Wireless Telecommunication Systems GSM as basis of current systems Enhancements for data communication: HSCSD, GPRS, EDGE UMTS: Future or not?

Transcription

1 Chapter 2 Technical Basics: Layer 1 Methods for Medium Access: Layer 2 Chapter 3 Wireless Networks: Bluetooth, WLAN, WirelessMAN, WirelessWAN Mobile Networks: GSM, GPRS, UMTS Chapter 4 Mobility on the network layer: Mobile IP, Routing, Ad-Hoc Networks Mobility on the transport layer: reliable transmission, flow control, QoS Mobility support on the application layer Wireless Telecommunication Systems GSM as basis of current systems Enhancements for data communication: HSCSD, GPRS, EDGE UMTS: Future or not? 1

2 Mobile Telephony A-Netz 1958 introduced by Federal Post Office Analogous and connected by operator No handover between base stations 1977 stopped B-Netz Introduced 1972 Caller had to know in range of which base station the called resided (using a region dialing code!) Partly roaming agreements with Austria, The Netherlands, Luxemburg 1994 stopped C-Netz No region dialing code necessary Cellular system with large number of base stations Also data and fax connections 2000 stopped 2

3 Standardization of Networks In the 70 th and 80 th : analogous, cellular mobile systems in most European countries (1 st generation networks) Incompatibility of the mobile systems 1982: Foundation of Groupe Spéciale Mobile (GSM) for solving interoperability issues Goal: digital network (D-Netz, also called 2 nd generation, 2G because of change in technology) 1990: first specification of GSM: GSM900 (900 MHz) 1991: specification of GSM1800 as E-Netz 1992: 13 networks in 7 countries, D1 and D2 in Germany 1994: E-Plus 1995: GSM1900 in the USA 1998: E2-Netz, VIAG Interkom 2000: auctioning of UMTS licenses (Integration of voice and data: 3 rd generation, 3G) 2001 Start of GPRS as enhancement to GSM for packet-oriented data transfer (also called 2.5G ) 3

4 GSM Basis of Current Mobile Systems GSM today means Global System for Mobile Communications Introduction by the European telephone exchange offices (Germany: D1 and D2) seamless roaming within Europe possible Today many providers all over the world use GSM (more than 210 countries in in Asia, Africa, Europe, Australia, America) More than 747 million subscribers in more than 400 networks More than 10 billion SMS per month in Germany, > 360 billion worldwide (more than 10% of the sales of the operators) Uses the frequency ranges of 900, 1800, and 1900 MHz Voice and data connections with up to 9.6 KBit/s (enhancement: 14.4 KBit/s) Access control by chip-cards Cell structure for a complete coverage of regions ( m Ø per cell in cities, up to 35 km on country-side) 4

5 Performance Characteristics of GSM Most important technical aspects: Communication: mobile, wireless communication; support for voice and data services Total mobility: international access, chip-card enables use of base stations of different providers Worldwide connectivity: only one number, the network handles localization High capacity: good frequency efficiency; relatively small cells to allow for a high number of customers High transmission quality: high audio quality and reliability for uninterrupted wireless phone calls also at higher speeds (cars, trains, ) Security functions: access control and authorization via chip-card and PIN GSM offers three types of services: Bearer Services Telematic Services Supplementary Services 5

6 Bearer Services Basic telecommunication services to transfer data between access points Specification of services up to the terminal interface (corresponding to OSI layers 1 3) Different data rates for voice and data (original standard) Data service (circuit switched) synchronous: 2.4, 4.8 or 9.6 KBit/s asynchronous: Bit/s Data service (packet switched) synchronous: 2.4, 4.8 or 9.6 KBit/s asynchronous: Bit/s Additionally: signaling channels for connection control (used by telematic services) 6

7 Telematic Services Telecommunication services that enable voice communication via mobile phones All services have to obey cellular functions, security measurements, etc. Offered services: Mobile telephony Primary goal of GSM was to enable mobile telephony offering the traditional bandwidth of 3.1 khz Emergency number Common number throughout Europe (112); mandatory for all service providers; free of charge; connection with the highest priority (preemption of other connections possible) Multinumbering Several phone numbers per user possible 7

