102713628-BSC6900V900R011-GO-Data-Configuration-ISSUE1-0-20091130-B

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Security Level: Internal Use

HUAWEI TECHNOLOGIES Co., Ltd. HUAWEI Confidential

Dual-mode BSC6900Data Configuration —GSM Only

TSD wireless product service department-GBSS

ISSUE2.0

2009-11



HUAWEI TECHNOLOGIES Co., Ltd. HUAWEI Confidential Page 2

This slide describes the process of creating the script of the

BSC6900 initial configuration depend on the WebLMT.




Be familiar with the data configuration steps

Know the method of data effective

Know how to create a new CELL and a new BTS quickly


http://slidepdf.com/reader/full/102713628-bsc6900v900r011-go-data-configuration-issue1-0-20091130-b 4/61HUAWEI TECHNOLOGIES Co., Ltd. HUAWEI Confidential Page 4

BSC6900 Intial Configuration Guide(V900R011C00)

BSC6900 Commissioning Guide(V900R011C00)

BSC6900 MML Command Reference (V900R011C00)

Typical Configuration Scripts (in Intial Configuration Guide)




Chapter 1 Summarize of Data Configuration

Chapter 2 Data Configuration




The Evolution of Data Configuration Client

We can use GUI and MML to complete the data configuration for BSC6000,

one for Graphic User Interface, another for Man Machine Language which canrun batch script.

For BSC6900, we use WebLMT and CME to do the data configuration. No

need to install the server software on your PC, and we can login by Web

anywhere to do the data configuration by MML command.

GUI LMT MML LMT

M2000 CME

Web LMT

M2000 CME

BSC6000 BSC6900




WebLMT Login

Enter the external virtual IP address of the OMU in the address bar on the IE.

Press Enter on the keyboard, or click Go next to the address bar to display thelogin window of the BSC6900.

Enter the Name , Password , and Verify Code . Select the User Type . You can

select Local User or EMS . If the verify code is illegible, click Change the verify

code for a new code.




Data Configuration Interface of MML

NavigationTree

Command Display

Running

Failed

RunningSuccessful

InputCommand




Run Batch Interface




Data Configuration Modes

Principle of Effective Mode Configuration

The process of effective mode configuration is as follows:The BSC6900 is switched to effective mode.

The configuration console (LMT or M2000) sends MML commands to the configuration

management module of the OMU.

The configuration management module of the OMU sends the configuration data to the

database of the related host board and writes the data to the OMU database.

Realize

We can use SET CFGDATAINEFFECTIVE to switch between effective and ineffective

mode.

One command just for one subrack.

This mode used in modifying data dynamic.




Data Configuration Modes

Principle of Ineffective Mode Configuration

The process of ineffective mode configuration is as follows:The BSC6900 is switched to ineffective mode.

The configuration console (LMT or M2000) sends MML commands to the configuration

management module of the OMU.

The configuration management module sends only the configuration data to the OMU database.

When a subrack or the BSC6900 is reset, the OMU formats the configuration data in the

database into a .dat file, loads the file onto the related host boards, and then activates the

configuration data.

Realize

We can use SET CFGDATAINEFFECTIVE to switch between effective and ineffective mode.

One command just for one subrack.

This mode used in Initial data Configuration .






Change in MML Data configuration of BSC6900

Equipment and logical data are separated in site and cell data configuration.Equipment data, logical data, bind.

SRAN sites 3900 sites of 2G and 3G unify to SRAN sites 3900 sites with 9.0software version

Types of sites supported SRANMODE:BTS3900,BTS3900A,DBS3900,BTS3036,BTS3036A,DBS3036A,BTS3900L Select SRANMODE when add bts;Select actual cabinets when add bts cabinets, such as APM30, RFC etc.

Designate the cabinet, subrack and slot information when add RXU board;Designate the cabinet, subrack and slot information of main control board which transmissionis connected to in BTS when add bts connect.The data of the site unsupported SRANMODE and cannot be changed to the site supportedSRANMODE by MML data configuration.

Others

OPC is binded to cells, not to the BSC subrack;Clock source is configured for interface boards, not for BSC subrack;Signaling links set is need to add;GSM CN node is need to configure.




PC OMU

FunctionsThe PC OMU is auxiliary software developed on the basis of the OMU software of

Windows version. The PC OMU enables Huawei engineers to operate the OMUsoftware on their PCs.Data configuration through MML commandsVerify the data configuration through the license filePanel display on the LMT (optional)

Methods of Obtaining the Software and DocumentsSoftware http://support.huawei.com Software -> Version Software -> Wireless Product Line -> Single RAN -> MBSC -> BSC6900 ->BSC6900 V900R011 -> BSC6900 V900R011C00SPC300 or later version. Windows version(windows is in the software name) should be used.Documents BSC6900 PC OMU Operation Guide in Version Documents

Method of Starting and Stopping PC OMUnet start omud net stop omud

Default functions settingDevice panel display, FTP tool, alarm, tracing, and monitoring are disabled by defaultBuilt-in OMU board mode, not the external BAM server mode

http://support.huawei.com/

http://support.huawei.com/




Chapter 1 Summarize of Data Configuration

Chapter 2 Data Configuration




The Chat Flow of Data Configuration

Configuring the system

information

Configuring a cabinet

Configuring a subrack

Configuring a board

Configuring acommunication patch

between subracks

Configuring the time

The EquipmentData

Configuring the

basic data

Configuring the

OPC

GlobalInformation

Configuring Ater

interface

Configuring A

interface

Configuring Gb

interface

InterfaceData

Set the Clock

source of

Interface board

Add the Clock

source of the

systemSet the work

mode of the

system Clock

source

The ClocksData

Configuring the

BTS device data

Configuring the

logic data of the cell

Configuring the

transmission dataActivating BTS

data

GBTS andCells

Data configuration scene

BM/TC Separated. A, Ater, Abis Over TDM Transmission.

