FI100445B - Method and arrangement for handover between base station controllers - Google Patents

Description

100445

Method and arrangement for hand-over between base station controllers

The invention relates to a handover between base station controllers in a personal communication system (PCS).

Various cellular radio systems that enable personal wireless communication have been in use for a long time. One such mobile communication system 10 is the European digital mobile communication system GSM

(Global System for Mobile Communications). In addition, a new generation of systems is under development, which it is hoped will further expand the capabilities of personal wireless communications. One such system under standardization 15 is the Personal Communication System (PCS) in the United States. Under current assumptions, there will be two types of PCS networks: traditional overlay-type networks and fixed ISDN-type and PSTN-type networks. There will be numerous options for the radio interface, one of which is the GSM-based PCS1900 (a GSM system operating in the 1900 MOz frequency range).

Modifying an existing mobile system standard (such as GSM or DCS1800) into a PCS overlay network (such as PCS1900) is a relatively straightforward process. On the other hand, PCS networks of the fixed ISDN and PSTN type, which use a normal fixed local area network (LE) instead of a mobile switching center, are more problematic, in which case such an ISDN / PSTN-based network is not directly suitable for, for example, GSM network architecture. Travel-. In the GSM-based overlay network, the 30 message centers are the central unit of the network * 4, but in the ISDN / PSTN-based network, the local exchange LE has no features supporting the mobile network at all. In the future, the local exchange LE can be expected to include a small number of common features that support the fields of mobile access networks (non-call signaling, some form of handover support) but may not be very useful for the PCS1900 system, for example.

5 One solution to this problem is set out in "Switching and Signaling Generic Requirements for Network Access Services to Personal Communication Services (PCS) Provider, GR-2801-CORE, Issue 1, December 1993, Bellcore, Bell Communications Research, in particular Chapter 1, 10 pages 1-10, section 2, pages 1-26 and section 3, pages 133-137 In this Bellcore-type network, the radio interface is a wireless access communication system WACS (Bellcore TR INS-001313) connected to a local area network of a fixed network. is connected to an intelligent network which provides the local exchange with the service logic, databases and operations required for access network mobility management, i.e. the intelligent network AIN (Advanced Intelligent Network) provides centralized subscriber database services, location management, authentication, access management, etc.

20 The basic functions of call control are in an ISDN local exchange, from which call control can initiate intelligent network operations according to predetermined triggers via the standard AIN interface. Bellcore’s system also supports handover, which Bellcore calls the Automa-25 tic Link Transfer (ALT). The purpose of ALT is to ensure continuity of service for the PCS user when the signal strength varies during a answered call. The signal strength may vary, for example, if the PCS user is moving or if the conditions in the radio environment change. The purpose of the ALT is. 30 allows an existing answered call to continue uninterrupted and without the PCS user having to take action to perform the ALT or know that the ALT has occurred. Chapter 3, pages 133-138 of the above publication describes an ALT procedure in which the "anchor point" of the handover 35 is the local exchange. That is, when performing ALT 3,100445 from the old base station system (IPS / RPCU) to the new base station system (IPS / RPCU), the exchange is disconnected from the old base station system at the exchange and a connection is established to the new base station system. In this case, the local center of the fixed network is the anchor of the connections and signaling. Such a handover using the local exchange as an anchor is possible in new national ISDN exchanges with the required features. However, such a handover solution cannot be considered as a good way 10 to proceed at least in the early stages of PCS systems, as the majority of existing fixed network exchanges are of the older type and therefore the availability of exchanges with the necessary features cannot be guaranteed. In addition, problems are caused by the fact that the anchor point of the handover connections is a network element incompatible with an access network standard such as GSM.

WO 95/01694 discloses a handover between base station systems under the control of a local exchange in a fixed network, in which the anchor point of the handover remains in the mobile communication system. That is, the first base station controller of the call acts as an anchor point to which the original connection established through the local exchange is maintained throughout the call. In the handover, an onward connection is established from the anchor base station controller to another base station controller.

