info SAE

SIZE ALTERATION EVENTS IN BSC/TRC

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© Copyright Ericsson AB 2004 - 2008. All Rights Reserved

Disclaimer

No part of this document may be reproduced in any form without the written permission of the copyright owner.

The contents of this document are subject to revision without notice due to continued progress in methodology, design, and manufacturing. Ericsson shall have no liability for any error or damage of any kind resulting from the use of this document.

Contents

APPLICATION INFORMATION 2/155 18-AXE 105 07 Uen AD2

1 General 2

Revision Information

3

Fixed SAE Guiding Values

3.1 Introduction 3.2 Global APT Size Alteration Events 3.3 Global APZ Size Alteration Events 3.4 Local APT Size Alteration Events 3.5 Local APZ Size Alteration Events 3.6 Node Changes Affecting 'Fixed' SAE Settings 3.7 Basis for Calculation of Fixed SAE Settings 4

Global Size Alteration Events

4.1 APT Size Alteration Events 4.2 APZ Size Alteration Events 5

Local Size Alteration Events

5.1 APT Size Alteration Events 5.2 APZ Size Alteration Events 6

RBS200 (G01) Changes

6.1 Transmission Radio Interface (TRI-EMG) 6.2 Transceiver Group (TG) 6.3 Transceiver (TRX) 7

RBS2000 (G12) Changes

7.1 Transceiver Group (TG) 7.2 Transceiver (TRX) 8

Changes in the BSC, TRC or BSC/TRC

8.1 Change of Node Type 8.2 ET155 Line Terminal 8.3 RTS A-Interface Line Terminal in BSC/TRC or TRC 8.4 RTS Abis-Interface Line Terminal in BSC or BSC/TRC 8.5 RTS Ater-Interface Line Terminal in BSC/TRC or TRC 8.6 RTS Ater-Interface Line Terminal in BSC 8.7 RTS GB-Interface Line Terminal in BSC/TRC or BSC

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8.8 RTS Lb-Interface Line Terminal in BSC 8.9 Transceiver Handler in BSC or BSC/TRC 8.10 GPRS Packet Handler in BSC or BSC/TRC 8.11 Transcoder and Rate Adaptation Unit in BSC/TRC or TRC8.12 Signal Terminal CCITT CCS7 in BSC, BSC/TRC or TRC 8.13 Signal Terminal ANSI CCS7 in BSC, BSC/TRC or TRC 8.14 Subrate Switch Units in BSC, BSC/TRC or TRC 8.15 Internal GSM Cell in BSC or BSC/TRC 8.16 External Cell in BSC or BSC/TRC 8.17 Change of Group Switch 8.18 Packet Gateway Devices 9

Recording Functions

9.1 Cell Traffic Recording 9.2 Mobile Traffic Recording 9.3 Channel Event Recording 9.4 Measurement Result Recording 9.5 Radio Interference Recording 9.6 Active BA-list Recording 9.7 BTS Configuration Data Collection 9.8 Call Path Tracing 9.9 Dropped Call Recording 9.10 Parameter Collection 10

Upgrade from RBS200 (G01) into RBS2000 (G12)

11

References



1 General

This document is meant to be an aid for managing the Size Alteration Events (SAEs) used in theBSC.

Proper setting of SAEs is important since the traffic handling capability of the BSC can be unnecessarily limited if SAEs are set too low. However, consideration of the effects on the system of over-dimensioning the SAEs must also be taken into account. Longer dump/restart/reload times are one side effect of SAE over-dimensioning. Another is inefficient use of the available data store memory. In addition, some SAEs may cause increased CP processor load.

The concept delta is used in chapter 8, indicating changes in the number of individuals related to BSS re-configuration. Delta is used to indicate how many individuals (records) that have to be seized in different configuration situations. An example: For one TRX there are eight TSs, in this case for TS delta = 8.

In this document CCITT is synonymous with ITU.

The APZ types presumed are APZ 212 30, APZ 212 33, APZ 212 33C and APZ 212 55

Below is a short description of each chapter.

Chapter 3 includes fixed guiding values calculated as reasonable highest values needed for SAEs in the BSC. This method can be regarded as a "Set and Forget Strategy” and is the method recommended by Ericsson.

Chapter 4 includes all SAEs for Global Size Alteration for APT and APZ.

Chapter 5 includes all SAEs for Local Size Alteration for APT and APZ.

Chapter 6 includes SAEs that concern re-configuration in an RBS200.

Chapter 7 includes SAEs that concern re-configuration in an RBS2000.

Chapter 8 includes SAEs that have to be changed when equipment and/or functionality in the BSC is added or removed. This chapter is only valid when not using fixed guiding values.

Chapter 9 includes SAEs that have to be set when the recording functions are used.

Chapter 10 includes SAEs that are involved when an upgrade from RBS200 into RBS2000 is performed. SAEs associated with RBS200 have to be decreased before SAEs associated with RBS2000 are increased.

Summary of the used SAEs in the BSC Global Size Alteration Events ------------------------------------------------------- APT 000, 019, 027, 048, 051-052, 058, 078, 087, 097, 156, 157, 159, 160, 163-166, 191, 207, 233, 256, 262, 298-299, 437, 442, 456, 459, 913, 995-997, 1001, 1047, 1078-1079, 1094, 1109, 1130, 1133, 1142-1143, 1152-1153, 1155, 1157-1158, 1161-1163 APZ 301-304, 310-311, 330, 332-334, 340-341,



343-371, 389-400, 417-421, 423-424, 462, 466, 958-961, 966-967, 1803, 1806-1836, 1843-1846, 1848-1851 Local Size Alteration Events ------------------------------------------------------- APT 500-502, 515, 522-524, 528-529, 533-534, 538, 550, 552, 554, 566, 583-585, 587-588, 600-613, 630, 634-636, 667, 700-703, 704, 710, 720, 730, 731, 755-756 APZ 500-507, 800-801, 803-807, 809-810, 812-817, 888

2 Revision Information

This document is based upon 2/155 18-AXE 105 07 Uen revision AC6

The changes for revision AD2 vs AD1 are:

SAE 1830 updated with splitted fixed size settings for A3x and A55 in chapt 3.3 and 4.2

The changes for revision AD1 vs AD are:

Fixed size setting for A55/GS890 added/updated for SAE 812 MFM in chapt 3.5

The changes for revision AD vs AC6 are:

Block RXEBL, RXOBL, RXESR, RXOSR added to SAE 500 in chapt 3.4, 5.1, 6.2, 6.3, 7.1, and 7.2

Block RXEFMM, RXOFMM, RXEVU, RXOVU added to SAE 502 in chapt 3.4, 5.1, 6.3 and 7.2

Block RXEPL, RXOPL, RTVPH, RTTRINT, RXOISH, RXELS, RXOLS, RXCLMO added to SAE 700 in chapt 3.4 and 5.1

Block RCSCB, RXCLIM, RXEPL, RXOPL, RTVPH, RTTRINT, RXOISH, RXCLMO added to SAE 710 in chapt 3.4 and 5.1

Block RCSCB, RXEPL, RXOPL, RTVPH, RTTRINT, RXOISH, RXCLMO added to SAE 720 in chapt 3.4 and 5.1

Block RCSCB, RXCLMO added to SAE 730 in chapt 3.4 and 5.1

Block RCCGD, RXCLIM added to SAE 1153 in chapt 6.3 and 7.2

RHLH, RHSNT, RHTRH added to SAE 1158 in chapt 4.1 and 8.9

SAE 1153 setting for GS890 increased to 4095 in chapt 3.2 and 4.1

SAE 812 MFM setting for APZ 212 55, GS890 (related to SAE1153) increased in chapt 3.5

SAE Setting for APZ 212 55, BTS logical model G12, GS890 increased to max size 49653 in chapt 3.4, 5.1, 7.1, and 7.2 for SAE 500 RXO3EP, RXO3OM, RXOABH, RXOADB, RXOADE, RXOBL, RXOFH, RXOIFH, RXOLE, RXOLH, RXOPL

SAE setting for APZ 212 55, BTS logical model G12, GS890 increased to 4095 in chapt 3.4, 5.1 and 7.2 for SAE 502 RTAPH, RTVPH, RXO3IM, RXOBVH, RXOFT, RXOISH, RXOLDF, RXOLH, RXOLS, RXRPM, RXOSR, RXOFMM, RXORPM, RXOVU

Section 7.2 updated.

SAE 1157 description updated with AMR WB in chapt 4.1

SAE 1158 setting increased to 256 in chapt 3.2



SAE 345, 350 fixed size setting 4000 added for APZ 212 55, G12;GS890 in chapt 3.3

3 Fixed SAE Guiding Values

3.1 Introduction

This chapter describes the method with Fixed SAE Guiding Values. This is the method recommended by Ericsson. SAE setting on the reference dump is documented in 4/1551-APT21009. The separate sections in this chapter covers:

3.2 - 3.5 Lists all global and local recommended SAE values 3.6 Lists the node changes where there is an impact on SAE settings 3.7 Gives some background information on the Maximum Traffic Intensity and how that has been used to obtain the Fixed SAE Guiding Values.

The guiding values are with a few exceptions reasonable maximum values which are node size independent and based on the Maximum Traffic Intensity per type of node or APZ type, When not explicitly specified per APZ type, the figures are valid for APZ 212 30, 212 33, 212 33C and 212 55. Some SAEs are Site Dependent:

Some SAEs related to hardware are also site dependent. SAE 304, SAE1822 and SAE 1850 may need to be adjusted at node expansion.

The advantages to use Fixed SAE method are:

a. With a few exceptions independent of the size of the node (dimensioning is needed only for a few SAEs)

b. The values are set only once (when the node is installed)

c. The values are site independent (same values for all nodes with the same APZ, same node type and with the same transmission and signalling type))

Although the fixed SAE strategy has many benefits, it must be noted that the strategy has some drawbacks too:

a. The data store memory need is increased.

b. CP Restart & BPC Recovery Times are increased compared to a properly tuned dependent setting if the node is small. The BSC/TRC downtime figures published however assume

Table 1

SAE 298 many blocks Number of cells SAE 502 RQUCD Number of UTRAN cell relations SAE 522 RQCD Number of internal cell relations SAE 523 RQCD Number of external cell relations SAE 524 RQCD Number of neighboring cell relations SAE 027 S7DR ANSI CCS7 signalling links SAE 166 C7DR2 CCITT CCS7 signalling links SAE 801 EXAL0 TRI external alarm receivers (RBS200 only)



use of fixed SAE settings.

c. CP processor load increases slightly.

Explanations to the tables in this section and below:

The 'conditional' column marked COND (or sometimes the "comments" column) is used to indicate that the information on the row is applicable only if a certain condition is fulfilled as follows: COND Explanation A30 Applicable for APZ 212 30 A33 Applicable for APZ 212 33 and APZ 212 33C A3x Applicable for A30 and A33 A55 Applicable for APZ 212 55 ABISOPT/IP Feature Abis Optimization and/or Abis over IP are used, else SAE=0. AN ANSI CCS7 signalling is used, else SAE=0 CC CCITT CCS7 signalling is used, else SAE=0 or minimum value according to value range. At Ater interface is used, else SAE=0 ET155-7 ET155-7 is used, else SAE=0 [7 board version] ET155-1 ET155-1 is used, else SAE=0 [1 board version] E1 PDH E1 is used, else SAE=0 T1 PDH T1 is used, else SAE=0 P32 32 channel PCM interfaces are used, else SAE=0 P24 24 channel PCM interfaces are used, else SAE=0 GS12 applicable when GS12 Group Switch is used GS890 applicable when GS890 Group Switch is used NNRP5 Applicable when NNRP5 is used RBS200 Radio Base Station 200 is used, else SAE=0 * RBS2000 Radio Base Station 2000 is used or will be used, else SAE=0 * RPGx RPG2/RPG3 is used. * Note: Use highest setting of RBS2000 and RBS200 when both are applicable

Explanations of other abbreviations used in the tables:

Table 2

AMR Adaptive Multi Rate ATM Asynchronous Transfer Mode



In nodes with ET155-1 it is possible to have a few ETC-5/ETC-T1H boards for the purpose of synchronization and HSL signalling (indicated with 'ETCSync' in section 3.4). The recommended SAE settings in this case is as follows, these values are enough for 6 ETC-5/ETC-T1H boards. The setting for ET155-1 SAEs are not changed due to this. Note that this is only a option for nodes delivered before R10.

SAE BLOCK R-BSC Comb TRC Comments ----------------------------------------------------- 32 channel PCM systems:

AOD Avoid over dimensioning, see 3.7 below Comb. Combined BSC/TRC with or without remote BSC's E1 2.048 Mbit/s interface to PDH network (32 channel PCM) EFR Enhanced Full Rate ETCSync In nodes with ET155-1 it is an option to have a few ETC-5/ETC-T1H

boards for the purpose of synchronization and HSL signalling. See below this table for the recommended settings in this case.

FR Full Rate GEM Generic Ericsson Magazine h Help variables may be used, see description for SAE 700- 704, 710,

720, 730 or 731 in chapter 5.1. Do not decrease existing value. HR Half Rate HSL High Speed Link M@H SAE is applicable for Mobile at Home. NB Narrow Band NNRP5 Network Node Renewal Process 5. Extension of the BYB501 concept

(for GS12) for adaption to the GEM concept PDH Plesiochronous Digital Hierarchy R-BSC Remote BSC Semiperm. SAE dependent on number of semipermanent connections in the

exchange. SL Number of CCS7 Signalling Links, SAE is site dependent, see section

'Node Changes Affecting 'Fixed' SAE Settings below STEB Signalling Terminal Enhanced Board T1 1.544 Mbit/s interface to PDH network (24 channel PCM) TD Traffic dependent, see section 'Other SAEs Affected at Extreme

Traffic Load' below TRA Transcoder TRC Transceiver Controller node, no Abis interface in the node. TRI Number of TRI-EMGs, SAE is site dependent, see section 'Node

Changes Affecting 'Fixed' SAE Settings below WB Wide Band x Site dependent, see section 'Node Changes Affecting 'Fixed' SAE

Settings below y1 Site dependent, guiding values for BSC and BSC/TRC are dependent

on the use of RBS 200, see chapter 5.1 SAE 538 and Section 3.6.10. y2 Site dependent, guiding values for BSC and BSC/TRC are dependent

on the use of RBS 2000, see chapter 5.1 SAE 538 and Section 3.6.10.

y3 Site dependent, guiding value for BSC and BSC/TRC are dependent on the use of RBS 200, see chapter 5.1 SAE 502.

z Site dependent (static value: z=0 for new installations, z=unchanged for existing BSCs)



500 HIDRALT 0 6 6 500 HIDRTB 6 0 0 500 RALT 0 192 192 500 RTLTB 192 0 0 515 DIPRALT 0 6 6 515 DIPRTB 6 0 0 529 ETRALT 0 6 6 529 ETRTB 6 0 0 24 channel PCM systems: 500 RALT24 0 144 144 500 RTLTB24 144 0 0 515 DIPRAT4 0 6 6 515 DIPRTB4 6 0 0 529 ETRALT4 0 6 6 529 ETRTB4 6 0 0

3.2 Global APT Size Alteration Events

SAE BLOCK COND R-BSC Comb TRC Comments ------------------------------------------------- Global APT SAE 000 1 1 1 019 AN 3 17 17 027 AN 250*SL 250*SL 250*SL AOD 048 100 100 100 051 2000 2000 2000 052 AN 32 32 32 058 64 64 64 GS12 058 0 0 0 GS890 078 0 0 0 087 1000 1000 1000 097 100 100 100 Semiperm. 156 3 3 3 157 1 1 1 159 20 20 20 160 1 1 1 163 CC 32 32 32 164 CC 3 17 17 165 CC 3 17 17 166 CC 250*SL 250*SL 250*SL AOD 191 CC 3 17 17 207 AN 3 17 17 233 AN 2 2 2 256 CC 5000 5000 5000 256 AN 100 100 100 262 0 0 0 298 x x 1 No.of cells 299 2048 2048 1 437 AN 1 1 1 442 96 96 96 GS890 442 0 0 0 GS12 456 AN 1 1 1 459 AN 3 17 17 913 8960 8960 1 TD,GS12 913 17204 17204 1 TD,GS890 969 0 0 0



970 0 0 0 971 0 0 0 995 0 z z TRA R5 FR 996 0 z z TRA R5 EFR 997 16384 16384 0 1001 0 0 0 1047 0 z z TRA R5 HR 1078 3 3 3 1079 1 1 1 1094 32768 32768 32768 GS12 1094 98304 98304 98304 GS890 1109 0 64 64 TRA R6;GS890;NNRP5 1130 0 0 0 1133 2048 2048 0 1142 0 z z TRA R5B,AMR FR 1143 0 z z TRA R5B,AMR HR 1152 1020 1020 0 GS12 1152 2048 2048 0 GS890 1153 1020 1020 0 GS12 1153 A3x 2048 2048 0 GS890 1153 A55 4095 4095 0 GS890 1155 x x x M@H 1157 0 32 32 TRA R7;GS890;NNRP5 1158 256 256 2 1161 x x x M@H 1162 8960 8960 1 Not M@H,TD,GS12 1162 17204 17204 1 Not M@H,TD,GS890 1162 17204 17204 1 M@H 1163 x x x M@H

3.3 Global APZ Size Alteration Events

SAE BLOCK COND R-BSC Comb TRC Comments --------------------------------------------------- Global APZ SAE 301 10000 10000 10000 302 200 200 200 303 30 30 30 304 768 768 768 310 RBS200 128 128 1 310 RBS2000 1 1 1 311 RBS200 256 256 1 330 16 16 16 332 10000 10000 10000 333 A3x 506 506 506 334 A3x 30 30 30 340 1024 1024 1024 341 128 128 128 343 1023 1023 1023 344 A3x 256 256 256 345 A3x 3000 3000 300 345 A55 4000 4000 400 G12;GS890 346 4000 4000 400 347 1000 1000 1000 348 400 400 400 349 560 560 500 350 A3x 3000 3000 400



350 A55 4000 4000 400 G12;GS890 351 100 100 32 352 42 42 42 353 24 24 24 354 71 71 71 355 17 17 16 356 10 10 10 357 10 10 10 358 50 50 50 359 100 100 100 360 50 50 50 361 1000 1000 1000 362 50 50 50 363 53 53 53 364 103 103 103 365 100 100 100 366 50 50 50 367 53 53 53 368 100 100 100 369 50 50 50 370 53 53 53 371 150 150 150 417 A3x 32 32 32 417 A55 1 1 1 418 A3x 32 32 32 418 A55 0 0 0 419 A3x 4096 4096 4096 419 A55 1 1 1 420 A3x 4096 4096 4096 420 A55 0 0 0 421 128 128 128 423 3000 3000 3000 424 512 512 512 462 3000 3000 3000 466 2000 2000 2000 958 256 256 256 959 256 256 256 960 8192 8192 8192 961 2000 2000 2000 966 16384 16384 16384 967 2048 2048 2048 1803 128 128 128 1806 54 54 54 1807 10 10 10 1808 256 256 256 1809 10 10 10 1810 40 40 40 1811 10 10 10 1812 54 54 54 1813 10 10 10 1814 256 256 256 1815 256 256 256 1816 256 256 256 1817 16 16 16 1818 2048 2048 2048 1819 16 16 16 1820 54 54 54 1821 10 10 10



1822 768 768 768 1823 100 100 100 1824 0 0 0 1825 1 1 1 1826 200 200 200 1827 200 200 200 1828 200 200 200 1829 100 100 100 1830 A3x 50 50 50 1830 A55 55 55 55 1831 20 20 20 1832 10 10 10 1833 A3x 6 6 6 1833 A55 250 250 250 1834 0 0 0 1835 6 6 6 1836 0 0 0 1843 512 512 512 1844 512 512 512 1845 2000 2000 2000 1846 512 512 512 1848 200 200 200 1849 2000 2000 2000 1850 12288 12288 12288 1851 A3x 40000 40000 40000

3.4 Local APT Size Alteration Events

SAE BLOCK COND R-BSC Comb TRC Comments ---------------------------------------------------- Local APT SAE 500 C7CLAN 1 1 1 500 C7CO CC 16360 16360 7400 TD GS12 500 C7CO CC 30492 30492 12288 TD GS890 500 C7PCDD 0 0 0 500 C7SRM CC 256 256 256 500 C7SRMH CC 256 256 256 500 COHW 0 0 0 500 COMAIN 0 0 0 500 COMES 0 0 0 500 COX 0 0 0 500 DIPHM1 P32 504 504 504 ET155-7 500 DIPHM2 P32 1008 1008 1008 ET155-1;GS890;NNRP5 500 DIPHM3 P24 1344 1344 1344 ET155-1;GS890;NNRP5 500 ETRALT2 P32 0 12480 12480 ET155-1;GS890;NNRP5 500 ETRALT3 P24 0 12480 12480 ET155-1;GS890;NNRP5 500 ETRALT5 P32 0 6528 7488 ET155-7 500 ETRBLT2 P32 7104 7104 0 ET155-1;NNRP5 500 ETRBLT2 P32 11232 11232 0 ET155-1;GS890 500 ETRBLT3 P24 7104 7104 0 ET155-1;NNRP5 500 ETRBLT3 P24 11232 11232 0 ET155-1;GS890 500 ETRBLT5 P32 7104 7104 0 ET155-7 500 ETRTB2 P32 3264 0 0 ET155-1 500 ETRTB3 P24 3264 0 0 ET155-1 500 ETRTB5 P32 1728 0 0 ET155-7 500 ETRTG2 P32 2048 2048 0 ET155-1;GS890;NNRP5 500 ETRTG3 P24 1536 1536 0 ET155-1;GS890;NNRP5



500 ETRTG5 P32 2048 2048 0 ET155-7 500 ETRTL2 P32 64 64 0 ET155-1;GS890;NNRP5 500 ETRTL3 P24 48 48 0 ET155-1;GS890;NNRP5 500 ETRTL5 P32 64 64 0 ET155-7 500 ETRTT2 P32 0 3552At 3552 ET155-1;GS890;NNRP5 500 ETRTT3 P24 0 3552At 3552 ET155-1;GS890;NNRP5 500 ETRTT5 P32 0 2016At 2304 ET155-7 500 EVREP CC 1000 1000 1000 500 EVREP AN 200 200 200 500 GCCGH x x x M@H 500 HIDRALT P32 0 204 234 GS12 500 HIDRALT P32 0 390 390 GS890;ETCSync 500 HIDRBLT P32 222 222 0 E1;GS12 500 HIDRBLT P32 351 351 0 E1;GS890 500 HIDRTB P32 54 0 0 GS12 500 HIDRTB P32 102 0 0 GS890;ETCSync 500 HIDRTG P32 64 64 0 E1 500 HIDRTL P32 2 2 0 E1 500 HIDRTT P32 0 63At 72 GS12;E1 500 HIDRTT P32 0 111At 111 GS890; E1 500 M3UADR 100 100 100 GS890;NNRP5 500 OMRV 0 0 0 500 OSRV 0 0 0 500 RABDI CC 8960 8960 0 TD GS12 500 RABDI CC 17204 17204 0 TD GS890 500 RABDIAN AN 8960 8960 0 TD GS12 500 RABDIAN AN 17204 17204 0 TD GS890 500 RALT P32 0 6528 7488 AOD;GS12 500 RALT P32 0 12480 12480 AOD;GS890;ETCSync 500 RALT2 P32 0 12480 12480 ET155-1;AOD;GS890;NNRP5 500 RALT3 P24 0 12480 12480 ET155-1;AOD;GS890;NNRP5 500 RALT15 P32 0 6528 7488 ET155-7;AOD 500 RALT24 P24 0 6528 7488 AOD;GS12 500 RALT24 P24 0 12480 12480 AOD;GS890;ETCSync 500 RBLT P32 7104 7104 0 E1; AOD;GS12 500 RBLT P32 11232 11232 0 E1; AOD;GS890 500 RBLT2 P32 7104 7104 0 ET155-1;AOD;NNRP5 500 RBLT2 P32 11232 11232 0 ET155-1;AOD;GS890 500 RBLT3 P24 7104 7104 0 ET155-1;AOD;NNRP5 500 RBLT3 P24 11232 11232 0 ET155-1;AOD;GS890 500 RBLT15 P32 7104 7104 0 ET155-7;AOD 500 RBLT24 P24 7104 7104 0 T1;AOD;GS12 500 RBLT24 P24 11232 11232 0 T1;AOD;GS890 500 RMSCS 4000 4000 0 TD; 500 RODCR 0 0 0 Ericsson internal 500 RODESI 16 16 16 500 RTATHB 6480 0 0 TD;GS12 500 RTATHB 12288 0 0 TD;GS890 500 RTATHT 0 6400At 7400 TD;GS12 500 RTATHT 0 12288At 12288 TD;GS890 500 RTBLE CC 2000 2000 0 500 RTBLEAN AN 2000 2000 0 500 RTBTAP CC 6400 6400At 7400 TD;GS12 500 RTBTAP CC 12288 12288At 12288 TD;GS890 500 RTBTAPA AN 6400 6400At 7400 TD;GS12 500 RTBTAPA AN 12288 12288At 12288 TD;GS890 500 RTGLT P32 2048 2048 0 E1 500 RTGLT2 P32 2048 2048 0 ET155-1;GS890;NNRP5



500 RTGLT3 P24 1536 1536 0 ET155-1;GS890;NNRP5 500 RTGLT15 P32 2048 2048 0 ET155-7 500 RTGLT24 P24 1536 1536 0 T1 500 RTGPHDV 128 128 1 500 RTLBT P32 64 64 0 E1 500 RTLBT2 P32 64 64 0 ET155-1;GS890;NNRP5 500 RTLBT3 P24 48 48 0 ET155-1;GS890;NNRP5 500 RTLBT15 P32 64 64 0 ET155-7 500 RTLBT24 P24 48 48 0 T1 500 RTLTB P32 1728 0 0 GS12 500 RTLTB P32 3264 0 0 GS890;ETCSync 500 RTLTB2 P32 3264 0 0 ET155-1 500 RTLTB3 P24 3264 0 0 ET155-1 500 RTLTB15 P32 1728 0 0 ET155-7 500 RTLTB24 P24 1728 0 0 GS12 500 RTLTB24 P24 3264 0 0 GS890;ETCSync 500 RTLTT P32 0 2016At 2304 AOD;GS12;E1 500 RTLTT P32 0 3552At 3552 AOD;GS890;E1 500 RTLTT2 P32 0 3552At 3552 ET155-1;AOD;GS890;NNRP5 500 RTLTT3 P24 0 3552At 3552 ET155-1;AOD;GS890;NNRP5 500 RTLTT15 P32 0 2016At 2304 ET155-7;AOD;GS12 500 RTLTT15 P32 0 2016At 2304 ET155-7;AOD;GS890 500 RTLTT24 P24 0 2016At 2304 AOD;GS12;T1 500 RTLTT24 P24 0 3552At 3552 AOD;GS890;T1 500 RTPDI 0 12288 12288 500 RTPGD 31488 31488 0 ABISOPT/IP;GS890;NNRP5 500 RTPLD 31488 31488 0 ABISOPT/IP;GS890;NNRP5 500 RTTCCT 0 6400At 7400 GS12 500 RTTCCT 0 12288At 12288 GS890 500 RTTPH 0 6400 7400 GS12 500 RTTPH 0 12288 12288 GS890 500 RTTPR 0 6400 7400 TD;GS12 500 RTTPR 0 12288 12288 TD;GS890 500 RXE3EP 12244 12244 0 RBS200;GS12 500 RXE3EP 23552 23552 0 RBS200;GS890 500 RXE3OM 12244 12244 0 RBS200;GS12 500 RXE3OM 23552 23552 0 RBS200;GS890 500 RXEABH 12244 12244 0 RBS200;GS12 500 RXEABH 23552 23552 0 RBS200;GS890 500 RXEADB 12244 12244 0 RBS200;GS12 500 RXEADB 23552 23552 0 RBS200;GS890 500 RXEADE 12244 12244 0 RBS200;GS12 500 RXEADE 23552 23552 0 RBS200;GS890 500 RXEBL 12244 12244 0 RBS200;GS12 500 RXEBL 23552 23552 0 RBS200;GS890 500 RXEFH 12244 12244 0 RBS200;GS12 500 RXEFH 23552 23552 0 RBS200;GS890 500 RXEIFH 12244 12244 0 RBS200;GS12 500 RXEIFH 23552 23552 0 RBS200;GS890 500 RXELE 12244 12244 0 RBS200;GS12 500 RXELE 23552 23552 0 RBS200;GS890 500 RXELH 12244 12244 0 RBS200;GS12 500 RXELH 23552 23552 0 RBS200;GS890 500 RXEPL 12244 12244 0 RBS200;GS12 500 RXEPL 23552 23552 0 RBS200;GS890 500 RXESR 12244 12244 0 RBS200;GS12 500 RXESR 23552 23552 0 RBS200;GS890 500 RXO3EP 15828 15828 0 RBS2000;GS12



500 RXO3EP A3x 27136 27136 0 RBS2000;GS890 500 RXO3EP A55 49653 49653 0 RBS2000;GS890 500 RXO3OM 15828 15828 0 RBS2000;GS12 500 RXO3OM A3x 27136 27136 0 RBS2000;GS890 500 RXO3OM A55 49653 49653 0 RBS2000;GS890 500 RXOABH 15828 15828 0 RBS2000;GS12 500 RXOABH A3x 27136 27136 0 RBS2000;GS890 500 RXOABH A55 49653 49653 0 RBS2000;GS890 500 RXOADB 15828 15828 0 RBS2000;GS12 500 RXOADB A3x 27136 27136 0 RBS2000;GS890 500 RXOADB A55 49653 49653 0 RBS2000;GS890 500 RXOADE 15828 15828 0 RBS2000;GS12 500 RXOADE A3x 27136 27136 0 RBS2000;GS890 500 RXOADE A55 49653 49653 0 RBS2000;GS890 500 RXOBL 15828 15828 0 RBS2000;GS12 500 RXOBL A3x 27136 27136 0 RBS2000;GS890 500 RXOBL A55 49653 49653 0 RBS2000;GS890 500 RXOFH 15828 15828 0 RBS2000;GS12 500 RXOFH A3x 27136 27136 0 RBS2000;GS890 500 RXOFH A55 49653 49653 0 RBS2000;GS890 500 RXOIFH 15828 15828 0 RBS2000;GS12 500 RXOIFH A3x 27136 27136 0 RBS2000;GS890 500 RXOIFH A55 49653 49653 0 RBS2000;GS890 500 RXOLE 15828 15828 0 RBS2000;GS12 500 RXOLE A3x 27136 27136 0 RBS2000;GS890 500 RXOLE A55 49653 49653 0 RBS2000;GS890 500 RXOLH 15828 15828 0 RBS2000;GS12 500 RXOLH A3x 27136 27136 0 RBS2000;GS890 500 RXOLH A55 49653 49653 0 RBS2000;GS890 500 RXOPL 15828 15828 0 RBS2000;GS12 500 RXOPL A3x 27136 27136 0 RBS2000;GS890 500 RXOPL A55 49653 49653 0 RBS2000;GS890 500 RXOSR 15828 15828 0 RBS2000;GS12 500 RXOSR A3x 27136 27136 0 RBS2000;GS890 500 RXOSR A55 49653 49653 0 RBS2000;GS890 500 SCCOC AN 16360 16360 7400 TD;GS12 500 SCCOC AN 30492 30492 12288 TD;GS890 500 SDIPHID P32 8 8 8 ET155-7 500 SDIPHM2 P32 16 16 16 ET155-1;GS890;NNRP5 501 C7CL CC 256 256 256 501 C7CO CC 600 600 600 502 RQUCD x x 0 502 RTAPH 1020 1020 0 RBS2000;GS12 502 RTAPH A3x 2048 2048 0 RBS2000;GS890 502 RTAPH A55 4095 4095 0 RBS2000;GS890 502 RTVPH 1020 1020 0 RBS2000;GS12 502 RTVPH A3x 2048 2048 0 RBS2000;GS890 502 RTVPH A55 4095 4095 0 RBS2000;GS890 502 RXE3IM 1020 1020 0 RBS200;GS12 502 RXE3IM 2048 2048 0 RBS200;GS890 502 RXEBVH 1020 1020 0 RBS200;GS12 502 RXEBVH 2048 2048 0 RBS200;GS890 502 RXEFMM 1020 1020 0 RBS200;GS12 502 RXEFMM 2048 2048 0 RBS200;GS890 502 RXEFT 1020 1020 0 RBS200;GS12 502 RXEFT 2048 2048 0 RBS200;GS890 502 RXELDF 1020 1020 0 RBS200;GS12 502 RXELDF 2048 2048 0 RBS200;GS890