Inner PCU, Gb over FR.






Step 1: Configuring the Global Information

Configuring the Basic Data:SET BSCBASIC : <Name>, <AreaCode>, <CC>, <AVer>, <UmVer>, <AbisVer>,<HiFreqBandSupport>, <ServiceMode>,<SptRanSharing><IsSupportTcPool><IsMainBSC><ATERTRANSMODE>;

Aver, Umver, AbisVer: Phase tag for GSM protocols supported by the A interface. The value

of this parameter is chosen according to the A interface phase tag provided by the

MSC.Recommended Value: "GSM_PHASE_2" is recommended in common scenarios. If the

BSC needs to support GPRS services, EDGE services, AMR services, eMLPP services, inter-

RAT handover, and A over IP mode, "GSM_PHASE_2Plus" is recommended.

ServiceMode: Service mode of the BSC,GUI Value Range: SEPARATE(Separate),

TOGETHER(Together), AIP(AIP).

SptRanSharing: Whether to support RAN Sharing .

IsMainBSC: Whether the BSC is a primary BSC . ATERTRANSMODE: Transport mode of the Ater interface. The Ater interface can be in TDMor in IP transport mode.Example: SET BSCBASIC: AreaCode=021, CC=86, AVer=GSM_PHASE_2Plus,UmVer=GSM_PHASE_2Plus, AbisVer=GSM_PHASE_2Plus, HiFreqBandSupport=DCS1800,ServiceMode=SEPARATE, ATERTRANSMODE=TDM;





Configuring the Basic Data:ADD GCNOPERATOR : <OperatorType>, <OPNAME> <MCC>, <MNC>,<MSCPOOLALLOW>, <SGSNPOOLALLOW>;

OperatorType: Primary operator or secondary operator, GUI Value Range: PRIM(PrimaryOperator), SEC(Secondary Operator).OPNAME: Name of the operator. This parameter uniquely identifies an operator.MCC: Mobile country code. This parameter identifies the country where amobile .subscriber is located, for example, the Chinese MCC is 460.

MNC: Mobile network code. This parameter identifies the public land mobile network(PLMN) where a mobile subscriber is homed.Example: ADD GCNOPERATOR: OperatorType=PRIM, OPINDEX=0,OPNAME="TEST", MCC="460", MNC="04", MSCPOOLALLOW=NO,SGSNPOOLALLOW=NO;





Configuring the OPC

ADD OPC : <NAME>, <SPX>, <NI>, <SPCBITS>, <SPC>NAME: OSP name.

SPX: OSP Index, To identify an OSP uniquely.

NI Network ID. GUI Value Range: INT(INT), INTB(INTB), NAT(NAT), NATB(NATB).

SPCBITS OSP code bits. GUI Value Range: BIT14(BIT14), BIT16(BIT16), BIT24(BIT24).

SPC Hexadecimal OSP code.

Example: ADD OPC: NAME="BSC130", SPX=0, NI=NATB, SPCBITS=BIT14,

SPC=H'0A03;





Configuring DPC

ADD N7DPC : <NAME>, <DPX>, <SPX>, <SPDF>, <DPC>, <DPCT>;NAME DSP name.

DPX The DSP index uniquely indicates the corresponding relationship of an DSP and

OSP.

SPX To identify an OSP uniquely.

DPC The DSP code is in the hexadecimal format and cannot be 0. The value is unique

in the SS7 signaling network. The number of DSP bits is the same as that of the SPC. If

the designated bit is Bit14 in the adding of the SPC, the value range of the parameter is

H'1~H'3FFF(1~16383). If the designated bit is Bit16 in the adding of the SPC, the value

range of the parameter is H'1~H'FFFF(1~65535). If the designated bit is Bit24 in the

adding of the SPC, the value range of the parameter is H'1~H'FFFFFF(1~16777215).

DPCT DSP type. GSM only mode configured as A.Example: ADD N7DPC: NAME="MSC", DPX=0, SPX=0, SPDF=WNF, DPC=H'0910,

DPCT=A;




Step 2: Configuring the Equipment Data

Finish

Begin

Configuring theInterfaces

Configuring theGlobal Information

Configuring the Clocks

Configuring theEquipment Data

Configuring a GSMBTS and Its Cells

Configuring theSystem

InformationSET SYS1

Configuring aCabinet

ADD CAB2

Configuring a

Subrack

ADD SUBRACK3

Configuring aBoard

ADD BRD5

Configuring aCommunication Path

Between SubrackADD SRCONPATH6

Configuring theTime

SET TZ7

8 ADD SNTPSRVINFO

4 SET SCUPORT





Configuring the System InformationSET SYS : <SYSDESC>, <SYSOBJECTID>, <SYSCONTACT>,<SYSLOCATION>, <SYSSERVICES>;

SYSDESC Description of the Base Station Controller.SYSOBJECTID Identifier of the Base Station Controller.SYSCONTACT Contact way of the Base Station Controller supplier.SYSLOCATION Location of the Base Station Controller.SYSSERVICES Services provided by the Base Station Controller.Example: SET SYS: SYSDESC="LAB", SYSOBJECTID="001",SYSLOCATION="XINTIANXIA";





Configuring a CabinetADD CAB : <CN>, <CABT>

CN Number of the cabinet .CABT Whether the added cabinet is a remote cabinet.Example ADD CAB: CN=1, CABT=YES;

Note

The MPR is configured by default. You cannot add or remove this cabinet by running the

MML command. The cabinets consist of the Main Processing Rack (MPR), Extended

Processing Rack (EPR), and TransCoder Rack (TCR).

If the TC subrack is configured in the local cabinet, the remote TCR cannot be configured.