8 Telematic Services Non-Voice-Teleservices Fax Voice mailbox (implemented in the fixed network supporting the mobile terminals) Electronic mail (MHS, Message Handling System, implemented in the fixed network)... Short Message Service (SMS) Alphanumeric data transmission to/from the mobile terminal using the signaling channel, thus allowing simultaneous use of basic services and SMS 8

9 Supplementary Services Services in addition to the basic services, cannot be offered stand-alone Similar to ISDN services besides lower bandwidth due to the radio link May differ between different service providers, countries and protocol versions Important services Identification: forwarding of caller number Suppression of number forwarding Automatic call-back Conferencing with up to 7 participants Locking of the mobile terminal (incoming or outgoing calls) 9

10 Cellular Network Signal attenuation restricts distance between sender and receiver (~ d² in line of sight, d 5.5 within buildings) Frequency range very limited and not suited for high number of subscribers Frequency re-use by SDMA: divide the whole area in cells Intentionally restriction of a cell by lowering the transmission power Frequency ranges can be re-used in a larger distance without problems of interference Two subscribers in distant cells can use the same channel simultaneously Zelle 1 technical possible transmission range Zelle 1 intentionally restriction of transmission range 10

11 Cellular Network The size of a cell is determined by a maximum given transmission power and a minimum receiver signal strength for a good voice quality Hexagonal cell pattern is idealized (Cells overlap irregularly) No uniform cell size, size depends on attenuation as well as expected traffic amount (inner city vs. unpopulated regions) Cell change of mobile user during a phone call Passing the connection to the neighbor cell: handover Cluster Distance depends on remaining signal strength

12 Cell Concept Lehrstuhl für Informatik 4 Cluster: Area in which all frequencies are used. Each cell in the cluster at least is assigned one frequency, but also several frequencies per cell are possible More cells per cluster: Less channels per cell Lower system capacity Less co-channel interference (co-channel cells have larger distance in between) Less cells per cluster: More channels per cell Higher system capacity More co-channel interference (co-channel cells are nearby) Cell planning: Optimize the luster size N in a way to maximize capacity and minimize interferences 12

13 Coverage of GSM Networks ( T-Mobile (GSM-900/1800) Vodafone (GSM-900/1800) e-plus (GSM-1800) O 2 (GSM-1800) 13

14 Architecture of the GSM System The GSM system is a so-called PLMNs (Public Land Mobile Network). Several providers setup mobile networks following the GSM standard within each country The GSM system consists of several components: MS (mobile station) BS (base station) MSC (mobile switching center) LRs (location register) Different subsystems are defined: RSS (radio subsystem): covers all radio aspects NSS (network and switching subsystem): call forwarding, handover, switching OSS (operation subsystem): management of the network 14

15 GSM - Architecture GSM Network Region with Mobile Switching Center (MSC) Location Area Location Area MSC Region Base Station Subsystem Base Station Subsystem Cell Cell Base Station Subsystem Location Area MSC Region GSM networks are hierarchical structured: At least one administrative region with Mobile Switching Center An administrative region consists of at least one location area A location area consists of several Base Station Subsystems A Base Station Subsystem consists of one Base Station Controller (BSC) and several Base Transceiver Stations (BTS, cells) 15

16 4 4 4 Lehrstuhl für Informatik 4 GSM Architecture OMC ISC PLMN, international BSC MSC GMSC PSTN ISDN BSC EIR AUC HLR VLR OSS NSS AUC: BSC: EIR: GMSC: HLR: Authentication Center Base Station Controller Equipment Identity Register Gateway Mobile Switching Center Home Location Register RSS ISC: International Switching Center MSC: Mobile Switching Center OMC: Operation and Maintenance Center PLMN: Public Land Mobile Network VLR: Visitor Location Register 16

