JP2001522178A - Method and apparatus for terminating a handover between wireless communication systems - Google Patents

Abstract

(57) [Summary] A handover method of a communication signal (270) related to a mobile communication device (209) is performed between a first wireless communication system (202) and a second wireless communication system (204). The first wireless communication system includes a landline switching element (211), a computer platform (212), and a first base station system element (206). The second wireless communication system includes a mobile switching element (216) and a second base station system element (208). The method according to the invention consists in establishing a multi-circuit link between the first base station system element and the mobile switching element and detecting by the first wireless communication system that a handover of the communication signal is required. Become. Further, the method comprises transferring the message (260) from the computer platform to the mobile switching element by the computer platform and selecting a selected circuit link (250) from the multiple circuit links by the first wireless communication system. Become. Based on this message, the second wireless communication system allocates the mobile communication resources and finally transfers the communication signal to the mobile communication resources via the selected circuit link (250).

Description

DETAILED DESCRIPTION OF THE INVENTION

TECHNICAL FIELD The present invention relates generally to communication systems, and more particularly, to a method and apparatus for terminating a handover between wireless communication systems.

BACKGROUND ART Communication systems such as land mobile radio, cellular radiotelephone, and personal communication system (PCS) are known. A typical multiple access wireless communication system, such as a digital radio frequency (RF) radio telephone system, has a base station system having one or more base station transmitters and receivers (BTS) and at least one base station controller (BSC) (BSS). The BSS communicates with a mobile communication device via an RF channel, which is often called a mobile station (MS) and has a BTS
It operates within the area served by. BSC stands for Mobile Switching Center (MSC)
This MSC provides a connection between the multiple access wireless communication system and the public switched telephone network (PSTN) as well as various cellular wireless telephone communication systems. The MSC provides switching functions, and also provides call routing (routing), call billing, and other processing for the subscriber. The BSC provides mobility management functions such as mobile station registration, location update and handover.

[0002] One such multiple access wireless communication system with a configuration based on MSC is:
There are direct sequence code division multiple access (DS-CDMA) cellular communication systems, for example, see "TIA Interim Standard (IS) -95A, Mobile Station-Base for Dual Mode Wideband Spread Spectrum Cellular Systems." See Bureau of Compatibility Standards, Telecommunications Industry Association, Washington DC, July 1993. According to these standards, a communication signal encoded between a BSS and a mobile station communicating within the service range of the BSS is transmitted on a common 1.25 megahertz (MHz) carrier.

[0003] The multiple access wireless communication system function could be implemented using a variety of formats. One such format is called Generic C, which is, for example, a five-class service switching point (SSP).
A switching function for a wireless communication system is provided by using a terrestrial line switch such as g point), and it responds to the request of the MSC. The SSP also provides a connection between the generic C wireless communication system and the PSTN.

In a generic C wireless communication system, at least one base station system (B
SS) is coupled to the SSP. Further, the SSP communicates with a service control unit (SCP). The SCP is a database located away from the SSP and communicates with the SSP to provide customer information. When queried from the SSP, the SCP provides information to the SSP via the Radio Access System Controller / Visitor Location Register (RASC / VLR). RSC / VLR, which provides wireless communication access to terrestrial switches,
It is also possible to bind to CP.

[0005] In addition to communication system users, communication system service providers desire handover capability between differently configured wireless communication systems. For example,
A mobile station that receives a terrestrial line call that was originally transmitting in a wireless communication system provided in the generic C format desires to hand over the communication signal to a wireless communication system provided in the MSC format. .

Performing a mobile station handover function between two generic C type wireless communication systems is required by standards. At present, realizing a mobile station handover function between a wireless communication system provided in the generic C format and a wireless communication system provided in the MSC format has not been sufficiently achieved.

Therefore, there is a need for a method and apparatus for completing a handover of a mobile communication signal between structurally different wireless communication systems.

SUMMARY OF THE INVENTION According to one aspect of the invention, the need described above is addressed by the first wireless communication system
A method is provided for completing a handover of a communication signal associated with a mobile communication device to a wireless communication system. The first wireless communication system includes a land line switching element,
Consists of a computer platform and a first base station system element. The second wireless communication system comprises a mobile switching element and a second base station system element. The method includes establishing a plurality of circuit links between the first base station system element and the mobile switching element, wherein the first base station system element and the mobile switching element are responsive to a computer platform; , Detecting that a handover of a communication signal is desired by the first wireless communication system. Further, the method comprises the steps of:
Transferring a message from the platform to the mobile switching element; and selecting a selected circuit link from the plurality of circuit links by the first wireless communication system. Based on this message, mobile communication resources are allocated by the second wireless communication system, and communication signals are transferred to the mobile communication resources via the selection circuit link.

