97420099 WCDMA NodeB Data Configuration

7/30/2019 97420099 WCDMA NodeB Data Configuration

1/58

HUAWEI TECHNOLOGIES CO., LTD. All rights reserved

www.huawei.com

Internal

WCDMA NodeBData Configuration

NodeBV200R011

Wireless Case and TrainingWRAN Training Team


2/58

HUAWEI TECHNOLOGIES CO., LTD. All rights reserved Page 2

Upon completion of this course, you will be able to:

detail data configuration procedure with CME

detail procedure of NodeB initial data

configuration

understand the data configuration for different

NodeB networking


3/58


WRAN CME User Guide

NodeB Initial ConfigurationGuide(V200R011)


4/58


5/58


AbbreviationsCME Configuration Management Element

WBBPa WCDMA Baseband Process unit Type AWRFU WCDMA Radio Filter Unit

UBFA Universal BBU Fan Unit Type A

UEIU Universal Environment Interface unit

UELP Universal E1/T1 Lighting Protection unit

UFLP Universal FE/GE Lighting Protection unitUPEU Universal Power and Environment Interface Unit

UTRP Universal Transmission Processing Unit

DCDU-01 Direct Current Distribution Unit-01

EXT Extending

MRRU Multi-carrier Remote radio unit

CPRI Common Protocol Radio Interface

NPSU NodeB Power Supply Unit

NPMU NodeB Power Monitoring Unit


6/58


Data Configuration Overview

NodeB initial data configuration

Definition:

NodeB initial configuration is the process of preparing and configuring the data

after the NodeB hardware components are installed. The configuration is based

on the NodeB hardware components, network planning, and data negotiationbetween the NodeB and other equipment. After the configuration, a data

configuration file is generated.

Scenarios:

A new NodeB is required during the initial phase of network construction.

A new NodeB is required during network optimization


7/58HUAWEI TECHNOLOGIES CO., LTD. All rights reserved Page 7

Data Configuration Overview

Tool ---- WRAN CME:

A tool for NodeB initial configuration, provides an integrated

solution to RAN data configuration

This tool can be used for initial configuration and data

reconfiguration for the NodeB and the RNC

The GUI-based CME provides the operating platform for RAN

data configuration

The forth generation NodeB require the CME V100R008 version

Methods : manually adding a NodeB

adding a NodeB through a template file

adding a NodeB through a existing configuration file


8/58


Data Configuration OverviewProcedure of Manually Adding NodeB Data Configuration

ConfiguringNodeBData

Step1:Configuring Physical

Equipment

Step 2:Configuring Transport

Step3:Configuring Local cell

The NodeB data configuration script name is NodeBCfg.xml


9/58


Chapter 1 Data Configuration Overview

Chapter 2 Configuring Physical Equipment

Chapter 3 Configuring Transport

Chapter 4 Configuring Local Cell

Chapter 5 CME Special Function for NodeB Configuration


10/58


Procedure Configuring NodeB Physical Equipment

Physical Equipment Configuration

Create Logical and Physical NodeB

Used for BTS3900&A Used for DBS3900

Choose Macro NodeB Attribute

Add UL basebandresource group Add

NPMUAdd

NEMU

Add

NPSU

End

Add UTRP

Add UTRP1~9

Add WMPT

Add WBBP

Add UPEA/UPEB B

Add BBU board

Add UEIU

Add RFChain/Ring

Add WRFU

Add MRRURHUB/PRRU

Add DL basebandresource group

AddUFAN

220V

Add BBU

B

Add RFChain/Ring

Add MRRURHUB/PRRU

APM30/100/200Add NPMU/NPSU/NCMU

AntennaDevice


11/58


BTS3900 subrack numbering andconfiguration

Subrack Subrack number Explain

0 BBU3900 Main control, baseband and

transport part

4 WRFU RF subrack

6 EXT Virtual expanding subrack

7 NPSU Only need be configured for 220V

cabinet

11 FAN The RF subrack fan heat dissipation

system

20254 RRU Virtual RRU subrack

Configuring Physical Equipment


12/58


BTS3900 board configuration

Subracknumber

Cabinettype

Slotnumber

Board type MML Command

0 BBU3900

03 WBBPx/UTRP ADD BRD

45 UTRP ADD BRD

67 WMPT ADD BRD

16 UBF ADD BRD1819 UPEA/UPEB/UEIU ADD BRD

4 WRFU 05 WRFU ADD RRU

6 EXT 0 NEMU ADD BRD

7 NPSU 0 NPMU

220V AC will be

configuredautomatically

11 FAN 0 NFAN ADD BRD

20~254 RRU 0MRRU/PRRU/RHUB

ADD RRU



13/58



BTS3900 equipment plane


14/58



BTS3900 A equipment plane


15/58



Subrack

number

Subrack

type

Configuration

methods

Explain

0 BBU3900 Default configuration Main control, baseband and transport

part

6 EXT Manuallyconfiguration

Virtual expanding subrack

7 NPSU Default Configuration

with power module

The accessorial equipment of power

system (APM30) of BBU

8 NCMU Default Configuration

with power module

The accessorial equipment of hot

switch system of BBU (only for

APM30)

