04 gu per zxur 9000 introduction（ur11.2&ur12）v2.20_20130202

ZXUR 9000 Product Introduction

GSM&UMTS Dual Mode

Chapter 1 General Introduction

Chapter 2 Product Description

Chapter 3 Product Highlights

Chapter 4 Product Configuration

© ZTE Corporation. All rights reserved.

ZXUR 9000 Location in Mobile Network

SGSN GGSN

BTS/NodeB

BSC/RNC

NodeB

BTS

BSC/RNC

BTS/NodeB

MSC-S/VLR GMSC-S

Other-PLMN

PSTN

MGW GMGW

Gb/IuPs

A/IuCs

A/IuCs Mc

Nb

Nc

Iur/Iur-g

Gb/IuPs

ZXUR 9000

Abis/Iub

Abis/Iub

Abis

Iub

CS Data PS Data

CS/PS Mixed Data

Signaling

3


Functionality of ZXUR 9000 in General

ZXUR 9000

ZXUR 9000

Node B

Node B

Node B

Abis/Iub

Iur-g

GERAN/UTRAN

BSC/RNC Basic Function

System information broadcast and

MS access control

Mobility management such as

handover, relocation, etc.

Radio resource management such as

power control, cell resource

allocation, etc.

CS and PS RAB services

Radio channel encryption for

transmitted data and signaling

4


Design Based on ZTE Common Hardware Platform

CSCF

AGCF

BGCF

MGCF

MME

PDN-GW

Serving-GW

PSS/PES

IM-MGW

MSCs/MSCe

MGW

BSC

RNC

USPP

SGSN

GGSN

AGW

PDSN/HA

All IP Platform Design

BSC/RNC/CN Co- Platform

GSM/UMTS/CDMA Co-Platform

Common platform enhance board integration, system stability and save spares

GSM and UMTS networks share interfaces and transmission, saving cost

Unified OMC simplifies O&M, saves manpower and unifies GU capacity planning

Resource pool, flexible GU resource allocation

Unified RRM realizes intelligent access, handover and GU load balance

Converged OMC Platform

Co

nvergen

ce

5


ZXUR 9000 Rack Components

The rack:

600mm width*800mm depth, in line with

ETS 300 119 or IEC60297 standard

2200mm height, support 3 sub-rack

configuration

Sub-racks are configured by sequence:

main sub-rack first, than sub-rack 1 and 2

Extension sub-rack

2

Power distribution sub-rack:

3U height, in top of the rack

Provide power distribution for the whole

system, power indication and outer

environment monitoring function

Dual power input, support automatic

switch between 2 power input

Wind guide sub-rack:

Provide wind duct for forward/backward wind to isolate the system wind duct and improve cooling efficiency

The wind duct is below service sub-rack.

The wind duct for main sub-rack is 2U height, and for extension sub-rack is 4U. Wind duct for each sub-rack is placed below the sub-rack.

Main

sub-rack

Extension sub-rack 1

6


ZXUR 9000 Service Sub-rack Introduction

7

19 inch standard shelf

Front and rear plug-in shelf for each sub-racks, each

have 14 slots

Processing boards and O&M boards in front shelves ,

designed with ATCA standard board

Interface boards and switching boards in rear shelves

ZXUR 9000 shelf (Front, Rear, Side view)

ZXUR 9000 includes two types of sub-racks:

Main sub-rack, service handling plus O&M and

clock function, compulsory for configuration.

Extension sub-rack, service handling, configured

based on capacity requirement, configured from 0-2.

Components of each sub-rack (from top to

bottom) ：

FAN unit (3 FANs, 2 for front shelf heat dissipation,

1 for rear shelf heat dissipation)

Plug-in boards (front board 8U, rear board 9U)

Power unit (each sub-rack configure 2)

ZXUR 9000 Rack

Distributed design, resource pool for service handling ensure high reliability, strong processing capability with high efficiency.

7


ZXUR 9000 System Architecture

ZXUR 9000 is designed with all IP switching architecture.

