Security Level:
LTE Transport Solution
Huawei
HUAWEI TECHNOLOGIES CO., LTD.
Huawei Confidential
www.huawei.com
Content
LTE Transport Network Interface
LTE Transmission Network Requirements
LTE Transmission Transmissio n Key Technologies
Huawei LTE Transport Solution
Page 2
Content
LTE Transport Network Interface
LTE Transmission Network Requirements
LTE Transmission Transmissio n Key Technologies
Huawei LTE Transport Solution
Page 2
LTE Transport Network Interface S11 MME
S-GW
S 1 C
S 1 U
Clock server OAM
X2 (X2-C, X2-U) eNodeB
eNodeB
The Transmission network of LTE consist of: S1 interface X2 interface The data to be transmitted over the transmission network are: S1 interface data including S1 Control Plane (S1-C) and S1 User Plane (S1-U) d ata X2 interface data including X2 Control Plan (X2-C) and X2 User Plane (X2-U) data OAM, Operation And Maintenance data Clock synchronization data Note that S11 S11 interface is part of the core network, so its specification is not covered by eRAN transport solution.
Page 3
Content
LTE Transport Network Interface
LTE Transmission Network Requirements
LTE Transmission Key Technologies
Huawei LTE Transport Solution
Page 4
LTE Transmission Requirements
SON …
QoS
Co-transmission
Security …
Maintainability
Reliability
LTE
…
Traditional Transmission Network
Page 5
Bandwidth Requirement Access technologies
3G(R99/R4) UL: 384 Kbps DL: 384 Kbps
LTE 3G/HSPA+(R8) UL: 50 Mbps DL: 100 Mbps UL: 11 Mbps 3G/HSxPA(R6/R7) DL: 42 Mbps UL: 5.76 Mbps 3G/HSDPA(R5) DL: 14.4 Mbps UL: 384 Kbps DL: 14.4 Mbps
Service Bandwidth
64~144 kbps
64~384 kbps
2002-2003 2003-2004 • • •
384 kbps ~ 5 Mbps
3~20 Mbps
2005-2006 2006-2009
10~50 Mbps
2008-2012
LTE-advanced UL: 500 Mbps(?) DL: 1000 Mbps(?)
20~100 Mbps
2009-2015
100~1000 Mbps(?)
2011-?
Bandwidth demand will be multiplied by 3~10 time in 2011 and beyond The transmission network technology must keep up with the access technology development Operators are looking for a mobile transmission network solution that is able to provide enough bandwidth to support the access technology traffic flow while saving CAPEX and OPEX. Page 6
Synchronization Requirements 1.
2.
Frequency stability requirements • For eNodeB, the frequency accuracy should be better than
0.05 ppm
Phase/time requirements • •
For eMBMS SFN, the time accuracy should be better than 4 s For TDLTE, the time accuracy should be better than 1.5 s
Page 7
QoS Requirements Compared to 2G/3G network, transmission over LTE backhaul required reduced and strict packet delay and packet error loss rate
Resource
Priority
Packet Delay Budget
Packet Error Loss Rate
2
100 ms
10-2
Conversational Voice
4
150 ms
10-3
Conversational Video (Live Streaming)
3
5
300 ms
10-6
Non-Conversational Video (Buffered Streaming)
4
3
50 ms
10-3
Real Time Gaming
5
1
100 ms
10-6
IMS Signaling
6
7
100 ms
10-3
Voice, Video (Live Streaming) , Interactive Gaming
QCI
Type
1 2 GBR
7
Non-GBR
6
8
8
9
9
Example of Services
Video (Buffered Streaming) 300 ms
10-6
TCP-based (e.g., www, e-mail, chat, ftp, p2p file sharing, progressive video, etc.)
AMBR: Aggregate Maximum Bit Rate ~ QCI: QoS Class Identifier ~ CoS: Class of Service ~ GBR: Guaranteed Bit Rate
Page 8
Security Requirement • •
3GPP has defined no security for the backhaul, i.e. t he transmission between eNodeBs and between the eNodeB and MME/S-GW For non-trusted network, IPSec should be used.
Tunnel mode IPSec
MME
IPSec function
Transport mode IPSec
S-GW
SEG IPsec
MME
S-GW
IPsec
IPsec
Security gateway
LTE
IPsec
IPsec
IPsec
IPsec
eNB
eNB
eNB
eNB
IPsec
IPsec
IPsec
IPsec
eNB
eNB
eNB
eNB
The eNodeB should support IPSec tunnel mode, and IPSec transport mode is optional
Page 9
Reliability Requirement Redundancy: the eNodeB and backhaul should provide different redundancy solutions based on backhaul design, this must include port redundancy and board redundancy.