17 Radio Subsystem The radio subsystem is the cellular network up to the switching centers It comprises several components: Base Station Subsystem (BSS): Base Transceiver Station (BTS): radio components including sender, receiver, antenna. A BTS can serve one cell or, if directed antennas are used, several cells. Base Station Controller (BSC): The BSC performs the switching between BTSs and the control of BTSs. It manages the network resources, mapping of radio channels onto terestrial channels. The complexity of BTSs only is low by that separation. BSS = BSC + Sum(BTS) + interconnection Mobile stations (MS) are seen as mobile network components. 17

18 Base Transceiver Station und Base Station Controller Functions BTS BSC Management of radio channels X Frequency hopping (FH) X X Management of terrestrial channels X Mapping of terrestrial onto radio channels X Channel coding and decoding X Rate adaptation X Encryption and decryption X X Paging X X Uplink signal measurements X Traffic measurement X Authentication X Location registry, location update X Handover management X 18

19 Base Station Subsystem BSC BSC BSC Base Station Controller F1 F2 F3 F5 F7 Fx Frequency range of a cell F7, F6 F8 F4 F6 F1 F9 F3 Base Transceiver Station BSC A BTS controls all transmission in a cell. Communication only is possible between a mobile station and its BTS Problems: Cell changes (Handover to another BTS), combined with a frequency change Location of a mobile station (HLR/VLR) 19

20 Mobile Station Lehrstuhl für Informatik 4 Terminal for the use of GSM services; it comprises several functional groups: MT (Mobile Terminal): Offers common functions used by all services the MS offers Corresponds to the network termination (NT) of an ISDN access End-point of the radio interface TA (Terminal Adapter): Terminal adaptation, hides radio specific characteristics TE (Terminal Equipment): Peripheral device of the MS, offers services to a user Does not contain GSM specific functions SIM (Subscriber Identity Module): Personalization of the mobile terminal, stores user parameters 20

21 Network and Switching Subsystem The network subsystem is the main component of the public mobile network GSM. It interconnects the BSSs with other networks and performs switching, mobility management, and system control Components are: Mobile Services Switching Center (MSC) Controls all connections via a separated network to/from a mobile terminal within the domain of the MSC - several BSC can belong to a MSC Databases Home Location Register (HLR) Central master database containing user data, permanent and semipermanent data of all subscribers assigned to the HLR (one provider can have several HLRs) Visitor Location Register (VLR) Local database for a subset of user data, including data about all user currently in the domain of the VLR 21

22 Mobile Switching Center The exchange central of a GSM network is the Mobile Switching Center: path choice, signaling and processing of service features Administration of and access to radio resources Additional functions for location registration and handover when a cell change occurs (support of subscriber mobility) Certain gateways to other fixed or mobile telephony networks (Gateway-MSC; GMSC) Most important functions of a MSC: Specific functions for paging and call forwarding Mobility specific signaling Location registration and forwarding of location information Provision of new services (fax, data calls) Support of short message service (SMS) Generation and forwarding of accounting and billing information 22

23 Home and Visitor Location Register Two types of databases are used for subscriber registration and location management: Home Location Register (HLR) Central location management, a subscriber can be searched for here, not the whole network has to be searched Contains all static subscriber data (number, access rights, subscribed services, service features) as well as a raw location information MSCs use HLR to get information about rights, services and current (raw) location of subscribers Visitor Location Register (VLR) Locale database for a subset of subscriber data, most important the current (detailed) subscriber location; is assigned a MSC Only stores information about subscribers which are in range of the corresponding MSC Contains dynamic data which are updated by information exchange with HLR and the mobile stations Data from a VLR follow the subscriber when he comes into range of another VLR 23

24 4 Lehrstuhl für Informatik 4 Connection Establishment POTS Gateway Destination MSC MSC BSS HLR VLR 1 - Call for a mobile station 2 - POTS forwards call to the GMSC connecting the GSM network 3 - GMSC uses HLR to request currently responsible MSC 4 - Response with switching information to the current subscriber location 5 - Forwarding of the call to the destination MSC 6 - MSC requests exact position of the subscriber in its VLR 7 - VLR checks service profile and availability of the MS and gives back the current BSS 8 - Paging of the mobile subscriber (broadcast in the whole BSS) 9 - MS answers, call can be established 24

