KR100934086B1 - Handover Method of Wireless Access System and Gateway Supporting the Same - Google Patents

Abstract

A method for a handover and a gateway supporting the same is disclosed, which is capable of optimally establishing a data path between a current BS being in contact with an MS and a target ASN-GW as well as a data path between a serving ASN-GW and a home network on the handover between ASNs, wherein the method of the handover between ASNs in the wireless access system after a handover between a previous BS and a current BS by a movement of an MS, comprises, when an ASN-ASN handover request message and first SF Info are transmitted to a target ASN-GW from a serving ASN-GW, establishing a first data path between the target ASN-GW and a home network; transmitting a data path ID of the target ASN-GW to the serving ASN-GW; and establishing a second data path between the current BS and the target ASN-GW through the use of data path ID of the target ASN-GW.

Description

Method for Hand-over in Wireless Access System and Gateway Supporting the Same

The present invention relates to a handover method of a wireless access system and a gateway supporting the same, and more particularly, to maintain an optimal data path during handover between access service networks (ASNs) according to movement of a mobile terminal. The present invention relates to a handover method and a gateway supporting the same.

The Wibro technology and the WiMAX NWG (Worldwide Interoperability for Microwave Access Forum Network Working Group) focus on the development and standardization of the network architecture for wireless Internet service delivery of mobile devices based on the IEEE 802.16 technology standard. And handover processing for maintaining data transmission and reception when the mobile terminal enters another base station area beyond the base station to which the mobile terminal is connected.

FIG. 1 is a block diagram for handling handover between an access service network (ASN) of a typical wireless access system. Hereinafter, terms described are WiBro, WiMAX Forum Network Architecture (Stage 3: Detailed Protocols and Procedures) May be based on Release 1.1.0, or IEEE 802.16 specifications.

The ASN handover is also referred to as a core mobility network (CSN Anchored Mobility). Here, ASN represents a network including an ASN gateway (ASN GateWay: referred to as 'ASN-GW') and a base station (Base Station: referred to as "BS").

A general wireless access system includes a home agent 102 existing on a home network of a mobile station 114a and a plurality of, for example, two ASNs, that is, serving ASN-GWs. 106) and a target ASN-GW (108). Here, the serving ASN-GW 106 manages the BS 110 before the handover, and the target ASN-GW 108 manages the current BS (Current BS) 112.

If the mobile terminal 114a (hereinafter referred to as 'MS') moves and network re-entry from the BS 110 before the handover to the current BS 112, the MS from the home agent 102 (hereinafter referred to as 'HA') The data path in the direction of 114b and the data path from the MS 114b toward the target ASN-GW 108 must be newly established. In this case, before the data path change due to the ASN handover, the data path between the current BS 112 and the MS 114b is first set by the BS inter-BS handover, that is, ASN Anchored Mobility. do. Thereafter, handover between ASNs is initiated such that the data path 116 between the HA 102 and the serving ASN-GW 106 via the service provider network 104 is connected to the HA 102 and the target ASN-GW 108. Will be changed to the data path 118 in between.

However, the data path 118 between the HA 102 and the target ASN-GW 108, which is a new foreign agent (hereinafter referred to as 'FA'), may be established, but the serving ASN-GW 106 and the hand may be configured. The manner in which the data path 122 between the BS 110 before the over is changed to the path 124 between the target ASN-GW 108 and the current BS 112 is not defined.

Thus, in order for the current BS 112 to receive data from the HA 102 after handover between ASNs, data transmitted to the target ASN-GW 108 is unnecessarily transmitted back to the serving ASN-GW 106 and then to the current BS. There is a burden to be routed 120 to 112.

On the other hand, when the serving ASN-GW 106 requests the target ASN-GW 108 for inter-ASN handover, the target ASN-GW 106 performs a series of MIP registration procedures for data path establishment or FA relocation by the target ASN-GW 108, and then the target ASN-GW The ASN-GW 108 notifies the serving ASN-GW 106 that a data path has been established between the HA 102 and the target ASN-GW 108. However, there is no way of recognizing whether the notification to the serving ASN-GW 106 has been properly delivered, which makes it difficult to determine whether to retransmit.

The present invention is to solve the above problems, to provide a handover method and a gateway supporting the radio access system for handover between ASNs to the technical problem.

Another object of the present invention is to provide a handover method of a wireless access system that can be implemented in a PMIPv6 protocol environment as well as a PMIPv4 and a gateway supporting the same.

Another object of the present invention is to provide a handover method of a wireless access system and a gateway supporting the same in order to reduce packet transmission delay during handover between ASNs.

Another object of the present invention is to provide a handover method of a wireless access system capable of preventing packet loss when data path is established between a current base station and a target ASN-GW according to handover between ASNs and a gateway supporting the same. do.

In addition, another object of the present invention is to provide a handover method of a wireless access system and a gateway supporting the same, which enables retransmission of a response to a handover request during handover between ASNs.

A handover method of a radio access system according to an aspect of the present invention for achieving the above object is an access service of an ASN (Radio Access System) of the radio access system performed after a handover between the base station and the current base station by the movement of the terminal; In the inter-network handover method, when the inter-ASN handover request and first service flow (SF) information are transmitted from the serving ASN-GW (Access Service Network GateWay) to the target ASN-GW, the target ASN-GW and the home are transmitted. Establishing a first data path between the networks; Transmitting the data path identifier of the target ASN-GW to the serving ASN-GW; And setting a second data path between the current base station and the target ASN-GW using the data path identifier of the target ASN-GW.

