 Technical Data of BS-240 / 240 II / 240XL / 240XL II (Extraction). . . . . 17

Tab. 1.2 Module HW Code Key . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22

Tab. 1.3 DC Breakers for BS-240XL Base Rack . . . . . . . . . . . . . . . . . . . . . . . . . 23

Tab. 1.4 DC Breakers for BS-240XL Extension Rack . . . . . . . . . . . . . . . . . . . . . 23

Tab. 1.5 DC Breakers for BS-240XL Service1 Rack . . . . . . . . . . . . . . . . . . . . . . 24

Tab. 1.6 DC Breakers for BS-240XL Service2 Rack . . . . . . . . . . . . . . . . . . . . . . 24

Tab. 1.7 DC Breakers for BS-240 Base Rack . . . . . . . . . . . . . . . . . . . . . . . . . . . 24

Tab. 1.8 DC Breakers for BS-240 Extension Rack . . . . . . . . . . . . . . . . . . . . . . . 24

Tab. 1.9 DC Breakers for BS-240 Service1 Rack . . . . . . . . . . . . . . . . . . . . . . . . 25

Tab. 1.10 DC Breakers for BS-240 Service2 Rack . . . . . . . . . . . . . . . . . . . . . . . . 25

Tab. 1.11 DC Breakers for BS-240XL II Base Rack . . . . . . . . . . . . . . . . . . . . . . . 25

Tab. 1.12 DC Breakers for BS-240XL II Extension Rack. . . . . . . . . . . . . . . . . . . . 25

Tab. 1.13 DC Breakers for BS-240 II Base Rack. . . . . . . . . . . . . . . . . . . . . . . . . . 25

Tab. 1.14 DC Breakers for BS-240 II Extension Rack . . . . . . . . . . . . . . . . . . . . . . 26

Tab. 1.15 DC Breakers for BS-240 II / 240XL II Service1 Rack. . . . . . . . . . . . . . . 26

Tab. 1.16 DC Breakers for BS-240 II / 240XL II Service2 Rack. . . . . . . . . . . . . . . 26

Tab. 1.17 Settings for ENVA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

Tab. 1.18 RF Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30

Tab. 1.19 Switch Setting for DIAMCO/DUAMCO. . . . . . . . . . . . . . . . . . . . . . . . . . 36

Tab. 1.20 Cascading of Multicouplers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39

Tab. 1.21 Adjustable Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39

Tab. 1.22 Boot Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

Tab. 1.23 Software Images SWI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

Tab. 1.24 Switch Setting on ACT. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

Tab. 1.25 Battery Manufacturer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47

Tab. 1.26 Slot-ID . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48

Tab. 3.1 Hardware Related Managed Objects. . . . . . . . . . . . . . . . . . . . . . . . . . . 64

Tab. 3.2 Key Commands for Mobile Controlled Test Sequence . . . . . . . . . . . . 153

Tab. 4.1 Frequency/Channel Conversion Table . . . . . . . . . . . . . . . . . . . . . . . . 169

Tab. 4.2 GSM Table. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 169

Tab. 4.3 DCS Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 173

Tab. 4.4 PCS Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 177

Tab. 5.1 Power Conversion Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 186

10 A30808-X3247-K356-4-7630



A30808-X3247-K356-4-7630 11



1 BS-240 / 240 II / 240XL / 240XL II InstallationTest

1.1 Introduction

1.1.1 Aims of Installation and Commissioning

Installation and commissioning is based on extensive, high quality final factory tests. Inthe factory, each module is tested during its production process; all RF parameters suchas the power and modulation spectrum are measured in the complete BTSE rack in cus-tomer configuration.

The Final Factory Tests comply with the tests and measurements required by GSMspecifications.

The installation test can therefore concentrate on functional tests of the delivered HW.

The installation and commissioning of a network element followed by unit acceptance isproof of:

It is assumed that:

The subdivision of tests in the steps

– final factory test

– installation/commissioning (HW-test)

– network integration (data base test)

allows a quick, economical, and reliable commissioning procedure.

1.1.2 Pre-Commissioning and Pre-Acceptance

The BTSE may also be delivered partly or completely pre-commissioned and pre-ac-cepted.

If the BTSE is pre-commissioned and pre-accepted, some procedures that usually areperformed on site (see Chapter 2 "Task List") have already been performed in the fac-tory. In this case, these particular procedures need not be performed again during theinstallation test phase.

It depends on the contract to what extent the BTSE is pre-commissioned and pre-ac-cepted.

All set parameters are listed in the Pre-Commissioning Paper. All executed tests andtheir results are documented in the Final Factory Test Protocol. Both documents are de-livered together with the site-specific documentation.

– a correct and complete delivery according to the network planning and thecustomer order.

– a correct mechanical and electrical installation according to the installationdocuments.

– the functional ability of the supplied HW(correct functioning of the NEs at an interface in relation to other networkelements).

12 A30808-X3247-K356-4-7630



Consult these documents to find out which procedures of the Task List can be left out.

1.1.3 Optional Measurements

RF and BERT measurements, which can be performed by means of spectrum analyzersor other BS-testers, are optional possibilities that can be done for localization of suspect-ed faults.They need not to be done in every BTSE as regular measurements.

1.1.4 Test Strategy

The BTSE functional test refers to only one network element at a time and is done of-fline.Offline means the BTSE has no active PCM link to the BSC. Due to the system conceptof the BTSE, some of the BSC functions must be simulated to activate the BTSE. Thisis done by an “SBS Abis Simulator” which will be connected to the Abis interface of theBTSE instead of the BSC.

1.1.5 Principle of BTSE Testing

After switching on the power supply of the BTSE, the “digital” boards perform a selftestwhich is seen as the first test step. When the boards reach the state “green” (green LEDindications mean that SW is loaded, activated, and the HW objects are created) theypassed the selftest and are O.K. If they don’t pass the selftest, they must be exchanged.The following function test consists of loading a database via an Abis simulator and set-ting up one or more test calls between the simulator and a mobile station. Each trafficchannel should be occupied at least once.

The BTSE is tested with the original customers configuration of hardware and the orig-inal software version that will run when the BTSE is in commercial service. No extrahardware or software in the BTSE must be implemented, so when the testcalls on eachtraffic channel work, the BTSE is seen as O.K.

Loading the database, the database alignment, via the Abis simulator is identical withthe procedure performed by the BSC. When the database alignment works with the sim-ulator, then the link interface communication is O.K. as well.

A standard mobile station without any special feature is used for the testcalls. If this MSis able to synchronize with the BTSE, read the system information messages and per-form calls, the communication on the Um interface is working and the BTSE is O.K.

1.1.6 Using the ITMN

1.1.6.1 Required knowledgeOnly trained personnel should carry out the installation and installation tests.The SIEMENS training center offers the necessary courses.

iIt is important, however, not to change the order of the remaining procedures.

A30808-X3247-K356-4-7630 13



1.1.6.2 Test EquipmentThe test equipment and tools required for the tests are described in the correspondingchapters.

1.1.6.3 Procedure in the Event of Faults after commissioningIf faults occur in on-line operation, they should be localized and cleared in accordancewith the instructions in the Maintenance Manual (MMN).

1.1.6.4 Procedure in the Event of Faults not described in the UMNFirst the specialist in the installation team should try to clear the fault. If the installationtechnician is not qualified to eliminate serious faults, a fault report must be filled out, pro-viding the following information in detail:

– description of the test step attempted

– description of the system response

– description of any system activities taking place at the same time, e.g., work doneby other testers during modifications to hardware or software

The fault report must be sent to the Technical Assistance Center (TAC).

1.1.6.5 Dealing with Defective ModulesIf a module proves to be defective, it should be sent in appropriate packaging to the re-pair center with the following information:

– Name and code of the site

– Name and code number of the module

– Description of the fault

14 A30808-X3247-K356-4-7630



1.1.6.6 Installation Test Sequence

Fig. 1.1 Installation Test Sequence

Visual Checkof BTS-Mechanics

Visual Checkof BTS-Electrics

Visual Checkof Boards

Preparation forFunction Tests

Execution ofFunction Tests

VISUAL

CONTROL

OFFLINE

ONLINE

S T A R T

E N D

Preparation /Executionof On-line Tests

A30808-X3247-K356-4-7630 15



1.1.7 Safety Instructions

1.1.7.1 Electrostatically Sensitive Components

General

All modules are to be handled with extreme care as each one contains many electrostat-ically sensitive devices (ESD).

All modules which contain ESD are marked with the ESD symbol on the faceplate or in-side.

Fig. 1.2 ESD Symbol

To avoid destruction or damage, comply with following rules.

Rules for Handling

The following safety instructions are to be observed:

– Personnel should avoid wearing synthetic clothing and shoes with plastic soles, asthese encourage the build-up of electrostatic charge.

– Before handling modules, personnel should be discharged of electrostatic charging.For this reason personnel should always put on a grounded wrist strap before chang-ing a module.

– ESDs should not be brought in contact with electrostatically charged or chargeableobjects.

– ESDs should only come in contact with high valued discharging material ("gentle"discharging), i.e., should not be made subject to "harsh" discharging with, for exam-ple, a metal plate.

– ESDs should be set down on grounded surfaces only (flexible bases with a ground-ing connection for servicing purposes)

– ESDs should not be brought into the vicinity of strong DC electrical fields, e.g. cath-ode ray tubes/monitors (safety distance at least 10 cm/~4 inches).

– All tools and test equipment should be discharged of electrostatic charging beforehandling modules.

– ESDs should only be transported in appropriate packing. A grounded wrist strapmust be put on before removing ESDs.

– Modules should only be touched by their edges. Components or printed circuitsshould not be touched.

16 A30808-X3247-K356-4-7630



1.1.7.2 System VoltagesAll system units require a power supply of ~230 V (~207 V in case of BS-240U / 240U II/ 240XLU / 240XLU II), which are converted to -48 V DC (positive pole grounded).Some parts are supplied with the line voltage directly and are to be handled with safetytools with extreme care. Only trained personnel should carry out those jobs.Care must be taken because some parts produce a high operating temperature.

This warning must appear in the original German text:

Alle Systemeinheiten benötigen eine Wechselspannung von ~230V (~207 V beiBS-240U / 240U II / 240XLU / 240XLU II), die in eine Gleichspannung von -48V (posi-tiver Pol an Masse) umgesetzt wird.Einige Teile führen Netzspannung und sind mit besonderer Sorgfalt zu behandeln. Nurausgebildetes Personal darf entsprechende Arbeiten übernehmen.Weiterhin ist zu beachten, daß sich einige Bauteile stark erhitzen.

1.1.7.3 Changing BreakersBreakers may only be changed by operator. Only authorized breakers as given in themanual may be used. Breakers are to be changed as described in this manual.

1.1.7.4 Grounding of Modules / RacksAll modules must be plugged in correctly to ground them before power is switched on.Ground connections between racks must be plugged in correctly.

1.1.7.5 Handling bedewed ModulesBedewed Modules must be dried before they are used, otherwise they will be destroyed.

1.1.7.6 CE and UL Declaration of Conformity

Fig. 1.3 CE Symbol / UL Symbol

The CE and UL declaration of conformity for the product will be fulfilled if the setup andcabling is undertaken in accordance with the specification in the manual and the docu-mentation listed there, such as mounting instructions, cable lists, etc. Where necessary,account should be taken of project-specific documentation.

Deviations from the specifications or independent changes during setup, such as use ofcable types with lower screening values, for example, can lead to the CE requirementsbeing violated. In such cases, the CE declaration of conformity is invalidated and the re-sponsibility passes to the person who has caused the deviations.

A30808-X3247-K356-4-7630 17



1.1.8 Technical Data

Extraction of common technical data as shown in the following table.

1.2 Visual Inspection of BTSE Mechanics

A visual inspection of all delivered racks must be executed to secure that these racksare not damaged and the quantity and location of the modules is correct.

1.2.1 Racks of BS-240 / 240 II / 240XL / 240XL II

A BS-240 / 240 II consists of one Base Rack, 1–2 Extension Racks (one Extension Rackfor BS-240XL / 240XL II Rack number 1), and 1–5 Service Racks. The numbering of theRacks is shown in the following table.

OBJECT BS-240 / 240 II/ 240XL / 240XL II

Input DC Power –48V –15%/+20%

Maximum Power consumption forone full equipped Base Rack(for 50W power amplifier)

BS-240 / 240 II:1570WBS-240XL / 240XL II:2230W

Frequency uplink D850 824–829 MHz

Frequency downlink D850 869–874MHz


Frequency downlink D900 921–960 MHz


Frequency downlink D1800 1805–1880 MHz

Frequency uplink D1900 1850–1910MHz

Frequency downlink D1900 1930–1990MHz

VSWR (DUAMCO, FICOM) 2< VSWR <3 warning3< VSWR alarm

TRX_max per Base Station 24

Cell_max per Base Station 12

TRX_max per Cell 12

CU TX Power D900 50W



ECU TX Power 850 32W

ECU HighTX Power 850 40W

Tab. 1.1 Technical Data of BS-240 / 240 II / 240XL / 240XL II (Extraction)

18 A30808-X3247-K356-4-7630



For setting the correct rack number, please refer to the Hardware Manual (see HW:BT-SE Modules, ACTP Switch Settings).

Rack numbering Type of Rack

0 Base Rack1 Extension Rack2 Extension Rack (not BS-240XL / 240XL II)3 Service 1 Rack (BS-240 / 240XL) with AC/DC modules4 Service 1A Rack (BS-240 II / 240XL II)with AC/DC modules4,..., 7 Service 2 Rack with Link Equipment and Backup Batteries

iThe numbering of the Service Racks always begins with 3 (4 for BS-240 II / 240XL II),even if there is no Extension Rack. Fig. 1.4 shows a BS-240 / 240 II with one BaseShelter and two Extension Racks.

A30808-X3247-K356-4-7630 19



Fig. 1.4 Example for BS-240 / 240 II (front view)

Base Rack Extension Rack

TMA7

TMA6

TMA0

TMA7

TMA6

TMA0

TMA7

TMA6

TMA0

TMA TMA TMA

LMT

BS-240

DCP OVPT

Extension Rack

BS-240

DCP

BS-240

DCP

CU#2

CU#3

CU#6

CU#7

DIA

MC

O#0

DIA

MC

O#1CU

#2CU#3

CU#6

CU#7

DIA

MC

O#0

DIA

MC

O#1

CU#0

CU#1

CU#4

CU#5

CU#0

CU#1

CU#4

CU#5

CO

RE

#0

CO

RE

#2

CO

RE

#1

CO

RE

#3 CU

#0CU#1

CU#4

CU#5

CU#2

CU#3

CU#6

CU#7

DIA

MC

O#0

DIA

MC

O#1

FAN#0 FAN#1

FAN#2 FAN#3

FAN#4 FAN#5

FAN#0 FAN#1

FAN#2 FAN#3

FAN#4 FAN#5

FAN#0 FAN#1

FAN#2 FAN#3

FAN#4 FAN#5

DU

AM

CO

#0

or

FIC

OM

#0

DU

AM

CO

#1

or

FIC

OM

#1

DU

AM

CO

#2

or

FIC

OM

#2

DU

AM

CO

#3

or

FIC

OM

#3

DU

AM

CO

#0

or

FIC

OM

#0

DU

AM

CO

#1

or

FIC

OM

#1

DU

AM

CO

#2

or

FIC

OM

#2

DU

AM

CO

#3

or

FIC

OM

#3

DU

AM

CO

#0

or

FIC

OM

#0

DU

AM

CO

#1

or

FIC

OM

#1

DU

AM

CO

#2

or

FIC

OM

#2

DU

AM

CO

#3

or

FIC

OM

#3

HPDU#0

HPDU#1

HPDU#0

HPDU#1

HPDU#0

HPDU#1

LMU#0

or

20 A30808-X3247-K356-4-7630



1.2.2 Mounting and Installation of BTSE

Check the internal/external interfaces and least replaceable units (LRU). For more de-tailed information, refer to the MMN:BTSE.

1.2.2.1 Check of Base Transceiver Station BTSECheck for delivery quality and quantity on site:

– installation of BTS rack (rack fixing, fixed boards)

– damage to rack or shelter (paintwork, dents)

– correct insertion of modules

– system/rack cabling

– grounding, earthing

– main breakers

– external interfaces: power supply, antenna, and Abis wiring

1.2.3 Check of BTSE Modules

1.2.3.1 Module IdentificationOnly the compatible released modules must be set in service. Check every module forthis release by the special label. Refer to the Stock List/Release Notes.

After the configuration of the modules in a BTSE, the code numbers and functionalstates are also electronically readable via LMT, see chapter 5.4 Module Identification byInventory Data and Label.

1.2.3.2 Modules in the RacksThe following table gives an overview of which modules can be installed in the rack-types.

Module BaseRack/Shelter

Extension 1/2Rack/Shelter

Service 1Rack/Shelter

Service 2Rack/Shelter

COBA XCOSA XCU X XFICOM X XDUAMCO X XDIAMCO X XDCP X X X XACTP X X X XACTM XAC/DC XDCBCTRL XBATTERY X XLE XLMU X

A30808-X3247-K356-4-7630 21



1.2.3.3 BTSE ModulesThe entire BTSE contains several cells called BTS:

Up to 12 Cells are available.

Check whether the BTSE modules are correctly configured.

Usage of FICOM modules of different suppliers

The FICOM modules (FIPLUB2RV3, FIPLUB2RV4, FIPLUX2RV3, FIPLUX2RV4) willbe produced by different manufacturers. This is indicated by the variants –V3 and –V4.One Base Module can be expanded by 3 Expansion Modules, all modules in this com-bination must have the same variant.

Redundancy

– CORE redundancy can be installed (not in BR 5.5). In the CORE, the functionalityof clock generation, link interface, and Call Control is implemented.

– The BCCH redundancy is matter of SW. The task "BCCH reconfiguration" runs inthe BTSEplus and the functionality is independent of the type of antenna combining.

– AC/DC redundancy is carried out as n+1 redundancy. N+1 AC/DC Converters oper-ate in load sharing, but n AC/DCs are able to supply the whole BTSEplus.

Hardware (HW) related modules:

Per CELL:DUAMCO Duplexer Amplifier MulticouplerDIAMCO Dual Integrated Amplifier MulticouplerFICOM Filter CombinerTMA Tower Mounted AmplifierHPDU High Power Duplexer

Per Transceiver TRX:CU Carrier Unit

In addition there are common modules:COBA Core BasisCOSA Core SatelliteACT Alarm Collection TerminalLMU Location Measurement Unit

Basic-Modules:DCP DC PanelFAN FanOVPT Overvoltage ProtectionAC/DC Alternating Current/Direct CurrentDCBCTRL DC and Battery ControllerBB Backup Battery

22 A30808-X3247-K356-4-7630



1.2.4 Antenna and Feeder Cable

The types of antennas must be tested in advance!

1.2.5 Module HW Coding

Every type of module has its own code key to ensure they are fitted in the correct slotposition. The on-board code must match the backplane code of the BTSE rack.

Note: The LMU doesn't have a code key, because it isn't installed inside in the rack.

1.3 Visual Inspection of BTSE Electrics

1.3.1 Polarity of DC Input and Tolerance

The BTSE requires –48V DC with a tolerance of –15%/+20% (–40,8V...–57,6V) for cor-rect operation (positive pole is grounded).Check this voltage.

1.3.2 Circuit Breakers

Rack internal breakers are available at the DC Panel for several modules to supply di-rect current (DC).

The breakers are mounted at the DC Panel on the top of the rack.There are different types of DC Panel for Base Rack, Extension Rack, Service1 Rackand Service2 Rack and there are also different types of DC Panels for BS-240 / 240 II/ 240XL / 240XL II.Check for fully equipped breakers and that all breakers are switched off.

Module Code Key

DUAMCO 7

FICOM 7

DIAMCO 8

CU 6

COBA 1

COSA 2

Tab. 1.2 Module HW Code Key

A30808-X3247-K356-4-7630 23



Fig. 1.5 DC Panel (Example BS-240XL Base Rack)

Breaker 1 2 3 4 5 6 7 8 9 10 11

Type 16A 16A 16A 16A 16A 16A 10A 10A 4A 4A 4A

Unit CU0–1

CU2–3

CU4–5

CU6–7

CU8–9

CU10–11

DIAMCOACOM/ACTPLMU

IN-TER-NALFAN

CORE/COBA,COSA

CORE/COBA,COSA

red

DCextern

Tab. 1.3 DC Breakers for BS-240XL Base Rack

Breaker 1 2 3 4 5 6 7 8

Type 16A 16A 16A 16A 16A 16A 10A 10A

Unit CU0–1

CU2–3

CU4–5

CU6–7

CU8–9

CU10–11

DIAMCOACOM/ACTP

IN-TER-NALFAN

Tab. 1.4 DC Breakers for BS-240XL Extension Rack

24 A30808-X3247-K356-4-7630



Breaker 1 2 3 4 5 6 7

Type 50A 80A 80A 4A 10A 10A 10A

Unit Service2 Rack

BaseRack

Exten-sionRack

ACTP IN-TER-NALFAN

LE0–2

LE3–5

Tab. 1.5 DC Breakers for BS-240XL Service1 Rack

Breaker 5 6 7 8 9

Type 4A 10A 10A 10A 10A

Unit ACTP IN-TER-NALFAN

LE0–2

LE3–5

LE6–8

Tab. 1.6 DC Breakers for BS-240XL Service2 Rack

Breaker 1 2 3 4 5 6 7 8 9 10

Type 16A 16A 16A 16A 4A 10A 4 4 4A 10A

Unit CU0–1

CU2–3

CU4–5

CU6–7

DIAMCOACOM/ACTPLMU

IN-TER-NALFAN

CORE/COBA,COSA

CORE/COBA,COSA

red

notused

notused(if exist-

ing)

Tab. 1.7 DC Breakers for BS-240 Base Rack

Breaker 1 2 3 4 5 6 10

Type 16A 16A 16A 16A 4A 10A 10A

Unit CU0–1

CU2–3

CU4–5

CU6–7

DIAMCOACOM/ACTP

INTER-NALFAN

notused(if exist-

ing)

Tab. 1.8 DC Breakers for BS-240 Extension Rack

A30808-X3247-K356-4-7630 25



Breaker 1 2 3 4 5 6 7 8 10

Type 50A 50A 50A 50A 4A 10A 10A 10A 10A

Unit Service2 Rack/Shelter

Exten-sion2Rack/

Shelter

Exten-sion1Rack/

Shelter

Base-Rack/

Shelter

ACTP INTER-NALFAN

LE0–2

LE3–5

notused(if exist-

ing)

Tab. 1.9 DC Breakers for BS-240 Service1 Rack

Breaker 5 6 7 8 9 10

Type 4A 10A 10A 10A 10A 10A

Unit ACTP INTER-NALFAN

LE0–2

LE3–5

LE6–8

notused(if exist-

ing)

Tab. 1.10 DC Breakers for BS-240 Service2 Rack

Breaker 1 2 3 4 5 6 7 8 9 10

Type 16A 16A 16A 16A 16A 16A 10A 16A 4A 4A

Unit CU0–1

CU2–3

CU4–5

CU6–7

CU8–9

CU10–11

DIAMCOACOM/ACTM

FAN0...7,

SMOKELMU

CORE0/1

CORE2/3

Tab. 1.11 DC Breakers for BS-240XL II Base Rack

Breaker 1 2 3 4 5 6 7 8 9

Type 16A 16A 16A 16A 16A 16A 10A 16A

Unit CU0–1

CU2–3

CU4–5

CU6–7

CU8–9

CU10–11

DIAMCOACOM/

FAN0...7,

SMOKEACT

notused

Tab. 1.12 DC Breakers for BS-240XL II Extension Rack

Breaker 1 2 3 4 5 6 7 8

Type 16A 16A 16A 16A 10A 10A 4A 4A

Tab. 1.13 DC Breakers for BS-240 II Base Rack

26 A30808-X3247-K356-4-7630



1.3.3 External Alarms

There are three types of ACT modules.