Configuring a SubrackADD SUBRACK : <SRN>, <SRName>, <TYPE>;

SRN Number of the subrack.SRName Name of the subrack to be added.TYPE Type of the subrack.ISTCCENTR Whether the subrack is a remote main TC subrack.Example ADD SUBRACK: SRN=3, SRName="TC1", TYPE=TCS, ISTCCENTRAL=YES;

ADD SUBRACK: SRN=1, SRName="EPR1", TYPE=EPS, WORKMODE=GO;





Configuring a Subrack enable the panel port of the SCUa board in themain subrack

SET SCUPORT : <SRN>, <PN>, <Switch >; SRN Subrack No.PN Port No.Switch GUI Value Range: CLOSE, OPEN Example SET SCUPORT: SRN=0, PN=0, Switch=OPEN;

SET SCUPORT: SRN=0, PN=2, Switch=OPEN;Note

For the active and standby SCUa boards, if you set the attributes of the port on one SCUaboard, those of the corresponding port on the other SCUa boards are also set.Except for port 10 and 11 on the SCUa board in subrack 0 when the external OMU is used,this command modifies the attributes of both an odd numbered port and an even numberedport. For example, if the attributes of port 2 on the SCUa board are modified, the attributesof port 3 are also modified. When the external OMU is used, only one of port 10 and port 11on the SCUa board in subrack 0 can be enabled.





Configuring a BoardADD BRD <SRN>, <BRDCLASS>, <BRDTYPE>, <LGCAPPTYPE>, <SN>,<MPUSUBRACK>, <MPUSLOT>;

BRDCLASS Classes of boards classified according to function modules, GUI Value

Range: INT, DPU, XPU, TNU, OMU.

BRDTYPE Type of the board.

LGCAPPTYPE Logic function type of the board, GUI Value Range: OAM,

TDM_Switching, GCP, UCP, RGCP, RUCP, IBCA, GTC, GPCU, UUP, ATM, IP, FR,HDLC, TDM, GbIP, Abis_TDM, Ater_TDM, Pb_TDM, A_TDM, Abis_IP.

MPUSUBRACK Number of the subrack where the MPU is located.

MPUSLOT Number of the slot where the MPU is located.Example: ADD BRD: SRN=0, BRDCLASS=XPU, BRDTYPE=XPUa,LGCAPPTYPE=RGCP, SN=0;

ADD BRD: SRN=0, BRDCLASS=XPU, BRDTYPE=XPUa, LGCAPPTYPE=GCP,SN=8, MPUSUBRACK=0, MPUSLOT=0;





Configuring a Communication PathADD SRCONPATH : <SRN1>, <SRN2>, <TDMN1>, <TDMN2>;

SRN1 Number of the subrack of one end of the inter-subrack connection channel.SRN2 Number of the subrack of the other end of the inter-subrack connection channelTDMN1 Each subrack has six TDM numbers, ranging from 0 to 5. Subrack 1 TDM PortNo. refers to the TDM number on subrack 1 of the inter-subrack connection.TDMN1 Each subrack has six TDM numbers, ranging from 0 to 5. Subrack 1 TDM PortNo. refers to the TDM number on subrack 1 of the inter-subrack connection.Example ADD SRCONPATH: SRN1=0, SRN2=1, TDMN1=0, TDMN2=0;

Note

Two different inter-subrack connection paths cannot be connected to the same TDM in an

identical subrack.

The two ports of one inter-subrack connection path cannot be connected to the same

subrack.The inter-subrack connection path can only be connected to the subracks of the same

types.

At most three inter-subrack connection paths can be configured between two subracks of

the same type.





Configuring the Time ZoneSET TZ : <ZONET>,< DST>;

ZONET Time zone.DST:Whether daylight saving time starts.Example SET TZ: ZONET=GMT-0800 DST=NO;

Configuring the SNTP Server ADD SNTPSRVINFO : <IP>, <PT>;

IP IP address of the server.PT Number of the port that provides the time information on the SNTP server. Example: ADD SNTPSRVINFO: IP="192.168.88.200", PT=123;

Note:

The number of SNTP servers cannot exceed 16.

If multiple SNTP servers are configured, the OMU selects the best SNTP server as the

clock source according to the algorithm defined in the Network Time Protocol (NTP).The IP address is the IP address of the SNTP server. The SNTP client in the active OMU

receives the time information from the SNTP server. The IP address cannot be set to a

special address such as 0.0.0.0 or 127.0.0.1.




Step 3: Configuring the Interfaces

Finish

Begin



Configuring Clock

Configuring theInterface

Configuring a GSM BTSand Its Cells

Configuring the A

interface

Configuring the physic Layer over A interfaceADD AE1T1

5

Configuring the control plane Over A interfaceADD MTP3LKSADD MTP3LNKADD MTP3RT

6

Configuring the Ater Interface

Configuring an Ater Connection PathADD ATERCONPATH

1

Configuring an Ater OML

ADD ATEROML2

Configuring an Ater Signaling LinkADD ATERSL3

Configuring theGB Interface

Configuring PCU typeSET BSCPCUTYPE

7

Configuring SGSN nodeADD SGSNNODE

8

Configuring NSEADD NSE

9

Configuring BCADD BC

10

Configuring NSVCADD NSVC

11

Configuring PTPBVCADD PTPBVC

12

4 Configuring the CN nodeADD GCNNODE

S 3 C fi i h I f A I f




Step 3: Configuring the Interface —Ater Interface

Configuring an Ater connection pathADD ATERCONPATH <ATERIDX>, <BMSRN>, <BMSN>, <BMPN>, <TCSRN>,<TCSN>, <TCPN>;

ATERIDX Index of an Ater connection path.BMSRN BMSN BMPN BM Subrack NO, Slot NO, Port NO.TCSRN TCSN TCPN TC Subrack NO, Slot NO, Port NO.Example: ADD ATERCONPATH: ATERIDX=0, BMSRN=0, BMSN=14, BMPN=0,TCSRN=3, TCSN=14, TCPN=0;

NoteThis command applies only in BM/TC separated configuration mode.

