KR20070008149A - Appratus and method for managing for the location of access terminal in mobile communication, and system thereof - Google Patents

Abstract

An apparatus and a method for managing mobility of an AT in a mobile communication system, and a system thereof are provided to enable a dormant AT to prevent a loss of packet data transmitted from a packet core network even when a subnet area is expanded, and reduce frequent A13 message transceiving between a target SC/MM and a source SC/MM caused by frequent movement of the AT, thereby reducing entire loads of the system. A mobile communication system comprises the followings: a PCF(Packet Control Function)(430a) which is included in a subnet(500), and periodically transmits a sector parameter message for periodically indicating the current location of an AT(410), to the AT(410) located in the subnet(500); the AT(410) which receives the sector parameter message from the PCF(430a), checks whether the AT(410) has moved only in the same subnet(500) or to a different subnet(502) and transmits a UATI(Universal Access Terminal Identifier) request message to an SC/MM(Session Control/Mobility Management) unit(440a) if the AT(410) has moved to the different subnet(502); and an SC/MM unit(440b) which manages the subnet(502) including at least two PCFs(430b,430c,430d) for providing packet data to the AT(410), assigns a UATI(Unicast Access Terminal Identity) effective only in the subnet(502), and manages session information of the AT(410) located within the subnet(502).

Description

APPARATUS AND METHOD FOR MANAGING FOR THE LOCATION OF ACCESS TERMINAL IN MOBILE COMMUNICATION, AND SYSTEM THEREOF}

1 is a diagram illustrating a general network structure of a CDMA 2000 1x EV-DO system;

2 is a flowchart illustrating an operation for receiving UATI assignment when an AT in a dormant state moves to another subnet in a general CDMA 2000 1x EV-DO system;

3 is a conceptual diagram illustrating an operation between a source SC / MM and a target SC / MM when the AT moves a subnet boundary area according to the prior art;

4 is a block diagram illustrating a mobile terminal, an access network, and a session management / mobility management unit in a mobile communication system according to an embodiment of the present invention;

5 is a conceptual diagram illustrating a configuration of a subnet according to a preferred embodiment of the present invention;

6 is a call flow diagram between each network element when the AT moves from subnet 1 to subnet 2 according to the first embodiment of the present invention;

7 is a call flow diagram between each network element when an AT moves only in the same subnet according to a second embodiment of the present invention;

8 is an operation flowchart of a target session control / mobility management unit (SC / MM) according to an embodiment of the present invention;

9 is an operation flowchart of an AT according to an embodiment of the present invention;

10 is a flowchart illustrating operations of an AT according to another embodiment of the present invention.

The present invention relates to an apparatus and method for mobility management of a mobile terminal in a wireless communication system, and more particularly, to an apparatus for mobility management of a mobile terminal moved in a subnet region of a CDMA 2000 1x EV-DO mobile communication system. And a method and system thereof.

In general, a wireless communication system is a system developed for a case in which a fixed wired network cannot be connected to a terminal and used. Representative systems of such a wireless communication system include a mobile communication system, a wireless LAN, Wibro, a mobile ad hoc, and the like.

 Mobile communication is intended to enable a call while a subscriber is moving at a high speed over a large area. A representative system of such a mobile communication system is a cellular system. A cellular system is a concept proposed to overcome the limitations of the service area and the subscriber capacity of the conventional mobile communication system. The cellular system is divided into several small areas, or cells, to be identical in two cells far enough apart from each other. The use of frequency bands means spatial reuse of frequencies. The first technology of such cellular systems is analog such as Advance Mobile Phone System (AMPS) and Total Access Communication Services (TACS), which is called first generation mobile communication. The first generation of mobile communication systems has made it difficult to accommodate the rapidly increasing subscribers of mobile communication services, and the development of technology has increased the demand for various services as well as previous voice services. Due to these demands, digital second generation mobile communication has emerged more advanced than first generation mobile communication. Unlike the analog system, the second generation mobile communication system digitalizes an analog voice signal, performs a voice encoding, and uses a digital modulation and demodulation method, and uses a frequency of 800 MHz. The multiple access method uses a time division multiple access (TDMA) method and a code division multiple access (CDMA). In the second generation mobile communication system, voice services and low-speed data services are provided, and there are IS-95 (CDMA), IS-54 (TDMA), and GSM (Global System for Mobile communication) systems in the United States. In addition, PCS (Personal Communication Services) system is classified as a 2.5 generation mobile communication system, and uses a frequency of 1.8 ~ 2GHz band. These second generation mobile communication systems have been established for the purpose of increasing the efficiency of mobile communication systems while providing voice services to users. However, the advent of the Internet and the demand for high-speed data services of users foreshadowed the emergence of a new wireless platform, and such a method is a third generation mobile communication such as International Mobile Telecommunication-2000 (IMT-2000).

The IMT-2000 is largely divided into a synchronous asynchronous method and a synchronous method, and a representative system of the asynchronous method is Universal Mobile Telecommunication Systems (UMTS) or Wideband CDMA (W-CDMA) of 3GPP (3rd Generation Partnership Project). The system includes CDMA 2000 1x of 3rd Generation Partnership Project 2 (3GPP2), CDMA 2000 1x Evolution Data Only (EV-DO), CDMA 2000 1x Evolution of Data and Voice (EV-DV), and the like.