502 RXELH 1020 1020 0 RBS200;GS12 502 RXELH 2048 2048 0 RBS200;GS890 502 RXELS 1020 1020 0 RBS200;GS12 502 RXELS 2048 2048 0 RBS200;GS890 502 RXERPM 1020 1020 0 RBS200;GS12 502 RXERPM 2048 2048 0 RBS200;GS890 502 RXESR 1020 1020 0 RBS200;GS12 502 RXESR 2048 2048 0 RBS200;GS890 502 RXETGH 1020 1020 0 RBS200;GS12 502 RXETGH 2048 2048 0 RBS200;GS890 502 RXEVU 1020 1020 0 RBS200;GS12 502 RXEVU 2048 2048 0 RBS200;GS890 502 RXO3IM 1020 1020 0 RBS2000;GS12 502 RXO3IM A3x 2048 2048 0 RBS2000;GS890 502 RXO3IM A55 4095 4095 0 RBS2000;GS890 502 RXOBVH 1020 1020 0 RBS2000;GS12 502 RXOBVH A3x 2048 2048 0 RBS2000;GS890 502 RXOBVH A55 4095 4095 0 RBS2000;GS890 502 RXOFMM 1020 1020 0 RBS2000;GS12 502 RXOFMM A3x 2048 2048 0 RBS2000;GS890 502 RXOFMM A55 4095 4095 0 RBS2000;GS890 502 RXOFT 1020 1020 0 RBS2000;GS12 502 RXOFT A3x 2048 2048 0 RBS2000;GS890 502 RXOFT A55 4095 4095 0 RBS2000;GS890 502 RXOISH 1020 1020 0 RBS2000;GS12 502 RXOISH A3x 2048 2048 0 RBS2000;GS890 502 RXOISH A55 4095 4095 0 RBS2000;GS890 502 RXOLDF 1020 1020 0 RBS2000;GS12 502 RXOLDF A3x 2048 2048 0 RBS2000;GS890 502 RXOLDF A55 4095 4095 0 RBS2000;GS890 502 RXOLH 1020 1020 0 RBS2000;GS12 502 RXOLH A3x 2048 2048 0 RBS2000;GS890 502 RXOLH A55 4095 4095 0 RBS2000;GS890 502 RXOLS 1020 1020 0 RBS2000;GS12 502 RXOLS A3x 2048 2048 0 RBS2000;GS890 502 RXOLS A55 4095 4095 0 RBS2000;GS890 502 RXORPM 1020 1020 0 RBS2000;GS12 502 RXORPM A3x 2048 2048 0 RBS2000;GS890 502 RXORPM A55 4095 4095 0 RBS2000;GS890 502 RXOSR 1020 1020 0 RBS2000;GS12 502 RXOSR A3x 2048 2048 0 RBS2000;GS890 502 RXOSR A55 4095 4095 0 RBS2000;GS890 502 RXOVU 1020 1020 0 RBS2000;GS12 502 RXOVU A3x 2048 2048 0 RBS2000;GS890 502 RXOVU A55 4095 4095 0 RBS2000;GS890 504 M3UADR 2 2 2 GS890;NNRP5 515 DIPM1 P32 504 504 504 ET155-7 515 DIPM2 P32 1008 1008 1008 ET155-1;GS890;NNRP5 515 DIPM3 P24 1344 1344 1344 ET155-1;GS890;NNRP5 515 DIPRALT P32 0 204 234 GS12 515 DIPRALT P32 0 390 390 GS890;ETCSync 515 DIPRAT4 P24 0 272 312 GS12 515 DIPRAT4 P24 0 520 520 GS890;ETCSync 515 DIPRBLT P32 222 222 0 E1;GS12 515 DIPRBLT P32 351 351 0 E1;GS890 515 DIPRBT4 P24 296 296 0 T1;GS12 515 DIPRBT4 P24 468 468 0 T1;GS890 515 DIPRTB P32 54 0 0 GS12



515 DIPRTB P32 102 0 0 GS890;ETCSync 515 DIPRTB4 P24 72 0 0 GS12 515 DIPRTB4 P24 136 0 0 GS890;ETCSync 515 DIPRTG P32 64 64 0 E1 515 DIPRTG4 P24 64 64 0 T1 515 DIPRTL P32 2 2 0 E1 515 DIPRTL4 P24 2 2 0 T1 515 DIPRTT P32 0 63At 72 E1;GS12 515 DIPRTT P32 0 111At 111 E1;GS890 515 DIPRTT4 P24 0 84At 96 T1;GS12 515 DIPRTT4 P24 0 148At 148 T1;GS890 515 SDIPAM3 P24 16 16 16 ET155-1;GS890;NNRP5 515 SDIPFM3 P24 16 16 16 ET155-1;GS890;NNRP5 515 SDIPM1 P32 8 8 8 ET155-7 515 SDIPM2 P32 16 16 16 ET155-1;GS890;NNRP5 515 SDIPM3 P24 16 16 16 ET155-1;GS890;NNRP5 515 SDIPQ P32 8 8 8 ET155-7 515 SDIPQM2 P32 16 16 16 ET155-1;GS890;NNRP5 515 SDIPQM3 P24 16 16 16 ET155-1;GS890;NNRP5 522 RQCD x x 0 523 RQCD x x 0 524 RQCD x x 0 528 SNTPCD 0 0 0 528 SNTPCDM 0 0 0 529 ETM1 P32 8 8 8 ET155-7 529 ETM2 P32 16 16 16 ET155-1;GS890;NNRP5 529 ETM3 P24 16 16 16 ET155-1;GS890;NNRP5 529 ETRALT P32 0 204 234 GS12 529 ETRALT P32 0 390 390 GS890;ETCSync 529 ETRALT4 P24 0 272 312 GS12 529 ETRALT4 P24 0 520 520 GS890;ETCSync 529 ETRBLT P32 222 222 0 E1;GS12 529 ETRBLT P32 351 351 0 E1;GS890 529 ETRBLT4 P24 296 296 0 T1;GS12 529 ETRBLT4 P24 468 468 0 T1;GS890 529 ETRTB P32 54 0 0 GS12 529 ETRTB P32 102 0 0 GS890;ETCSync 529 ETRTB4 P24 72 0 0 GS12 529 ETRTB4 P24 136 0 0 GS890;ETCSync 529 ETRTG P32 64 64 0 E1 529 ETRTG4 P24 64 64 0 T1 529 ETRTL P32 2 2 0 E1 529 ETRTL4 P24 2 2 0 T1 529 ETRTT P32 0 63At 72 GS12;E1 529 ETRTT P32 0 111At 111 GS890; E1 529 ETRTT4 P24 0 84At 96 GS12;T1 529 ETRTT4 P24 0 148At 148 GS890;T1 529 RTPGS 41 41 0 ABISOPT/IP;GS890;NNRP5 529 SNTPCD 0 0 0 529 SNTPCDM 0 0 0 529 SRS 8 8 8 GS12 529 SRS 0 0 0 GS890 529 SRSTRAF 8 8 8 GS12 529 SRSTRAF 0 0 0 GS890 533 ROBAR 32768 32768 0 534 ROBAR 65536 65536 0 538 RXEFT RBS200 y1 y1 0 538 RXOFT RBS2000 y2 y2 0



550 RXCMSD 512 512 0 552 RXCMSD 512 512 0 554 S7GST AN 128 128 128 STEB NB;GS890;NNRP5 554 S7HST AN 4 4 4 STEB HSL;GS890;NNRP5 554 S7ST AN 0 0 0 554 S7STG AN 32 32 32 RPGx NB 566 C7GST CC 128 128 128 STEB NB;GS890;NNRP5 566 C7GSTAH CC 4 4 4 STEB HSL;Q.703;GS890;NNRP5566 C7GSTH CC 4 4 4 STEB HSL;ATM;GS890;NNRP5 566 C7ST2 CC 0 0 0 566 C7ST2C CC 32 32 32 RPGx NB 583 C7SC2 CC 3 17 17 584 C7TMA2 CC 3 17 17 585 C7TMP2 CC 2 9 9 SAE583/2 587 C7PMA2 CC 3 17 17 SAE584 588 C7PMP2 CC 2 9 9 SAE583/2 600 CH 0 0 0 GS12 600 CH 96 96 96 GS890 600 HWID 0 0 0 600 IP 16 16 16 GS890;NNRP5 600 RTPRH 512 512 0 ABISOPT/IP;GS890;NNRP5 600 SCTP 16 16 16 GS890;NNRP5 600 XM 0 0 0 GS12 600 XM 96 96 96 GS890 601 IP 16 16 16 GS890;NNRP5 602 IP 128 128 128 GS890;NNRP5 602 SCTP 64 64 64 GS890;NNRP5 603 IP 128 128 128 GS890;NNRP5 603 SCTP 32 32 32 GS890;NNRP5 604 COHW 0 0 0 604 COSEM 1 1 1 604 COX 0 0 0 604 RXCML 65535 65535 65535 604 SCPA 1 1 1 604 SCRD 500 500 500 604 SCTP 512 512 512 GS890;NNRP5 605 COSEM 1 1 1 605 COX 0 0 0 605 SCRD 500 500 500 605 SCTP 2048 2048 2048 GS890;NNRP5 606 COHW 0 0 0 606 COMAIN 0 0 0 607 C7ACCL2 0 0 0 607 C7EPC2 0 0 0 607 C7PAN 0 0 0 607 C7SACP 0 0 0 607 COMAIN 100 100 100 607 GCRLC x x x M@H 607 OCVTR 0 0 0 607 SCGT 0 0 0 608 C7ACCL2 0 0 0 608 C7EPC2 0 0 0 608 C7SACP 0 0 0 608 COMES 0 0 0 608 OCVTR 0 0 0 609 OCVTR 0 0 0 610 OCVTR 0 0 0 611 OCVTR 0 0 0



612 OCVTR 0 0 0 613 OCVTR 0 0 0 630 C7DR2 CC 3 17 17 634 C7PVC2 0 0 0 635 C7CVR2 10 10 10 636 C7CVR2 10 10 10 667 C7GT CC 1 1 1 700 C7OMASE 0 0 0 700 C7TCP 0 0 0 700 GCIMSI h h h 700 GCRLC h h h 700 GCURR h h h 700 RCLCCH h h h 700 RCSCB h h h 700 RHDEV h h h 700 RHLAPD h h h 700 RMHBI h h h 700 RMVGCH h h h 700 RNCM h h h 700 RNLC h h h 700 RNLCH h h h 700 RNTCH h h h 700 RQRCQS h h h 700 RQUNC h h h 700 RQUPD h h h 700 RTTRINT h h h 700 RTVPH h h h 700 RXCLMO h h h 700 RXCML h h h 700 RXELS h h h 700 RXEPL h h h 700 RXOISH h h h 700 RXOLS h h h 700 RXOPL h h h 701 C7TCP 0 0 0 701 RCLCCH h h h 701 RHLAPD h h h 701 RQRCQS h h h 701 RQUNC h h h 702 C7TCP 0 0 0 703 SGSCR 0 0 0 704 SGSCR 0 0 0 710 RCLCCH h h h 710 RCSCB h h h 710 RMHBI h h h 710 RMVGCH h h h 710 RNCM h h h 710 RNLC h h h 710 RNLCH h h h 710 RNTCH h h h 710 RTTRINT h h h 710 RTVPH h h h 710 RXCLIM h h h 710 RXCLMO h h h 710 RXCML h h h 710 RXEPL h h h 710 RXOISH h h h 710 RXOPL h h h



720 RCLCCH h h h 720 RCSCB h h h 720 RMHBI h h h 720 RNCM h h h 720 RNLC h h h 720 RNLCH h h h 720 RNTCH h h h 720 RTTRINT h h h 720 RTVPH h h h 720 RXCML h h h 720 RXCLIM h h h 720 RXCLMO h h h 720 RXEPL h h h 720 RXOISH h h h 720 RXOPL h h h 730 RCSCB h h h 730 RNLCH h h h 730 RNTCH h h h 730 RXCLIM h h h 730 RXCLMO h h h 730 RXCML h h h 731 RXCML h h h 755 TPLAT 0 0 0 756 TPLAT 0 0 0

3.5 Local APZ Size Alteration Events

SAE BLOCK COND R-BSC Comb TRC Comments --------------------------------------------------- Local APZ SAE 500 OCITS 12 12 12 500 RTS00-19 150 150 150 501 RTS00-19 150 150 150 502 RTS00-19 0 0 0 503 RTS00-19 101 101 101 504 RTS00-19 0 0 0 505 RTS00-19 101 101 101 506 RTS00-19 101 101 101 507 RTS00-19 101 101 101 800 AD1 A3x 512 512 512 800 AF 32 32 32 800 APFMI 64 64 64 800 APFPI 256 256 256 800 AT A3x 125 125 125 800 COCAT 300 300 300 800 LADSD A3x 0 0 0 800 LAEL 10000 10000 10000 800 LOGB 200 200 200 800 TW RBS200 128 128 0 801 EXAL0 RBS200 TRI*32 TRI*32 32 801 EXAL0 RBS2000 32 32 32 801 EXAL2 A3x 32 32 32 803 ALSA RBS200 4128 4128 0 803 ALSA RBS2000 32 32 0 804 ALSA RBS200 4128 4128 0



804 ALSA RBS2000 32 32 0 805 DBTAB7 100 100 100 805 FIE 128 128 128 806 ALIM A3x 10 10 10 806 DBTAB7 10 10 10 807 RPDI 3173 3173 3173 809 LAVS 16384 16384 16384 810 LAVS 1024 1024 1024 812 MFM 106 112 8 GS12,Max step=1000 812 MFM A3x 207 219 12 GS890,Max step=1000 812 MFM A55 393 405 12 GS890,Max step=1000 813 MFM 417 417 161 Max step=1000 814 DBCOH 10 10 10 814 DBPOH 10 10 10 815 DBTRH 256 256 256 816 DBTRH 8192 8192 8192 817 DBTRH 8192 8192 8192 888 LASCS A55 200 200 200

3.6 Node Changes Affecting 'Fixed' SAE Settings

The following node changes affects the SAE setting when using the Fixed SAE Setting strategy.

3.6.1 Number of Internal GSM Cells

When adding a number of cells belonging to the current BSC or BSC/TRC the following SAEs should be adjusted. If these SAEs are set too high, a large amount of dummy counters will be transferred to the APG. This means increased load for APG and an increased risk for overload problems.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 298 Global 0 - 1024 NO OF INTERNAL CELLS Delta = number of added cells. The value should be equal to the actual number of internal cells or slightly higher. Command to check current number of internal cells: RLCRP:CELL=ALL; 522 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE INTERNAL HANDOVER COUNTER FILE Delta = 2 * (number of internal neighboring cells to the new cell). There is a restriction that both handover counter files (SAE 522 + SAE 523) may not in total exceed the size of the neighboring cell relation file (SAE 524). Command to check current number



of cell relations: RLNRP:CELL=ALL, NODATA; 523 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE EXTERNAL HANDOVER COUNTER FILE Delta = 1 * (number of external neighboring cells to the new cell). There is a restriction that both handover counter files (SAE 522 + SAE 523) may not in total exceed the size of the neighboring cell relation file (SAE 524). Command to check current number of cell relations: RLNRP:CELL=ALL, NODATA; 524 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE NEIGHBORING CELL RELATION FILE Delta = according to the restriction below. There is a restriction that the size of the neighboring cell relation file (SAE 524) may not fall below the actual sum of both handover counter files (SAE 522 + SAE 523). Command to check current number of cell relations: RLNRP:CELL=ALL,NODATA;

3.6.2 Number of Internal GAN Cells

When adding a number of GAN cells belonging to the current BSC or BSC/TRC the following SAEs should be adjusted. If these SAEs are set too high, a large amount of dummy counters will be transferred to the APG. This means increased load for APG and an increased risk for overload problems.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 1163 Global 0 - 2048 NUMBER OF GAN CELLS The SAE increases or decreases the Generic Access Network (GAN) cell individual file. Guiding value = Site dependent for BSC and BSC/TRC. = 0 for TRC.

3.6.3 Number of Cell Relations



When adding a number of cell relations in the BSC or BSC/TRC the following SAEs should be adjusted. If these are set too high, a large amount of dummy counters will be transferred to theAPG. This means increased load for APG and an increased risk for overload problems. This is applicable if Fixed SAE Settings are in use.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 502 RQUCD 0 - 16384 NO OF UTRAN CELL RELATIONS The SAE handles the UTRAN FDD cell relation file. Guiding value = site dependent for BSC, BSC/TRC = 0 for TRC Command to check current number of cell relations: RLNRP:CELL=ALL,UTRAN; 522 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE INTERNAL HANDOVER COUNTER FILE Delta = added number of cell relations between internal cells. (A mutual relation counted as two relations.) There is a restriction that both handover counter files (SAE 522 + SAE 523) may not in total exceed the size of the neighboring cell relation file (SAE 524). Command to check current number of cell relations: RLNRP:CELL=ALL, NODATA; 523 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE EXTERNAL HANDOVER COUNTER FILE Delta = added number of cell relations where one cell is external. There is a restriction that both handover counter files (SAE 522 + SAE 523) may not in total exceed the size of the neighboring cell relation file (SAE 524). Command to check current number of cell relations: RLNRP:CELL=ALL, NODATA; 524 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE NEIGHBORING CELL RELATION FILE Delta = according to the restriction



below. There is a restriction that the size of the neighboring cell relation file (SAE 524) may not fall below the actual sum of both handover counter files (SAE 522 + SAE 523). Command to check current number of cell relations: RLNRP:CELL=ALL,NODATA;

3.6.4 Number of CCITT CCS7 Signalling Links

This SAE is affected when the number of CCITT CCS7 signalling links is changed. Over dimensioning could increase the risk for delays on the CCS7 signalling links.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 166 C7DR2 0 - 65535 NO OF MESSAGE STORING BUFFERS Delta = 250 per signalling link. The SAE value should be 250 times the number of signalling links in use. Command to check current number of signalling links: C7LTP:LS=ALL;

3.6.5 Number of ANSI CCS7 Signalling Links

This SAE is affected when the number of ANSI CCS7 signalling links is changed. Over dimensioning SAE027 could increase the risk for delays on the CCS7 signalling links.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 027 S7DR 0 - 65534 NO OF MSU BUFFER RECORDS Delta = 250 per signalling link. The SAE value should be 250 times the number of signalling links in use for ANSI. Command to check current number of signalling links: S7SLP:LS=ALL;

3.6.6 Number of TRI-EMGs (Transmission Radio Interfaces)

This SAEs is affected when the number of TRI-EMs is changed. Over dimensioning of SAE 801 EXAL0 has an adverse affect on the idle load.

SAE Block Value Range Description and Hints ----------------------------------------------------------



801 EXAL0 0 - 65503 NO OF EXTERNAL ALARMS RECEIVERS FOR THE TRI'S Delta = 32. The SAE value shall be 32 * number of TRI EMGs. Command to check current number OF TRI EMGs: EXEGP:EMG=ALL;

3.6.7 Number of RPs

These SAEs are affected when the number of RPs is increased. In case of a node expansion it is advisable to check if these SAEs have to be adjusted.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 304 Global 1 - 1024 NO OF REGIONAL PROCESSORS Delta = 1. Change is needed only if any of the new RPs has the highest RP number. Guiding value = highest RP number + 1 Command to check highest used RP number: EXRPP:RP=ALL; 1822 Global 0 - 1024 NO OF TABLE ROWS IN DATABASE TABLE RPSRPBSPOS Delta = 1. Change is needed only if any of the new RPs has the highest RP number. Guiding value = 0 if RPB-S is not used. = (SAE 304) if RPB-S is used. 1850 RPMBH 0 - 16384 NO OF RECORDS FOR STORING HWI INFORMATION FOR BOARDS IN BYB 501 The SAE 1850 shall be set according to the number of RPs in the system (SAE 304). If SAE 304 is increased, SAE 1850 must be increased accordingly. Guiding value = 16 * (SAE 304).

3.6.8 Change of Group Switch

The process for replacing a GS12 switch with GS890 while reusing the already installed devices is commented in chapter 8.17.

3.6.9 Other SAEs Affected at Extreme Traffic Load



The values for Maximum Traffic Intensity are dependent on the traffic model (amount of hand overs, amount of registrations etc.). In the tables above, it is stated which SAEs that are traffic dependent (comment TD in the tables). In extreme cases more traffic may be handled, e.g. in the case of an unusual traffic mix. Then the traffic dependent SAE values might have to be increased.

It is necessary to activate Automatic Size Alteration and - if CCITT#7 signalling is used - Event Reporting Function for the block C7CO when using these SAE values.

The following SAEs are classified as traffic dependent in this sense and may have to be adjustedif the traffic exceeds the Maximum Traffic Intensity:

The calculations of the number of MS individuals and SCCP connections are based on the traffic in Erlang and an assumption that the amount of SDCCH connections is 40% of the traffic in Erlang.

3.6.10 BTS related settings

The blocks RXEFT and RXOFT holds a cache memory in BSC CP used when loading BTS SW, the size of this cache is controlled by SAE 538. RXEFT is for model G01, i.e the RBS200 family. RXOFT is for model G12, i.e the RBS2000 family. The BTS SW consists of a number of files and the largest file has to fit into the cache, otherwise BTS program load will fail. Larger sizes of the files can improve performance since more files fit into the cache. The SAE values are given in file segments, one segment holds 230 bytes of BTS software and consumes 272 bytes or 136 W16 DS memory in BSC.

Note that the size of SAE 538 RXOFT also impacts the size of the Transport Area (TA). By lowering the value of SAE 538 RXOFT (from the recommended 130 000 individuals), the TA will also be reduced. This gives double effect on memory savings.

The recommendations are as follows:

SAE RXEFT shall be 0 if RBS200 is not in use.

In a TRC node, which does not handle BTS SW, both SAEs shall be set to 0.

Standard guiding value, which gives space for two versions of BTS SW, also when using RBS200 on 900 and 1800 band:

538 RXEFT = 10 000

Table 3

SAE Applicable in node type Dependent on 913, 1161 BSC, BSC/TRC No. of MS individuals 500 C7CO All SCCP connections (CCITT) 500 SCCOC All SCCP connections (ANSI) 500 RABDI All No of MS individuals (CCITT) 500 RABDIAN All No of MS individuals (ANSI) 500 RMSCS BSC, BSC/TRC No of simultaneous signalling connection

setup procedures 500 RTATHB BSC Traffic (Erlang) on Ater interface 500 RTATHT If Ater interface is used Traffic (Erlang) on Ater interface 500 RTBTAP If Ater interface is used Traffic (Erlang) on Ater interface, CCITT

signalling 500 RTBTAPA If Ater interface is used Traffic (Erlang) on Ater interface, ANSI

signalling 500 RTTPR BSC/TRC, TRC Traffic in Erlang



538 RXOFT =130 000

3.7 Basis for Calculation of Fixed SAE Settings

The following values for Maximum Traffic Intensity (in Erlang) have been used as a base value in the calculations for the node types R-BSC and Combined BSC/TRC, dependent on GS type GS12 or GS890.

A margin for traffic peaks is included in the calculations. Therefore adjustments of the SAE values are required only in rare cases.

As for the SAEs related to devices RALT, RBLT, RTLBT, RTLTT and RTLTB, over dimensioning these values results in an increase in idle load. The Fixed SAE recommendations are based on the interface sizes as given in the table below. These are reasonable maximum values based on the Maximum Traffic Intensity for the various node types. The Abis interface is dimensioned for 2048 TRXs (4 devices per TRX) and on top of this full scale PCU with Edge configuration. Also a margin for some 100 semipermanent connections is included. This results in the following interface dimensioned in number of 64 kb/s devices, most figures are a multiple of 96 (in order to get an integer value for both 32 and 24 channel transmission systems):

If MSC in Pool is used there can be a need to increase the A interface.

For ET155-1 the assumption is that 10 ET155 terminals are used . For ET155-7 the assumption is that 8 ET155-7 terminals are used. Note that the ET155 dependent SAEs are conditional, that is if ET155 is not in use, then these SAEs (SAE500, 515 and 529 for applicable blocks) should be set to zero.

If more devices are required, depending on the BSS Network Configuration (Abis/Ater/A/Lb Interface, LAPD Concentration/Multiplexing, EMGs etc.) the SAEs related to DIPs and devices RALT, RBLT, RTLBT, RTLTT and RTLTB should be dimensioned accordingly. This includes SAE 500, SAE 515 and SAE 529 for the applicable blocks.

The recommendations are based on that only one transmission type (24 or 32 channel PCM) is

Table 4

GS Type BSC BSC/TRC, no Ater interface

BSC/TRC with Ater interface

TRC

GS12 6400 6400 6400 7400 GS890 12288 12288 12288 12288

Table 5

Node type: R-BSC BSC/TRC TRC GS: GS12 GS890 GS12 GS890 GS12 GS890 A interface - - 6528 12480 7488 12480 Abis interface 7104 11232 7104 11232 - - Ater Interface 1728 3264 2016 3552 2304 3552 Gb interface, 24 channels

1536 1536 1536 1536 - -

Gb interface, 32 channels

2048 2048 2048 2048 - -

Lb interface, 24 channels

48 48 48 48 - -

Lb interface, 32 channels

64 64 64 64 - -



used in a node. If both are in use the recommendations should be used with care. SAEs for a transmission type not in use on an interface should be set to zero. Also if ET155 is in use in combination with 24 or 32 channel ETCs over dimensioning should be avoided. The guiding values for ET155 given above are such that ET155 is possible to use fully on any interface.

4 Global Size Alteration Events

4.1 APT Size Alteration Events

For fixed SAE settings see chapter 3.2.

If the SAEs are marked with *), they do not need to be changed after initial settings.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 000*)LOAS 1 - 65534 NO OF ROUTES (RMPAG) Block RMPAG has no route file of TRAN its own, but uses the NI-value to find out if Paging Messages are handled. 1 - : Paging Messages are handled. Guiding value = 1. 019*)S7DP 0 - 7281 NO OF DESTINATIONS S7DR Each record contains data for a M3UADR cluster destination, member destination, or exception list members. If ANSI CCS7 is used: Guiding value = 17 for BSC/TRC and TRC. = 3 for BSC. If CCITT CCS7 is used: Guiding value = 0. COMMAND: S7DEP:DEST=ALL; 027 S7DR 0 - 65534 NO OF MSU BUFFER RECORDS Each record contains message data. A record is seized when a transfer or originating message cannot be immediately transmitted to the destination. The record is released when the message can be transmitted. At decrease, SAE 052 must be performed first. Guiding value = 250*(SAE 052) if ANSI CCS7 is used. = 0 if CCITT CCS7 is used. 048 TIMET 0 - 512 NO OF MEASURING PROGRAMS A measuring program defines a set of recordings executed by a



user block. The required number of measuring programs is depending on the number of user blocks (functions). /------------------\ |FUNCTION|MEASURING| |BLOCK |PROGRAMS | +--------+---------+ | C7PMA2 | 6 | | C7TMA2 | 8 | | LOAM | 2 | | RHLR | 1 | | RXCHEC | 1 | | | ------- | | | 18 | \------------------/ Guiding value = 18 if CCITT CCS7 is used. = 4 if ANSI CCS7 is used. COMMAND: TRDIP:ALL; 051 DEPO1 0 - 65535 NO OF HARDWARE UNIT SUITES This size alteration event defines the number of individuals containing positions for HW objects. Each individual may contain the position of up to 3 HW objects. Increase the number of individuals when the command for defining the position of HW objects, EXPOI, results in fault code 3. Guiding value = number of HW objects in the exchange. 052 SCRD 0 - 1024 NO OF ANSI SIGNALLING LINKS S7DR S7SL is the main block for this S7LS SAE. S7SL At increase, SAE 027 must be performed first. Guiding value = site dependent if ANSI CCS7 is used. = 0 if CCITT CCS7 is used. COMMAND: S7SLP:LS=ALL; 058 COSEM 0 - 256 NO OF TIME SWITCH MODULES GS TSM is the main block for this GSM1 SAE. The SAE increases or GSM2 decrease the number of TSMs. SNEC SAE individuals are seized at SNEFD connection of TSM and released SNEFI at disconnection.



SNETR At SAE alteration SAE 1094 and SRSTRAF SAE 58 must be increased in the TSM following order: First Second SAE1094 SAE058 Decrease in reverse order. Guiding value = site dependent. COMMAND: EXEMP:RP=ALL,EM=ALL; 078*)LOAS 0 - 65535 NO OF TIME SWITCH BUSES Time switch buses are not used by the BSC. Guiding value = 0. 087 TRAN1 0 - 65535 NO OF DIGITAL PATHS This size alteration event defines the allowed total number of digital paths that could be connected to GS and TRI. It is used for translating digital paths in the blocks below. Guiding value for 32 channel PCM systems = (SAE 515 DIPRALT)+ (SAE 515 DIPRBLT)+(SAE 515 DIPRTT)+(SAE 515 DIPRTB)+(SAE 515 DIPRTL)+(SAE 515 DIPRTG)+ (no of digital paths in block RIDIPST) + (no of paths in block RXODPI). Guiding value for 24 channel PCM systems= (SAE 515 DIPRAT4) + (SAE 515 DIPRBT4) + (SAE 515 DIPRTT4) + (SAE 515 DIPRTB4) + (SAE 515 DIPRTL4) + (SAE 515 DIPRTG4) + (no of paths in block RXODPI); COMMAND: DTDIP:DIP=ALL; 097 SECA 0 - 32767 NO OF SEMIPERMANENT CONNECTIONS SECOM SECA/SECOM is used for setting up command ordered semipermanent connections. This function may be used for other reasons like loop test or colocation with other equipment. For calculation below, the real values for C7GST and S7GST shall be used. See 566 C7GST and 554 S7GST Guiding value = (SAE 566 C7ST2C) + (SAE 566 C7GST) + (SAE 566 C7GSTH) + (SAE 566 C7GSTAH) + (other use)if



CCITT CCS7 is used. = (SAE 554 S7STG) + (SAE 554 S7GST) + (SAE 554 S7HST) + (other use)if ANSI CCS7 is used. COMMAND: EXSCP:NAME=ALL; if CCITT CCS7 is used. 156 C7GT 0 - 65534 NO OF SUBSYSTEMS C7SM The subsystem data records contain information regarding each subsystem defined to the local SCCP. Guiding value = 3. COMMAND: S7MSP:SP=ALL,SSN=ALL; (ANSI) COMMAND: C7NCP:SP=ALL,SSN=ALL; (CCITT) 157*)C7GT 0 - 65534 NO OF GLOBAL TITLE ROUTING CASES The global title case data records contain information regarding each global title case defined at the local SCCP. Guiding value = 1. COMMAND: C7GCP:GTRC=ALL; 159*)C7GT 0 - 65534 NO OF GLOBAL TITLE TRANSLATION TREE RECORDS The tree data records contain pointers to translation results. Guiding value = 20. COMMAND: C7GSP; 160*)C7GT 0 - 65534 NO OF GLOBAL TITLE SERIES TRANSLATION RESULTS Guiding value = 1. COMMAND: C7GSP; 163 C7DR2 0 - 65534 NO OF CCITT 7 SIGNALLING LINKS C7LS2 This size alteration event must C7SL2 have the same number of individuals as (SAE 566 C7ST2C, C7GST, C7GSTH, C7GSTAH). The number of signalling terminals is indicated. Count the number of CCITT no 7 signalling terminals in all blocks together. For C7GST, the real value shall be used, see 566 C7GST. At size alteration must be increased in the following order:



First Second C7DR2(165) C7LS2(164) Third Fourth C7DR2(166) C7SL2(163) Decrease in reverse order. Guiding value = site dependent if CCITT CCS7 is used. = 0 if ANSI CCS7 is used. COMMAND: C7LTP:LS=ALL; 164*)C7ACCL2 0 - 1022 NO OF SIGNALLING LINK SETS C7DP2 If CCITT CCS7 is used: C7DR2 At size alteration must be C7EPC2 increased in the following C7LS2 order: C7MCDA2 C7PDA First Second C7PDA C7DR2(165) C7LS2(164) C7PVC2 Third Fourth C7DR2(166) C7SL2(163) Decrease in reverse order. Guiding value = 17 for BSC/TRC and TRC. = 3 for BSC. If ANSI CCS7 is used: Guiding value = 0. COMMAND: C7LDP:LS=ALL; 165*)C7DP2 0 - 4079 NO OF SIGNALLING POINTS C7DR2 If CCITT CCS7 is used: C7EPC2 At size alteration must be C7LS2 increased in the following C7MCDA2 order: C7PVC2 M3UADR First Second C7DR2(165) C7LS2(164) Third Fourth C7DR2(166) C7SL2(163) Decrease in reverse order. Guiding value = 17 for BSC/TRC and TRC. = 3 for BSC. If ANSI CCS7 is used: Guiding value = 0. COMMAND: C7SPP:SP=ALL;



166 C7DR2 0 - 65535 NO OF MESSAGE STORING BUFFERS Minimum value is twice the number of signalling links. At size alteration must be increased in the following order: First Second C7DR2(165) C7LS2(164) Third Fourth C7DR2(166) C7SL2(163) Decrease in reverse order. Note that overdimensioning of this SAE may cause too long delays on the A and Ater interfaces. Guiding value = 250 * (SAE 163) if CCITT CCS7 is used. = 0 if ANSI CCS7 is used. 191*)C7CO 0 - 4079 NO OF SIGNALLING POINTS IN THE C7GT SCCP NETWORK C7RTA The signalling point record C7SM contains C7SRM information regarding each C7SRMH signalling point defined at local SCCP. If CCITT CCS7 is used: Guiding value = 17 for BSC/TRC and TRC. = 3 for BSC. If ANSI CCS7 is used: Guiding value = 0. COMMAND: C7NCP:SP=ALL; if CCITT CCS7 is used. 207*)S7DP 0 - 1024 NO OF ANSI LINK SET INDIVIDUALS S7DR This size alteration event S7LS supports the link set and combined link set files. For each link set record, two combined link set records are allocated. If ANSI CCS7 is used: Guiding value = 17 for BSC/TRC and TRC. = 3 for BSC. If CCITT CCS7 is used: Guiding value = 0. COMMAND: S7LSP:LSN=ALL; 233*)SCRD 0 - 7536 NO OF ANSI CLUSTER RECORDS



S7DP Guiding value = 2 if ANSI CCS7 S7DR is used. = 0 if CCITT CCS7 is used. COMMAND: S7DEP:DEST=ALL; 256*)C7ER 0 - 65535 NO OF REGISTERED REPORTS One record contains data for one report. The sum of values of parameter EMAX in command C7ESC for all events that reports are required on is indicated. Guiding value = 5000 if CCITT CCS7 is used and event recording is activated. = 100 if ANSI CCS7 is used. COMMAND: C7ESP:ENUM=ALL; if CCITT CCS7 is used. 262*)SCRD 0 - 125 NO OF GATEWAY LINK SETS SGSCR Guiding value = 0. S7DR S7LS 298 RCACCA 0 - 1024 NO OF INTERNAL CELLS RCCD The SAE controls the file size RCCGD of the internal cell file. RCLAH Guiding value = Cell planning RCLS dependent for RCSCB BSC and BSC/TRC. RCSES = 1 for TRC. RCSI COMMAND: RLDEP:CELL=ALL; RCSLC RGCNT RGCON RGNCC RGRLC RGSERV RGSI RMASHO RMASS RMCASS RMCC RMCHO RMCIPH RMCNT RMDTM RMHBI RMHOAC RMHOEB RMHOEC RMPAG RMQ RMRLS



RMSCS RMTRE RMVGASS RMVGCH RNCM RNLC RNLCH RNLCT RNTCH RNSDCCH ROBAR ROCTR ROMTR RORIR ROTRAN ROTRS RQCD RQRCQS RQUCD RQUNC RQUPD 299 RCCD 0 - 2048 NO OF EXTERNAL CELLS RGSI The SAE controls the file size RGCON of the external cell file. RQCD Guiding value = Cell planning ROMTR dependent for ROTRAN BSC and BSC/TRC. ROCTR = 1 for TRC. COMMAND: RLDEP:CELL=ALL,EXT; 437*)S7DR 0-65534 NO OF USER PART RECORDS Guiding value = 1 if ANSI CCS7 is used. = 0 if CCITT CCS7 is used. COMMAND: S7LPP; if ANSI CCS7 is used. 442 CH 0 - 512 NO OF PHYSICAL MUP INDIVIDUALS COSEM Each individual represents 1024 MUX3 Multiple Positions (MUPs). XM Individuals are seized at connection of Switch Matrix (XM) unit and released at disconnection. Each connected XM board owns 16384 UPDs. Minimum step size increase and decrease is 16 individuals. At size alteration SAE must be increased in the following order. First Second Third SAE442 SAE600(CH) SAE600(XM) Decrease in reverse order. Guiding value = site dependent.



