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Handover Handover is the process by which the communication with a mobile station is transferred from one radio channel to another. As in nar- rowband CDMA systems, there are different types of handovers — hard handover and soft handover. The hard handover takes place when the base stations participating in the handover process oper- ate on different CDMA carriers, thus requiring that all old radio links be released before new ones are established. Consequently, this type of handover causes the received signal to be interrupted even though it may be for a short time. In a soft handover, on the other hand, a mobile station can receive signals from two or more base sta- tions or two or more sectors of one or more base stations at the same time. As such, the received signal is not interrupted. A soft handover is possible only when the participating base stations use the same CDMA carrier frequency, which is usually the case. The IMT-2000 supports intracell, intercell, and multibearer handovers. In fact, seamless handover without any perceptible degradation in the received signal quality is a desired goal of 3G systems. The handover in W-CDMA is similar in concept to the handoff pro- cedure in cdmaOne based on the standard IS-95. For example, like cdmaOne, it is also triggered by a measurement of the pilot strength. Chapter 6 250 UE UTRAN RRC CONNECTION REQUEST RRC CONNECTION SETUP RRC CONNECTION SETUP COMPLETE Figure 6-32 RRC connection procedure But there are some significant differences. Recall that in cdmaOne, if the signal strength of a pilot exceeds a given threshold, that pilot is taken to be a candidate for handover and is added to the candidate set. In other words, we do not compare the pilots and then select one that is relatively stronger. The threshold may be set to different values by different base stations but does not change dynamically. In W-CDMA, on the other hand, a pilot is selected on the basis of its rel- ative signal strength compared to other pilots. Handover Types As in cdmaOne, there are three types of han- dovers in W-CDMA: ■ Soft handover where all cells in a serving area use the same W- CDMA frequency. ■ Hard handover where the participating cells operate on different W-CDMA frequency bands. Here, not only is it necessary to change the frequency, but also the mode may have to be changed, say, from FDD to TDD. ■ Intersystem handover, for example, with GSM. The network initiates this handover by issuing a handover command. For the purpose of handover, the UE maintains a list of the cells that it is currently using or may likely use at some point during a call. This list includes the following: ■ Active set It consists of all cells that are simultaneously involved in a communication during a soft handover. The UE demodulates the received signals from these cells and coherently combines them to provide diversity. The net gain in performance depends, among other things, upon the relative path loss from the participating base stations to the UE and may be as much as 2 dB or so. An active set contains two or more cells for an FDD system but only one in a TDD mode. ■ Monitored set These are cells that are not in the active set but are monitored by the UE because they are part of the neighbor list. 251 Universal Mobile Telecommunications System (UMTS) ■ Detected set These are cells that are neither in the active nor in the monitored set but are detected by the UE anyway. In what follows, we shall only describe the soft handover [43]. Soft Handover The soft handover concept is illustrated in Figure 6-33. As we just said, the UE maintains an active set for handover purposes. The permissible number of cells in an active set is a sys- tem parameter. Assume that cell 1, being the strongest for a given UE, is the only cell in the active set. If, at a certain instant t 1 , the pilot associated with cell 2 is sufficiently strong that the difference ⌬ 1 between the signal strengths of pilot 1 and pilot 2 is less than a threshold, we can say that pilot 2 is usable, and can therefore include it in the active set. So, from this point on, the UE is in communica- tion with two cells and may, as a result, use diversity combining. This threshold is L Ϫ H 1 , where L is the reporting range, and H 1 is the addition hysteresis. If, at some later time, say, t 2 , pilot 1 has degraded enough that the difference ⌬ 2 between pilot 2 and pilot 1 is greater than another threshold, pilot 1 is no longer usable and can, there- Chapter 6 252 1 t 2 t Pilot