The CDMA 2000 1x has a forward speed of 144kbps, which is faster than the IS-95A / IS-95B network, which provides a data transfer rate of 14.4kbps / 56kbps using the IS-95C network evolved from the existing IS-95A and IS-95B networks. Provides data service at the transmission rate. The CDMA 2000 1x EV-DO (1x EVolution Data Only) is designed to provide a forward transfer rate of about 2.4 Mbps by evolving the CDMA 2000 1x one step for large digital data transmission, and the CDMA 2000 1x EV-DO. DV complements the problem of CDMA 2000 1x EV-DO, which cannot support simultaneous voice and data services.

The CDMA 2000 1x EV-DO system is a representative mobile communication system having a channel structure for high-speed data transmission. The CDMA 2000 1x EV-DO system is a mobile communication system of the standard proposed by 3GPP2 to supplement data communication of the IS-2000 system.

In this CDMA 2000 1x EV-DO system, data communication can be divided into forward and reverse directions. In the present invention, the forward direction means the direction from the base station to the terminal, and the reverse direction means the direction from the terminal to the base station. Next, the configuration of the forward channel of the 1x EV-DO system will be described. Types of the forward channel include a pilot channel, a forward medium access control (“MAC”) channel, a forward traffic channel, a forward control channel, and the like, which are time division multiplexed and transmitted to a terminal. do. In this case, a bundle of signals transmitted by time division multiplexing is called a burst.

Among the above channels, user data packets are transmitted in the forward traffic channel, and control messages and user data packets are transmitted in the forward control channel. The forward MAC channel is used for reverse rate control and power control information transfer or designation of a forward data transmission channel.

1 is a diagram illustrating a general network structure of a CDMA 2000 1x EV-DO system.

An access terminal (AT) 100 is an IS-856 radio access standard that defines signaling procedures, packet forwarding procedures, media access control (MAC), etc. for handling the origination and reception of packet calls. Is connected to an access network transmission system (ANTS) 102 which processes a call processing and selection function (SF) and a radio link protocol (RPP). A controller 104 is connected to an access network controller (ANC) 104. As shown in FIG. 1, the ANC 104 may be connected to two or more ANTSs. The ANC 104 is a packet data serving node (PDSN) 110 of a data core network (DCN) that is responsible for authentication, IP address assignment, and routing functions for the mobile terminal 100. ) And a packet control function (PCF) 108.

The PCF 108 connects the ANC 104 and the PDSN 110 to perform a user traffic transfer function between the ANC 104 and the PDSN 110, and performs session management, mobility management, and the like for the mobile terminal 100. A session management / mobility management unit (SCMM) 112 that is responsible for functions such as authentication for the mobile terminal 100 may be included. In FIG. 1, the SC / MM 112 is shown separated from the PCF 108.

The SC / MM 112 performs mobility management for the CDMA 2000 1x EV-DO subscriber. The SC / MM 112 processes the allocation request of the Universal Access Terminal Identifier (UATI) of the ANC 104 for the subnet area. IMSI and session information are transmitted), and when a paging request for AT 100 occurs, paging is performed according to a location.

 In addition, the PCF 108 is an access network (AN) -Authentication Authorization Accounting (ANA) 114 and an SC / MM 112 or AN-AAA, which are network servers in charge of authentication, access rights, and billing functions for users. It is connected to the element management system (EMS) managing the system of 114 and the PDSN 112 of the data core network.

The PDSN 110 is connected to a Home Agent (HA) 120 that manages a session of the mobile IP in order to receive the mobile IP, and the HA 120 is responsible for authentication and authorization of the subscriber's wireless data service. It is connected with Authentication Authorization Accounting (AAA) 118 and IP network 122.

The most prominent feature of the cellular mobile communication technologies that have evolved from the first to the second generation to the third generation based on voice service through the circuit network as shown in FIG. 1 is that subscribers can access the Internet in a wide range of wireless communication environments. It is to provide packet data service. However, there is a limit to supporting high-speed packet data service in cellular mobile communication network, and CDMA2000 1x EV-DO system, which is a synchronous mobile communication system, provides data rate of up to about 2.4Mbps.

In general, in the case of wireless data communication through the CDMA 2000 1x EV-DO network, the AT 100 should be given a unique ID, which is referred to as UATI described above with reference to FIG. 1. UATI is assigned from the SC / MM 112 to the AT 100 as the only value in the Subnet region, and if the AT 100 moves to another subnet, the SC / The MM reassigns its own UATI for that subnet only. The AT 100 assigned the UATI from the SC / MM 112 proceeds with negotiation about the session information, and the UATI is recognized as a unique identifier in the subnet to which the AT 100 belongs. Subnet is generally defined as the area that one PCF is responsible for.Information such as subnet ID, latitude, longitude of ANTS broadcasted from access network (ANC, ANTS) when AT 100 enters subnet By receiving a sector parameter message including a SectorParameter, it is recognized that the subnet has been changed. As such, the subnet is intended to be assigned to use a unique ID (UATI) value in a specific area to which the AT 100 moves or belongs. As described above, when the AT 100 moves to another subnet, when handoffs are made between subnets, a unique identifier must be reassigned in a new subnet, which will be described with reference to FIG. 2 below. Hereinafter, an ANTS 102 and an ATC 104 will be referred to as an access network (AN).