20254 RRU Manually

configuration

Virtual RRU subrack

DBS3900 subrack numbering and configuration


16/58


DBS3900 board configuration

Subracknumber

Subracktype

Slot number Board type MML Command

0 BBU3900

03 WBBPx/UTRP ADD BRD

45 UTRP ADD BRD

67 WMPT ADD BRD

16 UBF ADD BRD

1819 UPEA/UPEB/UEIU ADD BRD

6 EXT 0 NEMU ADD BRD

7 NPSU 0 NPMUSETPWRSYSCFG

8 NCMU 0 NCMUSETPWRSYSCFG

20~254 RRU 0MRRU/PRRU/RHUB

ADD RRU



17/58



DBS3900 equipment plane

Right-click the slot numbers, and configure related parameters based on prepared

data so as to add board information of the BBU.


18/58


The RF Configuration Rules of New NodeB

The mechanism of the RF board is the chain and ring mechanism in V200R010.

WRFU of BTS3900

RRU of DBS3900

The steps of configuration the RF board

1.ADD SUBRACK to add RFU cabinet. 2.ADD RRUCHAIN to add chain or ring.

3.SET RRUCHAINBRKPOS to set the break pointoptional)

4.ADD RRU to add WRFU/MRRU/PRRU

5.RMV RRUCHAINBRKPOS to cancel the break pointoptionalRight-click the RRU chain to configure the previous five steps in CME software.


19/58


The Backup Mode of RF board

WRFU support the hot backup mode and cold backup mode

MRRU only support the cold backup mode

The backup mode should be configured in properties of the RRU chain/ring

When the chain/ring is in hot backup mode, only the WRFU can be added

The hot backup ring can not support the upper layer cascading The RRUs are of the following types: MRRU, RHUB, PRRU, and WRFU

The RRU Chain of the distributed NodeB supports the configuration of three

RRU types: MRRU, RHUB, and PRRU

the RRU Chain of the macro NodeB supports the configuration of four RRUtypes: MRRU, RHUB, PRRU, and WRFU


20/58








21/58



Sector 1 Configuring Transport over ATM

Sector 2 Configuring Transport over IP


22/58


Configuring Transport over ATM

Iub Interface protocol over ATMControl Plane

Transport NetworkControl Plane

User plane

RadioNetworkLayer

Transport NetworkUser Plane

TransportNetworkLayer

TransportNetwork

User Plane

NCP CCP

A B C

CCP

NBAP

SAAL UNI AAL2 PATH

Physical Layer

ALCAP

SAAL UNI

RACHF

P

FACHF

P

ATM


23/58


Physical Layer

VPI-10

VPI-20

VCI-100

VCI-101

VCI-100

VCI-101

ATM Cell

segmentation packing

Iub data

CBR

E1/T1/SDH(STM-1)

ATM LayerAAL Layer

VBR-NRT

AAL5AAL1 AAL2

VBR-RT

VPI-10

CES

AAL2 PATH

NCP or CCP or ALCAP or IPoA

IMA/UNI/STM-1

AAL2Path

RNC

NodeBNCP

CCP 1~n RNC

Control Plane

ALCAP

NodeB

User Plane

Adjnode

Iub Interface protocolConfiguring Transport over ATM


24/58


TransportConfiguration

Create NodeB

Add UTRP

Add FractionalATM

Add UNI LINKAdd IMA Group

Add WMPT

Add IMA Link

Add Treelink PVCAdd NCP/CCP/

IPoA DeviceAdd ALCAP Add CES

Add AAL2 Path

Add Time SlotAcross

Add STM-1 Link

End



25/58


Board type Port number Work mode

WMPT 4 E1/T1 ports

When the interface board is the WMPT board, the total

number of the added IMA groups, IMA links, UNI links, and

Fractional ATM links should not be greater than 4.

UTRP 8 E1/T1 ports

When the interface board is the UTRP board, the total

number of the added IMA groups, IMA links, UNI links, and

Fractional ATM links should not be greater than 8.


