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GSM Channels & Air Interface. The GSM radio interface. The radio interface is the interface between the mobile stations and the fixed infrastructure. It is one of the most important interfaces of the GSM system.
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The GSM radio interface • The radio interface is the interface between the mobile stations and the fixed infrastructure. It is one of the most important interfaces of the GSM system. • One of the main objectives of GSM is roaming. Therefore, in order to obtain a complete compatibility between mobile stations and networks of different manufacturers and operators, the radio interface must be completely defined.
---- • The spectrum efficiency depends on the radio interface and the transmission, more particularly in aspects such as the capacity of the system and the techniques used in order to decrease the interference and to improve the frequency reuse scheme. • The specification of the radio interface has then an important influence on the spectrum efficiency.
Frequency allocation • Two frequency bands, of 25 MHz each one, have been allocated for the GSM system: • The band 890-915 MHz has been allocated for the uplink direction (transmitting from the mobile station to the base station). • The band 935-960 MHz has been allocated for the downlink direction (transmitting from the base station to the mobile station).
GSM Bands in Pakistan (From Frequency Allocation Board, Pakistan)
Definition of Channels Logical Channel Type of information to be transmitted e.g., traffic or control logical channels. Transport Channel How and with what format data is transmitted through physical links. Physical Channel Unit of radio resource of a radio system e.g., frequency band, time slot, code, etc. RF Channel Fixed frequency band of a radio system. • The MAC (media access control) sub-layer is responsible for mapping logical channels onto transport channels. • The physical layer is responsible for mapping transport channels onto physical Channels.
What is MAC? • Short for Media Access Control address, a hardware address that uniquely identifies each node of a network. In IEEE 802 networks, the Data Link Control (DLC) layer of the OSI Reference Model is divided into two sub-layers: theLogical Link Control (LLC) layer and the Media Access Control (MAC) layer.The MAC layer interfaces directly with the network medium. Consequently, each different type of network medium requires a different MAC layer. • On networks that do not conform to the IEEE 802 standards but do conform to the OSI Reference Model, the node address is called the Data Link Control (DLC) address.
GSM Physical Channel GSM physical channel relates to the recurrence of one burst in every frame. This channel is characterized by both its frequency and its position within the TDMA frame.
GSM Logical Channel • The logical channels consist of the information carried over the physical channel. • There are two major categories of GSM Logical channels • Traffic channels • Control channels.
GSM Physical Channel (in detail) A single GSM Carrier is divided into eight timeslots. Therefore can support up to eight MS subscribers simultaneously. The timeslots are arranged in sequence and are conventionally numbered 0 to 7. Each repetition of this sequence is called a “TDMA frame”.
GSM Physical Channel Cntd.... BURST: • The information carried in one timeslot is called a “burst”. • The timing of the burst transmissions to and from the mobiles is critical. • Each time slot of a TDMA frame lasts for duration of 156.25 bit periods or • 576.9 µsec or 0.576 ms • so a frame takes 4.615 ms • GSM’s data transmission rate is 270.83 kbps per carrier frequency. • Therefore one bit duration is 3.692 µsec
Burst structure • As it has been stated before, the burst is the unit in time of a TDMA system. Four different types of bursts can be distinguished in GSM: • The frequency-correction burst is used on the FCCH. It has the same length as the normal burst but a different structure. • The synchronization burst is used on the SCH. It has the same length as the normal burst but a different structure. • The random access burst is used on the RACH and is shorter than the normal burst. • The normal burst is used to carry speech or data information. It lasts approximately 0.577 ms and has a length of 156.25 bits.
TB Data Training seq. Data TB GP Normál burst (NB) 000 58 bit 26 bit 58 bit 000 8.25 bit time TB 000...0 TB GP Frequency Correction Burst (FB) 000 142 bit 000 8.25 bit time TB Data Sync. seq. Data TB GP Synchronization burst (SB) 000 39 bit 64 bit 39 bit 000 8.25 bit time TB Sync. seq. Data TB GP Access burst (AB)or RACH 000 41 bit 36 bit 000 68.25 bit time
GSM Logical Channels • There are two main groups of logical channels, traffic channels and control channels. • Run over a physical channel, but not necessarily in all its time slots • Have to be managed: set up, maintenance, tear down. • Traffic & Control channels are further classified into groups.