Hereinafter, in FIG. 2, the PCF 108 of the access network 120 to which the AT 100 is currently connected is referred to as a source PCF, and the PCF 110 of the access network that is the target when the mobile terminal 100 is handed off. Is called the target PCF.

2 is a flowchart illustrating an operation for receiving an UATI when an AT 100 in a dormant state moves to another subnet in a general CDMA 2000 1x EV-DO system.

First, in step 206, the AT 100 initializes session establishment with the target AN (ANTS, ANC) 200 to receive the UATI from the target PCF (SC / MM) 204 to which it moves. This process is described in the IS-856 specification of CDMA 2000 1x EV-DO. In step 208, the AN 200 generates an A14 UATI Request message and delivers it to the PCF (SC / MM) 202. At this time, the PCF (SC / MM) 202 is a target PCF (SC / MM) 408 of the CDMA 2000 1x EV-DO network to which the AT 100 attempts to access.

In step 210, the target PCF (SC / MM) 202 receiving the A14 UATI request message generates an A13 Session Information Request message to obtain session information of the AT 100, and the AT ( 100 passes to the source PCF (SC / MM) 204 of the subnet in which it was originally located. In step 212, the source PCF (SC / MM) 204 that receives the A13 session information request message generates an A13 Session Information Response message including session information of the AT 100 and generates a target PCF ( SC / MM) (202).

Steps 214 to 222 are steps for completing a session initialization procedure for the AT 100 accessing the CDMA 2000 1x EV-DO system. The details of this procedure are specified in the HRPD IOS standard defined in 3GPP2 TSG-A, so the detailed description will be omitted.

In step 224, the target PCF (SC / MM) 202 generates an A11 Registration Request message using the session information obtained in step 212, and delivers the A11 registration request message to the PDSN 110. . At this time, the PCF of the target PCF (SC / MM) 202 includes a Lifetime value greater than 0 and a Mobility Event Indicator (MEI) field in the A11 registration request message. Thus, when the AT 100 connects to a new subnet, it may be connected to the same PDSN 110 as the previously connected PDSN 110.

In step 226, the PDSN 110 that receives the A11 registration request message generates an A11 Registration Response message and delivers it to the target PCF (SC / MM) 202. If there is an IP packet to be transmitted to the AT 100 by the PDSN 110, the PDSN 110 includes a data available indicator (DAI) in the A11 registration response message. If the target PCF (SC / MM) 202 receives the A11 registration response message including the DAI, it performs a 'Network Initiated Call Reactivation' procedure defined in HRPD IOS.

Step 228 is a procedure for releasing the connection between the source PCF (SC / MM) 204 and the PDSN 110.

3 is a conceptual diagram illustrating an operation between a source SC / MM and a target SC / MM when the AT 100 moves through a subnet boundary area according to the related art.

In the conventional CDMA 2000 1x EV-DO system, when the AT 100 frequently moves between the subnet 1 300 and the subnet 2 302, as shown in FIG. 3, the source PCF (SC / MM) 202 ) And frequently transmit session information between the target PCF (SC / MM) 204. That is, as in steps 210 and 212 of FIG. 2, the A13 session information request message and the A13 session information response message are frequently transmitted, thereby increasing the load of the entire system.

In more detail, when the AT 100 is in a Dormant state, when the AT 100 moves to another subnet region, the AT 100 performs the doment handoff. When performing the handoff procedure, a procedure for receiving a new UATI between the AT 100 and the target AN 200 is performed. The target PCF (SC / MM) 202 and the source PCF (SC / MM) 204 exchange session information through an A13 message in order to be allocated a new UATI.

In general, a region with a large number of CDMA 2000 1x EV-DO subscribers sets the subnet area small due to the capacity of the system. Areas with a small subnet area will send and receive A13 messages more frequently due to frequent subscriber movements. This results in an increase in load of the target PCF (SC / MM) 202 and the source PCF (SC / MM) 204.

In order to prevent the load increase of such a system, it is preferable to aggregate subnets. However, when integrating subnets, even when the AT 100 moves to another subnet, the doment handoff is not performed. If the AT 100 does not perform domental handoff, the PCF in the access network does not update its connectivity with the PDSN, causing subscriber data to be lost by sending data from the IP data network to the previous PCF. Occurs.

 Accordingly, an object of the present invention is to provide an apparatus and method and a system capable of preventing packet data loss caused by frequent movement of a mobile terminal in a mobile communication system.

Another object of the present invention is to provide an apparatus and method for reducing the load of the entire system by reducing the signaling process between the session management / mobility management unit (SC / MM) in accordance with the movement of the mobile terminal in a mobile communication system and a system thereof. have.

The mobile terminal of the present invention for achieving the above object, the sector information storage unit for storing the sector information is located, the mobile terminal receives the sector parameter information from the packet control unit and the existing sector information stored in the sector information storage unit; A control unit which checks whether the sector information of the newly received sector parameter information is the same, and if the subnet is changed, controls to transmit a new identifier request message to the session control / mobility management unit managing the packet control unit; do.