ACTM for Base Rack optionalACTP for each Rack, for Base Rack optionalACTC for all Racks is part of the DC Panel.

Unit CU0–1

CU2–3

CU4–5

CU6–7

DIAMCOACOM/ACTMLMU

FAN0...5,

SMOKE

CORE0/1

CORE2/3

Tab. 1.13 DC Breakers for BS-240 II Base Rack

Breaker 1 2 3 4 5 6

Type 16A 16A 16A 16A 10A 10A

Unit CU0–1

CU2–3

CU4–5

CU6–7

DIAMCOACOM/ACTP

FAN0...5,

SMOKE

Tab. 1.14 DC Breakers for BS-240 II Extension Rack

Breaker 1 2 3 4 5 6 7 8

Type max25A

max25A

max25A

max25A

max25A

max25A

max25A

max25A

Unit LE/Wave

0

LE/Wave

1

LE/Wave

2

LE/Wave

3

LE/Wave

4

LE/Wave

5

LE/Wave

6

LE/Wave

7

Tab. 1.15 DC Breakers for BS-240 II / 240XL II Service1 Rack

Breaker 1 2 3 4 5 6 7 8

Type max25A

max25A

max25A

max25A

max25A

max25A

max25A

max25A

Unit LE/Wave

0

LE/Wave

1

LE/Wave

2

LE/Wave

3

LE/Wave

4

LE/Wave

5

ACTC:FAN

ACTC:DC IN

Tab. 1.16 DC Breakers for BS-240 II / 240XL II Service2 Rack

A30808-X3247-K356-4-7630 27



All Racks are equipped with one ACTC which is part of the DC Panel. In the Base Rack,the ACTC is directly connected to the COBA. In the other Racks, the ACTC is connectedto the ACTP. On each ACTC, 16 Alarms are available, 7 Rack Alarms (RAL) that arecreated automatically during the creation of RACK and FAN and 9 Operator Alarms(OAL). The OAL must be created via 3.16 "Creating the Alarm Configuration (ENVABT-SE)" and have the numbering ENVA 0–ENVA 8.

The Base Rack can be equipped with ACTM. The ACTM supports 48 additional ENVAs,numbered ENVA 9–ENVA 56, and 8 Operator Commands (not supported by SW ofBR5.5). The installation of ACTM is optional. If no ACTM is installed in the Base Rack,16 Alarms are available.

The ENVAs 0–6 and ENVA 8 are connected to the DC Panel (described in IMN:BTSEBS-240) and should be named as in the table below.

1.3.4 DC Connector for Network Termination (NT)

The power supply (–48 V, max. 1A) at the SubD9 connector is free for operator use.

1.4 Visual Inspection of BTSE Modules

1.4.1 STAR/LOOP/MULTIDROP/CROSS CONNECT Connection

The following figure shows four possible Abis configurations to connect the BTS to theBSC. These configurations are called Star (single), Loop (several in circle), Multidrop(several), and Cross Connect.

In case of a STAR link, only PCM1 must be wired. For LOOP and MULTIDROP links,PCM one and two are necessary.

For pinning see IMN:BTSE chapter “Abis-Interface–PCM Link Terminal”.

ENVA Name Connector on DC Panel

0 FAN 6 FAN 6 (not used for BS-240XL/ 240XL II)

1 FAN 7 FAN 7 (not used for BS-240XL/ 240XL II)

2 free configurable

3 Shelter in service SIS

4 Smoke (not valid) SMOKE

5 Battery Breaker 0,1,2 BB 0–2

6 Over Voltage Protection

7 can be defined by operator

8 Microwave MW 1–9

Tab. 1.17 Settings for ENVA

28 A30808-X3247-K356-4-7630



For the settings of Abis Interface to match 120 Ohm, 100 Ohm or 75 Ohm line imped-ance, see chapters 1.4.6.4 "Switch Setting on COBA" and 1.4.6.5 "Switch Setting onCOSA".

Fig. 1.6 Star/Loop/Multidrop/Cross Connect Configuration

1.4.2 Antenna Connection

Check the connection of TX and RX coax jumper cables.

1.4.2.1 TX Antenna ConnectionThe TX antenna coax jumper cable must be directly connected to the 7/16" FICOM/ DU-AMCO antenna connector (Tab. 1.18).

Multidrop Cross Connect

BSC

BTSE 2BTSE 1 BTSE 3

Star Loop

BSC

BTSE 2BTSE 1 BTSE 3

BSC

BTSE 2BTSE 1 BTSE 3

BTSE 1BSC

BTSE 3BTSE 2 BTSE 4

A30808-X3247-K356-4-7630 29



1.4.2.2 RX Antenna ConnectionThe RX antennas are connected via a jumper cable to the inputs N_female on the DI-AMCO and 7/16" on the DUAMCO. For diversity use, the DUAMCO/DIAMCO must beconnected to two antennas.

DUAMCO uses the same jumper cable for TX and RX path. The DIAMCO is connectedvia jumper cable (Tab. 1.18).

1.4.2.3 Tower Mounted Amplifier (TMA) ConnectionIf an antenna is present, check for correct RF cabling connections of TMA. The DUAM-CO/DIAMCO supply the DC power for TMA at their antenna ports via the RF coax cable.

Fig. 1.7 TMA

1.4.3 RF System Cabling

There are several RF boards interconnected with RF-cables.Check whether the corresponding Carrier Units (CU modules) are connected to theirbranching equipment FICOM, DUAMCO, DIAMCO.

Handle with extreme care when connecting/changing modules!

AntennaConnection

BTSEConnection

30 A30808-X3247-K356-4-7630



Connection Type of cable Connectors

HPDU–ACOM Jumper 1/2" 7/16male–7/16male

HPDU–DIAMCO 1.41 semi-rigid aluor flexicable

SMAmale–Nmale

DUBIAS–TMA coax flexible 7/16female–7/16male

DUBIAS–HPDU (TX path) coax flexible 7/16male–7/16male

DUBIAS–HPDU (RX out) coax flexible SMAmale–SMAmale

DUBIAS–DIAMCO (RX path) coax flexible SMAmale–Nmale

DIAMCO–TMA coax flexible Nmale–7/16male

DIAMCO–DIAMCO coax flexible SMAmale–Nmale

DIAMCO–DUAMCO coax flexible SMAmale–7/16male

DUAMCO–DIAMCO coax flexible SMAmale–Nmale

DIAMCO–CU (RX path) 0.86 semi-rigid aluor flexicable

SMCmale–SMCmale

DUAMCO–CU (RX path) 0.86 semi-rigid aluor flexicable

SMCmale–SMCmale

DUAMCO–CU (TX path) 1.41 semi-rigid aluor flexicable

SMAmale–SMAmale

FICOM–CU (TX path) 1.41 semi-rigid aluor flexicable

SMAmale–SMAmale

LMU–DUAMCO (Test out) 0.86 semi-rigid aluor flexicable

SMAmale–SMAmale

Tab. 1.18 RF Cabling

A30808-X3247-K356-4-7630 31



Fig. 1.8 RF System Cabling CU–DUAMCO (Example)

TX

RX

RX Diversity

DUAMCO 4:2 (FOREM)CU

32 A30808-X3247-K356-4-7630



Fig. 1.9 RF System cabling CU - FICOM and DIAMCO - CU (example)

1.4.4 Antenna Combining

The DUAMCO/FICOM must be installed in the ACOM slots. To achieve short cablingbetween CU and ACOM, the ACOM slots are assigned to definite CU slots.

1.4.4.1 DUAMCOThe DUAMCO 2:2,4:2 occupy one ACOM slot each and are installed in the assigned slotfor the CU that must be combined.The DUAMCO 8:2 occupies two ACOM slots and is installed either on the left or on theright two slots.

All unused RX and RXCA connectors must be terminated with a 50 Ω load when the cor-responding antenna port of the DUAMCO is connected to an antenna or cascading out-put of DUAMCO/DIAMCO.

The open TX inputs of DUAMCO do not need to be terminated in normal operation.

AntennaConnection

FICOM (Kathrein)Base module

CU DIAMCO

A30808-X3247-K356-4-7630 33



1.4.4.2 FICOM

Usage of FICOM Modules of Different Suppliers

The FICOM modules (e.g., FIPLUB2RV3, FIPLUB2RV4, FIPLUX2RV3, FIPLUX2RV4)will be produced by different manufacturers.This is indicated by the variants –V3 and –V4.

Installation of FICOM Modules

For each cell, one FICOM plus base module (FIPLUB) must be installed. To combinemore than 2 carriers, the base module can be expanded by the FICOM plus expansionmodule (FIPLUX). The expansion can be done to one side only per base module.

Expansion of FICOM can be only done inside each rack. To combine more than 8 car-riers, a base module must be installed in the extension rack

!One Base Module can be expanded by 3 Expansion Modules, all modules in this com-bination must have the same variant.

iOpen expansion connectors RF EXP of FICOM modules must be terminated with theTerminator delivered with the FICOM base module.

!It is suggested to fix the jumper cable very carefully, do not torque too strong. The cableshould not move. Otherwise the cable’s inner conductor will tear.

34 A30808-X3247-K356-4-7630



Fig. 1.10 FICOM Modules for 8 Carriers in 1-Cell Configuration

Mounting Location

Cell 0

Slot/ FICOMNumber 0 1 2 3

Base Expansion Expansion Expansion

ANTOUT

TESTOUT

RF EXP RF EXP RF EXP RF EXP

TX0 TX1 TX0 TX1 TX0 TX1 TX0 TX1

A30808-X3247-K356-4-7630 35



Fig. 1.11 FICOM Modules in 2-Cell Configuration

The mounting location of the FICOM modules depends on the Cell configuration and an-tenna combining.

It is possible to have a mixed installation of DUAMCO and FICOM modules, within oneRack/Shelter.

1.4.5 Antenna Multicoupling

Multicoupling can be done by DIAMCO or DUAMCO. Each DIAMCO/DUAMCO candrive as much CUs as RX output connectors are available.

1.4.5.1 DIAMCOAll unused RX and RXCA connectors must be terminated with a 50 Ω load when the cor-responding antenna port of the DIAMCO is connected to an antenna or cascading out-put of DUAMCO/DIAMCO.

Cell 1Cell 0

Base free Expansion Base

Mounting LocationSlot/ FICOMNumber 0 1 2 3

ANTOUT

TESTOUT

RF EXP

TX0 TX1

ANTOUT

TESTOUT

RF EXP

TX0 TX1 TX0 TX1

RF EXP

36 A30808-X3247-K356-4-7630



Fig. 1.12 DIAMCO Antenna Connection and DIP Switches

At the DIP Switch, the input level of the DIAMCO/DUAMCO must be set. Switch 1 mustbe set on if there is a TMA installed. If there is no TMA installed, switch 1 must be set off.

Antenna Connector

1

2

3

4

iThe setting of switches 2–4 regulates the attenuation at the DIAMCO/DUAMCO.The total attenuation of cable (between TMA and DIAMCO/DUAMCO) and Dip Switchmust be 6dB.

Function Switch1

Switch2

Switch3

Switch4

TMA off / AMCO mode off X X X

TMA on / MUCO mode on X X X

attenuator LNA 0 dB off X X X

attenuator LNA 0 dB on off off off

attenuator LNA 1 dB on on off off

attenuator LNA 2 dB on off on off

Tab. 1.19 Switch Setting for DIAMCO/DUAMCO

A30808-X3247-K356-4-7630 37



"X": any position allowed

Fig. 1.13 View of DIP Switch (factory setting)

attenuator LNA 3 dB on on on off

attenuator LNA 4 dB on off off on

attenuator LNA 5 dB on on off on

attenuator LNA 6 dB on off on on

attenuator LNA 7 dB on on on on

factory setting off off off off

iSwitch 1 does not work when a TMA Alarm is present.

Function Switch1

Switch2

Switch3

Switch4

Tab. 1.19 Switch Setting for DIAMCO/DUAMCO

1 2 3 4

off off off off

38 A30808-X3247-K356-4-7630



1.4.5.2 DUAMCO

Fig. 1.14 DUAMCO DIP Switch and Antenna Connection

The switch setting for DUAMCO is the same as for DIAMCO, described in Tab. 1.19.

1.4.5.3 HPDUThe High Power Duplexer is an RF module with the requirement to save antennas in theTX path. For FICOM use, two antennas per cell are necessary for RX diversity and oneantenna is necessary for TX.

The main functions of HPDU is combining RX and TX signal. In the TX path, the HPDUis filtering the TX signals coming from the shelter and feeding them to the TX/RX anten-na. In the RX path, the function is filtering the incoming signal.

The HPDU is placed between antenna and FICOM/DIAMCO. The cabling is describedin Tab. 1.18.

1.4.5.4 Cascading MulticouplersFor supplying more receiver inputs, the multicoupler can be cascaded to save antennasin the RX path. Cascading can be done twice, the possible configurations are shown inTab. 1.20.

1 2 3 4

DIP Switch(hide behind plade)

Antenna Connector

Test out (for LMU connection)

A30808-X3247-K356-4-7630 39



The chain goes from the antenna to the BTSE, so the first device is the one nearest tothe antenna. The Parameter LNAPRED must be set if there is a TMA installed to activatethe TMA. If there is no TMA, LNAPRED must be set only for the 1. and 2. Cascade.

1.4.6 Adjustable Modules

There are several modules containing adjustable devices. Check the default states orspecial project settings. The software image SWI is only adjustable via LMT.

The following table gives an overview:

1.4.6.1 Boot Software (FW)Some modules contain special on board boot software on EPROMs.

First Device 1. Cascade 2. Cascade

DIAMCO DIAMCO

DIAMCO DIAMCO DIAMCO

DUAMCO DIAMCO

DUAMCO DUAMCO

TMA–DIAMCO DIAMCO

TMA–DIAMCO DIAMCO DIAMCO

TMA–DUAMCO DIAMCO

TMA–DUAMCO DUAMCO

If the cascaded element is a DUAMCO, a special cable must be used with an SMAconnector at one end and a 7/16 connector at the other end. (This cable is not avail-able as part of the system cabling).

Tab. 1.20 Cascading of Multicouplers

iThe first device in the chain must be switched into the high amplifying AMCO mode, thecascaded devices into MUCO mode.For TMA installed, all other devices have to be set in MUCO mode.

No MODULE see

1 ACT Fig. 1.15

2 COBA Fig. 1.16

3 COSA Fig. 1.19

4 DCBCTRL Fig. 1.21

5 DIAMCO Tab. 1.19

6 DUAMCO Tab. 1.19

Tab. 1.21 Adjustable Modules

40 A30808-X3247-K356-4-7630



The allocation of the EPROMs is listed in the Release Note. The new boot software canbe downloaded via LMT.

1.4.6.2 Software Images SWISome modules receive the SWI via the LMT.

1.4.6.3 Switch Setting on ACTOn the ACT, the rack address must be set. The switches 1–3 are used to set the rackaddress. For the Base Rack, the Extension Rack 0, and the Service Rack 0, the rackaddress setting is done in the factory.Base = 0; Ext. = 1; Service1 = 3; Service2 = 4Thus only for Extension Rack 1 and Service 2 Racks > 4 a setting on site is required.Switch 4 enables (on) or disables (off) the watchdog function.

Fig. 1.15 View of DIP Switch (factory setting)

Module Board FILE NAME

COBA COBA2P8V2 btbbcx01. swi

CU CUxxx btbbix01. swi

Tab. 1.22 Boot Software

OBJECT FILE NAME

SWL hsxxxxxx. swl

depending on variant of ciphering

VAM vsxxxxxx. vam

depending on variant of ciphering

COBA BTSBCX01. SWI

CU BTSBIX01. SWI

Tab. 1.23 Software Images SWI

1 2 3 4

ON

Racktype Rackno. Switch 1 Switch 2 Switch 3 Switch 4

Base Rack 0 off off off on

Tab. 1.24 Switch Setting on ACT

A30808-X3247-K356-4-7630 41



1.4.6.4 Switch Setting on COBAThe COBA contains three transceiver submodules for 75 Ω, 100 Ω, or 120 Ω impedancematching.

Extension Rack 0 1 on off off on

Extension Rack 1(not BS-240XL/ 240XL II)

2 off on off on

Service Rack 0 3 on on off on

Service Rack 1 4 off off on on

Service Rack 2 5 on off on on

Service Rack 3 6 off on on on

Service Rack 4 7 on on on on

Racktype Rackno. Switch 1 Switch 2 Switch 3 Switch 4

Tab. 1.24 Switch Setting on ACT

42 A30808-X3247-K356-4-7630



Fig. 1.16 COBA

Port 1

S1

Port 2

S2

External ClockSynchronization

Impedance Switch 1 Switch 2 Switch 3 Switch 4 Switch 5 Switch 6PCM30 120 Ohms off off off off off offPCM30 75 Ohms on on on off off offPCM24 100 Ohms off off off on on on

A30808-X3247-K356-4-7630 43



Fig. 1.17 Switch Settings of Port 1 and Port 2

Fig. 1.18 External Clock Synchronization

ON

1 4 5 632

ON

1 4 5 632

ON

1 4 5 632

PCM30 120 Ohms PCM30 75 Ohms PCM24 100 Ohms

Impedance Switch 1 Switch 2 Switch 3 Switch 4 Switch 5 Switch 675 Ohms on off off on on on100 Ohms off on off off on on120 Ohms off off on off on onhigh (TTL)f=< 2 MHz

off off off on off off

high (TTL)f=> 2 MHz

off off off on on on

ON

ON

ON

ON

ON

1 4 5 632

1 4 5 632

1 4 5 632

1 4 5 632

1 4 5 632

75 Ohms

120 Ohms

100 Ohms

TTL f>=2MHz

TTL f<=2MHz

44 A30808-X3247-K356-4-7630



1.4.6.5 Switch Setting on COSA

Fig. 1.19 COSA

Port 5

S5

Port 6

S6

Port 4

S4

Port 3

S3

Port 2

S2

Port 1

S1

A30808-X3247-K356-4-7630 45



Fig. 1.20 Switch Settings of Port 1 to Port 6

Impedance Switch 1 Switch 2 Switch 3 Switch 4 Switch 5 Switch 6PCM30 120 Ohms off off off off off offPCM30 75 Ohms on on on off off offPCM24 100 Ohms off off off on on on

ON

1 4 5 632

ON

1 4 5 632

ON

1 4 5 632

PCM30 120 Ohms PCM30 75 Ohms PCM24 100 Ohms

46 A30808-X3247-K356-4-7630



1.4.6.6 Switch Settings on DCBCTRL

Fig. 1.21 DIP Switches for Battery Manufacturer, Battery Capacities and Slot-ID

Battery Manufacturer

Select a proper characteristic curve for battery charging.

Selectable Battery Capacities

Selectable Slot-ID

Selectable Battery Manufacturer

A30808-X3247-K356-4-7630 47



Fig. 1.22 Battery Manufacturer DIP Switch

Battery Capacity

Selectable battery capacities: 0 Ah (no battery), 5 Ah, 10 Ah,...1275 Ah.

The battery capacities can be set with two 8 bit DIP switches, one for each battery block;1 LSB = 5Ah. The setting is calculated by adding all values where the contacts of theDIP switch are set to "ON".

Fig. 1.23 Battery Capacity DIP Switch

Slot-ID

Selectable Slot-ID: The CAN-Bus address can be set with a 2 bit DIP switch in order todistinguish between different AC/DC frames mounted to one rack.

Manufacturer Bit 0 Bit 1

Oerlikon on not used

Sonnenschein off not used

Tab. 1.25 Battery Manufacturer

ONBatt

TypeBit 1

Bit 0

ON640 Ah

320 Ah

160 Ah

80 Ah

40 Ah

20 Ah

10 Ah

5 Ah

iThe state of the object “BATTERY” does not depend on the existence of a real battery.It depends on the “Battery Capacity” DIP switch settings on the DCBCTRL module. Ifone of these two DIP switches is set to a value different from “0 Ah”, the respective HMO“BATTERY” goes to “enabled”.