A handover method of a wireless access system according to another aspect of the present invention for achieving the above object is a handover method between ASNs of a wireless access system performed after the base station handover from the previous base station to the current base station by the movement of the terminal The method of claim 1, further comprising: establishing a first data path between the target ASN-GW and a home network when an inter-ASN handover request message is transmitted from a serving ASN-GW to a target ASN-GW; And establishing a second data path between the current base station and the target ASN-GW.

A handover method of a wireless access system according to another aspect of the present invention for achieving the above object is a current base station supporting an ASN handover performed after the handover occurs from the previous base station to the current base station by the movement of the terminal A handover method in a network comprising: receiving a data path identifier of a target ASN-GW and a second data path establishment request message between the current base station and the target ASN-GW from a serving ASN-GW; Establishing a second data path between the current base station and the target ASN-GW using the data path identifier of the target ASN-GW; And transmitting a second data path establishment complete message to the serving ASN-GW.

A handover method of a radio access system according to another aspect of the present invention for achieving the above object is a handover method in an ASN-GW performing a FA function of a radio access system, the terminal information from the serving ASN-GW And receiving an ASN handover request including first SF information connected with the terminal. Requesting a MIP registration to the HA in a process of resetting a foreign agent (FA) in response to an ASN handover request; And receiving a response to the MIP registration request and transmitting a response to the inter-SNSN handover request including second SF information generated based on the first SF information.

The gateway supporting the handover of the radio access system according to an aspect of the present invention for achieving the above object is to perform the ASN handover performed after the base station handover from the previous base station to the current base station by the movement of the terminal; In the supporting gateway, receiving the first SF information and the first ASN handover request from the first ASN-GW, and generating the second SF information by using the first SF information to the first ASN-GW. And a data path setting unit which transmits a response to the first ASN handover request. And an external agent for requesting registration of a temporary address of the terminal in the home network of the terminal in response to the first ASN handover request.

As described above, according to the present invention, a handover method of a wireless access system for handover between ASNs and a gateway supporting the same can be implemented.

In addition, there is another effect of implementing a method for handover between ASNs and a gateway supporting the same in a wireless access system under PMIPv6 protocol environment as well as PMIPv4.

In addition, by directly setting the data path between the current base station and the target ASN-GW during handover between ASNs, there is another effect of optimizing the routing path between the mobile terminal and the home network and reducing packet transmission delay.

 In addition, according to the present invention, by generating a temporary tunnel during the process of establishing a data path between the base station and the target ASN-GW during handover between ASNs, packet loss transmitted from the home network during the data path establishment procedure between the base station and the ASN-GW There are other effects to reduce this.

In addition, according to the present invention, it is possible to retransmit the response to the handover request during the handover between the ASN, so that the data path change between the base station and the ASN-GW can be reliably progressed, and the FA relocation can be cancelled. It has a different effect.

Before describing the embodiments of the present invention, the terms used in the present invention will be briefly described.

The network supporting mobile IP (hereinafter referred to as 'MIP') includes a home agent (hereinafter referred to as 'HA'), an external agent (hereinafter referred to as 'FA') and a mobile terminal. (Mobile Station: hereinafter referred to as 'MS'). The following functions are required for MIP operation.

First, Agent Discovery is a method of determining whether the MS is currently connected to its home network or located in an external network. By this method, the MS can recognize that it has moved to another network.

The registration function provides a flexible mechanism to deliver the current location information to the home agent when the mobile terminal recognizes that the mobile terminal has moved to another network so that the service provided on the home network can be provided on the new network as it is. .

Proxy Mobile IP (hereinafter referred to as 'PMIP') technology is a network entity that performs PMIP to handle authentication or MIP registration on behalf of MS. If the MS's IP address (e.g., a temporary address) needs to be changed, the Access Service Network GateWay (FAN) includes FA functions on behalf of the MS. Send MIP registration message. After receiving it, ASN-GW delivers it to HA to perform MIP registration procedure.

Therefore, even if the IP address needs to be changed on the MS side, the network entity that performs PMIP performs the MIP registration procedure (Proxy MIP), so if only its own home address is initially configured, You do not need to change your own IP address even if you move to a network that belongs to it, that is, to a network belonging to another FA.

An Access Service Network (ASN) is a set of network functions that provides wireless access to subscribers of a wireless access system. The ASN includes a base station (hereinafter referred to as a BS) and an ASN-GW (ASN GateWay). Layer-2 connection establishment function, network discovery and network selection function, forwarding function for layer-3 connection establishment of MS, and radio resource management function.

ASN-GW is located in ASN and includes FA function of MIP, data path function (hereinafter referred to as 'DPF'), PMIP client function, session mobility management function, DHCP relay / The server may further include a proxy function, an ASN radio resource management function, a location management function, or a paging function. In addition, these functions may optionally be further configured as necessary.

The FA is located in the ASN-GW to support the mobility of the MS, and is a router connected to a network different from the home network, and delivers a packet received from the HA to the MS. The HA is located in the CSN (Core Service Network), which is a network managing the ASN and the MS, to support mobility of the MS, and delivers data to the FA from the corresponding node communicating with the MS.

The temporary address (hereinafter referred to as 'CoA') is a temporary address that the MS has when connecting to another access router or ASN. In particular, the FA CoA, FA-CoA, is an Agent Advertisement message. Is provided by the FA, and the FA's IP address is often used as the FA-CoA.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a signal flow diagram illustrating an ASN handover operation in a wireless access system implemented with PMIPv4 according to an embodiment of the present invention.