The session control and mobility management unit of the present invention for achieving the above object, when receiving a subnet area table storage unit for storing the subnet information of the mobile terminal, and an identifier request (UATI Request) message from the mobile terminal, A subnet area determination unit that checks the subnet information of the received message and the subnet information of the subnet area table storage unit to check whether the mobile terminal has moved in the same subnet area; If the mobile terminal is moved to a different subnet area, the control unit for controlling to generate a message for obtaining the session information of the mobile terminal from the source session control / mobility management unit where the mobile terminal was originally located through a message generator; The source session under control of the controller Word / portion comprises message generator for generating a message to be sent to the mobility manager.

The method of the present invention for achieving the above object, in the method for setting up a subnet (Subnet) to manage the session and mobility of the mobile terminal and transmitting the packet data, the packet control unit (PCF) included in the subnet Periodically transmitting sector parameters indicating the current location of the mobile terminal to mobile terminals located in the subnet; and if the mobile terminal moves to a different subnet, an identifier (UATI) request message is sent to the session control / mobility management unit. Transmitting, and setting, by the session control / mobility management unit, a subnet including at least two packet controllers for transmitting a packet received from a packet data serving node (PDSN) to the mobile terminal, and by using the session control / mobility management unit. Is assigned to the mobile terminal an identifier (Uunicast Access Terminal Identity: UATI) that is valid only in the subnet. Allocating, and managing, by the session control / mobility management unit, session information of the mobile terminal located in the subnet, when the mobile terminal requests a new identifier (UATI). And requesting session information for the mobile terminal from the source session control / mobility management unit before moving to the current subnet.

A system of the present invention for achieving the above objects, in the mobile communication system for establishing a subnet (Subnet) to manage the session and mobility of the mobile terminal and transmitting packet data without loss to the mobile terminal, A packet controller (PCF) for transmitting a sector parameter message periodically indicating a location of the current mobile terminal to a mobile terminal located in the subnet periodically, and receiving the sector parameter message from the packet controller (PCF), The mobile terminal transmits an identifier (UATI) request message to the session control / mobility management unit and checks whether the mobile terminal has moved to a different subnet or to a different subnet, and provides packet data to the mobile terminal. Manage subnets containing at least two packet controls And a session control / mobility management (SC) for allocating an identifier of the mobile terminal (UATI) valid only in the subnet and managing session information of the mobile terminal located in the subnet. / MM).

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that the same components in the figures represent the same numerals wherever possible. Specific details are set forth below, which are provided to aid a more general understanding of the present invention. In describing the present invention, when it is determined that description of related known functions or configurations may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

First, before describing the present invention, the basic concept of the present invention will be described.

In a CDMA 2000 1x EV-DO system, when a 1x EV-DO subscriber moves frequently in a subnet boundary area, the actual subscriber is handed off in a dormant state while not serving data. At this time, the target PCF (SC / MM) and the source PCF (SC / MM) exchanges the session information through the A13 message, in the present invention, by expanding the subnet area, the target PCF (SC / MM) and the source PCF (SC / MM) By reducing the exchange of A13 messages between the two systems, the load on the system can be reduced.

That is, in the past, one SC / MM is connected to one PCF to manage session management and location of a mobile terminal. However, in the present invention, at least two PCFs are connected to one SC / MM to manage sessions and mobile terminals. By managing the mobility of, the object of the present invention can be achieved. In addition, by updating the location information of the mobile terminal to the PCF to perform the R-P update between the PCF and PDSN, it is possible to prevent the loss of subscriber packet data that may be caused by expanding the subnet area.

4 is a block diagram illustrating a mobile terminal, an access network, and a session management / mobility management unit in a mobile communication system according to an exemplary embodiment of the present invention.

Referring to FIG. 4, the AT 410 moving a subnet area according to the present invention includes a sector information storage unit 400, a controller 402, a message generator 404, a transceiver 406, and a distance measurer. 508. In addition, the ANTS and the ANC are named as one Access Network (AN) 420 to facilitate understanding in the present invention, and the AN 420 may include a first transceiver 422, a controller 424, and an A14 message. The generator 426 and the second transceiver 428 are included. The PCF 430 illustrated in FIG. 4 merely performs message transfer between the AN 420 and the SC / MM 440 in the present invention.

First, the block configuration of the AT 410 according to an embodiment of the present invention will be described. The transceiver 406 of the AT 410 receives and demodulates a sector parameter (SectorParameter) message periodically transmitted by the AN 420 to the controller 402, and provides a message generated by the message generator 404. Send to AN 420. According to an embodiment of the present invention, the message generator 404 generates a UATI request message, which is a new identifier assignment message, when the AT 410 moves between or within subnet regions. In addition, the message generator 9504 generates a route update (Route_Update) message, which is a distance measurement message in which the AT 410 measures the distance between the ANs 420.