48 A30808-X3247-K356-4-7630



Fig. 1.24 DCBCTRL Slot-ID DIP Switch

1.5 Preparation for Offline Tests

The purpose of this chapter is to execute all commissioning activities for checking thedelivery quality and quantity of the BTSE on site.

The following steps must be executed to start the system:(refer to the relevant procedures)

1. Obtain the recommended tests and test equipment

2. Preparation of tests and test equipment

3. BTSE power on

4.Start of LMT

5. SW load

6. SW activation

7. Set RACK

8. Creation of HW related MO

9. Create BPORT

Address Bit 0 Bit 1

ACDCP0 on off

ACDCP1 off on

Tab. 1.26 Slot-ID

ONSlot-ID Bit 1

Bit 0

iBoth switches must be in different positions.

A30808-X3247-K356-4-7630 49



10. Create Xconnect

11. Set attributes for BTSE

12. Backup generation

13. BTSE phase 3

14. Offline tests

Finally, all documents must be filled in and all activities must be confirmed by the cus-tomer.

1.5.1 Recommended Test Equipment and Tools

Several devices, instruments, accessories, and utensils must beprovided and prepared for commissioning on site.

1.5.1.1 Test EquipmentThe equipment, especially the available options change quickly. Therefore, the listedequipment may not be currently available. It is suggested that the equipment listed be-low or equivalent must be present for call simulation and verification of correct operation.

SBS Abis Simulator

Local Maintenance Terminal LMT

For detailed requirements, refer to manual OGL:LMT.

Spectrum Analyzer with GSM Measuring Functions

– HW:– Portable PC min. Pentium II, 128 MByte RAM– 500 MByte HD– Mouse– 2x serial interfaces– 1x parallel interface, 1hour Battery Time– 8631PCMCIA Card

– SW: Abis simulation applicationWin 98/2000

– Cable: 2x RJ45 --> open ends for PCMCIA <-> OVPT (ABIS)

– HW:– for example: HP8594A/E– Option: 004/010/021/101/102/105

– SW:– GSM: HP 85715B Personality Card– DCS: HP 85722B Personality Card

50 A30808-X3247-K356-4-7630



MS_BS RF Coupling BOX

RF Termination

Depending on the BTSE and the equipped modules, some RF terminations must bepresent.

Mobile Station MS

Multimeter

LMU

– PCS: Option 20 for HP 85722B Personality Card– Cable:

– RF cables with N–N connectors– RF cables with N–SMA connectors– RF cables with SMC–SMA connectors

– Adapter:– N_male–SMA_female– 7/16"_male–N_female

– HW:– MS Box– Coupling-Box

– Cable:– BNC_male–BNC_male (MS)– 3x:7/16_male–N_male (RX/TX)

– Adapter:– 7/16_male–N_male

– Tool:– Absorber 20dB/50Watt– 50 Ω Termination N_male

– TX:– 50 Ω SMA (DUAMCO,FICOM)

– RX:– 50 Ω SMC (DIAMCO,DUAMCO)

– RXCA:– 50 Ω SMA (DIAMCO cascading output)

– HW:– mobile phone, e.g., S25– C25– PCS mobile phone, e.g., S40– Test Plug-In SIM

– HW:– SIEMENS Multimeter

– Cable:– Installation Utility Cable

A30808-X3247-K356-4-7630 51



1.5.1.2 ToolsSpecial tools for commissioning activities on site are listed below.

Antistatic Set

for ESD Module Handling

SMA Tool

with torque wrench for semi-rigid/flexi Cable Connectors

SMC Tool

with torque wrench for semi-rigid/flexi Cable Connectors

Semi-Rigid Bending Tool

for semi-rigid cable connection

TDMA Measuring Tools (Tests with HP 8594A/E) and Trigger Adapter

1.5.2 Preparation and Presetting of Test Equipment

1.5.2.1 Test EquipmentFor minimum test time and correct test results, the devices must be prepared on site.

Spectrum Analyzer

– HW:– PCS: HP 8594 Personality Card– 2 Measuring cables with BNC-Plugs male (sufficient length)– Adapter SMA male–BNC female– Trigger Adapter TAD-L S30861-U2003-X-*

(100-pins AMP-Plug with 4 x BNC-Plug female– 1 Adapter N-Connector male–BNC female– HP 8590 series spectrum analyzer operating manual– User´s Guide HP85715B GSM900 Transmitter Measurement Personality– User´s Guide HP 85722B DCS1800 Transmitter Measurement Personality

– HW: The HP8594A/E needs a warm-up time of 20 minutes depending on theavailable options.The display shows "OVEN COLD" during the heating phase. Afterwards a CAL-IBRATION must be carried out for defined measurement execution (Removetrigger signal from "Gate Trigger Input" while performing calibration).

– SW: The SW of the GSM/DCS card must be installed in advance.– Cable: For special tests, e.g., "Power versus Time", a BNC loop at the

backplane must be provided:GATE-OUTPUT (TTL) to EXTERN TRIGGER INPUTThe cable from T-Frame (TAD-L) to GATE-INPUT (TTL)for TDMA-FRAME Trigger must be connected.

See the analyzer operating manual for more detailed information.

52 A30808-X3247-K356-4-7630



RF Termination

1.5.2.2 Software (SW)For all tests, only released SW (corresponding to the BTSE HW/SW release) is allowedto be running on the test equipment (TE).

1.5.2.3 Boot Software/Firmware (SW/FW)For all tests, only the released SW is allowed to be running on the BTSE correspondingto the BTSE HW/SW/FW release/revision.

1.5.3 BTSE Power ON

1.5.3.1 BreakersDepending on the configuration of equipped modules, only the corresponding breakersmust be switched on. For the Base Rack see Tab. 1.3 or Tab. 1.7, for the ExtensionRack see Tab. 1.4 or Tab. 1.8.

All other breakers are switched off.

1.5.3.2 LED IndicationThe following LED description is only valid for the software installation.

The modules have the normal LED indication set as shown below for normal operation.

1. DIAMCO

– HW: Before RF measurements are executed, the following connectors must beterminated with 50 Ohm SMA/SMC resistors:– TX: open FICOM/DUAMCO inputs (SMA)– RX: open DUAMCO/DIAMCO outputs (SMC)– RXCA: open DUAMCO/DIAMCO outputs (SMA)– TESTOUT: open DUAMCO/FICOM outputs (SMA)

iIn case of supervising all breakers with one common alarm sensor, all breakers mustbe switched on, independent of the configuration.

R redG greenfl(R) flashing redfl(G) flashing greeno off

OK o o ALOK G o RS

A30808-X3247-K356-4-7630 53



2. FICOM

3. DUAMCO

4. CU

5. COBA

6. COSA

7. ACT

Forem FICOM (base module)TNF ALM o o TNF ALM

G DC ONVSWR o o RESET

Forem FICOM (expansion module)TNF ALM o o TNF ALM

G DC ONo RESET

Kathrein FICOM (base module)VSWR ALM o o TNF ALM 0DC ON G o TNF ALM 1RESET o

Kathrein FICOM (expansion module)o TNF ALM 0

DC ON G o TNF ALM 1

TMA 0 o o TMA 1RESET o o o RESET 1VSWR 0 o o VSWR 1POWER 0 G G POWER 1

OK fl(G) o SWRES o R PA

ACT fl(G) fl(R) RCOBAFLOC o o HMOABIS 1 o o ABIS 2

ACT fl(G) fl(R) RCOSAABIS 7 o o ABIS 8ABIS 5 o o ABIS 6ABIS 3 o o ABIS 4

To be activated by SW o o Reset of mC

54 A30808-X3247-K356-4-7630



2 Task List

2.1 SW Download and ActivationThe SW must be downloaded from the LMT to the BTSE . . . . . . . . . . . . . . . . . . . . . (see 3.1)

2.2 RackThe Racktype must be defined . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (see 3.2)

2.3 Creation of HW Related Managed ObjectsEach HW related managed object must be created separately. . . . . . . . . . . . . . . . . (see 3.3)

2.4 Setting Attributes for BTSEThe attributes for the BTSE must be set . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (see 3.17)

2.5 BPORTThe PCM line configurations must be determined . . . . . . . . . . . . . . . . . . . . . . . . . . . (see 3.18)

2.6 XConnectThe Cross Connect must be defined . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (see 3.19)

2.7 BTSMSettings for the Abis must be set . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (see 3.20)

2.8 LAPDLEEnter values for LAPD Channel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (see 3.21)

2.9 CORE RedundancyEnable the CORE Redundancy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (see 3.22)

2.10 Checking the State of all ModulesCheck the state of all modules. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (see 3.23)

2.11 Changing the BTSE to phase 3Change the BTSE from phase 2 to 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (see 3.28)

2.12 Execution of Offline TestsCarry out the offline test. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . (see 3.29)

A30808-X3247-K356-4-7630 55



3 Procedures

56 A30808-X3247-K356-4-7630



A30808-X3247-K356-4-7630 57



3.1 SW Download and Activation

1 Reset of Core Basis COBA

Switch off the right pair of CORE modules (COBA and COSA) with the breakerconcerned on the DC-Panel.

Reset the left COBA with the push button on the board.

After about 15 seconds, the COBA reaches the start connection status.

2 Connect LMT Cable

Connect the LMT cable to the LMT 15-pin SUB-D connector on the DC-Panel.

3 Start of LMT Program

b StartProgramsLMT xxxxx (String of Version)Start LMT

The “LMT DashBoard” opens (title bar named “LMT Control Center”).Detailed explanation for using the Dash Board is given in the OGL:LMT.

iA directory for the software to be downloaded must be present on the harddisk of theLMT containing all files of the relevant software load.The V.11/X.21 interface (HDLC-Adapter, DLHC) has been installed and tested in ad-vance.

LED indication of COBA:

ACT fl(G) R RCOBA

FLOC o(R) o(R) HMO

ABIS 1 o(R) o(R) ABIS 2

58 A30808-X3247-K356-4-7630



4 Start Connection to the BTSE

b Click on the “StartNet” button.

The “Session Starter” window opens.(“Start new Session” is pre-selected.)

b Click on the “OK” button.

The “Logon” button in the “MCDA” window is activated.

b Click on the “Logon” button.

The “Logon Request” window opens.

b Enter UserID: <user>.Enter Password: <password>.Click on the “Connect” button.Click on "Close".

The Logon Request window is closed.

5 System Response

Several CHANGED STATE EVENT REPORTs will follow. They can be examinedin the “LMT Message Browser” window.

The BTSE is now in phase 1.

6 Start Input Handler

The Input Handler is already open; if not:

b Click on the “Input Hdl” button.

The “Input Handler” window opens.

Logon request:NAME=BTSE;

<date> <time> Command

============================================

JOB: <no>

PC Time&Date = <time> <date>

NE Time&Date = <time> <date>

USER NAME: <user>

COMMAND: Logon request:NAME=BTSE;

SW RELEASE: = <no>

COMMAND RESULT: OPERATION COMPLETED

ACK

END OF OUTPUT FOR JOB <no>

A30808-X3247-K356-4-7630 59



7 SW Download

b MANAGED-ELEMENTSOFTWARE-MANAGEMENTDNLALLEXESRCPATH=<path where the SW Load is stored on the LMT and filename e.g.,:HS010808.SWL>OVERWRITE=yes

DNLALLEXE: SRCPATH="<path>\ hs010808.swl", OVERWRITE=YES;

8 System Response

For the downloading of each file:

Several messages of the structure shown below will follow. They provide infor-mation on the progress and the end of the download for each file:

JOB: <no>

PC Time&Date: <date> <time>

COMMAND:

DNLALLEXE:SRCPATH=<path><file name>,OVERWRITE=YES;


Downloading File: <file name>:01-01-14-01-06-00_01-12-19

Version: 01-04-14-01-09-00_01-12-20


JOB: <no>


COMMAND:

DNLALLEXE:SRCPATH=<path>\<file name>,OVERWRITE=YES;


Downloading File <file name>:

xx% of packets transferred


60 A30808-X3247-K356-4-7630



It is possible that the LMT performs an automatic logoff after a few minutes. Ifthe session is closed, please log on again.

9 SW Activation

b MANAGED-ELEMENTBSS-FUNCTIONALBTSMACTIVATE BTSMNAME=BTSM:0FILEID=<enter header according to the SW Load e.g.: HS010808.SWL>FILESWV=<enter file version string e.g.: 01-01-08-00-08-00_98-08-21

ACTIVATE BTSM:NAME=BTSM:0,FILEID="hs010808.swl",FILESWV="01-01-08-00-08-00_98-08-21"

10 System Response

JOB: <no>


COMMAND:

DNLALLEXE:SRCPATH=<path>\<file name>,OVERWRITE=YES;


Download End: File BTSBIX01.SWI Transfer Completed


ACTIVATE BTSM:NAME=BTSM:0;FILEID="hs010808.swl",FILESWV="01-01-08-00-08-00_98-08-21";


============================================

JOB: <no>



USER NAME: <user>

COMMAND: ACTIVATE BTSM:NAME=BTSM:0;FILEID="hs010808.swl",FILESWV="01-01-08-00-08-00_98-08-21";

SW RELEASE: = <no>


Activate BTSM SW ACK:

A30808-X3247-K356-4-7630 61



The session is now closed.

11 Login

b Click on the “Logon” button.

The Session Starter window opens.(Start new Session is pre-selected.)


The Logon Request window opens.

b Enter UserID: <user>.Enter Password: <password>.Click on the “Connect” button.

12 System Response

The BTSE is now in phase 2.

END

name = BTSM:0

fileId = "hs010808.swl"

fileSoftwareVersion = "01-01-08-00-08-00_98-08-21"


LED_Indication of COBA:

ACT fl(G) o(R) RCOBA

FLOC o(R) o(R) HMO


(Port 1) Logon Ack Received Response on BTS dated “date and time” (on Session xxx)

62 A30808-X3247-K356-4-7630



3.2 Rack

The first step of the creation of the HMO is the creation of the rack.

Only the Base Rack is automatically created, but the rack type must be set.The Extension/Service Rack must be created and the rack type must be set as well.

The rack numbering is described in the introduction (1.2.1).

1 Setting the Rack Type ......(see OGL:LMT)

The following action must be repeated for each rack of the BTSE.

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKSET RACKNAME=RACK:<no> (see below)TYPRACK=<Racktype>(see below)

Racktype: Choose the BTSE Type that must be installedBS-240 / 240 II / 240XL / 240XL II for Base Rack (no. 0) or Extension Rack (no.1/2) BS240SR/BS240XLSR for the Service Rack (no. 3 .. 7)

Set RACK:NAME=RACK:<no>,TYPRACK=BS240;

2 System Response

SET RACK:NAME=RACK:<no>,TYPRACK=BS240;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: SET RACK:NAME=RACK:<no>,TYPRACK=BS240;

SW RELEASE: = <no>


SET ATTRIBUTES ACK RACK:

name = RACK:0

typeOfBtse = BS240

A30808-X3247-K356-4-7630 63



The LED indicators do not change.

END


64 A30808-X3247-K356-4-7630



3.3 Hardware Related Managed Objects

1 Overview of Hardware Related Managed Objects

For the BTSE, all types of HMOs must be created.The BTSEP, RACK:0 and COBA:0 is always provided automatically.

iThe rack must be set before the HMOs are created!

NO. MODULE RANGE

1. RACK 0...7

2. ACDCP 0...1

3. ACT 0

4. COBA 0...1

5. COSA 0...1

6. CU 0...11

7. DIDCTMA 0...7

8. DILNA 0...7

9. DUDCTMA 0...7

10. DULNA 0...7

11. DUVSWR 0...7

12. ENVABTSE 0...56

13. FANP 0...7

14. FTNFP 0...7

15. FVSWRP 0...3

16. TMA 0...15

17. LMU 0

Tab. 3.1 Hardware Related Managed Objects

A30808-X3247-K356-4-7630 65



Now proceed with the following creation procedures. h...Procedure: 3.4

END

To find the mounting position of the HMOs and modules, refer to the MMN:BTSE BS-240 / 240 II / 240XL/ 240XL II:

BS-240 Base Rack BS-240 Extension Rack BS-240 Service 1 Rack BS-240 Service 2 Rack

BS-240XL Base Rack BS-240XL Extension Rack BS-240XL Service 1 Rack BS-240XL Service 2 Rack

66 A30808-X3247-K356-4-7630



3.4 ACDCP

ACDCP can only be installed in the Service1 Rack.The Managed Object ACDCP is realized in the DCBCTRL module.

1 ACDCP Creation ......(see OGL:LMT)

The following action must be repeated for all equipped modules.

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKACDCPCREATE ACDCPNAME=RACK:<no>/ACDCP:<no>

For the Service 1 Rack, the rack number is 3.

CREATE ACDCP:NAME=RACK:<no>/ACDCP:<no>

2 System Response

CREATE ACDCP:NAME=RACK:<no>/ACDCP:<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE ACDCP:NAME=RACK:<no>/ACDCP:<no>;

SW RELEASE: = <no>


CREATE ACDCP ACK:

name = RACK:<no>/ACDCP:<no>

A30808-X3247-K356-4-7630 67




Administrative State = UNLOCKEDOperational State = ENABLEDAvailability Status = NULL_valueAlarm Status = cleared


END


68 A30808-X3247-K356-4-7630



3.5 ACT

Different ACTs (1.3.3) can be installed in the rack types. To activate the Alarm CollectionTerminal, the HMO ACT must be created in each Extension/Service Rack.

In the Base Rack, the ACT must only be created, if an ACTM is installed!

1 ACT Creation ......(see OGL:LMT)

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKACTCREATE ACTNAME=RACK:<no>/ACT:<no>

Check the correct rack numbering. ......(see 1.2.1)

CREATE ACT:NAME=RACK:<no>/ACT:<no>;

2 System Response

iSet the correct Rack address for each rack as described in Tab. 1.24.

CREATE ACT:NAME=RACK:<no>/ACT:<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE ACT:NAME=RACK:<no>/ACT:<no>;

SW RELEASE: = <no>


CREATE ACT ACK:

name = RACK:<no>/ACT:<no>

A30808-X3247-K356-4-7630 69





END


70 A30808-X3247-K356-4-7630



3.6 Battery

The battery can be installed in the Service1 Rack and/or Service2 Rack.

1 Battery Creation ......(see OGL:LMT)

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKBATTERYCREATE BATTERYNAME=RACK:<no>/BATTERY:<no>

Check the correct rack numbering. ......(see 1.2.1)

CREATE BATTERY:NAME=RACK:<no>/BATTERY:<no>;

2 System Response

CREATE BATTERY:NAME=RACK:<no>/BATTERY:<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE BATTERY:NAME=RACK:<no>/BATTERY:<no>;

SW RELEASE: = <no>


CREATE BATTERY ACK:

name = RACK:<no>/BATTERY:<no>

A30808-X3247-K356-4-7630 71





END


72 A30808-X3247-K356-4-7630



3.7 COSA

The COSA must be created to use more than two PCM lines or more than 8 CUs, alsofor using the cross connect function. For a BS-240 / 240 II / 240XL / 240XL II, there canbe 8 PCM lines connected. PCM line 1 and 2 are supplied by COBA. For the PCM lines3–8, the COSA must be installed.

1 COSA Creation ......(see OGL:LMT)

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKCOSACREATE COSANAME=RACK:<no>/COSA:<no>

The COSA can only be installed in the Base Rack. The rack number is 0.

CREATE COSA:NAME=RACK:<no>/COSA:<no>;

2 System Response

iIn case of core redundancy, two COSAs must be created.Repeat this procedure two times for COSA 0 and COSA 1.

CREATE COSA:NAME=RACK:<no>/COSA:<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE COSA:NAME=RACK:<no>/COSA:<no>;

SW RELEASE: = <no>


CREATE COSA ACK:

name = RACK:<no>/COSA:<no>

A30808-X3247-K356-4-7630 73





END


74 A30808-X3247-K356-4-7630



3.8 CU

The Base Rack and the Expansion Racks can be equipped with 8 CUs each (12 CUs inBS-240XL / 240XL II). For more than 8 CUs per BS-240 / 240 II / 240XL / 240XL II, themodule COSA must be created.

The module CU may also be an EDGE CU (ECU)! It is possible to mix the CU and ECU.

1 CU Creation ......(see OGL:LMT)


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKCUCREATE CUNAME=RACK:<no>/CU:<no>RXLEVADJ adjust_value=<no> adjust_div_value=<no> (see below)TXLEVADJ adjust_value=<no> (see below)

Check the correct rack number. ......(see 1.2.1)

The parameter RXLEVADJ must be set in case of different cable length in theRX path. Default value for adjust_val = 0, adjust_div_value = 0Adjustable values are:adjust_value -> -24.0 ... 24.0 in steps of 1.0adjust_div_value -> -24.0 ... 24.0 in steps of 1.0

TXLEVADJ:Adjustable values are:TXLEVADJ: -63.0 ... 63.0 in steps of 1.0.The following formula is used to determine this value:TXLEVADJ = attenuation factor of the used combiner + attenuation factor of RFcable - amplification factor of the used booster

Note: use values without minus/plus sign for the formula!

Example:Combiner: -1.5 dBCable: -0.5 dBBooster: +15 dB(1.5 dB) + (0.5 dB) - (15 dB) = -13 dB means TXLEVADJ=-13

See TED: BS-24x for typical attenuation factors in the TX path. ......(see TED: BS-24x)

Create CU:NAME=RACK:0/CU:0,RXLEVADJ=0-0,TXLEVADJ=0;

A30808-X3247-K356-4-7630 75



2 System Response



END

CREATE CU:NAME=RACK:<no>/CU:<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE CU:NAME=RACK:<no>/CU:<no>;

SW RELEASE: = <no>


CREATE CU ACK:

name = RACK:<no>/CU:<no>


The LED indication changes to

OK fl(G) o(G) SW

RES o(R) R PA

76 A30808-X3247-K356-4-7630



3.9 ECU

ECU is a Carrier Unit for the EDGE technology.For creation continue with procedure: h 3.8 "CU"

A30808-X3247-K356-4-7630 77



3.10 FAN

The racks can be equipped with 6 fans. During the creation of each fan, the alarm fordefect fan is generated automatically.