Channel Signal Strength Soft Handover Cell 2 added to the active set 11 HL Ϫ<⌬ 2 HLϩ> Pilot 1 from Cell 1 Pilot 2 from Cell 2 Cell 1 deleted from active set 1 ⌬ 2 ⌬ Figure 6-33 Soft handover in UTRAN fore, be removed from the active list. Thus, from now on, the UE is in communication with only one cell, namely cell 2. This second threshold is L ϩ H 2 , where H 2 is the removal hysteresis. As the mobile moves away from its present cell into the coverage area of another, the signal level from the present cell will fall with respect to the signal from the new cell as shown in Figure 6-34. At instant t 0 , the signal strength of the best candidate exceeds pilot 1. Consequently, at that point, we can replace pilot 1 with the new one. This would mean that if pilot 1 was the only member of the active set, the UE will now be communicating with the new cell exclusively, instead of cell 1. If, on the other hand, there were two or more pilots in the active set, the weakest pilot is compared with the new and subsequently replaced if the criterion indicated in the figure is ful- filled. As a result, the UE is now involved in communication with this new cell as well as all old cells except cell 1 (or a particular sec- tor of a cell). The UE updates the active set on command from the UTRAN and sends an acknowledgement back. The messages exchanged when the active set is to be updated are shown in Figure 6-35. 253 Universal Mobile Telecommunications System (UMTS) t 0 t Pilot Channel Signal Strength 3 H> Pilot 1 in Active Set Candidate Pilot Candidate Pilot Replaces Pilot 1 in Active Set Figure 6-34 Intercell handover. In this case, all cells have the same W-CDMA carrier. Summary In this chapter, we have presented a brief description of the UMTS system, its features, and the UTRAN network architecture. The radio interface protocol stack of the UTRAN, which is also the same as the lower-layer protocols of UE, has been presented in some detail. More specifically, we have described the physical layer, the medium access control layer, radio link control, the packet data con- vergence layer, the broadcast multicast protocol, and the radio resource control protocol. Procedures such as those used in synchro- nization, power controls, and handovers are also described. The key features of UMTS W-CDMA may be summarized as fol- lows: ■ Wider bandwidth This is a direct-spread CDMA system with a nominal bandwidth of 5 MHz. The chip rate is 3.84 Mc/s. A radio Chapter 6 254 Active Set Update UE UTRAN Active Set Update Complete Active Set Update UE UTRAN Active Set Update Failure Figure 6-35 Procedure to update the active set TEAMFLY Team-Fly ® frame is usually 10 ms long and consists of 15 slots, each of duration 2,560 chips. ■ Asynchronous operation There is no need for cell sites to be synchronized to each other using a global timing reference. Each cell site may operate in a fully asynchronous manner. However, this requires a different scrambling code for each cell or each sector of a cell. ■ Channel coding Incoming data, depending upon applications, may not be encoded at all or may be encoded into either a convolutional code of rate 1 / 3 or 1 / 2 , or turbo code of rate 1 / 3 . ■ Spreading codes Physical channels are separated at the receiver by spreading them with channel-specific OVSF codes. A spreading factor of 256 is used for control channels. For user data channels, spreading factors vary from 4 to 256 on uplinks and 4 to 512 on downlinks. ■ Scrambling codes Uplink scrambling codes are complex valued and may be either long or short. The long codes have a length of 38,400 chips (that is, 10 ms), whereas short codes are only 256 chips long. The short codes are particularly useful for multiuser detection at base stations. Downlink scrambling codes are also complex-valued. There are a total of 2 18 Ϫ 1 of these codes. However, only 8,192 are used on downlinks. They are divided into 512 groups, each containing one primary scrambling code and 15 secondary scrambling codes. Each code is of length 38,400 chips. ■ Complex spreading W-CDMA uses complex spreading that reduces the amplitude variations of the baseband filter output, thus making the signal more suitable for nonlinear power amplifiers. It also provides better efficiency by reducing the difference between the peak power and the average power. ■ Variable bandwidth Any user equipment may be assigned a variable bandwidth by simply changing the spreading factors and allocating one or more slots and one or more dedicated channels to the UE. Similarly, the system supports multiple