COMMAND:EXMDP; 456*)SCRD 0 - 255 NO OF NETWORK RECORDS S7DR Guiding value = 1 if ANSI CCS7 is used. = 0 if CCITT CCS7 is used. 459*)SCCOC 0 - 7281 NO OF ANSI SCCP SIGNALLING SCGD POINTS SCMD If ANSI CCS7 is used: SCRD Guiding value = 17 for BSC/TRC and TRC. = 3 for BSC. (The value should be equal to or less than SAE 019.) If CCITT CCS7 is used: Guiding value = 0. COMMAND: S7NCP:SP=ALL; if ANSI CCS7 is used. 913 RGCON 0-32768 NO OF MS INDIVIDUALS RGRLC RGSERV One individual is needed for RMASHO each active TCH and SDCCH RMASS channel in the BSC or BSC/TRC. RMCASS Least extension or reduction RMCC stage = 1 individual. This SAE RMCCHM is automatically supervised for RMCHO congestion. RMCIPH Guiding value for BSC = RMCR 1.4X * (SAE 500 RTLTB/RTLTB24/ RMDTM RTLTB15/RTLTB2/RTLTB3), RMHBI see note below. RMHOAC Guiding value for BSC/TRC = RMHOEB 1.4X * (SAE 500 RALT/RALT24/ RMHOEC RALT15/RALT2/RALT3 for RMHTR own BSC) RMPH Command: STDSP:DETY=RALT/RALT24/ RMPOS RALT15/RALT2/RALT3, RMQ BSC=OWN; RMRLS Guiding value for TRC = 1. RMTRE RMVGASS RMVGCH RNLCT RODCR RQRCQS Note:X=4 if full rate only is used. X=8 if half rate only is used. X is between 4 and 8 for a mix of half rate and full rate. For example, X=6 at 50% of each speech codec type. 969 RTTF1S 0 - 683 NO OF RTTF1S/RTTF1D SNT RTTF1D INDIVIDUALS This SAE is not used.



Number of SNTs and corresponding device individuals for full-rate (FR) transcoder supported by R4 hardware. Size alteration of the device data file is done in steps of 32 (no of devices per SNT), and size alteration of CM and SNT data file is done in steps of 1. Guiding value = 0. (Not used in BSC) Command: NTSTP:SNT=ALL; 970 RTTF2S 0 - 683 NO OF RTTF2S/RTTF2D SNT RTTF2D INDIVIDUALS This SAE is not used. Number of SNTs and corresponding device individuals for enhanced full-rate (EFR) transcoder supported by R4 hardware. Size alteration of the device data file is done in steps of 32 (no of devices per SNT), and size alteration of CM and SNT data file is done in steps of 1. Guiding value = 0. (Not used in BSC) Command: NTSTP:SNT=ALL; 971 RTTH2S 0 - 683 NO OF RTTH2S/RTTH2D SNT RTTH2D INDIVIDUALS This SAE is not used. Number of SNTs and corresponding device individuals for half-rate (HR) transcoder supported by R4 hardware. Size alteration of the device data file is done in steps of 32 (no of devices per SNT), and size alteration of CM and SNT data file is done in steps of 1. Guiding value = 0. (Not used in BSC) Command: NTSTP:SNT=ALL; 995 RTTF1S1 0 - 683 NO OF RTTF1S1/RTTF1D1 SNT RTTF1D1 INDIVIDUALS Number of SNTs and corresponding device individuals for full-rate (FR) transcoder supported by R5 hardware. Size alteration of the device data file is done in steps of 32 (no of devices per SNT), and size alteration of CM and SNT data file is done in steps of 1. Guiding value = 0 for BSC. = site dependent for BSC/TRC and



TRC (The highest number of type RTTF1S1). = number of transcoder R5 boards in the exchange, if Self Con- figuring Trans- coder in Pools is used. Command: NTSTP:SNT=ALL; 996 RTTF1S2 0 - 683 NO OF RTTF1S2/RTTF1D2 SNT RTTF1D2 INDIVIDUALS Number of SNTs and corresponding device individuals for enhanced full-rate (EFR) transcoder supported by R5 hardware. Size alteration of the device data file is done in steps of 32 (no of devices per SNT), and size alteration of CM and SNT data file is done in steps of 1. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC (The highest number of type RTTF1S2). = number of transcoder R5 boards in the exchange, if Self Con- figuring Trans- coder in Pools is used. Command: NTSTP:SNT=ALL; 997 RCSCB 0-16384 NO OF MESSAGE PAGE FILE RCTIMER INDIVIDUALS Least extension or reduction stage = 1 message. Guiding value for BSC and BSC/TRC = 0 if Short Message Service Cell Broadcast is not used. = no of Short Message Service Cell Broadcast message pages that can be defined in the BSC. Guiding value for TRC = 0. 1001 COHW 0 - 8388607 NO OF DEVICE INDIVIDUALS COMAIN A device individual is used in CODIG AM call for control of HW for tone sending, sending and receiving of codes and digits, and for announcement machines.



Guiding value = 0 (AMs do not exist in BSC). 1047 RTTH1D 0 - 683 NO OF RTTH1S/RTTH1D SNT RTTH1S INDIVIDUALS Number of SNTs and corresponding device individuals for half-rate (HR) transcoder supported by R5 hardware. Size alteration of the device data file is done in steps of 32 (no of devices per SNT), and size alteration of CM and SNT data file is done in steps of 1. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC (The highest number of type RTTH1S). = number of transcoder R5 boards in the exchange, if Self Con- figuring Trans- coder in Pools is used. Command: NTSTP:SNT=ALL; 1078 SCGD 0 - 65534 NO OF SUBSYSTEMS CONNECTED TO AN SCMD SCCP SIGNALLING POINT. SCRD One individual is seized when a subsystem is defined and released when a subsystem is deleted. Guiding value = 3. Command: C7NCP:SP=ALL,SSN=ALL; 1079 SCGD 0 - 65534 NO OF INDIVIDUALS TO STORE DATA SCRD ABOUT PRIMARY AND SECONDARY DESTINATIONS (SIGNALLING POINTS OR SUBSYSTEMS). One individual is seized when a Global Title Routing Case (GTRC) is defined and is released when a GTRC is deleted. Guiding value = 1. Command: C7GCP:GTRC=ALL; 1094 COSEM 0 - 8388607 NO OF MUP INDIVIDUALS COX Global MUP individuals are used to store MUP data, such as connection individual, switch type, relevant physical MUP/virtual MUP data. For each connection, at least two individuals are seized. At SAE alteration SAE 1094 and



SAE 58 must be increased in the following order: First Second SAE 1094 SAE 058 Decrease in reverse order. Guiding value = site dependent (The minimum number of individuals is the number of physical MUPs defined by SAE 442 or SAE 058). 1109 RTTGD 0 - 255 NUMBER OF RTTGS/RTTGD SNT RTTGS INDIVIDUALS Number of SNT and corresponding device individuals for FR, EFR, HR, AMR FR, AMR HR and AMR WB transcoder supported by TRA R6 hardware. The relation between the number of SNT Owner individuals is: 1 SNT ind. = 1 CM ind. = 8 Config Data ind. = 256 Devices. The relation between the number of Device Owner individuals is: 1 SNT ind. = 8 Config Data ind.= 256 Device ind. = 256 Idle List ind. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC (The highest number of type RTTGS). Command: NTSTP:SNT=ALL; 1130 COMAIN 0 - 8388607 NO OF CHANNEL INDIVIDUALS CODIG The channel represents the subscriber in an SV, from a user's point of view. Guiding value = 0 (AMs do not exist in BSC). 1133 ROTRAN 0 - 2048 NO OF UTRAN CELL INDIVIDUALS. ROCTR The SAE increases or decreases ROMTR the number of external UTRAN RQUCD cell individuals Guiding value = 2048. Command: RLDEP:CELL=ALL,EXT, UTRAN; 1142 RTTAF1S 0 - 683 NO OF RTTAF1S/RTTAF1D SNT RTTAF1D INDIVIDUALS. Number of SNTs and corresponding device individuals for Adaptive Multi Rate (AMR) full-rate (FR)



transcoder supported by R5B hardware. Size alteration of the device data file is done in steps of 32 (no of devices per SNT), and size alteration of CM and SNT data file is done in steps of 1. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC (The highest number of type RTTAF1S). = number of transcoder R5B boards in the exchange, if Self Con- figuring Trans- coder in Pools is used. Command: NTSTP:SNT=ALL; 1143 RTTAH1S 0 - 683 NO OF RTTAH1S/RTTAH1D SNT RTTAH1D INDIVIDUALS. Number of SNTs and corresponding device individuals for Adaptive Multi Rate (AMR) half-rate (HR) transcoder supported by R5B hardware. Size alteration of the device data file is done in steps of 32 (no of devices per SNT), and size alteration of CM and SNT data file is done in steps of 1. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC (The highest number of type RTTAH1S). = number of transcoder R5B boards in the exchange, if Self Con- figuring Trans- coder in Pools is used. Command: NTSTP:SNT=ALL; 1152 RCC 0 - 2048 NO OF CHANNEL GROUP RCCGD INDIVIDUALS. RNCM RCCGD is the master block of RNLCH this SAE. RNSDCCH If it is not possible to decrease the RNTCH SAE even if the number of Channel Groups is less than the SAE value it is necessary to delete and define the Channel Groups. Follow



OPI: BSC, Channel Groups, Delete and: BSC, Channel Groups, Define. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC. Command: RLDGP:CELL=ALL; 1153 RBLT 0 - 4095 NO OF TRANCEIVER CONTROLLER RCC (TRXC) INDIVIDUALS. RCCGD RCLCCH RCSCB RXCMOO is the master block of RCSI thiS SAE. RGPDCH RGRLC RGSI Guiding value = site dependent RHLAPD for BSC and RHLH BSC/TRC. RHLINK = 0 for TRC. RMHBI Command = RXMSP:MOTY=RXETRX; RMVGCH RXMSP:MOTY=RXOTRX; RMPAG RNCM RNLC RNLCH RNSDCCH RNTCH ROTRS RQRCQS RQUNC RQUPD RTODCON RTSIGH RTTRINT RXCBM RXCCD RXCCOR RXCDI RXCLCO RXCLIM RXCLMO RXCMOO RXCMSD 1155 GCURR 0 - 1048575 NO OF REGISTERED MS INDIVIDUALS GCIMSI One individual is needed for each GCRLC MS registered in the Home Base Controller (HBSC). Guiding value = Site dependent for BSC and BSC/TRC. = 0 for TRC. 1157 RTTG1D 0 - 127 NUMBER OF RTTG1S/RTTG1D SNT RTTG1S INDIVIDUALS Number of SNT and corresponding device individuals for FR, EFR,



HR, AMR FR, AMR HR and AMR WB transcoder supported by TRA R7 hardware, to be connected in a BSC/TRC or TRC. SAE individuals must not be released if corresponding device individuals are attached to recording references. SAE individuals are seized at connection of SNTs and released at disconnection of SNTs. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC (The highest number of type RTTG1S). Command: NTSTP:SNT=ALL; 1158 RCLCCH 2 - 256 NUMBER OF TRANSCEIVER RCSCB HANDLER INDIVIDUALS RHDEV This SAE corresponds to the number RHLAPD of TRH Regional Processors. RHLH RHSNT Guiding value = site dependent RHTRH for BSC and RMPAG BSC/TRC RQRCQS = 2 for TRC. RQUNC RQUPD 1161 GCCC 0 - 16384 NO GAN SESSION INDIVIDUALS GCMSGH One individual is needed for each GCASS active GAN signalling connection GCHO between Mobile Station (MS) and GCPOS Mobile Switching Centre (MSC) Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC. 1162 RMHAIDL 0 - 32768 NUMBER OF HAI INDIVIDUALS RMHAIUL One individual is needed for each Signalling Connection Control (SCCP) connection. Note! If the calculated number of individuals exceeds the maximum value, the SAE must be set to its maximum size. Guiding value = (SAE1161)+(SAE913) for BSC and BSC/TRC = 1 for TRC 1163 ROTRAN 0 - 2048 NUMBER OF GAN CELLS GCCD The SAE increases or decreases the GCRLC Generic Access Network (GAN) cell GCCGH individual file.



Guiding value = Site dependent for BSC and BSC/TRC. = 0 for TRC.

4.2 APZ Size Alteration Events



SAE Block Value Range Description and Hints --------------------------------------------------------- 301*)IOH 1000 - 65535 SEIZURE QUEUE FOR I/O DEVICES AND ALARM LIST The queue elements are used as input queue for alarms, alarm list and different seizing signals towards alphanumerical and file devices. Guiding value = 10000. 302 ADE 16 - 1024 NO OF I/O ALPHANUMERICAL AUE INDIVIDUALS AFP Guiding value = (SAE 800 AF) + AICP (SAE 800 AT) + (SAE 800 TW) + AOT no of AMTP devices defined OID (there is one AMTP device for each link to an Operation and Maintenance Center). AOT is the master block of this SAE. 303*)FIC 1 - 1024 NO OF I/O FILE DEVICES FIO Size alteration case for the FIT number of file devices (magnetic tape stations, cartridge tape units and data channels). FIC and FIT are not used in A55. Guiding value = 30. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX This size alteration event LARP includes all RPs directly RENFD connected to the RP-bus RPADM including RPG2s, RPADS RPG3s, RPPs and PGWs. EMRPs are RPAL not included. The RP with the RPDI highest number + 1 (in the RP RPDU allocation) is indicated. RPDUD Note also that this size RPFD alteration event is dependent on RPIFD SAE 807 being sufficiently high. RPITAB RPADM is the master block of RPREC this SAE. RPREP Guiding value = site dependent.



RPRES COMMAND: EXRPP:RP=ALL; RPROUT 310 CSLDEV 1 - 1024 NO OF EXTENSION MODULE GROUPS CSLLINK EMGADM is the master block of CSLM7 this SAE. Note that the BSC can CSLSEMI only handle 256 EMGs. CSLSNT Guiding value = total number of EMGADM BTS sites with TRI. EMGADS COMMAND: EXEGP:EMG=ALL; EMGAL EMGDI EMGDU EMGDUD EMGFD EMGREC EMGREP EMGRES FCEET FCEPEX LAEP RPROUT 311 CLC 0 - 1024 NO OF STC-STR SIGNALLING LINKS At least one link per EMG (SAE 310) is required. Maximum two links per EMG can be defined. Guiding value = 2*(SAE 310) if redundancy = 1*(SAE 310) if not redundancy COMMAND: EXCLP:EQM=ALL; 330*)OIDC 0 - 1000 NO OF PASSWORD INDIVIDUALS Guiding value = 16. 332*)LAEL 0 - 65535 NO OF EMRP VARIABLES PER EMRP Guiding value = 10000. COMMAND: PRINT EMRP; 333*)CPSPTRA 50 - 1024 NO OF TRANSPORT INDIVIDUALS Guiding value = 506 (Not A55). 334*)CPSPTRA 16 - 512 NO OF TSAP INDIVIDUALS Guiding value = 30*n, where n denotes the number of Support Processor Groups (normally n = 1). Not A55 COMMAND: EXTDP; 340*)LARI 1 - 1024 NO OF FUNCTION CODES The highest numbered function code + 1 is the minimum number of individuals needed. Least extension and reduction step = 1 individual. Guiding value = 1024.



341*)FMI 2 - 16383 NO OF FILE REFERENCE INDIVIDUALS Guiding value = 128. 343*)BUE 1 - 1023 NO OF REGIONAL SOFTWARE UNITS LAEC The number of regional software LAEL units + 1 is the minimum number PCEI of individuals needed. The number of software units can be obtained by means of the command LAEIP:SUID=ALL; During function change it is advisable to increase this value by at least 10 (included in the guiding value below). LAEC is the master block of this SAE. Guiding value = 1023. COMMAND: LAEIP:SUNAME=ALL; 344*)ASCP 16 - 32767 NO OF ALPHA NUMERIC SESSION INDIVIDUALS Two files are contained, one for session data and one for print- buffers. There are two print- buffers to every session individual. Guiding value = 256 (Not A55). 345 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 W Note: 32 W is equal to 64 octets. It is advisable to set an alarm to be issued when most of the data file is used (command AFTSS:...). Least extension and reduction step = 1 individual. The recording functions will use the following number of 32 W buffers: 1 per Cell Traffic Recording (CTR). Value range: 0 - 1. COMMAND: RATRP; 1 per Mobile Traffic Recording (MTR) with file output. Value range: 0 - 4. 1 per Channel Event Recording (CER). Value range: 0 - 16. COMMAND: RACEP; 1 per Dropped Call Recording (DCR). Value range: 0 - 1. COMMAND: Internal command for DCR. 1 per Parameter Collection. Value range: 0 - 1. COMMAND: RAPCP;



Guiding value = 270 + (no of TRXs) + (no of CFs). The Guiding Value includes the maximum number of recordings. COMMAND: RXMSP:MOTY=RXETRX; RXMSP:MOTY=RXOTRX; RXMSP:MOTY=RXOCF; 346 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 64 W Note: 64 W is equal to 128 octets. It is advisable to set an alarm to be issued when most of the data file is used (command AFTSS:...). Least extension and reduction step = 1 individual. The recording function Radio Interference Recording will use the following number of 64 W buffers: 61 + (no of Radio Interference Recordings). value range: 0 - 71. COMMAND: RARRP:RID=ALL; 8 per Call Path Tracing. Value: 8. COMMAND: RAPTI; Guiding value = 460 + (no of TRXs) + (no of CFs) + (SAE 298) + 8. The Guiding Value includes the maximum number of recordings. COMMAND: RXMSP:MOTY=RXETRX; RXMSP:MOTY=RXOTRX; RXMSP:MOTY=RXOCF; 347 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 128 W The number of pre-allocated (by CCS) buffers used for A-interface message handling is checked with command C7BPP. Note: 128 W is equal to 256 octets. It is advisable to set an alarm to be issued when most of the data file is used (command AFTSS:...). Guiding value = 652 + (no of preallocated buffers by CCS) + 8. COMMAND: C7BPP; 348 LAD 50 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 256 W The number of pre-allocated (by CCS) buffers used for A-interface message handling is



checked with command C7BPP. Note: 256 W is equal to 512 octets. It is advisable to set an alarm to be issued when most of the data file is used (command AFTSS:...). Guiding value = 112 + (no of preallocated buffers by CCS) + 8. COMMAND: C7BPP; 349 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 512 W The number of pre-allocated (by CCS) buffers used for A-interface message handling is checked with command C7BPP. Note: 512 W is equal to 1024 octets. It is advisable to set an alarm to be issued when most of the data file is used (command AFTSS:...). The recording function Radio Interference Recording will use the following number of 512 W buffers: 40 if Radio Interference Recording iS used. Value range: 0 or 40. COMMAND: RARRP:RID=ALL; Guiding value = 228 + (no of preallocated buffers by CCS) + 40 (if Radio Interference Recording is used) + 8. 350 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 1 KW The number of pre-allocated (by CCS) buffers used for A-interface message handling is checked with command C7BPP. Note: 1 KW is equal to 2048 octets. It is advisable to set an alarm to be issued when most of the data file is used (command AFTSS:...). The recording functions will use the following number of 1 kW buffers: 2 per Radio Interference Recording. Value range: 0 - 20. COMMAND: RARRP:RID=ALL; 1 per Active BA-list Recording, up to 10. Value range: 0 - 10. COMMAND: RABRP:RID=ALL; 2 per BTS Configuration Data Collection.



Value range: 0 or 2. 8 per Call Path Tracing. Value: 8. COMMAND: RAPTI; Guiding value = 51 + (no of TRXs) + (no of CFs) + (no of Radio Interference Recordings) * 2 + (no of Active BA-list Recordings) + (no of BTS Configuration Data Collection)*2 + (no of pre-allocated buffers by CCS) +8. COMMAND: RXMSP:MOTY=RXETRX; RXMSP:MOTY=RXOTRX; RXMSP:MOTY=RXOCF; 351 LAD 5 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 2 KW Note: 2 KW is equal to 4096 octets. It is advisable to set an alarm to be issued when most of the data file is used (command AFTSS:...). Least extension and reduction step = 1 individual. The recording functions will use the following numbers of 2 kW buffers: 16 per Cell Traffic Recording. Value range: 0 or 16. COMMAND: RATRP; 2 per Mobile Traffic Recording with file output. Value range: 0 - 8. 2 per Measurement Result Recording. Value range: 0 - 20. COMMAND: RAMRP:RID=ALL; 8 per Call Path Tracing. Value: 8. COMMAND: RAPTI; Guiding value = 32 + (no of Cell Traffic Recordings)*16 + (no of Mobile Traffic Recordings)*2 + (no of Measurement Result Recordings)*2 + 8 352*)LAD 2 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 4 KW Note: 4 KW is equal to 8192 octets. Least extension and reduction step = 1 individual. Guiding value = 42. 353*)LAD 0 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 8 KW



Note: 8 KW is equal to 16384 octets. Least extension and reduction step = 1 individual. Guiding value = 24. 354 LAD 2 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 16 KW Note: 16 KW is equal to 32768 octets. Least extension and reduction step = 1 individual. The recording functions will use the following number of 16 kW 2 per Dropped Call Recording. Value range: 0 - 2 Command: Internal command for DCR. 1 per Parameter Collection. Value range: 0 - 1 Command: RAPCP; 8 per Call Path Tracing. Value: 8 Command: RAPTI ; Guiding value = 71 355 LAD 0 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 KW Note: 32 KW is equal to 65536 octets. Least extension and reduction step = 1 individual. The recording functions will use the following number of 32 kW buffers: 1 per BTS Configuration Data Collection. Value range: 0 - 1 1 per Radio Interference Recording. Value range: 0 - 10 Command: RARRP:RID=ALL; Guiding value = 6 + (no of BTS Configuration Data Collections + no of Radio Inter- ference Recordings.) 356*)DBTAB5 0 - 65032 NO OF TABLE ROWS IN TABLE TRANSLATE Guiding value = 10. 357*)DBTAB5 1 - 500 NO OF WORK ROWS IN TABLE TRANSLATE Guiding value = 10. 358*)DBTAB2 50 - 500 NO OF WORK ROWS IN TABLE PROGRAMS Guiding value = 50.



359*)DBTAB3 100 - 65031 NO OF TABLE ROWS IN TABLE TABLES Guiding value = 100. 360*)DBTAB3 50 - 500 NO OF WORK ROWS IN TABLE TABLES Guiding value = 50. 361*)DBTAB4 500 - 65032 NO OF TABLE ROWS IN TABLE FIELDS DBTAB5 (Number of rows in table DBSEXTTRANSPECS will automatically be set to the integer part of (SAE 361 DBTAB4)/10). Guiding value = 1000. 362*)DBTAB4 50 - 500 NO OF WORK ROWS IN TABLE FIELDS Guiding value = 50. 363*)DBTAB1 53 - 503 NO OF WORK ROWS IN TABLE KEYS (The no. of work rows is only 50 - 500. 53 - 503 includes 3 rows for system internal use.) Guiding value = 53. 364*)DBTAB1 53 - 503 NO OF WORK ROWS IN TABLE KEYFIELDS (The no. of work rows is only 50 - 500. 53 - 503 includes 3 rows for system internal use.) Guiding value = 103 due to TR HF91880. 365*)DBTAB2 100 - 65031 NO OF TABLE ROWS IN TABLE FOREIGNKEYS Guiding value = 100. 366*)DBTAB2 50 - 500 NO OF WORK ROWS IN TABLE FOREIGNKEYS Guiding value = 50. 367*)DBTAB1 53 - 503 NO OF WORK ROWS IN TABLE SYSTEMFIELDS (The no. of work rows is only 50 - 500. 53 - 503 includes 3 rows for system internal use.) Guiding value = 53. 368*)DBTAB7 0 - 65032 NO OF TABLE ROWS IN TABLE SYSFAULTCODES Guiding value = 100. 369*)DBTAB7 0 - 500 NO OF WORK ROWS IN TABLE SYSFAULTCODES Guiding value = 50. 370*)DBTAB1 53 - 503 NO OF WORK ROWS IN TABLE TOWFAULTCODES



(The no. of work rows is only 50 - 500. 53 - 503 includes 3 rows for system internal use.) Guiding value = 53. 371*)DBTAB6 50 - 500 NO OF WORK ROWS IN TABLE SYMBOLS Guiding value = 150. 417*)PXZS 1 - 4096 NO OF WORK ROWS IN TABLE SIGNALDIFF Guiding value = 32 (A3x). 418*)PXZS 0 - 65031 NO OF OPERATION ROWS IN TABLE SIGNALDIFF Guiding value = 32 (A3x). 419*)PXZD 1 - 4096 NO OF WORK ROWS IN TABLE VARIABLEDIFF Least extension or reduction step = 1 individual. Guiding value = 4096 (A3x). 420*)PXZD 0 - 65031 NO OPERATION ROWS IN TABLE VARIABLEDIFF Least extension or reduction step = 1 individual. Guiding value = 4096 (A3x). 421*)ADT 16 - 10240 NO OF IO DEVICES Contains the number of registered IO devices. Least step = 1, max step = 5000. Guiding value = 128. 423*)SAFH 2000 - 65535 NO OF TABLE ROWS IN TABLE SAEMEMBERSHIPS The SAE defines the total number of relations between the SAE participating blocks and the SAEs that they participate in. Step size = 1. Guiding value = 3000 424*)SAFH 512 - 65535 NO OF WORK ROWS IN TABLE LOCALSAES Step size = 1. Guiding value = 512. 462*)ADE 3000 - 65535 NO OF COMMANDS THAT CAN BE STORED IN THE HASH CODED TABLE The minimum number of steps at size alteration is 1. Maximum increment step is 5000. Initial value is 3000. Guiding value = 3000. 466 ALA 100 - 5000 NO OF ALARM LIST ELEMENTS It is advisable to set an alarm



to be issued when most of the data file is used (command AFTSS:...). Guiding value = 2000. 958*)PARTAB1 256 - 4096 NO OF AXE PARAMETER SETS IN DATABASE TABLE AXEPARSETS The total number of AXE parameter sets that can be loaded in the system. In the BSC, the AXE parameter sets are used for optional features. The minimum number of steps at size alteration is 1. Guiding value = 256. 959*)PARTAB1 256 - 4096 NO OF ROWS IN WORK AREA FOR DATABASE TABLE AXEPARSETS In the BSC, the AXE parameter sets are used for optional features. The minimum number of steps at size alteration is 1. Guiding value = 256. 960*)PARA 8192 - 131072 NO OF AXE PARAMETERS IN DATABASE TABLE AXEPARS The total number of AXE parameters that can be loaded in the system. In the BSC, the AXE parameters are used for optional features. The minimum number of steps at size alteration is 1. Guiding value = 8192. 961*)PARA 512 - 65535 NO OF ROWS IN WORK AREA FOR DATABASE TABLE AXEPARS In the BSC, the AXE parameters are used for optional features. The minimum number of steps at size alteration is 1. Guiding value = 2000. 966*)PARTAB2 16384-131072 NO OF RELATIONS BETWEEN AXE PARAMETERS AND BLOCKS IN DATABASE TABLE AXEPARBLOCKRELS The total number of relations between an AXE parameter and a block that can be loaded in the system. In the BSC, the AXE parameters are used for optional features. The minimum number of steps at size alteration is 1. Guiding value = 16384. 967*)PARTAB2 2048 - 65535 NO OF ROWS IN WORK AREA FOR DATABASE TABLE AXEPARBLOCKRELS In the BSC, the AXE parameters



are used for optional features. The minimum number of steps at size alteration is 1. Guiding value = 2048. 1803*)AFBLA 128 - 8192 NO OF RECORDS IN THE PS BUILD LEVEL LOG FILE No limit on the extension or reduction stage. The size alteration decrease will not be permitted if the maximum used individual is greater than the parameter NI specified. It may be necessary to clear the log by command, AFBLS, to allow the size alteration decrease. Guiding value = 128. 1806*)RPADM 0 - 256 NO OF TABLE ROWS IN TABLE RPSRPTYPES This value is normally set at function change of block RPADM and there is therefore no need change this by the operator. Guiding value = 54. 1807*)RPADM 1 - 256 NO OF WORK ROWS IN TABLE RPSRPTYPES This value is normally set at function change of block RPADM and there is therefore no need to change this by the operator. Guiding value = 10. 1808*)RPADM 0 - 2048 NO OF TABLE ROWS IN TABLE RPSHWSWCOMP This value is normally set at function change of block RPADM2 and there is therefore no need to change this by the operator. Guiding value = 256. 1809*)RPADM 1 - 2048 NO OF WORK ROWS IN TABLE RPSHWSWCOMP This value is normally set at function change of block RPADM2 and there is therefore no need to change this by the operator. Guiding value = 10. 1810*)RPADM 0 - 256 NO OF TABLE ROWS IN TABLE RPSRPPROPERTIES This value is normally set at function change of block RPADM and there is therefore no need to change this by the operator. Guiding value = 40.



1811*)RPADM 1 - 256 NO OF WORK ROWS IN TABLE RPSRPPROPERTIES This value is normally set at function change of block RPADM and there is therefore no need to change this by the operator. Guiding value = 10. 1812*)RPADM 0 - 256 NO OF TABLE ROWS IN TABLE RPSTYPESTOPROPS This value is normally set at function change of block RPADM and there is therefore no need to change this by the operator. Guiding value = 54. 1813*)RPADM 1 - 256 NO OF WORK ROWS IN TABLE RPSTYPESTOPROPS This value is normally set at function change of block RPADM and there is therefore no need to change this by the operator. Guiding value = 10. 1814*)RPDI1 0 - 256 NO OF TABLE ROWS IN TABLE RPSBOARDS This value is normally set at function change of block RPDI1 and there is therefore no need to change this by the operator. Guiding value = 256. 1815*)RPDI1 1 - 256 NO OF WORK ROWS IN TABLE RPSBOARDS This value is normally set at function change of block RPDI1 and there is therefore no need to change this by the operator. Guiding value = 256. 1816*)RPDI2 0 - 2048 NO OF TABLE ROWS IN TABLE RPSBOARDLISTS This value is normally set at function change of block RPDI2 and there is therefore no need to change this by the operator. Guiding value = 256. 1817*)RPDI2 1 - 2048 NO OF WORK ROWS IN TABLE RPSBOARDLISTS This value is normally set at function change of block RPDI2 and there is therefore no need to change this by the operator. Guiding value = 16. 1818*)RPDI 0 - 4096 NO OF TABLE ROWS IN TABLE RPSFAULTWEIGHTS



This value is normally set at function change of block RPDI and there is therefore no need to change this by the operator. Guiding value = 2048. 1819*)RPDI 1 - 4096 NO OF WORK ROWS IN TABLE RPSFAULTWEIGHTS This value is normally set at function change of block RPDI and there is therefore no need to change this by the operator. Guiding value = 16. 1820*)RPADM 0 - 256 NO OF TABLE ROWS IN DATABASE TABLE RPSPHYSRPTYPES This value is normally set at function change of block RPADM and there is therefore no need to change this by the operator. Guiding value = 54. 1821*)RPADM 1 - 256 NO OF WORK ROWS IN DATABASE TABLE RPSPHYSRPTYPES This value is normally set at function change of block RPADM and there is therefore no need to change this by the operator. Guiding value = 10. 1822 RPADM 0 - 1024 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS The number of RPs in the exchange with serial RP bus (RPB-S). Guiding value = 0 if RPB-S is not used. = (SAE 304) if RPB-S is used. 1823*)RPADM 1 - 1024 NO OF WORK ROWS IN DATABASE TABLE RPSRPBSPOS Guiding value = 1 if RPB-S is not used. = 100 if RPB-S is used. 1824 LADSD1 0 - 20000 NO OF TABLE ROWS IN DATABASE TABLE DSVARS The table DSVARS is not used (no SRAM is used in the BSC). Guiding value = 0. 1825 LADSD1 1 - 4095 NO OF WORK ROWS IN DATABASE TABLE DSVARS Guiding value = 1. 1826 LAD 200 - 4M NO OF COMMUNICATION BUFFERS WITH



SIZE 32W16 Not in use for the BSC. Guiding value = 200. 1827 LAD 200 - 4M NO OF COMMUNICATION BUFFERS WITH SIZE 64W16 Not in use for the BSC. Guiding value = 200. 1828 LAD 200 - 4M NO OF COMMUNICATION BUFFERS WITH SIZE 128W16 Not in use for the BSC. Guiding value = 200. 1829 LAD 100 - 4M NO OF COMMUNICATION BUFFERS WITH SIZE 256W16 Not in use for the BSC. Guiding value = 100. 1830 LAD 50 - 4M NO OF COMMUNICATION BUFFERS WITH SIZE 512W16 512W16 Communication Buffers are used by SAE 500 M3UADR, SAE 600 SCTP and SAE 605 SCTP. Guiding value = 50 (A3x). = 55 (A55) 1831 LAD 20 - 4M NO OF COMMUNICATION BUFFERS WITH SIZE 1KW16 Not in use for the BSC. Guiding value = 20. 1832 LAD 10 - 4M NO OF COMMUNICATION BUFFERS WITH SIZE 2KW16 Not in use for the BSC. Guiding value = 10. 1833 LAD 6 - 4M NO OF COMMUNICATION BUFFERS WITH SIZE 4KW16 4KW16 Communication Buffers are used by SAE 500 M3UADR, SAE 600 SCTP and SAE 605 SCTP. Guiding value = 6 (A3x) = 250(A55) 1834 LAD 0 - 4M NO OF COMMUNICATION BUFFERS WITH SIZE 8KW16 Not in use for the BSC. Guiding value = 0. 1835 LAD 6 - 4M NO OF COMMUNICATION BUFFERS WITH SIZE 16KW16 Not in use for the BSC. Guiding value = 6. 1836 LAD 0 - 4M NO OF COMMUNICATION BUFFERS WITH SIZE 32KW16 Not in use for the BSC.