Traffic Channels A traffic channel (TCH) is used to carry speech and data traffic. TCHs for the uplink and downlink are separated in time by 3 burst periods. Therefore MS does not have to transmit & receive simultaneously, thus simplifying the electronics. In addition to these full-rate TCHs, there are also half-rate TCHs defined. Half-rate TCHs will effectively double the capacity of a system at the cost of voice quality.
Traffic Channels Cntd.... • Traffic channels can carry either • Speech or • Data • Speech channels are supported by two different methods of coding known as • Full Rate (FR) • Enhanced Full Rate (EFR)
Traffic Channels Cntd.... Enhanced Full Rate coding provides a speech service that has improved voice quality from the original Full Rate speech coding. EFR employs a new speech coding algorithm and additions to the full rate channel coding algorithm to accomplish this improved speech service. it is only supported by Phase 2+ mobiles onwards.
Full Rate TCH TRAFFIC CHANNELS Half Rate TCH TCH/HR TCH/FR TCH/F 9.6 TCH/H4.8 TCH/F 4.8 TCH/H2.4 TCH/F 2.4 Full Rate Traffic Channels Data Rate NAME Name Type Type Data Rate TCH/HR TCH/FR Speech Speech 11.4 kbps 22.8 kbps 22.8 kbps TCH/H9.6 TCH/F9.6 Data Data 11.4 kbps 22.8 kbps TCH/H4.8 TCH/F4.8 Data Data 11.4 kbps 22.8 kbps TCH/F2.4 Data Traffic Channels Cntd.... Half Rate Traffic Channels
GSM CONTROL CHANNELS (CCH) • There are three main control channels in the GSM system • Broadcast Channel (BCH) • Common Control Channel (CCCH) • Dedicated Control Channel (DCCH) • Each control channel consists of several logical channels having different Control Functions.
Broadcast Channels (BCH) The broadcast channel operates on the forwardlink of a specific ARFCNs It transmits data only in (TS 0) of certain ARFCNs. Other TSs are available for TCHs. The BCH provides synchronization for all mobiles within the cell. It is also monitored by mobiles in neighboring cells so that the received power and MAHO decisions can be made by out-of-cell users.
i) BROADCAST CONTROL CHANNEL (BCCH) BCCH is a forward control channel. information such as cell and network identity. The BCCH is transmitted by the BTS at all times. The RF carrier used to transmit the BCCH is referred to as the BCCH carrier. Information on BCCH is monitored by the MS periodically (at least every 30 secs), when switched on & not in a call. The BCCH is transmitted at constant power at all times, and its signal strength is measured by all MS which may seek to use it.
BROADCAST CONTROL CHANNEL Cntd…. • BCCH Carries the following information (this is only a partial list): • Location Area Identity (LAI). • List of neighboring cells which should be monitored by the MS. • List of frequencies used in the cell. • Cell identity. • Power control indicator. • DTX permitted. • Access control (for example, emergency calls, call barring). • CBCH description. • List of Channels currently in use within a cell.
ii) FREQUENCY CORRECTION CHANNEL (FCCH) FCCH is a forward control channel. It is transmitted on same ARFCN i.e. of BCCH The FCCH allows each subscriber unit to synchronize its internal frequency standard (local oscillator) to exact frequency of the base station
iii) SYNCHRONIZATION CHANNEL (SCH) • It’s also a Downlink Channel. • SCH allows each mobile to frame synchronize with the base station. • It transmits two Important Information • Frame number. • Base Site Identity Code (BSIC). • The frame number (FN) ranges from 0 to 2715647. • The BSIC is uniquely assigned to each BTS in a GSM system. • The BS issues course timing advancement command to the mobile station over the SCH
COMMON CONTROL CHANNEL (CCCH) The common control channels occupy TS 0 of every GSM frame that is not otherwise used by the BCH. CCCH consist of three different channels. These channels are described in following slides
i) PAGING CHANNEL (PCH) It exists only on downlink (Forward channel). The paging channel (PCH) provides paging signals to all mobiles. notifies a specific mobile of an incoming call which originates from the PSTN. The PCH transmit the IMSI of the target subscriber, along with a request for acknowledgment from the mobile unit. the PCH is also used to provide cell broadcastASCII text messages to all subscribers, as part of the SMS feature of GSM
ii) RANDOM ACCESS CHANNEL (RACH) The RACH is the onlyreverselink (uplink) channel. MS acknowledges a page from the PCH on RACH. RACH is also used by mobiles to originate a call. The RACH uses slotted ALOHA access scheme. At the BTS, every frame (even the idle frame) will accept RACH transmissions from mobiles during TS 0
iii) ACCESS GRANT CHANNEL (AGCH). AGCH is used by the BS to provide forward link communication. The AGCH is used by the BS to respond to a RACH sent by a mobile station. It carries data for MS to operate in a particularphysical channel (time slot and ARFCN). The AGCH is the final CCCH message sent by the base station before a subscriber is moved off the control channel.