According to another aspect of the invention, there is provided an apparatus for completing a handover of a communication signal associated with a mobile communication device from a first wireless communication system to a second wireless communication system. The first wireless communication system comprises a land line switching element, a computer platform and a first base station system element. The second wireless communication system includes:
It comprises a mobile switching element and a second base station system element. The apparatus comprises a circuit link established between a first base station system element and a mobile switching element, and a computer platform in communication with the first base station system element and a mobile switching center. If the first wireless communication system detects that a handover of the communication signal is desired, the computer platform forwards the message from the computer platform to the mobile switching element and the second wireless communication system moves the mobile communication system. Assigning communication resources, the circuit link and the mobile communication resources provide a path for transferring communication signals from the first wireless communication system to the second wireless communication system by the first wireless communication system.

(Best Mode for Carrying Out the Invention) In the drawings described below, the same numbers indicate the same elements. FIG. 1 shows a wireless communication system 100, such as a direct sequence code division multiple access (DS-CDMA) digital wireless telephone system. The base stations 110, 112, 114 can communicate with the mobile station 116 via a radio frequency (RF) channel,
This channel provides a specific path through which communication signals such as voice, data and video used in the coverage area 120 are transmitted. Base station locations are selected to provide overlapping coverage areas. Base stations 110 and 112
, 114 are coupled to a base station controller (BSC) 150, which comprises, among other things, a processor 162 and a memory 164, and is coupled to a mobile switching center / visitor location register (MSC / VLR) 160, which is in particular a MSC / VLR. A processor 162 and a memory 164 are provided. BSC 150 and base stations 110 and 112
, 114 are referred to as base station systems (BSS). M
SC 160 is coupled to PSTN 170. The origination or termination of a mobile station 116 call may be made via MSC 160 via a preferred customer coupled to a public switched telephone network (PSTN) 170 or other wireless telephone serviced by MSC 160 or other MSC (not shown). Processed for a user of the communication system. BSC and MS
C operates according to a well-known method. For example, Motorola, Inc. It is commercially available from.

FIG. 2 shows first and second wireless communication systems. The first wireless communication system is a wireless communication system 202 of the generic C type, and the generic C system 2
02, and the second wireless communication system is a wireless communication system 204 of the MSC type.
It is.

The generic C format has been developed to integrate wireless communication services from wireless base station systems and landline communication elements, typically using 800 MHz and 1800 MHz bandwidths. Therefore, Generic C System 2
02 utilizes an existing landline terminal 211 including a landline terminal switch, such as a class 5 switch, which is coupled to a base station element 206 to provide wireless communication services. The land line terminal station 211 is a public switched telephone network (PSTN) 2
It also provides an interface with 10.

[0013] Base station system element 206 comprises a BSC 213 coupled to BTS 214 and BTS 215, but may include additional BSCs and BTSs. BSC 213 communicates with BTS 214 via signaling link 235 and at least one trunk 236, and communicates with BTS 215 via signaling link 238 and at least one trunk 237. Signaling links 235 and 238 can be implemented utilizing one of a number of suitable protocols. Suitable base station system elements 206 include, for example, Motorola, Inc.
It is possible to obtain from.

The landline terminal 211 is coupled to the computer platform 212 via a signaling link 230. The computer platform 212 includes a service control unit (SCP) capable of providing specific service information to the landline terminal switch 216 and a radio access system controller (RASC).
), Which comprises a mobility manager capable of coupling the base station system element 216 to the landline terminal 211 and a location register (VLR) capable of providing a local wireless subscriber database. . Such a computer platform could be called an SCP / RAS / VLR. Unlike the MSC format, the switching function associated with a wireless communication call is performed in the landline terminal switch 212 for each command to be executed from the SCP. The computer platform 212 communicates with the landline terminal 211 using an out-of-band signaling protocol for the signaling link, such as SS7. For this protocol, for example, Adva
See nced Intelligent Network (AIN) 0.1, Bellcore, August 1992, (AIN 0.1). Computer platform 212 also communicates with home location registry 240, which provides a permanent subscriber database.

The landline terminal 211 communicates with the base station system element 206 via a signaling link 234 and a plurality of trunks such as E1 or T1, but only the trunk 231 is illustrated for simplicity. Further, base station system element 206 provides signaling link 232 to computer platform 212. Signaling links 234 and 232 are provided out of band, and bi-directional signals such as SS7 can cover IS-634 protocols for digital and analog mobility management.