It is an object of the present invention to provide an improved handover between base station controllers that is flexible and independent of the characteristics of a local area network in a fixed network.

This is achieved by an arrangement for performing handover between base station controllers in a • communication system comprising a fixed network local exchange (LE); mobile stations (PS); base station systems that form a wireless access network for mobile stations to a local exchange, each base station system including a base station controller (BSC) and base stations (BTS); transmission lines 4,100,445 on which the local exchange is connected to base station controllers; the handover control between the base station controllers (BSCs) being located in the base station controllers so that the first base station controller of the call acts as an anchor point to which the original connection established through the local exchange is maintained and from which a further connection to the second base station controller is established in handover. The arrangement according to the invention is characterized in that the handover control between the base station controllers is located in the base station controllers so that the first base station controller of the call acts as an anchor point to which the original connection via the local exchange is stored. the first or second base station controller is adapted to decide on the use of said pre-reserved local call connection as an onward connection in the new handover between the base station controllers and to notify and notify the new handover between the base station controllers. any additional connection-related parameters for the second 25 base station controllers.

The invention also relates to a method for performing handover between base station controllers in a communication system comprising a local exchange of a fixed network; mobile stations; base station systems providing mobile stations with a wireless access network to a local exchange, each base station system including a base station controller and base stations; and transmission lines connecting the local exchange to the base station controllers, wherein the method 35 establishes a call connection from the local exchange to the first base station controller serving the mobile station, handovering the call and the mobile station from the first base station controller to the first base station controller, establishing an onward connection from the first base station controller to the second base station controller as a local call connected via the local exchange, connecting the call to said second base station controller via said onward connection. The method according to the invention is characterized in that, if necessary, the local call connection between the base station controllers is not disconnected at the end of the call and kept on hold waiting for the next handover between the base station controllers. notifying the second base station controller of the selection, establishing a handover extension connection via said pre-reserved local call connection from the first base station controller to the second base station controller.

The invention also relates to another method for performing handover between base station controllers, which method is characterized in that a new local call connection is established in advance between the base station controllers and kept in reserve waiting for a handover between the base station controllers.

The handover from the base station controllers is controlled independently of the local exchange, the call connection is maintained from the local exchange to the first base station controller, a decision is made in the first or second base station controller to use via said pre-reserved local call connection from the first base station controller to the second base station controller.

In the invention, the "anchor" of the handovers is, as is known per se, the first base station controller, through which the original voice connection is connected from the local exchange of the fixed network to the base station and further by radio to the mobile station. When handovering to the second base station controller, the original connection between the ISDN local exchange and the first base station controller is maintained and a downlink is established from the first base station controller to the second base station controller either as a local call through the local exchange (s) or another route. The handover is controlled from the base station controllers. Thanks to the solution according to the invention, the "anchor" and the controller of the handover are a network element of the radio system, i.e. the base station controller, and the local exchange only connects according to the instructions of the base station controllers. Since the handover according to the invention does not require any additional features from the local exchange, the handover can also be implemented with the existing local exchange types. 30 all.

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Establishing a local call through a local exchange requires signaling between the local exchange and both base station controllers. In the invention, this signaling load can be reduced so that the local call-35 connection once established between the two base station 7 100445 ground controllers is not disconnected immediately after the call or calls that have used it end or handover to another location. . Instead, the local call connection can be maintained and held in reserve pending the next 5 handovers that require a connection between the base station controllers. The decision to maintain a local call connection can be made, for example, on the basis of network traffic or handover frequency, i.e. when it is assumed that network connections may soon be needed. It is also possible to form such "handover" local call connections to wait for future handovers when they are expected. The invention reduces signaling because connection resources to the local exchange are not constantly allocated and released when new handovers occur. Once established, the local call connection can be used for multiple hand-over connections. Only signaling between base station controllers is required when they establish and disconnect hand-over connections over such a "permanent" local call connection. The establishment and disconnection of local call connections can thus be performed more stably than the establishment and disconnection of handover connections themselves. The invention also shortens the switching time of the handover.