Logical units including: access unit, switching unit, processing unit, O&M unit etc.

Power, FAN

Processing Unit

O&M

Environment Monitoring Unit

Access U

nit

Switch

ing

Un

it

ZXUR 9000

BTS/Node B

BSC/RNC

CN

STM - 1

E 1 FE GE

485

Abis/Iub

Iur-g/Iur

A/Gb/Iu

9


ZXUR 9000 Board Classification

Switching Board

Processing Board

Interface Board

Switching board deals with the switching in control plane (BASE) and media plane (FABRIC). Besides the intra-shelf switching, it also provides switching channels for all inter-shelf communication.

Processing board handles the protocol processing in control plane and user plane, and is responsible for the overall processing and control in terms of O&M.

Interface board offers access of STM-1, E1/T1, CSTM-1 via interfaces including A, Abis, Gb, Iu, Iub and Iur to meet various requirements of networking.

10


Switching and Processing Board

Boards Full Name Function Description Conf. Principle

EGBS Enhanced GE Base Switch board

Handles switching in BASE, namely control plane; provides switching channels for all intra-shelf and inter-shelf communication in control plane.

The number of EGBS is always 2 for each shelf. GSM and UMTS can share these 2 EGBSs.

EGFS Enhanced GE Fabric Switch board

Handles switching in FABRIC, namely media plane; provides switching channels for all intra-shelf and inter-shelf communication in media plane. Provides clock function.

The number of EGFS is always 2 for each shelf. GSM and UMTS can share these 2 EGFSs.

11

Physical Boards Full Name Logical

Boards Function Description Conf. Principle

USP Universal Service Process board

RUP Processing in user plane; handles the voice and data processing within system. Capacity decides the

number of USP. GSM and UMTS should configure respectively. DMP is for UMTS only.

CMP Control plane processing, for common signaling processing among cells

DMP Control plane processing, dedicated for user signaling processing irrelative with cells

UMP Universal Management Process board

OMP Overall management 2 OMPs, 2 OMMs. GSM and UMTS share the boards. OMM Local O&M

ETCB Enhanced Trans Coder Board

Support transcoding and rate adaptation. Apply to GSM only

Switching Board

Processing Board


Interface Board Boards Full Name Function Description GSM or UMTS

EAPB Enhanced ATM Process

Board

Offer interface for ATM over

STM-1 Apply to UMTS only

EDTA Enhanced Digital Trunk board

ATM version Offer interface for ATM over E1 Apply to UMTS only

ESDTA Enhanced SDH Digital Trunk

board ATM version

Offer interface for ATM over

channelized STM-1 Apply to UMTS only

EDTI Enhanced Digital Trunk board

IP version Offer interface for IP over E1 Apply to GSM and UMTS

ESDTI Enhanced SDH Digital Trunk

board IP version

Offer interface for IP over

channelized STM-1 Apply to GSM and UMTS

EGPB Enhanced GE Process Board Offer GE/FE interfaces Apply to GSM and UMTS

ESDTG Enhanced SDH Digital Trunk

board GSM version Offer access of TDM CSTM-1 Apply to GSM only.

EDTT Enhanced Digital Trunk board

TDM version Offer access of TDM E1/T1 Apply to GSM only

ESDTT Enhanced SDH Digital Trunk

board IP version Offer access of TDM CSTM-1 Apply to GSM only

Abundant interfaces for different networking requirements

12


Signaling Processing Flow-GSM/UMTS

Signaling Processing Flow

13


Service Processing Flow-GSM(IP A)/UMTS

CS Service Processing Flow

PS Service Processing Flow


14


Service Processing Flow-GSM(TDM A)


PS Service Processing Flow

15


Huge Capacity & Flexible Combination

1. Software configuration only to realize working mode adjustment, cost free migration from GSM to UMTS. 2. G/U capacity is a combination of GSM and UMTS capacity, just for example.