Guiding value = 0. 1843 SAFH 512 - 65535 NO OF TABLE ROWS IN DATABASE TABLE SAESUBS The total number of relations between SAE subscribers and the SAEs that they subscribe to that can be loaded into the system. Guiding value = 512. 1844 SAFH 512 - 65535 NO OF WORK ROWS IN DATABASE TABLE SAESUBS Guiding value = 512. 1845 SAFCO 1000-65535 NO OF TABLE ROWS IN DATABASE TABLE LOCALSAES The SAE defines the total number of local SAEs that can be loaded into the system. Guiding value = 2000. 1846 SAFCO 512-65535 NO OF WORK ROWS IN DATABASE TABLE LOCALSAES Guiding value = 512. 1848 RPIDI 100 - 10000 NO OF POSITIONS IN DATABASE TABLE RPSRPIEVENTS This SAE is equal to the number of individuals in SAE 1848 and it depends on the number of RPs, and the number of RPIGs and the traffic intensity. Guiding value = 200. 1849 SAFCO 2000-65535 NO OF TABLE ROWS IN DATABASE TABLE GLOBALSAES The SAE defines the largest global SAE number that can be loaded in the system. Guiding value = 2000. 1850 RPMBH 0 - 16384 NO OF RECORDS FOR STORING HWI INFORMATION FOR BOARDS IN BYB 501 The SAE 1850 shall be set according to the number of RPs in the system (SAE 304). If SAE 304 is increased, SAE 1850 must be increased accordingly. This value is normally set automatically at function change and there is no need to change this by the operator. Guiding value = 16 * (SAE 304). 1851 LADSD 0 - 4194303 NO OF INDIVIDUALS LAMEAS SAE increases and decreases the



number of individuals in the RECORD DSCMPRIOLIST. The size of the SAE sets the maximum number of base addresses selected for measurement in APZ 212 33 or APZ 212 33C. The master block is LAMEAS. Guiding value: A3x = 40 000. Not applicable for A55.

5 Local Size Alteration Events

5.1 APT Size Alteration Events



SAE Block Value Range Description and Hints ---------------------------------------------------------- 500*)C7CLAN 1 - 65535 NO OF RECORDS FOR SEARCHING PATTERN ANALYSIS The block C7CLAN is involved in segmentation and reassembly of messages longer than 255 octets sent by SCCP users. In the BSC, the messages are shorter than 255 octets and therefore C7CLAN does not participate in traffic handling. Guiding value = 1. 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS One individual is needed for each active TCH and SDCCH channel in the BSC/TRC. Additional individuals are required for signalling on the Ater- and Lb-interface. It is advisable to activate C7 Event Recording so congestions get registered (command C7ERI:ENUM=120;). This SAE is only applicable for CCITT CCS7. Guiding value for BSC = 1.4X * (2*(SAE 500 RTLTB/ RTLTB24/RTLTB15/RTLTB2/ RTLTB3)) + SAE 500 RTBLE, see note in the end of this chapter. Guiding value for BSC/TRC = 1.4 * (SAE 500 RALT/RALT24/



RALT15/RALT2/RALT3 (all RALT/RALT24/RALT15/ RALT2/RALT3))+ SAE 500 RTBLE. Guiding value for TRC = (SAE 500 RALT/RALT24/ RALT15/RALT2/RALT3). 500*)C7PCDD 0 - 65535 NO OF C7PCDD INDIVIDUALS This size alteration event is for hardware no longer used in BSC. Guiding value = 0 500 C7SRM 0 - 65280 NO OF TASK INDIVIDUALS. The purpose of the records used in this file is to keep up with the process specific data for the different processes handled by block C7SRM. Guiding value = 256. 500 C7SRMH 0 - 65280 NO OF TASK INDIVIDUALS. The purpose of the records used in this file is to keep up with the process specific data for the different processes handled by block C7SRMH. Guiding value = 256. 500 COHW 0 - 8388607 NO OF ACCESS INDIVIDUALS An access individual represents an access inlet to the switch at AM calls. Guiding value = 0. 500 COMAIN 0 - 8388607 NO OF SWITCH VIEW (SV) INDIVIDUALS The SV is seized by AM user during call set up or when a service is to be given. Guiding value = 0. (AMs do not exist in BSC). 500 COMES 0 - 65534 NO OF MESSAGE INDIVIDUALS Guiding value = 0 (Message service is not used in BSC). 500 COX 0 - 8388607 NO OF LOGICAL MULTIPLE POSITION (LMUP) INDIVIDUALS. The LMUPs simulate real MUPs and provide XSS with the means to manipulate the logical switch views used when calls are set up between an AM and the XSS. Guiding value = 0. (AMs do not exist in BSC).



500 DIPHID 0 - 2047 NO OF HID INDIVIDUALS The block DIPHID stores data for the 2048 kbit/s Digital Path (DIP) termination at digital exchanges. This SAE does not exist in the BSC. Instead, the BSC uses 9 blocks based on the function block DIPHID. See SAE 500 for DIPHM1, DIPHM2, DIPHM3, HIDRALT, HIDRBLT, HIDRTB, HIDRTG, HIDRTL and HIDRTT. 500 DIPHM2 0 - 44352 NO OF HID INDIVIDUALS FOR ET155-1 DIPHM2 is based on block DIPHID. The SAE increases or decreases the number of Historical Data individuals and Registers (REG). At size alteration must be increased in the following order: First Second DIPM2(515) DIPHM2(500) Decrease in reverse order. Guiding value=no of ET155-1 * 63 500 DIPHM3 0 - 59136 NO OF HID INDIVIDUALS FOR ET155-1 DIPHM3 is based on block DIPHID. The SAE increases or decreases the number of Historical Data individuals and Registers (REG). At size alteration must be increased in the following order: First Second DIPM3(515) DIPHM3(500) Decrease in reverse order. Guiding value=no of ET155-1 * 84 500 DIPHM1 0 - 64512 NO OF HID INDIVIDUALS FOR ET155-7 DIPHM1 is based on block DIPHID. The SAE increases or decreases the number of Historical Data individuals and Registers (REG). At size alteration must be increased in the following order: First Second DIPM1(515) DIPHM1(500)



Decrease in reverse order. Guiding value=no of ET155-7 *63. 500 ETDIF 0 - 131072 NO OF DEVICE INDIVIDUALS This SAE does not exist in the BSC. Instead, the BSC uses blocks based on the function block ETDIF. See SAE 500 for ETRALT5, ETRBLT5, ETRTB5, ETRTG5, ETRTL5 and ETRTT5 or ETRALT2, ETRBLT2, ETRTB2, ETRTG2, ETRTL2 and ETRTT2 (in case of ET155-1 for ETSI) or ETRALT3, ETRTT3, ETRTG3, ETRTB3, ETRBLT3 and ETRTL3 (in case of ET155-1 for ANSI). 500 ETRALT2 0 - 1048576 NO OF DEVICE INDIVIDUALS FOR ETRBLT2 ET155-1 ETRTB2 32 channels PCM ETRTG2 At size alteration, ETDIF based ETRTL2 block and the corresponding ETRTT2 Device owning block RALT2, RBLT2, RTGLT2, RTLTB2, RTLBT2 or RTLTT2 shall be size modified in the following order: Alt. 1st 2nd Increase ETDIF Dev. owner Decrease Dev. owner ETDIF Guiding value = Site dependent. One ET155-1 may have a maximum of 2016 (63 * 32) individuals. 500 ETRALT3 0 - 1048560 NO OF DEVICE INDIVIDUALS FOR ETRBLT3 ET155-1 ETRTB3 24 channels PCM ETRTG3 At size alteration, ETDIF based ETRTL3 block and the corresponding ETRTT3 Device owning block RALT3, RBLT3, RTGLT3, RTLTB3, RTLBT3 or RTLTT3 shall be size modified in the following order: Alt. 1st 2nd Increase ETDIF Dev. owner Decrease Dev. owner ETDIF Guiding value = Site dependent. One ET155-1 may have a maximum of 2016 (84 * 24) individuals. 500 ETRALT5 0 - 131072 NO OF DEVICE INDIVIDUALS FOR ETRBLT5 ET155-7 ETRTB5 At size alteration, ETDIF based ETRTG5 block and the corresponding



ETRTL5 Device owning block RALT15, ETRTT5 RBLT15, RTGLT15, RTLTB15, RTLBT15 or RTLTT15 shall be size modified in the following order: Alt. 1st 2nd Increase ETDIF Dev. owner Decrease Dev. owner ETDIF Guiding value = Site dependent. One ET155-7 may have a maximum of 2016 (63 * 32) individuals. 500 EVREP 0 - 65535 NO OF EVENT REPORTS INDIVIDUALS. The SAE increases or decreases the number of event reports which can be stored by block EVREP. The sum of values of parameter EMAX in command ERESC for all events that reports are required on is indicated. Guiding value = 1000 if CCITT CCS7 is used and event recording is activated. = 200 if ANSI CCS7 is used. COMMAND: ERESP:ENUM=ALL; if CCITT CCS7 is used. 500 GCCGH 0 - 4096 NO OF DEVICE INDIVIDUALS This SAE is hardware dependent. Guiding value = 64 * (Number of Circuit Switch Generic Access Handler (CGH) extension module individuals) 500 HIDRALT 0 - 2047 NO OF HID INDIVIDUALS HIDRALT is based on block DIPHID. The SAE increases or decreases the number of Historical Data individuals and Registers (REG). The number of HID individuals must not be greater than the number of DIP individuals. At size alteration SAE 500 RALT, SAE 500 HIDRALT, SAE 515 DIPRALT and SAE 529 ETRALT must be size increased in the following order for 32 channel: First Second Third Fourth DIPRALT ETRALT RALT HIDRALT Decrease in reverse order. Guiding value for BSC = 0.



Guiding value for BSC/TRC and TRC = (SAE 500 RALT)/32. 500 HIDRBLT 0 - 2047 NO OF HID INDIVIDUALS HIDRBLT is based on block DIPHID. The SAE increases or decreases the number of Historical Data individuals and Registers (REG). The number of HID individuals must not be greater than the number of DIP individuals. At size alteration SAE 500 RBLT, SAE 500 HIDRBLT, SAE 515 DIPRBLT and SAE 529 ETRBLT must be size increased in the following order for 32 channel: First Second Third Fourth DIPRBLT ETRBLT RBLT HIDRBLT Decrease in reverse order. Guiding value for BSC or BSC/TRC = (SAE 500 RBLT)/32. Guiding value for TRC = 0. 500 HIDRTB 0 - 2047 NO OF HID INDIVIDUALS HIDRTB is based on block DIPHID. The SAE increases or decreases the number of Historical Data individuals and Registers (REG). The number of HID individuals must not be greater than the number of DIP individuals. At size alteration SAE 500 RTLTB, SAE 500 HIDRTB, SAE 515 DIPRTB and SAE 529 ETRTB must be size increased in the following order for 32 channel: First Second Third Fourth DIPRTB ETRTB RTLTB HIDRTB Decrease in reverse order. Guiding value for BSC = (SAE 500 RTLTB)/32. Guiding value for TRC or BSC/TRC = 0. 500 HIDRTG 0 - 2047 NO OF HID INDIVIDUALS HIDRTG is based on block DIPHID. The SAE increases or decreases the number of Historical Data individual and Registers (REG). The number of HID individuals must not be greater than the number of DIP individuals. At size alteration



SAE 500 RTGLT, SAE 500 HIDRTG, SAE 515 DIPRTG and SAE 529 ETRTG must be size increased in the following order for 32 channel: First Second Third Fourth DIPRTG ETRTG RTGLT HIDRTG Decrease in reverse order. Guiding value for BSC and BSC/TRC = (SAE 500 RTGLT)/32. Guiding value for TRC = 0. 500 HIDRTL 0 - 2047 NO OF HID INDIVIDUALS HIDRTL is based on block DIPHID. The SAE increases or decreases the number of Historical Data individuals and Registers (REG). The number of HID individuals must not be greater than the number of DIP individuals. At size alteration SAE 500 RTLBT, SAE 500 HIDRTL, SAE 515 DIPRTL and SAE 529 ETRTL must be size increased in the following order for 32 channel: First Second Third Fourth DIPRTL ETRTL RTLBT HIDRTL Decrease in reverse order. Guiding value for BSC and BSC/TRC = (SAE 500 RTLBT)/32. Guiding value for TRC = 0. 500 HIDRTT 0 - 2047 NO OF HID INDIVIDUALS HIDRTT is based on block DIPHID. The SAE increases or decreases the number of Historical Data individuals and Registers (REG). The number of HID individuals must not be greater than the number of DIP individuals. At size alteration SAE 500 RTLTT, SAE 500 HIDRTT, SAE 515 DIPRTT and SAE 529 ETRTT must be size increased in the following order for 32 channel: First Second Third Fourth DIPRTT ETRTT RTLTT HIDRTT Decrease in reverse order. Guiding value for BSC = 0. Guiding value for BSC/TRC and TRC= (SAE 500 RTLTT)/32.



500 M3UADR 100 - 65535 NO OF BUFFER INDIVIDUALS FOR STORING MSUs Individuals are used for storing M3UA messages during rerouting and congestion of endpoints. Each individual contains a buffer that is used to store one MSU in the routing file queue. One individual is allocated and linked to a queue for each stored MSU. Guiding value = 100. 500 OMRV 0 - 300 NO OF MTP ROUTING VERIFICATION TEST INDIVIDUALS. Individuals are used to support the MTP Routing Verification Test function. Guiding value = 0. 500 OSRV 0 - 150 NO OF SCCP ROUTING VERIFICATION TEST INDIVIDUALS. Individuals are used to support the SCCP Routing Verification Test function. Guiding value = 0. 500 RABDI 0 - 32768 NO OF SIGNALLING CONNECTION RABDIAN INDIVIDUALS One individual is needed for each active TCH and SDCCH channel in the BSC. RABDI is used for CCITT CCS7, RABDIAN for ANSI CCS7. This SAE is automatically supervised for congestion. Guiding value for BSC = (SAE 913). 500 NO OF DEVICES ON A-INTERFACE RALT 0 - 65504 32 channels PCM RALT24 0 - 65520 24 channels PCM Least extension or reduction stage = 24 RALT24 devices or 32 RALT devices, depending on number of devices per CM. At size alteration SAE 500 RALT/ RALT24, SAE 500 HIDRALT, SAE 515 DIPRALT/DIPRAT4 and SAE 529 ETRALT/ETRALT4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRALT ETRALT RALT HIDRALT Decrease in reverse order.



24 channel increase: First Second Third DIPRAT4 ETRALT4 RALT24 Decrease in reverse order. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC. COMMAND: EXEMP:RP=ALL,EM=ALL; 500 RALT2 0 - 65504 NO OF DEVICES ON A-INTERFACE FOR ET155-1 32 channels PCM This is a local size alteration event to be used when increasing or decreasing the number of RALT2 devices. Least extension or reduction stage = 32 RALT2 devices. The number of RALT2 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RALT2, SAE 500 ETRALT2, SAE 529 ETM2, SAE 515 DIPM2, SAE 515 SDIPM2, SAE 515 SDIPQM2 must be size modified in the following order: FIRST SECOND SDIPQM2(515) SDIPM2(515) THIRD FOURTH DIPM2(515) ETM2(529) FIFTH SIXTH ETRALT2(500) RALT2(500) Decrease in reverse order. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC. 500 RALT3 0 - 65520 NO OF DEVICES ON A-INTERFACE FOR ET155-1 24 channels PCM This is a local size alteration event to be used when increasing or decreasing the number of RALT3 devices. Least extension or reduction stage = 24 RALT3 devices. The number of RALT3 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RALT3, SAE 500 ETRALT3,



SAE 529 ETM3, SAE 515 DIPM3, SAE 515 SDIPM3, SAE 515 SDIPFM3, SAE 515 SDIPAM3, SAE 515 SDIPQM3 must be size modified in the following order: FIRST SECOND SDIPQM3(515) SDIPAM3(515) THIRD FOURTH SDIPFM3(515) SDIPM3(515) FIFTH SIXTH DIPM3(515) ETM3(529) SEVENTH EIGHTH ETRALT3(500) RALT3(500) Decrease in reverse order. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC. 500 RALT15 0 - 65504 NO OF DEVICES ON A-INTERFACE FOR ET155-7 This is a local size alteration event to be used when increasing or decreasing the number of RALT15 devices. Least extension or reduction stage = 32 RALT15 devices. The number of RALT15 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RALT15, SAE 500 ETRALT5, SAE 529 ETM1, SAE 515 DIPM1, SAE 515 SDIPM1, SAE 515 SDIPQ must be size modified in the following order: FIRST SECOND SDIPQ(515) SDIPM1(515) THIRD FOURTH DIPM1(515) ETM1(529) FIFTH SIXTH ETRALT5(500) RALT15(500) Decrease in reverse order. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC. 500 NO OF DEVICES ON ABIS-INTERFACE RBLT 0 - 65504 32 channels PCM RBLT24 0 - 65520 24 channels PCM



Least extension or reduction stage = 24 RBLT24 devices or 32 RBLT devices, depending on number of devices per CM. At size alteration SAE 500 RBLT/ RBLT24, SAE 500 HIDRBLT, SAE 515 DIPRBLT/DIPRBT4, SAE 529 ETRBLT/ETRBLT4 and must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRBLT ETRBLT RBLT HIDRBLT Decrease in reverse order. 24 channel increase: First Second Third DIPRBT4 ETRBLT4 RBLT24 Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC. COMMAND: EXEMP:RP=ALL,EM=ALL; 500 RBLT2 0 - 65504 NO OF DEVICES ON ABIS-INTERFACE FOR ET155-1 32 channels PCM This is a local size alteration event to be used when increasing or decreasing the number of RBLT2 devices. Least extension or reduction stage = 32 RBLT2 devices. The number of RBLT2 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RBLT2, SAE 500 ETRBLT2, SAE 529 ETM2, SAE 515 DIPM2, SAE 515 SDIPM2, SAE 515 SDIPQM2 must be size modified in the following order: FIRST SECOND SDIPQM2(515) SDIPM2(515) THIRD FOURTH DIPM2(515) ETM2(529) FIFTH SIXTH ETRBLT2(500) RBLT2(500) Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC.



= 0 for TRC. 500 RBLT3 0 - 65520 NO OF DEVICES ON ABIS-INTERFACE FOR ET155-1 24 channels PCM This is a local size alteration event to be used when increasing or decreasing the number of RBLT3 devices. Least extension or reduction stage = 24 RBLT3 devices. The number of RBLT3 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RBLT3, SAE 500 ETRBLT3, SAE 529 ETM3, SAE 515 DIPM3, SAE 515 SDIPM3, SAE 515 SDIPFM3, SAE 515 SDIPAM3, SAE 515 SDIPQM3 must be size modified in the following order: FIRST SECOND SDIPQM3(515) SDIPAM3(515) THIRD FOURTH SDIPFM3(515) SDIPM3(515) FIFTH SIXTH DIPM3(515) ETM3(529) SEVENTH EIGHTH ETRBLT3(500) RBLT3(500) Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC. 500 RBLT15 0 - 65504 NO OF DEVICES ON ABIS-INTERFACE FOR ET155-7 This is a local size alteration event to be used when increasing or decreasing the number of RBLT15 devices. Least extension or reduction stage = 32 RBLT15 devices. The number of RBLTT15 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RBLT15, SAE 500 ETRBLT5, SAE 529 ETM1, SAE 515 DIPM1, SAE 515 SDIPM1, SAE 515 SDIPQ must be size modified in the following order: FIRST SECOND SDIPQ(515) SDIPM1(515)



THIRD FOURTH DIPM1(515) ETM1(529) FIFTH SIXTH ETRBLT5(500) RBLT15(500) Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC. 500 RMSCS 0 - 32768 NO OF MS INDIVIDUALS The SAE controls the size of the task file (MS individuals). One individual is needed for each MS signalling connection setup. This SAE is automatically supervised for congestion. Least extension or reduction step = 1. Guiding value = 4000 for BSC and BSC/TRC. = 0 for TRC. 500 RODCR 0 - 32768 NO OF DCR RECORDING INDIVIDUALS This SAE is designated for Ericsson personnel only to be used for the internal dropped call recording function. The SAE is related to the MS individuals controlled by SAE 913. Guiding value = 0. Increased on Ericsson maintenance demand to desired number of recorded individuals, less than or equal to the size of SAE 913. 500*)RODESI 0 - 65535 NO OF SIMULTANEOUS STDEP RODESI offers a multi-user facility for printing of device states. The maximum number of users is set by this size alteration event. Guiding value = 16. 500 RTATHB 0 - 32768 NO OF INDIVIDUALS IN THE BSC CALL INDIVIDUAL FILE Each individual contains the call related data such as MS individual, channel rate etc. Least extension and reduction step = 1 individual. This SAE is automatically supervised for congestion. Guiding value for the BSC =



X * (SAE500 RTLTB/RTLTB24/ RTLTB15/RTLTB2/RTLTB3), see note in the end of this chapter. Command: EXEMP:RP=ALL, EM=ALL; Guiding value = 0 for BSC/TRC and TRC. 500 RTATHT 0 - 32768 NO OF INDIVIDUALS IN THE TRC CALL INDIVIDUAL FILE Each individual contains the call related data such as MS individual, channel rate etc. Least extension and reduction step = 1 individual. This SAE is automatically supervised for congestion. Guiding value for BSC = 0. Guiding value for BSC/TRC and TRC = X * (SAE 500 RTLTT/RTLTT24/ RTLTT15/RTLTT2/RTLTT3), see note in the end of this chapter. Command: EXEMP:RP=ALL, EM=ALL; 500 RTBLE 0 - 32768 NO OF SIGNALLING CONNECTION RTBLEAN INDIVIDUALS RTBLE is used for CCITT CCS7 signalling, RTBLEAN for ANSI CCS7 signalling towards SMLC. This SAE is automatically supervised for congestion. Least extension and reduction step = 1 individual. Guiding value for BSC and BSC/TRC = 2000 if LB-interface is used, else guiding value for BSC and BSC/TRC = 0. Guiding value for TRC = 0. 500 RTBTAP 0 - 32768 NO OF INDIVIDUALS IN SC RTBTAPA INDIVIDUAL FILE No of individuals in the signalling connection individual file. RTBTAP handles BTAP messages for CCITT signalling. RTBTAPA handles BTAP messages for ANSI signalling. Least extension and reduction step = 1 individual. The file participates in the Software File Congestion Supervision function.



Guiding value for BSC = X * (SAE 500 RTLTB/RTLTB24/ RTLTB15/RTLTB2/RTLTB3), see note in the end of this chapter. Guiding value for BSC/TRC and TRC = X * (SAE 500 RTLTT/RTLTT24/ RTLTT15/RTLTT2/RTLTT3), see note in the end of this chapter. Command: EXEMP:RP=ALL, EM=ALL; 500 NO OF DEVICES ON GB INTERFACE RTGLT 0 - 65504 32 channel PCM RTGLT24 0 - 65520 24 channel PCM Least extension or reduction stage = 24 RTGLT24 devices or 32 RTGLT devices, depending on number of devices per CM. The number of RTGLT device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTGLT/RTGLT24, SAE 500 HIDRTG, SAE 515 DIPRTG/DIPRTG4 and SAE 529 ETRTG/ETRTG4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRTG ETRTG RTGLT HIDRTG Decrease in reverse order. 24 channel increase: First Second Third DIPRTG4 ETRTG4 RTGLT24 Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC. COMMAND: EXEMP:RP=ALL,EM=ALL; 500 RTGLT2 0 - 65504 NO OF DEVICES ON GB INTERFACE FOR ET155-1 32 channel PCM This is a local size alteration event to be used when increasing or decreasing the number of RTGLT2 devices. Least extension or reduction



stage = 32 RTGLT2 devices. The number of RTGLT2 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTGLT2, SAE 500 ETRTG2, SAE 529 ETM2, SAE 515 DIPM2, SAE 515 SDIPM2, SAE 515 SDIPQM2 must be size modified in the following order: FIRST SECOND SDIPQM2(515) SDIPM2(515) THIRD FOURTH DIPM2(515) ETM2(529) FIFTH SIXTH ETRTG2(500) RTGLT2(500) Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC. 500 RTGLT3 0 - 65520 NO OF DEVICES ON GB INTERFACE FOR ET155-1 24 channel PCM This is a local size alteration event to be used when increasing or decreasing the number of RTGLT3 devices. Least extension or reduction stage = 24 RTGLT3 devices. The number of RTGLT3 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTGLT3, SAE 500 ETRTG3, SAE 529 ETM3, SAE 515 DIPM3, SAE 515 SDIPM3, SAE 515 SDIPFM3, SAE 515 SDIPAM3, SAE 515 SDIPQM3 must be size modified in the following order: FIRST SECOND SDIPQM3(515) SDIPAM3(515) THIRD FOURTH SDIPFM3(515) SDIPM3(515) FIFTH SIXTH DIPM3(515) ETM3(529) SEVENTH EIGHTH ETRTG3(500) RTGLT3(500) Decrease in reverse order. Guiding value = site dependent



for BSC and BSC/TRC. = 0 for TRC. 500 RTGLT15 0 - 65504 NO OF DEVICES ON GB INTERFACE FOR ET155-7 This is a local size alteration event to be used when increasing or decreasing the number of RTGLT15 devices. Least extension or reduction stage = 32 RTGLT15 devices. The number of RTGLT15 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTGLT15, SAE 500 ETRTG5, SAE 529 ETM1, SAE 515 DIPM1, SAE 515 SDIPM1, SAE 515 SDIPQ must be size modified in the following order: FIRST SECOND SDIPQ(515) SDIPM1(515) THIRD FOURTH DIPM1(515) ETM1(529) FIFTH SIXTH ETRTG5(500) RTGLT15(500) Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC. 500 RTGPHDV 1-128 NO OF GPH DEVICES This SAE corresponds to the number of GPH Regional Processors Guiding value = site dependent for BSC and BSC/TRC. = 1 for TRC. 500 NO OF DEVICES ON LB-INTERFACE IN BSC RTLBT 0 - 65504 32 channel PCM RTLBT24 0 - 65520 24 channel PCM Least extension or reduction stage = 24 RTLBT24 devices or 32 RTLBT devices, depending on number of devices per CM. The number of RTLBT device individuals must be equal to the number of ET device individuals.



At size alteration SAE 500 RTLBT/RTLBT24, SAE 500 HIDRTL, SAE 515 DIPRTL/DIPRTL4 and SAE 529 ETRTL/ETRTL4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRTL ETRTL RTLBT HIDRTL Decrease in reverse order. 24 channel increase: First Second Third DIPRTL4 ETRTL4 RTLBT24 Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC. COMMAND: EXEMP:RP=ALL,EM=ALL; 500 RTLBT15 0 - 65504 NO OF DEVICES ON LB-INTERFACE IN BSC FOR ET155-7 This is a local size alteration event to be used when increasing or decreasing the number of RTLBT15 devices. Least extension or reduction stage = 32 RTLBT15 devices depending on number of devices per CM. The number of RTLBT device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLBT15, SAE 500 ETRTL5, SAE 529 ETM1, SAE 515 DIPM1, SAE 515 SDIPM1, SAE 515 SDIPQ must be size modified in the following order: FIRST SECOND SDIPQ(515) SDIPM1(515) THIRD FOURTH DIPM1(515) ETM1(529) FIFTH SIXTH ETRTL5(500) RTLBT15(500) Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC.



500 RTLBT2 0 - 65504 NO OF DEVICES ON LB-INTERFACE IN BSC FOR ET155-1 32 channel PCM This is a local size alteration event to be used when increasing or decreasing the number of RTLBT3 devices. Least extension or reduction stage = 32 RTLBT2 devices depending on number of devices per CM. The number of RTLBT2 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLBT2, SAE 500 ETRTL2, SAE 529 ETM2, SAE 515 DIPM2, SAE 515 SDIPM2, SAE 515 SDIPQM2 must be size modified in the following order: FIRST SECOND SDIPQM2(515) SDIPM2(515) THIRD FOURTH DIPM2(515) ETM2(529) FIFTH SIXTH ETRTL2(500) RTLBT2(500) Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC. 500 RTLBT3 0 - 65520 NO OF DEVICES ON LB-INTERFACE IN BSC FOR ET155-1 24 channel PCM This is a local size alteration event to be used when increasing or decreasing the number of RTLBT3 devices. Least extension or reduction stage = 24 RTLBT3 devices depending on number of devices per CM. The number of RTLBT3 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLBT3, SAE 500 ETRTL3, SAE 529 ETM3, SAE 515 DIPM3, SAE 515 SDIPM3, SAE 515 SDIPFM3, SAE 515 SDIPAM3, SAE 515 SDIPQM3 must be size modified in the following order: FIRST SECOND SDIPQM3(515) SDIPAM3(515)



THIRD FOURTH SDIPFM3(515) SDIPM3(515) FIFTH SIXTH DIPM3(515) ETM3(529) SEVENTH EIGHTH ETRTL3(500) RTLBT3(500) Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC. = 0 for TRC. 500 NO OF DEVICES ON ATER-INTERFACE IN BSC RTLTB 0 - 65504 32 channel PCM RTLTB24 0 - 65520 24 channel PCM Least extension or reduction stage = 24 RTLTB24 devices or 32 RTLTB devices, depending on number of devices per CM. The number of RTLTB device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLTB/RTLTB24, SAE 500 HIDRTB, SAE 515 DIPRTB/DIPRTB4 and SAE 529 ETRTB/ETRTB4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRTB ETRTB RTLTB HIDRTB Decrease in reverse order. 24 channel increase: First Second Third DIPRTB4 ETRTB4 RTLTB24 Decrease in reverse order. Guiding value = site dependent for BSC. = 0 for TRC and BSC/TRC. COMMAND: EXEMP:RP=ALL,EM=ALL; 500 RTLTB2 0 - 65504 NO OF DEVICES ON ATER-INTERFACE IN BSC FOR ET155-1 32 channel PCM This is a local size alteration event to be used when increasing



or decreasing the number of RTLTB2 devices. Least extension or reduction stage = 32 RTLTB2 devices. The number of RTLTB2 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLTB2, SAE 500 ETRTB2, SAE 529 ETM2, SAE 515 DIPM2, SAE 515 SDIPM2, SAE 515 SDIPQM2 must be size modified in the following order: FIRST SECOND SDIPQM2(515) SDIPM2(515) THIRD FOURTH DIPM2(515) ETM2(529) FIFTH SIXTH ETRTB2(500) RTLTB2(500) Decrease in reverse order. Guiding value = site dependent for BSC. = 0 for TRC and BSC/TRC. 500 RTLTB3 0 - 65520 NO OF DEVICES ON ATER-INTERFACE IN BSC FOR ET155-1 24 channel PCM This is a local size alteration event to be used when increasing or decreasing the number of RTLTB3 devices. Least extension or reduction stage = 24 RTLTB3 devices. The number of RTLTB3 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLTB3, SAE 500 ETRTB3, SAE 529 ETM3, SAE 515 DIPM3, SAE 515 SDIPM3, SAE 515 SDIPFM3, SAE 515 SDIPAM3, SAE 515 SDIPQM3 must be size modified in the following order: FIRST SECOND SDIPQM3(515) SDIPAM3(515) THIRD FOURTH SDIPFM3(515) SDIPM3(515) FIFTH SIXTH DIPM3(515) ETM3(529) SEVENTH EIGHTH ETRTB3(500) RTLTB3(500)



Decrease in reverse order. Guiding value = site dependent for BSC. = 0 for TRC and BSC/TRC. 500 RTLTB15 0 - 65504 NO OF DEVICES ON ATER-INTERFACE IN BSC FOR ET155-7 This is a local size alteration event to be used when increasing or decreasing the number of RTLTB15 devices. Least extension or reduction stage = 32 RTLTB15 devices. The number of RTLTB15 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLTB15, SAE 500 ETRTB5, SAE 529 ETM1, SAE 515 DIPM1, SAE 515 SDIPM1, SAE 515 SDIPQ must be size modified in the following order: FIRST SECOND SDIPQ(515) SDIPM1(515) THIRD FOURTH DIPM1(515) ETM1(529) FIFTH SIXTH ETRTB5(500) RTLTB15(500) Decrease in reverse order. Guiding value = site dependent for BSC. = 0 for TRC and BSC/TRC. 500 NO OF DEVICES ON ATER-INTERFACE IN TRC RTLTT 0 - 65504 32 channels PCM RTLTT24 0 - 65520 24 channels PCM Least extension or reduction stage = 24 RTLTT24 devices or 32 RTLTT devices, depending on number of devices per CM. The number of RTLTT device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLTT/RTLTT24, SAE 500 HIDRTT, SAE 515 DIPRTT/DIPRTT4 and SAE 529 ETRTT/ETRTT4 must be size modified in the



following order: 32 channel increase: First Second Third Fourth DIPRTT ETRTT RTLTT HIDRTT Decrease in reverse order. 24 channel increase: First Second Third DIPRTT4 ETRTT4 RTLTT24 Decrease in reverse order. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC. COMMAND: EXEMP:RP=ALL,EM=ALL; 500 RTLTT2 0 - 65504 NO OF DEVICES ON ATER-INTERFACE IN TRC FOR ET155-1 This is a local size alteration event to be used when increasing or decreasing the number of RTLTT2 devices. Least extension or reduction stage = 32 RTLTT2 devices. The number of RTLTT2 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLTT2, SAE 500 ETRTT2, SAE 529 ETM2, SAE 515 DIPM2, SAE 515 SDIPM2, SAE 515 SDIPQM2 must be size modified in the following order: FIRST SECOND SDIPQM2(515) SDIPM2(515) THIRD FOURTH DIPM2(515) ETM2(529) FIFTH SIXTH ETRTT2(500) RTLTT2(500) Decrease in reverse order. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC. 500 RTLTT3 0 - 65520 NO OF DEVICES ON ATER-INTERFACE IN TRC FOR ET155-1 This is a local size alteration event to be used when increasing or decreasing the number of RTLTT3 devices. Least extension or reduction stage = 24 RTLTT3 devices.



