GSM TOWARDS LTE NETWORKS Lecture # 5
MOBILE TRAFFIC VOICE AND DATA Source: Internal Ericsson DVB-H, Mobile WiMax, M2M and WiFi traffic not included This slide contains forward looking statements Exabyte = Giga Giga Byte
THE 3G VISION Global Seamless Roaming Common Worldwide Spectrum Multiple Radio Environments Wide Range of Services -Voice & Data Equally Flexible, Spectrum Efficient Technologies Wireless - Wireline Integration Enhanced Security and Performance Wireline Services and Quality Levels Rapid Introduction of New Technology
3G VISION - APPLICATION Application Multimedia Message Service (MMS) Video phone Video streaming Any service from the Internet
3G VAS APPLICATIONS Video SMS Video Portal Mobile TV Video IVR Video CRBT Mobile Video Marketing YouTube upload Video conferencing Video greeting Dial TV service 3G Music Station with full track song download Video Contact Center
2G TOWARDS 3G Higher data bandwidth requirement Anticipated subscriber demand for Audio/Video streaming Other multimedia services Collaborative services Location services
3G - PRINCIPLE REQUIREMENT Support for voice quality comparable with fixed line networks Support for both circuit-switched and packet-switched data services Support for greater capacity and improved spectrum efficiency
3G–PRINCIPAL REQUIREMENT A data rate of 144 kb/s for users moving quickly e.g. moving vehicles A data rate of 384 kb/s for pedestrians A data rate of 2 Mb/s in a low mobility or office environment. Note how a network using GPRS and EDGE meets most of these criteria!
Example: 3G SERVICES (UMTS) Universal Mobile Telephone System (UMTS) Four QoS classes of services Conversational Class Voice, video telephony,video gaming Streaming Class multimedia, video on demand, webcast Interactive Class WWW browsing, database access, online gaming Background Class , SMS, file downloading
2.5 GPRS VOICE / data ARCHITECTURE Voice Calls Path Data Calls Path Packet Data14.4 Kp/s
3G NETWORK GGSN IP networks SGSN Iu Gb 2G3G BSC BTS RNC Node B HLR/HSS Gr Gi LTE/SAE Architecture Iur Only PS Domain shown Gn
HSPA (High Speed Packet Access) GGSN IP networks SGSN Iu CP Gb 2G3G BSC BTS RNC Node B HLR/HSS PCRF Iu UP Gr Gi LTE/SAE Architecture Iur Gx Only PS Domain shown Gn Optimizing the 3G/HSPA payload plane for Broadband traffic Release 7 ”Direct Tunnel”
STEPS TOWARDS 3G 1- Backbone Roll Out (Packet Network) All the backend traffic transfer on IP (Packets) /Passport/ATM/MPBN 2- Data Network 3- Core Network 4- RAN Network
1-BACKBONE ROLL OUT (Packet Network ) Migration Steps
2-DATA NETWORK MIGRATION
2nd GENERATION NETWORK
3 rd GENERATION NETWORK
2G & 3G NETWORK
TOWARDS IP NETWORK
3-CORE NETWORK MIGRATION Classic MSC (Control and Switching) Classical MSC Architecture (old name: Non-Layered Mobile Core Network/ ’Monolitic’ Architecture) TDM MSC MSC Server (Control) Mobile Media Gateway (Switching) Mobile Softswitch Solution (old name: Layered Mobile Core Network Architecture) IP/ATM/TDM Control Layer MSC-SMGwMSC-SMGw
INCREMENTAL MIGRATION In Pakistan, Most operators have incrementally Migrated. Two strategies have been adapted GPRS adapted by Warid Telecom. EDGE adapted by Ufone.
MOBILE SOFT SWITCH SOLUTION FOR 3G CORE NETWORK One of the most efficient way to upgrade for 3G core networks. Layered architecture for ease MSS is only for Mobile core networks
LAYERED ARCHITECTURE The benefit of layered architecture is from research and development purpose. In communication there are two main recourses i.e. controlling and connectivity.
