KR100754648B1 - Hand-over method and system between heterogeneous mobile telecommunication systems - Google Patents

Abstract

The present invention relates to a hand misdetection method and system for efficient call switching between heterogeneous mobile communication systems using different communication methods. In the present invention, a first base station controller for providing a service in a first communication method by a mobile terminal. Communicate with the first and second base station controllers when performing a handover connected to the wireless network through a second base station controller providing a service in a manner different from the first communication method while being connected to the wireless network through The connected mobile exchange / gateway receives voice call / packet data destined for the mobile terminal from an external communication network, and then transmits a first call request message for the mobile terminal to the first base station controller. After the base station controller checks its radio resource state, the base station controller receives a radio station from the second base station controller. The original information is received to determine whether the handover. And when the handover is determined through the second base station controller, the first base station controller transmits a second call request message for the mobile terminal to the second base station controller, and the second base station controller transmits the mobile switch / gateway. By performing the handover process to check the location information of the mobile terminal through the voice call / packet data to the mobile terminal. Therefore, according to the present invention, it is possible to provide an efficient handover service to a heterogeneous network having a better available radio resource state to a subscriber.

Handover, Heterogeneous Network, Radio Resources, CDMA, UMTS, Base Station Controller

Description

Hand-over method and system between heterogeneous mobile telecommunication systems             

1 is a block diagram illustrating a configuration of a general mobile communication system in which a CDMA network and a UMTS network are mixed.

2 is a block diagram illustrating a configuration of a mobile communication system supporting handover between heterogeneous networks according to the present invention.

3 is a flowchart illustrating a handover method between heterogeneous mobile communication systems according to the present invention.

4 is a flowchart illustrating the operation of the RNC 270 of FIG. 2 during handover between heterogeneous mobile communication systems according to the present invention.

5 is a flowchart illustrating the operation of the BSC 230 of FIG. 2 during handover between heterogeneous mobile communication systems according to the present invention.

The present invention relates to a handover method and a system of the mobile communication system, and more particularly, to a handover method and system for an efficient call transfer between heterogeneous mobile communication systems using different communication methods.

In general, a mobile communication system divides a frequency band determined according to a communication method into a plurality of channels and uses a frequency division multiplexing scheme (FDMA) that uses a frequency channel allocated to each subscriber, and a plurality of frequency channels. Time Division Multiple Access (TDMA), where subscribers divide time, and code division multiplexing, in which multiple subscribers use the same frequency band in the same time zone and assign different codes to each subscriber for communication. Division Multiple Access (hereinafter referred to as "CDMA").

According to the rapid development of communication technology, the mobile communication system has reached a stage of providing a high speed data service capable of providing a general voice call service as well as a multimedia service such as an email, a still image, a video, etc. to a mobile terminal. The so-called third generation mobile communication system for providing the high-speed data service generally adopts the CDMA scheme, but the CDMA scheme is divided into a synchronous scheme adopted in the United States and the asynchronous scheme adopted in Europe and Japan, as is known. In the third generation mobile communication system, which is the next generation communication network, standardization work is performed in different countries depending on whether synchronous and asynchronous methods are used.

The third generation mobile communication system (hereinafter, referred to as "CDMA network") of the synchronous method is a CDMA 2000 1x currently being serviced in North America and high-speed packet transmission for IMT-2000 (International Mobile Telecommunication 2000). Evolved in the form of 1x EV-DO (Evolution Data Only) and Evolution of Data and Voice (EV-DV) capable of supporting voice and packet services simultaneously. , Called "UMTS network" includes UMTS (Universal Mobile Telecommunication Systems) being developed in Europe. The UMTS is also called Wideband Code Division Multiple Access (W-CDMA).

However, the CDMA network is a method of communicating with a mobile terminal by synchronizing the time synchronization of all base stations by GPS, and the UMTS network is a method of communicating with a mobile terminal without synchronizing time synchronization between base stations. In addition, a mobile terminal, a base station and a base station controller according to different standards are used for each communication scheme. Therefore, it is difficult to configure a CDMA network and a UMTS network using a different communication system as a common network, and communication operators who want to use both the CDMA network and the UMTS network are duplicated in the area where the CDMA network is already installed. UMTS network should be installed or CDMA network should be installed in the area where UMTS network is installed to provide individual services.