As shown, the radio access system includes an MS 202, a current BS (Current BS: 204), a serving ASN-GW 206 that performs the FA1 role in ASNa, and a target ASN-GW (the FA2 role in ASNb). 208), the PMIP client 210 performing the Proxy Mobile IPv4 (PMIPv4) registration procedure, and the HA 212 belonging to the home network of the current MS 202.

If a handover occurs due to movement of the MS 202, the MS 202 is connected from the serving ASN-GW 206 of the ASNa to the target ASN-GW 208 of the ASNb. At this time, before the data path change due to the ASN handover, which is the CSN fixed mobility (CSN Anchored Mobility), the BS (204) by the BS between the handover, that is, the ASN is fixed mobility (ASN Anchored Mobility) And a data path between the MS 202 is established first.

Therefore, before the ASN handover, the data path between the ASN-GW and the BS is set to the data path 262 between the serving ASN-GW 206 and the current BS 204, and between the ASN-GW and the HA 212. The data path is set to the data path 272 between the serving ASN-GW 206 and the HA 212 which is FA1.

Subsequently, handover between ASNs is performed. In detail, the data path between the ASN-GW and the HA 212 is first set as the data path between the target ASN-GW 208 and the HA 212, which is FA2. 1 A data path ', or to perform FA relocation, the target ASN-GW 208 may serve an inter-SNSN handover trigger message (hereinafter referred to as' Anchor_DPF_HO_Trigger'). Transmit to GW 206 (step 222).

After sending the Anchor_DPF_HO_Trigger message, the process proceeds to the next step (step 224). Here, the entity attempting the FA relocation for the first time may also be the serving ASN-GW 206, and the target ASN-GW 208 may attempt to do so in the next step (224). The first step (step 222) is an optional step.

Next, the serving ASN-GW 206 transmits an inter-SNSN handover request message (hereinafter referred to as 'Anchor_DPF_HO_Req') to the target ASN-GW 208 (step 224). Here, Anchor_DPF_HO_Req includes FA1-CoA, which is a CoA of the serving ASN-GW 206, DHCP information, and Service Flow Information (SF Info) of the serving ASN-GW 206, and the information includes TLV (Type). Length Value).

Anchor_DPF_HO_Req according to an embodiment of the present invention may have an Anchor MM context having an Authenticator ID, CoA of FA1, and DHCP related information as a TLV, and deliver the TLV to the target ASN-GW 208. This allows the target ASN-GW 208 to prepare with the PMIP client 210 to register the MIP with the HA 212.

In particular, in the present invention, when the Anchor_DPF_HO_Req is transmitted, service flow information (SF Info: hereinafter referred to as 'first SF information') of the serving ASN-GW 206 or terminal information (MS Info) including the first SF information are included as a TLV. To pass.

The reason for including the first SF information is to inform the target ASN-GW 208 of all SF information that the MS 202 has. The first SF information is a sub-TLV, an SF identifier (SF ID) generated by the serving ASN-GW 206, whether uplink or downlink (Direction), and data path information (hereinafter, referred to as 'Data Path Info'). Have the information needed to maintain the data path.

Here, the downlink SF information of the first SF information includes the Data Path Info of the BS 204 as the sub TLV, and the Data Path Info includes the Tunnel Endpoint and the Data Path ID as the sub TLV. The link SF information may be used by the target ASN-GW 208 to establish a data path (hereinafter referred to as 'second data path') between the current BS 204 and the target ASN-GW 208.

The Data Path ID among the sub TLVs of Data Path Info is a data path identifier and may be, for example, a GRE key. In addition, the Tunnel Endpoint in the sub TLV may be a channel receiver IP address. Accordingly, the target ASN-GW 208 may know the GRE key of the current BS 204 and the IP address of the current BS 204 through the first SF information.

Next, the target ASN-GW 208 transmits an FA reset request message (hereinafter referred to as 'Anchor_DPF_Relocate_Req') to the PMIP client 210 for the FA reset (step 226). This message includes FA1-CoA, which is a CoA of the serving ASN-GW 206, and FA2-CoA, which is a CoA of the target ASN-GW 208.

Then, the PMIP client 210 checks whether the received FA1-CoA matches its database information, generates a FA registration request message (hereinafter referred to as 'FA_Register_Req'), and transmits it to the target ASN-GW 208 ( Step 228).

FA_Register_Req has a Registration Request (RRQ) as a TLV, and an RRQ has an IP / UDP header, which is a format defined in RFC 3344. In addition, the RRQ has FA2-CoA in the CoA field. In addition, FA_Register_Req enables the registration of FA2-CoA in HA 212 by including the FA-HA MIP Key used for mobility authentication of MS 212.

Next, the target ASN-GW 208 transfers the RRQ received through FA_Register_Req to the HA 212 for MIP registration of the UE (step 230). Accordingly, the HA 212 notifies the target ASN-GW 208 of the new MIP registration by sending a Registration Reply (RRP) (step 232).

Subsequently, the target ASN-GW 208 transmits an FA registration completion response message (hereinafter referred to as 'FA_Register_Rsp') including the RRP received from the HA 212 to the PMIP client 210, and the PMIP client 210 Record FA2 as a new FA in its own database (step 234).

As a next step, the PMIP client 210 transmits an FA reset completion response message (hereinafter referred to as 'Anchor_DPF_Relocate_Rsp') to the target ASN-GW 208 (step 236). Here, Anchor_DPF_Relocate_Rsp may be a format indicating only the success or failure of the first data path establishment. This step 236 may optionally be included. Through the above-described steps, the first data path 274 is established between the HA 212 and the target ASN-GW 208.