Physical Links Configuration

Physical ports


26/58


Configuring Transport over ATM Physical Links Configuration

Add an UNI link

Header

256 bits/125 ls

ATM cell mapping field: 30 octets (TS1 - TS15 and TS17 - TS31)

TS0 provides F3 OAM functions:Performance monitoring (CRC-4)

Transmission of FERF and LOC

Performance reporting

Detection of loss of frame alignment

Header

Header

Header

TS16: Reserved for signaling

ATM cell 53 octets

Header


27/58




Add an IMA Group

PHY

PHY

PHY

PHY

PHY

PHY

ATMOriginal ATM cell streamfrom ATM layer

IMA group Physical I ink #0 IMA group

Recovered ATM cellstream to ATM layer

Physical I ink #1

Physical I ink #2

IMA virtual link


28/58


Configuring Transport over ATM Physical Links Configuration

Adding a Fractional ATM Link

Bearing port No. : defines the E1/T1 No. on the WMPT and UTRP

BTS3900 RNC Iubinterfaceboard

WMPT E1 0/1Fractional ATM linkATM cell carrying

3G data

Fractional E1 slots available for ATM

cell, others may be used by 2G BTS

Transport other informationrather than ATM cell


29/58




Adding a Timeslot Across Channel

Add the corresponding Fractional ATM link on WMPT and UTRP E1/T1 0 first.

BTS3900 RNC Iub

interface

board

timeslots available on

NDTI No.2/3 E1/T1

ATM cell carrying 3G data

2G BTS data 2G BSC data

Fractional ATM Link

Timeslot across channel

WMPT,UTRPNo.0 E1/T1

Fractional E1/T1timeslots are used

by Fractional ATM; other timeslots

are used by timeslot across channel


30/58



Adding NCP

Adding CCP

Adding ALCAP

Adding AAL2path Adding Tree link PVC

Adding OMCH


31/58



Definitions of NodeBs in direct/cascading connections

In direct connection, the NodeB is connected to the RNC directly or through transport equipment .

In cascading mode, the NodeB is connected to the RNC through another NodeB.


32/58


IPOA channel for direct connection

NodeB provides two modes of operation andmaintenance:

Near end operation and maintenance:

Far end operation and maintenance:

RNC

SNTP Server

M2000

Subnet 2 Subnet 3

IPoA local IP

IPoA Peer IP

RNC BAM IP

Subnet 5

Subnet 4

LMT 2

LMT1

Subnet 1

BTS3900

WMPT EthernetPort IP address



33/58


IPoA Channel for Cascading NodeB

Local BTS3900

IP1

Lower levelNode B

RNC LMT

IP4IP3

IP0BTS3900WMPT ETH IP

IP2

IP5IP6

The route to LMT(IP4), SNTP Server,

gateway: IP2(A) Configure IPoA(B) local IP: IP1

IPoA peerIP: IP2

(C) Configure LMTEthernet

IP: IP4

(D) Configure theroute to

BTS3900 (IP1),gateway:IP3

Configure the route tolower NodeB (IP6),

gateway:IP3

(B) Configurenetworking PVC

IPoA peerIP:IP5

The route toLMT(IP4)

gateway:IP5 Configure IPoAlocal IP: IP6



34/58


Example 1 Star NodeB Networking Configuration

RNC

NodeB

NodeB

E1

E1E1

ATM Network

Negotiation Data CME Configuration Demo


35/58


Example 2 Cascading NodeB networking

RNC NodeB1 NodeB2

E1

E1E1

ATM Network



36/58


Example 3 DBS3900 RRU Ring networking

BBU3900

RRU3804_1

RRU3804_2

RRU3804_3

RNC



37/58



Sector 1 Configuring Transport over ATM

Sector 2 Configuring Transport over IP


38/58


Configuring Transport over IP

Iub interface protocol over IP

Control Plane User PlaneRadioNetworkLayer

TransportNetworkLayer


NCP CCP

A C

CCP

NBAP

Data Link Layer

Physical Layer

Data Link Layer

RACHF

P

FACHF

P

IP

UDP

IP

SCTP

USCHF

P

CPCHF

P




39/58



TransportConfiguration

Configure the IP Route

Configure the PPP

End

Configure the MLPPPConfigure the timeslotCross channel

Configure the Dev IP

Configure the Qos Optional

Configure the SCTP

Configure the IPCP

Configure the OM

Configure the IP Path


40/58



Configure the PPP, MP, and Ethernet IP

In a single transport mode, configure one type of transport links.