A wireless communication system 204 based on MSC, which is a second wireless communication system, has a mobile switching center / visitor location register (MSC / VLR) 216 communicating with a base station system element 208 and a home location register (HLR) 217. Is provided. MSC / V
LR 216 can also communicate with and apply to PSTN 210. MS / VLR 216 provides switching and routing functions for base station system element 208.

MSC / VLR 216 communicates with base station system element 208 via signaling link 242. Signaling link 242 for transmitting mobility management signals from base station system element 206 is defined in TIA / EIA / IS-634, dated December 18, 1995, for a public 800 MHz MSC-BS interface. It is possible to use the TIA Interim Standard 634 (IS-634) protocol. MSC / VLR 216 provides switching capabilities for base station transceivers 224,225. Acoustic traffic between the MSC / VLR 216 and the base station system element 208 is transferred via multiple trunks, but only one trunk 241 is shown for convenience of explanation.

The location registration unit and the visitor location registration unit such as the HLR 217 are, in particular, a mobile station such as the MS 206 and a service profile informati
on). The visitor location register provides the MSC 216 with a local database to register incoming mobile communications devices. HLR
The visitor location register, which has obtained information (database to be used hereinafter) from 217, maintains that information as long as the mobile communication device is within the geographic range of MSC / VLR 216.

The base station system element 208 includes a BSC 223 coupled to the BTS 224 and BTS 225, but may include additional BSCs and BTSs. BSC 223 communicates with BTS 224 via signaling link 245 and at least one trunk 246 and with BTS 225 via signaling link 248 and at least one trunk 247. Signaling links 245 and 248 can be implemented utilizing one of a variety of suitable protocols.

The mobile station 209 moves within the coverage area of the base station system 206 and
It communicates with the base station system 206 based on well-known radio frequency air interface specifications, such as 95 or IS-91. The mobile station 209 can communicate with another mobile station or a terrestrial line station via the terrestrial line terminal station 211. When the mobile station 209 approaches the outer boundary of the range served by the generic C system 202, the mobile communication signal 270 for the mobile station 209 must be handed over to another wireless communication system to continue the ongoing call call. Must. If the handover capability of a mobile communication signal between two wireless communication systems is insufficient, the communication signal 270 is terminated.

A handover situation between the two communication systems shown in FIG. 2, according to a preferred embodiment of the present invention, is illustrated in FIG. FIG. 3 shows additional elements to FIG. 2 which are required for performing a handover of a mobile communication signal. An IS-41 handover message 260 has been added in the computer platform 212 to allow the base station system 206 and MSC / VLR
A dedicated terrestrial line 250 is added between the 216 and the computer platform 2
IS-41 signaling link 261 between C.12 and MSC / VLR 216 provides the additional elements needed to support handover.

FIG. 4 depicts a flowchart generally illustrating a method for processing a handover for a mobile communication signal 270 between the two wireless communication systems illustrated in FIG.

The method begins at step 41 where a dedicated terrestrial line is established between the source base station controller of the generic C type wireless communication system 202 and the MSC / VLR 216 of the MSC type wireless communication system 204. Is done.

In step 42, IS-41 message processing occurs between the computer platform 212 and the MSC / VLR 216. IS-41 message processing is performed via the IS-41 signaling link 261.

Next, at step 44, mobile station 209 establishes an RF link between mobile station 209 and source base station controller 213 that carries mobile communication signal 270 via source base station transceiver 215.

In step 46, the source base station controller 213 sets the mobile communication signal 2
As the signal strength of 70 decreases, it informs computer platform 212 of the need for a handoff of the mobile communication signal. The source base station controller 213 signals the need for handoff from the source base station transceiver 215 to the target base station transceiver based on information contained in a handover message, eg, a “handover request message”. In addition to including the identity of the mobile station, the handoff request message includes a cell ID (CELL ID), ie, coverage area information in which the mobile station is traveling.

Next, at step 48, based on the handover message, the computer platform 212 determines that the mobile station is traveling within the coverage area served by the target base station transceiver 224. .

In step 50, computer platform 212 selects one of the leased lines and is capable of carrying mobile station voice traffic on the selected leased line 250.

Next, in step 52, the computer platform 212 utilizes the IS-41 message processing function between itself and the MSC / VLR 216 to send the information from the source base station transceiver 215 to the target base station transceiver 224. Request handover of communication signal. For example, an IS-41 Facility Command Assistance Message (IS-41 Facilitation Message) with appropriate information, including the identity of the selected circuit link 250
ities Directive Invoke message) via a signal link 261
Sent from platform 212 to MSC / VLR 216.