Next, the target ASN-GW 208 newly generates its own SF information (hereinafter referred to as 'second SF information') based on the first SF information (step 238). Here, the type of the sub TLV included in the second SF information may be the same as the aforementioned first SF information.

In one embodiment of the present invention, the downlink SF information of the first SF information may be used as the downlink SF information of the second SF information. This is because the downlink SF information of the first SF information received from the serving ASN-GW 206 may be utilized when the BS 204 is not changed at the time of the ASN handover, which is a procedure after the inter-BS handover. .

Here, the second SF information has information necessary to maintain a data path such as SF ID, Direction, and Data Path Info as a sub TLV.

The uplink SF information of the second SF information may be generated based on the first SF information, and the subpath TLV may include the data path identifier of the target ASN-GW 208. Here, the data path identifier of the target ASN-GW 208 may be a GRE key of the target ASN-GW 208 as a Data Path ID which is a sub-TLV of Data Path Info.

That is, the target ASN-GW 208 generates Data Path Info of the second SF information to be sent to the current BS 204 via the serving ASN-GW 206 to establish the second data path, in particular the second data. A GRE key of the target ASN-GW 208 that is the uplink direction receiver of the path is generated.

In addition, the Data Path Info of the uplink SF information of the second SF information may include the IP address of the target ASN-GW 208 by having the Tunnel Endpoint which is the channel receiver IP address as the sub TLV.

Next, the target ASN-GW 208 transmits a first data path setup completion message (hereinafter referred to as 'Anchor_DPF_HO_Rsp') to the serving ASN-GW 206 (step 240). In this case, the present invention transmits not only whether the first data path setup is completed or failed, but also the second SF information through Anchor_DPF_HO_Rsp.

Here, transmitting the second SF information together with Anchor_DPF_HO_Rsp is for forwarding the second SF information to the current BS 204 using the serving ASN-GW 206 as a proxy for setting up the second data path. to be.

Here, the uplink SF information among the second SF information transmitted together with the Anchor_DPF_HO_Rsp is automatically set to the IP address of the target ASN-GW 208 which is the message sender when the Tunnel Endpoint value of the sub TLV is omitted and transmitted.

In the above-described embodiment, the second SF information is described as being transmitted. However, since the downlink SF information of the second SF information uses the first SF information, the BS 204 already knows the first SF information. In the modified embodiment, only uplink SF information of the second SF information may be transmitted.

Next, the serving ASN-GW 206 sends a second data path establishment request message (hereinafter referred to as 'Path_Modification_Req') to the current BS 204 (step 242).

The serving ASN-GW 206 serves as a proxy in the process of receiving Anchor_DPF_HO_Rsp including the second SF information and transmitting Path_Modification_Req. That is, it acts as an intermediary to convey the data path identifier of the target ASN-GW 208 among the target ASN-GW 208 and the current BS 204.

Path_Modification_Req may have a Registration Type as a TLV and may have terminal information (MS Info) or base station information (BS Info). In this case, the second SF information received from the target ASN-GW 208 may be transmitted as a sub TLV of MS Info or BS Info.

Next, the current BS 204 updates the data path info in the uplink direction based on the second SF information included in the received Path_Modification_Req for setting the second data path (step 244). At this time, the BS 204 currently transmits the IP address and the target ASN-GW 208 of the target ASN-GW 208, which is the channel receiver, through the Tunnel Endpoint and the Data Path ID among the sub TLVs of the Data Path Info included in the second SF information. ) 'S GRE Key can be used for updates.

Thus, the current BS 204, which is one end of the second data path, can know the GRE Key of the target ASN-GW 208, which is the uplink direction receiver, and the target ASN-GW 208, which is the other end of the second data path, The second data path 264 between the target ASN-GW 208 and the current BS 204 is known because the GRE key of the current BS 204 that is the downlink direction receiver is known due to the first SF information received in step 224. ) Can be set explicitly.

Next, the current BS 204 sends a second data path establishment complete message (hereinafter referred to as 'Path_Modification_Rsp') to the serving ASN-GW 206 (step 246). Path_Modification_Rsp may have a Registration Type as a TLV and may have UE information or BS Info. The serving ASN-GW 206 then deletes the record of the data path associated with the MS 202 that is no longer needed after receiving the Path_Modification_Rsp.

Subsequently, the serving ASN-GW 206 transmits an acknowledgment message (hereinafter referred to as 'Path_Modification_Ack') for completing the second data path establishment to the current BS 204 (step 248). Path_Modification_Ack has a Registration Type as a TLV and may include terminal information (MS Info).

Next, the serving ASN-GW 206 transmits a data path setup completion recognition message (hereinafter referred to as 'Anchor_DPF_HO_Ack') to the target ASN-GW 208 (step 250). This is to prevent the serving ASN-GW 206 from receiving the Anchor_DPF_HO_Rsp so that the second data path cannot be created. In addition, Anchor_DPF_HO_Ack serves to inform that the serving ASN-GW 206 has completed the proxy function for establishing the second data path.

In one embodiment, if the target ASN-GW (208) operates the timer after transmitting a Anchor_DPF_HO_Rsp, not for a certain period of time (T _{Anchor _ DPF _ HO _ Req)} Anchor_DPF_HO_Ack is received from the serving ASN-GW (206) Anchor_DPF_HO_Rsp may be repeatedly transmitted until Anchor_DPF_HO_Ack is received.

In addition, the target ASN-GW 208 may cancel the FA relocation according to whether the Anchor_DPF_HO_Ack is received.

3A is a signal flow diagram illustrating an ASN handover operation in which a temporary tunnel is supported in a wireless access system implemented with PMIPv4 according to another embodiment of the present invention.

