Chapter 7 The 2nd Generation Cellular Systems

1. Chapter 7 The 2nd Generation Cellular Systems GSM: Pan-European Digital Cellular System Prof. Huei-Wen Ferng

2. Background and Goals • GSM (Global System for Mobile Communications) • Beginning from 1982 • European standard • Full roaming in Europe • A purely digital system • Goals (principal/ original) -> Phase 1, 2, 2+: • full international roaming Prof. Huei-Wen Ferng

3. Background and Goals • provision for national variations in charging and rates • efficient interoperation with ISDN systems • signal quality better than or equal to that of existing mobile systems • traffic capacity higher than or equal to that of present systems • lower cost than existing systems • accommodation of non-voice services and portable terminals Prof. Huei-Wen Ferng

4. Architecture • Network elements • Mobile stations, base stations, and mobile switching center • Three databases • Home location registers (HLR) • Visitor location registers (VLR) • Equipment identity registers (EIR) Prof. Huei-Wen Ferng

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6. Architecture • In contrast to the original cellular, micro cells are used in GSM • A BS separates into two parts: BTS (base transceiver station) and BSC (base station controller) • Typically, a BSC controls several BTS • To reduce the cost with the greatest possible service extent Prof. Huei-Wen Ferng

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8. Architecture • Subscriber identity module (SIM) • Two types: one like credit card and the one smaller • An important GSM innovation • A removable card that stores information, including ID number, abbreviated dialing code, and subscriber’s service plan • Easy to change telephones Prof. Huei-Wen Ferng

9. Architecture • As in the other systems, GSM uses a variety of ID codes • GSM Identifiers • International Mobile Subscriber Identity (15 digits) • Temporary Mobile Subscriber Identity (32 bits) • Advantages: Privacy and save BW • International Mobile Equipment Identifier (15 digits) Prof. Huei-Wen Ferng

10. Architecture • Authentication Key (max = 128 bits) • Cipher key (64 bits): • Terminal and network use authentication key to compute the cipher key • Mobile station classmark including: • Version of the GSM standard • RF power capability (power levels available) • Encryption method • Other properties of terminal Prof. Huei-Wen Ferng

11. Architecture • Training Sequence (26 bits) • help a terminal verify that it receives information from the correct BS rather than another BS using the same physical channel • BS Identity Code (6 bits) • Location Area Identity (40 bits) including: • A mobile country code, network code, and area code Prof. Huei-Wen Ferng

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13. Radio Transmission • GSM Spectrum • There are two 25 MHz bands separated by 45 MHz • Initial GSM systems operate in the upper 10 MHz • Physical Channels • GSM is a Hybrid FDMA/TDMA system • Each GSM band has carriers spaced at 200 kHz • The frame duration is 120/26 = 4.62 ms • Each frame contains 8 time slots • There are 25 MHz/200 k Hz = 125 carriers in per direction • GSM specifies only 124 carriers (one is used as guard band) Prof. Huei-Wen Ferng

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17. Radio Transmission • GSM time interval • A hyperframe = 2048 superframe = 3 h 28 m 53.76 s • A superframe = 51 traffic multiframes = 26 control multiframes = 6.12 s • A traffic multiframe = 26 frames = 120 ms • A control multiframe = 51 frames = 235.4 ms • A frame = 8 time slots = 4.615 ms • A slot = 156.25 bits = 577 µs • A bit = 3.69 µs Prof. Huei-Wen Ferng

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19. Physical Channels • Traffic Channels • A full-rate traffic channel (TCH/F) occupies one time slot in 24 of 26 frames in every multiframe • Traffic channel information travels in frames 0-11 and 13-24 • Control information travels in frames 12 and 25 • The SACCH occupies one frame in every traffic multiframe • A SACCH associated with a full-rate traffic channel alternatively occupies one slot in frame 12 and one slot in frame 25 Prof. Huei-Wen Ferng

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21. Physical Channels • A half-rate traffic channel (TCH/H) occupies a specific time slot in 12 of 26 frames in every multiframe • Each carrier can carry up to 16 half-rate traffic channels • Eight of these traffic channels have a SACCH in frame 12 and the other eight half-rate channel have a SACCH in frame 25 Prof. Huei-Wen Ferng

22. GSM Bit Stream • The contents of a GSM time slot is shown in Fig. 7.8 • 26 bits of training sequence serves as a purpose similar to that of the SYNC field in NA-TDMA • GSM specifies 8 different training sequences with low mutual cross-correlation • Network operators assign different training sequences to nearby cells that use the same carrier • The two DATA fields carry either user information or network control information Prof. Huei-Wen Ferng

23. Radio Transmission • The FLAG indicates whether the DATA field contains user information or control one • The TAIL bits all set to 0 • There is also a guard time 0f 30.5 µs • The GSM transmission rate is 270.833 kb/s • The modulation scheme in GSM is GMSK a form of frequency shift keying • The modulation efficiency of GSM is 1.35 b/s/Hz • GSM BS turn off its transmitter at the end of each time slot. It resume transmitting after a pause of 30.5µs to send to another terminal in the next time slot • The BS turn off its transmitter in unassigned time slots Prof. Huei-Wen Ferng

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25. Slow Frequency Hopping • The signal moves from one frequency to another in every frame • The purpose of FH is to reduce the transmission impairments • Without FH, the entire signal is subject to distortion whenever the assigned carrier is impaired • Network operator assigns different hopping patterns to different cells Prof. Huei-Wen Ferng