The number of RTLTT3 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLTT3, SAE 500 ETRTT3, SAE 529 ETM3, SAE 515 DIPM3, SAE 515 SDIPM3, SAE 515 SDIPFM3, SAE 515 SDIPAM3, SAE 515 SDIPQM3 must be size modified in the following order: FIRST SECOND SDIPQM3(515) SDIPAM3(515) THIRD FOURTH SDIPFM3(515) SDIPM3(515) FIFTH SIXTH DIPM3(515) ETM3(529) SEVENTH EIGHTH ETRTT3(500) RTLTT3(500) Decrease in reverse order. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC. 500 RTLTT15 0 - 65504 NO OF DEVICES ON ATER-INTERFACE IN TRC FOR ET155-7 This is a local size alteration event to be used when increasing or decreasing the number of RTLTT15 devices. Least extension or reduction stage = 32 RTLTT15 devices. The number of RTLTT15 device individuals must be equal to the number of ET device individuals. At size alteration SAE 500 RTLTT15, SAE 500 ETRTT5, SAE 529 ETM1, SAE 515 DIPM1, SAE 515 SDIPM1, SAE 515 SDIPQ must be size modified in the following order: FIRST SECOND SDIPQ(515) SDIPM1(515) THIRD FOURTH DIPM1(515) ETM1(529) FIFTH SIXTH ETRTT5(500) RTLTT15(500) Decrease in reverse order. Guiding value = 0 for BSC. = site dependent for BSC/TRC



and TRC. 500 RTPDI 0 - 32768 NO OF TRANSCODER RESOURCES INDIVIDUALS Number of resource individuals which can be connected in the combined BSC/TRC or the standalone TRC. Guiding value = 0 for BSC = Max traffic intensity in Erlang for BSC/TRC and TRC. 500 RTPGD 0 - 49152 NO OF PGW DEVICES The SAE increases or decreases number of RTPGD devices. It can be increased or decreased only by a multiple of 768. SAE 500 RTPGD, SAE 500 RTPLD and SAE 529 RTPGS are dependent on each other (SAE 500 RTPGD = 768 * SAE 529 RTPGS) and must be increased in the following order: First Second Third 529 RTPGS 500 RTPLD 500 RTPGD Decrease in reverse order. Guiding value=768*SAE 529 RTPGS = 0 for TRC 500 RTPLD 0 - 49152 NO OF PGW DEVICES The SAE increases or decreases number of RTPLD devices. It can be increased or decreased only by a multiple of 768. SAE 500 RTPLD, SAE 500 RTPGD and SAE 529 RTPGS are dependent on each other (SAE 500 RTPLD = 768 * SAE 529 RTPGS) and must be increased in the following order: First Second Third 529 RTPGS 500 RTPLD 500 RTPGD Decrease in reverse order. Guiding value=768*SAE 529 RTPGS = 0 for TRC 500 RTTCCT 0 - 32768 NO OF TRC CALL INDIVIDUALS This SAE increases or decreases the TRC call individual file. A decrease is only permitted when the new file size is not smaller than the TRC call size (SAE 500) in block RTATHT. Guiding value for BSC = 0. Guiding value for BSC/TRC and TRC = Site dependent.



500 RTTPH 0 - 32768 NO OF TRANSCODER RECOURCES The total number of transcoder resources that could be contained in the Transcoder pools. Guiding value for BSC = 0. Guiding value for BSC/TRC and TRC = site dependent (for further information, see Ref. 1. (24 * ((SAE 995) + (SAE 996) + (SAE 1047)) + 192 * (SAE 1109) + 384 * (SAE 1157) - the number of semipermanent connected transcoders.) Command: NTSTP:SNT=ALL; 500 RTTPR 0 - 32768 NO OF TRANSMISSION INDIVIDUALS Least extension and reduction step = 1 individual. The file participates in the 'Software File Congestion Supervision' function. The block coordinates the connection of A-interface Line Terminal (RALT), the GS path and the transcoder resources (RTTPH). The function is used for both semipermanent and pooled transcoders. Guiding value = 0 for BSC. = site dependent for BSC/TRC and TRC. (SAE 500 RALT/ RALT24/ RALT15/RALT2/ RALT3) Command: EXEMP:RP=ALL, EM=ALL; 500 RXEADB 0 - 32768 NO OF MANAGED OBJECTS IN THE BTS RXEADE LOGICAL MODEL G01 RXEFH At size alteration all blocks RXEIFH dependent on the number of MOs RXELE in the BTS logical model, must RXELH be size modified. The number of RXEPL MOs must always be sufficient RXE3EP for at least the number of MOs RXE3OM defined in the BTS logical RXEABH model. RXEBL 2*TG + 11*TRX is indicated. RXESR Guiding value = Cell planning dependent for BSC and BSC/TRC. (0 if no RBS200 is used). = 0 for TRC.



COMMAND: RXMSP:MOTY=RXETG; RXMSP:MOTY=RXETRX; RXMSP:MOTY=RXERX; RXMSP:MOTY=RXETF; RXMSP:MOTY=RXETX; RXMSP:MOTY=RXETS; 500 RXOFH 0 - 49653 NO OF MANAGED OBJECTS IN THE BTS RXOIFH LOGICAL MODEL G12 RXOLE At size alteration all blocks RXOLH dependent on the number of MOs RXOPL in the BTS logical model, must RXO3EP be size modified. The number of RXO3OM MOs must always be sufficient RXOADE for at least the number of MOs RXOABH defined in the BTS logical RXOADB model. RXOBL 9*TG + 11*TRX is indicated. RXOSR Guiding value = Cell planning dependent for BSC and BSC/TRC. (0 if no RBS2000 is used). = 0 for TRC. COMMAND: RXMSP:MOTY=RXOTG; RXMSP:MOTY=RXOTRX; RXMSP:MOTY=RXOTF; RXMSP:MOTY=RXORX; RXMSP:MOTY=RXOTX; RXMSP:MOTY=RXOTS; RXMSP:MOTY=RXODP; RXMSP:MOTY=RXOCF; RXMSP:MOTY=RXOIS; RXMSP:MOTY=RXOCON; 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS One individual is needed for each active TCH and SDCCH channel in the BSC/TRC. Additional individuals are required for signalling on the Ater- and Lb-interface. This SAE is only applicable for CCS7 ANSI. Guiding value for BSC = 1.4X * (2 * (SAE 500 RTLTB/ RTLTB24/RTLTB15/RTLTB2/ RTLTB3)) + SAE 500 RTBLEAN, see note in the end of this chapter. Guiding value for BSC/TRC = 1.4 * (SAE 500 RALT/RALT24/ RALT15/RALT2/RALT3 (all RALT/RALT24/RALT15)) + SAE 500 RTBLEAN Guiding value for TRC = 1.4 * (SAE 500 RALT/RALT24/



RALT15/RALT2/RALT3). 500 SDIPHM2 0 - 704 NO OF HID INDIVIDUALS FOR ET155-1 The block SDIPHM2 stores historical quality supervision data for 155 Mbit/s Synchronous Digital Path (SDIP) termination at digital exchanges. The SAE increases or decreases the number of Historical Data (HID) individuals, MS, VC4 (for HP layer) and VC12 (for LP layer) registers. The HID file is master file. One HID record is used per SDIP and 2*(n+1) MSREG, n+1 VC4REG and 63*(n+1) VC12 REG records are used per HID, where n is between 1 - 96, set in parameter list for SDIPHM2. Order of increase: First Second SDIPQM2 (515) SDIPHM2 (500) Decrease in reverse order. COMMAND: TPQCP Guiding value = no of ET155-1. 500 SDIPHID 0 - 1024 NO OF HID INDIVIDUALS FOR ET155-7 The block SDIPHID stores historical quality supervision data for 155 Mbit/s Synchronous Digital Path (SDIP) termination at digital exchanges. The SAE increases or decreases the number of Historical Data (HID) individuals, MS, VC4 (for HP layer) and VC12 (for LP layer) registers. The HID file is master file. One HID record is used per SDIP and 2*(n+1) MSREG, n+1 VC4REG and 63*(n+1) VC12 REG records are used per HID, where n is between 1 - 96, set in parameter list for SDIPHID. Order of increase: First Second SDIPQ (515) SDIPHID (500) Decrease in reverse order. COMMAND: TPQCP Guiding value = no of ET155-7. 501 C7CL 0 - 16384 NO OF CONNECTIONLESS SEGMENTATION AND REASSEMBLY MESSAGE INDIVIDUALS The SAE increases or decreases



the message file size. One page contains 256 individuals. Least extension and reduction stage = 256. Guiding value = 256 if CCITT CCS7 is used. = 0 if ANSI CCS7 is used. 501 C7CO 0 - 4095 NO OF ELEMENTS IN THE CONNECTION ORIENTED MESSAGE QUEUE The SAE increases or decreases the number of connection- oriented message individuals. Guiding value = 600 if CCITT CCS7 is used. = 0 if ANSI CCS7 is used. 502 RQUCD 0 - 16384 NO OF UTRAN CELL RELATIONS The SAE handles the UTRAN FDD cell relation file. Guiding value = site dependent for BSC, BSC/TRC = 0 for TRC Command to check current number of cell relations: RLNRP:CELL=ALL,UTRAN; 502 RXE3IM 0 - 2048 NO OF TRXC INDIVIDUALS RXEBVH The SAE corresponds to number of RXEFMM Transveiver Controller Managed RXEFT Objects in the BSC related to RXELDF BTS model G01. RXELH RXELS RXE3IM and RXELH must be in- RXERPM creased in the following order: RXESR First Second RXETGH RXE3IM RXELH RXEVU Decrease in reverse order. Guiding value: = no of defined TRXs in the BSC or BSC/TRC = 0 for TRC Command to check current number of TRXs: RXMSP:MOTY=RXETRX; 502 RTAPH 0 - 4095 NO OF TRXC INDIVIDUALS RTVPH The SAE corresponds to number of RXO3IM Transceiver Controller Managed RXOBVH Objects in the BSC related to RXOFMM BTS model G12. RXOFT RXOISH RXO3IM and RXOLH must be in- RXOLDF creased in the following order: RXOLH First Second



RXOLS RXO3IM RXOLH RXORPM Decrease in reverse order. RXOSR Guiding value: RXOVU = no of defined TRXs in the BSC or BSC/TRC = 0 for TRC Command to check current number of TRXs: RXMSP:MOTY=RXOTRX; 504 M3UADR 0 - 8191 NO OF M3UA ROUTE DATA INDIVIDUALS One SAE individual is seized when a M3UA route is defined using command M3RSI and is released when the SP is deleted using command M3RSE. Guiding value = 2. 515 DIPM2 0 - 44352 NO OF DIGITAL PATHS FOR ET155-1 DIPM2 is based on block DIPST. The SAE increases or decreases the number of DIP individuals. One record is used per DIP. Order of increase: First Second Third SDIPM2(515) DIPM2(515) ETM2(529) Decrease in reverse order. Guiding value = no of ET155-1 * 63. 515 DIPM3 0 - 59136 NO OF DIGITAL PATHS FOR ET155-1 DIPM3 is based on block DIPST. The SAE increases or decreases the number of DIP individuals. One record is used per DIP. At size alteration the corresponding SDIPQM3, SDIPAM3, SDIPFM3, SDIPM3, DIPM3 and ETM3 blocks must be size modified in the following increasing order: First Second SDIPQM3(515) SDIPAM3(515) THIRD FOURTH SDIPFM3(515) SDIPM3(515) FIFTH SIXTH DIPM3(515) ETM3(529) Decrease in reverse order. Guiding value = no of ET155-1 * 84. 515 DIPM1 0 - 64512 NO OF DIGITAL PATHS FOR ET155-7 DIPM1 is based on block DIPST. The SAE increases or decreases the number of DIP individuals. One record is used per DIP. Order of increase: First Second Third



SDIPM1(515) DIPM1(515) ETM1(529) Decrease in reverse order. Guiding value = no of ET155-7 * 63. 515 NO OF DIGITAL PATHS FOR A-INTERFACE DIPRALT 0 - 2048 32 channels SNT. DIPRAT4 0 - 2048 24 channels SNT. These blocks are based on block DIPST. At size alteration SAE 500 RALT/RALT24, SAE 500 HIDRALT, SAE 515 DIPRALT/DIPRAT4 and SAE 529 ETRALT/ETRALT4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRALT ETRALT RALT HIDRALT Decrease in reverse order. 24 channel increase: First Second Third DIPRAT4 ETRALT4 RALT24 Decrease in reverse order. Guiding value for BSC = 0. Guiding value for BSC/TRC and TRC = (SAE 500 RALT24)/24 or (SAE 500 RALT)/32. COMMAND: DTDIP:DIP=ALL; 515 NO OF DIGITAL PATHS FOR ABIS INTERFACE DIPRBLT 0 - 2048 32 channels SNT. DIPRBT4 0 - 2048 24 channels SNT. These blocks are based on block DIPST. At size alteration SAE 500 RBLT/RBLT24, SAE 500 HIDRBLT, SAE 515 DIPRBLT/DIPRBT4, SAE 529 ETRBLT/ETRBLT4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRBLT ETRBLT RBLT HIDRBLT Decrease in reverse order. 24 channel increase: First Second Third DIPRBT4 ETRBLT4 RBLT24



Decrease in reverse order. Guiding value for BSC or BSC/TRC = (SAE 500 RBLT24)/24 or (SAE 500 RBLT)/32. Guiding value for TRC = 0. COMMAND: DTDIP:DIP=ALL; 515 NO OF DIGITAL PATHS FOR ATER INTERFACE DIPRTB 0 - 2048 32 channels SNT. DIPRTB4 0 - 2048 24 channels SNT. These blocks are based on block DIPST. At size alteration SAE 500 RTLTB/RTLTB24, SAE 500 HIDRTB, SAE 515 DIPRTB/DIPRTB4 and SAE 529 ETRTB/ETRTB4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRTB ETRTB RTLTB HIDRTB Decrease in reverse order. 24 channel increase: First Second Third DIPRTB4 ETRTB4 RTLTB24 Decrease in reverse order. Guiding value for BSC = (SAE 500 RTLTB24)/24 or (SAE 500 RTLTB)/32. Guiding value for TRC and BSC/TRC = 0. COMMAND: DTDIP:DIP=ALL; 515 NO OF DIGITAL PATHS FOR GB INTERFACE DIPRTG 0 - 2048 32 channels SNT. DIPRTG4 0 - 2048 24 channels SNT. These blocks are based on block DIPST. At size alteration SAE 500 RTGLT/RTGLT24, SAE 500 HIDRTG, SAE 515 DIPRTG/DIPRTG4, SAE 529 ETRTG/ETRTG4 and must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRTG ETRTG RTGLT HIDRTG



Decrease in reverse order. 24 channel increase: First Second Third DIPRTG4 ETRTG4 RTGLT24 Decrease in reverse order. Guiding value for BSC or BSC/TRC = (SAE500 RTGLT24)/24 or (SAE500 RTGLT)/32. Guiding value for TRC = 0. COMMAND: DTDIP:DIP=ALL; 515 NO OF DIGITAL PATHS FOR LB-INTERFACE DIPRTL 0 - 2048 32 channels SNT. DIPRTL4 0 - 2048 24 channels SNT. These blocks are based on block DIPST. At size alteration SAE 500 RTLBT/RTLBT24, SAE 500 HIDRTL, SAE 515 DIPRTL/DIPRTL4 and SAE 529 ETRTL/ETRTL4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRTL ETRTL RTLBT HIDRTL Decrease in reverse order. 24 channel increase: First Second Third DIPRTL4 ETRTL4 RTLBT24 Decrease in reverse order. Guiding value for BSC and BSC/TRC = (SAE500 RTLBT24)/24 or (SAE500 RTLBT)/32. COMMAND: DTDIP:DIP=ALL; Guiding value for TRC = 0. 515 NO OF DIGITAL PATHS FOR ATER INTERFACE DIPRTT 0 - 2048 32 channels SNT. DIPRTT4 0 - 2048 24 channels SNT. These blocks are based on block DIPST. At size alteration SAE 500 RTLTT/RTLTT24, SAE 500 HIDRTT, SAE 515 DIPRTT/DIPRTT4 and SAE 529 ETRTT/ETRTT4 must be size modified in the



following order: 32 channel increase: First Second Third Fourth DIPRTT ETRTT RTLTT HIDRTT Decrease in reverse order. 24 channel increase: First Second Third DIPRTT4 ETRTT4 RTLTT24 Decrease in reverse order. Guiding value for BSC = 0. Guiding value BSC/TRC and TRC = (SAE 500 RTLTT24)/24 or (SAE 500 RTLTT)/32. COMMAND: DTDIP:DIP=ALL; 515 SDIPM2 0 - 704 NO OF SDIP INDIVIDUALS FOR SDIPQM2 ET155-1 SDIPM2 is based on SDIPST (SAE 515). When using the function historical storage of quality data, the number of Historical Data (HID) individuals in block SDIPHM2 must be increased (SAE 500) after the SDIPM2 individuals and decreased before the SDIPM2 individuals (HID individuals <= SDIPM2 individuals). At size alteration the corresponding SDIPQM2, SDIPM2, DIPM2 and ETM2 blocks must be size modified in the following increasing order: First Second SDIPQM2(515) SDIPM2(515) Third Fourth DIPM2(515) ETM2(529) Decrease in reverse order. Guiding value = no of ET155-1. 515 SDIPM3 0 - 704 NO OF SDIP INDIVIDUALS FOR SDIPQM3 ET155-1 SDIPM3 is based on SDIPST (SAE 515). At size alteration the corresponding SDIPQM3, SDIPAM3, SDIPFM3, SDIPM3, DIPM3 and ETM3 blocks must be size modified in the following increasing order: First Second SDIPQM3(515) SDIPAM3(515)



Third Fourth SDIPFM3(515) SDIPM3(515) FIFTH SIXTH DIPM3(515) ETM3(529) Decrease in reverse order. Guiding value = no of ET155-1. 515 SDIPM1 0 - 1024 NO OF SDIP INDIVIDUALS FOR SDIPQ ET155-7 SDIPM1 is based on SDIPST (SAE 515). When using the function historical storage of quality data, the number of Historical Data (HID) individuals in block SDIPHID must be increased (SAE 500) after the SDIP individuals and decreased before the SDIP individuals (HID individuals <= SDIP individuals). At size alteration the corresponding SDIPQ, SDIPST, DIPST and ET blocks must be size modified in the following increasing order: First Second SDIPQ(515) SDIPM1(515) Third Fourth DIPM1(515) ETM1(529) Decrease in reverse order. Guiding value = no of ET155-7. 515 SDIPAM3 0 - 704 NO OF SDIP INDIVIDUALS FOR SDIPFM3 ET155-1 At size alteration the corresponding SDIPQM3, SDIPAM3, SDIPFM3, SDIPM3, DIPM3 and ETM3 blocks must be size modified in the following increasing order: First Second SDIPQM3(515) SDIPAM3(515 Third Fourth SDIPFM3(515) SDIPM3(515) FIFTH SIXTH DIPM3(515) ETM3(529) Decrease in reverse order. Guiding value = no of ET155-1. 522 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE INTERNAL HANDOVER COUNTER FILE Increase the number of individuals when the command for initiating neighboring cell relations, RLNRI, results in



fault code 127. There is a restriction that both handover counter files (SAE 522 + SAE 523) may not in total exceed the size of the neighboring cell relation file (SAE 524). Guiding value for BSC and BSC/TRC = no of internal cell relations (defined in the cell plan). Note that mutual cell relations count as two relations. Guiding value for TRC = 0. COMMAND: RLNRP:CELL=ALL,NODATA; 523 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE EXTERNAL HANDOVER COUNTER FILE Increase the number of individuals when the command for initiating neighboring cell relations, RLNRI, results in fault code 128. There is a restriction that both handover counter files (SAE 522 + SAE 523) may not in total exceed the size of the neighboring cell relation file (SAE 524). Guiding value for BSC and BSC/TRC = no of external cell relations (defined in the cell plan). Guiding value for TRC = 0. COMMAND: RLNRP:CELL=ALL,NODATA; 524 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE NEIGHBORING CELL RELATION FILE Increase the number of individuals according to the restriction below. There is a restriction that the size of the neighboring cell relation file (SAE 524) may not fall below the actual sum of both handover counter files (SAE 522 + SAE 523). Guiding value for BSC and BSC/TRC = according to the restriction above. Guiding value for TRC = 0



COMMAND: RLNRP:CELL=ALL,NODATA; 528*)SNTPCD 0 - 2048 NO OF SNTPCD TYPES This size alteration event is for hardware no longer used in BSC. Guiding value = 0 528*)SNTPCDM 0 - 2048 NO OF SNTPCD TYPES This size alteration event is for hardware no longer used in BSC. Guiding value = 0 529 ET 0 - 2046 NO OF SNT INDIVIDUALS This block is not used in the BSC. Instead, the BSC uses 9 blocks based on the function block ET. See SAE 529 for ETM1, ETM2, ETM3, ETRALT/4, ETRBLT/4, ETRTB/4, ETRTG/4, ETRTL/4 and ETRTT/4. Order of increase: First Second Third SDIPST(515) DIPST(515) ET(515) Decrease in reverse order. Guiding value = 0; 529 ETM2 0 - 704 NO OF ETM2 SNT INDIVIDUALS FOR ET155-1 This block is based on ET (SAE 529). At increase the number of DIP individuals in DIPM2 must be 63 times the number of SNT individuals. Number of SDIPM2-individuals must equal the number of SNT- individuals. An SNT can handle up to 2016 devices. ETM2 also has an interface towards ETDIF based blocks and Device owner. ETDIF based blocks and Device owner must therefore also be sized increased/ decreased. This is independent of the file size of ETM2. Order of increase: First Second SDIPQM2(515) SDIPM2(515) Third Fourth DIPM2(515) ETM2(529) Decrease in reverse order. Guiding value = no of ET155-1. 529 ETM3 0 - 704 NO OF ETM3 SNT INDIVIDUALS FOR ET155-1



This block is based on ET (SAE 529). At increase the number of DIP individuals in DIPM3 must be 84 times the number of SNT individuals. Number of SDI3P-individuals must equal the number of SNT- individuals. An SNT can handle up to 2016 devices. ETM3 also has an interface towards ETDIF based blocks and Device owner. ETDIF based blocks and Device owner must therefore also be sized increased/ decreased. This is independent of the file size of ETM3. Order of increase: First Second SDIPQM3(515) SDIPAM3(515) Third Fourth SDIPFM3(515) SDIPM3(515) FIFTH SIXTH DIPM3(515) ETM3(529) Decrease in reverse order. Guiding value = no of ET155-1. 529 ETM1 0 - 1024 NO OF ETM1 SNT INDIVIDUALS FOR ET155-7 This block is based on ET (SAE 529). At increase the number of DIP individuals in DIPM1 must be 63 times the number of SNT individuals. Number of SDIPM1-individuals must equal the number of SNT- individuals. An SNT can handle up to 2016 devices. ETM1 also has an interface towards ETDIF based blocks and Device owner. ETDIF based blocks and Device owner must therefore also be sized increased/decreased. This is independent of the file size of ETM1. Order of increase: First Second SDIPQ(515) SDIPM1(515) Third Fourth DIPM1(515) ETM1(529) Decrease in reverse order. Guiding value = no of ET155-7. 529 NO OF ETRALT SNT INDIVIDUALS ETRALT 0 - 2048 32 channels SNT. ETRALT4 0 - 2046 24 channels SNT.



At increase the number of SNT individuals must be equal to the number of DIP individuals in DIPRALT. At decrease the number of SNT individuals must be equal to the number of device individuals in RALT24 divided by 24 or the number of device individuals in RALT divided by 32 (number of devices per SNT). At size alteration SAE 500 RALT/RALT24, SAE 500 HIDRALT, SAE 515 DIPRALT/DIPRAT4 and SAE 529 ETRALT/ETRALT4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRALT ETRALT RALT HIDRALT Decrease in reverse order. 24 channel increase: First Second Third DIPRAT4 ETRALT4 RALT24 Decrease in reverse order. Guiding value for BSC = 0. Guiding value for BSC/TRC and TRC = (SAE 500 RALT)/32 or (SAE 500 RALT24)/24 (24 channels SNT) COMMAND: EXEMP:RP=ALL,EM=ALL; 529 NO OF ETRBLT SNT INDIVIDUALS ETRBLT 0 - 20468 32 channels SNT. ETRBLT4 0 - 2046 24 channels SNT. At increase the number of SNT individuals must be equal to the number of DIP individuals in DIPRBLT. At decrease the number of SNT individuals must be equal to the number of device individuals in RBLT24 divided by 24 or the number of device individuals in RBLT divided by 32 (number of devices per SNT). At size alteration SAE 500 RBLT/RBLT24, SAE 500 HIDRBLT, SAE 515 DIPRBLT/DIPRBT4,



SAE 529 ETRBLT/ETRBLT4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRBLT ETRBLT RBLT HIDRBLT Decrease in reverse order. 24 channel increase: First Second Third DIPRBT4 ETRBLT4 RBLT24 Decrease in reverse order. Guiding value for BSC and BSC/TRC = (SAE 500 RBLT)/32 or (SAE 500 RBLT24)/24 ( 24 channels SNT) Guiding value for TRC = 0. COMMAND: EXEMP:RP=ALL,EM=ALL; 529 NO OF ETRTB SNT INDIVIDUALS ETRTB 0 - 2048 32 channels SNT. ETRTB4 0 - 2046 24 channels SNT. At increase the number of SNT individuals must be equal to the number of DIP individuals in DIPRTB. At decrease the number of SNT individuals must be equal to the number of device individuals in RTLTB24 divided by 24 or the number of device individuals in RTLTB divided by 32 (number of devices per SNT). At size alteration SAE 500 RTLTB/RTLTB24, SAE 500 HIDRTB, SAE 515 DIPRTB/DIPRTB4 and SAE 529 ETRTB/ETRTB4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRTB ETRTB RTLTB HIDRTB Decrease in reverse order. 24 channel increase: First Second Third DIPRTB4 ETRTB4 RTLTB24 Decrease in reverse order. Guiding value for BSC =



(SAE 500 RTLTB)/32 or (SAE 500 RTLTB24)/24 ( 24 channels SNT) Guiding value for TRC and BSC/TRC = 0. COMMAND: EXEMP:RP=ALL,EM=ALL; 529 NO OF ETRTG SNT INDIVIDUALS ETRTG 0 - 2048 32 channels SNT. ETRTG4 0 - 2046 24 channels SNT. At increase the number of SNT individuals must be equal to the number of DIP individuals in DIPRTG. At decrease the number of SNT individuals must be equal to the number of device individuals in RTGLT24 divided by 24 or the number of device individuals in RTGLT divided by 32 (number of devices per SNT). At size alteration SAE 500 RTGLT/RTGLT24, SAE 500 HIDRTG, SAE 515 DIPRTG/DIPRTG4, SAE 529 ETRTG/ETRTG4 and must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRTG ETRTG RTGLT HIDRTG Decrease in reverse order. 24 channel increase: First Second Third DIPRTG4 ETRTG4 RTGLT24 Decrease in reverse order. Guiding value for BSC and BSC/TRC = (SAE 500 RTGLT)/32 or (SAE 500 RTGLT24)/24 (24 channels SNT) Guiding value for TRC = 0. COMMAND: EXEMP:RP=ALL,EM=ALL; 529 NO OF ETRTL SNT INDIVIDUALS ETRTL 0 - 2048 32 channels SNT. ETRTL4 0 - 2046 24 channels SNT.



At increase the number of SNT individuals must be equal to the number of DIP individuals in DIPRTL. At decrease the number of SNT individuals must be equal to the number of device individuals in RTLBT24 divided by 24 or the number of device individuals in RTLBT divided by 32 (number of devices per SNT). At size alteration SAE 500 RTLBT/RTLBT24, SAE 500 HIDRTL, SAE 515 DIPRTL/DIPRTL4 and SAE 529 ETRTL/ETRTL4 must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRTL ETRTL RTLBT HIDRTL Decrease in reverse order. 24 channel increase: First Second Third DIPRTL4 ETRTL4 RTLBT24 Decrease in reverse order. Guiding value for BSC and BSC/TRC = (SAE 500 RTLBT)/32 or (SAE 500 RTLBT24)/24 (24 channels SNT) Guiding value for TRC = 0. COMMAND: EXEMP:RP=ALL,EM=ALL; 529 NO OF ETRTT SNT INDIVIDUALS ETRTT 0 - 2048 32 channels SNT. ETRTT4 0 - 2046 24 channels SNT. At increase the number of SNT individuals must be equal to the number of DIP individuals in DIPRTT. At decrease the number of SNT individuals must be equal to the number of device individuals in RTLTT24 divided by 24 or the number of device individuals in RTLTT divided by 32 (number of devices per SNT). At size alteration SAE 500 RTLTT/RTLTT24, SAE 500 HIDRTT, SAE 515 DIPRTT/DIPRTT4 and SAE 529 ETRTT/ETRTT4



must be size modified in the following order: 32 channel increase: First Second Third Fourth DIPRTT ETRTT RTLTT HIDRTT Decrease in reverse order. 24 channel increase: First Second Third DIPRTT4 ETRTT4 RTLTT24 Decrease in reverse order. Guiding value for BSC = 0. Guiding value for BSC/TRC and TRC = (SAE 500 RTLTT)/32 or (SAE 500 RTLTT24)/24 (24 channels SNT) COMMAND: EXEMP:RP=ALL,EM=ALL; 529 RTPGS 0 - 64 NO OF PGW SNT INDIVIDUALS The SAE increases and decreases the number of SNTs and EMs for PGW. SAE 500 RTPGD, SAE 500 RTBLD and SAE 529 RTPGS are dependent on each other. SAE 500 RTPGD and SAE 500 RTPLD = 768 * SAE 529 RTPGS and must be increased in the following order: First Second Third 529 RTPGS 500 RTPLD 500 RTPGD Decrease in reverse order. Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC 529*)SNTPCD 0 - 2047 NO OF SNTPCD INDIVIDUALS This size alteration event is for hardware no longer used in BSC. Guiding value = 0 529*)SNTPCDM 0 - 2047 NO OF SNTPCD INDIVIDUALS This size alteration event is for hardware no longer used in BSC. Guiding value = 0 529 SRSTRAF 0 - 8 NO OF SUBRATE SWITCH UNITS SRS Increases or decreases the number of Subrate Switch units that may be connected to the Group Switch. Step size for



increase or decrease = 1 individual. Size per individual = 160263 (16-bit) words. At size alteration of SRS data, SRSTRAF and the co-operating SRS block must be size modified in the following order: First Second Increase: SRSTRAF SRS Decrease: SRS SRSTRAF Guiding value =8 for GS12. =0 for GS890. (The number of SNT of type SRS) Command: NTSTP:SNT=ALL; 533 ROBAR 0 - 65534 NO OF GSM TEST FREQUENCY INDIVIDUALS IN ACTIVE BA-LIST RECORDING The number of individuals is determined by all possible combinations of test frequencies and active cells connected to the active BA-list recording. Guiding value = 32768 for BSC and BSC/TRC. = 0 for TRC. 534 ROBAR 0 - 131072 NO OF TEST UMTS MEASUREMENT FREQUENCY INFORMATION (TUMFI) INDIVIDUALS The number of individuals is determined by all possible combinations of TUMFIs (test UMTS measurement frequency information) and active cells connected to BA-list recording. Guiding value = 65536 for BSC and BSC/TRC. = 0 for TRC. 538 RXEFT 0 - 218834 NO OF FILE SEGMENTS AT SW FILE STORAGE FOR BTS LOGICAL MODEL G01 The least extension or reduction stage = 1 file segment. 1 file segment = 230 byte. 218834 file segments = 49152 kbyte for storage of software files. The minimum number of file segments is equal to the size of the largest subfile. It is recommended to allow for storage of two different SW packages (i.e. storage for all subfiles of two packages) for the BTS logical model G01.