1 FANP Creation ...... (see OGL:LMT)


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKFANPCREATE FANPNAME=RACK:<no>/FANP:<no>

CREATE FANP:NAME=RACK:<no>/FANP:<no>;

2 System Response

CREATE FANP:NAME=RACK:<no>/FANP:<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE FANP:NAME=RACK:<no>/FANP:<no>;

SW RELEASE: = <no>


CREATE FANP ACK:

name = RACK:<no>/FANP:<no>

78 A30808-X3247-K356-4-7630





END


A30808-X3247-K356-4-7630 79



3.11 DIAMCO

If there is a TMA installed, the DIAMCO must be switched in MUCO mode, if there is noTMA, the DIAMCO must be switched in AMCO mode by setting the dip switches(Tab. 1.19).

In case of Cascading, the first device in the chain must be switched in AMCO mode, allother devices in MUCO mode (1.4.5.4).

iDILNA

DIDCTMA

This MOs of the DIAMCO supplies the RX path. There are two managedobjects of this type per module and they must be handled separately

There are two MO of this type per module and they must be handledseparately. The DIDCTMA offers the DC power supply for the TMA. Itmust be created only in the case of a TMA installation.

80 A30808-X3247-K356-4-7630



1 DILNA Creation ......(see OGL:LMT)


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKDILNACREATE DILNANAME=RACK:<no>/DILNA:<no>CELLNO=<no>COMBMD=<combiner mode> (see below)LNAPRED= (see below)PredType=<preswitched device>PredRack=RACK<no of Rack of preswitched device>PredNo=<no of preswitched device>WDLNA=<no of CU normal or diversity mode> (see below)

The combiner mode depends on the DIAMCO Type. DIAMCO 4:2 means that 2antennas can be connected and 4 RX out paths are available for each side ofthe DIAMCO.

All CUs connected to DILNA must be set as follows:CUxN = CU number x connected via the RX plug (normal RX path)CUxD = CU number x connected via the RXDIV (diversity RX path)

The LNAPRED must be activated in case of Cascading and TMA installed. Thedevice that is installed before must be chosen. ......(see 1.4.5.4)

CREATE DILNA:NAME=RACK:<no>/DILNA:<no>,CELLNO=<no>,COMB-MD=<combiner mode>,LNAPRED=DILNA(RACK<no>-DILNA<no>),WDL-NA=<no of CU normal or diversity mode>;

2 System Response

CREATE DILNA: NAME=RACK:<no>/DILNA:<no>, CELLNO=<no>, COMBMD=<combiner mode>,LNAPRED=DILNA(RACK<no>-DILNA>no>), WDLNA=<no of CU normal or diversity mode>;


============================================

JOB: <no>



USER NAME: <user>

A30808-X3247-K356-4-7630 81





Is a TMA installed? Y h...3N h...END

3 DIDCTMA Creation


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKDIDCTMACREATE DIDCTMANAME=RACK:<no>/DIDCTMA:<no>

...... (see OGL:LMT)

CREATE DIDCTMA:NAME=RACK:<no>/DIDCTMA:<no>;

4 System Response

COMMAND: CREATE DILNA: NAME=RACK:<no>/DILNA:<no>, CELLNO=<no>, COMBMD=<combin-er mode>, LNAPRED=DILNA(RACK<no>-DILNA<no>), WDLNA=<no of CU normal or diversity mode>;

SW RELEASE: = <no>


CREATE DILNA ACK:

name = RACK:<no>/DILNA:<no>

cellNumber=<no>

combmode=<combiner mode>

lnapred=DILNA(RACK<no>-DILNA<no>)

wiringDataLna=<no of CU normal or diversity mode>


CREATE DIDCTMA:NAME=RACK:<no>/DIDCTMA:<no>;


============================================

JOB: <no>

82 A30808-X3247-K356-4-7630





END



USER NAME: <user>

COMMAND: CREATE DIDCTMA:NAME=RACK:<no>/DIDCTMA:<no>;

SW RELEASE: = <no>


CREATE DIDCTMA ACK:

name = RACK:<no>/DIDCTMA:<no>


A30808-X3247-K356-4-7630 83



3.12 DUAMCO

If a TMA is installed, the DUAMCO must be switched in MUCO mode, if there is no TMA,the DUAMCO must be switched in AMCO mode by setting the dip switches (Tab. 1.19).

In case of Cascading, the first device in the chain must be switched in AMCO mode, allother devices must be switched in MUCO mode (1.4.5.4).

1 DUVSWR Creation ...... (see OGL:LMT)


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKDUVSWRCREATE DUVSWRNAME=RACK:<no>/DUVSWR:<no>CELLNO=<no>COMBMD=<combiner mode>WDDUVSWR=<no of CU>

The combiner mode depends on the DUAMCO type. DUAMCO 4:2 means that4 TX paths and 2 antennas can be connected.

CREATE DUVSWR:NAME=RACK:<no>/DUVSWR:<no>,CELLNO=<no>,COMBMD=<combiner mode> ,WDDUVSWR=<no of CU>;

2 System Response

iDUVSWR

DULNA

DUDCTMA

This HMO supplies the VSWR logic of the DUAMCO. Thereare two managed objects of this type per module. They mustbe handled separately.

This HMO supplies the TX path of the DUAMCO. There aretwo managed objects of this type per module. They must behandled separately.

This HMO offers the power supply for the TMA. The DUDCT-MA must be created only if a TMA is installed.

CREATE DUVSWR:NAME=RACK:<no>/DUVSWR:<no>;


============================================

JOB: <no>


84 A30808-X3247-K356-4-7630






USER NAME: <user>

COMMAND: CREATE DUVSWR:NAME=RACK:<no>/DUVSWR:<no>;

SW RELEASE: = <no>


CREATE DUVSWR ACK:

name = RACK:<no>/DUVSWR:<no>

cellNumber=<no>

combMode=<combiner mode>

wiringDuamcoVswr=<no of CU>


A30808-X3247-K356-4-7630 85



3 DULNA Creation ...... (see OGL:LMT)


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKDULNACREATE DULNANAME=RACK:<no>/DULNA:<no>CELLNO=<no>COMBMD=<combiner mode>LNAPRED=(see below)PredType=<preswitched device>PredRack=RACK<no of rack of preswitched device>PredNo=<no of preswitched device>WDLNA=<no of CU normal or diversity mode>(see below)

The combiner mode depends on the DUAMCO type. DUAMCO 4:2 means that2 antennas can be connected and 4 RX pathes are available for each side of theDUAMCO.

All CUs connected to DULNA must be set as follows:CUxN = CU number x connected via the RX plug (normal RX path).CUxD = CU number x connected via the RXDIV (diversity RX path).

The LNAPRED must be activated in case of Cascading and TMA installed. Thedevice that is installed before must be chosen. ...... (see 1.4.5.4)

CREATE DULNA:NAME=RACK:<no>/DULNA:<no>,CELLNO=<no>,COMB-MD=<combiner mode>,LNAPRED=DULNA(RACK<no>-DULNA<no>),WDL-NA=<no of CU normal or diversity mode>;

4 System Response

CREATE DULNA:NAME=RACK:<no>/DULNA:<no>,CELLNO=<no>,COMBMD=<combinermode>,LNAPRED=DULNA(RACK<no>-DULNA<no>),WDLNA=<no of CU normal or diversity mode>;


============================================

JOB: <no>



USER NAME: <user>

86 A30808-X3247-K356-4-7630





Is a TMA installed? Y h...5N h...END

5 DUDCTMA Creation ......(see OGL:LMT)


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKDUDCTMACREATE DUDCTMANAME=RACK:<no>/DUDCTMA:<no>

CREATE DUDCTMA:NAME=RACK:<no>/DUDCTMA:<no>;

6 System response

COMMAND: CREATE ULNA:NAME=RACK:<no>/DULNA:<no>,CELLNO=<no>,COMBMD=<combinermode>,LNAPRED=DULNA(RACK<no>-DULNA<no>),WDLNA=<no of CU normal or diversity mode>;

SW RELEASE: = <no>


CREATE DULNA ACK:

name = RACK:<no>/DULNA:<no>

cellNumber=<no>

combmode=<combiner mode>

lnapred=DULNA(RACK<no>-DULNA<no>)

wiringDataLna=<no of CU normal or diversity mode>


CREATE DUDCTMA:NAME=RACK:<no>/DUDCTMA:<no>;


============================================

JOB: <no>

A30808-X3247-K356-4-7630 87





END



USER NAME: <user>

COMMAND: CREATE DUDCTMA:NAME=RACK:<no>/DUDCTMA:<no>;

SW RELEASE: = <no>


CREATE DUDCTMA ACK:

name = RACK:<no>/DUDCTMA:<no>


88 A30808-X3247-K356-4-7630



3.13 FICOM

1 FVSWRP Creation ......(see OGL:LMT)


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKCREATE FVSWRPNAME=RACK:<no>/FVSWRP:<no>CELLNO=<no>

CREATE FVSWRP:NAME=RACK:<no>/FVSWRP:<no>,CELLNO=<no>;

2 System Response

iFVSWRP

FTNF

Is one of the two managed objects of the FICOM and existsonly once per basis module (not in expansion modules). ThisHMO supplies the VSWR logic of the FICOM.

There are two managed objects of this type per module andthey must be handled separately. This MO is the tunable nar-rowband filter.

CREATE FVSWRP:NAME=RACK:<no>/FVSWRP:<no>,CELLNO=<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE FVSWRP:NAME=RACK:<no>/FVSWRP:<no>,CELLNO=<no>;

SW RELEASE: = <no>


CREATE FVSWRP ACK:

name = RACK:<no>/FVSWRP:<no>

cellno=<no>

A30808-X3247-K356-4-7630 89





3 FTNFP Creation ...... (see OGL:LMT)


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKCREATE FTNFPNAME=RACK:<no>/FTNFP:<no>CELLNO=<no>WDTFNFP: CUWiring=CU<no>,FVSWRPWiring=FVSWRP<no>

CREATE FTNFP:NAME=RACK:<no>/FTNFP:<no>,CELLNO=<no>,WDFTN-FP=CU<no>-FVSWRP<no>;

4 System Response


CREATE FTNFP:NAME=RACK:<no>/FTNFP:<no>,CELLNO=<no>,WDFTNFP=CU<no>-FVSWRP<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE FTNFP:NAME=RACK:<no>/FTNFP:<no>,CELLNO=<no>,WDFTNFP=CU<no>-FVSWRP<no>;

SW RELEASE: = <no>


CREATE FTNFP ACK:

name = RACK:<no>/FTNFP:<no>

cellno = 0

90 A30808-X3247-K356-4-7630






END

wiringDataTnf

CUWiring = CU<no>

FVSWRPWiring = FVSWRP<no>


A30808-X3247-K356-4-7630 91



3.14 TMA

For amplifying the RX signal a Tower Mounted Amplifier can be installed. If a TMA isinstalled, all other devices in the RX path must be switched in MUCO mode.

The HMO DIDCTMA/DUDCTMA must be created for the DC power supply of the TMA.

1 TMA Creation ...... (see OGL:LMT)


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKTMACREATE TMANAME=RACK:<no>/TMA:<no>

CREATE TMA:NAME=RACK:<no>/TMA:<no>;

2 System Response

CREATE TMA:NAME=RACK:<no>/TMA:<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE TMA:NAME=RACK:<no>/TMA:<no>;

SW RELEASE: = <no>


CREATE TMA ACK:

name = RACK:<no>/TMA:<no>

92 A30808-X3247-K356-4-7630






END


A30808-X3247-K356-4-7630 93



3.15 LMU (optional)

For the Enhanced Observed Time Difference (E-OTD) location service, a LocationMeasurement Unit (LMU) must be installed. The LMU must first be tested separatelyfrom the rest of the BTSE and its configuration data logged for forwarding to the ServingMobile Location Center (SMLC) database. Only then can it be created within the BTSE.

1 Stop LMT Application

b On the LMT, stop the LMT application. ...... (see OGL:LMT)

2 LMU Installation Utility Start

b Start up the “LMU Installation Utility” in the WINDOWS start menu (Start:\Pro-grams\LMU Installation Utility).

The dialog box below will open:

94 A30808-X3247-K356-4-7630



3 Connect the LMU Installation Utility Serial Cable

Connect the special LMU Installation Utility serial cable between the LMT andthe diagnostic port of the LMU.

This cable resets the LMU in preparation for the Installation Utility (IU) tests.

4 Enter LMU Configuration Data

b Enter the correct data for the site, on the dialog box “SITE CONFIGURATION”page #1-#5.

5 Save LMU Configuration

b When all the fields are filled in, click on the “Save Configuration” button.

This stores the entered data into a CSV log file for the SMLC database.

6 Start LMU IU Tests

b Click on the “Run Tests” button.

The IU will now download the test code to the LMU, activate it, and then runthrough a series of tests. The progress and results of these tests is shown in thedialog box below:

A30808-X3247-K356-4-7630 95



7 Complete LMU IU Tests

If the result of the tests is:

– “DSP Download Fail”, proceed to step... h...8

– “DSP Activation Fail”, proceed to step... h...9

– “ANT1 Fail”, proceed to step... h...10

– “ANT2 Fail”, proceed to step... h...11

– “MON1 Fail”, proceed to step... h...12



– “GPS Fail”, proceed to step... h...15

– “passed”, proceed to step... h...16

8 DSP Download Fail

Ensure the LMU IU is correctly installed on the LMT. ...... (see OGL:LMT)

Restart the tests from step... h...6

9 DSP Activation Fail

Restart the tests from step... h...6If the DSP Activation fails again, replace the LMU i ...MMN:BTSE

BS-240 / 240 II/ 240XL/ 240XL II

Then start again from step... h...2

96 A30808-X3247-K356-4-7630



10 ANT1 Failure

– If the ANT1 fails because the maximum power is too low, reduce theattenuation between the lightning protection and the ANT1 RF port to aminimum of 10dB.

– If the ANT1 test fails because the maximum power is too high, increase theattenuation between the lightning protection and ANT1 RF port to amaximum of 30dB.

– If ANT1 fails after this, replace the LMU and repeat the tests from step... h...1

– If ANT1 continues to fail, then the problem may be in the antenna and cablechain. See corresponding Fault Clearance Procedure in...

i....MMN:BTSEBS-240 / 240 II/ 240XL/ 240XL II

11 ANT2 Failure

– If the ANT2 fails because the maximum power is too low, reduce theattenuation between the lightning protection and the ANT2 RF port to aminimum of 10dB.

– If the ANT2 test fails because the maximum power is too high, increase theattenuation between the lightning protection and ANT2 RF port to amaximum of 30dB.

– If ANT2 fails after this, replace the LMU and repeat the tests from step... h...1

– If ANT2 continues to fail, then the problem may be in the antenna and cablechain. See corresponding Fault Clearance Procedure in...


12 MON1 Failure

– If MON1 fails because the power level is too low, decrease the attenuationbetween the coupler and the LMU MON1 port to a minimum of 20dB.

– If MON1 continues to fail, then the problem may be in the cabling betweenthe DUAMCO and the LMU. Inspect, check and replace if necessary. Seecorresponding Fault Clearance Procedure in...


– If MON1 continues to fail after this, replace the LMU and repeat the tests fromstep...

h...1

A30808-X3247-K356-4-7630 97



13 MON2 Failure



i ...MMN:BTSEBS-240 / 240 II/ 240XL/ 240XL II


h...1

14 MON3 Failure





h...1

15 GPS Failure

– If GPS fails, then the problem may be in the cabling between the GPSAntenna, the lightning protection and the LMU. Inspect, check and replace ifnecessary. See corresponding Fault Clearance Procedure in...


– If GPS continues to fail after this, replace the LMU and repeat the tests fromstep...

h...1

16 LMU Creation ...... (see OGL:LMT)

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKLMUCREATE LMU

CREATE LMU:NAME=RACK:<no>/LMU:<no>

98 A30808-X3247-K356-4-7630



17 System Response

CREATE LMU:NAME=RACK:<no>/LMU:<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE LMU:NAME=RACK:<no>/LMU:<no>;

SW RELEASE: = <no>


CREATE LMU ACK:

name = RACK:<no>/LMU:<no>

Several CHANGED STATE EVENT REPORTs will follow. They can be examinedin the “LMT Message Browser” Window.

Administrative State = UNLOCKED

Operational State = ENABLED

Availability Status = NULL_value

Alarm Status = cleared


END

A30808-X3247-K356-4-7630 99



3.16 Creating the Alarm Configuration (ENVABTSE)

Each rack is equipped with an ACTC that supplies 9 ENVAs. In the Base Rack (option-ally) the ACTM can be installed that supplies 48 additional ENVAs (1.3.3). For unin-stalled ACTM, the alarms for the Base Rack are the same as for the other racks.

The ENVAs 0–8 should be named as described in Tab. 1.17.

For more information, refer to CML:BS-4x/240/241/240XL and MMN:BS-240 / 240 II/ 240XL / 240XL II.

1 ENVABTSE Creation ...... (see OGL:LMT)


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKENVABTSECREATE ENVABTSENAME=RACK:<no>/ENVABTSE:<no>(see below)INTINF=<interfaceInformation>(see below)ASEV=<associatedSeverity>(see below)ASTRING=<associatedString>

For Base Rack with installed ACTM the range of ENVA is 0....56In all other cases the range is 0...8.

The alarms can be configured as high active or low active:high active : alarm message starts if the pins are opened.low active: alarm message starts if the pins are closed by short circuit.

Alarm severity level can be chosen (critical, major, minor) or it can be read out ofthe database (default_db).

CREATE ENVABTSE:NAME=RACK:<no>/ENVABTSE:<no>,INTINF=low,ASEV=DEFAULT_DB,ASTRING="Fire";

iThe alarms for "FAN" and "Rack Door open" are created automatically during the cre-ation of FAN and SET RACK.

100 A30808-X3247-K356-4-7630



2 System Response


CREATE ENVABTSE:NAME=RACK:0/ENVABTSE:0,INTINF=low,ASEV=DEFAULT_DB, AS-TRING="Fire";


============================================

JOB: <no>



USER NAME: <user>

Command: CREATE ENVABTSE:NAME=RACK:0/ENVABTSE:0,INTINF=low,ASEV=DEFAULT_DB,ASTRING="Fire";

SW RELEASE: = <no>


CREATE ENVABTSE ACK:

name = RACK:0/ENVABTSE:0

interfaceInformation = low

associatedSeverity = DEFAULT_DB

associatedString = Fire


The following ENVAs are fix related to some Shelter alarms and are recom-mended to be defined as shown in the table:

ENVA Corresponding alarm Interface Information

0 free configurable high



3 Rack in Service low

4 Smoke (not BS-240U) low

5 Battery Breaker 0,1,2 high

6 Over Voltage Protection high

8 Microwave 1...9 low

A30808-X3247-K356-4-7630 101



END

102 A30808-X3247-K356-4-7630



3.17 Setting Attributes for the BTSE

The location name, vendor name, sales unique name and software load safety must beset. For more information, refer to the CML:BS-4x/240/241/240XL

1 Set Attributes for BTSE Equipment ......(see OGL:LMT)

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPSET BTSEP

[BASICS]NAME=<BTSEP:0>BTSEPOS=<SBS_Equipment_Position>CHIDT=<noChangeOnIDT/IDTWasChanged>EAUTOREC=<enabled/disableAutomaticRecovery>LOCNAME=<locationName>RXDIVSV=<enable/disableRxDiversitySupervision>SALUNAME=<salesUniqueName>(see below)VENDNA=<vendorName>

[SEVERITY]ALRMSEVxxx=<CRITICAL/MAJOR/MINOR/DEFAULT_DB> (see below)

[SWL]SWLDSAF=<swLoadSafety: swLoadSafetyField, swLoadSafetyVersion>

SALUNAME: The Sales unique name is a ASCII character string with length 11,e.g: "AD042S7449E". The SALUNAME must be the same in the BSC databaseand the local BTSE database.

ALRMSEV: Select one or more parameters and enter the appropriate severity ofthe alarms for the following MOs: ACDCP, ACT, COBA, BATTERY, COSA, CU,DIDCTMA, DILNA, DUDCTMA, DULNA, DUVSWR, FANP, FTNFP, FVSWRP,and TMA.

The SWLDSAF must be set after connecting the BTSE with the BSC.SWLDSAF can only be set after a single transmitting.

SET BTSEP:NAME=BTSEP:0,ALRMSEVxxx="severity"...,BTSEPOS="Mu-nich", CHIDT=noChangeOnIDT,EAUTOREC=enabled,LOCNAME="Munich",RXDIVSV=enabled, SALUNAME="AD042S7449E", SWLDSAF="hs010808.swl:01-01-08-00-08-00_98-08-21", VENDNA="Siemens";

iFor Remote Inventory, the SALUNAME and BTSEPOS must be set correctly.