Next, at step 54, the MSC / VLR 216 requests a request message from the target base station controller 223 and requests a handover of the communication signal 270 between the source base station transceiver 215 and the target base station transceiver 224.
For example, MSC / VLR 215 may send an IS-634 handover request message containing the identity of target base station transceiver 224 to target base station controller 22.
Send to 3.

In step 56, the target base station controller 223 uses the authentication message including information indicating the resource allocation of the target base station transceiver 224 to send the MSC /
Responds to VLR 216. For example, an IS-634 handoff authentication message including an assigned target RF channel associated with the target base station transceiver 224 can be utilized.

Next, at step 58, the MSC / VLR 216 sends information indicating the resource allocation of the target base station transceiver 224 via the IS-41 message processing function.
It forwards it to the computer platform 212 and authenticates the request made in step 54. For example, in response to an IS-41 Facilities Directive Return message from computer platform 212, MSC / VLR 216 returns an IS-41 Facilities Directive Return Result message.

In step 60, necessary information describing the resource allocation associated with the target base station transceiver 224 is sent to the source base station transceiver 215 via a handover command message, for example, a T1.659 handover command message. In addition to the assigned target RF channel, the resource assignment includes a land line.

Next, in step 62, the source base station controller 213
Command the mobile station 209 to obtain the assigned target RF channel via an appropriate air interface message, such as the ST-008 extended handoff command message.

In step 64, source base station controller 213 communicates via circuit 251 and selected circuit link 250 with the landline terminal and MSC / VLR
216 relay mobile station voice traffic.

Next, in step 66, the target base station controller 223
Checks to see if the appropriate communication signal 280 associated with is present on the assigned target RF channel and informs the MSC / VLR 216 via a handoff complete message thereafter.

Finally, at step 68, the MSC / VLR 216 notifies the computer platform 212 of the processed connection via an IS-41 Mobile On Channel Invoke message.

The handover of the mobile communication signal from the generic C type wireless communication system to the MSC type wireless communication system has been described above. Conversely, the handover from the MSC type wireless communication system to the generic C type wireless communication system has been described. It would also be possible for a handover to take place.

Those skilled in the art will be able to obtain other aspects of the invention and embodiments other than the specific embodiments described above without departing from the spirit of the invention.

[Brief description of the drawings]

FIG. 1 shows an outline of a general wireless communication system.

FIG. 2 shows two wireless communication systems, one in the generic C format and the other in the MSC format.

FIG. 3 illustrates the wireless communication system of FIG. 2 according to a preferred embodiment of the present invention.

FIG. 4 shows a flowchart for completing a handover of a communication signal between two wireless communication systems according to a preferred embodiment of the present invention.

────────────────────────────────────────────────── ─── [Continuation of summary] Eventually transfer to mobile communication resources.

Claims (10)

[Claims] 1. A method for completing a handover of a communication signal associated with a mobile communication device from a first wireless communication system to a second wireless communication system, wherein the first wireless communication system comprises a land line switching element, a computer, A platform and a first base station system element, wherein the second wireless communication system comprises a mobile switching element and a second base station system element, the method comprising: Establishing a plurality of circuit links between the first base station system element and the mobile switching element responsive to the computer platform; Detecting that a handover is desired; said computer platform Transferring a message from the computer platform to the mobile switching element; selecting a selected circuit link from the plurality of circuit links by the first wireless communication system; Allocating mobile communication resources by a communication system; and transferring the communication signals to the mobile communication resources via the selection circuit link. 2. Prior to said detecting step, a first signaling link is established between said mobile communication device and a landline switching element, a portion of said first signaling link passing through said base station system element. The method of claim 1, wherein: 3. The method of claim 1, further comprising: forwarding the message further comprising: supporting the message processing between the computer platform and the mobile switching element by the computer platform; Requesting a handover of the communication signal from a station element to the second base station element. 4. The method of claim 1, wherein said mobile communication resource comprises a radio frequency channel between said second base station system element and said mobile communication device. 5. The method of claim 4, wherein said mobile communication resources further comprise a signaling link and a traffic link between said second base station system element and said mobile switching element. 6. A second signaling link is established between the mobile communication device and the landline switching element prior to the step of transferring the communications signal to the mobile communications resource, and wherein a portion of the second signaling link is established. 5. The method according to claim 4, wherein comprises the mobile communication resource. 7. The method of claim 1, wherein the first wireless communication system comprises a generic C type wireless communication system. 8. The method of claim 1, wherein said landline switching element comprises a Class 5 switch. 9. The method of claim 2, wherein the second wireless communication system is a code division multiple access (CDM).
The method of claim 1, comprising A) a system, a time division multiple access (TDMA) system, or an analog communication system. 10. The method of claim 1, wherein the communication signal is associated with a wireless communication device.