iv) CELL BROADCAST CHANNEL (CBCH) CBCH is used to transmit messages to be broadcasted to all MSs within a cell. it is considered a common channel because the messages can be received by all mobiles in the cell.
DEDICATED CONTROL CHANNELS (DCCH) There are three (03) types of Dedicated Control Channels in GSM. like Traffic Channels they are bi-directional. Same format and function in both the forward and reverse links. DCCHs may exist in any time slot and any ARFCN except TS 0 of the BCH ARFCN.
i) STAND-ALONE DEDICATED COTROL CHANNEL (SDCCH) The SDCCH carries signaling data following the connection of the MS with the BTS just before a TCH assignment. The SDCCH ensures the Connection b/w MS and BS during the verification of subscriber unit & allocation of resources for the MS. It is a dedicatedpoint-to-point signaling channel which is not tied to the existence of a TCH (stand-alone),
i) STAND-ALONE DEDICATED COTROL CHANNEL (SDCCH)…… • The SDCCH is requested from the MS via the RACH and assigned via the AGCH. • The SDCCH can be thought of as an intermediate and temporary channel. • A SDCCH may also be used for • call setup, • Authentication • location updating • SMS point to point • e-Fax
ii) SLOW-ASSOCITED CONTROL CHANNEL (SACCH) • The SACCH is always associated with a TCH or a SDCCH and maps onto the same physical channel. • Each ARFCN systematically carries SACCH data for all of its current users. • On the downlink, SACCH sends slow but regularly changing control information to the mobile station. • transmit power level instruction. • and specific timing advance instruction.
ii) SLOW-ASSOCITED CONTROL CHANNEL (SACCH)….. • On reverse channel SACCH sends • received signal strength (form Serving BTS). • quality of the TCH. • BCH measurement results (from neighboring cells) • The SACCH is transmitted during the 13thframe of every speech dedicated control channel
iii) FAST-ASSOCIATED CONTROL CHANNEL (FACCH) FACCH carries urgent messages, and contains essentially the same type of information as the SDCCH. A FACCH is assigned whenever a SDCCH has not been dedicated for a particular user and there is an urgent message (e.g. handoff request). The FACCH gains access to a time slot by “stealing” frames from the traffic channel to which it is assigned
Speech coding The transmission of speech is, at the moment, the most important service of a mobile cellular system. The GSM speech codec, which will transform the analog signal (voice) into a digital representation, has to meet the following criteria: • A good speech quality, at least as good as the one obtained with previous cellular systems. • To reduce the redundancy in the sounds of the voice. This reduction is essential due to the limited capacity of transmission of a radio channel. • The speech codec must not be very complex because complexity is equivalent to high costs. The final choice for the GSM speech codec is a codec named RPE-LTP (Regular Pulse Excitation Long-Term Prediction). This codec uses the information from previous samples (this information does not change very quickly) in order to predict the current sample. The speech signal is divided into blocks of 20 ms. These blocks are then passed to the speech codec, which has a rate of 13 kbps, in order to obtain blocks of 260 bits.
Discontinuous transmission (DTX) • This is another aspect of GSM that could have been included as one of the requirements of the GSM speech codec. The function of the DTX is to suspend the radio transmission during the silence periods. This can become quite interesting if we take into consideration the fact that a person speaks less than 40 or 50 percent during a conversation. The DTX helps then to reduce interference between different cells and to increase the capacity of the system. It also extends the life of a mobile's battery.