1 is a block diagram illustrating a configuration of a general mobile communication system in which the CDMA network and the UMTS network are mixed.

In FIG. 1, the CDMA network includes a mobile station (MS) 110 provided with a communication service in a synchronous CDMA scheme, and a base transceiver system wirelessly connected to the mobile terminal 110 to allocate a communication channel. And a base station controller (BSC) 130 that is connected to the base station 120 by wire and manages radio resources of the mobile terminal 110.

The base station controller 130 is connected to a circuit switched network such as a public switched telephone network (PSTN) through a mobile switching center (MSC) 140 or a gateway (GateWay: GW) ( 150 is connected to a packet switched network such as the Internet / Packet Data Network (PSDN).

The gateway GW is a generic name of a network component for accessing a packet network and is called a packet data service node (PDSN), an access gateway, a media gateway, or the like. The mobile exchange 140 and the gateway 150 may be integrated into a single device according to the network configuration.

In FIG. 1, the UMTS network includes, for example, a mobile terminal (MS) 160 provided with a communication service in an asynchronous W-CDMA scheme, and a base station (node B) 170 which allocates a wireless communication channel to the mobile terminal 160. And a base station controller (RNC) 180 connected to the base station 170 by wire to manage radio resources for communication of the mobile terminal 160. The wireless network controller 180 is connected to a circuit network such as a public switched network (PSTN) through a mobile switch 140 in the same manner as the base station controller 130 of the CDMA network, or is connected to the Internet / Internet through a gateway 150. It is connected to a packet network such as a packet data network (PSDN).                         

In the CDMA network and the UMTS network having the above-described configuration, the mobile terminals 110 and 160 are connected to the wireless network through the base stations 120 and 170, respectively, and are connected to the mobile switch 140 through the base station controllers 130 and 160. When the voice service is provided through the circuit network, and when the communication is connected to the gateway 150 through the base station controller (130, 160) is provided with the data service through the packet network. The names of network components in the mobile communication system of FIG. 1 may vary depending on the type of mobile communication system such as CDMA 2000 1x, 1xEV-DO, 1xEV-DV GPRS, and W-CDMA.

Meanwhile, in FIG. 1, the mobile terminal 110 connected to the CDMA network and the mobile terminal 160 connected to the UMTS network are distinguished from each other, but the dual chips supporting both network standards for the mobile terminals 110 and 160 ( Dual chip) will be able to receive communication service selectively through one network.

However, in the network configuration of the conventional mobile communication system, even when using the mobile terminal equipped with the dual chip, the service network cannot be switched from the CDMA network to the UMTS network or the UMTS network to the CDMA network during service use. In case of a communication failure such as explosion of users or lack of radio resources in a network, there is a problem that the service cannot be switched to another network even though the service in other networks is more efficient than the current network.

An object of the present invention is to provide a handover method and a system for performing call switching in consideration of network conditions between heterogeneous mobile communication systems serviced by different communication methods.

A handover method between heterogeneous mobile communication systems according to the present invention for achieving the above object is the first communication method in a state in which the mobile terminal is connected to a wireless network through a first base station controller providing a service in a first communication method. A method for performing a handover connected to the wireless network through a second base station controller providing a service in a different manner from the above, wherein the predetermined switching means connected in communication with the first and second base station controllers is moved from an external communication network. A first step of receiving service data destined for a terminal, a second step of the switching means transmitting a first call request message for the mobile terminal to the first base station controller, and the first base station controller itself Check the radio resource status of the mobile station and receive radio resource information from at least one of the second base station controllers. A third step of deciding whether or not to de-over, and a fourth step in which the first base station controller transmits a second call request message for the mobile terminal to the second base station controller when handover is determined through the second base station controller. And a fifth step of the second base station controller checking the location information of the mobile terminal through the switching means and transmitting the service data transmitted from the switching means to the mobile terminal.