Conf. Working

Mode TRX Site Cell Erl BHCA(K)

PS Thr. (Gbps)

MCS9 PDTCH（K

）

Single Shelf

G 3,200 1,200 1,200 19,200 5,600 NA 11.2

U NA 900 1,800 36,000 7,000 6.4 NA

G/U 1,920/NA 720/450 720/900 11,500/18,00

0 2,800/3,500 NA/3.2 6.7/NA

Two Shelves

G 8,320 2,800 3,120 49,900 14,000 NA 29.1

U NA 2,250 4,500 90,000 17,400 16 NA

G/U 3,200/NA 1,600/1,350 1,200/2,700 19,200/ 54,000

5,600/ 10,500

NA/9.6 11.2/NA

Three Shelves

G 12,250 2,800 5,600 73,500 16,800 NA 42.8

U NA 2,800 5,600 234,000 13,050 41.6 NA

G/U 5,760/NA 2,160/2,250 2,160/4,500 34,500/ 90,000

8,400/ 17,400

NA/16 20.1/NA

16


Huge Capacity in One Rack

Traffic 234,000Erl

BHCA 29,000k

Throughput 41.6Gbps

Node B 2800

Cell 5600

UMTS Single Mode Capacity

IP-based switch platform, data transmission with high efficiency.

High integrity design, realize huge capacity, facilitate expansion and evolving data processing capability.

ZXUR 9000

Traffic 73,500Erl

BHCA 16,800k

MCS9 PDTCH 42,800

TRX 12,250

GSM Single Mode Capacity

Traffic 34,500Erl+90,000Erl

BHCA 8,400k+17,400k

Throughput 1.01 Gbps+16Gbps

Cell 2,160+4,500

GU Dual-Mode Capacity (Typical Value GSM+UMTS)

18


Rich Interface Types for Various Networking Requirements

19

2G&3G share switch unit

2G&3G share O&M unit

2G&3G share IP interface unit

ATM interface unit for 3G

TDM interface unit for 2G


High Reliability Design—All Boards Have Backup

Logical Unit Physical Board

Logical Board Backup Method

O&M Unit UMP OMM 1+1

OMP 1+1

Access Unit

EAPB EAPB 1+1

ESDTA ESDTA 1+1

EDTA EDTA Load sharing

EGPB EGPB 1+1, load sharing

EDTI EDTI 1+1

ESDTI ESDTI 1+1

EDTT EDTT 1+1

ESDTT ESDTT 1+1

ESDTG ESDTG 1+1

Switch Unit EGBS EGBS Load sharing

EGFS EGFS Load sharing

Processing Unit

USP RUP/DMP Load sharing

CMP 1+1

ETCB ETCB Load sharing

20


Based on Unified Platform, Flexible Dual Mode Resource Sharing and System Processing

Co-rack, co-shelf, co-power supply, FAN and

other fundamental facility

Co-boards (interface board, switching board

and O&M board)

Share hardware of processing board, only software configuration to adjust working mode

IP transmission resource sharing to improve

efficiency

Co-network operation and management

Unified RRM (cell load sharing between 2G and

3G)

21


ZXUR 9000 Configuration Principle and Highlight

3-layer shelf, main shelf is preferred for the lower layer.

Every shelf is composed of front and rear plug-in shelf, with 14 board slots for each.

UMP is fixed in No. 5-8 slot in front plug-in shelf; EGBS and EGFS fixed in No. 19-22 slots in

rear plug-in shelf; interface board is configured in rear plug-in shelf, while USP and ETCB in

front plug-in shelf, and no slot limitation for these boards.

The configuration of processing boards depends on traffic model and have several

limitations for each board need to be considered and calculated.

23

Almost non-limitation on slot design, easy to expand. Flexible and easy configuration for

conversion between GSM and UMTS modes.

Any idle slot is available, high shelf utilization.