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27. Radiated Power • GSM specifies 5 classes of mobile stations transmitting power, ranging from 20 W (43 dBm) to 0.8 W (29 dBm) • Typically, vehicle-mounted terminal is 8 W and portable terminals is 2 W Prof. Huei-Wen Ferng

28. Spectrum Efficiency • The reuse factor of N = 3 or 4 • The number of physical channel is 124 carriers x 8 channels/carriers = 992 physical channels • The efficiency of GSM is E = 992 channels/4 cells/cluster/50 MHz = 4.96 conversation/cell/MHz (N= 4) or • The efficiency of GSM is E = 992 channels/3 cells/cluster/50 MHz = 6.61 conversation/cell/MHz (N= 3) Prof. Huei-Wen Ferng

29. Logical Channels • Traffic channels (two-way) • Broadcast channels (base-to-mobile) • Common control channels (base-to-mobile or mobile-to-base) • Dedicated control channels (two-way) Prof. Huei-Wen Ferng

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31. Broadcast channels and Common control channels • The broadcast channels always occupy time slot 0 • The common control channels can also occupy time slots 0 • Control Multiframe • There are 5 groups of frames, each containing ten frames beginning with a frequency-correction frame and a synchronization frame • In the reverse direction, time slot 0 is assigned to random access channels in all 51 frames Prof. Huei-Wen Ferng

32. Figure 7.11 shows the contents of time slot 0 in each of the 51 frames Prof. Huei-Wen Ferng

33. Logical Channels • Frequency Correction Channel (FCCH) • The FCCH simply transmits 148 0s • The FCCH always occupies time slot 0 in a frame of 8 time slots • A terminal without a call in progress searches for a FCCH • Synchronization Channel (SCH) • A BS transmits a SCH in time slot 0 of every frame that follows a frame containing an FCCH • The SCH contains a TRAINING sequence • The DATA fields contain BS identity code (6 bits) and the present frame number Prof. Huei-Wen Ferng

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35. Logical Channels • Broadcast Control Channel (BCCH) • BS use the BCCH to transmit the information that terminals need to set up a call, including the control channel configuration and the access protocol • The message length is 184 bits and the encoded message is 456 bits occupying 4 time slots Prof. Huei-Wen Ferng

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37. Logical Channels • Paging Channel (PCH) and Access Grant Channel (AGCH) • The purpose of the AGCH is to direct a terminal to a stand-alone dedicated control channel (SDCCH) • Both channels use the same coding scheme as the BCCH • They occupy 36 frames of time slot 0 per multiframe Prof. Huei-Wen Ferng

38. Logical Channels • Random Access Channel (RACH) • GSM terminals send messages on the RACH to originate phone calls, initiate transmissions of short messages, respond to paging messages, and register their locations • Terminals with information to transmit use the slotted ALOHA protocol to gain access to the time slot • The Ack directs the terminal to a stand-alone dedicated control channel (SDCCH) to be used for further communications Prof. Huei-Wen Ferng

39. Logical Channels • The RACH slot includes a 41-bit TRAIN and 36-bit DATA • The 36-bit DATA field carries a simple 8-bit message • Three of the 8 bits indicate the purpose of the access attempt and the other 5 bits are produced by a random number generator • The 5-bit random code is likely (with probability 31/32) to distinguish the successful terminal from the other Prof. Huei-Wen Ferng

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42. Logical Channels • Stand-Alone Dedicated Control Channel (SDCCH) • SDCCH is a two-way channel assigned to a specific terminal • The physical channel used by an SDCCH is a set of four time slots in each 51-frame control multiframe • With 114 data bits per time slot, the data rate of the SDCCH is 1937.25 b/s (see eq. 7.7) • Each SDCCH has a slow associated control channel • The SACCH occupies an average of two time slots per control multiframe (969 b/s) Prof. Huei-Wen Ferng

43. Logical Channels • Traffic Channels (TCH) • GSM defines two traffic channels, a full-rate channel occupies 24 time slots in every 26-frame and a half-rate channel • The bit rate of a full-rate traffic channel is 22,800 b/s • SACCH occupies time slots in frames 12 or 25 of each 26-frame traffic multiframe • The transmission rate of a traffic SACCH is 950 b/s • With 456 bits transmitted per message, a message spans four traffic multiframes, a time interval of 480 ms Prof. Huei-Wen Ferng

44. Logical Channels • Fast Associated Control Channel (FACCH) • Use the traffic channel to transmit control information, which is an in-band signaling channel • Each FACCH message is multiplexed with user information and interleaved over 8 frames. Therefore, the transmission time of an FACCH message is approximately 40 ms Prof. Huei-Wen Ferng

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46. Messages • GSM Protocol Layers • GSM provides a large number of open interfaces • Message Structure • All of the signaling message length is 184 bits with the exception of the FCCH, SCH, and RACH Prof. Huei-Wen Ferng

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49. Network Operations • Call to a GSM Terminal • Terminal uses the frequency correction channel (FCCH) to synchronize its local oscillator • It then gains timing information from the SCH • The terminal then obtains important information from broadcast control channel (BCCH) • After the initialization procedure, the terminal monitors a paging channel (PCH) • Eventually, it detects a paging request message and this message cause the terminal to transmit a channel request message on the random access channel (RACH) Prof. Huei-Wen Ferng

50. Network Operations • The network response this request by transmitting an immediate assignment message on an access grant channel (AGCH) • This message established a stand-alone dedicated control channel (SDCCH) to be used for exchange of mobility management messages and call management messages • When terminal moves to SDCCH, it transmits a paging response message to BS • The BS then initiates the GSM authentication procedure Prof. Huei-Wen Ferng