25 Handover Lehrstuhl für Informatik 4 Automatic change of the responsible BTS without influence on the quality of a connection a caller should not be able to notice the change. Process: 1. Measurement During a transmission permanently measurements in the signaling channel are performed to detect the necessity of a handover (receiving power, bit error rates, distance to base station, participants in the cell, narrow-band interference) 2. Initiation of handover Establishment of a connection from the responsible MSC to the new base station Selection of a new channel with the new base station 3. Switching to new BTS Network-controlled handover (e.g. C-Netz), MS-supported handover (e.g. GSM) or MS-controlled handover (e.g. DECT) 25

26 Handover Decision Signal strength of signal A receiving power Signal strength of signal B handover range MS movement MS Last point of switching BTS A BTS B 26

27 Handover Procedure MS measurement report BTS old measurement result BSC old MSC BSC new BTS new HO decision HO required HO request HO command HO command HO command HO access Link establishment clear command clear command clear complete clear complete resource allocation ch. activation HO request ack ch. activation ack HO complete HO complete 27

28 Operation Subsystem The OSS performs some central tasks for the provision of the whole GSM network as well as maintenance of that network Components are: Authentication Center (AUC) Creates on demand of a VLR the access right parameters for a subscriber These parameters serve for security and protection of subscriber information in the GSM system Equipment Identity Register (EIR) Registers serial numbers of GSM mobile stations as well as the assigned usage right Devices which are registered in the AUC can be locked and maybe located if stolen Not a mandatory component in the GSM architecture Operation and Maintenance Center (OMC) Control centers for the maintenance of all other GSM architecture parts 28

29 GSM900 vs. GSM1800 Criterion GSM900 GSM1800 Frequency range (Uplink) 890 MHz MHz 1710 MHz MHz Frequency range (Downlink) 935 MHz MHz 1805 MHz MHz Duplexing distance 45 MHz 95 MHz Bandwidth Up- and Downlink 2 x 25 MHz 2 x 75 MHz Bandwidth of a channel 200 khz 200 khz Access method FDMA & TDMA FDMA & TDMA Number of carrier frequencies Timeslots per carrier frequency 8 8 Channels Bit rate 270,833 KBit/s 270,833 KBit/s Net bit rate for voice 13 KBit/s 13 KBit/s Modulation method GMSK GMSK Cell size (radius) 2-35 km 0,2-8 km Transmission power of a MS max. 20 Watt max. 1 Watt 29

30 GSM Protocol Lehrstuhl für Informatik 4 Access method: combination of: Frequency multiplexing (FDMA/FDD) Sending on 124 channels of 200 KHz each between 890 and 915 MHz Receiving on 124 channels of 200 KHz each between 935 and 960 MHz Time multiplexing (TDMA) with a shift of 3 time slots between sending and receiving time by to avoid the need for duplex-enabled transceiver units 960 MHz f MHz khz 915 MHz MHz MHz 1 t 30

31 TDMA Frames Lehrstuhl für Informatik 4 Frequency range MHz MHz GSM TDMA Frame GSM Timeslot 124 channels with 200 khz each Downstream 124 channels with 200 khz each Upstream Higher GSM Frame Structures guard time tail payload S training S payload tail ,615 ms guard time Time 3 bit 546,5 µs 577 µs GSM timeslot: Burst und guard times Tail (000): define start und end of a Bursts Training: synchronization sequence with well-known bit pattern for adapting the receiver to the current signal propagation characteristics, e.g. calculating the strongest signal part in case of multipath propagation S (Signaling): what is the content of the payload field: user or control data (optional: slow frequency hopping after each TDMA frame to avoid frequencydependent signal fading) 31

32 Frame Hierarchy One MS can use one slot per frame as a channel. But there are also other possibilities: Sharing of one channel with other devices (by voice compression) Control channels for maintenance, requests of new stations to get assigned a channel, Thus: different types of channels: TCH/F (full) and TCH/H (half) as well as control channels Result: complex frame hierarchy to come to a common structure Hyperframe Superframe Multiframe Frame slot burst 3 h 28 min 53,76 s 6,12 s 120 ms 235,4 ms 4,615 ms 577 µs 32