Highlight

Configuration Principle


Processing Board Capability

Index CMP RUP ETCB PDCH - 5000 -

CS Erl - 7000 4800

Cell 1024 560 -

BHCA (K) 2800 - -

TRX 2048 - -

Index CMP DMP RUP MAX PS Throughput(Mbps) - - 1600

MAX CS Erl （non encrypted） - - 9000

BHCA (K) 4350 2900 -

Cell 1200 - -

Online Subs. (D+F+P) 120000 65000 34000

Online Subs. (D+F) 120000 65000 8000

GSM Mode：

UMTS Mode：

Remark: D-DCH, F-FACH, P-PCH For UMTS, The PS index of RUP is based on subscribed MBR 4M, HS896/128 with 2K signaling (UL+DL)

24


Processing board Calculation in GSM mode

In GSM detail calculation, USP consists of RUP and CMP, and ETCB is needed as A interface

adopts TDM transmission type, the formulas are shown as following:

N_USP= N_CMP+ N_RUP

N_CMP= ROUNDUP (MAX (N_BHCA/ 2800K, N_TRX/ 2048, N_Cell/ 1024)/ (1-RelayP), 0)*2

IP A:

N_RUP= MAX (2, ROUNDUP (MAX (N_Cell/ 560, N_MCS9/ 5000）+N_Erl/ 7000)/ (1-RelayP), 0))

TDM A:

N_RUP=MAX (2, ROUNDUP (MAX (N_Cell/ 560, N_MCS9/ 5000)/ (1-RelayP), 0))

N_ETCB= MAX (2, ROUNDUP ((N_Erl/4800, 0)/ (1-RelayP), 0))

Ater :

N_RUP=MAX (2, ROUNDUP (MAX (N_Cell/ 560, N_MCS9/ 5000)/ (1-RelayP), 0))

In which:

• N_BHCA: Number of BHCA

• N_TRX: Number of TRX

• N_Cell: Number of Cell

• N_MCS9: Number of PDCH

• N_Erl: Number of Erl

• RelayP: Processing redundancy ,default as 10%

25


Processing board Calculation in UMTS mode

In UMTS detail calculation, USP consists of RUP, CMP and DMP, the formulas are shown

as following:

N_USP= N_CMP+ N_DMP+ N_RUP

N_CMP= ROUNDUP (MAX (N_BHCA/ 4350K, N_Cell/ 2000, N_PDF/ 120000)/ (1-RelayP), 0)* 2

N_DMP= MAX (2, ROUNDUP (MAX (N_BHCA/ 2900K, N_PDF/ 65000)/ (1-RelayP), 0))

N_RUP= MAX (2, ROUNDUP (MAX ((N_PS/ 1600 +N_Erl/ 9000), N_PDF/ 34000)/ (1-RelayP), 0))

In which:

• N_RUP: Number of RUP

• N_PS: Throughput of PS

• N_BHCA: Number of BHCA

• N_Erl: Number of Erl

• N_Cell: Number of Cell

• N_PDF: Number of active subscribers in PCH, DCH or FCH cell

• RelayP: Processing redundancy ,default as 10%

26


Interface Board Dimensioning

The limitation factor for interface board is listed in the following table:

27

Interface

Board

Port

Number

NodeB

Number Throughput Capacity Time Slot CID

EDTA 32 E1 42 NodeB Max 60Mbps (UL or DL) - 1260K/h CID setup and delete

EAPB 4 STM-1 420 NodeB Max 300Mbps (UL or DL) - 1260K/h CID setup and delete

ESDTA 4 CSTM-1 168 NodeB Max 300Mbps (UL or DL) - 1260K/h CID setup and delete

EDTT 32 E1 - -

Abis: 992 TS

- A: 992 TS

Ater: 792 TS

ESDTT 4 CSTM-1 - - A: 7812 TS -

ESDTG 4 CSTM-1 - -

Abis: 3906 TS

- A: 7812 TS

Ater:3168 TS

EDTI 32 E1 512 NodeB

(PPP)

55 Mbps(DL) and 110 Mbps (UL+DL)

-


Interface board Capacity Interface

Board Port Number

NodeB

Number

Throughput

Capacity Time Slot

ESDTI 4 CSTM-1 512 NodeB

(PPP)