A30808-X3247-K356-4-7630 103



2 System Response


END

SET BTSE:NAME=BTSEP:0,ALRMSEVxxx="severity"...,BTSEPOS="Munich", CHIDT=noChangeOnIDT,EAUTOREC=enabled,LOCNAME="Munich", RXDIVSV=enabled, SALUNAME="AD042S7449E", SWLDSAF="hs010808.swl: 01-01-08-00-08-00_98-08-21", VENDNA="Siemens";


============================================

JOB: <no>



USER NAME: <user>

COMMAND: Set BTSE:NAME=BTSEP:0,ALRMSEVxxx="severity"...,BTSEPOS="Munich", CHIDT=noChangeOnIDT,EAUTOREC=enabled,LOCNAME="Munich", RXDIVSV=enabled, SALUNAME="AD042S7449E", SWLDSAF="hs010808.swl: 01-01-08-00-08-00_98-08-21", VENDNA="Siemens";

SW RELEASE: = <no>


SET ATTRIBUTES ACK BTSE:

name = RACK:<no>/ACT:<no>


104 A30808-X3247-K356-4-7630



3.18 BPORT

1 BPORT Creation ......(see OGL:LMT)

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPBPORTCREATE BPORTNAME=BPORT:<no>L1PT=<layer1 ProtocolType>LCONF=<lineConfiguration>BERT lower Threshold=<no> upper Threshold=<no>L1CTRLTS TSL=<no> SSL=<no>(see below)L1RAT=<layer1 RemoteAlarm Type>

The parameters for L1CTRLTS must be set only in case of Loop Configuration.

For more information, refer to the CML:BS-4x/240/241/240XL.(Example see below.)

CREATE BPORT:NAME=BPORT:<no>,L1PT=pcm30crc4,LCONF=loop,BERT=E10_9-E10_3,L1CTRLTS=1-0,L1RAT=ProtocolSignalling;

iBefore the BPORT is created, the rack must be created.The object BPORT determines the PCM line configuration.

iThe number of available BPORTs depends on the used HW variant for the objectsCOBA and COSA

– COBA = 2 ports (instances x = 0,1)– COSA = 6 additional ports (instances x = 2,...,7)

iIn case of ’lineConfiguration’ = multidrop/loop, the following attributes of instance x and(x+1), where x and (x+1) are considered as a port pair, are equal:

– layer1ControlTS (for loop configuration only)– layer1ProtocolType– layer1RemoteAlarmType– lineConfiguration

iThe even numbered port of a port pair is always the default receiving port from the BSCand must be created first.The odd numbered port is always the default transmitting port to the BSC:To guarantee a correct transition of SW releases, BPORT instance 0 must be used forthe O&M link.

A30808-X3247-K356-4-7630 105



2 System Response


END

CREATE BPORT:NAME=BPORT:<no>,L1PT=pcm30crc4, LCONF=loop,BERT=E10_9-E10_3,L1CTRLTS=1-0,L1RAT=ProtocolSignalling;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE BPORT:NAME=BPORT:<no>,L1PT=pcm30crc4, LCONF=loop,BERT=E10_9-E10_3,L1CTRLTS=1-0,L1RAT=ProtocolSignalling;

SW RELEASE: = <no>


CREATE BPORT ACK:

name = BPORT:<no>

bitErrorRateThreshold

lowerThreshold = E10_9

upperThreshold = E10_3,

layer1ControlTS

tsl = 1

ssl = 0

layer1ProtocolType = pcm30crc4

layer1RemoteAlarmType = ProtocolSignalling

lineConfiguration = loop


106 A30808-X3247-K356-4-7630



3.19 XCONNECT

1 XCONNECT Creation ......(see OGL:LMT)

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPXCONNECTCREATE XCONNECTNAME=XCONNECT:<no>MPTSL<no> targetBport<n0>-targetTSL<no>::


CREATE XCONNECT:NAME=XCONNECT:0,MPTSL01=1-4,MPTSL02=1-5,MPTSL03=3-12,MPTSL04=3-13, ... ;

2 System Response

iBefore the XCONNECT can be created, the BPORT objects must be created.

iPrimary ports must be distinguished from secondary ports. The related BPORT instanc-es of a primary port are configured as star, multidrop or loop; for a secondary port theBPORT instance is configured as StarX.

iCross connections can be established between a primary and a secondary port, but notbetween two primary or two secondary ports.

CREATE XCONNECT:NAME=XCONNECT:0,MPTSL01=1-4,MPTSL02=1-5,MPTSL03=3-12,MPTSL04=3-13, ... ;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE XCONNECT:NAME=XCONNECT:0,MPTSL01=1-4,MPTSL02=1-5,MPTSL03=3-12,MPTSL04=3-13, ... ;

SW RELEASE: = <no>


A30808-X3247-K356-4-7630 107




END

CREATE XCONNECT ACK:

name = XCONNECT:<no>

mappingTSL<no>

ltargetBPort = <no>

targetTSL=<no>


108 A30808-X3247-K356-4-7630



3.20 Set BTSM

1 Enter Values for TEI and Abis Channel ......(see OGL:LMT)

In Phase two, the LMT prepares for the establishment of the Abis interface tothe BSC.

The O&M terminal endpoint identifier (TEI), the kind of connection and the AbisTime must be programmed for the BTS manager (BTSM).

Obtain the corresponding TEI from the configuration data.

b MANAGED-ELEMENTBSS-FUNCTIONALBTSMSET BTSMNAME=BTSM:<no>ABISLKSAT=<terrestrial/satellite connection>ABISTIME=<year, month, day, hour, minute, second>TEI=<no>


SET BTSM:NAME=BTSM:<no>,ABISLKSAT=terrestrialConnection,ABIS-TIME=<date and time>,TEI=<no>;

2 System Response

SET BTSM:NAME=BTSM:<no>,ABISLKSAT=terrestrialConnection,ABISTIME=<date andtime>,TEI=<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: SET BTSM:NAME=BTSM:<no>,ABISLKSAT=terrestrialConnection,ABISTIME=<date andtime>,TEI=<no>;

SW RELEASE: = <no>


SET BTSM ACK:

name = BTSM:0

A30808-X3247-K356-4-7630 109




END

ABISLKSAT = <connection type>

ABISTIME = <date and time>

TEI = <no>


110 A30808-X3247-K356-4-7630



3.21 LAPDLE

1 Enter Values for LAPD Channel ......(see OGL:LMT)

In Phase two, the LMT prepares for the establishment of the Abis interface tothe BSC.

Obtain the corresponding BPORT No., Subslot No., and transfer rate from theconfiguration data.

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPLAPDLECREATE LAPDLENAME=LAPDLE:<No.>LAPDCH=<BPORT No., TIMESLOT No., SUBSLOT No.>


Create LAPDLE: NAME=LAPDLE:<No.>, LAPDCH=BPORT<No.>,--SSL<No.>_<transfer rate>;

2 System Response

Create LAPDLE: NAME=LAPDLE:<No.>, LAPDCH=BPORT<No.>-TSL<No.>-SSL<No.>_<transferrate;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: Create LAPDLE: NAME=LAPDLE:<No.>, LAPDCH=BPORT<No.>-TSL<No.>-SSL<No.>_<transfer rate;

SW RELEASE: = <no>


Create LAPDLE ACK:

name = LAPDLE:<No.>

LAPDCH=<TIMESLOT No., SUBSLOT No.>

A30808-X3247-K356-4-7630 111




END


112 A30808-X3247-K356-4-7630



3.22 CORE Redundancy

1 Switch on the Right COBA

2 COBA1 Creation

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACKCOBACREATE COBANAME=RACK:0/COBA:1

Create COBA:NAME=RACK:0/COBA:1;

3 System Response

iCore redundancy is only possible with 2 COBA modules and a boot software of BR 6.0or higher.

Switch on the right COBA with the corresponding breaker on the DC-Panel, seeHW:BTSE FRAMES/PANELS, DC-Panels to find the appropriate module de-scription.

Create COBA:NAME=RACK:0/COBA:1;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: Create COBA:NAME=RACK:0/COBA:1;

SW RELEASE: = <no>


Create COBA ACK:

name = RACK:0/COBA:1


A30808-X3247-K356-4-7630 113



4 Reset the Left COBA

Reset the left COBA with the push button on the board to force a redundancyswitch.

Log in immediately(within 10 seconds) to prevent a switching back.

After about 15 seconds, the right COBA reaches the start connection status

5 SW Activation

b MANAGED-ELEMENTBSS-FUNCTIONALBTSMACTIVATE BTSMNAME=BTSM:0FILEID=<enter header according to the SW Load e.g.: HS010808.SWL>FILESWV=<enter file version string e.g.: 01-01-08-00-08-00_98-08-21

ACTIVATE BTSM:NAME=BTSM:0,FILEID="hs010808.swl",FILESWV="01-01-08-00-08-00_98-08-21"

6 System Response

LED_Indication of the right COBA:

ACT fl(G) R RCOBA

FLOC o(R) o(R) HMO


ACTIVATE BTSM:NAME=BTSM:0;FILEID="hs010808.swl",FILESWV="01-01-08-00-08-00_98-08-21";


============================================

JOB: <no>



USER NAME: <user>

COMMAND: ACTIVATE BTSM:NAME=BTSM:0;FILEID="hs010808.swl",FILESWV="01-01-08-00-08-00_98-08-21";

SW RELEASE: = <no>


Activate BTSM SW ACK:

name = BTSM:0

fileId = "hs010808.swl"

fileSoftwareVersion = "01-01-08-00-08-00_98-08-21"

114 A30808-X3247-K356-4-7630



The BTSE is now in phase 2

7 Login

The Session Starter window opens.(Start new Session is pre-selected.)


The Logon Request window opens.

b Enter UserID: <user>.Enter Password: <password>.Click on the “Connect” button.

8 System Response

9 Database Download to the Redundant COBA

In order to reconfigure a BTS, a backup copy of the initial configuration can beused. This can be done by submitting the script files through the CLI.

b Copy the 6 backup files “script*p.lmt” from the storage medium to the directory:

C:\SIEMENS\LMT\BKBTS\BTSPLUS


LED Indication of the right COBA:

ACT fl(G) o(R) RCOBA

FLOC o(R) o(R) HMO


(Port 1) Logon Ack Received Response on BTS dated “date and time” (on Session xxx)

Continue immediately with step 9 (after approx. 1 min. the activity is automati-cally switched back to the left COBA).

A30808-X3247-K356-4-7630 115



10 Submitting the Backup Script Files

Start the Command Line Interface (CLI).

b Choose “Open CL interface” in the “CL interface” menu of the LMT Input Han-dler.

Open the script file BTSCONFP.LMT.

b Choose “Open” in the “File” menuorclick on the “Open” button of the symbol bar at the CLI.

b Open the file BTSCONFP.LMT, located in the BKBTS\BTSPLUS directory.

b Submit the commands of the script file by clicking on the “cmd” button or choos-ing “Command -> Submit” from the menu bar.

11 Result

The result for all modules should be as follows:

The 6 script files in the BKBTS\BTSPLUS directory will be executed:

SCRIPT1P.LMT

SCRIPT2P.LMT

SCRIPT3P.LMT

SCRIPT4P.LMT

SCRIPT5P.LMT

SCRIPT6P.LMT

iThe BTSCONFP.LMT script can be executed only if the LMT is connected toa BTSE in phase 2.

CREATE <module>:NAME=RACK:<no>/<module>:<no>,CELLNO=<no>;


============================================

JOB: <no>



USER NAME: <user>

COMMAND: CREATE <module>:NAME=RACK:<no>/<module>:<no>,CELLNO=<no>;

SW RELEASE: = <no>


116 A30808-X3247-K356-4-7630



12 Download nob_RIU File to the Redundant COBA

Change to the LMT application!

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPREMINVDNLIDFD REMINVSRCDIR=<C:\IDFeditor>

DNLIDFD REMINV:NAME:=REMINV:0,SRCDIR=”C:\IDFeditor”;

13 System Response

END

CREATE <module> ACK:

name = RACK:<no>/<module>:<no>


DNLIDFD REMINV:NAME=REMINV:0,:SRCDIR=”C:\IDFeditor”;


============================================

JOB: <no>



USER: <user>

COMMAND: DNLIDFD REMINV:NAME=REMINV:0,:SRCDIR=”C:\IDFeditor”

SW RELEASE: <no>

DOWNLOAD END: FILE “BTS_NRIU” TRANSFER COMPLETED


A30808-X3247-K356-4-7630 117



3.23 Checking the State of all Modules

1 Check the State of all Modules ...... (see OGL:LMT)

All images have been loaded. This is confirmed by the state event report:

Administrative State = UNLOCKEDOperational State = ENABLEDfor all successfully created objects.

This can be verified via logfile in browser mode or via LMT commands with:

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPRACK<module>GET <module>NAME=RACK:<no>/<module>:<no>REQATTL=AST&OST

All red LEDs (exept the PA LED on the CU) have been switched off.If no Abis is connected, the coresponding LED on the COBA/COSA is red.

The files can be viewed in the “Message Browser” window.

END

118 A30808-X3247-K356-4-7630



3.24 Replacing Failed HW

1 Module Test

After replacing a failed HW unit, it is necessary to enable this new HW unit via“test” or “delete”/”create” command before starting any other activities (e.g., SWdownload or activation) because the PID of a new module is only updated after“test” or “create” commands and it is necessary during download to have the ac-tual PID of all modules stored on the COBA.

Unlocking the BTSM will cause a full BTS alignment.When issuing BTSE configuration commands during an alignment, a new align-ment will be started.

For further information, refer to the: ......MMN:BTSEBS-240 / 240 II/ 240XL/ 240XL II

END

A30808-X3247-K356-4-7630 119



3.25 External Alarm Check

The Operator Alarm Interface must be checked. All the alarms should have been con-figured previously during Procedure 3.16 "Creating the Alarm Configuration (ENVABT-SE)".

For every couple of alarm terminals on the ACT (see IMN:BTSE) alternativelyclose/open the contact and check the corresponding alarm message at the LMT. If thealarm is configured high, an alarm start message will be displayed first, if it is configuredlow, an alarm cease message will be displayed first.

iImportant:The test should not be done before the completion of ACT configuration.

120 A30808-X3247-K356-4-7630



3.26 BTS Backup Files Generation

In order to reconfigure a BTS in case of losing all configuration data after a COBA re-placement, a backup copy should be generated and stored on site.

The backup files are generated via the Backup BTS Tool: the configuration data of theBTSE are at first loaded to the LMT PC and are then converted to script files. Thosescript files are written to the LMT subdirectory “BKBTS\BTSPLUS”.

1 Start the Backup BTS Tool

b Start the Backup BTS tool via the WINDOWS Start menu (“Start” -> “Programs”-> “LMT...” -> “Backup BTS”),orclick on the “Backup BTS” icon in the “LMT Control Center” window.

The “BACKUPBTS” window opens.

2 Perform the Command “Get HW Configuration”

b Click on the button “Get HW Configuration”.

Several reports are displayed in the “BACKUPBTS” window. After a fewminutes, the following message is displayed:

THE SCRIPT WAS DONE SUCCESSFULLY

3 Convert the Configuration Data to Script Files

b Click on the button “Convert to Script File”.

The following message is displayed in the “BACKUPBTS” window:

THE CONVERSION WAS DONE SUCCESSFULLY!THE SCRIPT WAS DONE SUCCESSFULLY

The backup BTS tool writes the following files into the BKBTS\BTSPLUS subdi-rectory:SCRIPT1P.LMTSCRIPT2P.LMTSCRIPT3P.LMTSCRIPT4P.LMTSCRIPT5P.LMTSCRIPT6P.LMT

A30808-X3247-K356-4-7630 121



4 Copy the Script Files to Disk

b Copy the script files from [Drive]:\[LMT_Root]\BKBTS\BTSPLUS to somestorage media and keep it at the site in case a backup copy of the BTSEconfiguration is needed.

END

122 A30808-X3247-K356-4-7630



3.27 Remote Inventory

The function “Remote Inventory” of the Siemens Basestation System performs electron-ic, non-volatile storing of the complete, individual product identification data (PID) ofeach inventory object.

Modules that have its inventory data on board are called ob_RIUs (on-board RemoteInventory Units). The PID of this ob_RIUs is automatically loaded to the inventory datafile (IDF).

In order to include inventory data of objects without a non volatile storage (e.g. frames,racks, OEM components), the data of these nob_RIUs (not on-board Remote InventoryUnits) are entered into a inventory data table (IDT) via the LMT and the offline tool ”IDF-Editor”. As a nob_RIU file (NOB), these data are stored on the COBA.

The complete Remote Inventory Data is delivered with each Rack on a disk. The filename is composed of the serial number of the Rack ( “/” replaced by “_“) and the exten-sion “IDF”, for example: “CN+_JD100001.IDF”. The data of the nob_RIUs must be at-tached to the automatically created PID of the ob_RIUs.

For nob_RIUs referring to MMN:BTSE BS-240 / 240 II / 240XL / 240XL II List ofnob_RIUs

1 Start IDF Editor

b Start the IDF Editor:

– Start the IDF editor via the WINDOWS Start menu (“Start” -> “Programs” ->“LMT...” -> “IDF Editor”),or

– click on the “IDF” icon on the “LMT Control Center” window.

The “IDF Editor” window opens:

A30808-X3247-K356-4-7630 123



2 Open IDF-File

The IDF-files are stored on a disk that is delivered with each Rack of the BTSE.Copy this file to the harddisk of the LMT PC e.g. C:\...\LMT<version>\IDF\*.idf.

b Open the IDF-file:

– Select “Open” in the “File” menu.

– Enter path and file name of the IDF-fileorselect the uploaded file from the list in the appearing window.

– Double-click on the file name orclick on the “Open” button.

124 A30808-X3247-K356-4-7630



3 Set SBS_Equipment_Position

b Select the “File” menu

– SetSBS_Eq_PosThe “Set SBS_Equipment_Position” window opens.

– Enter the SBS_Equipment_Position and click on “Replace All” button.

4 Set RACK_Position


– Set RACK_PosThe “Set Rack Position” window opens.

– Enter the RACK_Position and click on the “Replace All” button.

5 Check nob_RIU Data

Are the data of the nob_RIU modules/elements ok? Y h...7N h...6

010101rack numberrow numberroom number

The meaning of the SBS Equipment Position is as follows:

A30808-X3247-K356-4-7630 125



6 Edit Remote Inventory Data of nob_RIU Units

The records of the nob-RIUs are shown in bold letters. Only these records areeditable.

b Move the mouse-cursor to the record of the replaced unit.

– Press the right mouse-button.An “Edit”-button opens.

– Click on the “Edit”-button.A window named “PIDnobRIU’s” for editing the inventory data of the unit willbe opened.

The data can be edited manually or automatically via the 2D-Code Reader.

– Edit the data manually, or

– click on the “Scan” button to use the 2D-Code Reader.

When the 2D-Code Reader is used for the first time, the “Common Port: Setting”window opens.

– Select the serial port.

– To start the scanning process, press the button on the 2D-Code Reader.

The data is inserted into the corresponding fields.

– Confirm by clicking on the “OK!” button.

– Click on “Safe” in the “File” menu.

126 A30808-X3247-K356-4-7630



7 Export Nob_Riu part for Download to the BTSE

Only the nob_RIU-part must be exported for downloading into the BTSE.

b Export the nob_RIU-part:

– Select “NOB” in the “Export” menu.

The file name is automatically composed of the “SalesUniqueName” with theextension “.nob ” .

– Click on the “Save” button.

A question window opens: Create Nob RIUs file for Download?

– Click on the “Yes” button.

A window opens that displays the destination path of the NOB-file, for example:C:...\LMT<version>\Idf\Dnload\BTS_NRIU.nob

– Click on the “OK” button.

8 Upload IDT-File from BTSE


Set the SBS_Equipment_Position (BTSEPOS) and the SalesUniqueName (SA-LUNAME) in Procedure “Set BTSE” ......(see 3.17)

The remote inventory data of the ob-RIUs must be loaded to the LMT PC.

b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPREMINVUPLLIDF REMINVDESTDIR=<path>FILE=<file name>OVERWRITE=YES

The values DESTDIR and FILE are optional. If no special path or file name isentered, the file is uploaded to the default directory of the IDF editor.If the value OVERWRITE=YES is selected, a former version of an uploaded IDT-file will be overwritten.

UPLLIDF REMINV:DESTDIR=”<for example: C:...\LMT<version>\Idf\Upload”>,FILE=<for example: “btse.idt”>,OVERWRITE= YES;

A30808-X3247-K356-4-7630 127



9 System Response

10 Open IDT-File

Change to IDF-Editor!


– Open

– Select the uploaded file from the list in the displayed window; e.g.: C:\SIE-MENS\LMT<version>\Idf\Upload\btse.idt

– Click on the “Open” button


============================================

JOB: <no>

PC Time&Date: <time>/<date>

COMMAND: UPLLIDF REMINV:NAME=REMINV:<no>,OVERWRITE=Yes;


Uploading File <for example: BTSE.IDT>:

To: <for example: BTSE.IDT>

On Directory:<for example:...\Idf\Upload>



============================================

JOB: <no>


COMMAND: UPLLIDF REMINV:NAME=REMINV:<no>,OVERWRITE=Yes;


Uploading End: File <for example: BTSE.IDT> Transfer Completed


128 A30808-X3247-K356-4-7630



11 Attach nob_RIU file to Actually Loaded IDF


– Attach

– Select the exported nob_RIU file from the list in the displayed window (thedestination path was given during step 7); e.g.: C:\SIEMENS\LMT<ver-sion>\Idf\Upload\BTS_NRIU.nob

An “ATTENTION” window opens.


12 Remove Redundant nob_RIU Files


– Remove nob_RIU’s

An “ATTENTION” window opens.

– Click on the “Yes” button to confirm the deletion of all redundant nob_RIUs

Another “ATTENTION” window opens.

– Click on the “Yes” button

13 Export IDF-File for Backup

b Select the “Export” menu

– IDF

– Select the destination path in the displayed window, preferably “A:\”

The file name is composed of the “SalesUniqueName” with the extension “.idf ”automatically

– Click on the “Save” button

– Put the disk with the backup file of the inventory data to the site specific doc-umentation

A30808-X3247-K356-4-7630 129



14 Export nob_RIU File for Download to the BTSE

Only the nob_RIU-part must be exported for downloading into the BTSE.

b Select the “Export” menu

– NOB

The file name is automatically composed of the “SalesUniqueName” with theextension “.nob ” .