A mobile communication system supporting handover between heterogeneous networks according to an aspect of the present invention for achieving the above object is a state in which a mobile terminal is connected to a wireless network through a first base station controller providing a service in a first communication method. In the mobile communication system performing a handover connected to the wireless network through a second base station controller that provides a service in a manner different from the first communication method in the connection, between the first and second base station controller and the circuit network A mobile switch for switching voice data transmission to the mobile terminal and transmitting predetermined subscriber information including the location information of the mobile terminal to the second base station controller when performing the handover; Each communication connection to a base station controller and a call to the mobile terminal from the mobile exchange The first base station performing an information request for radio resource identification to the second base station controller when there is a request, and performing a call request to the mobile terminal to the second base station controller when the radio resource of the second base station controller is better. The mobile station is connected to the base station controller, the first base station controller, and the mobile switch, respectively, and receives the position information of the mobile terminal from the first base station controller and receives the position information of the mobile terminal from the first base station controller; And a second base station controller configured to perform a call request to a terminal and transmit and process the voice data to the mobile terminal.

In addition, a mobile communication system supporting handover between heterogeneous networks according to another aspect of the present invention for achieving the above object is connected to a wireless network through a first base station controller for providing a service by a mobile terminal in a first communication manner. In a mobile communication system performing a handover connected to the wireless network through a second base station controller that provides a service in a different manner from the first communication method in a state, between the first and second base station controller and the packet network A gateway connected to switch packet data transmission for the mobile terminal and transmitting predetermined subscriber information including location information of the mobile terminal to the second base station controller when the handover is performed, the gateway and the second base station; Each connected to a controller and from the gateway to the mobile terminal. Performing a request for information for radio resource identification to the second base station controller when an outgoing request is made; and performing a call request to the mobile station to the second base station controller when the radio resource of the second base station controller is better. And are connected to a first base station controller, the first base station controller, and the gateway, respectively, and receive the subscriber information from the gateway when the call request for the mobile terminal is received from the first base station controller, and then call the mobile terminal. And a second base station controller configured to perform a request and transmit and process the packet data to the mobile terminal.

Hereinafter, with reference to the accompanying drawings will be described in detail the operating principle of the preferred embodiment of the present invention. In the following description of the present invention, detailed descriptions of well-known functions or configurations will be omitted if it is determined that the detailed description of the present invention may unnecessarily obscure the subject matter of the present invention. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.                     

FIG. 2 is a block diagram showing a configuration of a mobile communication system supporting handover between heterogeneous networks according to the present invention. The configuration of FIG. 2 is a mobile terminal (hereinafter, referred to as “MS”) 210 as the configuration of FIG. 1. ), A base station (hereinafter referred to as "BTS") 220, a base station controller (hereinafter referred to as "BSC") 230, a mobile exchange (hereinafter referred to as "MSC") 240 and a gateway (hereinafter referred to as "GW"). Network components make up the CDMA network. In addition, network components including the MS 210, the base station (hereinafter referred to as "node B") 260, the base station controller (hereinafter referred to as "RNC") 270, the MSC 240 and the GW 250 may be configured to support the UMTS network. Configure. Also, although the network components of FIG. 2 are shown one by one for convenience of description, a plurality of network components are actually connected to each other.

In the configuration of FIG. 2, each network component constituting the CDMA network and the UMTS network is basically configured to support a corresponding communication scheme as described in FIG. 1, and CDMA during service use of the MS 210 according to the present invention. A handover is performed in which the call of the MS 210 is switched to a network having a better state of radio resources between the network and the UMTS network. In the present invention, it is assumed that the mobile terminal 210 is equipped with, for example, a dual chip to use both communication services through a CDMA network and a UMTS network. In addition, the BSC 230 and the RNC 270 transmit and receive radio resource information to each other at the time of handover, and determine whether a network having a better state of a current radio resource is a CDMA network or a UMTS network.

When handing over from the UMTS network to the CDMA network, the BSC 230 receives a predetermined call request message for performing the handover from the RNC 270 confirming the radio resource information, and the network to which the MS 210 currently communicates is connected. It checks whether it is a circuit network or a packet network, and transmits a predetermined service request message for inquiring the location information of the MS 210 to the MSC 240 or the GW 250. The MSC 240 / GW 250 receiving the service request message transmits a predetermined service response message including the location information of the MS 210 to the BSC 230.