In hybrid transport mode, configure E1 and FE transport links.

For E1 links, configure PPP or MP

For FE links, configure PPPoE or Ethernet IP

IP networkNodeB RNC

PDH/SDH

IP hybrid transmission


41/58



Configure the IP route

If the gateway type of the route is Ethernet, the next hop address and

the gateway IP address must be in the same network segment

If the NodeB and RNC are in layer 2 networking

The IP addresses of the FE ports on the NodeB and RNC should

be in the same subnet

If the NodeB and RNC are in layer 3 networking The next hop address is the IP address of the router that

connects to the NodeB or the IP address of the port on a layer 3

switch.

The destination address of packets has the corresponding route in the

routing table.

The corresponding link layer address can be found only when the

router specifies the next hop IP address (gateway).


42/58



Configure the QoSTo configure signaling and OM priorities

IP Quality of Service (QoS) is an IP network capability to provide

specific services over the IP network that uses mutiple bottom-layer

network technologies such as MP, FR, ATM, Ethernet, SDH, and

MPLS

IP QoS supports the switching between the IP precedence and DSCP

The IP QoS configuration is flexible


43/58



Configure the IPCP

Configure destination IP address & local IP interface, port type and

port number

The IP routes for destination addresses are available

Only one NCP can be configured

Several CCPs can be configured

The destination IP address, local port number, and destination port

number of the NCP/CCP on the same link should be different

When you choose one NCP/CCP on the NBAP tab page, the

corresponding links are displayed in the middle part, and the

corresponding routes are displayed in the lower part


44/58



Configure the OM

Ensure that the route from the LMT (or M2000) to

the subnet is configured

Only one OM channel can be configured

If you choose an OM channel in the upper part of

the OM tab page, the corresponding route is

displayed in the lower part

The destination IP address of the OM channel is

the IP address of the NodeB LMT or M2000


45/58



Configure the IP path

The IP routes for destination addresses are available

The IP path does not have bandwidth limit. Therefore, to configure the

IP path is to differentiate service priorities. When the HSDPA service

is transmitted, configure two IP paths with different path IDs. The two

paths correspond to R99 service and HSDPA service. There is noservice priority at the NodeB side. Therefore, configure one IP path at

the NodeB side

If you choose one path on the upper part of the IP path tab page, the

corresponding links are displayed in the middle part and the

corresponding route is displayed in the lower part


46/58


Example 1 IP Networking Configuration

Node B

Node B

Data Network

FE

FE FE MediaConverter

RNC

GE/FE



47/58


Example 2 Dual Stack Networking

Metro Core(Existing)

RNC

E1(CS/signalling)

GE

STM-1

STM-1

FE (PS)

E1(CS/signalling)

FE(PS)

OSN

Metro

Metro

Node B

Node B

GE

RNC



48/58


Example 3 IP Apart Networking

Metro Core(Existing)

RNC

IP over E1

GE

STM-1

STM-1

IP over FE

IP over E1

IP over FE

OSN

Metro

Metro

Node B

Node B

GE

RNC



49/58








50/58


Configuring Local Cell

Procedure of Local Cell Configuration

Add

Site

Add

Sector

AddLocal

Cell

Localcell


51/58


Configuring Local Cell Adding Site

Adding a site to the NodeB

Note

A site number within one

NodeB must be unique.

Adding SectorAdding a sector to the NodeB

Note

A sector number must be unique within one NodeB

Configuring a sector is mainly configuring the corresponding

antenna and feeder system


52/58


Configuring Local Cell

Adding Local Cell

Adding a local cell to the NodeB

Note

Local Cell ID must be unique within thesame NodeB

Negotiated with the peer end RNC

Local Cell ID

Uplink Frequency

Downlink Frequency


53/58







Addi N d B Th h h T l Fil


54/58


Adding a NodeB Through the Template File

Saving a Existing NodeB as Template file


55/58


Saving a Existing NodeB as Template file

Typical 3*1 Configuration Expansion


56/58



3*1/3*2 3*3 3*4 3*5/3*6

AEach carrier 20W

BEach carrier 15W

3*1 3*2/3*3 3*5/3*6 3*6/3*73*4 3*8


57/58



AEach carrier 20W configuration

3*2 3*3 3*4 3*5/3*6

BEach Carrier 15W configuration

3*2 3*3/3*4 3*5/3*6 3*7/3*8


58/58

Thank You

www.huawei.com

Date post:	04-Apr-2018
Category:	Documents
Upload:	rngwena
View:	235 times
Download:	0 times

97420099 WCDMA NodeB Data Configuration

Documents