– Click on the “Save” button.

A question window opens: Create Nob RIUs file for Download?

– Click on the “Yes” button.

A window opens that displays the destination path of the NOB-file, for example:C:...\LMT<version>\Idf\Dnload\BTS_NRIU.nob


15 Download nob_RIU File


b MANAGED-ELEMENTBSS-EQUIPMENTBTSEPREMINVDNLIDFD REMINVSRCDIR=<source directory>

SRCDIR: enter the source directory in which the exported NOB-file was saved,for example C:...\LMT<version>\Idf\Dnload.

DNLIDFD REMINV:NAME:=REMINV:0,SRCDIR=”<for example:C:...\LMT<ver-sion>\Idf\Dnload”;

130 A30808-X3247-K356-4-7630



16 System Response

END


============================================

JOB: <no>


COMMAND: DNLIDF REMINV:NAME=REMINV:<no>,SRCDIR=”<for example:C:...\LMT<ver-sion>\Idf\Dnload”:


Downloading File <for example: BTS_NRIU>:

100% of packets transferred



============================================

JOB: <no>


COMMAND: DNLIDF REMINV:NAME=REMINV:<no>,SRCDIR=”<for example: C:...\LMT<ver-sion>\Idf\Dnload”:


Download End: File <for example: BTS_NRIU> Transfer Completed


A30808-X3247-K356-4-7630 131



3.28 BTSE Phase 3

1 Manual Switch to Phase 3

For forced switchover to Phase 3, a special command may be entered at theLMT.

b MANAGED-ELEMENTBSS-FUNCTIONALBTSMCONNBSC BTSMNAME=BTSM:0


CONNBSC BTSM:NAME=BTSM:0;

2 System Response

The session is closed, processing is aborted.

3 Logon

b LogonUserID: <user>Password: <password>Connect


The BTSE is now in phase 3. The BTSE is now connected to the BSC.

The LED indication on the COBA changes to :

ACT fl(G) RCOBA

FLOC fl(G) HMO

ABIS 1 ABIS 2

The LED indication on the COSA changes to :

ACT fl(G) RCOSA

ABIS 7 ABIS 8

ABIS 5 ABIS 6

ABIS 3 ABIS 4

The LED indication on the CU changes to :

OK fl(G) fl(G) SW

RES PA

132 A30808-X3247-K356-4-7630



END

If you have problems switching over to Phase 3:

In case of problems with the switchover to Phase 3, please refer to the following checklist. Here the minimalBTSE configuration is described with the preconditions for a successful switchover to Phase 3:

COBA-0 = unlocked.enabled

– COBA-0 is always created and enabled automatically.Here the Administrative State (AST*) is relevant.

Minimal parameters of RACK-0: available

– This means that “TypeOfBTSE” (TYPRACK) must be set first beforeany HMO can be created.

LAPDLE-0 = created

Minimal parameters of LAPDLE-0: available

– This means that the LAPD channel (LAPDCH) must be defined.

Accuracy of CCLK >= medium (at least !)

– The current CCLK accuracy can be determined by performing theLMT command Get COBA ---> REQATTL ---> CCLKACC.

Minimal parameters of BTSM: available

– This means that the TEI must be defined.

Minimal parameters of BPORT-0: available

– This means that the “L1ControlTimeSlot” (L1CTRLTS) and“LoopConfiguration” (LCONF) must be defined.

*) For more information on the Administrative State (AST), please refer to MMN:BTSE BS-240 / 240 II/ 240XL / 240XL II

A30808-X3247-K356-4-7630 133



3.29 Execution of Offline Tests

3.29.1 RF and Function Tests

Fig. 3.1 Configuration for Offline Test with FICOM and DIAMCO

Test Out

ANT

Coupler Box

Abis

BTSE

FICOM

DIAMCO

OVPT

LMT

MS

Receiver

Transmitter

Attenuator20dB / 50W

LMT

8631

Transmitter

MS Box

Note:The attenuator 20dB/50W is sufficient for tests with 1 carrier only.

50 ΩTermination

Spectrum Anal.

134 A30808-X3247-K356-4-7630



Fig. 3.2 Configuration for Offline Test with DUAMCO

3.29.2 Purpose of the Abis Simulation

The Abis simulation is used for offline functional tests on site.The following tests, for example, can be performed with the Abis simulators:

1. BER test with MS loop.

2. Voice test with simulator loop.

3. Channel activation and deactivation from any channel.

4. Test and status request of modules of the BTS.

3.29.3 Preparation of the Abis Simulation

The Abis simulation requires:

DUAMCO

Test Out

ANT

Abis

BTSE

OVPT

LMT

LMT

8631

0 1

Coupler Box

MS

Receiver

Transmitter

Transmitter

MS Box

50 ΩTermination

Note:With this configuration, it is possible to test the DUAMCO internal receiving path.

Attenuator20dB / 50WSpectrum Anal.

A30808-X3247-K356-4-7630 135



– an 8631 PCMCIA card with Abis simulation SW on CD

– a DOS computer with WINDOWS 98/2000 for the 8631 PCMCIA card.

– the cable for the connection to the BTSE Abis interface.

See also additional information in the help menu of the simulator.

3.29.4 Connection of Test equipment (TE)

To achieve reliable measurement results, the connections must be plugged correctlyand faultless contact must be guaranteed.

3.29.5 Check BTSE Phase

Before you start the Abis Simulation, check the phase of the BTSE at the LMT. It mustbe in phase 3. If it is not in phase 3, start the Abis simulation nevertheless. Then, changethe phase via LMT. Afterwards, re-initialize the hardware via the commands “Actions”-> “Sequences” -> “Init at Startup”. For more information, please refer to the Abis Simu-lation Help.

iThe IMSI of TestSim, which will be used for the MS, has to be entered on desktop inadvance.Make sure to use an IMSI with an unknown mobile country code and an unknown mobilenetwork code. Otherwise, no test connection is possible.

The complete equipment must be connected in the following order:1. Attenuator (20dB/50W) to FICOM, DUAMCO(ANT)2. FICOM, DUCOM (Testout) to RF-Coupler Box (Testout 0-Transm 0)3. Coupler Box (Receive) to RX BTSE (DIAMCO, DUAMCO)4. MS-Box to Coupler-Box(MS)5. 8631 Card to OVPT-Abis

136 A30808-X3247-K356-4-7630



3.30 Starting the Abis Simulation

The Abis simulation requires an 8631 PCMCIA card.

1 Starting the Abis Simulation

To start the Abis simulation, start WINDOWS.

b Configure the board:

– Click on the following symbol in the WINDOWS start bar.

The ’Abis Server Configuration (8631)’ window opens:

Click on the waveform button

A30808-X3247-K356-4-7630 137



– Select the desired E1 or T1 interface’.

– Confirm by clicking on the ’OK’ button.

Only for BS-240XL / 240XL II with more than 15 TRX: click on tab "Abis Server".

– Choose 2 Trunks in field "used Trunks".

– Confirm by clicking on the ’OK’ button.

b Start the Simulation:

– Click on the desktop icon ’Abis Simulation’ or select the Program ’Abis Sim-ulation’ in the WINDOWS start menu.

– Start

– Programs

– WWG-8631

– Abis Simulation

Continue with step h...2

138 A30808-X3247-K356-4-7630



2 Configuration of the BTSE-Type

Main window of the Abis Simulation Software, the "AbisSimClient" window:

Status Indicator:See Additional

Information Below

Menu Tree

Green Arrow Used as Start Button See also Additional Information in theHelp Menu of the Simulator

Tabs to Choose Between3 Different Menu Trees

’Trace Output’ Section:See Additional

Information Below

tab ’Config’

’BTSConf’

Status bar’

A30808-X3247-K356-4-7630 139



A green status Indicator signals normal operation.A red status Indicator signals problems. In this case, more information is given inthe status bar.In the ’Trace Output’ section, the following information may be displayed:’Mobile controlled Test sequence not executed.’For this feature you need a special access code. With this function you can nav-igate the BTSE via mobile phone.

b The special BTSE parameters must be set by using the folder ’BasicConfigura-tion.

– Select the tab ’Config’ in the menu tree section of the main window (’Abis-SimClient’ window).

– Double-click on ’BTSConf’ in the folder ’BasicConfiguration’ of the menu tree.

– The following window opens:

– Select the number of Cells, number of TRX’s and Network Type (e.g. GSMMIXED).

– Select the tab ’TrxConf’.

140 A30808-X3247-K356-4-7630




– Select the TRX type for the ’Mixed Cell’, if used

– Select the tab ’Abis Signaling’.


– Select the channel type (’ChanType’), the timeslot (’Ts’), the sub-timeslot(’SubTs’) and the terminal endpoint identifier (’Tei’).

– Click on the ’Apply’ button.

A30808-X3247-K356-4-7630 141



3 Configuration of the IMSI

The current TestSim IMSI for the mobile station corresponding to the systemstandard GSM 850/900/1800/1900 and the customer must be chosen.

– Double-click on the icon ’IMSI’ in the ’GeneralProperties’ folder.

– The window ’GeneralProperties’ opens and the tab ’IMSI’ is already selected.

– Enter the IMSI of the used TestSIM.

– Save with ’Apply’.

4 Optional Step: Save the Set Parameters

b To save the set parameters:

– Select ’File’ in the menu bar of the main window.

– Select ’Save as’.

– Enter a name for the file and click on ’ok’.

5 Close all Configuration Windows

END

142 A30808-X3247-K356-4-7630



3.31 Database Alignment

1 Start of Database Download

b Start the database download via the main window ("AbisSimClient" window):

– Select the tab "Action" in the menu tree section.

– Select the folder "InitBTS with Bcch" in the menu tree: testseq.act:\Sequenc-es\InitBTS with Bcch.

– Press the "+" sign next to the "InitBTS with Bcch" folder.

– Select "[0] DB Alignment".

– Click with the right mouse button on "Properties".

The following window appears:

– Repeat the same steps for ’[1] Send SysInfos (...)’.


A30808-X3247-K356-4-7630 143



– Make sure that there is no tick in the box before "All Cell without selectedbarred".

– Click on the "Apply" button.

– Press the "-" sign next to the "InitBTS with Bcch" folder.

– Click on the green arrow in the tool bar.

The database download starts.The Download was successful if the following message appears in the "Simula-tion Status/Result" section of the main window:"Result: success."

END

Click on...

144 A30808-X3247-K356-4-7630



3.32 Local Test Loop

The carrier unit is able to test major parts of its own transmitter and receiver functionalityduring a special test mode. During this test mode the transmit signal is converted to thecorresponding receive frequency and routed to the receiver input via a local test loop(LTL).

Additional information can be found in the online help of the Abis simulator.

1 Start Test

b Start the test via the main window (’AbisSimClient’ window):

– Select the tab ’Actions’ in the menu tree section.

– Select the folder ’Channeltest MTC/ECHOLOOP’ in the menu tree:testseq.act --> Sequences --> Channeltest MTC/ECHOLOOP.

– Click on the ’+’ sign next to the folder ’Channeltest MTC/ECHOLOOP’.

– Click with the right mouse button on ’[0] Set Param [...’.

– Select ’Properties’ in the appearing pop up menu.

Click on...

A30808-X3247-K356-4-7630 145




– Select the required channel for the test.

– Choose the number of the IMSI you want to use (see Procedure: 3.30, Step:3, IMSI number 1 - 5) and the channel you want to test.


– Click on the ’-’ sign next to the folder ’Channeltest MTC/ECHOLOOP’ in themenu tree of the main window.


2 Test Execution

The mobile phone rings.

– Press the connect button on the mobile phone.

If you can hear yourself speaking into the phone with a delay of approximately 1second, the test is successful.

3 Stop Test

– Stop the test by pressing the disconnect button on the mobile phone.

END

Note: if the pin symbolbutton is pressed in, thewindow is fixed. To unfixit, click on this buttonagain.

146 A30808-X3247-K356-4-7630



3.33 Bit Error Rate Test (BERT) with MS-Loop (optional)

The carrier unit is able to test major parts of its own transmitter and receiver functionalityduring a special test mode. During this test mode the transmit signal is converted to thecorresponding receive frequency and routed to the receiver input via a local test loop(LTL).

Additional info can be found in the online help of the Abis simulator.

1 Start Test

b Start the test via the main window (’AbisSimClient’ window):

– Select the tab ’Actions’ in the menu tree section.

– Select the folder ’Channeltest with MTC/BERT’ in the menu tree:testseq.act --> Sequences --> Channeltest with MTC/BERT.

– Press the ’+’ sign next to the folder ’Channeltest with MTC/BERT’.

– Click with the right mouse button on ’[0] Set Param [...’


iThe current TestSim IMSI for the mobile station corresponding to the system standardGSM 850/900/1800/1900 and the customer has to be chosen.

Click on...

A30808-X3247-K356-4-7630 147




– Select the required channel for the test.

– Choose the number of the IMSI you want to use (see Procedure: 3.30 Step:3, IMSI number 1 - 5).


– Click with the right mouse button on ’[3] Start Bert [...’.





148 A30808-X3247-K356-4-7630



– Select the measurement time (’Meastime’) for the test.

– If you want to change the default value, follow the next step.

– Click with the right mouse button on ’[4] Wait ...’



– Choose the wait time.


– Press the ’-’ sign next to the folder ’Channeltest with MTC/BERT’ in the menutree of the main window.


The test starts.

2 Test Execution

The mobile phone rings.

– Press the connect button on the mobile phone.

The test runs until the chosen measurement time is reached.The BERT measurement values are listed in the corresponding section of themain window.

END


iThe wait time must be longer than the above chosen measurement time(’Meastime’).

A30808-X3247-K356-4-7630 149



3.34 Mobile Controlled Test Sequence (optional)

The “Mobile controlled Test sequence” is an optional feature to control the tests via amobile phone. To use this function you need a special access code.

The following example explains the test sequence procedure.

1 Select a “CbThema”

b Select a “CBThema”:

– Select the tab “Config” in the menu tree section of the main window (“Abis-SimClient” window).

The tree “Configuration” appears.

– Double-click on “Special”.

The “Special” page opens:

– Select a value for the "CbThema" (default: 12).

– Click on the "Apply" button and close the window.

– The same code must be entered on the mobile phone.

– Refer to the installation guide of the mobile phone to perform this task.

iTest conditions: One BTS containing two cells (cell 0 and cell 1). Each of these cells isequipped with two TRX and each TRX is configured with seven channels. The test se-quence is configured with default settings.

i Prerequisites: You must select a "CbThema". To do so, follow the next steps.

150 A30808-X3247-K356-4-7630



2 Configuration Settings

b Configuration Settings:

– Select the tab “Actions” in the menu tree section of the main window (“Abis-SimClient” window).

– Select the folder “MobilControlledTestsequence” in the menu tree (test-seq.act\TestCases\MobilControlledTestsequence).

– Click with the right mouse button on "[0] Testsequence 1 ...".

– Click on "Properties" in the appearing pop-up menu.

The “Property” window opens.

Configure the test sequence to the base station that is to be tested. In this exam-ple the default configuration is used with the following settings:

– Meas Mode: BERT

– Meas Time: 30 s

– Call Modes in Cell: 1.MOC - next MTC (i.e. the test is started in cell 0 by aMOC; all further tests are started with a MTC automatically)

– Bert Mode: BERT_MS_LOOP

– Bert Polynom: E9_1

– sel Imsi: 1

– Select "Ch1" (click left mouse button only once).

– Click on the "Apply" button.

A30808-X3247-K356-4-7630 151



3 Start the Test Sequence

b Start the Test Sequence:

In the main window (“AbisSimClient” window) “MobilControlledTestsequence” isselected (tab "Actions", menu tree: testseq.act\TestCases\MobileCon-trolledTestsequence):


The sequence starts.The “Testcase Action State” window opens.

152 A30808-X3247-K356-4-7630



The "Status" box shows the message "Do you see the MNC, MCC in the Mo-bile?”

– If you are not connected to the cell, click the "No" button,

– if you see the MNC and MCC (e.g. MNC 262, MCC 09), click the "Yes" button.

If you click on "Yes", the mobile phone display shows the message "Wait forMOC".If you click on "No", the following window opens:

The "Status" box shows the message "Go to the first Agent for testing and followthe CB_SMS_CMD’s".

– Confirm the status message by clicking on "Yes", then power up the mobilephone.

– Follow the CB message on the mobile phone display.

– Start the test of the individual channels in cell 0 with a "MOC".

After the test a message is shown on the display, e.g. "Test ok 0/0/2".The tests are repeated until the mobile phone moves to the next cell of the BTSunder test (cell 1 in this example) or until the test is stopped by pressing a keyon the mobile phone. ......3.35

The progress of the test sequence is recorded on the "Trace" page in the "Simu-lation Output" window.

END

A30808-X3247-K356-4-7630 153



3.35 Key Functions of the Mobile Phone During Test Sequence

The keys on the mobile phone can be used to influence the progress of the test se-quence. The connection to the BTS must be set up before the test sequence can bestarted.

After selecting a command with the corresponding key (e.g. “3”), the call must be dis-connected by pressing the “disconnect” key at the mobile phone. The respective mes-sage (in this case, “Measure next channel with BERT”) is then displayed on the phone.After the subsequently following message “Waiting for MOC”, reconnect the mobilephone with the “connect” key in order to start the next test.

Dialing Number and Related Commands / Effects:

DTMFCommand

Meaning Effect

0 Reserved -

1 Test sequence re-set

Ends the current test sequence.Resets the sequence to the first cell and the firstTRX in this cell.The simulator is in the initial position prior to thefirst call in order to restart the test.

2 Test next channel(+1)

The connection via the active channel is cleareddown after the end of the test.The channel number is increased by "1"

3 Measure nextchannel withBERT

The connection via the active channel is cleareddown after the end of the test and the next channelis activated.A BERT is performed using the preset measure-ment time.

4 Measure nextchannel withEcho-Loop

The connection via the active channel is cleareddown after the end of the test and the next channelis activated.An Echo Loop is then set up.

5 Select and testnext channel

The connection via the active channel is cleareddown after the end of the test.The new channel is set by three entries using thekeypad:1. Enter: first digit of TRX number2. Enter: second digit of TRX number3. Enter: air timeslot (channel)The TRX number is always entered as 2 digits, e.g."01" for TRX 1.

6 Change cell The call is terminated by the network after the cur-rent test. Then it changes to the next cell and thetest is resumed.

Tab. 3.2 Key Commands for Mobile Controlled Test Sequence

154 A30808-X3247-K356-4-7630



7 Display cell infor-mation

There is a short pause at the end of the current testand the mobile phone displays the message"Channels: ..., successful: ...".

8 Display test menu There is a short pause at the end of the current testand the mobile phone displays the test menu.

i For detailed information please refer to the online help of the Abis simulator.

DTMFCommand

Meaning Effect

Tab. 3.2 Key Commands for Mobile Controlled Test Sequence

A30808-X3247-K356-4-7630 155



3.36 Setup for Optional RF-Tests

3.36.1 Measuring Setup

For he necessary tools, see chapter 1.5.1

– Connect the Trigger adapter with CU.

– Connect test lead 1 from Gate Trigger Input (TTL) at HP8594A (Backplane) to Trig-ger adapter X2 (T-Frame). See Fig. 3.4.

– Connect test lead 2 from Input 50 Ohm at HP 8594A to Test-Output at FICOM or DU-AMCO (BTSE) (beware of 40 dB reduction from normal Antenna Output).

– Connect Loop at HP 8594A backplane from Gate Output to EXT Trig Input (TTL).

Fig. 3.3 Measurement Set-Up

Fig. 3.4 Used Trigger Adapter (TAD-L)

X3

X4X1X2

CU

Cable 1

Cable 2

Testout

FICOM/DUAMCO

BTSE

TAD-L

HP 85715A

INPUT

GATEOUTPUT(TTL)

PLUG IN CARD

50 Ohm

EXT TRIGINPUT(TTL)

GATE TRIGGERINPUT(TTL)(BACKPLANE)

HP8594A

AMP100pin

X4

X1

X2

X3

T-Frame

156 A30808-X3247-K356-4-7630



Fig. 3.5 Trigger Adapter (TAD-L) with Housing and Adapter (TADADPT)

TADADPT

X3

X1

X2

X4

T-Frame

A30808-X3247-K356-4-7630 157



3.37 Channel Activation/Deactivation

It is possible to activate/deactivate single channels, a complete TRX, or all TRXs of acell.

Precondition: The Abis Simulation SW is started and the BTSE is configured.

1 Starting the Database Download Without BCCH

b Start the Database Download without BCCH:


– Select the folder “SingleActions” in the menu tree.

– Select “[10] DBAligment No Bcch”.


iFor TCH-Loop and BERT-Tests you must download the database with BCCH. Refer to3.31 "Database Alignment".

158 A30808-X3247-K356-4-7630



The database download starts.The download was successful if the following message is displayed in the“Simulation Status/Result” section of the main window:Result: success.

2 Channel Activation

b Channel Activation:

– Click with the right mouse button on “[11] Channel Act (Cell...)”.

A30808-X3247-K356-4-7630 159



– Select “Properties” in the appearing pop-up menu.

The “Property: [Channel Act]” window opens. It is possible to activate a singlechannel, a complete TRX, or all TRXs from one cell (see below):

To change the default “Power Reduction”, proceed to step... h...3After the required channel/TRX/cell was activated, you can perform yourmeasurements.

To measure the output power, activate the required TRX and use your measure-ment equipment.For Spectrum Analyzer Measurements, activate the required channel and referto... i ...3.38

After the measurements, the channels/TRXs/cells must be deactivated.

To deactivate the channels/TRXs/cells, proceed with step... h...4

To activate a sin-gle channel, clickon the requiredchannel, e.g.:

To activate allTRXs of a cell,click on the re-

quired cell, e.g.:

To activate a com-plect TRX, click onthe required TRX,

e.g.:

iThere is a default value “Power Reduction = 6” in the database. This meansthat all TRXs are 12 dB less than the maximum power.