The base station controllers choose whether to use such a pre-reserved location call to establish a handover onward connection. Two forwarding lines are required for each forward connection, one for each forwarding direction. If a new local call is established for the handover extension connection, both base station controllers can independently select the transmission lines to the local exchange, which connects them together. If the handover extension connection is established by means of a pre-booked local call according to the invention, it is important to know which party decides on the connection type and reserves the connection. If both sides were allowed to make reservations independently, the same lines could be booked at the same time at both ends. To eliminate this problem, responsibility for decision making can be assigned to either base station controller. The decision is then signaled to the other party. The base station controller can transfer decision making to another base station controller by leaving the connection information undefined in the signaling.

The invention will now be described by way of preferred embodiments with reference to the accompanying drawings, in which Figure 1 is a block diagram illustrating an ISDN-based PCS network according to the invention, Figure 2 is a block diagram illustrating the division of mobile exchange functions into functional units and their allocation to different networks. , 3B, 3C and 3D show three different ways of performing a handover between base station controllers, Fig. 4 is a block diagram showing handover branches in connection with two consecutive handovers, Figs. 5A, 5B and 5C show a signaling diagram in which a new handover AB 'is formed and an old handover AB is shown. 4, 20, Figure 6 shows a signaling diagram for a handover based on a previously reserved connection.

The basic principles of the invention can be applied to the connection of any wireless access network to a local exchange of a fixed network and to the size of an intelligent network. In preferred embodiments of the invention, the access network is a radio system based on the GSM system, such as PCS1900. In other words, the access network is modified from the GSM mobile communication system or its 1800 MHz version DCS1800. For details of the GSM system, see. 30 ETSI GSM recommendations and the book "The GSM System for • *

Mobile Communications ", M. Mouly & M. Pautet, Palaiseau, France, 1992, ISBN: 2-9507190-0-0-7.

The block diagram of Figure 1 illustrates the network elements of a PCS1900 network based on a fixed network. The access network PCS1900 comprises base station systems BSS, each of which includes one base station controller BSC and several base stations BTS. The base stations BTS communicate over the radio interface with the personal stations PS (mobile stations). The radio interface between the mobile station PS and the base station BTS and the interface between the base station BTS and the base station controller BSC are similar to those in a conventional overlay-type PCS1900 system and will not be discussed in more detail here. However, unlike a conventional GSM-based network, the base station controllers BSC are not connected to a mobile switching center MSC but to a fixed network, such as ISDN or a PSTN local exchange LE. In preferred embodiments of the invention, the local exchange is an ISDN exchange. The local exchange LE, in turn, connects to the AIN (Advanced Intelligent Network) service control point SCP 15 via a standard intelligent network interface. In some cases, the smart grid is unnecessary. In this case, the local center itself may contain more intelligent functions. Furthermore, the local exchange LE is normally connected to other local exchanges LE or remote exchanges TX in the ISDN network.

20 Such a PCS network based on a fixed network is thus not directly compatible with the GSM architecture, since it has no mobile switching center MSC at all. In a conventional over-lay type mobile communication network, the mobile switching center MSC is a central unit of the network, but the local exchange of the fixed network does not support the full functionality of the MSC. Therefore, in the present invention, the functions of the mobile switching center are divided into functional units, which are placed in the base station controller BSC, except for call control. In addition, with the help of the intelligent network AIN, the function corresponding to the home system-30 register HLR of the GSM system is implemented, as well as at least a part of the function corresponding to the visitor register.

The possible allocation of functional units to different network elements is illustrated in Figure 2. Functionally, the names of the units all end in the letter F (function) to distinguish between the functional units and the physical network elements (BSC, SCP, LE...) To which they belong. can be placed, in between. The following is a brief description of each functional unit.

The BSCF (Base Station Controller Function) corresponds to the nor-5 target BSC functionality in the GSM network.