The temporary tunnel 302 is configured as the first data path after the tunnel 274 between the target ASN-GW 208 and the HA 212 is established, and then the target ASN-GW 208 as the second data path and the current BS 204. Is a tunnel created between the serving ASN-GW 206 and the target ASN-GW 208 until the tunnel 264 is completed.

Here, in the temporary tunnel, the HA 212 is connected to the target ASN-GW 208 during the second data path setup process, but the BS 204 is not the target ASN-GW 208 but the serving ASN-GW 206. ) To prevent packet loss caused by That is, packet loss between the MS 202 and the corresponding node (CN) in communication with the MS 202 occurring during the data path establishment procedure for the ASN handover is minimized.

Specifically, referring to FIG. 3A, when a first data path is established and a message Anchor_DPF_HO_Rsp, which informs completion thereof, is transmitted to the serving ASN-GW 206, the serving ASN-GW 206 and the target ASN-GW ( In step 302, a temporary tunnel that is a temporary data path is formed.

The temporary tunnel 302 is maintained until the second data path is established, and is removed when the data path establishment completion message Anchor_DPF_HO_Ack is sent to the target ASN-GW 208 so that there is no fear of packet loss (step 304).

FIG. 3B is a configuration diagram for handling inter-ASN handover supported by a temporary tunnel in a wireless access system implemented with PMIPv4 shown in FIG. 3A.

If an inter-ASN handover occurs due to the movement of the MS 202, the serving ASN-GW 206 sends the inter-ASN handover request message and the first SF information to the target ASN-GW 208, and the HA 212. And the data path 272 formed between the serving ASN-GW 206 is set as the first data path 274 between the HA 212 and the target ASN-GW 208.

Subsequently, the serving ASN-GW 206 serves to deliver the second SF information generated by the target ASN-GW 208 to the current BS 204 in the process of receiving Anchor_DPF_HO_Rsp and transmitting Path_Modification_Rsp. Here, the current BS 204 deletes the data path 262 between the current BS 204 and the serving ASN-GW 206 using the data path identifier of the target ASN-GW 208 included in the second SF information. 2 Set to change to the data path 264. In this process, after setting up the first data path 274, a temporary tunnel 302 is created to prevent packet loss until the completion of setting up the second data path 264. This completes the path establishment procedure during handover between ASNs.

4 is a signal flow diagram illustrating an ASN handover operation in a wireless access system implemented with PMIPv6 (PMIPv6) according to another embodiment of the present invention.

The messages and TLVs described below are used to implement PMIPv6 and are defined for convenience of description, so if the term is different from those defined in the IETF and WiMAX Forum Network Architecture specification, they are defined in the specification if they are responsible for the same functionality. May be replaced with other terms.

As shown, the radio access system includes a serving ASN-GW 406 serving as a Mobile Access Gateway (MAG1) in the MS 402, a current BS 404, an ASNa, and a target ASN- serving as a MAG2 in the ASNb. A GW 408, a Proxy Mobile Agent (PMA) 410 performing a PMIPv6 (Proxy Mobile IPv6) registration procedure, and a Local Mobility Agent (412) belonging to a home network of the MS 402.

Before the ASN handover, the data path between the ASN-GW and the BS is set to the data path 462 between the serving ASN-GW 406 and the current BS 404, and the data between the ASN-GW and the LMA 412. The path is set to the data path 472 between the serving ASN-GW 406 and the LMA 412 which is MAG1.

Next, the data path establishment procedure due to the handover between ASNs will be described. First, the data path between the ASN-GW and the LMA 412 is referred to as the data path between the target ASN-GW 408 and the LMA 412, which is MAG2 (hereinafter, referred to as " Target ASN-GW 408 sends an inter-SNSN handover trigger message (hereinafter referred to as 'Anchor_DPF_HO_Trigger') to serving ASN-GW 406 (step 422).

After transmitting the Anchor_DPF_HO_Trigger message, the process proceeds to the next step (step 424). Here, the first entity attempting to reset the proxy CoA may also be the serving ASN-GW 406, and the target ASN-GW 408 attempts for the first time since the attempt may be made in the next step (424). Step 422 is an optional step.

Next, the serving ASN-GW 406 transmits an inter-SNSN handover request message (hereinafter referred to as 'Anchor_DPF_HO_Req') to the target ASN-GW 408 (step 424). Here, Anchor_DPF_HO_Req includes SF information (hereinafter referred to as 'first SF information') of the serving ASN-GW 406 or terminal information (MS Info) including the first SF information as a TLV, and includes the first SF information. TLVs constituting may be information necessary to maintain a data path such as SF ID, Direction, and Data Path Info.

Here, the target ASN-GW 408 can know all the SF information that the MS 402 has through the first SF information, and can know the GRE key of the current BS 404 and the IP address of the current BS 404. Will be.

Next, the target ASN-GW 408 transmits a temporary address reset request message (hereinafter referred to as 'Anchor_DPF_Relocate_Req') to the PMA 410 (step 426). This message may include a proxy home address (pHoA).

Subsequently, the PMA 410 starts a MIP registration procedure with the target ASN-GW 408 by transmitting a PMIP6 handover request message (hereinafter referred to as 'PMIP6_HO_Req') to the target ASN-GW 408 (step 428). .

Next, the target ASN-GW 408 transmits a Proxy Binding Update (PBU) message to the LMA 412 (step 430). Here, the PBU message may include a proxy home address and a proxy care address (pCoA) of the target ASN-GW 408. In response, the LMA 412 notifies the MIP registration fact to the target ASN-GW 408 by responding with a PBA (Proxy Binding Acknowledgement) message (step 432).