applications simultaneously for the same UE. 255 Universal Mobile Telecommunications System (UMTS) ■ Packet mode data services W-CDMA UMTS supports a highly flexible packet mode data service. The multiple-access procedure is based upon the slotted Aloha scheme. Channels that may be used for this purpose include the RACH, CPCH, dedicated channels, and FACH. ■ Coherent demodulation, multiuser detection, and adaptive antenna arrays The system has been designed to facilitate coherent demodulation using pilot bits and supports such advanced technologies as beam forming with adaptive antennas and multiuser detection techniques. ■ Transmit diversity In contrast to GSM, the performance of W- CDMA can be improved to some extent by implementing transmit diversity on a downlink channel. References General Systems Descriptions [1] 3G TS 22.105, Service Aspects; Services and Service Capabil- ities. [2] 3GPP TS 23.107, QoS Concept and Architecture. [3] 3GPP TS 25.401, UTRAN Overall Description. [4] 3GPP TS 25.101, UE Radio Transmission and Reception. [5] 3GPP TS 25.104, UTRA (BS) FDD, Radio Transmission and Reception. [6] 3GPP TS 25.105, UTRA (BS) TDD, Radio Transmission and Reception. Overview of the UE-UTRAN Protocols [7] 3GPP TS 25.301, Radio Interface Protocol Architecture. Chapter 6 256 Physical Layer [8] 3GPP TS 25.201, Physical Layer — General Description. [9] 3GPP TS 25.211, Physical Channels and Mapping of Trans- port Channels onto Physical Channels (FDD). [10] 3GPP TS 25.212, Multiplexing and Channel Coding. [11] 3GPP TS 25.213, Spreading and Modulation (FDD). [12] 3GPP TS 25.214, Physical Layer Procedures. [13] 3GPP TS 25.215, Physical Layer — Measurements. [14] 3GPP TS 25.302, Services Provided by the Physical Layer. Layer 2 and Layer 3 Protocols [15] 3GPP TS 25.321, MAC Protocol Specification. [16] 3GPP TS 25.322, RLC Protocol Specification. [17] 3GPP TS 25.323, Packet Data Convergence Protocol (PDCP) Specification. [18] 3GPP TS 25.324, Broadcast/Multicast Control (BMC) Proto- col Specification. [19] 3G TS 25.331, RRC Protocol Specification. [20] 3G TS 25.303, Interlayer Procedures in Connected Mode. Also, 3GTS 25.304, UE Procedures in Idle Mode and Proce- dures for Cell Reselection in Connected Mode. Protocols at Different Interface Points [21] 3GPP TS 25.410, UTRAN Iu Interface: General Aspects and Principles. [22] 3GPP TS 25.411, UTRAN Iu Interface: Layer 1. [23] 3GPP TS 25.412, UTRAN Iu Interface: Signaling Transport. [24] 3GPP TS 25.413, UTRAN Iu Interface: RANAP Signaling. 257 Universal Mobile Telecommunications System (UMTS) [25] 3GPP TS 25.414, UTRAN Iu Interface: Data Transport and Transport Signaling. [26] 3GPP TS 25.415, UTRAN Iu Interface: CN-RAN User Plane Protocol. [27] 3GPP TS 25.420, UTRAN Iur Interface: General Aspects and Principles. [28] 3GPP TS 25.421, UTRAN Iur Interface: Layer 1. [29] 3GPP TS 25.422, UTRAN Iur Interface: Signaling Transport. [30] 3GPP TS 25.423, UTRAN Iur Interface: RNSAP Signaling. [31] 3GPP TS 25.424, UTRAN Iur Interface: Data Transport and Transport Signaling for CCH Data Streams. [32] 3GPP TS 25.425, UTRAN Iur Interface: User Plane Protocols for CCH Data Streams. [33] 3GPP TS 25.426, UTRAN Iur and Iub Interface Data Trans- port and Transport Signaling for DCH Data Streams. [34] 3GPP TS 25.427, UTRAN Iur and Iub Interface User Plane Protocols for DCH Data Streams. [35] 3GPP TS 25.430, UTRAN Iub Interface: General Aspects and Principles. [36] 3GPP TS 25.431, UTRAN Iub Interface: Layer 1. [37] 3GPP TS 25.432, UTRAN Iub Interface: Signaling Transport. [38] 3GPP TS 25.433, UTRAN Iub Interface: NBAP Signaling. [39] 3GPP TS 25.434, UTRAN Iub Interface: Data Transport and Transport Signaling for CCH Data Streams. [40] 3GPP TS 25.435, UTRAN Iub Interface: User Plane Protocols for CCH Data Streams. Miscellaneous Specifications of Interest [41] 3G TR 23.922, Architecture of an All IP Network. [42] 3G TR 25.990, Vocabulary. [43] 3G TR 25.922, Ver. 0.5.0, Radio Resource Management Strategies. Chapter 6 258 Other References [44] N. Abramson, “The Throughput of Packet Broadcasting Channels,” IEEE Trans. Comm., Vol. COM-25, No. 1, January 1977, pp. 117-128. [45] S.W. Golomb, Shift Register Sequences. Revised Edition, Aegean Park Press, Laguna Hills, CA, 1982. Web Sites http://www.itu.int/publications/ http://www.itu.int/imt/2-rad-devt/index.html http://www.itu.int/brsg/ties/imt-2000/index.html 259 Universal Mobile Telecommunications System (UMTS) [...]