BSCF + (Base Station Controller Function Additions) - distributes the A-interface from the BSCF so that call control goes to the LEF and other signaling to the RSCF - performs handover (HO) related switching operations as an anchor for connections - converts GSM-based for call control ISDN call control - includes various possible adapter functions (interworking) 15 LEF (local exchange function) contains standard ISDN local exchange LE functions (by default National ISDN3). The LEF may also support non-call related (NCA) signaling from the base station system BSS to the service control node SCP. In the preferred embodiment of the invention, no changes to the standard LEF function are proposed, because the ISDN-based PCS1900 system should operate under any standard fixed network ISDN local exchange LE.

, The RSCF (radio system control function) takes care of many tasks of the mobile switching center MSC. It controls radio resources (e.g., generates assignment and handover request instructions and controls handover between base station controllers BSCs or local exchanges LE. RSCF is also a boundary unit between A-interface protocols and MAP protocols 30.

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HOF (handover decision function). This unit has been separated from the RSCF to allow the handover process to be controlled from an even higher level. However, only high-level decisions, such as congestion control 35, are made in the HOF. The actual handover HO

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11 100445 is executed by BSCF + and is controlled by RSCF.

The VLRF (visitor location register function) is a traditional VLR divided into two parts: VRL1F and VRL2F. The upper part VLR2F of the VLR is located in the service control point SCP 5 of the intelligent network and the lower part VLR1F is located in the access network, more precisely in the base station controller. According to the currently most advantageous division, the lower VLR1F takes care of authentication, location management, temporary identification, etc., and the upper VLR2F takes care of the service control base and other matters related to the user profile.

The SCF (service control function) is a standard fixed network service control function SCF that provides standard intelligent network services (AIN). It also has the ability to make location queries to the HLRF (equivalent to gateway-MSC situations), local location queries to the VRLF, collaborate with the VRLF to answer AIN queries, and so on.

HLRF (home location register function) is a GSM home register. In addition, the intelligent network includes an EIRF (equipment identification register function) and possibly an SMS-GIWF (short message service gateway - interworking function), which, however, need not be described in more detail here.

In a preferred embodiment of the invention, the functional units described above are divided into network elements 25 according to Figure 2: the local exchange LE includes a LEF unit, · the SCP includes SCF and VLR2F units; the base station controller BSC includes BSCF and BSCF + units and an access manager AM, which includes RSCF, HOF and VLR1F units. Alternatively, the entire VLRF may be located in the BSC or • 30 SCPs.

It should be noted that only the functional units BSCF, BSCF + and LEF handle the actual voice / data connections. These functional units, which are at the bottom of the functional model, are bound to route connections (link chain: BSCF, BSCF +, LEF). Other functional units only handle signaling and therefore their allocation may differ from the above if desired.

In a preferred embodiment of the invention, there is further 5 a new alternative signaling path 10 which bypasses the local exchange LE between the base station controller BSC and the service control point SCP. This makes signaling between the BSC and the HLR simpler. The signaling interfaces LE-BSC and SCP-BSC are called C-interfaces. The C-interface signaling 10 may use signaling unrelated to the call of the ISDN network, or alternatively the Signaling System No. 7 (SS7) network may be used for signaling between the base station controller BSC and the intelligent network AIN related to PCS functions.

The handoverpro-15 procedures according to the invention are described below. In handover, an ongoing call is transferred from one traffic channel to another traffic channel on the same or a neighboring base station. In this way, the continuity of the call is ensured through the signal strength as the quality varies as a result of user movement or as the radio environment 20 changes. The handover between base stations under the same base station controller BSC (base station controller internal handover) is performed in substantially the same manner as in a conventional DCS1900 system and is not significant to the invention. Instead, the present invention provides improvements to the han-Dover between the two base station controllers BSC.