End-to-end redundancy
S-GW/MME (S1 interface)
Work path
eNode B Transport layer Network layer Data link layer
Backhaul transport network
Traffic flow protection Control Plane
User Clock Plane data
Traffic flow protection Control Plane
Protection path
OAM data
Work path
Port Board PHY layer redundancy redundancy Protection path
Backhaul transport network
Segment-by-segment redundancy
Work path
User Plane
Board Port redundancy redundancy
Transport layer Network layer Data link layer PHY layer
Protection path
OAM backup
Page 10
Clock Server (optional)
Maintainability Requirement •
Network Management Quality: • Service quality Monitoring • Fault prediction (active maintenance) • Fault location and fast recovery
•
Two scenarios • E2E maintenance • Segment by segment maintenance
Transport equipment eNode B
Transport network
Transport equipment GE/FE
S-GW/MME
End-to-end (X2 interface)
Seg-by-Seg
eNode B End-to-end (S1 interface)
Page 11
Co-transmission Requirement •
LTE will co-exist with legacy netw ork for longtime
•
Transmission sharing with legacy network (co-sitting with 2G/3G network)
•
Simultaneous use of different technologies (IP, TDM)
•
Maximum reuse of existing resource is a big challenge
S-GW UMTS Node B
eNode B
Backhaul transmission network
MME
RNC GSM BTS
eNode B
GSM BSC
Page 12
SON Requirement
The main goal of SON is to minimize transport operational effort and cost, and to increase the network performance and quality. With the lack of RNC, SON is used to facilitate the communication among eNodeBs that are linked directly to the backhaul and distributed in the network.
Selfoptimization: routing optimization
The main functions of SON include: self-planning, selfdeployment, self-optimization and self-maintenance.
Selfmaintenance: Automatic Neighbor Relation
Selfdeployment: transport parameters setup
Self-planning: transport parameters planning
Page 13
Content
LTE Transport Network Interface
LTE Transmission Network Requirements
LTE Transmission Key Technologies
Huawei LTE Transport Solution
Page 14
Mobile Backhaul Structure PoC3
PoC2
PoC1
TDM MW or Packet MW
eNodeB
FE/GE
VDSL eNodeB
GPON
P2P fiber eNodeB RNC/GGSN/SGW/MME/HSS/HLS/O AM/…
Access LTE
• • •
Metro/aggregation
Core
Backhaul
SAE
Mobile backhaul can be divided into access layer, metro/aggregation layer and the core layer. The part of the access layer that is connected to the eNodeB is called the last mile solution. It consist of the most important part of the transport solution. However, the transmission networking includes also synchronization, QoS, security, reliability, maintainability and SON different key technologies. PoC: Point of Convergence
Page 15
The Last Mile Bandwidth Solution 1 1
Packet microwave access
Ethernet packet microwave: low TCO and high capability
Dynamic Adaptive Modulation can dynamically improve the spectrum efficiency, providing more transport bandwidth. It can increase the bandwidth efficiency up to 400%
Page 16
The Last Mile Bandwidth Solution 2 P2P Fiber/ADSL/VDSL/GPON access
2 Technology
ADSL2+/VDSL2/G, SHDSL,. copper Based VDSL2
Fiber-based: GPON/P2P
Distance
<1km
>5km
bandwidth
>25 Mbps
>=100Mps
P2P fiber eNodeB ONU
GE
eNodeB GE
Splitter
GE
transport network
ONU
GPON DSLA M
eNodeB
MME/S-GW /PDN GW
Mini DSLAM
FE eNodeB
ADSL2+/SHDSL/VDSL2 modem
P2P fiber/VDSL2 support flexible capacity upgrades once the base stations are connected
An ADSLVDSL/GPON co-platform DSLAM
Carrier grade IP DSLAM
Page 17
Flexible Synchronization Solution Frequency synchronization ①
GPS
②
BITS
③
From legacy base station when co-sites
④
IEEE1588v2
⑤
E1/T1 line clock (if E1/T1 used)
⑥
Huawei clock over IP @Ethernet
⑦
Synchronous Ethernet
⑧
1PPS
clock path 1 GPS
4 IEEE 1588v2 IP/Ethernet FE/GE Network Traditional network
2 BITS
S-GW/ MME FE
eNode B
(Clock client)
3 legacy BS
BITS or Clock server
Time or phase synchronization
• • • • • •
①
GPS
⑤
IEEE1588v2
⑧
1PPS+ TOD
5 E1/T1
7 Sync. Ethernet
6 Clock over IP@Eth
8 1PPS+ TOD
Provide E2E clock solution Support clock redundancy Unified clock server solution for LTE and legacy BTS The clock server can be either a stand alone equipment or integrated in S-GW /MME/OMC Moreover, When all external clock sources are lost, the internal clock of the eNodeB, OXCO can keep it on normal service up to 90 days. Compares to GPS, IEEE1588v2 is cost-effective and suit better to indoor coverage
Page 18
E2E QoS Solution IEEE802.1P
MPLS TE/IP DiffServ
IEEE802.1P/DSCP
PE eNodeB PE MME/S-GW /PDN GW
IP/ MPLS network eNodeB Pre-marker DSCP and CoS
user 1 user 2 user 3 user n
1.