160 A30808-X3247-K356-4-7630



3 Changing the Default “Power Reduction”

b Changing the Default “Power Reduction”:

– Click with the right mouse button on “[9] Change Sngle Attr”.


The following window opens:

– Select the required “Power Reduction” and click on the “Apply” button.

– Click on the green arrow in the tool bar of the main window (“AbisSimClient”window).

The “Power Reduction” is set to the required value.

After the required channel/TRX/cell was activated, you can perform yourmeasurements.

After the measurements, the channels/TRXs/cells must be deactivated.

To deactivate the channels/TRXs/cells, proceed with step... h...4

A30808-X3247-K356-4-7630 161



4 Channel Deactivation

b Channel Deactivation:


– Click with the right mouse button on “[12] Channel Deact (Cell...)” in the folder“SingleActions” in the menu tree.

162 A30808-X3247-K356-4-7630




The following window opens:

– Select the channel, TRX, or cell you want to deactivate or tick the check box“Deactivate all” to deactivate all activated channels.

– Click on the “Apply” button.

– Click on the green arrow in the tool bar of the main window (“AbisSimClient”window).

The selected channels are deactivated.

END

A30808-X3247-K356-4-7630 163



3.38 Spectrum Analyzer Measurements

There are some optional useful RF measurements with a spectrum analyzer (here HP8594A) to check the functioning of the BTS.

Start the Abis simulation and check the SW card (Plug in Card, HP 85715B GSM 900Measurements Personality Card or HP 85722 DCS 1800 Measurements PersonalityCard) before measurements are executed.

After switching on the spectrum analyzer, you must wait until it has warmed up to its op-erating temperature. The warm-up phase lasts about 15 minutes and is indicated on thescreen by the message "OVEN COLD". As soon as the warm-up phase is over, the mes-sage "OVEN COLD" disappears. Then you must start the self-calibration routine of thespectrum analyzer in order to prepare the analyzer for measurement operation.

Fig. 3.6 Spectrum Analyzer HP8954A

The following blocks show 3 tests:

Mode

Softkeys

164 A30808-X3247-K356-4-7630



1 P vs T Frame

The spectrum analyzer is triggered externally.

– Press the key "MODE"

– Press the softkeys of the spectrum analyzer next to the corresponding screentext in the following order:– "DCS 1800/GSM Analyser" or "GSM Analyser"– "Physical Channel"– "Auto Function"– "Auto ARFCN"


– Press the softkeys next to the corresponding screen text in the following or-der:– "DCS 1800/GSM Analyser" or "GSM Analyser"– "Power vs Time"– "P vs T Frame"

Result: Value Power vs Time

2 P vs T Timeslot


– Press the softkeys of the spectrum analyzer next to the corresponding screentext in the following order:– "DCS 1800/GSM Analyzer" or "GSM Analyzer"– "Physical Channel"– "Auto Function"– "Auto ARFCN & TN"


– Press the softkeys next to the corresponding screen text in the following or-der:– "DCS 1800/GSM Analyzer" or "GSM Analyzer"– "Power vs Time"– "P vs T Timeslot"

Result: Limit Pass or Limit Fail

A30808-X3247-K356-4-7630 165



3 Output of Spectrum Switching Transients



– Press the softkeys of the spectrum analyzer next to the corresponding screentext in the following order:– “DCS 1800/GSM Analyser" or "GSM Analyser"– "Physical Channel"– "Auto Function"– "Auto ARFCN"


– Press the softkeys next to the corresponding screen text in the following or-der:– "DCS 1800/GSM Analyzer" or "GSM Analyzer"– "Out RF Spectrum"– "RF Spect Transient"– "Transient Swept"

Result: Limit Pass or Limit Fail

For more detailed information on RF-measurements read the HP User Guide.

END

166 A30808-X3247-K356-4-7630



3.39 VSWR Test

For VSWR test, disconnect the antenna cable! After disconnecting all antenna cables,the respective VSWR LEDs on the CUs should illuminate.

3.40 RFI-Confirmation: Unit ATMN

All commissioning tasks on site for providing successfulintegration have to be confirmed in the ATMN:BTSE.

A30808-X3247-K356-4-7630 167



4 Tables, Lists and Figures

168 A30808-X3247-K356-4-7630



A30808-X3247-K356-4-7630 169



4.1 Frequency/Channel Conversion Table

4.1.1 GSM Table

Frequency-Band ARFCN Quantity Uplink (MHz) Downlink(MHz)

E-GSM 900 0...124 125 890.0 - 914.8 935.0 - 959.8

975...1023 49 880.2 - 889.8 925.2 - 934.8

P-GSM 900 1...124 124 890.2 - 914.8 935.2 - 959.8

R-GSM 900 0...124 125 890.0 - 914.8 935.0 - 959.8

955...1023 69 876.2 - 889.8 921.2 - 934.8

GSM-850 128...251 124 824.2 - 848.8 869.2 - 893.8

GSM-RE 1...55 55 890.2 - 901.0 935.2 - 946.0

955...1023 69 876.2 - 889.8 921.2 - 934.8

DCS 1800 512...885 374 1710.2 -1784.8 1805.2 -1879.8

PCS 1900 512...810 299 1850.2 -1909.8 1930.2 -1989.8

Tab. 4.1 Frequency/Channel Conversion Table

ARFCN Frequency (MHz) ARFCN Frequency (MHz) ARFCN Frequency (MHz)