Figures 3A, 3B, 3C and 3D show three different ways to perform a handover between base station controllers BSC. Fig. 3A shows a pre-handover situation in which the connection is connected via the local exchange LE to the base station controller BSC1 and further by radio to the mobile station PS. The aim is to perform a handover so that the call is switched to pass through the base station controller BSC2 to the mobile station PS. Figure 3B shows a prior art handover using a local exchange LE as an anchor, requiring new functions from 13,100,445 local exchange LEs. This method of handover may be possible in new ISDN exchanges, but it is not a good implementation in the early stages of BSC systems, as the availability of exchanges with the required features cannot be guaranteed. Additional problems are caused by the handover anchor being a network element that does not comply with the access network standard (e.g. GSM).

Figure 3C illustrates a local call-based handover in which the original connection LE-BSC1 is maintained and an additional connection is established between the base station controllers BSC1 and BSC2 via the exchange LE by the local call BSC1-LE-BSC2. Thanks to this solution, the handover anchor is BSC1, and the local exchange LE only connects the connection. Because no additional features are required from the LE, hand-15 over can be implemented under all existing ISDN exchanges.

Figure 3D shows a fixed connection handover. Also in this case, the original connection between the LE-BSC1 is maintained and a "local call" is established between the base station controllers BSC1 and BSC2 when the BSC2 acts as an anchor. However, in this case, the local call is not established as connected by the exchange LE, but fixed connections between the base station controllers BSC1 and BSC2 are used. It should be noted that these leased lines may physically pass through 25 LEs. The leased lines between the base station controllers BSCs shown in Figure 3D are preferably used where handovers between these base station controllers occur frequently.

30 Subsequent handover based on a local call *.

Figure 4 shows a call situation in which the original call is established from the exchange LE to the base station controller BSC / A. This is co-identified by the number DNorig. A handover to the base station controller BSC / B is then performed. As a result, a local call-based handover branch is formed, which allocates one line on the BSC / A side of the DNAold anchor and one line on the BSC / B side of the DNBold base station controller. The following describes a new subsequent handover from the base station controller BSC / A to the base station controller BSC / B '. In this handover 5, a new local call-based handover branch will be formed, which reserves the line DNAnew on the BSC / A side of the anchor and the DNBnew line on the BSC / B 'side of the base station controller. After a successful handover, the old handover branch is dismantled. This is the most complex handover situation, which will be described with reference to the Signaing diagram shown in Figs. 5A, 5B and 5C, where the numbering used corresponds to the numbering in the following text.

New messages that are not standard GSM, ISDN, or AIN messages are in lower case. 15 Capital letters are used in messages where there are only changes in parameters. LEF / A, LEF / B and LEF / B 'are LEF units of base station controllers BSC / A, BSC / B and BSC / B' in the local exchange LE, respectively.

1: The HANDOVER_REQUIRED message starts the handover in ku-20 ten GSM. BSCF + only forwards this message to the RSCF.

2: map_select_target is a new message introduced to allow handover decisions to be made higher online. This can be useful if, for example, the RSCF is allocated to the base station controller BSC and the BSC is not considered to have enough global information about the network load or the like. The message is sent to HOF. The sole purpose of this message is to select the most appropriate target cell (TCI) for the handover and return the Target Number (Tnr) indicating the RCSF associated with the target cell.

.30 3: MAP_PREPARE_SUBSEQUENT_HANDOVER is a GSM compliant message. However, the destination number parameter (Tnr) indicates the new visited RCSF and not the mobile switching center MSC.

4: The decision as to which type of coupling should be used for the new handover branch on the B 'side is made in 35 RCSF. In this example, it is assumed that the RSCF on the anchor side makes this decision. Alternatively, the decision can also be made by B '. Possible connection type options are to establish a local call BSC / A-BSC / B 'via the exchange LE, to use a fixed connection between BSC / A-BSC / B', if any, or to use a previously reserved free but unconnected local connection BSC / A-BSC / B 'or part of a previously reserved local call connection. The RSCF also controls the use of access lines, i.e. from catalog number DN. The RCSF allocates a new access line DNAnew to a new 10 local call containing a new branch A-B '.