2.
Classify accordingly to DSCP or CoS
Et
Mobile VoIP Video Internet
Pre-marker DSCP and CoS
Service differentiation QoS mapping Traffic shaping Scheduling Transport resource allocation Congestion control Admission control
Qos Mapping • Traffic QoS: user plan traffic ( based on QCI, GBR, Non-GBR, priority), signaling, IP clock and OAM data. • IP layer: DSCP marking, DiffServ • Data link layer: Ethernet Qos (IEEE802.1P/Q), VLAN based traffic separation. Traffic shaping • Logical port shaping • Physical port shaping MPLS: Multi Protocol Label Switching ~ SDSCP: Differentiated Ser vice Code Point ~ CoS: Class of Service
Page 19
L2VPN and L3VPN Comparison
Feature
Layer 2 VPLS
Layer 3 MPLS
Dynamic Path establishment
Supported with VPLS
Supported with MPLS
Ability to route between directly connected cell site
Not supported if on separate broadcast domain (Layer3 needed to go between broadcast domains)
Supported
End-point Identification
Mac address
IP address
IP address transparency
Supported
Not supported without layer 3 VPNs
CAPEX
Less expensive
More expensive
OPEX
Lower
Higher
QoS capability
Low
Higher
Broadcast domains
Supported (both point-to-point and multi-point)
Not supported in routed network
Network expansion
Manual effort configuration-intens ive
Easier with support of Automatic Discovery
Page 20
Security Solution
Air interface: ciphering, SNOW 3G and AES. Transport module and transport equipment: the target is to try to keep security breaches as local as possible by using a security gateway. 1.
Scenarion1: Non- trusted network Security Gateway FE/GE
IP/Ethernet network (Non-trusted)
IP/Ethernet network (trusted)
FE/GE
eNodeB S-GW/MME
SSL tunnel for OAM data
eNodeB OMC The eNodeB supports IPsec
IPSec tunnel for all traffic flow on S1/X2
SSL tunnel for OAM data
IPSec for all traffic over S1 interface and X2 interface
IPSec tunnel mode is recommended, but the transport mode can also be used
If required, IPSec and SSL can be used together for AOM data protection
ACL for firewall SSL - Security Socket Layer ~ ACL-Access Control List
Page 21
Security Solution 2.
Scenario2: Trusted network
VLAN for Ethernet network MPLS VPN for IP/MPLS network
PE Ethernet S-GW/MME eNodeB
PE
IP/MPLS Network
Ethernet PE
VLAN for Ethernet network
eNodeB
PE: Provider Edge ~ LSP: Label Switch Path
Page 22
Reliability Solution route backup: active route + backup route
GE
Router
eNodeB
IP/MPLS Network
GE
GE S-GW/MME eNodeB
Ethernet
GE eNodeB
S-GW Pool S/R
Switch/router
S-GW
MME Pool
S-GW
Ethernet Trunk
1.
2.
Reliability solutions: S1-flex, OAM channel backup, IP routing backup and Ethernet trunk
S-GW MME
MME
S1-flex eNodeB E-UTRAN
eNodeB eNodeB eNodeB
eNodeB
eNodeB eNodeB eNodeB
Failure detection Mechanism: BFD, ARP and Ethernet OAM BFD - Bidirectional Failure Detection; ARP - Address Resolution Protocol.