In addition, when handing over from the CDMA network to the UMTS network, the RNC 270 receives a predetermined call request message for performing the handover from the BSC 270 confirming the radio resource information, and the MS 210 is currently connected to the communication network. It checks whether it is a line network or a packet network, and transmits a predetermined service request message for inquiring the location information of the MS 210 to the MSC 240 or the GW 250, and the MSC 240 / GW 250 receiving the service request message. ) Transmits a predetermined service response message including the location information of the corresponding MS 210 to the RNC 270.

According to the above configuration, for example, when there is data transmission from the circuit network / packet network while the MS 210 is connected to the UMTS network, the voice data is delivered to the MSC 240, and the packet data is delivered to the GW 250. . The MSC 240 / GW 250 receiving the voice call / packet data transmits a call message for the corresponding MS 210 to the RNC 270 that manages the radio resource, and the RNC 270 currently transmits the radio resource. When normal communication is difficult in consideration of the state, a predetermined information request message for confirming the radio resource state of the corresponding BSC 230 is delivered to at least one BSC 230 located in the same cell.

Upon receiving the information request message, the BSC 230 transmits a predetermined information response message including its radio resource information to the RNC 270, and the RNC 270 checks the radio resource information received from the BSC 230. When the radio resource state of the BSC 230 is better than itself, the call request message is transmitted to the corresponding BSC 230 for handover to the CDMA network. The BSC 230 inquires the location information of the MS 210 to the MSC 240 / GW 250 and then stores the voice call / packet data transmitted through the MSC 240 / GW 250. And data transmission is performed.

Meanwhile, the handover method from the CDMA network to the UMTS network only needs to reverse the message transmission / reception subject between the BSC 230 and the RNC 270 in the handover method from the UMTS network to the CDMA network. Shall be.

FIG. 3 is a flowchart illustrating a handover method between heterogeneous mobile communication systems according to the present invention applied to the configuration of FIG. 2. FIG. 3 illustrates a handover process from a UMTS network to a CDMA network. The handover process from the CDMA network to the UMTS network will be omitted as described in FIG. 2.

First, the MS 210 is connected to the UMTS network. Accordingly, it is assumed that there is no actual voice call / packet data transmission with the RNC 270, but mutual synchronization is obtained. In this case, when voice call / packet data destined for the MS 210 in the idle state is transmitted to the MSC 240 / GW 250 through the circuit network / packet network, the MSC 240 / GW is performed. After receiving the voice call / packet data, the 250 identifies the location of the MS 210 through a home location registration (HLR) (not shown) where subscriber information is stored.

Thereafter, the MSC 240 / GW 250 that checks the location of the MS 210 in step 303 is a first call request message for the MS 210 to the RNC 270 in which the corresponding MS 210 is located. Send it. In this case, the normal RNC calls the MS through the Node B and delivers voice calls or packet data to the MS. In this embodiment, when the RNC 270 fails to provide the service to the MS 210 requesting the new service, or when the BSC 230 of the heterogeneous network can provide more efficient service than the RNC 270. It is about.

In such a case, the RNC 270 allocates all radio resources to other MSs 210 currently serving, and there is no resource to be allocated to the MS 210 to be newly serviced. ), Or the data rate of the BSC 230 is higher and more efficient than the data rate of the RNC 270. Hereinafter, for convenience, the RNC 270 allocates all radio resources to the MS 210 and assumes that there are currently no available resources.

After receiving the first call request message, the RNC 270 checks its radio resource state in step 305, and if it is determined that the available radio resources are sufficient, the RNC 270 calls the corresponding MS 307 in step 307 to call the MSC 240. / GW 250 transmits the voice call / packet data transmitted through. On the other hand, when it is determined in step 305 that the available radio resources are not sufficient, in step 309, the RNC 270 requests at least one BSC 230 in the same cell (area) to request information on the available radio resources. Send the information request message.

In this case, a communication interface for transmitting and receiving messages between the RNC 270 and the BSC 230 located in the same cell may be installed and set in advance in each of the RNC 270 and the BSC 230, or may be updated through an additional update. . In addition, it may be desirable to set two or more BSCs 230 that are requested for information on the available radio resources.                     