The sector information storage unit 400 stores sector information of the area where the AT 410 is currently located, and the control unit 402 receives sector parameter information periodically transmitted from the AN 420 to receive the sector information storage unit. If it is different from the existing sector information compared to the sector information stored in the 400, the registration procedure associated with the zone (Zone) change is performed. In this case, the message used is a UATI request message in the CDMA 2000 1x EV-DO system. The transceiver 406 plays a role of transmitting the message generated by the message generator 404 to the AN 420, and delivers data or a message received from the AN 420 to the controller 402. . The distance measuring unit 408 periodically measures the distance from the AN 420 and provides the result to the controller 402. Then, the controller 402 controls the message generator 404 to generate a Route_Update message if the distance measured by the distance measurer 408 is longer than a predetermined distance.

Second, the block configuration of the AN 420 according to an embodiment of the present invention will be described. Basically, the AN 420 transfers sector parameter information generated by the PCF 430, which is an upper node, to the AT 410, and transmits a message or data transmitted by the AT 410 to the upper node. Accordingly, the first transmitter / receiver 422 transmitting sector parameter information received from the upper node to the AT 410 and receiving a route update message or an UATI request message generated by the AT 410 to perform the above role. Generate an A14 General Update message when a route update message is received from the controller 424 and the AT 410 that process the received messages, and generate an A14 UATI request message when a UATI request message is received. A14 message generating unit 426 and a second transmitting and receiving unit 428 for transmitting the generated message to the SC / MM 440 via the PCF (430). The first transmitter / receiver 422 and the second transmitter / receiver 428 may be configured as a single device.

Lastly, the SC / MM 440 includes a transceiver 441, a subnet area determiner 442, a subnet area table storage 443, a subnet area manager 444, a controller 445, and a message generator 446. It is configured to include).

Then, a block configuration of the SC / MM 440 according to an embodiment of the present invention will be described. The transceiver 441 receives the A14 General Update message or the A14 UATI request message from the AN 420 through the PCF 430 and transmits the received A14 General Update message to the subnet region determination unit 442. The subnet area determination unit 442 determines whether the AT 410 should be processed as an inter handoff or an intra handoff based on the information included in the received A14 message. To this end, the subnet zone determination unit 442 searches a table of the subnet zone table storage unit 443 that stores the subnet zone, and the sector or subnet included in the A14 General Update or A14 UATI request message sent by the AN 420. It is checked whether the information is the same subnet area as the subnet area already defined in the subnet area table storage 443. Here, the A14 General Update message and the A14 UATI request message are defined in 3GPP2 TSG-A A.S0007A.

The subnet zone management unit 444 manages the subnet zone table storage unit 443 in which the subnet zone management table is stored, and a system list of ANs included in the same subnet is defined in advance by an operator of the CDMA 2000 1x EV-DO system. .

The subnet area determining unit 442 transmits the result to the control unit 445 when it is determined that the area moved by the AT 410 is the same subnet area based on the information of the message transmitted by the AN 430. The controller 445 receiving the result updates the location information of the AT 410, omits the process of A13 message, and targets the PCF 430 and the AT 410 of the subnet area to which the AT 410 has moved. The control unit 446 controls the message generator 446 to generate a message for RP update between the PDSN 110 transmitting the packet data to the source PCF (not shown) before moving.

The message generator 446 generates a corresponding message under the control of the controller 445. If the AT 410 has moved only in the same subnet, instead of generating an A13 message, instead of generating an A13 message, an AT14 410 generates an A14 General Update Complete message for the RP update and transmits the target PCF (where the AT 410 is located) through the transceiver unit 441. 430). On the other hand, if the AT 410 has moved to a different subnet, it generates an A14 UATI Assignment message, which is an identifier assignment message, and transmits it to the target PCF 430 where the AT 410 is located through the transceiver 441.

 Upon receiving the message from the SC / MM 440, the PCF 430 processes the A11 message as shown in steps 224 to 228 of FIG. 2 to update the PDSN (not shown) and the R-P. Through this process, loss of packet data coming from the packet core network can be prevented even if the subnet is expanded. In FIG. 4, the AN 420 and the PCF 430 are shown as separate network elements (NEs). The AN 420 may be configured in a form including the PCF 430.

5 is a conceptual diagram illustrating a configuration of a subnet according to a preferred embodiment of the present invention. First, before describing FIG. 5, two preferred embodiments of the present invention will be briefly described.

Hereinafter, embodiments of the present invention will be described by dividing the case where the AT 410 moves to different subnet areas and the case where the AT 410 moves in the same subnet area. First, the case in which the AT 410 moves to different subnet regions (reference numeral 508) will be referred to as the first embodiment of the present invention, and the case in which the AT 410 moves to the same subnet region (reference numeral 510) is seen. This will be referred to as a second embodiment of the invention.

Referring to FIG. 5, in the present invention, the SC / MMs 440a and 440b share session information of the AT 410 according to the subnet size, and integrate and manage multiple PCFs into one subnet by a system operator. do. Subnet 1 500 and subnet 2 502 are different from each other, and each subnet includes SC / MM 440a for session control and mobility management for AT 410 connected to each subnet. 440b) is connected. In addition, reference numeral 508 indicates that the AT 510 has moved from subnet 1 500 to subnet 2 502, and reference numeral 510 means that the AT 510 has moved from subnet 2 502.