Page 23
Maintainability Solution
Access link OAM: IEEE802.3ah, ARP
Connectivity OAM: IEEE802.1ag
Service Layer OAM: BFD, GTP-U OAM, UDP OAM, SCTP OAM
802.3ah
802.3ah
router FE/GE IP/Ethernet IP/MPLS
FE/GE router eNodeB
router
router
S-GW /MME 802.1ag
802.1ag 802.1ag
BFD: Bi-directional Failure Detection ~ GTP-U: GPRS Tunnel Protocol- User Plane ~ UDU: User Data Protocol ~ SCTP: Stream Control Transmission Protocol
Page 24
Co-transmission Solution LTE eNodeB co-location with traditional legacy base station
Scenario 1
PW emulation for ATM/TDM traffic over Ethernet
Co-located GE
eNodeB
TGW/Router
GE
GE
IP/Ethernet Network
S-GW/MME TDM/ATM
Legacy BTS (2G BTS or UMTS NodeB)
nE1/T1,STM-1
eNodeB
E1/T1, FE/GE S-GW/MME
IP/Ethernet Network IP-based 2G/3G
Legacy BSC/RNC
Multi-mode base station or eNodeB co-location with IP-based legacy base station
Scenario 2
Multi-mode eNodeB
TGW/Router
eNodeB
GE
FE/GE
BSC/RNC
E1/T1, FE/GE TGW: Transport Gateway ~ PW: Pseudo Wire
Page 25
Intelligent SON Solution
BITS / Clock server
Neighbor eNodeB
5
S1 3
X2
SGW / MME Pool
4 1
eNodeB
ACS
2 NE/NMS
DHCP Server
1. 2. 3. 4. 5.
IP address allocation through DHCP and OAM channel establishment Configuration parameters download S1 interface configuration and setup X2 interface configuration and setup Clock server channel configuration and setup
Page 26
X2 interface implementation Solution 1.
Distributed Solution PoC3
PoC2
PoC1
S1 eNodeB
X2
eNodeB
S-GW/MME
eNodeB Last mile
• • •
Metro
Core
The X2 and S1 interfaces share the same physical interface, and X2 interface is established through the nearest PoC equipment between the two eNodeBs Advantage: reduced X2 data delay and packet loss, save the metro and core network transmission bandwidth Disadvantage: complex transmission equipment configuration and management, the addition of new eNodeB requires the transmission network reconfiguration and planning. PoC: Point of Convergence
Page 27
X2 interface implementation Solution 2.
Convergence Solution ( recommended) PoC3
PoC2
PoC1
S1 eNodeB
X2
eNodeB
S-GW/MME
eNodeB Last mile
• •
•
Metro
Core
The X2 and S1 interfaces share the same physical interface, and X2 interface is established through the PoC1 equipment Advantage: easy transmission network planning and management, simple configuration . Moreover, the PoC2 and PoC3 equipments do not required complex routing functions. Therefore reduce the transmission network cost Disadvantage: bandwidth cost
Page 28
Content
LTE Transport Network Interface
LTE Transmission Network Requirements
LTE Transmission Key Technologies
Huawei LTE Transport Solution
Page 29
IP/Ethernet Backhaul Solution GE FE/GE (fiber) eNode B
S-GW/MME
IP/Ethernet (MPLS, VPLS, VLAN) GE FE/GE (cable)
eNode B
FE
S-GW/MME GPS
BITS
Scenario: For operator which has built or plans to deploy IP/Ethernet network.
Benefits:
Enough transport bandwidth for S1/X2 interface
Cost-effective
Meet flexibility and convergence requirements
Key technologies
Transport security: MPLS VPN, VLAN
QoS guarantee: MPLS TE, MPLS DiffServ, IP DiffServ
Synchronization: Synchronous Ethernet, IEEE1588v2, BITS, GPS or Huawei clock over IP
Transport access layer: FE/GE cable, cable (VDSL), Packet MW , P2P fiber and GPON.
Page 30
MSTP-based Backhaul Solution Rt VC-trunk: bearer high QoS traffic
FE/GE eNode B GE
MSTP transmission network
FE/GE
S-GW/ MME
eNode B
2M line: used for
clock sync.
eNode B
FE/GE
Nrt VC-trunk: bearer low QoS traffic
Scenario: For operator which has MSTP network or plan to upgrade from SDH to MSTP
Benefits:
Enough transport bandwidth for S1/X2 interface
Co-working with MSTP network
Easy expansion
The bandwidth multiplexing in MSTP ring can improve the transmission efficiency up to more than 30%
Key Technologies
Transport security: VLAN
QoS guarantee: separated trunk for real time (rt) and non-real time (Nrt) applications
Synchronization: 2Mbps line for clock synchronization such as synchronous Ethernet, IEEE1588v2, Huawei clock over IP, GPS or BITS.