After receiving the information request message, the BSC 230 measures its radio resource state in step 311 and transmits an information response message including the available radio resource information to the RNC 270 that transmitted the information request message. . Receiving the information response message, the RNC 270 checks available radio resources of each BSC 230 in step 313, and is available to accommodate the voice call / packet data to be transmitted to the MS 210 in the BSC 230. When it is determined that there is a radio resource, that is, when handover to the CDMA network is possible, the second call request message for the MS 210 is transmitted to the corresponding BSC 230 in step 315. On the other hand, if it is determined in step 313 that the available radio resources of the BSC 230 are insufficient, the BSC 230 moves to step 305 to repeat the subsequent step within a predetermined number of times / time, for example.

Upon receiving the second call request message, the BSC 230 requests the service to the MSC 240 / GW 250 to obtain subscriber information for call connection, such as location information for the MS 210 in step 317. The MSC 240 / GW 250 receiving the service request message checks the location information of the corresponding MS 210. In step 319, the MSC 240 / GW 250 adds the location information to the service response message and transmits the location information to the corresponding BSC 230.

Upon receiving the service response message, the BSC 230 transmits an acknowledgment message to the MSC 240 / GW 250 that transmitted the service response message in step 321, and in step 323, the BSC 230 transmits a corresponding MS 210. ) To transmit voice / packet data delivered through MSC 240 / GW 250.                     

Meanwhile, in step 309, the RNC 270 transmits an information request message to the BSC 230 when there is not enough available radio resource. Unlike this, the RNC 270 sends the information to the BSC 230 at predetermined intervals. It would also be desirable to send a request message. Therefore, according to the above process, the RNC 270 determines which base station controller of which of the BSC 230 and itself is more efficient, and if the BSC 230 is more efficient according to the determination result, As in step 315, the call request message is transmitted to the corresponding BSC (230).

Meanwhile, in FIG. 3, the processes of steps 301 to 323 in relation to the handover operation for the voice service show a voice call transmission process. Therefore, when the MS 210 of the called subscriber and the MS (not shown) of the calling subscriber are already connected, the radio resources of the RNC 270 may be insufficient or a communication failure may occur, for example, a hand from the UMTS network to the CDMA network. If over is required, the process of transmitting the first call request message according to step 301 may be omitted.

In this case, an operation after step 305 is performed and a handover is performed between the RNC 270 and the BSC 230. In this case, in step 315 of FIG. 3, the call request message transmitted by the RNC 270 is used as the BSC 230 to request a handover to the BSC 230. Conversely, handover from the CDMA network to the UMTS network during voice service provision may also be performed in the same manner.

Hereinafter, operations of the RNC 270 and the BSC 230 performing the handover operation between the heterogeneous networks will be described in detail with reference to FIGS. 4 and 5. 4 and 5 illustrate the operation of the RNC 270 and the BSC 230 during the handover from the UMTS network to the CDMA network.

4 is a flowchart illustrating the operation of the RNC 270 during handover between heterogeneous mobile communication systems according to the present invention.

In step 401, the MSC 240 / GW 250 receives voice call / packet data transmitted through the circuit / packet network, and the RNC 270 transmits voice call / packet data from the MSC 240 / GW 250. Receive a call request message (see step 303 of FIG. 3). In step 403, the RNC 270 checks whether its available radio resources are sufficient to provide the MS 210 with a certain level or more. The predetermined level or more relates to whether the service can be provided to the MS 210 or if the service is provided to satisfy the minimum requirements.

For example, in providing a video service to the MS 210, if a data rate of at least 1 Mbps is required, in step 403, an available radio resource to be allocated to the MS 210 by the RNC 270 ensures the data rate. If possible, in step 405, the RNC 270 performs a call request for data transmission to the MS 210 according to a conventional procedure, and then transmits packet data transferred from the GW 250 to the corresponding MS 210. do.

Meanwhile, if the available radio resource of the RNC 270 cannot support the data rate in step 403, the RNC 270 is at least one BSC 230 located in the same cell and available radio of the corresponding BSC 230 in step 407. Sends an information request message for inquiring resource information. Upon receiving the information request message, the BSC 230 measures its radio resource state and transmits it to the RNC 270. In step 409, the RNC 270 receives radio resource information transmitted from the BSC 230. .