Abis:(160Byte) DL:440M

DL+UL:800M

Gb:(200Byte) DL:250M

DL+UL:500M

Iub:(340Byte) DL:440M

DL+UL:880M

IuCS:(95Byte) DL:440M

DL+UL:470M

IuPS:(660Byte) DL:440M

DL+UL:880M

EGPB 4 GE 400 NodeB

(1588V2)

Abis:(160Byte) DL:1110M

DL+UL:1110M

A:(95Byte) DL:660M

DL+UL:660M

Gb:(200Byte) DL:1390M

DL+UL:1390M

Iub:(340Byte) DL:2360M

DL+UL:2360M

IuCS:(95Byte) DL:680M

DL+UL:680M

IuPS:(660Byte) DL:4590M

DL+UL:2880M


ZXUR 9000 Summary

29

Huge capacity, high integrity, easy to expand, effectively saving footprint; adapt to various environment and fast growth of traffic load, protecting operators’ investment.

All-IP structure meets the requirement of network evolution. Compared with TDM/ATM platform, IP switch management features convenient maintenance, simple configuration, flexible expansion, higher delivery efficiency and more flexible delivery mechanism.

The entire system adopts redundancy design by platform and high reliability. No single point fault, online software download supported, loading and being activated in remote.

Simple configuration, convenient maintenance. Few board types, including processing, interface and switching boards, making configuration simpler and expansion easier, also reducing spare parts types, cutting down maintenance cost.

Abundant interfaces, flexible networking, TDM/ATM/IP protocol stack and diverse physical interfaces like E1, STM-1, channelized STM-1, FE and GE supported, flexibly responding to transmission changes.

ZXUR 9000

Complete transmission and processing resources sharing between GSM and UMTS, unified RRM realizing users flexible access to Gu network, balancing loads, maximally utilizing network resources. Smooth evolution from 2G to 3G by software upgrading.


SW Configuration for Mode & Capacity Modification

Capacity modification by software configuration

Mode modification by software configuration

Flexible and easy mode modification or capacity modification.

GSM GSM

UMTS

GSM

GSM

U G

U G

U G

U G

U G U G

U G

30


IP Transmission Resource Sharing

31

Phase I: Static Allocation, Configurable

Phase II: Dynamic Allocation

BTS/Node B BSC/RNC

BSC

RNC Manual Configuration

Period 1

Period 2

Period 3

Abis Iub

Abis Iub

Abis Iub

BTS/Node B BSC/RNC

BSC

RNC Dynamic Adaptation

Period 1

Period 2

Period 3

Abis Iub

Abis Iub

Abis Iub


Efficiency Improvement – Co-O&M Platform Existing O&M

GSM EMS

Area 1

BSC

RNC EMS

RNC

Area 2

BSC/RNC UEMS

Unified O&M

Area 1

BSC/RNC

Unified O&M in BSC/RNC

Centralized FM: combined/optimized alarms

Centralized PM：KPI optimization

Integrated CM：Simplified configuration, inter NE

configuration

Unified Platform, integrated O&M

32


Distributed Co-RRM, G/U convergence

Synthesis strategy including: G/U radio resource access control, transmission resource access control, cell attribute access control.

Access Control

Congestion Control

Procedure including: G/U optimized handover target cell selection and handover procedure.

Handover Control

Load Control

Co-RRM Key Algorithm

Strategy including: first resort on intra system load balance then inter system load balance; specific service first resort on inter system balance.

Load Balance

Unified loading standard between different modes

Co-RRM Entities exchange content（Static Information, Dynamic Information, Cell synthesis load）

CoRRM Entities exchange method (Requiring or reporting)

Co-RRM Algorithm highlights

Optimized inter system handover procedure

Optimized load balancing strategy

Unified transmission and radio resources management

Optimized resource alarm, congestion control and load control

Strategy including: G/U triggered inter system handover, service release, re-configuration of transmission resource

Co-RRM enhance the co-operation between GSM and UMTS networks, optimize resource

utilization and service provision, improves service quality.

Synthesis Estimation strategy optimize inter system load balancing.