Transport access layer: FE/GE cable, cable (VDSL), Packet MW, P2P fiber, and GPON.
Page 31
PTN-based Backhaul Solution FE/GE eNode B GE FE/GE
PTN network S-GW/ MME
eNode B
eNode B
FE/GE
Scenario: For operator which has PTN ne twork or plan to upgrade from SDH ( or SONET) to PTN
Benefits:
Enough transport bandwidth for S1/X2 interface
Co-working with traditional network
Easy expansion
The bandwidth multiplexing in PTN ring can impro ve the transmission efficiency up to more than 30 %
Key Technologies
Transport security: VLAN
QoS guarantee: separated tunnel for real time (rt) and non-real time (Nrt) applications
Synchronization: 2Mbps line for clock synchronization such as synchronous Ethernet, IEEE1588v2, Huawei clock over IP, GPS or BITS.
Transport access layer: FE/GE cable, cable (VDSL), Packet MW, P2P fiber, and GPON.
Page 32
TDM-based Backhaul Solution TDM equipment
TDM
equipment
TDM Transport Network
IP/Eth Network
GE
eNode B IP ML-PPP nE1/T1
or cPoS STM-1 (optional)
S-GW/MME
IP ML-PPP nE1/T1
Scenario: For operator which has TDM or leased E1/T1 legacy network and plan to upgrade to IP/Ethernet broadband solution
Benefits:
Reuse of legacy transmission network
The use of IP over TDM will improve TDM res ource utilization
Suit to low traffic network
Key technologies
Transport security: VLAN, MPLS L2VPN, MPLS L3VPN
QoS guarantee: MPLS TE, MPLS DiffServ, IP DiffServ, VLAN CoS
Synchronization: the clock data can be de rived from legacy TDM network or through syn chronous Ethernet, IEEE1588v2, Huawei clock over IP, GPS or BITS on the IP/Ethernet network.
Transport access layer : nxE1/T1.
ML-PPP: Multi-link Point-to-Point Protocol ~ Channelized Packet over SDH ~ STM: Synchronous Transport Module
Page 33
Flexible E2E LTE Backhaul Networking Satellite-based Backhaul
TDM-based backhaul solution
nxE1/T1
eNode B
eNode B TDM network
nxE1/T1
Ethernet
FE/GE
Aggregation/Core Transport Network
S-GW/MME
IP/Ethernet backhaul
MSTP-based backhaul
GE/FE
Microwave-based backhaul
Metro
eNode B Metro
MSTP Network
Metro
IDU
IDU
FEeNode B
Metro
GE/FE
eNode B
S-GW/MME
IP/Ethernet Networ k
TDM MW or Packet MW
Adaptive to all kind of backhaul scenarios
Page 34
Ethernet
eNode B
Application Scenarios Suburban/rural • •
P2P fiber GPON
E1/T1 over microwave or cable eNodeB
IDU eNodeB
P2P fiber/G-PON
IDU
eNodeB
TDM network
ONU
GE
G-PON
transport network
eNodeB
Splitter
GE DSLA M
MME/S-GW /PDN GW
Microwave
GE
IDU
IDU
Urban area
eNodeB
• Mini DSLAM
ADSL2+/SHDSL/VDSL2
•
Microwave P2P fiber/GPON/VDSL2 (if already available)
FE eNodeB
modem
Page 35
To Learn More … Doc. Name
Release link
Contact person
Promotion White paper One-page
ID: xxxxxx 00xxxxxx E-Mail:
[email protected] Dept.: XXX
Case study
Strategy Go-to-MKT strategy Sales guide
ID: xxxxxx 00xxxxxx E-Mail:
[email protected] Dept.: XXX
Others
Branding Flash & Video Special Release
ID: xxxxxx 00xxxxxx E-Mail:
[email protected] Dept.: XXX
Others
Page 36
资料使用评价反馈页 Quality Assessment 请点击此处反馈您对本资料的意见,您的反馈是资料不断改进的指南针! Please click the following link to feedback your comments on this documents, helping us to improve the materials quality. Thank you in advance!
您对该资料的评价是: 很好
(Very Good)
好
(Good
)
一般
(General
)
待改进 (Not Good ) 注意:将资料传递给客户时请删除该页胶片!Please delete this page when you submit to our customers. Page 37