Guiding Value for BSC and BSC/TRC=(BTS SW 1 volume + BTS SW 2 volume)/230. The guiding values for BSC and BSC/TRC if RBS200 is in use = 10000, if RBS200 is not in use = 0. Guiding value for TRC = 0. Alternative recommendations are given if there is lack of memory, see section 3.6.10. SW volume shall be given in bytes. COMMAND: INFIP:FILE=subfiles; 538 RXOFT 0 - 218834 NO OF FILE SEGMENTS AT SW FILE STORAGE FOR BTS LOGICAL MODEL G12 The least extension or reduction stage = 1 file segment. 1 file segment = 230 byte. 218834 file segments = 49152 kbyte for storage of software files. The minimum number of file segments is equal to the size of the largest subfile. It is recommended to allow for storage of two different SW packages (i.e. storage for all subfiles of two packages) for the BTS logical model G12. Guiding Value for BSC and BSC/TRC=(BTS SW 1 volume + BTS SW 2 volume)/230. The guiding values for BSC and BSC/TRC = 130000. Guiding value for TRC = 0. Alternative recommendations are given if there is a lack of memory, see section 3.6.10. SW volume shall be given in bytes. COMMAND: INFIP:FILE=subfiles; 550 RXCMSD 0 - 512 NO OF TG MANAGED OBJECTS IN THE BSC The SAE increases or decreases the amount of space available for definition of Transceiver Group managed objects in the BSC, whichever logical model they are in. Guiding value for BSC and BSC/TRC = cell planning dependent. Guiding value for TRC = 0. COMMAND: RXMSP:MOTY=RXETG; RXMSP:MOTY=RXOTG;



552 RXCMSD 0 - 512 NO OF CF MANAGED OBJECTS IN THE BSC The SAE increases or decreases the amount of space available for definition of Common Functions managed objects in the BSC. Guiding value for BSC and BSC/TRC = cell planning dependent. Guiding value for TRC = 0. COMMAND: RXMSP:MOTY=RXOCF; 554 S7GST 0 - 16384 NO OF NB ANSI SIGNALLING TERMINAL INDIVIDUALS This SAE is used for NB signalling terminal administration and SPNC-, RP-, and EM handling for Generic Ericsson Magazine (GEM), based on Signalling Terminal Enhanced Board (STEB) hardware platform. Min and max value is 128 For calculation of SAE 097, the real value shall be used. 554 S7HST 0 - 128 NO OF HSL ANSI SIGNALLING TERMINAL INDIVIDUALS This SAE is used for HSL signalling terminal administration and SPNC-, RP-, and EM handling for Generic Ericsson Magazine (GEM), based on Signalling Terminal Enhanced Board (STEB) hardware platform. 554*)S7ST 0 - 1024 NO OF ANSI SIGNALLING TERMINAL INDIVIDUALS This size alteration event is for hardware no longer used in BSC. Guiding value = 0 554 S7STG 0 - 1024 NO OF ANSI SIGNALLING TERMINAL INDIVIDUALS This size alteration event is used for RPG2 and RPG3 based signalling terminal. Check also against SAE 052. Guiding value = 0 if CCITT CCS7 is used. = site dependent if ANSI CCS7 is used. The formula 4 * ceil (STDATA/4) shall be used where: ceil(x) = smallest integer no smaller than x STDATA = number of RPG2, RPG3 based signalling terminals.



COMMAND: EXEMP:RP=ALL,EM=ALL; 566 C7GST 0 - 16384 NO OF NB CCITT SIGNALLING TERMINAL INDIVIDUALS This SAE is used for NB signalling terminal administration and SPNC-, RP-, and EM handling for Generic Ericsson Magazine (GEM), based on Signalling Terminal Enhanced Board (STEB) hardware platform. Min and max value is 128 For calculation of SAE163 and SAE097, the real value shall be used. 566 C7GSTAH 0 - 128 NO OF HSL CCITT SIGNALLING TERMINAL INDIVIDUALS (Q.703) This SAE is used for HSL signalling terminal administration and SPNC-, RP-, and EM handling for Generic Ericsson Magazine (GEM), based on Signalling Terminal Enhanced Board (STEB) hardware platform. 566 C7GSTH 0 - 128 NO OF HSL CCITT SIGNALLING TERMINAL INDIVIDUALS (ATM) This SAE is used for HSL signalling terminal administration and SPNC-, RP-, and EM handling for Generic Ericsson Magazine (GEM), based on Signalling Terminal Enhanced Board (STEB) hardware platform. 566*)C7ST2 0 - 1023 NO OF CCITT SIGNALLING TERMINAL INDIVIDUALS This size alteration event is for hardware no longer used in BSC. Guiding value = 0 566 C7ST2C 0 - 16383 NO OF CCITT SIGNALLING TERMINAL INDIVIDUALS This size alteration event is used for RPG2 or RPG3 based signalling terminal. Check also against SAE 163. The signalling terminal can handle up to four signalling links for the RPG2 and RPG3. Guiding value = site dependent if CCITT CCS7 is used. = 0 if ANSI CCS7 is used. COMMAND: EXEMP:RP=ALL,EM=ALL; 583*)C7SC2 0 - 1024 NO OF RECORDING OBJECT RECORDS File dimensioning for CCITT7 traffic and performance



measurement. Records relate to recording objects: link sets, signalling links and destinations. Guiding value = 3 (R-BSC) or 17 (Comb/TRC) for CCITT CCS7 = 0 for ANSI CCS7 COMMAND: C7TRP:TRG=ALL; 584*)C7TMA2 0 - 4096 NO OF TRAFFIC RECORDING GROUPS The recording objects (link sets or destinations with attached signalling links) are connected to traffic recording groups. There is a maximum of 16 link sets or destinations per TRG. Guiding value = 3 (R-BSC) or 17 (Comb/TRC) for CCITT CCS7 = 0 if ANSI CCS7 COMMAND: C7TRP:TRG=ALL; 585*)C7TMP2 0 - 4096 NO OF OUTREC'S The record type OUTREC holds the data associated with the Measuring Program and Traffic Recording Group. Guiding value = (SAE 583)/2 if CCITT CCS7 is used. = 0 if ANSI CCS7 is used. 587*)C7PMA2 0 - 4095 NO OF TRAFFIC RECORDING GROUPS See SAE 584. Guiding value = (SAE 584). 588*)C7PMP2 1 - 3169 NO OF OUTREC'S See SAE 583. Guiding value = (SAE 583)/2. 600 CH 0 - 128 NO OF SUBRATE CONNECTIONS THAT MAY BE ESTABLISHED Each individual represents 1024 Multiple Positions (MUPs). Individuals are seized at connection of XM unit and released at disconnection. Eight subrate connections correspond to MUP. The number of individuals to be specified in the SAAII command must be the same number of individuals related to SAE 442. At size alteration SAE must be increased in the following order.



First Second Third SAE 442 SAE 600(CH) SAE 600(XM) Decrease in reverse order. Guiding value = site dependent for GS890. = 0 for GS12 600 HWID 0 - 65535 HARDWARE DATA FOR ACCESS 910 HARDWARE In BSS where Access 910 hardware is not available the SAE size is set to 0. 600 IP 0 - 128 NO OF IP EM OBJECTS An individual is seized when an IP EM connection is ordered with the command EXEMI and it is released when an IP EM disconnection is performed with the command EXEMI. Maximum 128 IP EMs can be connected simultaneously. Guiding value = 0. 600 RTPRH 0 - 512 NO OF SUPER CHANNEL GROUPS The SAE controls the file size of the Super Channel Group (SCGR) file and the Super Channel (SC) file. Increase or decrease by one results in changing the SCGR file with one and the SC file with four records. Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC 600 SCTP 0 - 128 NO OF SCTP EM OBJECTS An individual is seized when a SCTP EM connection is ordered and it is released when a SCTP EM disconnection is performed and at most 128 SCTP EMs can be connected simultaneously. Guiding value = 0. 600 XM 0 - 128 NO OF SUBRATE CONNECTIONS THAT MAY BE ESTABLISHED Each individual represents 1024 Multiple Positions (MUPs). Individuals are seized at connection of XM unit and released at disconnection. Eight subrate connections correspond to MUP. The number of individuals to be specified in



the SAAII command must be the same number of individuals related to SAE 442. At size alteration SAE must be increased in the following order. First Second Third SAE 442 SAE 600(CH) SAE 600(XM) Decrease in reverse order. Guiding value = site dependent for GS890. = 0 for GS12. 601 IP 0 - 512 NO OF IP PORT OBJECTS Each individual stores information related to IP ports and IP port pairs. An individual is seized when a connection is ordered with the command IHCOI and it is released when an IP port disconnection is performed with the command IHCOE. Only one IP port can be defined over the same equipment, although the HW is equipped with three Ethernet interfaces, only the ETH2 can be configured. At most 512 IP ports can be defined simultaneously. Guiding value = 0. 602 IP 0 - 4096 NO OF IP ADDRESS OBJECTS Each individual stores information related to IP addresses. An individual is seized when an IP port definition is ordered with the command IHCOI or when an IP address is added with the command IHCOC. At most two IP addresses can be defined over the same IP port. It is possible to remove an IP address only if there is no user using it. It is possible to remove, by IHCOC command, an IP address only if there is still another IP address defined over the same port. At most 1024 IP addresses can be defined simultaneously, even though the SAE maximum is 4096. Guiding value = 0. 602 SCTP 0 - 2048 NO OF SCTP ASSOCIATIONS An individual is seized when an SCTP association definition is ordered with the command IHADI and it is released when an SCTP



association undefinition is performed with the command IHADE. At most 2048 SCTP associations can be defined simultaneously. Guiding value = 0. 603 IP 0 - 2048 NO OF IP ROUTES Each individual stores information related to a static route defined on an IP port. An individual is seized when a route is defined with the command IHRDI and it is released when a static route is deleted with IHRDE command. When IP port disconnection is performed with the command IHCOE, the individuals related to the static routes configured on it are released as well. Only 4 static routes can be defined over one IP port. At most 2048 static routes can be defined simultaneously. Guiding value = 0. 603 SCTP 0 - 2048 NO OF SCTP INDIVIDUALS An individual is seized when an SCTP Initialize is ordered with the command IHBII and it is released when an SCTP Destroy is performed with the command IHBIE. At most 2048 SCTP instances can be defined simultaneously and at most 128 instances can be hosted on an SCTP EM. Guiding value = 0. 604 COHW 0 - 65534 NO OF MONITORING INDIVIDUALS The monitoring file provides control over monitoring connections in AM calls. Guiding value = 0 (AMs do not exist in BSC). 604 COSEM 0 - 8388607 NO OF CONNECTION INDIVIDUALS Increases or decreases the number of connections that may be set up involving at least one vMUP. Guiding value = 1 (vMUPs are not used by BSC). 604 COX 0 - 8388607 NO OF CONNECTION INDIVIDUALs Increases or decreases the number of connections that may be set up involving at least one LMUP. Guiding value = 0.



(LMUPs are not used by BSC) 604 RXCML 8192 - 262140 NO OF EVENTS LOGGED BY USER FUNCTIONS The SAE controls the number of events in the eventdata file, logged by the user function in the maintenance log. Changing the file size clears the log (increase or decrease) Maximum step size for increase and decrease = 32767 Guiding value = 65535 604 SCPA 0 - 65534 NO OF INDIVIDUALS TO STORE SEARCH PATTERN KEYS USED TO REASSEMBLE CONNECTIONLESS MESSAGE SEGMENTS. The number of individuals seized is the number of octets in an incoming connectionless message segment that do not match any currently stored search pattern keys. Guiding value = 1. 604 SCRD 500 - 65535 NO OF SCCP MESSAGE INDIVIDUALS. Individuals are used to store SCCP message or message segment contents. One individual is seized when a non-segmented SCCP message is sent or received and is released when the message processing is completed. Guiding value = 500. 604 SCTP 0 - 16392 NO OF IP ADDRESSES Each individual stores information related to a remote IP address. Several individuals, max 8, are seized when an SCTP association establishment is ordered with the command IHASC and they are released when an SCTP shut down or abort is performed with the same command. At most 16392 remote IP addresses can be defined simultaneously and at most 8 remote IP addresses for each assiciation can exist. Guiding value = 0. 605 COSEM 0 - 8388607 NO OF GUARD USER INDIVIDUALS The individual is seized when a user registers to guard an vMUP. Guiding value = 1. (vMUPs are not used by BSC).



605 COX 0 - 8388607 NO OF DEVICE INDIVIDUALs The individual is seized when a user registers to guard an LMUP. Guiding value = 0 (LMUPs are not used by BSC). 605 SCRD 500 - 65535 NO OF SCCP MESSAGE CONTROL INFORMATION INDIVIDUALS. Individuals are used to store SCCP message control information. One individual is seized when an SCCP message is sent or received and is released when the message processing is completed. Guiding value = 500. 605 SCTP 2048 - 65535 NO OF SCTP MESSAGE CONTROL INFORMATION INDIVIDUALS Individuals are used to reassemble incoming data to be forwarded in a communication buffer. An individual is seized when a message is received by a remote peer and it is released when remote data is sent to SCTP user. Guiding value = 2048. 606 COHW 0 - 65534 NO OF MULTIPARTY INDIVIDUALS A multiparty individual is used in an AM call for control of HW for conference connections or for sending of CCD tones in an AM call. Guiding value = 0 (AMs do not exist in BSC). 606 COMAIN 0 - 8388607 NO OF QUEUE INDIVIDUALS The queue individual is seized when the first SV in a call is seized. The queue is released when the call is released. Guiding value = 0 (AMs do not exist in BSC). 607 C7ACCL2 0 - 65334 NO OF ACCOUNTING CLASS INDIVIDUALS. One individual is used to store the information relating to one accounting class. Guiding value = 0. 607 C7EPC2 0 - 65534 NO OF SIGNALLING TRANSFER POINT (STP) POLICING SPECIFICATION INDIVIDUALS. The purpose of the records within this file is to indicate



if an STP policing specification exists for a particular combination of link set, originating point,destination point and service indicator. Guiding value = 0 (Not used in BSC) 607 C7PAN 0 - 65280 NO OF PARAMETER VALUE TREE INDIVIDUALS. The purpose of the records within this file is to store nibbles of the parameter values under a policing sub-criterion. Guiding value = 0. 607 C7SACP 0 - 65334 NO OF ACCOUNTING CLASS INDIVIDUALS. The purpose of the records within this file is to store the accounting information for the corresponding accounting class. Guiding value = 0. (Not used in BSC) 607 COMAIN 0 - 8388607 NO OF BUFFER INDIVIDUALS A buffer individual is used to store user orders while other work is going on in SV chain. Guiding value = 100 (AMs do not exist in BSC). 607 GCRLC 0 - 512 NO OF GAN-CGI DATA INDIVIDUALS The SAE is translation related. The individuals are used for storing GAN-CGI (Generic Access Network - Cell Global Identity) data. Guiding value = Site dependent for BSC and BSC/TRC. = 0 for TRC. 607 OCVTR 0 - 65534 NO OF SCCP CALLED/CALLING PARTY ADDRESS CONVERSION DATA. Individuals are used to store data required to convert an SCCP Called Party Address or an SCCP Calling Party Address. Guiding value =0. COMMAND: S7OLP:ID=ALL; 607*)SCGT 0 - 1024 NO OF GLOBAL TITLE TRANSLATION TREE RECORDS. The tree data records contain pointers to translation results. Guiding value = 0. COMMAND: C7GSP;



608 C7ACCL2 0 - 65334 NO OF ACCOUNTING CASE INDIVIDUALS. One individual is used to store the information relating to one accounting case. Guiding value = 0. 608 C7EPC2 0 - 65534 NO OF SIGNALLING NETWORK MANAGEMENT (SNM) POLICING SPECIFICATION INDIVIDUALS. The purpose of the records within this file is to indicate if an SNM policing specification exists for a particular combination of link set, originating point, destination point, header code and concerned destination point. Guiding value = 0. (Not used in BSC) 608 C7SACP 0 - 65280 NO OF CRITERION INDIVIDUALS. The purpose of the records within this file is to store the accounting criteria data. Guiding value = 0. 608 COMES 0 - 65535 NO OF BROADCAST INDIVIDUALS Guiding value = 0 (Message service is not used in BSC). 608 OCVTR 0 - 1024 NO OF GLOBAL TITLE TRANSLATION DATA IN ANSI FORMAT. Individuals are used to store data for translation of Global Title. Guiding value = 0. Command: S7ODP:ID=ALL, FORMAT=ANSI; 609 OCVTR 0 - 255 NO OF NETWORK DATA INDIVIDUALS. Individuals are used to store network data. Guiding value = 0. Command: S7ODP:ID=ALL; 610 OCVTR 0 - 7536 NO OF CLUSTER DATA INDIVIDUALS. Individuals are used to store cluster data. Guiding value = 0. Command: S7ODP:ID=ALL; 611 OCVTR 0 - 65534 NO OF SUBSYSTEM CONNECTED TO SIGNALLING POINTS DATA INDIVIDUALS. Individuals are used to store



data concerning subsystem connected to signalling points. Guiding value = 0. Command: S7ODP:ID=ALL; 612 OCVTR 0 - 4094 NO OF NATURE OF ADDRESS DATA INDIVIDUALS. Individuals are used to store data concerning NATURE ADDRESS. Guiding value = 0. Command: S7ODP:ID=ALL; 613 OCVTR 0 - 1024 NO OF GLOBAL TITLE TRANSLATION DATA IN ITU-T FORMAT INDIVIDUALS. Individuals are used to store Global Title data in ITU-T format. Guiding value = 0. Command: S7ODP:ID=ALL, FORMAT=ITU; 630 C7DR2 0 - 4079 NO OF SIGNALLING POINTS ADDRESSING DATA INDIVIDUALS. If CCITT CCS7 is used: Guiding value = 17 for BSC/TRC and TRC. = 3 for BSC. If ANSI CCS7 is used: Guiding value = 0. COMMAND: C7SPP:SP=ALL; 634 C7PVC2 0 - 65536 NO OF REGISTERED MESSAGES. Guiding value = 0. 635 C7CVR2 0 - 8191 NO OF INDIVIDUALS FOR LONG MESSAGE VIOLATION REPORTS. Guiding value = 10. 636 C7CVR2 0 - 8191 NO OF INDIVIDUALS FOR CONFUSION MESSAGE. Guiding value = 10. 667*)C7GT 0 - 4094 NO OF GLOBAL TITLE TRANSLATION TYPE AND NUMBERING PLAN COMBINATIONS Guiding value = 1. COMMAND: C7GSP; 700 C7OMASE 0 - 65535 NO OF DIALOGUE INDIVIDUALS The dimensioning of Dialogue Individuals depends on the number of OMASE-USERS (OMAP Service Element) in the node, the number of link sets and the number of routes to a destination. Guiding value = 0.



700 C7TCP 0 - 262143 NO OF DIALOGUE INDIVIDUALS. This SAE handles dialogue individuals. Guiding value = 0. 700 RHDEV 0 - 65536 NO OF INDIVIDUALS. RHLAPD This SAE increases or decreases the number of individuals in the file containing a help variable associated with the Device Individual file DEVDATA. The file size is only increased if the help variable is needed for a correction in the block. Guiding value = 0 if no corrections are loaded that uses these help variables. 700 RCLCCH 0 - 73728 NO OF INDIVIDUALS. RMHBI This SAE is the Size Alteration RNCM Event for the file containing RNLC a help variable associated with RNLCH the Logical Channel (LCH) file. RNTCH The file size is only increased RQUNC if the help variable is needed RMVGCH for a correction in the block. RQRCQS Guiding value = 0. If no corrections are loaded that uses these help variables. 700 RCSCB 0 - 262144 NO OF INDIVIDUALS. RQUPD This SAE increases or decreases the number of individuals in the file containing a help variable associated with the Local Data Link Individual (LDLI) file. The file size is only increased if the help variable is needed for a correction in the block. Guiding value = 0 if no corrections are loaded that uses these help variables. 700 GCIMSI 0 - 1048575 NO OF INDIVIDUALS. GCURR This SAE increases or decreases GCRLC the number of individuals in the file containing a help variable associated with the MS individual database file. The file size is only increased if the help variable is needed for a correction in the block. Guiding value = 0 if no corrections are loaded that uses these help variables.



700 RXCLMO 0 - 100840 NO OF INDIVIDUALS. RXEPL 0 - 32511 This SAE increases or decreases RXOPL 0 - 49653 the number of individuals in RTVPH 0 - 74734 a file containing help RTTRINT 0 - 83004 variables. RXOISH 0 - 81901 The file sizes are only increased RXELS 0 - 74528 if the help variable is needed for RXOLS 0 - 206291 a correction in the block. RXCML 0 - 262144 Guiding value = 0 if no corrections are loaded that uses these help variables. 701 C7TCP 0 - 262143 NO OF OPERATION INDIVIDUALS. This SAE handles operation individuals. Guiding value = 0. 701 RHLAPD 0 - 262144 NO OF INDIVIDUALS. This SAE increases or decreases the number of individuals in the file containing a help variable associated with the Local Data Individual file LDLDATA. The file size is only increased if the help variable is needed for a correction in the block. Guiding value = 0 if no corrections are loaded that uses these help variables. 701 RCLCCH 0 - 262144 NO OF INDIVIDUALS. RQUNC This SAE increases or decreases RQRCQS the number of individuals in the file containing a help variable associated with the Local Data Link Individual (LDLI) file. The file size is only increased if the help variable is needed for a correction in the block. Guiding value = 0 if no corrections are loaded that uses these help variables. 702 C7TCP 0 - 12287 NO OF MESSAGE INDIVIDUALS. This SAE handles messages individuals. Guiding value = 0. 703 SGSCR 0 - 1021 NO OF DEFINED GATEWAY SCREENING REFERENCES. Individual is seized when a new gateway screening reference is defined and released when the gateway screening reference is undefined. Guiding value = 0.



704 SGSCR 0 - 65534 NO OF DEFINED GATEWAY SCREENING ENTITIES. An individual is seized when a new gateway screening entity is defined, and released when the gateway screening entity is undefined. Guiding value = 0. 710 RCLCCH 0 - 73728 NO OF INDIVIDUALS. RMHBI This SAE is the Size Alteration RNCM Event for the file containing RNLC the first additional record of RNLCH help variables in the block. RNTCH The file size is only increased RMVGCH if the help variables are needed for a correction in the block. Guiding value = 0. If no corrections are loaded that uses these help variables. 710 RXCLIM 0 - 262080 NO OF INDIVIDUALS. RXEPL 0 - 32511 This SAE increases or decreases RXOPL 0 - 49653 the number of individuals in RTVPH 0 - 74734 a file containing help RTTRINT 0 - 83004 variables. RXOISH 0 - 81901 The file sizes are only increased RXCLMO 0 - 100840 if the help variable is needed for RXCML 0 - 262140 a correction in the block. RCSCB 0 - 262144 Guiding value = 0 if no corrections are loaded that uses these help variables. 720 RCLCCH 0 - 73728 NO OF INDIVIDUALS. RMHBI This SAE is the Size Alteration RNCM Event for the file containing RNLC the second additional record of RNLCH help variables in the block. RNTCH The file size is only increased if the help variables are needed for a correction in the block. Guiding value = 0. If no corrections are loaded that uses these help variable. 720 RXCLIM 0 - 262080 NO OF INDIVIDUALS. RXEPL 0 - 32511 This SAE increases or decreases RXOPL 0 - 49653 the number of individuals in RTVPH 0 - 74734 a file containing help RTTRINT 0 - 83004 variables. RXOISH 0 - 81901 The file sizes are only increased RXCLMO 0 - 100840 if the help variable is needed for RXCML 0 - 262140 a correction in the block. RCSCB 0 - 262144 Guiding value = 0 if no corrections are loaded that



uses these help variables. 730 RNLCH 0 - 73728 NO OF INDIVIDUALS. RNTCH This SAE is the Size Alteration Event for the file containing the third additional record of help variables in the block. The file size is only increased if the help variables are needed for a correction in the block. Guiding value = 0. If no corrections are loaded that uses these help variables. 730 RXCLIM 0 - 262080 NO OF INDIVIDUALS. RXCLMO 0 - 100840 This SAE increases or decreases RXCML 0 - 262140 the number of individuals in RCSCB 0 - 262144 a file containing help variables. The file sizes are only increased if the help variable is needed for a correction in the block. Guiding value = 0 if no corrections are loaded that uses these help variables. 731 RXCML 0 - 262140 NO OF INDIVIDUALS. This SAE is the Size Alteration Event containing a help variable associated with the log entries file. The file size is only increased if the help variable is needed for a correction in the block. Guiding value = 0. If no corrections are loaded that uses these help variables. 755 TPLAT 0 - 65534 NO OF INDIVIDUALS FOR OPERATIONS INVOKED BY THE LOCAL TC-USER. Individuals are used for supervision of operations invoked by the local TC-User. Guiding value = 0. 756 TPLAT 0 - 65534 NO OF TRANSACTION INDIVIDUALS. Individuals are used for each transaction that is initiated. The transaction file is used by the applications asking to use services from the TCAP platform. Guiding value = 0. Note:X=4 if full rate only is used. X=8 if half rate only is used. X is between 4 and 8 for a mix of half rate and full rate. For example, X=6 at 50% of each speech codec type.



5.2 APZ Size Alteration Events



SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 OCITS 10 - 64 NO OF INDIVIDUALS FOR HANDLING THE COMMUNICATION LINKS Guiding value = 12. This corresponds to the number of STOCs. OCITS is the main block in the function Open Communication Internet Transport Service in the OCS subsystem. 500*)RTS00- 0 - 65534 NO OF PROCESS INDIVIDUALS RTS19 Guiding value = 150. (Not used, RTS is a generic block that implements some of the runtime features of the HLPlex language) 501*)RTS00- 0 - 65534 NO OF EVENT INDIVIDUALS RTS19 Guiding value = 150. (Not used, RTS is a generic block that implements some of the runtime features of the HLPlex language) 502*)RTS00- 0 - 65534 NO OF FORLOPP INDIVIDUALS RTS19 Guiding value = 0. (Not used, RTS is a generic block that implements some of the runtime features of the HLPlex language) 503*)RTS00- 0 - 65534 NO OF MODULE INDIVIDUALS RTS19 Guiding value = 101. (Not used, RTS is a generic block that implements some of the runtime features of the HLPlex language) 504*)RTS00- 0 - 65534 NO OF OBMAN INTERFACE RTS19 INDIVIDUALS Guiding value = 0. (Not used, RTS is a generic block that implements some of the runtime features of the HLPlex language) 505*)RTS00- 0 - 65534 NO OF APPLICATION MODULE



RTS19 PROTOCOL CARRIER LINK INTERFACE INDIVIDUALS Guiding value = 101. (Not used, RTS is a generic block that implements some of the runtime features of the HLPlex language) 506*)RTS00- 0 - 65534 NO OF OF GLOBAL SEIZURECASE RTS19 INDIVIDUALS Guiding value = 101. (Not used, RTS is a generic block that implements some of the runtime features of the HLPlex language) 507*)RTS00- 0 - 65534 NO OF OF GLOBAL SEIZURECASE RTS19 INDIVIDUALS Guiding value = 101. (Not used, RTS is a generic block that implements some of the runtime features of the HLPlex language) 800 COCAT 100 - 65535 NO OF COMMANDS IN COMMAND CATEGORY GROUP TABLE The number of commands that one wants to change from the default Command Category Group to another Command Category Group. The minimum number of steps at size alteration is 1. The maximum increment and decrement step is 5000. Guiding value = 300. Command: IOCTP:COMMAND=ALL; 800 AD1 0 - 16384 NO OF RECORDS USED FOR SESSIONS The file is used to hold transaction data during a command or printout session. The block AD works as a device block towards terminals connected to the Adjunct Processor (AP). Guiding value = 512 (Not A55). Command: IOMSP; 800 AF 0 - 64 NO OF ALPHANUMERICAL FILES Guiding value = 32. 800 APFMI 2 - 16383 NO OF REQUESTS TO OPEN A FILE IN AP An SAE individual is used as a reference to an open file located in the Adjunct Processor (AP). Size per individual = 129 (16 bit) words.



Guiding value = 64. 800 APFPI 16 - 1024 NO OF SESSIONS BETWEEN CP AND AP An SAE individual is used as a temporary storage for calls from Central Processor (CP) users to the file processing functions of the Adjunct Processor (AP). Size per individual = 20 (16 bit) words. Guiding value = 256. 800 AT 1 - 1024 NO OF ALPHANUMERICAL TERMINALS Guiding value = 125 (Not A55). 800 TW 0 - 8192 NO OF I/O TERMINALS IN TRI Guiding value = SAE 310. COMMAND: IOIOP:IO1=ALL; 800 LADSD 0 - 4194303 NO OF INDIVIDUALS IN RECORD DSCMVARS SAE increases and decreases the number of individuals in the RECORD DSCMVARS. If congestion occurs it will not be possible to insert new individuals in the record. Not applicable for A55. Guiding value = 0. 800 LAEL 0 - 65535 NO OF COMMON STORED VARIABLES SAE for the VAR DATASB record. The SAE should be set in the CP stand-by side before the function change. The SAE must be set equal to SAE 332. Guiding value = 10000. 800*)LOGB 40 - 65535 NO OF RECORDS FOR BUFFERING COMMANDS Number of 512 byte records for buffering commands for logging. This represents the record size for the command log file. Size per individual = 260 (16 bit) words. Guiding value: NI = ((ARC/(INT(502/(ACL+3)))- RR)*PKLTP*SF where: NI = Number of individuals ARC = Average rate of loggings (commands/s) INT = 'Integer of' function ACL = Average command length logged



RR = 20 (rate of release of logging ind.) PKLTP = Peak load time period (seconds) SF = 1,5 Safety factor (optional, value>=1) Note: If a negative result is evaluated, default NIs will cope with logging load. Default: A default of 120 ind., for basic operation, exists for very modest command logging loads. A more realistic value should be used depending on the exchange requirements for the logging commands. 801 EXAL0 0 - 65503 NO OF EXTERNAL ALARMS RECEIVERS FOR THE TRI'S The smallest extension or reduction step is 32 (1 Extension Module). Guiding value = (SAE 310)*32. 801*)EXAL2 0 - 65535 EXTERNAL ALARMS RECEIVERS FOR I/O-CONNECTED ALI'S The smallest extension or reduction step is 32 (1 Extension Module). Guiding value = 32 (Not A55). 803 ALSA 0 - 65535 NO OF EXTERNAL ALARM CATCH WORDS Guiding value = (SAE 801 EXAL0) + (SAE 801 EXAL2). 804 ALSA 0 - 65535 NO OF EXTERNAL ALARM RECEIVERS Guiding value = (SAE 801 EXAL0) + (SAE 801 EXAL2). 805*)FIE 0 - 16383 NO OF FILE USERS Number of file users who are using files on FMS through the file interface in PLEX. Guiding value = 128. 805*)DBTAB7 100 - 65032 NUMBER OF TABLE ROWS IN TABLE DBSFCERRORS. Guiding value = 100 806*)ALIM 0 - 65535 NO OF ALARM INTERFACES Number of I/O-connected alarm devices. Guiding value = 10 (Not A55).



806*)DBTAB7 0 - 500 NUMBER OF WORK ROWS IN TABLE DBSFCERRORS. Least extension or reduction stage = 1. Guiding value = 10 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD This size alteration event is dependent on SAE 304. The NI value is not allowed to be less than (SAE 304)*4 + 101. At size alteration, the maximum number of increments step is set to 2048. Guiding value = (SAE 304)*4 + 101. 809*)LAVS 16384 - 65535 NO OF VARIABLES IN THE SYSTEM THAT BELONG TO VARIABLE GROUPS The total number of variables that belong to any Variable Groups defined in the system is indicated. Least extension and reduction step = 1 individual. Guiding value = 16384. 810*)LAVS 512 - 65535 NO OF VARIABLE GROUPS The total number of variable groups defined in the system is indicated. Least extension and reduction step = 1 individual. Guiding value = 1024. 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS The total number of Forlopps is equal to SAE 812 * 1024. That is, using guiding value 6 means max 6*1024 forlopps. Least extension or reduction step = 1. Max extension or reduction step = 1000. Guiding value = 1 + (( SAE913 + SAE500(RMSCS) + SAE500(RTATHT))/1024) + (SAE1153(RXCMOO)/11). 813 MFM 10 - 4194303 NO OF FORLOPP USER-GROUPS The total number of individuals in all forlopps is equal to SAE 813 * 1024. That is, using guiding value 161 means that there is a maximum of 161*1024 individuals. Least extension or reduction step = 1. Max extension or reduction step = 1000. Guiding value = 161 + (SAE550 RXCMSD)/2.



814*)DBCOH 10 - 65535 NO OF TASK INDIVIDUALS FOR DBPOH COMMAND AND PRINTOUT HANDLING FOR DBS Guiding value = 10. 815*)DBTRH 10 - 256 NO OF TASK INDIVIDUALS AT TRANSACTION HANDLING FOR DBS Guiding value = 256. 816*)DBTRH 100 - 1M NO OF ROW LOG INDIVIDUALS Guiding value = 8192. 817*)DBTRH 100 - 1M NO OF FIELD LOG INDIVIDUALS Guiding value = 8192. 888*)LASCS 0 - 200 AREA SIZE FOR SCR FILE LOADING Guiding value = 200.

6 RBS200 (G01) Changes

This chapter is only valid when not using fixed guiding values.

6.1 Transmission Radio Interface (TRI-EMG)

This chapter involves SAEs that have to be changed when a TRI-EM is added. The TRI forms a digital cross connection function which makes it possible to switch the 64 kbit/s time slots on a PCM line to time slots directed to a radio transceiver and vice versa. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below, do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 4 (minimum start value is 101). Change is needed only if the new RP has the highest number. 304 FCRET 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 1. LARP Change is needed only if the RENFD new RP has the highest number. RPADM RPADS RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES



RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 311 CLC 0 - 1024 NO OF STC-STR SIGNALLING LINKS Delta = 2 if redundancy, 1 if not redundancy. 310 CSLDEV 1 - 1024 NO OF EXTENSION MODULE GROUPS CSLLINK Delta = 1. CSLM7 Note that the BSC can only CSLSEMI handle 256 EMGs. CSLSNT EMGADM EMGADS EMGAL EMGDI EMGDU EMGDUD EMGFD EMGREC EMGREP EMGRES FCEET FCEPEX RPROUT 800 TW 0 - 8192 NO OF I/O TERMINALS IN TRI Delta = 1. 302 ADE 16 - 1024 NO OF I/O ALPHANUMERICAL AUE INDIVIDUALS AFP Delta = 1. AICP AOT LOGB OID 801 EXAL0 0 - 65503 NO OF EXTERNAL ALARMS RECEIVERS FOR THE TRI'S Delta = 32. 803 ALSA 0 - 65535 NO OF EXTERNAL ALARM CATCH WORDS Delta = 32. 804 ALSA 0 - 65535 NO OF EXTERNAL ALARM RECEIVERS Delta = 32.