MAP_PREPARE_HANDOVER is the same as in GSM, but a new parameter HOCT (handover connection type) has been added, which allows the use of different handover types. The message may also contain other parameters related to the HOCT parameter. The values of the HOCT parameters as well as possible Additional Parameters are defined in more detail in Table I. For example, in the case of using part of an existing local call, the message could have two additional parameters: DNBnew indicating that the interface line corresponds to 20 existing local calls on the B 'side; ) indicating which part of the 64 kbit / s line is used.

5, the B-side RSCF allocates a connection line as a local DNBnew new. It should be noted that in the traditional 25 GSM system, the VLR allocates a handover number to the new branch. Instead, the catalog number DNBnew allocated by the RSCF is closely related to the connection line used. Therefore, it cannot be returned after the handover has been performed like a handover number in traditional GSM only 30 only after the handover branch has been disconnected, as a result of a call disconnection or a new handover. It should also be noted that two connection lines and corresponding catalog numbers are required for the new handover branch.

The HANDOVER_REQUEST message is the same as in GSM, but between 35 RSCF / B1 and BSCF + / B 'an allocated handover number 16 100445 is sent and not the CIC. This message also includes the HOCT and any Additional Parameters.

6: HANDOVER_REQUEST is as in GSM. HANDOVER_RE -QUEST_ack is the same as in GSM. BSCF + / B ', forward the message only 5 A-side RCSFrlle. The Layer 3 information parameter (L3info) contains HANDOVER_COMMAND (see section 21).

8: MAP_PREPARE_HANDOVER_ack is as in GSM. The HOCT parameter is also included (see section 11) as defined in Table I. The HOCT parameter (and any additional 10 meters) is sent back to the anchor side to allow the connection type to be negotiated and / or the communication resources to be controlled from the B 'side. In this example, the HOCT does not carry any new information to the anchor side A.

9: new_leg_command is a new message linking 15 RCSF handover controls to BSCF + call control. The RSCF instructs the BSCF + to establish a new handover branch for the current call. The new branch is to use the number DNAnew and the corresponding connection line A-side of the BSCF + and DNBnew digits (and the corresponding connection line), the B-side, the BSCF + Act. HOCT says 20 that the type of this handover is "new local call".

10: The SETUP message is like in an ISDN network. The local exchange must establish a local call for the handover branch.

11, 12, 13: INITIAL_ADDRESS_MESSAGE, CALL_PROCEEDING 25 and SETUP are as in ISDN.

14: setup_detect is a new message telling RCSF / B 'that the new handover branch is complete. The BSCF + / B 'is able to link this new branch based on the previously allocated radio resources to the interface used, which corresponds to the number DNBnew.

15, 16, 17: ALERTING, ADDRESS_COMPLETE_MESSAGE and ALERTING are as in ISDN.

18: new_leg_complete reports that a new handover branch has been successfully formed.

35 19: MAP_PREPARE_SUBSEQUENT_HANDOVER_ack is like 17 100445 in GSM.

20, 21: HANDOVER_COMMAND is as in GSM. The BSCF + / B1 only forwards the message, but it should also be noted that a CONNECT message can now be sent (see section 25).

5 25, 26, 27, 28, 29: CONNECT, CONNECT_ACK, ANSWER_MESSAGE, CONNECT and CONNECT_ACK are as for ISDN.

30. connect_detect is a new message indicating that the connection line is connected.

31: MAP_SEND_END_SIGNAL is the same as in GSM.

10 32: switch_leg_command is a new message telling BSCF + / A that the new branch can be used from now on. As a result, the old handover branch can be dropped off. In this example case, the HOCT parameter indicates that the local call 15 associated with the old branch can be disconnected (cf. Table I). It should be noted, however, that it is not necessary to disconnect the local call after all the handover branches in it have been disconnected. It is also possible, for example, to maintain the connection waiting for new handover between the branches of the A side and the B-side. The value of the HOCT parameter in this case is "nothing" (cf. Table I).

33, 34, 35, 36: MAP_SEND_END_SIGNAL_ACK message, CLEAR_COMMAND messages and CLEAR_COMPLETE messages are as in GSM. BSCF + / B only passes the CLEAR_COMMAND message and turns off the handover branch.