If the TC pool function is enabled, this command applies to only the active BSC. For the

standby BSCs, you need to run the ADD ATERE1T1 command to add the Ater

connection path.

S 3 C fi i h I f A I f




Step 3: Configuring the Interface —Ater InterfaceConfiguring Ater OML

ADD ATEROML : <ATEROMLINX>, <ATERPIDX>, <TSMASK>;

ATEROMLINX Ater maintenance link index. ATERPIDX Ater connection path index.TSMASK Time slots for Ater operation and maintenance. These time slots are provided bythe ports connected to the Ater connection path.Example ADD ATEROML: ATEROMLINX=0, ATERPIDX=0, TSMASK=TS1-1&TS2-1&TS3-1&TS4-1&TS5-1&TS6-0&TS7-0&TS8-0&TS9-0&TS10-0&TS11-0&TS12-0&TS13-0&TS14-0&TS15-0&TS16-0&TS17-0&TS18-0&TS19-0&TS20-0&TS21-0&TS22-0&TS23-0&TS24-0&TS25-0&TS26-0&TS27-0&TS28-0&TS29-0&TS30-0&TS31-0;

NoteOnly the remote TCS can be configured with the OML on the Ater interface.Before configuring the OML on the Ater interface, you must configure the Ater connection path.The Ater OML only configured between the local switching subrack and the remote mainsubrack. The BM and TC subracks used for the OML on the Ater interface must be mainsubracks.Besides timeslot 1, the OML on the Ater interface must contain four consecutive timeslots.

At most two OMLs on the Ater interface can be configured in the entire system.

St 3 C fi i th I t f At I t f




Step 3: Configuring the Interface —Ater Interface

Configuring an Ater Signaling LinkADD ATERSL : <BTCFLAG>, <ATERIDX>, <ATERMASK>, <TNMODE>;

BTCFLAG GUI Value Range: CFGBM(BM), CFGTC(TC). CFGBM indicates that the signaling link isfrom XPU to Ater interface board in BM, and CFGTC indicates the signaling link from Ater interface boardin TC to the A interface board. To configure a whole AterRSL from A interface board to XPU board, twoMML commands are needed.

TNMODE The Ater signaling link operates in the terrestrial transmission or satellitetransmission mode. In the areas such as desert and lake where the terrestrial transmissionis difficult, the satellite transmission can be used.Example ADD ATERSL: BTCFLAG=CFGBM, ATERIDX=0, ATERMASK=TS1-0&TS2-0&TS3-0&TS4-0&TS5-0&TS6-

0&TS7-0&TS8-0&TS9-0&TS10-0&TS11-0&TS12-0&TS13-0&TS14-0&TS15-0&TS16-1&TS17-0&TS18-0&TS19-0&TS20-0&TS21-0&TS22-0&TS23-0&TS24-0&TS25-0&TS26-0&TS27-0&TS28-0&TS29-0&TS30-0&TS31-0, TNMODE=TRRS;

ADD ATERSL: BTCFLAG=CFGTC, BSCTID=0, ATERIDX=0, ATERMASK=TS1-0&TS2-0&TS3-0&TS4-0&TS5-0&TS6-0&TS7-0&TS8-0&TS9-0&TS10-0&TS11-0&TS12-0&TS13-0&TS14-0&TS15-0&TS16-1&TS17-0&TS18-0&TS19-0&TS20-0&TS21-0&TS22-0&TS23-0&TS24-0&TS25-0&TS26-0&TS27-0&TS28-0&TS29-0&TS30-0&TS31-0, TNMODE=TRRS;

Note

Each BSC can be configured with a maximum of 64 Ater connection links; Each A interfaceboard can be configured with a maximum of 64 signaling links; Each ATER interface board

can be configured with a maximum of 64 timeslots used for Ater signaling link.

St 3 C fig i g th I t f —A I t f




Step 3: Configuring the Interface —A Interface

Configuring GSM CN NodeADD GCNNODE : <CNNODEIDX>, <DPC>, <DPCGIDX>, <OPNAME>,<CNID><DFDPC>;

CNNODEIDX Node index of an MSC.DPC Code of a destination signaling point (DSP) in a signaling network. In a signalingnetwork, each signaling point has a corresponding signaling point code (SPC).

DPCGIDX Signaling group of a DSP.

If multiple DSPs or one DSP serves as a logical entity, this logical entity is a DSP group.

OPNAME Name of the operator. This parameter uniquely identifies an operator.

CNID Used to uniquely identify an MSC.





Step 3: Configuring the Interface A Interface

DFDPC: For the default DPC corresponds to the CN of the primary operator: when only

one DPC is configured, this parameter must be set to "YES", indicating that all the calls

for the operator are accessed through the CN identified by the DPC. When multiple DPCs

are configured, this parameter also determines the DPC that allows the generation of

ESN. In this case, the parameter is set to "YES" for this DPC while the value for other

DPCs is "NO".

For the CN of a secondary operator, this parameter must be set to “Yes" when only one

DPC is configured. This indicates that all the calls for the secondary operator areaccessed through the CN. When multiple DPCs are configured, this parameter is invalid.