6.2 Transceiver Group (TG)

These SAEs have to be increased when a TG is added. A TG handles functions common to a



number of transceivers. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 RXEABH 0 - 32768 NO OF MANAGED OBJECTS IN THE BTS RXEADE LOGICAL MODEL G01 RXEFH Delta = 2. RXEIFH RXELE RXEPL RXE3EP RXE3OM RXEADB RXELH RXEBL RXESR 813 MFM 10 - 4194303 NO OF FORLOPP USER-GROUPS Delta = 1000, see SAE 813 MFM in chapter 5.2. 550 RXCMSD 0 - 512 NO OF TG MANAGED OBJECTS IN THE BSC Delta = 1.

6.3 Transceiver (TRX)

The following SAEs are affected when a TRX is added in RBS200. For each carrier in a cell a TRXis needed. A TRX contains most of the equipment required to transmit/receive on the carrier. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

When a TRX is removed from RBS200, it is recommended to free the memory allocated for this TRX by decreasing the SAEs below, except for SAE 812. The reduction of SAE 812 is not recommended since it may lead to hanging forlopps. SAE 345, 346, 350 500 and 502 can be reduced using the standard APZ command. SAE 1153 can be reduced only when the processor is separated due to the protection implemented for preventing the decrease of this SAE, while any of the TRXs or their subordinates are in operational mode. Thus, for reducing SAE 1153, separate the processor, execute the reduction in stand-by separated part, and then perform a large restart with configuration.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 345 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 W Delta = 1 (minimum value is 250). 346 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 64 W Delta = 1 (minimum value is 390). 350 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 1 KW



Delta = 1 (minimum value is 51). 500 RXEABH 0 - 16384 NO OF MANAGED OBJECTS IN THE BTS RXEADE LOGICAL MODEL G01 RXEFH Delta = 11. RXEIFH RXELE RXEPL RXE3EP RXE3OM RXEADB RXELH RXEBL RXESR 502 RXE3IM 0 - 2048 NO OF TRXC INDIVIDUALS RXEBVH Delta = 1. RXEFMM RXEFT RXELDF RXELH RXELS RXERPM RXESR RXETGH RXEVU 1153 RBLT 0 - 2048 NO OF TRANCEIVER CONTROLLER RCC (TRXC) INDIVIDUALS. RCCGD RCLCCH Delta = 1. RCSCB RCSI RGPDCH RGRLC RGSI RHLAPD RHLH RHLINK RMHBI RMPAG RMVGCH RNCM RNLC RNLCH RNSDCCH RNTCH ROTRS RQRCQS RQUNC RQUPD RTODCON RTSIGH RTTRINT RXCBM RXCCD RXCCOR RXCDI



RXCLIM RXCLCO RXCLMO RXCMOO RXCMSD 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2.

7 RBS2000 (G12) Changes


If adding an RBS with a platform not used before, an increase of SAE 538 RXOFT might be necessary, see the description of SAE 538 in chapter 5.1.

7.1 Transceiver Group (TG)

These SAEs have to be increased when a TG is added. A TG handles functions common to a number of transceivers. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 345 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 W Delta = 1 (minimum value is 250). 346 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 64 W Delta = 1 (minimum value is 390). 350 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 1 KW Delta = 1 (minimum value is 51). 500 RXOFH 0 - 49653 NO OF MANAGED OBJECTS IN THE BTS RXOIFH LOGICAL MODEL G12 RXOLE Delta = 9. RXOLH RXOPL RXOADE RXOABH RXO3EP RXO3OM RXOADB RXOBL RXOSR 813 MFM 10 - 4194303 NO OF FORLOPP USER-GROUPS



Delta = 1000, see SAE 813 MFM in chapter 5.2. 550 RXCMSD 0 - 512 NO OF TG MANAGED OBJECTS IN THE BSC Delta = 1. 552 RXCMSD 0 - 512 NO OF CF MANAGED OBJECTS IN THE BSC Delta = 1.

7.2 Transceiver (TRX)

The following SAEs are affected when a TRX is added in RBS2000. For each carrier in a cell a TRX is needed. A TRX contains most of the equipment required to transmit/receive on the carrier. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

At increase of the number of TRXs above 2048, the number of parallell TG loads and -upgrades must be limited by setting the BSC exchange properties FCMAXNOPTGLG12 and FCMAXNOPTGUG12 to values greater than 0, not to exceed the size limits of SAE 345, 346 and 350

When a TRX is removed from RBS2000, it is recommended to free the memory allocated for this TRX by decreasing the SAEs below, except for SAE 812. The reduction of SAE 812 is not recommended since it may lead to hanging forlopps. SAE 345, 346, 350, 500 and 502 can be reduced using the standard APZ command. SAE 1153 can be reduced only when the processor is separated due to the protection implemented for preventing the decrease of this SAE, while any of the TRXs or their subordinates are in operational mode. Thus, for reducing SAE 1153, separate the processor, execute the reduction in stand-by separated part, and then perform a large restart with configuration.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 345 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 W Delta = 1 (minimum value is 250). 346 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 64 W Delta = 1 (minimum value is 390). 350 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 1 KW Delta = 1 (minimum value is 51). 500 RXOFH 0 - 49653 NO OF MANAGED OBJECTS IN THE BTS RXOIFH LOGICAL MODEL G12 RXOLE Delta = 11. RXOPL RXOADE RXOABH RXO3EP RXO3OM RXOLH



RXOADB RXOBL RXOSR 502 RTAPH 0 - 4095 NO OF TRXC INDIVIDUALS RTVPH Delta = 1. RXO3IM RXOBVH RXOFMM RXOFT RXOISH RXOLDF RXOLH RXOLS RXORPM RXOSR RXOVU 1153 RBLT 0 - 4095 NO OF TRANCEIVER CONTROLLER RCC (TRXC) INDIVIDUALS. RCCGD RCLCCH Delta = 1. RCSCB RCSI RGPDCH RGRLC RGSI RHLAPD RHLH RHLINK RMHBI RMPAG RMVGCH RNCM RNLC RNLCH RNSDCCH RNTCH ROTRS RQRCQS RQUNC RQUPD RTODCON RTSIGH RTTRINT RXCBM RXCCD RXCCOR RXCDI RXCLCO RXCLIM RXCLMO RXCMOO RXCMSD 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in



chapter 5.2.

8 Changes in the BSC, TRC or BSC/TRC


8.1 Change of Node Type

Figure 1 below shows a possible network configuration with the node types BSC, BSC/TRC, TRC and SGSN and how they are connected via the traffic interfaces A, Abis, Ater and GB. Figure 1 also shows how the RTS interface line terminals ETRALT, ETRTT, ETRTB, ETRBLT, ETRTL and ETRTG are connected, see chapter 8.3 to 8.7.

/-\ ETRTG | +---------------------------------------\ | | | | | /-\ | | /-\ | | | | /-\ ETRALT |T| ETRTT ETRTB |B| ETRBLT | | | +------------+R+----------------+S+--------- | | | | |C| |C| |S| | | | | | | |G| | | \-/ \-/ ETRTL /-\ |S| |M| \------------+S| |N| |S| |M| | | |C| /------------+L| | | | | /-\ ETRTL /+C| | | | | /-\ |B| |\-/ | | | | ETRALT |T| ETRTT ETRTB |S| ETRBLT | | | | +------------+R+----------------+C+--------- | | | \-/ |C| | | | | | ETRTG +-+ \-/ | | +-------------------+B| | | | |S| ETRBLT | \-/ |C+---------------------------- | \-/ | \------------------------------/ ETRTL Fig.1

At change of node type, the SAEs described in chapter 6.2, 6.3, 7.1, 7.2 and 8.2 to 8.16 has to be looked at and changed if needed. In addition, the following SAEs may have to be changed:

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 RMSCS 0 - 16384 NO OF MS INDIVIDUALS Guiding value = 2000 for BSC and BSC/TRC. = 0 for TRC. 533 ROBAR 0 - 65534 NO OF GSM TEST FREQUENCY INDIVIDUALS



IN ACTIVE BA-LIST RECORDING Guiding value = 32768 for BSC and BSC/TRC. = 0 for TRC. 534 ROBAR 0 - 131072 NO OF TEST UMTS MEASUREMENT FREQUENCY INFORMATION (TUMFI) INDIVIDUALS Guiding value = 65536 for BSC and BSC/TRC. = 0 for TRC. 538 RXEFT 0 - 218834 NO OF FILE SEGMENTS AT SW FILE STORAGE FOR BTS LOGICAL MODEL G01 Guiding Value for BSC and BSC/TRC = (BTS SW 1 volume + BTS SW 2 volume)/230. Guiding value for TRC = 0. 538 RXOFT 0 - 218834 NO OF FILE SEGMENTS AT SW FILE STORAGE FOR BTS LOGICAL MODEL G12 Guiding Value for BSC and BSC/TRC = (BTS SW 1 volume + BTS SW 2 volume)/230. Guiding value for TRC = 0.

8.2 ET155 Line Terminal

8.2.1 ET155-7 Line Terminal

This chapter describes which SAEs that are affected when an ET155-7 line terminal is added. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD



RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 087 TRAN1 0 - 65535 NO OF DIGITAL PATHS Delta = 63. 515 SDIPQ 0 - 1024 NO OF SDIP INDIVIDUALS Delta = 1. 515 SDIPM1 0 - 1024 NO OF SDIP INDIVIDUALS Delta = 1. 515 DIPM1 0 - 64512 NO OF DIGITAL PATHS Delta = 63. 529 ETM1 0 - 1024 NO OF ETM1 SNT INDIVIDUALS Delta = 1. 500 SDIPHID 0 - 1024 NO OF HID INDIVIDUALS Delta = 1. 500 DIPHM1 0 - 64512 NO OF HID INDIVIDUALS Delta = 63.

8.2.2 ET155-1 Line Terminal (32 PCM)

This chapter describes which SAEs that are affected when an ET155-1 line terminal for 32 channel PCM system is added. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2.



LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 087 TRAN1 0 - 65535 NO OF DIGITAL PATHS Delta = 63. 515 SDIPQM2 0 - 704 NO OF SDIP INDIVIDUALS Delta = 1. 515 SDIPM2 0 - 704 NO OF SDIP INDIVIDUALS Delta = 1. 515 DIPM2 0 - 44352 NO OF DIGITAL PATHS Delta = 63. 529 ETM2 0 - 704 NO OF ETM2 SNT INDIVIDUALS Delta = 1. 500 SDIPHM2 0 - 704 NO OF HID INDIVIDUALS Delta = 1. 500 DIPHM2 0 - 44352 NO OF HID INDIVIDUALS Delta = 63.

8.2.3 ET155-1 Line Terminal (24 PCM)

This chapter describes which SAEs that are affected when an ET155-1 line terminal for 24 channel PCM system is added. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD



Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 087 TRAN1 0 - 65535 NO OF DIGITAL PATHS Delta = 84. 515 SDIPQM3 0 - 704 NO OF SDIP INDIVIDUALS Delta = 1. 515 SDIPM3 0 - 704 NO OF SDIP INDIVIDUALS Delta = 1. 515 DIPM3 0 - 59136 NO OF DIGITAL PATHS Delta = 84. 529 ETM3 0 - 704 NO OF ETM3 SNT INDIVIDUALS Delta = 1. 500 DIPHM3 0 - 59136 NO OF HID INDIVIDUALS Delta = 84. 515 SDIPAM3 0 - 704 NO OF SDIP INDIVIDUALS Delta = 1. 515 SDIPFM3 0 - 704 NO OF SDIP INDIVIDUALS Delta = 1.

8.3 RTS A-Interface Line Terminal in BSC/TRC or TRC



8.3.1 ETRALT/ETRALT4

These SAEs are affected when an RTS A-interface Line Terminal is added. RALT is the functional software for ordinary ETCs for the interface function towards the MSC. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 087 TRAN1 0 - 65535 NO OF DIGITAL PATHS Delta = 1. 500 RTTPR 0 - 16384 NO OF TRANSMISSION INDIVIDUALS Delta = 32 (RALT) 24 (RALT24) 515 DIPRALT 0 - 2048 NO OF DIGITAL PATHS DIPRAT4 0 - 2048 24 channels SNT. Delta = 1.



529 ETRALT 0 - 2048 NO OF ETRALT SNT INDIVIDUALS ETRALT4 0 - 2046 24 channels SNT. Delta = 1. 500 RALT 0 - 65504 NO OF DEVICES ON A-INTERFACE RALT24 0 - 65520 Delta = 32 (RALT) 24 (RALT24) 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used: Delta = 32 (RALT) 24 (RALT24) Delta = 0 if ANSI CCS7 is used. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = 32 (RALT) 24 (RALT24) Delta = 0 if CCITT CCS7 is used. 500 HIDRALT 0 - 2047 NO OF HID INDIVIDUALS Delta = 1. 500 RABDI 0 - 32768 NO OF SIGNALLING CONNECTION RABDIAN INDIVIDUALS Delta for BSC/TRC, own RALT/RALT24 = 32 (RALT) 24 (RALT24) Delta for BSC/TRC, external RALT/RALT24 = 0. Delta for TRC = 0. 913 RGCON 0 - 32768 NO OF MS INDIVIDUALS RGRLC RGSERV Delta for BSC/TRC, own RMASHO RALT/RALT24 = RMASS 32 (RALT) RMCASS 24 (RALT24) RMCC RMCCHM Delta for BSC/TRC, external RMCHO RALT/RALT24 = 0. RMCIPH Delta for TRC = 0. RMCR RMDTM RMHBI RMHOAC RMHOEB RMHOEC RMHTR RMPH RMPOS RMQ



RMRLS RMTRE RMVGASS RMVGCH RNLCT RODCR RQRCQS 1161 GCCC 0 - 16384 NO GAN SESSION INDIVIDUALS GCMSGH One individual is needed for each GCASS active GAN signalling connection GCHO between Mobile Station (MS) and GCPOS Mobile Switching Centre (MSC) Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC. 1162 RMHAIDL 0 - 32768 NUMBER OF HAI INDIVIDUALS RMHAIUL One individual is needed for each Signalling Connection Control (SCCP) connection. Note! If the calculated number of individuals exceeds the maximum value, the SAE must be set to its maximum size. Guiding value = (SAE1161)+(SAE913) for BSC and BSC/TRC = 1 for TRC 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2.

8.3.2 ETRALT5

These SAEs are affected when one 2 Mb/s digital path using ET155-7 is added to the A-interface. ETRALT5 is the functional software for digital paths using ET155 for the A-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 RTTPR 0 - 16384 NO OF TRANSMISSION INDIVIDUALS Delta = 32 500 ETRALT5 0 - 131072 NO OF DEVICE INDIVIDUALS Delta = 32. 500 RALT15 0 - 65504 NO OF DEVICES ON A-INTERFACE Delta = 32. 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used:



Delta = 32. Delta = 0 if ANSI CCS7 is used. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = 32. Delta = 0 if CCITT CCS7 is used. 500 RABDI 0 - 32768 NO OF SIGNALLING CONNECTION RABDIAN INDIVIDUALS Delta for BSC/TRC, own RALT15 = 32. Delta for BSC/TRC, external RALT15 = 0. Delta for BSC/TRC and TRC = 0. 913 RGCON 0 - 32768 NO OF MS INDIVIDUALS RGRLC RGSERV Delta for BSC/TRC, own RMASHO RALT15 = 32. RMASS Delta for BSC/TRC, external RMCASS RALT15 = 0. RMCC Delta for TRC = 0. RMCCHM RMCHO RMCIPH RMCR RMDTM RMHBI RMHOAC RMHOEB RMHOEC RMHTR RMPH RMPOS RMQ RMRLS RMTRE RMVGASS RMVGCH RNLCT RODCR RQRCQS 1161 GCCC 0 - 16384 NO GAN SESSION INDIVIDUALS GCMSGH One individual is needed for each GCASS active GAN signalling connection GCHO between Mobile Station (MS) and GCPOS Mobile Switching Centre (MSC) Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC. 1162 RMHAIDL 0 - 32768 NUMBER OF HAI INDIVIDUALS RMHAIUL One individual is needed for each



Signalling Connection Control (SCCP) connection. Note! If the calculated number of individuals exceeds the maximum value, the SAE must be set to its maximum size. Guiding value = (SAE1161)+(SAE913) for BSC and BSC/TRC = 1 for TRC 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2.

8.3.3 ETRALT2

These SAEs are affected when one 2 Mb/s digital path using ET155-1 is added to the A-interface. ETRALT2 is the functional software for digital paths using ET155-1 for the A-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 RTTPR 0 - 16384 NO OF TRANSMISSION INDIVIDUALS Delta = 32 500 ETRALT2 0 - 1048576 NO OF DEVICE INDIVIDUALS Delta = 32. 500 RALT2 0 - 65504 NO OF DEVICES ON A-INTERFACE Delta = 32. 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used: Delta = 32. Delta = 0 if CCITT is used. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = 32. Delta = 0 if CCITT CCS7 is used. 500 RABDI 0 - 32768 NO OF SIGNALLING CONNECTION RABDIAN INDIVIDUALS Delta for BSC/TRC, own RALT2 = 32. Delta for BSC/TRC, external RALT2 = 0. Delta for BSC/TRC and TRC = 0. 913 RGCON 0 - 32768 NO OF MS INDIVIDUALS RGRLC RGSERV Delta for BSC/TRC, own RMASHO RALT2 = 32. RMASS Delta for BSC/TRC, external



RMCASS RALT2 = 0. RMCC Delta for TRC = 0. RMCCHM RMCHO RMCIPH RMCR RMDTM RMHBI RMHOAC RMHOEB RMHOEC RMHTR RMPH RMPOS RMQ RMRLS RMTRE RMVGASS RMVGCH RNLCT RODCR RQRCQS 1161 GCCC 0 - 16384 NO GAN SESSION INDIVIDUALS GCMSGH One individual is needed for each GCASS active GAN signalling connection GCHO between Mobile Station (MS) and GCPOS Mobile Switching Centre (MSC) Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC. 1162 RMHAIDL 0 - 32768 NUMBER OF HAI INDIVIDUALS RMHAIUL One individual is needed for each Signalling Connection Control (SCCP) connection. Note! If the calculated number of individuals exceeds the maximum value, the SAE must be set to its maximum size. Guiding value = (SAE1161)+(SAE913) for BSC and BSC/TRC = 1 for TRC 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2.

8.3.4 ETRALT3

These SAEs are affected when one 1544 kb/s digital path using ET155-1 is added to the A-interface. ETRALT3 is the functional software for digital paths using ET155-1 for the A-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints



---------------------------------------------------------- 500 RTTPR 0 - 16384 NO OF TRANSMISSION INDIVIDUALS Delta = 24 500 ETRALT3 0 - 1048560 NO OF DEVICE INDIVIDUALS Delta = 24. 500 RALT3 0 - 65520 NO OF DEVICES ON A-INTERFACE Delta = 24. 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used: Delta = 24. Delta = 0 if CCITT is used. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = 24. Delta = 0 if CCITT CCS7 is used. 500 RABDI 0 - 32768 NO OF SIGNALLING CONNECTION RABDIAN INDIVIDUALS Delta for BSC/TRC, own RALT3 = 24. Delta for BSC/TRC, external RALT3 = 0. Delta for BSC/TRC and TRC = 0. 913 RGCON 0 - 32768 NO OF MS INDIVIDUALS RGRLC RGSERV Delta for BSC/TRC, own RMASHO RALT3 = 32. RMASS Delta for BSC/TRC, external RMCASS RALT3 = 0. RMCC Delta for TRC = 0. RMCCHM RMCHO RMCIPH RMCR RMDTM RMHBI RMHOAC RMHOEB RMHOEC RMHTR RMPH RMPOS RMQ RMRLS RMTRE RMVGASS RMVGCH RNLCT RODCR RQRCQS



1161 GCCC 0 - 16384 NO GAN SESSION INDIVIDUALS GCMSGH One individual is needed for each GCASS active GAN signalling connection GCHO between Mobile Station (MS) and GCPOS Mobile Switching Centre (MSC) Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC. 1162 RMHAIDL 0 - 32768 NUMBER OF HAI INDIVIDUALS RMHAIUL One individual is needed for each Signalling Connection Control (SCCP) connection. Note! If the calculated number of individuals exceeds the maximum value, the SAE must be set to its maximum size. Guiding value = (SAE1161)+(SAE913) for BSC and BSC/TRC = 1 for TRC 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2.

8.4 RTS Abis-Interface Line Terminal in BSC or BSC/TRC

8.4.1 ETRBLT/ETRBLT4

These SAEs are affected when an RTS Abis-interface Line Terminal is added. RTS Abis-interface Line Terminal is the functional software for ordinary ETCs devices needed for the physical connection towards the RBS. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of new RPs has the highest RP RPADS number. RPAL RPDI



RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 087 TRAN1 0 - 65535 NO OF DIGITAL PATHS Delta = 1. 515 DIPRBLT 0 - 2048 NO OF DIGITAL PATHS DIPRBT4 0 - 2048 24 channels SNT. Delta = 1. 529 ETRBLT 0 - 2048 NO OF ETRBLT SNT INDIVIDUALS ETRBLT4 0 - 2046 24 channels SNT. Delta = 1. 500 RBLT 0 - 65504 NO OF DEVICES ON ABIS-INTERFACE RBLT24 0 - 65520 Delta = 32 (RBLT) 24 (RBLT24) 500 HIDRBLT 0 - 2047 NO OF HID INDIVIDUALS Delta = 1.

8.4.2 ETRBLT5

These SAEs are affected when one 2 Mb/s digital path using ET155-7 is added to the Abis-interface. ETRBLT5 is the functional software for digital paths using ET155-7 for the Abis-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRBLT5 0 - 131072 NO OF DEVICE INDIVIDUALS Delta = 32. 500 RBLT15 0 - 65504 NO OF DEVICES ON ABIS-INTERFACE Delta = 32.

8.4.3 ETRBLT2



These SAEs are affected when one 2 Mb/s digital path using ET155-1 is added to the Abis-interface. ETRBLT2 is the functional software for digital paths using ET155-1 for the Abis-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Rang Description and Hints ---------------------------------------------------------- 500 ETRBLT2 0 - 1048576 NO OF DEVICE INDIVIDUALS Delta = 32. 500 RBLT2 0 - 65504 NO OF DEVICES ON ABIS-INTERFACE Delta = 32.

8.4.4 ETRBLT3

These SAEs are affected when one 1544 kb/s digital path using ET155-1 is added to the Abis-interface. ETRBLT3 is the functional software for digital paths using ET155-1 for the Abis-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRBLT3 0 - 1048560 NO OF DEVICE INDIVIDUALS Delta = 24. 500 RBLT3 0 - 65520 NO OF DEVICES ON ABIS-INTERFACE Delta = 24.

8.5 RTS Ater-Interface Line Terminal in BSC/TRC or TRC

8.5.1 ETRTT/ETRTT4

These SAEs are affected when an RTS Ater-interface Line Terminal is added. RTS Ater-interface Line Terminal is the functional software for ordinary ETCs devices needed in the TRC or combined BSC/TRC for the physical connection towards external BSC. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest



RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 087 TRAN1 0 - 65535 NO OF DIGITAL PATHS Delta = 1. 515 DIPRTT 0 - 2048 NO OF DIGITAL PATHS DIPRTT4 0 - 2048 24 channels SNT. Delta = 1. 529 ETRTT 0 - 2048 NO OF ETRTT SNT INDIVIDUALS ETRTT4 0 - 2046 24 channels SNT. Delta = 1. 500 RTLTT 0 - 65504 NO OF DEVICES ON ATER-INTERFACE RTLTT24 0 - 65520 IN TRC Delta = 32 (RTLTT) 24 (RTLTT24) 500 HIDRTT 0 - 2047 NO OF HID INDIVIDUALS Delta = 1. 500 RTATHT 0 - 16384 NO OF INDIVIDUALS IN THE TRC CALL INDIVIDUAL FILE Delta = X * 32 (RTLTT) X * 24 (RTLTT24) see note below. 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2. 500 RTBTAP 0 - 32768 NO OF INDIVIDUALS IN SC RTBTAPA INDIVIDUAL FILE Delta = X * 32 (RTLTT) X * 24 (RTLTT24) see note below.



Note:X=4 if full rate only is used. X=8 if half rate only is used. X is between 4 and 8 for a mix of half rate and full rate. For example, X=6 at 50% of each speech codec type.

8.5.2 ETRTT5

These SAEs are affected when one 2 Mb/s digital path using ET155-7 is added to the Ater-interface. ETRTT5 is the functional software for digital paths using ET155-7 for the Ater-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRTT5 0 - 131072 NO OF DEVICE INDIVIDUALS Delta = 32. 500 RTLTT15 0 - 65504 NO OF DEVICES ON ATER-INTERFACE IN TRC Delta = 32. 500 RTATHT 0 - 16384 NO OF INDIVIDUALS IN THE TRC CALL INDIVIDUAL FILE Delta = X * 32 see note below. 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2. 500 RTBTAP 0 - 32768 NO OF INDIVIDUALS IN SC RTBTAPA INDIVIDUAL FILE Delta = X * 32 see note below. Note:X=4 if full rate only is used. X=8 if half rate only is used. X is between 4 and 8 for a mix of half rate and full rate. For example, X=6 at 50% of each speech codec type.

8.5.3 ETRTT2

These SAEs are affected when one 2 Mb/s digital path using ET155-1 is added to the Ater-interface. ETRTT2 is the functional software for digital paths using ET155-1 for the Ater-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRTT2 0 - 1048576 NO OF DEVICE INDIVIDUALS Delta = 32. 500 RTLTT2 0 - 65504 NO OF DEVICES ON ATER-INTERFACE IN TRC



Delta = 32. 500 RTATHT 0 - 16384 NO OF INDIVIDUALS IN THE TRC CALL INDIVIDUAL FILE Delta = X * 32 see note below. 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2. 500 RTBTAP 0 - 32768 NO OF INDIVIDUALS IN SC RTBTAPA INDIVIDUAL FILE Delta = X * 32 see note below. Note:X=4 if full rate only is used. X=8 if half rate only is used. X is between 4 and 8 for a mix of half rate and full rate. For example, X=6 at 50% of each speech codec type.

8.5.4 ETRTT3

These SAEs are affected when one 1544 kb/s digital path using ET155-1 is added to the Ater-interface. ETRTT3 is the functional software for digital paths using ET155-1 for the Ater-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRTT3 0 - 1048560 NO OF DEVICE INDIVIDUALS Delta = 24. 500 RTLTT3 0 - 65520 NO OF DEVICES ON ATER-INTERFACE IN TRC Delta = 24. 500 RTATHT 0 - 16384 NO OF INDIVIDUALS IN THE TRC CALL INDIVIDUAL FILE Delta = X * 24 see note below. 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2. 500 RTBTAP 0 - 32768 NO OF INDIVIDUALS IN SC RTBTAPA INDIVIDUAL FILE Delta = X * 24 see note below. Note:X=4 if full rate only is used. X=8 if half rate only is used. X is between 4 and 8 for a mix of half rate and full rate. For example, X=6 at 50% of each speech codec type.



8.6 RTS Ater-Interface Line Terminal in BSC

8.6.1 ETRTB/ETRTB4

These SAEs are affected when an RTS Ater-interface Line Terminal is added. RTS Ater-interface Line Terminal is the functional software for ordinary ETCs devices needed in the BSC for the physical connection towards external TRC or combined BSC/TRC. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 087 TRAN1 0 - 65535 NO OF DIGITAL PATHS Delta = 1. 515 DIPRTB 0 - 2048 NO OF DIGITAL PATHS DIPRTB4 0 - 2048 24 channels SNT. Delta = 1. 529 ETRTB 0 - 2048 NO OF ETRTB SNT INDIVIDUALS



ETRTB4 0 - 2046 24 channels SNT. Delta = 1. 500 RTLTB 0 - 65504 NO OF DEVICES ON ATER-INTERFACE RTLTB24 0 - 65520 IN BSC Delta = 32 (RTLTB) 24 (RTLTB24) 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used: Delta = X * 2 * 32 (RTLTB) X * 2 * 24 (RTLTB24) Delta = 0 if ANSI CCS7 is used. See note below. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = X * 2 * 32 (RTLTB) X * 2 * 24 (RTLTB24) Delta = 0 if CCITT CCS7 is used. See note below. 500 HIDRTB 0 - 2047 NO OF HID INDIVIDUALS Delta = 1. 500 RABDI 0 - 32768 NO OF SIGNALLING CONNECTION RABDIAN INDIVIDUALS Delta = X * 32 (RTLTB) X * 24 (RTLTB24) See note below. 500 RTATHB 0 - 16384 NO OF INDIVIDUALS IN THE BSC CALL INDIVIDUAL FILE Delta = X * 32 (RTLTB) X * 24 (RTLTB24) See note below. 500 RTBTAP 0 - 32768 NO OF INDIVIDUALS IN SC RTBTAPA INDIVIDUAL FILE Delta = X * 32 (RTLTB) X * 24 (RTLTB24) See note below. 913 RGCON 0-32768 NO OF MS INDIVIDUALS RGRLC RGSERV Delta = X * 32 (RTLTB) RMASHO X * 24 (RTLTB24) RMASS See note below. RMCASS RMCC RMCCHM RMCHO RMCIPH RMCR RMDTM RMHBI



RMHOAC RMHOEB RMHOEC RMHTR RMPH RMPOS RMQ RMRLS RMTRE RMVGASS RMVGCH RNLCT RODCR RQRCQS 1161 GCCC 0 - 16384 NO GAN SESSION INDIVIDUALS GCMSGH One individual is needed for each GCASS active GAN signalling connection GCHO between Mobile Station (MS) and GCPOS Mobile Switching Centre (MSC) Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC. 1162 RMHAIDL 0 - 32768 NUMBER OF HAI INDIVIDUALS RMHAIUL One individual is needed for each Signalling Connection Control (SCCP) connection. Note! If the calculated number of individuals exceeds the maximum value, the SAE must be set to its maximum size. Guiding value = (SAE1161)+(SAE913) for BSC and BSC/TRC = 1 for TRC 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2. Note:X=4 if full rate only is used. X=8 if half rate only is used. X is between 4 and 8 for a mix of half rate and full rate. For example, X=6 at 50% of each speech codec type.

8.6.2 ETRTB5

These SAEs are affected when one 2 Mb/s digital path using ET155-7 is added to the Ater-interface. ETRTB5 is the functional software for digital paths using ET155-7 for the Ater-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRTB5 0 - 131072 NO OF DEVICE INDIVIDUALS



Delta = 32. 500 RTLTB15 0 - 65504 NO OF DEVICES ON ATER-INTERFACE IN BSC Delta = 32. 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used: Delta = X * 2 * 32 Delta = 0 if ANSI CCS7 is used. See note below. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = X * 2 * 32 Delta = 0 if CCITT CCS7 is used. See note below. 500 RABDI 0 - 32768 NO OF SIGNALLING CONNECTION RABDIAN INDIVIDUALS Delta = X * 32 See note below. 500 RTATHB 0 - 16384 NO OF INDIVIDUALS IN THE BSC CALL INDIVIDUAL FILE Delta = X * 32 See note below. 500 RTBTAP 0 - 32768 NO OF INDIVIDUALS IN SC RTBTAPA INDIVIDUAL FILE Delta = X * 32 See note below. 913 RGCON 0-32768 NO OF MS INDIVIDUALS RGRLC RGSERV Delta = X * 32 RMASHO See note below. RMASS RMCASS RMCC RMCCHM RMCHO RMCIPH RMCR RMDTM RMHBI RMHOAC RMHOEB RMHOEC RMHTR RMPH RMPOS RMQ RMRLS RMTRE RMVGASS



RMVGCH RNLCT RODCR RQRCQS 1161 GCCC 0 - 16384 NO GAN SESSION INDIVIDUALS GCMSGH One individual is needed for each GCASS active GAN signalling connection GCHO between Mobile Station (MS) and GCPOS Mobile Switching Centre (MSC) Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC. 1162 RMHAIDL 0 - 32768 NUMBER OF HAI INDIVIDUALS RMHAIUL One individual is needed for each Signalling Connection Control (SCCP) connection. Note! If the calculated number of individuals exceeds the maximum value, the SAE must be set to its maximum size. Guiding value = (SAE1161)+(SAE913) for BSC and BSC/TRC = 1 for TRC 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2. Note:X=4 if full rate only is used. X=8 if half rate only is used. X is between 4 and 8 for a mix of half rate and full rate. For example, X=6 at 50% of each speech codec type.

8.6.3 ETRTB2

These SAEs are affected when one 2 Mb/s digital path using ET155-1 is added to the Ater-interface. ETRTB2 is the functional software for digital paths using ET155-1 for the Ater-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints --------------------------------------------------------- 500 ETRTB2 0 - 1048576 NO OF DEVICE INDIVIDUALS Delta = 32. 500 RTLTB2 0 - 65504 NO OF DEVICES ON ATER-INTERFACE IN BSC Delta = 32. 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used:



Delta = X * 2 * 32 Delta = 0 if ANSI CCS7 is used. See note below. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = X * 2 * 32 Delta = 0 if CCITT CCS7 is used. See note below. 500 RABDI 0 - 32768 NO OF SIGNALLING CONNECTION RABDIAN INDIVIDUALS Delta = X * 32 See note below. 500 RTATHB 0 - 16384 NO OF INDIVIDUALS IN THE BSC CALL INDIVIDUAL FILE Delta = X * 32 See note below. 500 RTBTAP 0 - 32768 NO OF INDIVIDUALS IN SC RTBTAPA INDIVIDUAL FILE Delta = X * 32 See note below. 913 RGCON 0-32768 NO OF MS INDIVIDUALS RGRLC RGSERV Delta = X * 32 RMASHO See note below. RMASS RMCASS RMCC RMCCHM RMCHO RMCIPH RMCR RMDTM RMHBI RMHOAC RMHOEB RMHOEC RMHTR RMPH RMPOS RMQ RMRLS RMTRE RMVGASS RMVGCH RNLCT RODCR RQRCQS 1161 GCCC 0 - 16384 NO GAN SESSION INDIVIDUALS GCMSGH One individual is needed for each GCASS active GAN signalling connection GCHO between Mobile Station (MS) and



GCPOS Mobile Switching Centre (MSC) Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC. 1162 RMHAIDL 0 - 32768 NUMBER OF HAI INDIVIDUALS RMHAIUL One individual is needed for each Signalling Connection Control (SCCP) connection. Note! If the calculated number of individuals exceeds the maximum value, the SAE must be set to its maximum size. Guiding value = (SAE1161)+(SAE913) for BSC and BSC/TRC = 1 for TRC 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2. Note:X=4 if full rate only is used. X=8 if half rate only is used. X is between 4 and 8 for a mix of half rate and full rate. For example, X=6 at 50% of each speech codec type.