6 and 7, the signal flow according to the preferred embodiment of the present invention will be described below. Each message described below follows the HRPD IOS standard defined in 3GPP2 TSG-A.

FIG. 6 is a call flow between network elements when the AT 410 moves from the subnet 1 500 to the subnet 2 502 according to the first embodiment of the present invention. In the first embodiment of the present invention, when the AT 410 moves from the PCF1 430a to the PCF2 430b region, the PCF1 430a is referred to as the source PCF, and the PCF2 430b is referred to as the target PCF.

Subnets are usually set based on the PCF, but depending on the operator, multiple PCFs can be combined into a single subnet.

First, in step 600, the AT 410 is connected to the source PCF1 430a of the subnet 1 500 to transmit and receive packet data. If the AT 510 moves to the target PCF2 430b of the subnet 2 502 as in step 602, the AT 410 sends a sector parameter message transmitted by the target PCF2 430b in step 604. Will be received. The sector parameter includes information such as the ID of the sector in which the AT 410 is currently located, the subnet mask such as color code, and the latitude and longitude of the target AN 420 to which the AT 410 is currently connected. PCFs periodically transmit the sector parameter.

Upon receiving the sector parameter message in step 604, the AT 410 recognizes that the subnet area is changed in step 606, and requests a valid UATI in the newly located subnet 2 (502). In step 606, the AT 410 recognizing that it is located in the new subnet transmits an UATI Request message, which is an identifier request message for requesting allocation of a new UATI, to the target AN 420.

The target AN 420 that has received the UATI request message in step 608 transmits an A14 UATI request message to the target SC / MM 440b via the target PCF 430b in step 610. The target SC / MM 440b that has received the A14 UATI Request message in step 610 sends the source SC / MM 440a of the subnet 1 500 where the AT 410 was previously located in step 612. Request session information of the AT 410. In this case, the message used by the target SC / MM 440b to request session information from the source SC / MM 440a is an A13 message.

In step 612, the target SC / MM 440b, which has obtained session information of the AT 410, assigns an A14 UATI through the target PCF 430b to allocate a new UATI to the AT 410 in step 614. Send a message to the target AN (420). In step 614, the target AN 420 receiving the A14 UATI assignment message transmits a UATI assignment message to the AT 410, whereby the AT 410 determines a valid UATI in the newly moved subnet 2 502b. Will receive. Subsequent processes are the same as steps 214 to 228 described with reference to FIG. 2, so that packet data may be continuously received by the AT 410 moving to a new subnet.

7 is a call flow between network elements when the AT 410 moves only in the same subnet 502 according to the second embodiment of the present invention.

According to the second embodiment of the present invention, when the AT 410 moves from the PCF2 430b to the PCF3 430c region, that is, in the same subnet, the PCF2 430b is the source PCF and the PCF3 430c is the target PCF. It will be called. In other words, the second embodiment of the present invention is a case in which the AT moves from the PCF2 430b to the PCF3 430c region, that is, the PCF region is moved, but the subnet 2 region 502 is moved from the subnet 2 region 502. There is no subnet change. In this case, the IDLE handoff does not occur, so the handoff procedure does not substantially occur. In this case, a distance based registraion procedure is performed for paging to receive data, and the AT 410 measures a distance from the AN 420 to route_update every predetermined distance. Message is sent to the AN 420.

First, in step 700, the AT 410 is connected to the source PCF2 430b to transmit and receive packet data. When the AT 410 moves to the target PCF3 430c in step 702, the AT 410 receives a sector parameter message periodically transmitted by the target PCF3 430c in step 704. The AT 410 that receives the sector parameter message in step 704 does not request a new UATI because it recognizes that it has moved in the same subnet area in step 706.

In step 708, the AT 410 transmits a Route_Update message to the target AN 420 in order to perform distance based registration. Upon receiving the route_update message in step 708, the target AN 420 generates an A14 general update message in step 710 based on the route_update message transmitted by the AT 410, thereby generating a target PCF3 ( 430c is transmitted to the target SC / MM 440b. Here, the route_update message includes the ID of the sector to which the AT 410 belongs and the location information of the AT 410.

Upon receiving the A14 General Update message in step 710, the target SC / MM 440b updates location information of the AT 410 for paging to the subnet area table storage 443. Also, since the AT 410 has moved in the same subnet 2 area 502, A13 message processing is not performed.

The target SC / MM 440b updating the location information of the AT 410 in step 712 transmits traffic to the target PCF3 430c with the PDSN (not shown) that has transmitted packet data to the source PCF2 430b in step 714. A14 general update complete message is sent to the target PCF 430c. Subsequent processes are the same as steps 214 to 228 described with reference to FIG. 2 so that packet data may be continuously received from the AT 410 moved from the source PCF2 430b to the target PCF3 430c.

8 is a flowchart illustrating an operation of a target session control / mobility management unit (SC / MM) 440b according to an exemplary embodiment of the present invention. First, although FIG. 8 illustrates that the UATI request message is first received among the UATI request message and the A14 general update message, this is for convenience of description and the A14 general update message may be received first.