Example: ADD GCNNODE: CNNODEIDX=0, DPX=0, DPCGIDX=0, OPNAME="TEST",

CNID=0, DFDPC=YES;






Configuring the Physical Layer ADD AE1T1 : <SRN>, <SN>, <PN>, <STCIC>, <DPCGIDX>, <OPCIDX>,

<BSCFLAG>;STCIC Number of the start CIC. The C/C of each E1/T1 timeslot can be calculated onthe basis of this parameter. Assume that the start CIC is 100, the CIC of the E1 timeslotson the A interface will automatically be set to 100, 101, 102, 103, and so on. Assume thatthe CIC of an E1 timeslot is 65535, the CICs of all successive E1 timeslots are all 65535.BSCFLAG It indicates whether the A interface E1/T1 is the primary BSC or secondaryBSC.Example: ADD AE1T1: SRN=0, SN=16, PN=0, STCIC=0, DPCGIDX=0, OPCIDX=0,BSCFLAG=MAINBSC;

NoteYou can configure up to 512 E1/T1 links on the A interface board.

The CICs of the two E1/T1 timeslots on the A interface with the same OSP index and

DPC Group Index must be different. In practice, however, running this command always

fails due to the same CIC of the two timeslots. In this case, you need to adjust the Start

CIC to ensure that the CIC of an E1/T1 timeslot on the A interface differs from that of

another timeslot.






Configuring the Control PlaneADD MTP3LKS : <SIGLKSX>, <DPX>, <NAME>;

SIGLKSX To identify an signaling link set uniquely.DPX The DSP index uniquely indicates the corresponding relationship of an DSP andNAME Signaling link set name.Example: ADD MTP3LKS: SIGLKSX=0, DPX=0, NAME="LINK1";

NoteThe DSP specified by DSP index must exist, and it must be an adjacent DSP.

One adjacent DSP can be configured with only one signaling link set.






Configuring the Control PlaneADD MTP3LNK : <SIGLKSX>, <SIGSLC>, <BEARTYPE>, <TCMODE>, <ATERIDX>,

<ATERTSMASK>, <ASRN>, <ASN>, <MTP2LNKN>, <APN>, <ATSMASK>;SIGLKSX To identify an signaling link set uniquely.SIGSLC M3UA link ID of the specified link set.

BEARTYPE Link bearer type. GUI Value Range: MTP2(MTP2), SAAL(SAAL).

TCMODE To specify the mode of TC. GUI Value Range:

SEPERATE_PRINCIPAL(Principal BSC), SEPERATE_SUBORDINATE(Subordinate

BSC), TOGETHER(BSC/TC Together).

ATERIDX Index of an Ater connection path. ATERTSMASK Ater interface timeslot mask.MTP2LNKN To identify an MTP2 link.

APN A interface port No.. ATSMASK A interface timeslot mask.






Configuring the Control PlaneExample: ADD MTP3LNK: SIGLKSX=0, SIGSLC=0, BEARTYPE=MTP2,

TCMODE=SEPERATE_PRINCIPAL, ATERIDX=0, ATERMASK=TS1-0&TS2-0&TS3-0&TS4-0&TS5-0&TS6-0&TS7-0&TS8-0&TS9-0&TS10-0&TS11-0&TS12-0&TS13-0&TS14-0&TS15-0&TS16-0&TS17-1&TS18-0&TS19-0&TS20-0&TS21-0&TS22-0&TS23-0&TS24-0&TS25-0&TS26-0&TS27-0&TS28-0&TS29-0&TS30-0&TS31-0, ASRN=3,

ASN=16, MTP2LNKN=0, APN=0, ATSMASK=TS1-0&TS2-0&TS3-0&TS4-0&TS5-0&TS6-0&TS7-0&TS8-0&TS9-0&TS10-0&TS11-0&TS12-0&TS13-0&TS14-0&TS15-0&TS16-

1&TS17-0&TS18-0&TS19-0&TS20-0&TS21-0&TS22-0&TS23-0&TS24-0&TS25-0&TS26-0&TS27-0&TS28-0&TS29-0&TS30-0&TS31-0, NAME="mtp3link0";





Step 3: Configuring the Interface A InterfaceNote

The link set to be used must exist.

Signalling Link Code must be set to the same value at the two ends of the signaling link.The total number of MTP3 signaling links cannot exceed 1904.

The number of MTP3 links controlled by the same CPUS subsystem cannot exceed 50.

ADD MTP3RT : <DPX>, <SIGLKSX>, < NAME>;DPX The DSP index uniquely indicates the corresponding relationship of an DSP andOSP.

SIGLKSX To identify an signaling link set uniquely.NAME One MTP3 route name.Example: ADD MTP3RT: DPX=0, SIGLKSX=0, NAME="RT1";

Note

DSP index and Signalling link set index must exist.

If the DSP specified by DSP index is inconsistent with that specified by Signalling link

set index , you need to check whether the DSP specified by Signalling link set index

has a transfer function.

In addition to a direct route, it is recommended to add an alternative route as a backup.

At most 238 MTP3 routes can be configured for the BSC.

Step 3: Configuring the Interface —Gb Interface




Step 3: Configuring the Interface Gb Interface

Configuring the PCU TypeSET BSCPCUTYPE : <TYPE>;

TYPE Type of the PCU.

GUI Value Range: OUTER(Outer PCU), INNER(Inner PCU).

Example: SET BSCPCUTYPE: TYPE=INNER;

Configuring the SGSN NodeADD SGSNNODE : <CNOPNAME>, <CNID>;

OPNAME Name of the operator. This parameter uniquely identifies an operator.CNID Identifies a service provider.Example: ADD SGSNNODE: OPNAME="TEST", CNID=0;






Configuring an NSEADD NSE : <NSEI>, <SRN>, <SN>, <PT>, <CNOPNAME>, <CNID>;

NSEI Identifies a unique NSE.SRN SN Subrack number and slot number of the XPU bound to the.

PT Subnet protocol type. GUI Value Range: GB_OVER_FR(Gb over FR),

GB_OVER_IP(Gb over IP).