25 37, 38, 39: DISCONNECT, RELEASE and RELEASE_COMPLETE

are as in ISDN.

40: disconnect_detect is a new message indicating that the interface line and catalog number have been released.

41, 42, 43, 44, 45: RELEASE, RELEASE_ACK, DISCON-30 NECT, RELEASE and RELEASE_COMPLETE are as in ISDN.

46: disconnect_detect is a new message indicating that the interface line and catalog number have been released.

In this exemplary case, a handover is performed from the base station controller BSC / A to the base station controller BSC / B using a local call, BSC / A-BSC / B, that is pre-reserved or not canceled during a previous call or handover to form a handover branch. In contrast, the idea of sa-5 noe is that a once-booked local call does not need to be disconnected immediately after the call (or calls) that used it is disconnected or a handover to a new location is made during the call. The local call can instead be stored and held on hold pending the next 10 handovers that require a connection between these same base station controllers BSCs. For example, in the handover process of Figures 5A-5C, the local call between the base station controllers BSC / A and BSC / B could have been omitted by setting the HOCT parameter 15 of the switch_leg_command message sent in step 32 to "nothing". Another option is to reserve such local call connections between base station controllers, for example on administrative grounds, assuming that handover connections may soon be needed. This method 20 of the invention reduces signaling between the base station controllers and the local exchange because connection resources are not continuously allocated and released whenever new handover connections are needed or no longer needed. With such a procedure according to the invention, the establishment and termination of local calls 25 can thus take place more stably than the establishment and termination of the handover connection itself.

The signaling diagram of Figure 6 shows such a handover based on a busy connection from a base station controller BSC / A to a base station controller BSC / B. Figure 6 shows the messages,. 30 for which a message of similar structure can be found in Figures 5A, 5B and 5C, denoted by the same numbers. In the following description, only the differences compared to the corresponding messages in Figures 5A-5C are listed. The example assumes that the hand-over type is decided by the B-side. The A-side RSCF set 35 MAP_PREPARE_HANDOVER p anoman HOCT parameter to "undecyl

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19 100445 fined, which tells the B side that it should make a decision on the type of handover (cf. Table I).

1,2: are as in Figure 5A, but in the base station controller BSC / A, 5 3: missing because there is no old hanodover branch in this example as in Figure 5, 4: the B side decides to use an existing local call between the base station controllers BSC / A and BSC / B between. Therefore, in the HANDOVER_REQUEST message, it sets the HOCT parameter-10 rin to "existing local call" and includes the directory number DNBnew and the identifier CIC in the message. The message is sent to the B-side BSCF + a.

5: The CIC contained in this HANDOVER_REQUEST message is the line identifier of the A-interface, i.e. different from the CIC of step 2.

6.7: as in Fig. 5A, but in BSC / B, 8: the A side must be informed of which type of handover has been decided to be used. For this purpose, the B-side RSCF set MAP_PREPARE_HANDOVER_ack message HOCT parameter to "existing local call" and include message read-telonumeron DNBnew 20 and the reserved line (point 2), the identifier of CIC.

9: Here, it is assumed that the A-side RSCF capable of managing the directory number DNAnew received by the catalog number DNBnew. DNBnew and DNAnew 25 and the CIC is included in the message new_leg-command, which is sent to the A-side BSCF + for connection to a handover branch.

10-17: unnecessary, 18: as in Fig. 5B, but in BSC / A, 19: unnecessary, • 20.21: as in Fig. 5B, but in BSC / A, 22,23,24: as in Fig. 5C, but in BSC / B, 25,26,27,28,29,30: unnecessary, 31: as in Figure 5C, but in BSC / B, 32,33,34,35,36: as in Figure 5C, but BSC / A 35 As shown in the signaling example above 100445, the use of a pre-allocated local call as a handover branch substantially reduces the signaling load, especially between the local exchange LE and the base station controllers BSC.

5, it should be noted that the handover based on the reserved local call can also be performed in the subsequent handover between the base stations BSC / A and BSC / B 'according to Figs. 5A-5C.