8.6.4 ETRTB3

These SAEs are affected when one 1544 kb/s digital path using ET155-1 is added to the Ater-interface. ETRTB3 is the functional software for digital paths using ET155-1 for the Ater-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRTB3 0 - 1048560 NO OF DEVICE INDIVIDUALS Delta = 24. 500 RTLTB3 0 - 65520 NO OF DEVICES ON ATER-INTERFACE IN BSC Delta = 24. 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used: Delta = X * 2 * 24 Delta = 0 if ANSI CCS7 is used. See note below. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = X * 2 * 24 Delta = 0 if CCITT CCS7 is used.



See note below. 500 RABDI 0 - 32768 NO OF SIGNALLING CONNECTION RABDIAN INDIVIDUALS Delta = X * 24 See note below. 500 RTATHB 0 - 16384 NO OF INDIVIDUALS IN THE BSC CALL INDIVIDUAL FILE Delta = X * 24 See note below. 500 RTBTAP 0 - 32768 NO OF INDIVIDUALS IN SC RTBTAPA INDIVIDUAL FILE Delta = X * 24 See note below. 913 RGCON 0 - 32768 NO OF MS INDIVIDUALS RGRLC RGSERV Delta = X * 24 RMASHO See note below. RMASS RMCASS RMCC RMCCHM RMCHO RMCIPH RMCR RMDTM RMHBI RMHOAC RMHOEB RMHOEC RMHTR RMPH RMPOS RMQ RMRLS RMTRE RMVGASS RMVGCH RNLCT RODCR RQRCQS 1161 GCCC 0 - 16384 NO GAN SESSION INDIVIDUALS GCMSGH One individual is needed for each GCASS active GAN signalling connection GCHO between Mobile Station (MS) and GCPOS Mobile Switching Centre (MSC) Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC. 1162 RMHAIDL 0 - 32768 NUMBER OF HAI INDIVIDUALS RMHAIUL One individual is needed for each



Signalling Connection Control (SCCP) connection. Note! If the calculated number of individuals exceeds the maximum value, the SAE must be set to its maximum size. Guiding value = (SAE1161)+(SAE913) for BSC and BSC/TRC = 1 for TRC 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2. Note:X=4 if full rate only is used. X=8 if half rate only is used. X is between 4 and 8 for a mix of half rate and full rate. For example, X=6 at 50% of each speech codec type.

8.7 RTS GB-Interface Line Terminal in BSC/TRC or BSC

8.7.1 ETRTG/ETRTG4

These SAEs are affected when an RTS GB-interface Line Terminal is added. RTGLT is the functional software for ordinary ETCs for the interface function towards the SGSN. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT



1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 087 TRAN1 0 - 65535 NO OF DIGITAL PATHS Delta = 1. 515 DIPRTG 0 - 2048 NO OF DIGITAL PATHS DIPRTG4 0 - 2048 24 channels SNT. Delta = = 1. 529 ETRTG 0 - 2048 NO OF ETRTG SNT INDIVIDUALS ETRTG4 0 - 2046 24 channels SNT. Delta = 1. 500 RTGLT 0 - 65504 NO OF DEVICES ON GB-INTERFACE RTGLT24 0 - 65520 Delta = 32 (RTGLT) 24 (RTGLT24) 500 HIDRTG 0 - 2047 NO OF HID INDIVIDUALS Delta = 1.

8.7.2 ETRTG5

These SAEs are affected when one 2 Mb/s digital path using ET155-7 is added to the RTS GB-interface. ETRTG5 is the functional software for digital paths using ET155-7 for the RTS GB-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRTG5 0 - 131072 NO OF DEVICE INDIVIDUALS Delta = 32. 500 RTGLT15 0 - 65504 NO OF RTGLT DEVICES Delta = 32.

8.7.3 ETRTG2

These SAEs are affected when one 2 Mb/s digital path using ET155-1 is added to the RTS GB-interface. ETRTG2 is the functional software for digital paths using ET155-1 for the RTS GB-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRTG2 0 - 1048576 NO OF DEVICE INDIVIDUALS Delta = 32.



500 RTGLT2 0 - 65504 NO OF RTGLT DEVICES Delta = 32.

8.7.4 ETRTG3

These SAEs are affected when one 1554 kb/s digital path using ET155-1 is added to the RTS GB-interface. ETRTG3 is the functional software for digital paths using ET155-1 for the RTS GB-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRTG3 0 - 1048560 NO OF DEVICE INDIVIDUALS Delta = 24. 500 RTGLT3 0 - 65520 NO OF RTGLT DEVICES Delta = 24.

8.8 RTS Lb-Interface Line Terminal in BSC

8.8.1 ETRTL/ETRTL4

These SAEs are affected when an RTS Lb-interface Line Terminal is added. RTLBT is the functional software for ordinary ETCs for the interface function towards the SMLC. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT



1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 087 TRAN1 0 - 65535 NO OF DIGITAL PATHS Delta = 1. 515 DIPRTL 0 - 2048 NO OF DIGITAL PATHS DIPRTL4 0 - 2048 24 channels SNT. Delta = 1. 529 ETRTL 0 - 2048 NO OF ETRTL SNT INDIVIDUALS ETRTL4 0 - 2046 24 channels SNT. Delta = 1. 500 RTLBT 0 - 65504 NO OF DEVICES ON LB-INTERFACE RTLBT24 0 - 65520 Delta = 32 (RTLBT) 24 (RTLBT24) 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used: Delta = 32 (RTLBT) 24 (RTLBT24) Delta = 0 if ANSI CCS7 is used. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = 32 (RTLBT) 24 (RTLBT24) Delta = 0 if CCITT CCS7 is used. 500 HIDRTL 0 - 2047 NO OF HID INDIVIDUALS Delta = 1. 500 RTBLE 0 - 16384 NO OF SIGNALLING CONNECTION RTBLEAN INDIVIDUALS SAE value for BSC and BSC/TRC = 2000, if Lb-interface is in use. SAE value for TRC = 0

8.8.2 ETRTL5

These SAEs are affected when one 2 Mb/s digital path using ET155-7 is added to the Lb-interface. ETRTL5 is the functional software for digital paths using ET155 for the Lb-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ----------------------------------------------------------



500 ETRTL5 0 - 131072 NO OF DEVICE INDIVIDUALS Delta = 32. 500 RTLBT15 0 - 65504 NO OF DEVICES ON LB-INTERFACE Delta = 32. 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used: Delta = 32. Delta = 0 if ANSI CCS7 is used. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = 32. Delta = 0 if CCITT CCS7 is used. 500 RTBLE 0 - 16384 NO OF SIGNALLING CONNECTION RTBLEAN INDIVIDUALS SAE value for BSC and BSC/TRC = 2000, if Lb-interface is in use. SAE value for TRC = 0

8.8.3 ETRTL2

These SAEs are affected when one 2 Mb/s digital path using ET155-1 is added to the Lb-interface. ETRTL5 is the functional software for digital paths using ET155-1 for the Lb-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRTL2 0 - 131072 NO OF DEVICE INDIVIDUALS Delta = 32. 500 RTLBT2 0 - 65504 NO OF DEVICES ON LB-INTERFACE Delta = 32. 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used: Delta = 32. Delta = 0 if ANSI CCS7 is used. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = 32. Delta = 0 if CCITT CCS7 is used. 500 RTBLE 0 - 16384 NO OF SIGNALLING CONNECTION RTBLEAN INDIVIDUALS SAE value for BSC and BSC/TRC = 2000, if Lb-interface is in



use. SAE value for TRC = 0

8.8.4 ETRTL3

These SAEs are affected when one 1544 kb/s digital path using ET155-1 is added to the Lb-interface. ETRTL3 is the functional software for digital paths using ET155-1 for the Lb-interface. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 ETRTL3 0 - 1048560 NO OF DEVICE INDIVIDUALS Delta = 24. 500 RTLBT3 0 - 65520 NO OF DEVICES ON LB-INTERFACE Delta = 24. 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS If CCITT CCS7 is used: Delta = 24. Delta = 0 if ANSI CCS7 is used. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS If ANSI CCS7 is used: Delta = 24. Delta = 0 if CCITT CCS7 is used. 500 RTBLE 0 - 16384 NO OF SIGNALLING CONNECTION RTBLEAN INDIVIDUALS SAE value for BSC and BSC/TRC = 2000, if Lb-interface is in use. SAE value for TRC = 0

8.9 Transceiver Handler in BSC or BSC/TRC

These SAEs are affected when a Transceiver Handler is added. The main purpose of the Transceiver Handler (TRH) is to maintain a resource in BSC and BSC/TRC for LAPD signalling from BSC to the transceivers in the BTS. All TRHs are connected to the group switch. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 4 (minimum start value is 101). Change is needed only if the new RP has the highest number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS



FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 1. Change is needed only if the new RP has the highest number and is connected to RPB-S. 1158 RCLCCH 2 - 256 NUMBER OF TRANSCEIVER RCSCB HANDLER INDIVIDUALS RHDEV This SAE corresponds to the number of RHLAPD TRH Regional Processors. RHLH Delta = 1. RHSNT RHTRH RMPAG RQRCQS RQUNC RQUPD

8.10 GPRS Packet Handler in BSC or BSC/TRC

The GPRS Packet Handler (GPH) is the RP part of the Packet Control Unit (PCU) in the BSC. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 4 (minimum start value is 101). Change is needed only if the new RP has the highest number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest



RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 1. Change is needed only if the new RP has the highest number and is connected to RPB-S. 500 RTGPHDV 1-128 NO OF GPH DEVICES This SAE corresponds to the number of GPH Regional Processors. Delta = 1.

8.11 Transcoder and Rate Adaptation Unit in BSC/TRC or TRC

These SAEs are affected when a Transcoder and Rate Adaptation Unit is added. The Transcoder and Rate Adaptation Unit (TRAU) in BSC performs transcoding of speech information and rate adaptation of data information. It also contains functions for Discontinuous Transmission. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD



RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 995 RTTF1S1 0 - 683 NO OF RTTF1S1/RTTF1D1 SNT RTTF1D1 INDIVIDUALS Blocks dedicated for TRA R5 Full Rate. Delta = 1. One SNT handles 24 transcoder resources (DEMUX). 996 RTTF1S2 0 - 683 NO OF RTTF1S2/RTTF1D2 SNT RTTF1D2 INDIVIDUALS Blocks dedicated for TRA R5 Enhanced Full Rate. Delta = 1. One SNT handles 24 transcoder resources (DEMUX). 1047 RTTH1D 0 - 683 NO OF RTTH1S/RTTH1D SNT RTTH1S INDIVIDUALS Blocks dedicated for TRA R5 Half Rate. Delta = 1. One SNT handles 24 transcoder resources (DEMUX). 1142 RTTAF1S 0 - 683 NO OF RTTAF1S/RTTAF1D SNT RTTAF1D INDIVIDUALS Blocks dedicated for TRA R5B Adaptive Multi Rate (AMR) Full Rate. Delta = 1. One SNT handles 24 transcoder resources (DEMUX). 1143 RTTAH1S 0 - 683 NO OF RTTAH1S/RTTAH1D SNT RTTAH1D INDIVIDUALS Blocks dedicated for TRA R5B Adaptive Multi Rate (AMR) Half Rate. Delta = 1. One SNT handles 24 transcoder resources (DEMUX). 1109 RTTGD 0 - 255 NUMBER OF RTTGS/RTTGD SNT



RTTGS INDIVIDUALS Number of SNT and corresponding device individuals for FR, EFR, HR, AMR FR, AMR HR and AMR WB transcoder supported by TRA R6 hardware. Delta = 1. One SNT handles 192 transcoder resources (DEMUX). 1157 RTTG1D 0 - 127 NUMBER OF RTTG1D/RTTG1S SNT RTTG1S INDIVIDUALS Number of SNT and corresponding device individuals for FR, EFR, HR, AMR FR, AMR HR and AMR WB transcoder supported by TRA R7 hardware. Delta = 1. One SNT handles 384 transcoder resources(DEMUX). 500 RTTPH 0 - 32768 NO OF TRANSCODER RESOURCES The total number of transcoder resources that could be contained in the Transcoder pools. Delta = 24, 192 or 384 depending on RP type. Transcoder resources per TRA-EM: = 24 for TRA R5, R5B = 192 for TRA R6 = 384 for TRA R7 Increase/decrease only if total number of transcoder resources in the transcoder pools needs to be changed. 500 RTPDI 0 - 32768 NO OF TRANSCODER RESOURCES INDIVIDUALS Number of resource individuals which can be connected in the combined BSC/TRC or the standalone TRC. Guiding value = 0 for BSC = Max traffic intensity in Erlang for BSC/TRC and TRC.

8.12 Signal Terminal CCITT CCS7 in BSC, BSC/TRC or TRC

These SAEs are affected when a Signal Terminal CCITT CCS7 is added. This chapter describes which SAEs that are included when signalling No.7 based on CCITT standard is used for one signalling link. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints



---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 166 C7DR2 0 - 65535 NO OF MESSAGE STORING BUFFERS Delta = 250 per signalling link. 163 C7DR2 0 - 65534 NO OF CCITT 7 SIGNALLING LINKS C7LS2 Delta = 1 to 4 C7SL2 Depends on how many links are connected to the ST. 566 C7ST2C 0 - 16383 NO OF CCITT SIGNALLING TERMINAL INDIVIDUALS Delta = 1 to 4 Depends on how many links are connected to the ST. or 566 C7GST 0 - 16384 NO OF NB CCITT SIGNALLING TERMINAL INDIVIDUALS See chapt 5.1



or 566 C7GSTAH 0 - 128 NO OF HSL CCITT SIGNALLING TERMINAL INDIVIDUALS (Q.703) See chapt 5.1 or 566 C7GSTH 0 - 128 NO OF HSL CCITT SIGNALLING TERMINAL INDIVIDUALS (ATM) See chapt 5.1 097 SECA 0 - 32767 NO OF SEMIPERMANENT CONNECTIONS SECOM Delta = 1 to 4 Depends on how many links are connected to the ST.

8.13 Signal Terminal ANSI CCS7 in BSC, BSC/TRC or TRC

These SAEs are affected when a Signal Terminal ANSI CCS7 is added. This chapter describes which SAEs that are included when signalling No.7 based on ANSI standard is used for one signalling link. The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one



of the new RPs has the highest RP number and is connected to RPB-S. 052 SCRD 0 - 1024 NO OF ANSI SIGNALLING LINKS S7DR Delta = 1 to 4 depending on how S7LS many links are connected to the S7SL ST. 554 S7STG 0 - 1024 NO OF ANSI SIGNALLING TERMINAL INDIVIDUALS Delta = 0 or 1, see formula in chapter 5.1. or 554 S7GST 0 - 16384 NO OF NB ANSI SIGNALLING TERMINAL INDIVIDUALS. See chapt 5.1 or 554 S7HST 0 - 128 NO OF HSL ANSI SIGNALLING TERMINAL INDIVIDUALS. See chapt 5.1 027 S7DR 0 - 65534 NO OF MSU BUFFER RECORDS Delta = 250. 097 SECA 0 - 32767 NO OF SEMIPERMANENT CONNECTIONS SECOM Delta = 1 to 4 depending on how many links are connected to the ST.

8.14 Subrate Switch Units in BSC, BSC/TRC or TRC

This SAE are affected when a Subrate Switch Units is added. This chapter describes included SAE regarding Subrate Switching. If LAPD multiplexing is used, or if there are changes in traffic load and the size of the transcoder pool, the following SAE are affected.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 529 SRSTRAF 0 - 8 NO OF SUBRATE SWITCH UNITS SRS Delta = 1.

8.15 Internal GSM Cell in BSC or BSC/TRC

This chapter describes which SAEs to include when adding a GSM cell belonging to the current BSC or BSC/TRC. For GAN cells, see chapter 8.16.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 346 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 64 W Delta = 1 (minimum value is 390).



298 RCACCA 0 - 1024 NO OF INTERNAL CELLS RCCD Delta = 1. RCCGD RCLAH RCLS RCSCB RCSES RCSI RCSLC RGCNT RGCON RGNCC RGRLC RGSERV RGSI RMASHO RMASS RMCASS RMCC RMCHO RMCIPH RMCNT RMDTM RMHBI RMHOAC RMHOEB RMHOEC RMPAG RMQ RMRLS RMSCS RMTRE RMVGASS RMVGCH RNCM RNLC RNLCH RNLCT RNSDCCH RNTCH ROBAR ROCTR ROMTR RORIR ROTRAN ROTRS RQCD RQRCQS RQUCD RQUNC RQUPD 522 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE INTERNAL HANDOVER COUNTER FILE Delta = 2 * (number of internal neighboring cells to the new cell).



523 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE EXTERNAL HANDOVER COUNTER FILE Delta = 1 * (number of external neighboring cells to the new cell). 524 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE NEIGHBORING CELL RELATION FILE Delta = according to the restriction below. There is a restriction that the size of the neighboring cell relation file (SAE 524) may not fall below the actual sum of both handover counter files (SAE 522 + SAE 523). 500 C7CO 0 - 65534 NO OF SCCP SIGNALLING CONNECTIONS Delta = 8 if CCITT CCS7 is used. = 0 if ANSI CCS7 is used. 500 SCCOC 0 - 65534 NO OF CONNECTION SECTION INDIVIDUALS Delta = 8 if ANSI CCS7 is used. = 0 if CCITT CCS7 is used. 500 RABDI 0 - 32768 NO OF SIGNALLING CONNECTION RABDIAN INDIVIDUALS Delta = 8. 913 RGCON 0-32768 NO OF MS INDIVIDUALS RGRLC RGSERV Delta = 8. RMASHO RMASS RMCASS RMCC RMCCHM RMCHO RMCIPH RMCR RMDTM RMHBI RMHOAC RMHOEB RMHOEC RMHTR RMPH RMPOS RMQ RMRLS RMTRE RMVGASS RMVGCH



RNLCT RODCR RQRCQS 812 MFM 2 - 1048575 NO OF FORLOPP GROUPS This SAE may need to be changed, see SAE 812 MFM in chapter 5.2. 997 RCSCB 0-16384 NO OF MESSAGE PAGE FILE RCTIMER INDIVIDUALS Least extension or reduction stage = 1 message. Guiding value = 1 * (no of Short Message Service Cell Broadcast message pages per cell). 500 RTBLE 0 - 16384 NO OF SIGNALLING CONNECTION RTBLEAN INDIVIDUALS Delta = 2. 1152 RCC 0 - 2048 NO OF CHANNEL GROUP RCCGD INDIVIDUALS. RNCM Delta = no of added Channel RNLCH Groups RNSDCCH RNTCH 1162 RMHAIDL 0 - 32768 NUMBER OF HAI INDIVIDUALS RMHAIUL One individual is needed for each Signalling Connection Control (SCCP) connection. Note! If the calculated number of individuals exceeds the maximum value, the SAE must be set to its maximum size. Guiding value = (SAE1161)+(SAE913) for BSC and BSC/TRC = 1 for TRC

8.16 External Cell in BSC or BSC/TRC

This chapter describes which SAEs to include when adding GSM or GAN cells belonging to other BSCs or BSC/TRCs, or UTRAN cells.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 299 RCCD 0 - 2048 NO OF EXTERNAL CELLS RGSI Delta = 1. RGCON RQCD ROMTR ROTRAN ROCTR



502 RQUCD 0 - 16384 NO OF UTRAN CELL RELATIONS Delta = 1 523 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE EXTERNAL HANDOVER COUNTER FILE Delta = number of internal cells having the new external cell as neighboring cell. 524 RQCD 0 - 32768 NO OF INDIVIDUALS IN THE NEIGHBORING CELL RELATION FILE Delta = according to the restriction below. There is a restriction that the size of the neighboring cell relation file (SAE 524) may not fall below the actual sum of both handover counter files (SAE 522 + SAE 523).

8.17 Change of Group Switch

The process for replacing a GS12 switch with GS890 while reusing the already installed devices is described in reference 4 and 5.

A number of SAEs have different fixed recommendations depending on if GS12 group switch or GS890 is used, this is based on the calculations described in section 3.7 above. With GS890 the capacity limit at roughly 6400 Erlang is removed. Thus, when upgrading the group switch to a GS890 a number of SAEs may need to be adjusted if high traffic is expected or if the interfaces are increased. It is thus advisable to check that all SAEs where different recommendations are given for GS12 and GS890 in section 3.2-3.5 above and increase the SAEs if needed.

These following SAEs are part of the replacement process. How they should be set is described in the references mentioned above.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 058 COSEM 0 - 256 NO OF TIME SWITCH MODULES GS The SAE increases or decreases GSM1 the number of TSMs. GSM2 SAE individuals are seized at SNEC connection of TSM and released SNEFD at disconnection. SNEFI SNETR The SAE 058 shall be set SRSTRAF according to the number of Time TSM Switch Modules in the system before command GSDCI in reference 4 is used. COMMAND: EXEMP:RP=ALL,EM=ALL; 442 CH 0 - 512 NO OF PHYSICAL MUP INDIVIDUALS COSEM Each individual represents 1024 MUX3 Multiple Positions (MUPs). XM Individuals are seized at



connection of Switch Matrix (XM) unit and released at disconnection. Each connected XM board owns 16384 UPDs. Minimum step size increase and decrease is 16 individuals. COMMAND:EXMDP; 529 SRSTRAF 0 - 8 NO OF SUBRATE SWITCH UNITS SRS Increases or decreases the number of Subrate Switch units that may be connected to the Group Switch. Step size for increase or decrease = 1 individual. Size per individual = 160263 (16-bit) words. Command: NTSTP:SNT=ALL; 600 CH 0 - 512 NO OF SUBRATE CONNECTIONS THAT MAY BE ESTABLISHED Each individual represents 1024 Multiple Positions (MUPs). Individuals are seized at connection of XM unit and released at disconnection. Eight subrate connections correspond to MUP. The number of individuals to be specified in the SAAII command must be the same number of individuals related to SAE 442. 600 XM 0 - 128 NO OF SUBRATE CONNECTIONS THAT MAY BE ESTABLISHED Each individual represents 1024 Multiple Positions (MUPs). Individuals are seized at connection of XM unit and released at disconnection. Eight subrate connections correspond to MUP. The number of individuals to be specified in the SAAII command must be the same number of individuals related to SAE 442. 1094 COSEM 0 - 8388607 NO OF MUP INDIVIDUALS COX Global MUP individuals are used to store MUP data, such as connection individual, switch type, relevant physical MUP/ virtual MUP data. For each connection, at least two individuals are seized. The SAE 1094 shall be set



according to the number of MUP individuals in the system before command GSDCI in reference 4 is used.

8.18 Packet Gateway Devices

This chapter describes which SAEs to include when increasing/decreasing the number of Packet Gateway Devices.The order in which the SAEs are entered is of significance. In order to increase, follow the order in which the SAEs are entered below. Do decrease in reversed order.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 807 RPDI 0 - 65535 NO OF INDIVIDUALS IN RP ERROR RECORD Delta = 8 (minimum start value is 101). Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number. 304 FCERT 1 - 1024 NO OF REGIONAL PROCESSORS FCEPEX Delta = 2. LARP Change is needed only if the new RENFD EM demands a new RP pair and one RPADM of the new RPs has the highest RPADS RP number. RPAL RPDI RPDU RPDUD RPFD RPIFD RPITAB RPREC RPREP RPRES RPROUT 1822 RPADM 0 - 1023 NO OF TABLE ROWS IN DATABASE RPIFD TABLE RPSRPBSPOS Delta = 2. Change is needed only if the new EM demands a new RP pair and one of the new RPs has the highest RP number and is connected to RPB-S. 529 RTPGS 0 - 64 NO OF PGW SNT INDIVIDUALS The SAE increases and decreases the number of SNTs and EMs for PGW. SAE 500 RTPGD, SAE 500 RTBLD and SAE 529 RTPGS are dependent on each other. SAE 500 RTPGD and SAE 500 RTPLD = 768 * SAE 529 RTPGS



and must be increased in the following order: First Second Third 529 RTPGS 500 RTPLD 500 RTPGD Guiding value = site dependent for BSC and BSC/TRC = 0 for TRC 500 RTPLD 0 - 49152 NO OF PGW DEVICES The SAE increases or decreases number of RTPLD devices. It can a multiple of 768. SAE 500 RTPLD, SAE 500 RTPGD and SAE 529 RTPGS are dependent on each other (SAE 500 RTPLD = 768 * SAE 529 RTPGS) and must be increased in the following order: First Second Third 529 RTPGS 500 RTPLD 500 RTPGD Guiding value=768*SAE 529 RTPGS = 0 for TRC 500 RTPGD 0 - 49152 NO OF PGW DEVICES The SAE increases or decreases number of RTPGD devices. It can be multiple of 768. SAE 500 RTPGD, SAE 500 RTPLD and SAE 529 RTPGS are (SAE 500 RTPGD = 768 * SAE 529 RTPGS) and must be increased in the following order: First Second Third 529 RTPGS 500 RTPLD 500 RTPGD Guiding value =768*SAE 529 RTPGS = 0 for TRC

9 Recording Functions

9.1 Cell Traffic Recording

This chapter describes what SAEs that must be increased in order to run the Cell Traffic Recording function.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 345 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 W In order to be able to run Cell Traffic Recording one buffer with size 32 W must be free to use. Delta adjustment already included in the guiding value



given in chapter 4.2. 351 LAD 5 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 2 KW In order to be able to run Cell Traffic Recording 16 buffers with size 2 kW must be free to use. Guiding value = increase with 16.

9.2 Mobile Traffic Recording

This chapter describes what SAEs that must be increased in order to run the Mobile Traffic Recording function with file output.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 345 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 W In order to be able to run Mobile Traffic Recording one buffer with size 32 W must be free to use for each recording with file output. Delta adjustment already included in the guiding value given in chapter 4.2. 351 LAD 5 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 2 KW In order to be able to run Mobile Traffic Recording 2 buffers with size 2 kW must be free to use for each recording with file output. Guiding value = increase with 2 - 8.

9.3 Channel Event Recording

This chapter describes what SAEs that must be increased in order to run the Channel Event Recording function.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 345 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 W In order to be able to run Channel Event Recording one buffer with size 32 W must be free to use for each recording. Delta adjustment already included in the guiding value given in chapter 4.2.



352 LAD 2 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 4 KW In order to be able to run Channel Event Recording, two buffers with size 4 kW must be free to use for each recording. Guiding value = increase with 2 - 32.

9.4 Measurement Result Recording

This chapter describes what SAEs that must be increased in order to run the Measurement Result Recording function.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 351 LAD 5 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 2 KW In order to be able to run Measurement Result Recording, 2 buffers with size 2 kW must be free to use for each recording, up to 20. Guiding value = increase with 2 - 20.

9.5 Radio Interference Recording

This chapter describes what SAEs that must be increased in order to run the Radio Interference Recording function.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 346 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 64 W In order to be able to run Radio Interference Recording, 61+SAE298 buffers with size 64 W must be free to use and also one free buffer for each recording. Delta adjustment already included in the guiding value given in chapter 4.2. 349 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 512 W In order to be able to run Radio Interference Recording 40 buffers with size 512 W must be free to use. Guiding value = increase with 40. This increase shall only be done for the first Recording Individual.



350 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 1 KW In order to be able to run Radio Interference Recording 2 buffers with size 1 kW must be free to use for each recording. Guiding value = increase with 2 - 20. 355 LAD 0 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 KW In order to be able to run Radio Interference Recording one buffer with size 32 kW must be free to use for each recording. Guiding value = increase with 1 - 10.

9.6 Active BA-list Recording

This chapter describes what SAEs that must be increased in order to run the Active BA-list Recording function.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 350 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 1 KW In order to be able to run Active BA-list Recording one buffer with size 1 kW must be free to use for each recording, up to 10. Guiding value = increase with 1 - 10. 352 LAD 2 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 4 KW In order to be able to run Active BA-list Recording, one buffer with size 4 kW must be free to use for each recording. Guiding value = increase with 1 - 10. 533 ROBAR 0 - 65534 NO OF GSM TEST FREQUENCY INDIVIDUALS IN ACTIVE BA-LIST RECORDING The number of individuals is determined by all possible combinations of test frequencies and active cells connected to the active BA-list recording. Guiding value = 32768 for BSC and BSC/TRC. = 0 for TRC.



534 ROBAR 0 - 131072 NO OF TEST UMTS MEASUREMENT FREQUENCY INFORMATION (TUMFI) INDIVIDUALS The number of individuals is determined by all possible combinations of TUMFIs (test UMTS measurement frequency information) and active cells connected to BA-list recording. Guiding value = 65536 for BSC and BSC/TRC. = 0 for TRC.

9.7 BTS Configuration Data Collection

This chapter describes what SAEs that must be increased in order to run the BTS Configuration Data Collection function.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 350 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 1 KW In order to be able to run BTS Configuration Data Collection 2 buffers with size 1 kW must be free, up to 2. Guiding value = increase with 2. 355 LAD 0 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 KW In order to be able to run BTS Configuration Data Collection one buffer with size 32 kW must be free. Guiding value = increase with 1.

9.8 Call Path Tracing

This chapter describes the different possible buffer sizes used by Call Path Tracing function.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 346 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 64 W In order to be able to run Call Path Tracing, one buffer with size 64 W must be free to use for each tracing, up to 8. Guiding value = increase with 1. 347 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 128 W In order to be able to run Call Path Tracing, one buffer with size 128 W must be free to use



for each tracing, up to 8. Guiding value = increase with 1. 348 LAD 50 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 256 W In order to be able to run Call Path Tracing, one buffer with size 256 W must be free to use for each tracing, up to 8. Guiding value = increase with 1. 349 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 512 W In order to be able to run Call Path Tracing, one buffer with size 512 W must be free to use for each tracing, up to 8. Guiding value = increase with 1. 350 LAD 25 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 1 KW In order to be able to run Call Path Tracing, one buffer with size 1 kW must be free to use for each tracing, up to 8. Guiding value = increase with 1. 351 LAD 5 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 2 KW In order to be able to run Call Path Tracing, one buffer with size 2 kW must be free to use for each tracing, up to 8. Guiding value = increase with 1. 352 LAD 2 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 4 KW In order to be able to run Call Path Tracing, one buffer with size 4 kW must be free to use for each tracing, up to 8. Guiding value = increase with 1. 353 LAD 0 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 8 KW In order to be able to run Call Path Tracing, one buffer with size 8 kW must be free to use for each tracing, up to 8. Guiding value = increase with 1. 354 LAD 2 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 16 KW In order to be able to run Call Path Tracing, one buffer with size 16 kW must be free to use for each tracing, up to 8. Guiding value = increase with 1.



9.9 Dropped Call Recording

This chapter describes the SAEs that must be increased in order to run the internal Dropped Call Recording function. It is just for use by Ericsson staff for maintenance purpose

SAE Block Value Range Description and Hints ---------------------------------------------------------- 500 RODCR 0 - 32768 NO OF DCR RECORDING INDIVIDUALS This SAE is designated for Ericsson personnel only to be used for the internal Dropped Call Recording function. The SAE is related to the MS individuals controlled by SAE 913. Guiding value = 0. Increased on Ericsson maintenance demand to desired number of recorded individuals, less than or equal to the size of SAE 913. 345 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 W In order to be able to run the internal Dropped Call Recording, one buffer with size 32 W must be free to use. Delta adjustment already included in the guiding value given in chapter 4.2. 354 LAD 2 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 16 KW In order to be able to run the internal Dropped Call Recording two buffers with size 16 kW must be free to use. Guiding value = increase with 1 - 2.

9.10 Parameter Collection

This chapter describes the SAEs that must be increased in order to run the Parameter Collection function.

SAE Block Value Range Description and Hints ---------------------------------------------------------- 345 LAD 100 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 32 W In order to be able to run the Parameter Collection, one buffer with size 32 W must be free to use. Delta adjustment already included in the guiding value given in chapter 4.2.



354 LAD 2 - 4096 NO OF DYNAMIC BUFFERS WITH SIZE 16 KW In order to be able to run the Parameter Collection one buffer with size 16 kW must be free to use. Guiding value = increase with 1.

10 Upgrade from RBS200 (G01) into RBS2000 (G12)

I SAE values for RBS200 have to be decreased before SAE values for RBS2000 can be increased.

Chapters to follow for decrease of RBS200 values: Section 6.1, Section 6.2 and Section 6.3

Chapters to follow for increase of RBS2000 values: Section 7.1 and Section 7.2

11 References

1. BSC Hardware Dimensioning Handbook 1555-AXE 105 07 Uen.

2. Application Information (documents on Block level) 2/155 18-CNx xxxx Uen.

3. Parameter Settings in the BSC/TRC 4/1551-APT 210 09

4. NNRP-4, CONGSDA User Guide, 2/154 31-ANT 213 18/2

5. Network Node Renewal Process-4, NNRP-4, 3/154 31-ANT 213 18/2 Uen



info SAE

Documents

owner 2nd

call path

radio interference

bts logical

dropped call

handover counter

radio interference

database table