When the SC / MM 440b receives the UATI request message in step 800, the SC / MM 440b proceeds to step 802, and compares the subnet information included in the received message with the subnet information of the subnet area table storage unit 443. In step 804, if the subnet information included in the received message and the subnet information stored in the subnet area table storage unit 443 are different, the SC / MM 440b recognizes that the UE has moved to another subnet area. If it is recognized in step 804 that the AT 410 has moved in the same subnet, the process proceeds to step 818 to update only the location information of the moved AT 410, and the AT 410 moves to another subnet. If it is recognized, the flow proceeds to step 806 to request session information of the AT 410 from the source SC / MM 440a. The message used at this time is an A13 message.

The SC / MM 440b having obtained the session information in step 806 transmits an UATI assignment message to the AN 420 in step 808 to allocate a new UATI to the AT 410, and stores the subnet area table in step 810. The subnet area management table of the section 443 is updated.

On the other hand, if the SC / MM (440b) A14 general update message is received in step 812, the process proceeds to step 814 to update the location information of the AT (410) to the subnet area table storage unit 443 for paging. In step 816, the SC / MM 440b transmits an A14 general update complete message to the AN 420.

9 is a flowchart illustrating operations of an AT 410 according to an embodiment of the present invention.

The AT 410 that has received the sector parameter information in step 900 proceeds to step 902 and checks whether the existing sector information stored in the sector information storage unit 400 and the sector information of the newly received sector parameter information are the same. If it is not the same sector information in step 902, go to step 904 to check whether the subnet area is changed. If it is recognized in step 904 that the subnet in which the current AT 410 is located is changed, the process proceeds to step 906 and transmits a UATI request message to the AN 420. Thereafter, when the UATI assignment message is received from the AN 420 in step 908, the AT 410 updates the sector information of the sector information storage unit 400 in step 910. On the other hand, the AT 410 recognizing that the subnet has not changed in step 904 proceeds to step 910 to update only the sector information of the sector information storage unit 400.

10 is a flowchart illustrating operations of an AT 410 according to another embodiment of the present invention.

In step 1000, the distance measuring unit 408 of the AT 410 measures the distance from the AN 420. In operation 1002, the controller 402 checks whether the AN 420 has fallen by more than a predetermined distance. If it is dropped by more than the predetermined distance, the controller 402 proceeds to operation 1004 and the message generator 404 generates a route_update message. Control is then transmitted to the AN (420).

As described above, even if the subnet area is extended, the AT of the dotting partner can prevent the loss of packet data transmitted from the packet core network, and the frequent A13 message between the target SC / MM and the source SC / MM due to frequent AT movements. Less transmission and reception reduces the overall system load.

Claims (23)