33 Data Services in GSM Data transmission in GSM with only 9.6 kbit/s Advanced channel coding allows 14.4 kbit/s Still not enough for Internet access or even multimedia applications Thus: UMTS as 3G network : Integration of data and voice in one network But: new network infrastructure, new software, new devices, Development of other enhancements of GSM as interim solutions 2.5G networks as interim solution HSCSD as software solution GPRS as hardware solution EDGE as 3G solution in a 2G network 33

34 HSCSD Lehrstuhl für Informatik 4 HSCSD (High-Speed Circuit Switched Data) Put together several time slots for one AIUR (Air Interface User Rate, up to 57.6 kbit/s with 4 Slots of 14.4 kbit/s) Symmetrical (2 time channels each for up- and downlink) and asymmetrical (3 + 1 channels) communication are supported Mainly software update for the realization of the putting together Advantage: fast availability, continuous quality, simple Disadvantage: connection-oriented, 4 channels are blocked the whole time, signaling for several channels necessary AIUR [kbit/s] TCH/F4.8 TCH/F9.6 TCH/F Three possible data rates for a full channel depending on the used coding and error correction 34

35 GPRS GPRS (General Packet Radio Service) Packet-oriented transmission, usable also for multicast Usage of up to 8 time slots of a TDMA frame on demand Usage of time slots only when data are available for sending (e.g. 50 kbit/s with short usage of 4 slots) Advantage: step towards UMTS, flexible Disadvantage: expensive because some new infrastructure is needed to handle the new transmission mechanism, wireless transmission becomes a bottleneck for high traffic amount Needed infrastructure: GSN (GPRS Support Nodes) - GGSN and SGSN - GGSN (Gateway GSN): translation between GPRS und PDN (Packet Data Network) - SGSN (Serving GSN): support of the MS (location, accounting, security) - GR (GPRS Register): Management of user addresses 35

36 4 4 Lehrstuhl für Informatik 4 GPRS Infrastructure Components SGSN GGSN PDN PCU BSC MSC GMSC PSTN ISDN AUC: Authentication Center BSC: Base Station Controller EIR: Equipment Identity Register GMSC: Gateway Mobile Switching Center GGSN: HLR: Home Location Register GR: MSC: Mobile Switching Center PCU: VLR: Visitor Location Register SGSN: EIR AUC HLR GR 36 VLR 4 NSS RSS GPRS OSS Gateway GPRS Support Node GPRS Register Packet Control Unit Serving GPRS Support Node

37 GPRS Data Rates [kbit/s] (error-) coding 1 time slot 2 time slots 3 time slots 4 time slots 5 time slots 6 time slots 7 time slots 8 time slots CS-1 9,05 18,2 27,15 36,2 45,25 54,3 63,35 72,4 CS-2 13,4 26,8 40,2 53, ,4 93,8 107,2 CS-3 15,6 31,2 46,8 62, ,6 109,2 124,8 CS-4 21,4 42,8 64,2 85, ,4 149,8 171,2 Data rate CS-1 to CS-4: decreasing error protection Dynamic choice of coding Basing on measurements of signal quality (and the needed QoS) CS-4 CS-3 CS-2 CS-1 The user is assigned the highest possible data rate Position 37

38 Advantages of GPRS Always connected Long duration for connection establishment are eliminated Transmission of data on demand Accounting by data volume, not by connection duration Robust connection Coding of data bases on current signal quality Even the BSS checks the data correctness and initiates if necessary a transmission repeat 38

39 EDGE EDGE (Enhanced Data Rates for GSM Evolution) Up to 384 kbit/s by enhanced modulation (8PSK instead of GMSK) Transmission repeat: Change of coding to adapt to the current channel quality Is build upon the existing GSM/GPRS system: New transceiver are needed (hardware upgrade in the BSS) Software-Upgrade BSS und BSC New devices (8PSK) No changes in the core network! Cheap alternative to UMTS? 39