Subsequently, the target ASN-GW 408 sends a PMIP6 handover response message (hereinafter referred to as 'PMIP6_HO_Rsp') to the PMA 410, and the PMA 410 sends a target ASN- which is a MAG2 as a new proxy to its database. The GW 408 is recorded (step 434).

As a next step, the PMA 410 transmits a temporary address reset complete response message (hereinafter referred to as 'Anchor_DPF_Relocate_Rsp') to the target ASN-GW 408 (step 436). Here, Anchor_DPF_Relocate_Rsp may be a format indicating only the success or failure of the first data path establishment. Through the above-described steps, the first data path 474 is established between the LMA 412 and the target ASN-GW 408.

Next, the target ASN-GW 408 newly generates SF information (hereinafter referred to as 'second SF information') based on the first SF information (step 438). In one embodiment of the present invention, the downlink SF information of the first SF information may be used as the downlink SF information of the second SF information. Here, the second SF information has information necessary to maintain a data path such as SF ID, Direction, and Data Path Info as a sub TLV.

That is, the target ASN-GW 408 generates Data Path Info of the second SF information to be sent to the current BS 404 via the serving ASN-GW 406 to establish the second data path, in particular the second data. A GRE key of the target ASN-GW 408, which is the uplink direction receiver of the path, is generated.

In addition, Data Path Info of the uplink SF information in the second SF information may include the IP address of the target ASN-GW 408 by having a Tunnel Endpoint, which is a channel receiver IP address, as a sub-TLV.

Next, the target ASN-GW 408 transmits a first data path setup completion message (hereinafter referred to as 'Anchor_DPF_HO_Rsp') to the serving ASN-GW 406 (step 440). At this time, in the present invention, the Anchor_DPF_HO_Rsp is transmitted along with the second SF information as well as whether the first data path setup is completed or failed.

Here, the uplink SF information among the second SF information transmitted together with the Anchor_DPF_HO_Rsp is automatically set to the IP address of the target ASN-GW 408, which is the message sender, when the Tunnel Endpoint value of the sub TLV is omitted.

In the above-described embodiment, all of the second SF information is described as being transmitted. However, since the downlink SF information of the second SF information uses the first SF information, the BS 404 already knows the first SF information. In the modified embodiment, only uplink SF information of the second SF information may be transmitted.

Next, the serving ASN-GW 406 sends a second data path establishment request message (hereinafter referred to as 'Path_Modification_Req') to the current BS 404 (step 442).

The serving ASN-GW 406 serves as a proxy in the process of receiving Anchor_DPF_HO_Rsp including the second SF information and transmitting Path_Modification_Req. Here, Path_Modification_Req includes SF Info as a TLV for transmitting the second SF information.

Next, the current BS 404 updates the Data Path Info in the uplink direction based on the second SF information included in the received Path_Modification_Req for setting the second data path (step 444). At this time, the BS 404 currently uses the target ASN-GW 408 IP address and the target ASN-GW, which are channel receivers, through Tunnel Endpoint and Data Path ID among the sub TLVs of Data Path Info included in the received second SF information. The GRE key of 408 can be used for updating.

Accordingly, the current BS 404, which is one end of the second data path, may know the GRE Key of the target ASN-GW 408, which is the uplink direction receiver, and the target ASN-GW 408, which is the other end of the second data path, The second data path 464 between the target ASN-GW 408 and the current BS 404 because the GRE key of the current BS 404 that is the downlink direction receiver is known due to the first SF information received in step 424. ) Can be set explicitly.

Next, the current BS 404 responds to the serving ASN-GW 406 with a second data path setup complete message (hereinafter referred to as 'Path_Modification_Rsp') (step 446). The serving ASN-GW 406 then deletes the data path record associated with the MS 402 that is no longer needed after receiving the Path_Modification_Rsp. Subsequently, the serving ASN-GW 406 transmits an acknowledgment message (hereinafter referred to as 'Path_Modification_Ack') for completing the second data path setup to the current BS 404 (step 448).

Next, the serving ASN-GW 406 transmits a data path setup completion recognition message (hereinafter referred to as 'Anchor_DPF_HO_Ack') to the target ASN-GW 408 (step 450). This is to retransmit when the serving ASN-GW 406 does not receive the Anchor_DPF_HO_Rsp and thus the second data path cannot be created.

As described above, when the inter-ASN handover occurs, the serving ASN-GW 406 transmits the inter-ASN handover request message and the first SF information to the target ASN-GW 408, and after setting up the first data path. , Anchor_DPF_HO_Rsp is received and Path_Modification_Rsp is transmitted. In this process, the serving ASN-GW 406 serves to deliver the second SF information generated by the target ASN-GW 408 to the current BS 404 so that the second data path is established.

5 is a block diagram illustrating a gateway supporting handover between ASNs of a wireless access system implemented with PMIPv4 according to an embodiment of the present invention.

As shown, the gateway 502 supporting inter-ASN handover includes a data path setting unit 504, an external agent unit 506, and a proxy mobile IP processing unit 508. Here, the gateway 502 supporting inter-ASN handover is an ASN-GW, which is an authentication unit (not shown) in charge of authentication and subscriber access management, a DHCP processing unit (not shown) in charge of DHCP discovery, request, and release, Or a paging control unit (not shown).

The data path setting unit 504 is responsible for generating, modifying, and deleting data paths, and generating, modifying, and deleting service flow information.