33


Performance Improvement – Co-RRM

Inter-RAT handover based on GSM load

Load information sharing

between GSM & WCDMA:

Load value

RT load

NRT load

Cell capacity

GSM Coverage

UMTS Coverage

Inter-RAT handover based on WCDMA load

BSC/RNC

BSC

RNC

34


Performance Improvement –Inter-RAT Handover

BSC RNC

UMTS/GSM CN

Legacy Inter-RAT IWK

From core-route mode to intra shelf/inter shelf information exchange

Low delay and unlimited information sharing, unbelievable inter-RAT cooperation

efficiency and performance!

ZXUR 9000 inter-RAT IWK

GSM

UMTS

G/U

Internal Processing

35


Processing Board Capability

For UMTS, the PS index of RUP is based on subscribed MBR 4M, HS896/128 with 2K signaling (UL+DL). And for the different average rate of PS active user, the capacity of RUP is changed. The relation between VACT and TRUP is following the table below:

In which:

VACT : The average rate of PS active user

TRUP: The throughput capacity of RUP

The CS index of RUP is based on VAF is 0.5. With different VAF, the non encrypted CS capacity of RUP is 9000*0.5/VAF, and the range of VAF is 0.5-1.

36

VACT

(Kbps) 16 32 48 64 96 128 192 256 512 1024 2048 4096

TRUP

(Mbps

)

110 190 270 330 450 530 570 620 740 900 1040 1600


ZXUR 9000 GSM&UMTS Dual-Mode Configuration Method1: Calculate GSM and UMTS capacity separately, common boards such as UMP, EGBS, EGFS are shared, for

interface boards, processing boards configured separately.

Method 2: GSM and UMTS both have typical configuration packages for processing boards of different capacity demands.

Example:

GSM IP A(2400TRX,13KErl)+ UMTS (2000 cell, CS 14KErl, PS 5Gbps)

Choose and combine the suitable packages：GSM step 5 + UMTS step 3.

Y-1 Single shelf Y-2 Two shelves Y-3 3 shelves

G U

IPA TDM TC外置

#1 #2 #3 #4 #5 #6 #7 #8 #9 #10 #11 #12 #13 #14 #15 #1 #2 #3 #4 #5 #6 #7 #1 #2 #3 #4 #5 #6 #7 #8 #9 #10 #11

#1 Y-1 Y-1 Y-1 Y-2 Y-2 Y-2 Y-2 Y-2 Y-3 Y-3 Y-3 Y-3 Y-3 Y-1 Y-2 Y-2 Y-2 Y-2 Y-2 Y-3 Y-1 Y-1 Y-2 Y-2 Y-2 Y-2 Y-2 Y-2 Y-3 Y-3 Y-3

#2 Y-2 Y-2 Y-2 Y-2 Y-2 Y-2 Y-3 Y-3 Y-3 Y-3 Y-3 Y-2 Y-2 Y-2 Y-2 Y-2 Y-3 Y-3 Y-2 Y-2 Y-2 Y-2 Y-2 Y-2 Y-2 Y-3 Y-3 Y-3 Y-3

#3 Y-2 Y-2 Y-2 Y-2 Y-2 Y-2 Y-3 Y-3 Y-3 Y-3 Y-2 Y-2 Y-2 Y-3 Y-3 Y-3 Y-3 Y-2 Y-2 Y-2 Y-2 Y-2 Y-3 Y-3 Y-3 Y-3 Y-3

#4 Y-2 Y-2 Y-2 Y-2 Y-3 Y-3 Y-3 Y-3 Y-2 Y-2 Y-3 Y-3 Y-3 Y-3 Y-3 Y-2 Y-2 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3

#5 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3

#6 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3 Y-3

#7

#8

#9

#10

#11

#12

#13

37


Thanks!

04 gu per zxur 9000 introduction（ur11.2&ur12）v2.20_20130202

Technology

Transcript of 04 gu per zxur 9000 introduction（ur11.2&ur12）v2.20_20130202