In the mobile communication system for establishing a subnet (subnet) to manage the session and mobility of the mobile terminal and transmitting packet data without loss to the mobile terminal, A packet controller (PCF) which is included in a subnet and periodically transmits a sector parameter message indicating a current location of a mobile terminal to a mobile terminal located in the subnet; Upon receiving the sector parameter message from the packet control unit (PCF), it is checked whether it has moved only on the same subnet or to a different subnet, and if it has moved to another subnet, an identifier (UATI) request message is sent to the session control / mobility management unit. A mobile terminal to transmit, Managing a subnet including at least two packet controllers for providing packet data to the mobile terminal, allocating an identifier of the mobile terminal (UTI) valid only in the subnet, wherein the mobile is located in the subnet And a session control / mobility management device (SC / MM) for managing session information of the terminal. The mobile terminal of claim 1, wherein the mobile terminal moves on the same subnet. Calculates the distance from the access network (AN) of the subnet to which it is connected, and transmits a distance measurement message indicating its location to the session control / mobility management device (SC / MM), The session control / mobility management device that receives the distance measurement message, Updating only location information for paging of the mobile terminal, and instructing a packet controller (PCF) to which the mobile terminal is connected to perform settings for transmitting and receiving a packet with the packet data serving node (PDSN); system. The method of claim 2, wherein the distance measurement message, Between the mobile terminal and the access network is delivered in the form of Route_Update message, The access network and the session control / mobility management unit are delivered in an A14 General Update complete message format. The apparatus of claim 1, wherein the session control / mobility management device comprises: When the mobile terminal moves to another subnet area and requests a new identifier (UATI), session information on the mobile terminal is controlled by a source session control / mobility management device (SC / MM) before the mobile terminal moves to the current subnet. And assigning a new identifier (UATI) to the mobile terminal based on the session information. A method for establishing a subnet and transmitting packet data to manage session and mobility of a mobile terminal, Transmitting, by a packet control unit (PCF) included in a subnet, a sector parameter periodically indicating a current location of a mobile terminal to mobile terminals located in the subnet; If the mobile terminal has moved to a different subnet, transmitting an identifier (UATI) request message to a session control / mobility management device (SC / MM); Setting, by the session control / mobility management unit, a subnet including at least two packet controllers for transmitting a packet received from a packet data serving node (PDSN) to the mobile terminal; A session control / mobility management device (SC / MM) assigning an identifier (Uunicast Access Terminal Identity: UATI) valid only in the subnet to the mobile terminal; Managing session information of the mobile terminal located in the subnet by a session control / mobility management apparatus (SC / MM); Requesting session information for the mobile terminal from a source session control / mobility management device (SC / MM) before the mobile terminal moves to the current subnet when the mobile terminal requests a new identifier (UATI). Characterized in that the method. The method of claim 5, wherein the mobile terminal is moved in the same subnet, Transmitting, by the mobile terminal, a message indicating the location of the mobile terminal by calculating a distance from an access network (AN) of a subnet to which the mobile terminal is connected to the session control / mobility management device (SC / MM); The session control / mobility management device (SC / MM) receives a message indicating the distance of the mobile terminal, updates only the location information for paging of the mobile terminal, and the packet controller (PCF) connected to the mobile terminal And indicating a setting for transmitting and receiving a packet with the packet data serving node (PDSN). The method of claim 5, wherein the session control / mobility management device (SC / MM), When the mobile station moves to a different subnet area and requests a new identifier (UATI), requesting session information for the mobile terminal from the source session control / mobility management device (SC / MM) where the mobile terminal was originally located, And assigning a new identifier (UATI) to the mobile terminal based on the session information. In the session control / mobility management device (SC / MM) for setting the subnet (Subnet) including at least two packet control unit (PCF), to manage the session control and mobility of the mobile terminal, A subnet area table storage unit storing subnet information of the mobile terminal; Upon receiving an UATI Request message from the mobile terminal, the subnet information of the received message and the subnet information of the subnet region table storage unit are examined to check whether the mobile terminal has moved in the same subnet region. Subnet zone determination unit, If the mobile terminal moves to a different subnet area according to the inspection result of the subnet area determining unit, session information of the mobile terminal is obtained from a source session control / mobility management device (SC / MM) where the mobile terminal is originally located. A control unit which controls to generate a message for obtaining through a message generating unit; And a message generator for generating a message to be transmitted to the source session control / mobility management device (SC / MM) under the control of the controller. According to claim 8, After obtaining the session information of the mobile terminal from the source session control / mobility management device (SC / MM), The subnet area determination unit updates the subnet area management table of the subnet area table storage unit, The controller controls the packet controller to transmit an UATI Assignment message. The apparatus of claim 8, wherein the session control / mobility management device (SC / MM) receives the distance measurement message from the access network by the mobile terminal. And the control unit updates only the location information of the mobile terminal for paging of the mobile terminal, and transmits an update completion message to the packet controller. The method of claim 10, wherein the distance measurement message, Between the mobile terminal and the access network is delivered in the form of Route_Update message, Wherein the access network and the session control / mobility management unit are delivered in the form of an A14 General Update complete message. The method of claim 8, wherein the mobile terminal moves in the same subnet area based on a result of a test of the subnet area determining unit. The device of claim 1, wherein only the location information of the mobile terminal is updated. A method for managing session control and mobility of a mobile terminal by setting a subnet including at least two packet controllers (PCFs), Checking whether an identifier allocation request message has been received from the mobile terminal; If the identifier assignment request message is received, comparing the subnet information of the received message with the subnet information stored in the subnet region table; As a result of the comparison, when the mobile terminal moves in different subnets, the mobile terminal includes requesting session information of the mobile terminal from a source session control / mobility management device (SC / MM) previously located. The method. 15. The method of claim 13, wherein when the subnet information of the received message and the subnet information stored in the subnet area table are compared, the same subnet, The location information of the mobile terminal is updated. The method of claim 13, wherein after obtaining session information from the source session control / mobility management device (SC / MM), Transmitting an identifier assignment message (UATI Assignment) and updating a subnet region management table. The method of claim 13, wherein the mobile terminal receives a distance measurement message from an access network And updating only the location information of the mobile terminal for paging of the mobile terminal, and transmitting an update completion message. A mobile terminal for transmitting a packet in a subnet configured to include at least two packet controllers (PCFs), A sector information storage unit for storing sector information in which the mobile terminal is located; Receiving sector parameter information from a packet control unit and checking whether the existing sector information stored in the sector information storage unit and the sector information of the newly received sector parameter information are the same, and if the subnet is changed, session control for managing the packet control unit. And a control unit for controlling to transmit a new identifier request message to a mobility management device (SC / MM). The method of claim 17, wherein the control unit, When receiving a new UATI Assignment message from the session control / mobility management unit, The sector information of the sector storage unit is updated. The method of claim 17, wherein the mobile terminal device, The apparatus of claim 1, further comprising a distance measuring unit for measuring a distance from an access network to which the mobile terminal is connected and transmitting the distance to the controller. The method of claim 19, wherein the control unit, And transmitting a route update message indicating a distance measured by the distance measurer. In the method for the packet transmission by the mobile terminal connected to the subnet (Subnet) including at least two packet control unit (PCF), Storing sector information in which the mobile terminal is located; Comparing the sector parameter information received from the packet controller with the existing sector information; And if the comparison results in other sector information, transmitting a new identifier request (UATI Request) message to a session control / mobility management device (SC / MM) that manages the packet controller. 22. The method of claim 21, wherein when receiving a new UATI Assignment message from the session control / mobility management device, And updating the stored sector information. The method of claim 21, And the mobile terminal transmits a route update message indicating the measured distance information by measuring a distance from an access network to which the mobile terminal is connected.

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