Although the invention has been described with reference to certain embodiments, it is to be understood that the description is given by way of example only and that changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

An arrangement for performing handover between base station controllers in a telecommunication system comprising a local station (LE) in a fixed network; mobile stations (PS); base station system forming a wireless connection network to the mobile station local station, each base station system comprising a base station controller (BSC) and base stations (BTS); transmission lines with which the local station is connected to the base station controllers; wherein the handover control between the base station controllers is arranged in such a manner in the base station controllers that a first base station control unit for the telephone call acts as an anchoring base for which the original connection established via the local station is maintained and from which a continuation connection is established in a handover situation. to a second base station controller, characterized in that the base station controllers are arranged so as not to disable a local call connection between the base station controllers when the call is terminated and without holding the connection in reserve pending the next handover between the base station controllers, a first or second base station controller. determining whether said pre-reserved local call switching should be used as a continuation connection in a new handover between the base station controllers and informing the second base station controller of the choice 30 and any other parameters related thereto. 2. Arrangement according to claim 1, characterized in that the base station controllers (BSC) are arranged to establish a new local call connection between the base station controllers in advance and to keep it in reserve pending the next handover between the 26 100445 base station controllers. Arrangement according to claim 1 or 2, characterized in that the same local call connection is used to form two or more handover connection connections at different times without disconnection between them. 4. Arrangement according to claim 1, 2 or 3, characterized in that the establishment of the handover connection via the reserved local call connection only comprises signaling between the base station controllers (BSC). A method for performing handover between base station controllers in a telecommunication system comprising a local station in a fixed network; mobile stations; A base station system forming a wireless connection network for the mobile stations to the local station, each base station system comprising a base station controller and base stations; and transmission lines with which the local station is connected to the base station controllers, in which method a telephone connection is established from the local station to a first base station controller serving the mobile station, handover is executed to transfer the telephone call and the mobile station from a base station controller to the another base station controller, the handover control occurs from the base station controllers independently of the local station, the call coupling from the local station to the first base station controller is maintained, a continuation connection is established from the first base station controller to the second base station controller as a local call coupled to the local station, the telephone call is coupled via said continuation connection to the second base station controller, characterized in that the local call connection is not switched off when necessary terminates without being held in reserve pending the next handover between the base station controllers, decisively struck in the first or second base station controller about the use of said pre-reserved local call switching as a continuation connection in a new handover between the base station controllers, the base station controller informs the second base station controller of its choice, a handover continuation connection is established via the pre-reserved local call connection from the first base station controller to the second base station controller n. Method according to claim 5 (characterized in that the same local call connection is used for establishing that one or more hand-forwarding connections at different times without disconnecting the connection therebetween. Method according to claim 5 or 6, characterized in that the handover-continuation connection is established via the reserved local call connection only with signaling between the base station control units. A method for executing handover between base station controllers in a telecommunications network, which comprises a local station in a fixed network; mobile. . 30 stations; base station systems which form a wireless network to the local station for the mobile stations, each base station system comprising a base station controller and base stations; and transmission lines with which the local station is connected to the base station controllers, in which method 28 100445 a telephone connection is established from the local station to a first base station controller serving the mobile station, a handover is performed to transmit the telephone call and the the mobile station from a first base station controller to a second base station controller, characterized in that a new local call connection is established in advance between the base station controllers and is held in reserve pending a handover between the base station controllers; the first base station controller is maintained, decisively met in the first or second base station controller about the use of said pre-reserved local call switching as a continuation connection in a new handover, base station the control unit that has made the decision informs the second base station controller of the choice, a handover continuation connection is established from the first base station controller to the second base station controller via said pre-reserved local call switching. ; 25 9. A method according to claim 8, characterized in that the same local call connection is used to establish one or more handover continuation connections at different times without switching it off in between. 30 Method according to claim 8 or 9, characterized in that a handover-continuation connection is established via the reserved local call connection only with signaling between the base station controllers. II