In step 411, the RNC 270 determines whether the available radio resource of the BSC 230 is better than its available radio resource information and determines whether handover to the CDMA network is possible. In this case, when there are a large number of accessible BSCs 230 and the MS 210 provided with the service, an appropriate one is selected by comparing radio resource information received from all corresponding BSCs 230.

If the available radio resource of the BSC 230 is not better than the available radio resource of the RNC 270 in step 411, the RNC 270 moves to step 403 to repeat the subsequent operation. In this case, the number of repetitions is performed within a predetermined number of times / hours, and when the number of times exceeds the predetermined number of times / hours, the RNC 270 performs the MS (as in step 405) in a general manner even if its available radio resources are not sufficient for service provision. After performing the call request to 210, it would be desirable to transmit voice call / packet data.

Meanwhile, if the available radio resource of the BSC 230 is better than the available radio resource of the RNC 270 in step 411, the RNC 270 requests a call for handover to the corresponding BSC 230 as in step 315 of FIG. 3. Send a message. Thereafter, as shown in FIG. 3, the BSC 230 of the CDMA network provides a service to the corresponding MS 210 according to a conventional procedure.

5 is a flowchart illustrating the operation of the BSC 230 during handover between heterogeneous mobile communication systems according to the present invention.                     

In step 501, the BSC 230 receives an information request message as in step 309 of FIG. 3 from the RNC 270 of the UMTS network. Upon receiving the information request message, the BSC 230 measures its available radio resource state in step 503 and transmits an information response message including radio resource information measured in step 505 to the corresponding RNC 270.

In operation 507, the BSC 230 checks whether a call request message for performing a handover has been received from the RNC 270 for a predetermined time. For example, if the call request message is received, the BSC 230 in step 509. ) Transmits a service request message for receiving subscriber (terminal) information such as location information of the corresponding MS 210 to the MSC 240 / GW 250.

Thereafter, in step 511, the BSC 230 checks whether the subscriber (terminal) information on the MS 210 has been received from the MSC 240 / GW 250 for a predetermined time, for example. ) If the information is received in step 513 BSC 230 performs a call request using the subscriber (terminal) information of the MS 210, and then the voice / packet data to the MS 210 in accordance with a conventional procedure Will be sent.

In the above-described embodiment of the present invention, the MS 210 and the RNC 270 of the UMTS network obtain mutual synchronization, and thus, the RNC 270 of the heterogeneous network and the radio resource information of the heterogeneous network due to the lack of radio resources. Although a process of performing handover by transmitting and receiving is described, the MS 210 and the BSC 230 of the CDMA network can provide handover service through the RNC 270 of the heterogeneous network even when mutual synchronization is obtained. Can be. In this case, the flowchart of FIG. 4 may be an operation in the BSC 230 instead of the RNC 270, and the flowchart of FIG. 5 may be an operation in the RNC 270 instead of the BSC 230. In addition, although an embodiment of the present invention has described service switching between a CDMA network and a UMTS network, it may be applied to other types of heterogeneous networks, for example, an EV-DO network and an EV-DV network.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by those equivalent to the scope of the claims.

As described above, according to the present invention, by transmitting and receiving radio resource information between base station controllers of different heterogeneous mobile communication systems, it is possible to provide an efficient handover service to a heterogeneous network having a better available radio resource state.

Claims (16)