OPNAME Name of the operator. This parameter uniquely identifies an operator.CNID Identifies a service provider.

Example: ADD NSE: NSEI=0, SRN=0, SN=0, PT=GB_OVER_FR, OPNAME="TEST",CNID=0;

Note

The NSE must be configured in the MPS or EPS.

A BSC can be configured with up to 128 NSEs.

When Protocol type is set to GB_OVER_IP and Subnetwork Configure Mode is set to

DYNAMIC, then Server IP and Server Port are determined by the serving GPRS support

node (SGSN). If Subnetwork Configure Mode is set to STATIC, then Server IP and

Server Port need not be set.

NSE identifier must be consistent with that on the SGSN side.






Configuring a BCADD BC : <SRN>, <SN>, <PN>, <BCID>, <TS>;

SRN SN PN: Subrack number, Slot number, Port number.BCID Identifies one BC at the same port. The BCID's value range of PEUa board is0~255 and that of POUc board is 0~511.TS Timesolt of bearing channels.Example: ADD BC: SRN=0, SN=24, PN=0, BCID=0, TS=TS1-1&TS2-1&TS3-1&TS4-1&TS5-1&TS6-1&TS7-1&TS8-1&TS9-1&TS10-1&TS11-1&TS12-1&TS13-1&TS14-

1&TS15-1&TS16-1;Note

Bearing timeslot and Protocol type must be consistent with those on the Serving GPRS

Support Node (SGSN) side.





p g gAdd NSVC

ADD NSVC : <NSVCIDX>, <NSVCI>, <NSEI>, <SRN>, <SN>, <BCID>, <DLCI>;

NSVCIDX NSVC index, identifying a unique NSVC.NSVCI NSVC ID, identifying a unique NSE. This ID must be negotiated with the peer SGSN.NSEI Identifies a unique NSE.BCID Identifies one BC at the same port. The BCID's value range of PEUa board is0~255 and that of POUc board is 0~511.DLCI ID of the data link connection of the NSVC. It is an interworking parameter whichmust be consistent on the BSC and the peer.Example: ADD NSVC: NSVCIDX=0, NSVCI=0, NSEI=0, SRN=0, SN=24, BCID=0,DLCI=16;

Note

An NSVC is carried on a bearer channel (BC) on the E1/T1 link. A BC can be configured

with several NSVCs (differentiated by The identifier of Data Link Connection ). AnNSVC can belong to only one BC and only one NSE, whereas an NSE can correspond to

several NSVCs.

NSE identifier , NSVC identifier , and The identifier of Data Link Connection must be

consistent with those on the SGSN side.





p g g

Configuring a PTPBVCADD PTPBVC : <NSEI>, <BVCI>, <IDTYPE>, <CELLNAME>;

NSEI Identifies a unique NSE.BVCI Identifies one PTP BVC.

IDTYPE Subscribers can specify the cell according to the index or the name.

GUI Value Range: BYNAME(By Name), BYID(By Index).

Example: ADD PTPBVC: NSEI=0, BVCI=2, IDTYPE=BYNAME, CELLNAME="CELL1";

Note

When the SGSN pool function is disabled, a cell can be configured with only one PTP

BVC. When the SGSN pool function is enabled, a cell can be configured with up to 32

PTP BVCs.

An NSE can support up to 2048 PTP BVCs.

This command can be used only in built-in PCU mode.



Step4: Configuring the Clocks




p g g

Set Board Clock SourceSET CLK : < SRT>, <SRN>, <SN>, <BT>, <REF2MCLKSR>, <BACK8KCLKSW1>;

SRT: Type of the subrack. GUI Value Range: MPS, EPS, TCS.

SRN: Number of the subrack.

BT: Type of the board. GUI Value Range: AEUa, PEUa, AOUa, POUa, UOIa, EIUa, OIUa,

AOUc, POUc, UOIc.

REF2MCLKSR: Clock source link No. of output clock 1. GUI Value Range: 0~31.

BACK8KCLKSW1 Switch of 8K output clock 1 on the backplane board.Example: SET CLK: SRT=TCS, SRN=3, SN=16, BT=EIUa, REF2MCLKSRC=0,BACK8KCLKSW1=ON;SET CLK: SRT=MPS, SN=14, BT=EIUa, REF2MCLKSRC=0, BACK8KCLKSW1=ON;

Note

The clock source of the interface board in the EPS cannot be set to the 8 kHz output

clock source.Each 8 kHz clock of the backplane has only one clock source. The output switch cannot

be set for multiple interface boards at the same time.





Add Clock SourceADD CLKSRC : <SRCGRD>, <SRCT>;

SRCGRD Priority of the clock source. GUI Value Range: 1~4.

SRCT Type of the clock source. GUI Value Range: BITS1-2MHZ(2MHZ Building

Integrated Timing Supply system 1), BITS2-2MHZ(2MHZ Building Integrated Timing

Supply system 2), BITS1-2MBPS(2MBPS Building Integrated Timing Supply system 1),

BITS2-2MBPS(2MBPS Building Integrated Timing Supply system 2), 8KHZ(8KHZ),

GPS(Globe Positioning System), LINE1_8KHZ(8KHZ line1), LINE2_8KHZ(8KHZ line2),BITS1-T1BPS(T1BPS Building Integrated Timing Supply system 1), BITS2-

T1BPS(T1BPS Building Integrated Timing Supply system.

Example: ADD CLKSRC: SRCGRD=1, SRCT=LINE1_8KHZ





Set Clock Working ModeSET CLKMODE : <MODE> <SRCGRD>;

MODE Working mode of the system clock. Working modes of the system clock are as

follows:

(1) MANUAL: In this mode, you must specify a clock source and prevent the switching of

the clock source.