When the gateway 502 supporting inter-ASN handovers performs a serving ASN-GW function, the data path setting unit 504 performs a serving ASN-GW (not shown) as a TLV to the first SF of the serving ASN-GW. The ASN handover request message (Anchor_DPF_HO_Req) including the terminal information (MS Info) including the information or the first SF information is transmitted. That is, when requesting a handover between ASNs to a target ASN, the terminal information or the information on the data path connected to the terminal may be transmitted together. Here, the terminal information may include the FA-CoA of the serving ASN-GW, and the information of the data path connected with the terminal may include a service flow identifier (SF ID) and a data path identifier (Data Path ID).

In addition, the second SF information is received from the target ASN-GW together with the first data path setting completion message (Anchor_DPF_HO_Rsp) between the home network of the terminal and the target ASN-GW. Then, a second data path setup request message (Path_Modification_Req) between the target ASN-GW including the second SF information and the current BS (not shown) is transmitted to the current BS.

Here, Anchor_DPF_HO_Rsp is a response to the ASN handover request, and the second SF information is information generated by the target ASN-GW including its own data path information.

Therefore, in this case, the gateway 502 supporting inter-ASN handover functions as a proxy for delivering the second SF information to the current BS. When receiving the second data path setup completion message Path_Modification_Rsp from the current BS, an acknowledgment message Path_Modification_Ack for completing the second data path setup is transmitted to the current BS.

The data path setting unit 504 transmits an FA reset request message (Anchor_DPF_Relocate_Req) to the proxy mobile IP processing unit 508 when the gateway 502 supporting inter-ASN handover performs the target ASN-GW function. The proxy mobile IP processing unit 508 may be present in the serving ASN-GW, the target ASN-GW, or another ASN-GW. In addition, for the inter-ASN handover request of the serving ASN-GW, Anchor_DPF_HO_Rsp including the SF information of the target ASN-GW is transmitted to the serving ASN-GW.

When the gateway 502 supporting the inter-ASN handover performs the target ASN-GW function, the external agent unit 506 temporarily requests the terminal to the HA 510 of the terminal in response to the inter-ASN handover request. Perform the address registration procedure. That is, the UE transmits a Registration Request (RRQ) to the HA 510 of the UE and receives a Registration Reply (RRP).

The proxy mobile IP processing unit 508 performs the FA resetting procedure of the terminal corresponding to the handover between ASNs. That is, upon handover between ASNs, if a FA reset request message (Anchor_DPF_Relocate_Req) including FA1-CoA and FA2-CoA is received, it is checked whether the received FA1-CoA matches its database information, and the FA registration request message ( FA_Register_Req) is generated and transmitted to the target ASN-GW. Here, FA1-CoA is a temporary address in the serving ASN-GW of the terminal, FA2-CoA is a temporary address in the target ASN-GW.

Those skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, it is to be understood that the embodiments described above are exemplary in all respects and not restrictive. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. do.

1 is a configuration diagram for processing handover between ASNs in a general wireless access system.

2 is a signal flow diagram illustrating an ASN handover operation in a wireless access system implemented with PMIPv4 according to an embodiment of the present invention.

3A is a signal flow diagram illustrating an ASN handover operation in which a temporary tunnel is supported in a wireless access system implemented with PMIPv4 according to another embodiment of the present invention.

FIG. 3B is a configuration diagram for handling inter-ASN handover supported by a temporary tunnel in a wireless access system implemented with PMIPv4 shown in FIG. 3A.

4 is a signal flow diagram illustrating an ASN handover operation in a wireless access system implemented with PMIPv6 according to another embodiment of the present invention.

FIG. 5 is a diagram illustrating a gateway supporting handover between ASNs of a wireless access system implemented with PMIPv4 according to an embodiment of the present invention. FIG.

<Description of the symbols for the main parts of the drawings>

202, 402: MS 204, 404: Current BS

206, 406: Serving ASN-GW 208, 408: Target ASN-GW

210: PMIP client 212: HA

410: PMA 412: LMA

Claims (31)