The wireless network through a second base station controller providing a service in a second communication method different from the first communication method while the mobile terminal is connected to the wireless network through a first base station controller providing a service in a first communication method. In the method for performing a handover connected to, A first step in which predetermined exchange means connected in communication with the first and second base station controllers receives service data destined for the mobile terminal from an external communication network; A second step of the switching means transmitting a first call request message for the mobile terminal to the first base station controller; A third step of the first base station controller checking its radio resource state and receiving radio resource information from at least one second base station controller to determine whether to hand over; A fourth step of transmitting, by the first base station controller, a second call request message for the mobile terminal to the second base station controller when handover is determined through the second base station controller; And a fifth step of the second base station controller checking the location information of the mobile terminal through the switching means and transmitting the service data transmitted from the switching means to the mobile terminal. Handover method between. The method of claim 1, The first and the second base station controller is located in the same cell handover method between heterogeneous mobile communication systems. The method of claim 1, In the third step, the first base station controller further comprises transmitting the service data to the mobile terminal in a normal procedure of the first communication method when the service for the mobile terminal is available in the current radio resource state. A handover method between heterogeneous mobile communication systems. The method of claim 1, The third step may include measuring, by the first base station controller, its own radio resource state; Requesting transmission of radio resource information from the first base station controller to the second base station controller; Transmitting, by the second base station controller, the radio resource information including its radio resource state to the first base station controller; When the first base station controller compares its available radio resource with the available radio resource of the second base station controller based on the radio resource information, when the available radio resource of the second base station controller is better, the first base station controller The handover method between heterogeneous mobile communication systems, characterized in that for determining the handover. The method of claim 4, wherein As a result of comparing available radio resources between the first base station controller and the second base station controller, when the available radio resources of the first base station controller are better, the first base station controller is transferred to the mobile terminal in the normal procedure of the first communication scheme. Handover method between heterogeneous mobile communication systems, characterized in that it further comprises transmitting the service data. The method of claim 1, The first communication scheme is a code division multiple access (CDMA) scheme and the second communication scheme is a universal mobile telecommunication systems (UMTS) scheme. The method of claim 1, The first communication method is a Universal Mobile Telecommunication Systems (UMTS) method and the second communication method is a Handover method between heterogeneous mobile communication systems is a Code Division Multiple Access (CDMA) method. The method of claim 1, And said service data is voice data and said switching means is a mobile switch connected to a circuit network. The method of claim 1, And said service data is packet data and said switching means is a gateway connected to a packet network. The method of claim 1, And said service data is a voice call and said switching means is a gateway connected to a circuit network. The wireless network through a second base station controller providing a service in a second communication method different from the first communication method while the mobile terminal is connected to the wireless network through a first base station controller providing a service in a first communication method. In a mobile communication system for performing a handover connected to, Is connected between the first and second base station controllers and a circuit network to switch voice data transmission to the mobile terminal, and to transmit the predetermined subscriber information including the location information of the mobile terminal to the second base station controller when the handover is performed. With mobile exchanger transmitting, When the mobile switch and the second base station controller are connected to each other and there is a call request for the mobile terminal from the mobile switch, the mobile station performs a request for information for radio resource identification to the second base station controller and The first base station controller for making a call request to the mobile terminal to the second base station controller when the radio resource is better; The mobile station is connected to the first base station controller and the mobile switch, respectively, and when there is a call request for the mobile terminal from the first base station controller, the mobile switch receives the location information of the mobile terminal and requests a call to the mobile terminal. And a second base station controller configured to transmit and process the voice data to the mobile terminal. The wireless network through a second base station controller providing a service in a second communication method different from the first communication method while the mobile terminal is connected to the wireless network through a first base station controller providing a service in a first communication method. In a mobile communication system for performing a handover connected to, Is connected between the first and second base station controllers and a packet network to switch packet data transmission for the mobile terminal, and transmits predetermined subscriber information including location information of the mobile terminal to the second base station controller when performing the handover. The gateway to transmit, When the communication request is made to the gateway and the second base station controller, respectively, and a call request is made to the mobile terminal from the gateway, an information request for radio resource confirmation is performed to the second base station controller and the radio resource of the second base station controller is performed. The first base station controller for making a call request to the mobile terminal to the second base station controller in this better case; The packet is received by the mobile station after receiving the subscriber information from the gateway when a call request for the mobile terminal is received from the first base station controller and is connected to the first base station controller and the gateway, respectively. And a second base station controller configured to transmit and process data to the mobile terminal. The method of claim 11, The first communication scheme is a code division multiple access (CDMA) scheme, and the second communication scheme is a universal mobile telecommunication systems (UMTS) scheme. The method of claim 11, The first communication scheme is a universal mobile telecommunication systems (UMTS) scheme, and the second communication scheme is a code division multiple access (CDMA) scheme. The method of claim 12, The first communication scheme is a code division multiple access (CDMA) scheme, and the second communication scheme is a universal mobile telecommunication systems (UMTS) scheme. The method of claim 11, The first communication scheme is a universal mobile telecommunication systems (UMTS) scheme, and the second communication scheme is a code division multiple access (CDMA) scheme.

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