(2) AUTO: In this mode, you do not need to specify a clock source and the system

automatically selects the clock source with the highest priority.(3) FREE: In this mode, the clock source of GCGa or GCUa is used.

GUI Value Range: MANUAL, AUTO, FREE

Example: SET CLKMODE: MODE=AUTO;

Note

If the manually-set clock source is unavailable, the switchover fails. Then, the current

clock source remains unchanged.

Step 5: Configuring a GSM BTS and Its Cells




Finish

Begin



Configuring Clock

Configuring a GSMBTS and Its Cells

Configuring theInterface

Configuring the

Equipment Data

Configure BTSADD BTS

1

Configure BTS subrackADD BTSCABINET

2

Configuring theLogical Data

Configure Cell dataADD CELLADD GCELLOSPMAPADD GCELLFREQ

4

Configure TRX dataADD BTSTRXBRDADD BTSRXUCHAINADD BTSRXUBRD

5

Bind a Cell to a BTS ADD CELLBIND2BTS

6

Configure BTS boardADD BTSBRD

3

Bind a physical board toa logic TRX

ADD TRXBIND2PHYBRD

7

Configuring theTransmission Data

ADD BTSCONNECT8

Activating the BTSConfiguration

ACT BTS9





Configuring a GSM BTSADD BTS : < BTSID>, <BTSNAME>, <BTSTYPE>, <SEPERATEMODE>

<SERVICEMODE> <SRANMODE>;SEPERATEMODE Whether to enable the BTS to support the separation between the

physical and logical. GUI Value Range: SUPPORT(Support), UNSUPPORT(Not Support).

SERVICEMODE Service bearer mode of the BTS. GUI Value Range: TDM, HDLC,

HDLC_HubBTS, IP.

SRANMODE Whether to enable the BTS to identify an object in the BTS in normalized

mode, for example, to identify a board by the slot No., subrack No., and cabinet No. and

to identify a transmission port by the port No. in a board. GUI Value Range:

SUPPORT(Support), NOT_SUPPORT(Not Support).

Example: ADD BTS: BTSID=0, BTSNAME="BTS3900", BTSTYPE=BTS3900_GSM,

SEPERATEMODE=SUPPORT, SERVICEMODE=TDM, SRANMODE=SUPPORT;





Add BTS CabinetADD BTSCABINET : <IDTYPE>, <BTSID>,<CN>, <TYPE>;

IDTYPE Index type of the BTS. BYNAME: query by BTS name; BYID: query by BTSindex. GUI Value Range: BYNAME(By Name), BYID(By Index).

BTSID ID of the BTS. The BTS ID must not conflict with other BTS IDs in the BSC.

CN Number of the cabinet.

TYPE Type of a cabinet.

Example: ADD BTSCABINET: IDTYPE=BYID, BTSID=1, CN=0, TYPE=BTS3012;

Add BTS BoardADD BTSBRD :<IDTYPE>, <BTSID>, <CN>, <SRN>, <SN>;

Example: ADD BTSBRD: IDTYPE=BYID, BTSID=0, CN=0, SRN=11, SN=0, BT=FMU;





3900 Series Base Stations

ADD BTSRXUCHAIN: <IDTYPE>, <BTSID>, <RCN>, <TT>, <HCN>, <HSRN>,

<HSN>, <HPN>;Number of the RXU chain or ring. The value scope is 0~11 for Non-SRAN BTS and 0~249 for

SRAN BTS. The RXU chain No. is unique in the same BTS. A maximum of 12 RXU chains

can be configured in one BTS.

RXU topology type, that is, RXU ring topology or RXU chain topology. In the case of the ring

topology, the optical ports of the head and tail boards must be specified. In the case of thechain topology, only the optical port of the head board must be specified.

Number of the cabinet where the head board of the RXU chain or ring is located.

HSRN:Number of the subrack where the head board of the RXU chain or ring is located. The

subrack No. is unique in the same BTS.

HSN: Number of the slot where the head board of the RXU chain or ring is located. The slot

No. is unique in the same BTS.

HPN:The number of the optical port of the head board in the RXU chain or ring.

Example: ADD BTSRXUCHAIN: IDTYPE=BYID, BTSID=0, RCN=0, TT=CHAIN, HCN=0,

HSRN=0, HSN=6, HPN=0;





3900 Series Base Stations

ADD BTSRXUBRD: <IDTYPE>, <BTSID>, <BT>, <CN>, <SRN>, <SN>,

<RXUNAME>, <RXUCHAINNO>, <RXUPOS>;BT:Type of the newly added RXU board. GUI Value Range: DRRU(DRRU),

DRFU(DRFU), MRRU(MRRU), XRRU(XRRU), MRFU(MRFU), GRFU(GRFU),

GRRU(GRRU), XRFU(XRFU), BTS3900E(BTS3900E).

RXUCHAINNO: Number of the RXU chain where the board is located.

RXUPOS: Position of the RXU board on an RXU chain.Example: ADD BTSRXUBRD: IDTYPE=BYID, BTSID=0, BT=DRFU, CN=0, SRN=4,

SN=0, RXUNAME="drfu0", RXUCHAINNO=0, RXUPOS=1;



Step 5: Configuring the Logical Data




Add BSC CellADD GCELL : <CELLID>, <CELLNAME>, <TYPE>, <MCC>, <MNC>, <LAC>,

<CI>;CELLID Index of a cell, uniquely identifying a cell in a BSC.CELLNAME Name of a cell, uniquely identifying a cell in a BSC.TYPE This parameter specifies the frequency band of new cells. Each new cell can beallocated frequencies of only one frequency band. Once the frequency band is selected, itcannot be changed.