... will review the 3G system requirements so that we can understand the driving forces behind the network evolution Review of 3G Requirements [1]–[4] 3G wireless systems are required to provide traditional voice, enhanced voice, multimedia services, and high-speed circuit and packet mode data to mobile users as well as special services such as paging and address dispatch or fleet operation A mobile station... 160 kb/s [9], [10] In view of the requirements of the 3G systems for both constant and variable bit rate services, the need for such a network appears to be even more compelling than ever before In fact, because of these 3G requirements and emerging applications (such as conversational voice and video, interactive data, high volume data transfer, and so on) with a guaranteed quality of service, the... of a mobile communication network Ai Um MS B ISDN Di D A BTS VLR MSC C HLR EIR Other MSC AC Evolution of Mobile Communication Networks 265 MSC saves all the pertinent information of that mobile station in its VLR The home MSC is also notified so that incoming calls to this mobile can be forwarded to the foreign MSC The information in the VLR is really the same as that of the HLR However, when the mobile. .. function labeled IWF, which actually performs some protocol conversion that might be necessary because of the differences in the protocols used on the mobile stations and the PDN To see what kind of protocol conversion is performed by IWF, consider Figure 7-4, where we show the protocol stacks between a mobile station and a base station and between IWF and PDN for packet data transmission in an IS-95... IS-634-A, already uses ATM at the link layer Furthermore, ATM has high-bandwidth capability, and provides low delays and bandwidth-on-demand with guaranteed QoS Second, it interfaces to legacy networks in a rather straightforward way For example, the media gateway performs the necessary protocol conversion between the backhaul ATM network and the circuit-switched PSTN or ISDN The IP routers are used to route... designed for a multimedia terminal use IP at the network layer For example, multimedia terminals in a 3G system may be based on International Telecommunications Union (ITU) standards H.324 and H.320 In either case, the control and indication signals, when transported across a 3G network, use User Datagram Protocol (UDP) at the transport layer and IP at the network layer Similarly, the H.323 protocol for. .. signaling point based upon, for example, the dialed digits The transport, session, and presentation layers are not used in the access or core network The application layer performs call controls and mobility management, and manages radio resources (RR) such as radio channels, spreading codes, scrambling codes, and so on CC and MM messages originate at an MSC and terminate on an MS, and vice versa Thus, they... at any time; however, the network is required to support, for each mobile station, a total bit rate of Evolution of Mobile Communication Networks 263 I 144 kb/s or more in vehicular operations I 384 kb/s or more for pedestrians I About 2.048 Mb/s for indoor or low-range outdoor applications Some user applications may require bandwidth on demand and a guaranteed quality of service (QoS) from networks... EIA Standard IS-41, which, more specifically, define procedures for handoff as a mobile moves from the service area of one MSC to another and automatic roaming IS-634-A [6], [7] defines the interface at reference point A between an MSC and a base station It specifies the interface requirements for all types of user traffic and signaling information exchanged over this reference point The Asynchronous... transport the following information: I The coded user traffic (such as user data or low bit-rate speech) and the signaling information between an MSC and a base station (BS) Separate logical channels carry the user traffic and the signaling information These interface functions are designated as the A3 interface I The signaling information between a source BS that initially serves a call and any other BS that . different types of handovers — hard handover and soft handover. The hard handover takes place when the base stations participating in the handover process oper- ate on different CDMA carriers, thus. changed, say, from FDD to TDD. ■ Intersystem handover, for example, with GSM. The network initiates this handover by issuing a handover command. For the purpose of handover, the UE maintains a list of. Signaling for CCH Data Streams. [32] 3GPP TS 25.425, UTRAN Iur Interface: User Plane Protocols for CCH Data Streams. [33] 3GPP TS 25.4 26, UTRAN Iur and Iub Interface Data Trans- port and Transport