MSS LAYERS 1.Control Layer 2.Connectivity Laye 3.Application Layer
CONTROL LAYER This layer is refer to the logical layer as it performs logical operations of the MSS this node provides the analysis and control functions required for circuit switched traffic and using standardized signaling controlling the allocation of required resources in the connectivity layer
CONNECTIVITY LAYER This layer is based on ATM (Asynchronous Transfer Mode) and IP protocols. Providing end-to-end connection throughout the core network. This layer provide standard interfaces for the connectivity with other legace networks.
APPLICATION LAYER In this layer all the application are added and managed. Like if Warid want to provide CBRT (Caller Back Ring Tone) service then it add server that provide this service to the user in the application layer. Recourses of such servers are controlled by MSC-S.
MSS ARCHITECTURE
MSS NODES 1. MSC-S (Mobile Switching Server) 2. M-MGW (Mobile Media Gateway)
MSC-SERVER MSC-S is the control layer device of the 3G network. It contains all call and control service logic such as: ѣ Charging analysis ѣ Bearer selection ѣ Route analysis ѣ Media Gate way selection
MSC-SERVER It provides efficient and centralized control of the distributed switching provided by the Mobile Media Gateway (M-MGw), ensuring flexible, cost-effective network design, and a smooth evolution to an all-IP core network.
MSC-SERVER MSC-S Data Base nodes Other MSC-S M-MGW Radio Sites
M-MGW M-MGW is the connectivity layer device. M-MGW connects the MSS core network with the external networks such as WCDMA and GSM radio access networks, PSTN networks, PABXs, IMS/VoIP network, or other mobile networks. This node controlled by MSC-S.
SIGNALING AND PROTOCOLS MSC Server 1 T-MSC Server 1 M-MGW 1M-MGW 2 RNC BSC PSTN/ISDN/PL MN BICC / MAP BSSAP ISUP SIP GCP RANAP Data Base Nodes MAP
INTERFACE & PROTOCOLS MSC Server 1 T-MSC Server 1 M-MGW 1M-MGW 2 RNC BSC PSTN/ISDN/PLMN Nb A Lu CS Control Plane User Plane Nc Mc POI
3G CALL SETUP
Call Setup Scenario : Subscriber “A” is a calling party from PTML and Subscriber “B” is called party that is related to PSTN
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 1. SETUP
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 2. RNC send SETUP message to MSC-S
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 3. SEIZE RESOURCES
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 4. M-MGW reply by ACK message
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 5. MSC-S inform RNC that call is in progress by CALL PROCESSED message
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 6. MSC-S send ASSIGNMENT message
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 7. RNC send ERQ message to selected M-MGW
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 8. M-MGW setup virtual connection with RNC and reply by ECF message
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 9. RNC send ASSIGNMENT COMPLETE message
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 10.MSC-S 1 send IAM message to MSC-S 2
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 11.T-Server send SEIZE RESOURCE message to selected M-MGW
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 12. M-MGW send reply by ACK
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 13. T-Server forward IAM to terminating end i.e. PSTN
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 14. PSTN reply by ACM
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 15. T-Server forward ACM to MSC-S
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 16. MSC-S order M-MGW to through connection back to party “A”
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 17. MSC-S alert party “A” by sending ring back tone and party “B” by ring tone
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 18. As “B” party answer the call and send ANM to T-Server
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 19. T-Server inform ANM to MSC-S
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 20. MSC-S order to through both way speech path
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 21. MSC-S order to RNC to connect call to traffic channel by CONNECT message
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 22. RNC send ACK
MSC Server 1 T-MSC Server 1 M-MGW 1 M-MGW 2 RNC BS PSTN/ISDN/PLM N IP 23. The UMTS call path has been established
GSM Toward LTE Networks
LTE/SAE Architecture Product dimension PDN GW Serving GW MME S1-MME S1-U LTE IP networks eNodeB SGSN Iu CP Gb 2G3G S3 BSC BTS RNC Node B HLR/HSS PCRF Iu UP S11 Gr S10 S6a SGi LTE/SAE Architecture X2 Iur S7 Non-3GPP access S2a/b S4 PDN GW Serving GW ”Gateway” MMESGSN ”Mobility Server” PCRF HLR/HSS ”HLR/HSS” EPC eNode B RBS OSS PA/DU Core & IMS PA/DU Radio
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