MCC Mobile country code. This parameter identifies the country where a mobilesubscriber is located, for example, the Chinese MCC is 460.MNC: Mobile network code. This parameter identifies the public land mobile network(PLMN) where a mobile subscriber is homed.LAC Location area code (LAC). MSs can freely move in the local location area with noneed of location update. Reasonable local allocation can effectively lighten the signaling

load and improve the call completion rate.CI Identity code of a cell.Example ADD GCELL: CELLID=0, CELLNAME="cell0", TYPE=GSM900, MCC="460",MNC="10", LAC=10, CI=11;





The Relation Between Cell And OSPADD GCELLOSPMAP : <IDTYPE>, <CELLID>, <OPC>;

IDTYPE Type of an index. GUI Value Range: BYNAME(By Name), BYID(By Index).CELLID Index of a cell, uniquely identifying a cell in a BSC.OPC: Code of the original signaling point (OSP) in the signaling network. In the signalingnetwork, each signaling point is identified by a signaling point code.Example: ADD GCELLOSPMAP: IDTYPE=BYID, CELLID=0, OPC=H'A03;

Configure the logic Data-Add Cell FrequencyADD GCELLFRQ : <IDTYPE>, <CELLID>, <FREQ1>;

FREQ1: Frequency 1Example: ADD GCELLFREQ: IDTYPE=BYID, CELLID=0, FREQ2=2;

Configure the logic Data-Add GSM TRXADD GTRX : < IDTYPE>, <CELLID>, <TRXID>, <FREQ> <ISMAINBCCH>;

FREQ: Frequency of the TRX.

ISMAINBCCH Whether to enable the TRX to carry the main BCCH in the cell. GUI

Value Range: NO(No), YES(Yes).

Example: ADD GTRX: IDTYPE=BYID, CELLID=0, TRXID=0, FREQ=2,

ISMAINBCCH=YES;





Bind a Cell to a BTSADD CELLBIND2BT : <IDTYPE>, <CELLID>, <BTSID>;

Example: ADD CELLBIND2BTS: IDTYPE=BYID, CELLID=0, BTSID=0 Configuring the Binding Between a Logical TRX and a Physical TRX Board

ADD TRXBIND2PHYBRD : <TRXID>, <TRXTP>, <TRXPN>, <SRN>, <SN>;TRXID ID of the TRX. The TRX ID must be globally unique.

TRXTP Type of the TRX board bound to the TRX. GUI Value Range: TRX(TRX),

TRU(TRU/DTRU), QTRU(QTRU), DRRU(DRRU), DRFU(DRFU), MRRU(MRRU),

MRFU(MRFU), GRFU(GRFU), GRRU(GRRU), BTS3900B(BTS3900B),

BTS3900E(BTS3900E).

TRXPN Number of the channel bound to the TRX on the TRX board.

Example: ADD TRXBIND2PHYBRD: TRXID=0, TRXTP=DRFU, TRXPN=0,

RXUIDTYPE=SRNSN, CN=0, SRN=4, SN=0;

NoteFor TRX boards of the DBS3900 GSM, BTS3900 GSM, BTS3900A GSM, DBS3036,

BTS3036, BTS3036A, BTS3900B GSM and BTS3900E GSM, you need to specify the

attributes of the RXU link.

Step 5: Configuring the Transmission Data




Add BTS ConnectADD BTSCONNECT : <IDTYPE>, <BTSID>, <INPN>, <DESTNODE>, <SRN>,

<SN>, <PN>;IDTYPE Index type of the BTS. BYNAME: query by BTS name; BYID: query by BTS

index. GUI Value Range: BYNAME(By Name), BYID(By Index).

BTSID ID of the BTS. The BTS ID must not conflict with other BTS IDs in the BSC.INPN Number of a BTS port.

DESTNODE Type of the object the BTS is connected to. Value range: BTS, BSC, and

DXX. GUI Value Range: BTS, BSC, DXX, OTHER.Example: ADD BTSCONNECT: IDTYPE=BYID, BTSID=0, INPN=0, INCN=0, INSRN=0,INSN=6, DESTNODE=BSC, SRN=0, SN=18, PN=0;

NoteThe connection between the BSC and the BTS is not required for the IP-based BTS that

supports IP over FE/GE transmission.

Step 5: Activating the BTS Configuration




Act BTSACT BTS : <IDTYPE>, <BTSID>;

IDTYPE Type of an index. GUI Value Range: BYNAME(By Name), BYID(By Index).BTSID ID of the BTS.

Example: ACT BTS: IDTYPE=BYID, BTSID=0;

Note

After this command is run, the BTS is initialized. This command can also be used to

check the BTS data as some data check is not done when BTS is not active in BSC6900.

Step 5: Configuring a GSM BTS and Its CELL




Quickly Configuring a GSM CellADD GCELLQUICKSETUP : <CELLID>, <CELLNAME>, <TYPE>, <MCC>,

<MNC>, <LAC>, <CI>, <OPC>, <BCCHFREQ>, <OTHERFREQ>;CELLID: Index of a cell, uniquely identifying a cell in a BSC.CELLNAME: Name of a cell, uniquely identifying a cell in a BSC.

TYPE Cell type. Currently, the fast BTS construction is available for only GSM900 and

DCS1800 cells. GUI Value Range: GSM900(GSM900), DCS1800(DCS1800).MCC MNC LAC CI Mobile country code. Mobile network code. Location area code

(LAC). Identity code of a cell.BCCHFREQ Frequency of the BCCH TRX.OTHERFREQ Ordinary frequency. Multiple frequencies are separated by "&". For example, "22&33&44&55" are allocated to TRXs in ascending order.Example: ADD GCELLQUICKSETUP: CELLID=1, CELLNAME="CELLA",TYPE=GSM900, MCC="460", MNC="04", LAC=10, CI=3, OPC=H'A03, BCCHFREQ=12,

OTHERFREQ="33&55";



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