Uplink Downlink Uplink Downlink Uplink Downlink

0 890.0 935.0 1 890.2 935.2 2 890.4 935.4

3 890.6 935.6 4 890.8 935.8 5 891.0 936.0

6 891.2 936.2 7 891.4 936.4 8 891.6 936.6

9 891.8 936.8 10 892.0 937.0 11 892.2 937.2

12 892.4 937.4 13 892.6 937.6 14 892.8 937.8

15 893.0 938.0 16 893.2 938.2 17 893.4 938.4

18 893.6 938.6 19 893.8 938.8 20 894.0 939.0

21 894.2 939.2 22 894.4 939.4 23 894.6 939.6

24 894.8 939.8 25 895.0 940.0 26 895.2 940.2

27 895.4 940.4 28 895.6 940.6 29 895.8 940.8

30 896.0 941.0 31 896.2 941.2 32 896.4 941.4

33 896.6 941.6 34 896.8 941.8 35 897.0 942.0

36 897.2 942.2 37 897.4 942.4 38 897.6 942.6

39 897.8 942.8 40 898.0 943.0 41 898.2 943.2

42 898.4 943.4 43 898.6 943.6 44 898.8 943.8

Tab. 4.2 GSM Table

170 A30808-X3247-K356-4-7630



45 899.0 944.0 46 899.2 944.2 47 899.4 944.4

48 899.6 944.6 49 899.8 944.8 50 900.0 945.0

51 900.2 945.2 52 900.4 945.4 53 900.6 945.6

54 900.8 945.8 55 901.0 946.0 56 901.2 946.2

57 901.4 946.4 58 901.6 946.6 59 901.8 946.8

60 902.0 947.0 61 902.2 947.2 62 902.4 947.4

63 902.6 947.6 64 902.8 947.8 65 903.0 948.0

66 903.2 948.2 67 903.4 948.4 68 903.6 948.6

69 903.8 948.8 70 904.0 949.0 71 904.2 949.2

72 904.4 949.4 73 904.6 949.6 74 904.8 949.8

75 905.0 950.0 76 905.2 950.2 77 905.4 950.4

78 905.6 950.6 79 905.8 950.8 80 906.0 951.0

81 906.2 951.2 82 906.4 951.4 83 906.6 951.6

84 906.8 951.8 85 907.0 952.0 86 907.2 952.2

87 907.4 952.4 88 907.6 952.6 89 907.8 952.8

90 908.0 953.0 91 908.2 953.2 92 908.4 953.4

93 908.6 953.6 94 908.8 953.8 95 909.0 954.0

96 909.2 954.2 97 909.4 954.4 98 909.6 954.6

99 909.8 954.8 100 910.0 955.0 101 910.2 955.2

102 910.4 955.4 103 910.6 955.6 104 910.8 955.8

105 911.0 956.0 106 911.2 956.2 107 911.4 956.4

108 911.6 956.6 109 911.8 956.8 110 912.0 957.0

111 912.2 957.2 112 912.4 957.4 113 912.6 957.6

114 912.8 957.8 115 913.0 958.0 116 913.2 958.2

117 913.4 958.4 118 913.6 958.6 119 913.8 958.8

120 914.0 959.0 121 914.2 959.2 122 914.4 959.4

123 914.6 959.6 124 914.8 959.8

128 824.2 869.2 129 824.4 869.4 130 824.6 869.6

131 824.8 869.8 132 825.0 870.0 133 825.2 870.2

134 825.4 870.4 135 825.6 870.6 136 825.8 870.8

137 826.0 871.0 138 826.2 871.2 139 826.4 871.4

140 826.6 871.6 141 826.8 871.8 142 827.0 872.0

143 827.2 872.2 144 827.4 872.4 145 827.6 872.6



Tab. 4.2 GSM Table

A30808-X3247-K356-4-7630 171



146 827.8 872.8 147 828.0 873.0 148 828.2 873.2

149 828.4 873.4 150 828.6 873.6 151 828.8 873.8

152 829.0 874.0 153 829.2 874.2 154 829.4 874.4

155 829.6 874.6 156 829.8 874.8 157 830.0 875.0

158 830.2 875.2 159 830.4 875.4 160 830.6 875.6

161 830.8 875.8 162 831.0 876.0 163 831.2 876.2

164 831.4 876.4 165 831.6 876.6 166 831.8 876.8

167 832.0 877.0 168 832.2 877.2 169 832.4 877.4

170 832.6 877.6 171 832.8 877.8 172 833.0 878.0

173 833.2 878.2 174 833.4 878.4 175 833.6 878.6

176 833.8 878.8 177 834.0 879.0 178 834.2 879.2

179 834.4 879.4 180 834.6 879.6 181 834.8 879.8

182 835.0 880.0 183 835.2 880.2 184 835.4 880.4

185 835.6 880.6 186 835.8 880.8 187 836.0 881.0

188 836.2 881.2 189 836.4 881.4 190 836.6 881.6

191 836.8 881.8 192 837.0 882.0 193 837.2 882.2

194 837.4 882.4 195 837.6 882.6 196 837.8 882.8

197 838.0 883.0 198 838.2 883.2 199 838.4 883.4

200 838.6 883.6 201 838.8 883.8 202 839.0 884.0

203 839.2 884.2 204 839.4 884.4 205 839.6 884.6

206 839.8 884.8 207 840.0 885.0 208 840.2 885.2

209 840.4 885.4 210 840.6 885.6 211 840.8 885.8

212 841.0 886.0 213 841.2 886.2 214 841.4 886.4

215 841.6 886.6 216 841.8 886.8 217 842.0 887.0

218 842.2 887.2 219 842.4 887.4 220 842.6 887.6

221 842.8 887.8 222 843.0 888.0 223 843.2 888.2

224 843.4 888.4 225 843.6 888.6 226 843.8 888.8

227 844.0 889.0 228 844.2 889.2 229 844.4 889.4

230 844.6 889.6 231 844.8 889.8 232 845.0 890.0

233 845.2 890.2 234 845.4 890.4 235 845.6 890.6

236 845.8 890.8 237 846.0 891.0 238 846.2 891.2

239 846.4 891.4 240 846.6 891.6 241 846.8 891.8

242 847.0 892.0 243 847.2 892.2 244 847.4 892.4



Tab. 4.2 GSM Table

172 A30808-X3247-K356-4-7630



245 847.6 892.6 246 847.8 892.8 247 848.0 893.0

248 848.2 893.2 249 848.4 893.4 250 848.6 893.6

251 848.8 893.8

955 876.2 921.2 956 876.4 921.4 957 876.6 921.6

958 876.8 921.8 959 877.0 922.0 960 877.2 922.2

961 877.4 922.4 962 877.6 922.6 963 877.8 922.8

964 878.0 923.0 965 878.2 923.2 966 878.4 923.4

967 878.6 923.6 968 878.8 923.8 969 879.0 924.0

970 879.2 924.2 971 879.4 924.4 972 879.6 924.6

973 879.8 924.8 974 880.0 925.0 975 880.2 925.2

976 880.4 925.4 977 880.6 925.6 978 880.8 925.8

979 881.0 926.0 980 881.2 926.2 981 881.4 926.4

982 881.6 926.6 983 881.8 926.8 984 882.0 927.0

985 882.2 927.2 986 882.4 927.4 987 882.6 927.6

988 882.8 927.8 989 883.0 928.0 990 883.2 928.2

991 883.4 928.4 992 883.6 928.6 993 883.8 928.8

994 884.0 929.0 995 884.2 929.2 996 884.4 929.4

997 884.6 929.6 998 884.8 929.8 999 885.0 930.0

1000 885.2 930.2 1001 885.4 930.4 1002 885.6 930.6

1003 885.8 930.8 1004 886.0 931.0 1005 886.2 931.2

1006 886.4 931.4 1007 886.6 931.6 1008 886.8 931.8

1009 887.0 932.0 1010 887.2 932.2 1011 887.4 932.4

1012 887.6 932.6 1013 887.8 932.8 1014 888.0 933.0

1015 888.2 933.2 1016 888.4 933.4 1017 888.6 933.6

1018 888.8 933.8 1019 889.0 934.0 1020 889.2 934.2

1021 889.4 934.4 1022 889.6 934.6 1023 889.8 934.8



Tab. 4.2 GSM Table

A30808-X3247-K356-4-7630 173



4.1.2 DCS Table



512 1710.2 1805.2 513 1710.4 1805.4 514 1710.6 1805.6

515 1710.8 1805.8 516 1711.0 1806 517 1711.2 1806.2

518 1711.4 1806.4 519 1711.6 1806.6 520 1711.8 1806.8

521 1712.0 1807.0 522 1712.2 1807.2 523 1712.4 1807.4

524 1712.6 1807.6 525 1712.8 1807.8 526 1713.0 1808.0

527 1713.2 1808.2 528 1713.4 1808.4 529 1713.6 1808.6

530 1713.8 1808.8 531 1714.0 1809 532 1714.2 1809.2

533 1714.4 1809.4 534 1714.6 1809.6 535 1714.8 1809.8

536 1715.0 1810.0 537 1715.2 1810.2 538 1715.4 1810.4

539 1715.6 1810.6 540 1715.8 1810.8 541 1716.0 1811.0

542 1716.2 1811.2 543 1716.4 1811.4 544 1716.6 1811.6

545 1716.8 1811.8 546 1717.0 1812 547 1717.2 1812.2

548 1717.4 1812.4 549 1717.6 1812.6 550 1717.8 1812.8

551 1718.0 1813.0 552 1718.2 1813.2 553 1718.4 1813.4

554 1718.6 1813.6 555 1718.8 1813.8 556 1719.0 1814.0

557 1719.2 1814.2 558 1719.4 1814.4 559 1719.6 1814.6

560 1719.8 1814.8 561 1720.0 1815 562 1720.2 1815.2

563 1720.4 1815.4 564 1720.6 1815.6 565 1720.8 1815.8

566 1721.0 1816.0 567 1721.2 1816.2 568 1721.4 1816.4

569 1721.6 1816.6 570 1721.8 1816.8 571 1722.0 1817.0

572 1722.2 1817.2 573 1722.4 1817.4 574 1722.6 1817.6

575 1722.8 1817.8 576 1723.0 1818 577 1723.2 1818.2

578 1723.4 1818.4 579 1723.6 1818.6 580 1723.8 1818.8

581 1724.0 1819.0 582 1724.2 1819.2 583 1724.4 1819.4

584 1724.6 1819.6 585 1724.8 1819.8 586 1725.0 1820.0

587 1725.2 1820.2 588 1725.4 1820.4 589 1725.6 1820.6

590 1725.8 1820.8 591 1726.0 1821.0 592 1726.2 1821.2

593 1726.4 1821.4 594 1726.6 1821.6 595 1726.8 1821.8

596 1727.0 1822.0 597 1727.2 1822.2 598 1727.4 1822.4

599 1727.6 1822.6 600 1727.8 1822.8 601 1728.0 1823.0

Tab. 4.3 DCS Table

174 A30808-X3247-K356-4-7630



602 1728.2 1823.2 603 1728.4 1823.4 604 1728.6 1823.6

605 1728.8 1823.8 606 1729.0 1824.0 607 1729.2 1824.2

608 1729.4 1824.4 609 1729.6 1824.6 610 1729.8 1824.8

611 1730.0 1825.0 612 1730.2 1825.2 613 1730.4 1825.4

614 1730.6 1825.6 615 1730.8 1825.8 616 1731.0 1826.0

617 1731.2 1826.2 618 1731.4 1826.4 619 1731.6 1826.6

620 1731.8 1826.8 621 1732.0 1827.0 622 1732.2 1827.2

623 1732.4 1827.4 624 1732.6 1827.6 625 1732.8 1827.8

626 1733.0 1828.0 627 1733.2 1828.2 628 1733.4 1828.4

629 1733.6 1828.6 630 1733.8 1828.8 631 1734.0 1829.0

632 1734.2 1829.2 633 1734.4 1829.4 634 1734.6 1829.6

635 1734.8 1829.8 636 1735.0 1830.0 637 1735.2 1830.2

638 1735.4 1830.4 639 1735.6 1830.6 640 1735.8 1830.8

641 1736.0 1831.0 642 1736.2 1831.2 643 1736.4 1831.4

644 1736.6 1831.6 645 1736.8 1731.8 646 1737.0 1832.0

647 1737.2 1832.2 648 1737.4 1832.4 649 1737.6 1832.6

650 1737.8 1832.8 651 1738.0 1833.0 652 1738.2 1833.2

653 1738.4 1833.4 654 1738.6 1833.6 655 1738.8 1833.8

656 1739.0 1834.0 657 1739.2 1834.2 658 1739.4 1834.4

659 1739.6 1834.6 660 1739.8 1834.8 661 1740.0 1835.0

662 1740.2 1835.2 663 1740.4 1835.4 664 1740.6 1835.6

665 1740.8 1835.8 666 1741.0 1836.0 667 1741.2 1836.2

668 1741.4 1836.4 669 1741.6 1836.6 670 1741.8 1836.8

671 1742.0 1837.0 672 1742.2 1837.2 673 1742.4 1837.4

674 1742.6 1837.6 675 1742.8 1837.8 676 1743.0 1838.0

677 1743.2 1838.2 678 1743.4 1838.4 679 1743.6 1838.6

680 1743.8 1838.8 681 1744.0 1839.0 682 1744.2 1839.2

683 1744.4 1839.4 684 1744.6 1839.6 685 1744.8 1839.8

686 1745.0 1840.0 687 1745.2 1840.2 688 1745.4 1840.4

689 1745.6 1840.6 690 1745.8 1840.8 691 1746.0 1841.0

692 1746.2 1841.2 693 1746.4 1841.4 694 1746.6 1841.6

695 1746.8 1841.8 696 1747.0 1842.0 697 1747.2 1842.2

698 1747.4 1842.4 699 1747.6 1842.6 700 1747.8 1842.8



Tab. 4.3 DCS Table

A30808-X3247-K356-4-7630 175



701 1748.0 1843.0 702 1748.2 1843.2 703 1748.4 1843.4

704 1748.6 1843.6 705 1748.8 1843.8 706 1749.0 1844.0

707 1749.2 1844.2 708 1749.4 1844.4 709 1749.6 1844.6

710 1749.8 1844.8 711 1750.0 1845.0 712 1750.2 1845.2

713 1750.4 1845.4 714 1750.6 1845.6 715 1750.8 1845.8

716 1751.0 1846.0 717 1751.2 1846.2 718 1751.4 1846.4

719 1751.6 1846.6 720 1751.8 1846.8 721 1752.0 1847.0

722 1752.2 1847.2 723 1752.4 1847.4 724 1752.6 1847.6

725 1752.8 1847.8 726 1753.0 1848.0 727 1753.2 1848.2

728 1753.4 1848.4 729 1753.6 1848.6 730 1753.8 1848.8

731 1754.0 1849.0 732 1754.2 1849.2 733 1754.4 1849.4

734 1754.6 1849.6 735 1754.8 1849.8 736 1755.0 1850.0

737 1755.2 1850.2 738 1755.4 1850.4 739 1755.6 1850.6

740 1755.8 1850.8 741 1756.0 1851.0 742 1756.2 1851.2

743 1756.4 1851.4 744 1756.6 1851.6 745 1756.8 1851.8

746 1757.0 1852.0 747 1757.2 1852.2 748 1757.4 1852.4

749 1757.6 1852.6 750 1757.8 1852.8 751 1758.0 1853.0

752 1758.2 1853.2 753 1758.4 1853.4 754 1758.6 1853.6

755 1758.8 1853.8 756 1759.0 1854.0 757 1759.2 1854.2

758 1759.4 1854.4 759 1759.6 1854.6 760 1759.8 1854.8

761 1760.0 1855.0 762 1760.2 1855.2 763 1760.4 1855.4

764 1760.6 1855.6 765 1760.8 1855.8 766 1761.0 1856.0

767 1761.2 1856.2 768 1761.4 1856.4 769 1761.6 1856.6

770 1761.8 1856.8 771 1762.0 1857.0 772 1762.2 1857.2

773 1762.4 1857.4 774 1762.6 1857.6 775 1762.8 1857.8

776 1763.0 1858.0 777 1763.2 1858.2 778 1763.4 1858.4

779 1763.6 1858.6 780 1763.8 1858.8 781 1764.0 1859.0

782 1764.2 1859.2 783 1764.4 1859.4 784 1764.6 1859.6

785 1764.8 1859.8 786 1765.0 1860.0 787 1765.2 1860.2

788 1765.4 1860.4 789 1765.6 1860.6 790 1765.8 1860.8

791 1766.0 1861.0 792 1766.2 1861.2 793 1766.4 1861.4

794 1766.6 1861.6 795 1766.8 1861.8 796 1767.0 1862.0

797 1767.2 1862.2 798 1767.4 1862.4 799 1767.6 1862.6



Tab. 4.3 DCS Table

176 A30808-X3247-K356-4-7630



800 1767.8 1862.8 801 1768.0 1863.0 802 1768.2 1863.2

803 1768.4 1863.4 804 1768.6 1863.6 805 1768.8 1863.8

806 1769.0 1864.0 807 1769.2 1864.2 808 1769.4 1864.4

809 1769.6 1864.6 810 1769.8 1864.8 811 1770.0 1865.0

812 1770.2 1865.2 813 1770.4 1865.4 814 1770.6 1865.6

815 1770.8 1865.8 816 1771.0 1866.0 817 1771.2 1866.2

818 1771.4 1866.4 819 1771.6 1866.6 820 1771.8 1866.8

821 1772.0 1867.0 822 1772.2 1867.2 823 1772.4 1867.4

824 1772.6 1867.6 825 1772.8 1867.8 826 1773.0 1868.0

827 1773.2 1868.2 828 1773.4 1868.4 829 1773.6 1868.6

830 1773.8 1868.8 831 1774.0 1869.0 832 1774.2 1869.2

833 1774.4 1869.4 834 1774.6 1869.6 835 1774.8 1869.8

836 1775.0 1870.0 837 1775.2 1870.2 838 1775.4 1870.4

839 1775.6 1870.6 840 1775.8 1870.8 841 1776.0 1871.0

842 1776.2 1871.2 843 1776.4 1871.4 844 1776.6 1871.6

845 1776.8 1871.8 846 1777.0 1872.0 847 1777.2 1872.2

848 1777.4 1872.4 849 1777.6 1872.6 850 1777.8 1872.8

851 1778.0 1873.0 852 1778.2 1873.2 853 1778.4 1873.4

854 1778.6 1873.6 855 1778.8 1873.8 856 1779.0 1874.0

857 1779.2 1874.2 858 1779.4 1874.4 859 1779.6 1874.6

860 1779.8 1874.8 861 1780.0 1875.0 862 1780.2 1875.2

863 1780.4 1875.4 864 1780.6 1875.6 865 1780.8 1875.8

866 1781.0 1876.0 867 1781.2 1876.2 868 1781.4 1876.4

869 1781.6 1876.6 870 1781.8 1876.8 871 1782.0 1877.0

872 1782.2 1877.2 873 1782.4 1877.4 874 1782.6 1877.6

875 1782.8 1877.8 876 1783.0 1878.0 877 1783.2 1878.2

878 1783.4 1878.4 879 1783.6 1878.6 880 1783.8 1878.8

881 1784.0 1879.0 882 1784.2 1879.2 883 1784.4 1879.4

884 1784.6 1879.6 885 1784.8 1879.8



Tab. 4.3 DCS Table

A30808-X3247-K356-4-7630 177



4.1.3 PCS Table



512 1850.2 1930.2 513 1850.4 1930.4 514 1850.6 1930.6

515 1850.8 1930.8 516 1851.0 1931.0 517 1851.2 1931.2

518 1851.4 1931.4 519 1851.6 1931.6 520 1851.8 1931.8

521 1852.0 1932.0 522 1852.2 1932.2 523 1852.4 1932.4

524 1852.6 1932.6 525 1852.8 1932.8 526 1853.0 1933.0

527 1853.2 1933.2 528 1853.4 1933.4 529 1853.6 1933.6

530 1853.8 1933.8 531 1854.0 1934.0 532 1854.2 1934.2

533 1854.4 1934.4 534 1854.6 1934.6 535 1854.8 1934.8

536 1855.0 1935.0 537 1855.2 1935.2 538 1855.4 1935.4

539 1855.6 1935.6 540 1855.8 1935.8 541 1856.0 1936.0

542 1856.2 1936.2 543 1856.4 1936.4 544 1856.6 1936.6

545 1856.8 1936.8 546 1857.0 1937.0 547 1857.2 1937.2

548 1857.4 1937.4 549 1857.6 1937.6 550 1857.8 1937.8

551 1858.0 1938.0 552 1858.2 1938.2 553 1858.4 1938.4

554 1858.6 1938.6 555 1858.8 1938.8 556 1859.0 1939.0

557 1859.2 1939.2 558 1859.4 1939.4 559 1859.6 1939.6

560 1859.8 1939.8 561 1860.0 1940.0 562 1860.2 1940.2

563 1860.4 1940.4 564 1860.6 1940.6 565 1860.8 1940.8

566 1861.0 1941.0 567 1861.2 1941.2 568 1861.4 1941.4

569 1861.6 1941.6 570 1861.8 1941.8 571 1862.0 1942.0

572 1862.2 1942.2 573 1862.4 1942.4 574 1862.6 1942.6

575 1862.8 1942.8 576 1863.0 1943.0 577 1863.2 1943.2

578 1863.4 1943.4 579 1863.6 1943.6 580 1863.8 1943.8

581 1864.0 1944.0 582 1864.2 1944.2 583 1864.4 1944.4

584 1864.6 1944.6 585 1864.8 1944.8 586 1865.0 1945.0

587 1865.2 1945.2 588 1865.4 1945.4 589 1865.6 1945.6

590 1865.8 1945.8 591 1866.0 1946.0 592 1866.2 1946.2

593 1866.4 1946.4 594 1866.6 1946.6 595 1866.8 1946.8

596 1867.0 1947.0 597 1867.2 1947.2 598 1867.4 1947.4

599 1867.6 1947.6 600 1867.8 1947.8 601 1868.0 1948.0

Tab. 4.4 PCS Table

178 A30808-X3247-K356-4-7630



602 1868.2 1948.2 603 1868.4 1948.4 604 1868.6 1948.6

605 1868.8 1948.8 606 1869.0 1949.0 607 1869.2 1949.2

608 1869.4 1949.4 609 1869.6 1949.6 610 1869.8 1949.8

611 1870.0 1950.0 612 1870.2 1950.2 613 1870.4 1950.4

614 1870.6 1950.6 615 1870.8 1950.8 616 1871.0 1951.0

617 1871.2 1951.2 618 1871.4 1951.4 619 1871.6 1951.6

620 1871.8 1951.8 621 1872.0 1952.0 622 1872.2 1952.2

623 1872.4 1952.4 624 1872.6 1952.6 625 1872.8 1952.8

626 1873.0 1953.0 627 1873.2 1953.2 628 1873.4 1953.4

629 1873.6 1953.6 630 1873.8 1953.8 631 1874.0 1954.0

632 1874.2 1954.2 633 1874.4 1954.4 634 1874.6 1954.6

635 1874.8 1954.8 636 1875.0 1955.0 637 1875.2 1955.2

638 1875.4 1955.4 639 1875.6 1955.6 640 1875.8 1955.8

641 1876.0 1956.0 642 1876.2 1956.2 643 1876.4 1956.4

644 1876.6 1956.6 645 1876.8 1956.8 646 1877.0 1957.0

647 1877.2 1957.2 648 1877.4 1957.4 649 1877.6 1957.6

650 1877.8 1957.8 651 1878.0 1958.0 652 1878.2 1958.2

653 1878.4 1958.4 654 1878.6 1958.6 655 1878.8 1958.8

656 1879.0 1959.0 657 1879.2 1959.2 658 1879.4 1959.4

659 1879.6 1959.6 660 1879.8 1959.8 661 1880.0 1960.0

662 1880.2 1960.2 663 1880.4 1960.4 664 1880.6 1960.6

665 1880.8 1960.8 666 1881.0 1961.0 667 1881.2 1961.2

668 1881.4 1961.4 669 1881.6 1961.6 670 1881.8 1961.8

671 1882.0 1962.0 672 1882.2 1962.2 673 1882.4 1962.4

674 1882.6 1962.6 675 1882.8 1962.8 676 1883.0 1963.0

677 1883.2 1963.2 678 1883.4 1963.4 679 1883.6 1963.6

680 1883.8 1963.8 681 1884.0 1964.0 682 1884.2 1964.2

683 1884.4 1964.4 684 1884.6 1964.6 685 1884.8 1964.8

686 1885.0 1965.0 687 1885.2 1965.2 688 1885.4 1965.4

689 1885.6 1965.6 690 1885.8 1965.8 691 1886.0 1966.0

692 1886.2 1966.2 693 1886.4 1966.4 694 1886.6 1966.6

695 1886.8 1966.8 696 1887.0 1967.0 697 1887.2 1967.2

698 1887.4 1967.4 699 1887.6 1967.6 700 1887.8 1967.8



Tab. 4.4 PCS Table

A30808-X3247-K356-4-7630 179



701 1888.0 1968.0 702 1888.2 1968.2 703 1888.4 1968.4

704 1888.6 1968.6 705 1888.8 1968.8 706 1889.0 1969.0

707 1889.2 1969.2 708 1889.4 1969.4 709 1889.6 1969.6

710 1889.8 1969.8 711 1890.0 1970.0 712 1890.2 1970.2

713 1890.4 1970.4 714 1890.6 1970.6 715 1890.8 1970.8

716 1891.0 1971.0 717 1891.2 1971.2 718 1891.4 1971.4

719 1891.6 1971.6 720 1891.8 1971.8 721 1892.0 1972.0

722 1892.2 1972.2 723 1892.4 1972.4 724 1892.6 1972.6

725 1892.8 1972.8 726 1893.0 1973.0 727 1893.2 1973.2

728 1893.4 1973.4 729 1893.6 1973.6 730 1893.8 1973.8

731 1894.0 1974.0 732 1894.2 1974.2 733 1894.4 1974.4

734 1894.6 1974.6 735 1894.8 1974.8 736 1895.0 1975.0

737 1895.2 1975.2 738 1895.4 1975.4 739 1895.6 1975.6

740 1895.8 1975.8 741 1896.0 1976.0 742 1896.2 1976.2

743 1896.4 1976.4 744 1896.6 1976.6 745 1896.8 1976.8

746 1897.0 1977.0 747 1897.2 1977.2 748 1897.4 1977.4

749 1897.6 1977.6 750 1897.8 1977.8 751 1898.0 1978.0

752 1898.2 1978.2 753 1898.4 1978.4 754 1898.6 1978.6

755 1898.8 1978.8 756 1899.0 1979.0 757 1899.2 1979.2

758 1899.4 1979.4 759 1899.6 1979.6 760 1899.8 1979.8

761 1900.0 1980.0 762 1900.2 1980.2 763 1900.4 1980.4

764 1900.6 1980.6 765 1900.8 1980.8 766 1901.0 1981.0

767 1901.2 1981.2 768 1901.4 1981.4 769 1901.6 1981.6

770 1901.8 1981.8 771 1902.0 1982.0 772 1902.2 1982.2

773 1902.4 1982.4 774 1902.6 1982.6 775 1902.8 1982.8

776 1903.0 1983.0 777 1903.2 1983.2 778 1903.4 1983.4

779 1903.6 1983.6 780 1903.8 1983.8 781 1904.0 1984.0

782 1904.2 1984.2 783 1904.4 1984.4 784 1904.6 1984.6

785 1904.8 1984.8 786 1905.0 1985.0 787 1905.2 1985.2

788 1905.4 1985.4 789 1905.6 1985.6 790 1905.8 1985.8

791 1906.0 1986.0 792 1906.2 1986.2 793 1906.4 1986.4

794 1906.6 1986.6 795 1906.8 1986.8 796 1907.0 1987.0

797 1907.2 1987.2 798 1907.4 1987.4 799 1907.6 1987.6



Tab. 4.4 PCS Table

180 A30808-X3247-K356-4-7630



800 1907.8 1987.8 801 1908.0 1988.0 802 1908.2 1988.2

803 1908.4 1988.4 804 1908.6 1988.6 805 1908.8 1988.8

806 1909.0 1989.0 807 1909.2 1989.2 808 1909.4 1989.4

809 1909.6 1989.6 810 1909.8 1989.8



Tab. 4.4 PCS Table

A30808-X3247-K356-4-7630 181



5 Appendix

5.1 Possible Configurations for Offline Tests

5.1.1 Possible Test Configurations for DUAMCO

Fig. 5.1 DUAMCO 2:2

Testout 1

Ant 0

RX

0

RX

2R

X 1

RX

3

TX

Triplexer

Ant 1

VSWRProc

TX

1

AMP 1

RX

AMP 2

Testout 0

TX

Triplexer

VSWRProc

AMP 1

RX

AMP 2

RX

0

RX

2R

X 1

RX

3

TX

0

182 A30808-X3247-K356-4-7630



Fig. 5.2 DUAMCO 4:2

Fig. 5.3 DUAMCO 8:2

Testout 1

Ant 0

RX

0

RX

2R

X 1

RX

3

TX

Triplexer

Ant 1

VSWRProc

TX

0

AMP 1

RX

AMP 2

Testout 0

TX

Triplexer

VSWRProc

AMP 1

RX

AMP 2

RX

0

RX

2R

X 1

RX

3

TX

1

TX

0T

X 1

Testout 1

RX

2

RX

4

RX

3

RX

5

TX

2

TX

1

TX

0

TX

3

TX

0

TX

1

RX

0

RX

1

RX

6

RX

7

TX

3

TX

2

VSWRProc

RX

2

RX

4

RX

3

RX

5

RX

0

RX

1

RX

6

RX

7

TX

Triplexer

Ant 1

AMP 1

RX

AMP 2

Testout 0

VSWRProc

TX

Triplexer

Ant 0

AMP 1

RX

AMP 2

A30808-X3247-K356-4-7630 183



5.1.2 DUAMCO Test Configurations

Fig. 5.4 Testconfiguration for DUAMCO 2:2 Serving 1 Cell with 1 Carrier

TX-FilRX-Fil

TX0 RX0

attenuator

1W terminator

Testout 1TX-Fil RX-Fil

TX 1RX 1

Testout 0

20dB/50W

VSWRProc

VSWRProc

attenuator

1W terminator

20dB/50W

CU 0

MS

CouplerBox

MSBox

TX 0TX 1

test connections

184 A30808-X3247-K356-4-7630



Fig. 5.5 Testconfiguration for DUAMCO 2:2 Serving 1 Cell with 2 Carriers

test connections

TX-FilRX-Fil

TX0 RX0

attenuator

1W terminator

Testout 1

CU 1CU 0

TX-Fil RX-Fil

TX 1RX 1

Testout 0

20dB/50W

MS

CouplerBox

MSBox

VSWRProc

VSWRProc

TX 0TX 1

attenuator

1W terminator

20dB/50W

A30808-X3247-K356-4-7630 185



5.1.3 FICOM Test Configurations

Fig. 5.6 Testconfiguration for FICOM Test

test connections

TX0

attenuator

1W terminator

CU 0

RX 0

Testout 0

20dB/50W

MS

CouplerBox

MSBox

TX 0RX 1

ANT 0

DIAMCOFICOMFILTER

VSWRProc

186 A30808-X3247-K356-4-7630



5.2 Power/Level Conversion

The formula for power calculation:

Lp[dBm] = 10lg(Px/P0)

P0[Watt] = 10-3

5.3 Used Expressions

Lp[dBm] Px[Watt]

0 10-3

10 10-2

20 10-1

30 1

33 2

37 5

39 8

40 10

44 25

46 40

47 50

48 60

50 100

Tab. 5.1 Power Conversion Table

+ 3dB ≅ factor 2+ 5dB ≅ factor 3+10dB ≅ factor 10

-48V -48V for test adapter12V +12 Volt1ER-3 bit error rate >10-3 port 11ER-6 bit error rate >10-6 port 11RAI remote alarm indication port 12RAI remote alarm indication port 22ER-3 bit error rate >10-3 port 22ER-6 bit error rate >10-6 port 25V +5 Volt

A30808-X3247-K356-4-7630 187



5.4 Module Identification by Inventory Data and Label

Every module in the BTSE is identified by one or more labels, depending of the type (e.g.with/without FW, OEM, ...) and the used labeling scheme. In general, the HW code num-ber including the HW issue is printed as a 4 code block separated by hyphens, followedby the functional state after a slash mark as separator, and can be found on any module.If a FW is included a second number with the same structure is shown on a common oranother label. A bar-code (or 2D-code) and a mnemonic name complete the identifica-tion of the module and they are usually fixed at the front or on the levers.

HW and FW code numbers including issue and functional state can also be receivedelectronically via the LMT and the offline tool “IDF Editor”. The so called Inventory Dataconsists, among HW and FW code numbers, of many other information items about themodule like series number of the PCB or HW/SW compatibility

Using the IDF Editor, the relevant information of each module respectively inventory tak-en unit can be displayed and compared with the one on the labels. The procedure ofreading the appropriate data is described in the MMN:BTSE in the procedure “Updatingthe Remote Inventory Data”.

Fig. 5.7 Labels and Inventory Data

M:

++/01

S30861-Q300-X101-02/01

M:ALCOS30861-Q300-X100-02/01

S30861-Q300-X101-02/01

S30861-Q300-X100-02/01

Siemens

S30861-Q300-X101-02/01

M:ALCO

S30861-Q300-X100-02/01

FW code

FW Item

FW issue+

functional state

HW code HW issue+

functional state

mnemonic of element

=

=

Label Lettering IDFEditor

ALCO

new

old

2D-code

Number&FUST

HW ItemNumber&FUST

188 A30808-X3247-K356-4-7630



A30808-X3247-K356-4-7630 189



6 AbbreviationsACOM Antenna Combiner

ACT Alarm Collection Terminal

ACTC Alarm Collection Terminal Connection Board

ACTM Alarm Collection Terminal for Base Rack

ACTP Alarm Collection Terminal for Extension/Service Racks

AMCO Amplifier Multicoupler

ANT Antenna

ARFCN Absolute Radio Frequency Channel Number

AST Administrative State

ATMN Acceptance Test Manual

BB Backup Battery

BCCH Broadcast Control Channel

BER Bit Error Rate

BERT Bit Error Rate Test

BS Base Station

BSC Base Station Controller

BSS Basestation Subsystem

BTS Base Transceiver Station

BTSM BTS Site Manager

CB Cell Broadcast

COBA Core Basis

COSA Core Satellite

CU Carrier Unit

DC Direct Current

DCP DC Panel

DCS Digital Communication System

DIAMCO Dual Integrated Amplifier Multicoupler

DIDCTMA DIAMCO DC Tower Mounted Amplifier

DUAMCO Duplexer Amplifier Multicoupler

DUDCTMA DUAMCO DC Tower Mounted Amplifier

DULNA DUAMCO Low Noise Amplifier

DUVSWR DUAMCO Voltage Standing Wave Ratio

ECU EDGE Carrier Unit

EDGE Enhanced Data Rates for GSM Evolution

E-GSM Extended GSM

E-OTD Enhanced Observed Time Difference

ESD Electrostatic Sensitive Device

FAN Fan Unit

FICOM Filter Combiner

FTNF FICOM Tunable Narrowband Filter

190 A30808-X3247-K356-4-7630



FVSWR FICOM Voltage Standing Wave Ratio

FW Firmware

GSM Global System for Mobile Communication

GSM-RE GSM Railway Extension

HMO Hardware related Managed Object

HMO Holdover Mode

HPDU High Power Duplexer

HW Hardware

IDT Inventory Data Table

IMN Installation Manual

IMSI International Mobile Subscriber Identity

IU Installation Utlility

LE Link Equipment

LED Light Emitting Diode

LMT Local Maintenance Terminal

LMU Location Measurement Unit

LNA Low Noise Amplifier

LRU Least Replaceable Units

µC Microcomputer

MCC Mobile Country Code

MMN Maintenance Manual

MNC Mobile Network Code

MO Managed Object

MOC Mobile Originated Call

MS Mobile Station

MTC Mobile Terminated Call

MUCO Multicoupler

NE Network Element

no Numero

NOB nob_RIUs only

nob_RIU not on-board Remote Inventory Data

NT Network Termination

O&M Operation and Maintenance

OAL Operator Alarm

ob_RIU on-board Remote Inventory Data

OEM Original Equipment Manufacturer

OVPT Overvoltage Protection and Tracer

PCB Printed Circuit Board

PCM Pulse Code Modulation

PCS Personal Communication System

P-GSM Primary GSM

A30808-X3247-K356-4-7630 191



PID Product Identification Data

RAL Rack Alarm

RF in Radio Frequency Input

RF out Radio Frequency Output

RFI Ready for Inspection

R-GSM Railway GSM

SMLC Serving Mobile Location Center

SWL Software Load

TAC Technical Assistance Center

TAD Testadapter

TCH Traffic Channel

TDMA Time Division Multiple Access

TE Test Equipment

TEI Terminal Endpoint Identifier

TMA Tower Mounted Amplifier

TNF Tunable Narrowband Filter

TRX Transceiver

TX Transmitter

Um Interface between MS and BTSE

UMN User Manual

VSWR Voltage Standing Wave Ratio

192 A30808-X3247-K356-4-7630



A30808-X3247-K356-4-7630 193



7 IndexAACT 40Alarm Collection Terminal 68Antenna 28

BBreaker 22, 52

CCOBA 41CORE Redundancy 112COSA 44

DDC Panels 23–26DIAMCO 35DUAMCO 32

FFICOM 33

HHardware related Managed Objects 64HPDU 38

IIDF Editor 122

LLED Indication 52

MMnemonic 187

RRack Size 62Racks 17

SSoftware 39–40, 52SW Download and Activation 57

TTechnical Data 17Test equipment 49, 51TMA 29Tools 51

194 A30808-X3247-K356-4-7630



bs240it.pdf

Documents

system installations

xl iia30808x3247

xl iireason

installation sites

installation instructions

electrical equipment

system installieren

harmful personal interference