In a handover method between access service networks (ASNs) of a radio access system performed after a base station handover from a previous base station to a current base station due to movement of a terminal, When the ASN handover request and the first service flow (SF) information are transmitted from the serving ASN-GW (Access Service Network GateWay) to the target ASN-GW, a first data path is established between the target ASN-GW and a home network. step; Transmitting the data path identifier of the target ASN-GW to the serving ASN-GW; And Establishing a second data path between the current base station and the target ASN-GW using the data path identifier of the target ASN-GW; Handover method of a wireless access system comprising a. The method of claim 1, wherein the serving ASN-GW transmits a data path identifier of the target ASN-GW to the current base station through a proxy function together with a second data path establishment request message generated by the serving ASN-GW. Handover method of a wireless access system, characterized in that it further comprises the step. The method of claim 1, wherein the establishing of the second data path comprises: Receiving, by the current base station, a second data path establishment request message including a data path identifier of the target ASN-GW from the serving ASN-GW; Updating data path information with an ASN-GW using the data path identifier of the target ASN-GW; And And transmitting the second data path establishment complete message to the serving ASN-GW. The data path identifier of claim 1, wherein the data path identifier of the target ASN-GW is: And the second SF information generated by the target ASN-GW in response to the inter-ASN handover request. The method of claim 4, wherein The target ASN-GW uses downlink SF information of the first SF information as downlink SF information of the second data path. And wherein the current base station uses uplink SF information of the second SF information as uplink SF information of the second data path. The handover method of claim 4, wherein the second SF information is a sub type length value (TLV), and includes an SF ID, a direction, and a data path info. The method of claim 1, further comprising forming a temporary tunnel between the serving ASN-GW and the target ASN-GW. And the temporary tunnel is maintained from when the setting of the first data path is completed to when the setting of the second data path is completed. The method of claim 1, The serving ASN-GW further comprises sending a data path establishment complete recognition message to the target ASN-GW; The target ASN-GW indicates a first data path indicating completion of setting of the first data path until the data path establishment completion recognition message is received when the data path establishment completion recognition message is not received from the serving ASN-GW. Handover method of a wireless access system, characterized in that repeatedly transmitting a configuration complete message to the serving ASN-GW. The method of claim 1, The serving ASN-GW and the target ASN-GW include a network entity operating as a foreign agent (FA), and the target ASN-GW includes a PMIP client and a HA of the home network. And a home agent) to set up the first data path. The method of claim 9, The PMIP client further comprises the step of responding to the target ASN-GW in the success or failure of the first data path establishment. The method of claim 1, The serving ASN-GW and the target ASN-GW include a network entity operating as a mobile access gateway (MAG), and the target ASN-GW includes a proxy mobility agent (PMA) and a local mobility agent (LMA) of the home network. And setting the first data path together with the handover method of the wireless access system. The method of claim 11, The PMA responding to the target ASN-GW whether the first data path is established or not; Handover method of a wireless access system, characterized in that it further comprises. The method of claim 1, wherein the establishing of the first data path comprises: Transmitting, by the target ASN-GW, a Proxy Binding Update (PBU) message to the home network; And The home network responds to the received PBU message with a Proxy Binding Acknowledgment (PBA) message; Handover method of a wireless access system comprising a. In the ASN handover method of the radio access system performed after the base station handover from the previous base station to the current base station due to the movement of the terminal, Establishing a first data path between the target ASN-GW and a home network when an ASN handover request message is sent from a serving ASN-GW to a target ASN-GW; And Establishing a second data path between the current base station and the target ASN-GW; Handover method of a wireless access system comprising a. The method of claim 14, The ASN handover request message includes first SF information of the serving ASN-GW and uses downlink SF information of the first SF information as downlink SF information of the second data path. Handover method of access system. The method of claim 15, Generating, by the target ASN-GW, second SF information corresponding to the inter-ASN handover request; And using uplink SF information of the second SF information as uplink SF information of the second data path. The method of claim 16, wherein the second SF information, Handover method of a wireless access system, characterized in that transmitted to the current base station by the proxy function of the serving ASN-GW. The method of claim 17, wherein the setting of the second data path comprises: The serving ASN-GW transmitting a second data path establishment request message including the second SF information to the current base station; Updating, by the current base station, data path information with an ASN-GW using uplink SF information among the second SF information; And Sending a second data path establishment complete message to the serving ASN-GW; Handover method of a wireless access system comprising a. The method of claim 14, wherein the target ASN-GW is: Determining whether a data path setting completion recognition message is received from the serving ASN-GW; When the data path setup completion recognition message is not received, the first data path setup complete message indicating the completion of the setup of the first data path is repeatedly transmitted to the serving ASN-GW until the data path setup completion recognition message is received. Handover method of a wireless access system, characterized in that for transmitting. In the handover method in the current base station to support the ASN handover performed after the base station handover from the previous base station to the current base station due to the movement of the terminal, Receiving a data path identifier of a target ASN-GW and a second data path establishment request message between the current base station and the target ASN-GW from a serving ASN-GW; Establishing a second data path between the current base station and the target ASN-GW using the data path identifier of the target ASN-GW; And And transmitting a second data path establishment complete message to the serving ASN-GW. The handover method of claim 20, wherein the data path identifier of the target ASN-GW is included in second SF information generated by the target ASN-GW. The method of claim 21, And wherein the current base station uses uplink SF information among the second SF information as uplink SF information of the second data path. The method of claim 20, And receiving an acknowledgment message for the completion of the second data path setup from the serving ASN-GW. In the handover method in the ASN-GW performing the FA function of the radio access system, Receiving, from a serving ASN-GW, an ASN handover request including first SF information connected to a terminal or terminal information having the first SF information; Requesting a MIP registration to the HA in the FA resetting process according to the inter-ASN handover request; And Receiving a response to the MIP registration request and transmitting a response to the inter-ASN handover request including second SF information generated based on the first SF information; Handover method of a wireless access system comprising a. The method of claim 24, The terminal information includes a handover address (FA-CoA) of the serving ASN-GW. The method of claim 24, The first SF information includes a service flow identifier and a data path identifier. In the gateway supporting the inter-ASN handover performed after the base station handover from the previous base station to the current base station due to the movement of the terminal, Receives a handover request between the first SF information and the first ASN from the first ASN-GW, and generates the second SF information and the first ASN between the first ASN-GW using the first SF information. A data path setting unit which transmits a response to the over request; And An external agent requesting registration of a temporary address of the terminal to the home network of the terminal in response to the first ASN handover request; Gateway comprising a. 28. The gateway of claim 27, further comprising a proxy mobile IP processing unit configured to perform an FA resetting procedure of the terminal during handover between the ASNs. The method of claim 27, The data path setting unit transmits a handover request between the second SF information and the second ASN to a second ASN-GW, and the third SF information and the second SF based on the second SF information from the second ASN-GW. Receiving a response to a handover request between ASNs, and transmitting a third SF information and a data path establishment request between the second ASN-GW and the current base station to the current base station. The method of claim 27, wherein the data path setting unit uses downlink SF information of the first SF information as downlink SF information of the second SF information, and uses its data path identifier to uplink the second SF information. Gateway used for SF information. 28. The gateway of claim 27, wherein the second SF information is a sub TLV, and includes an SF ID, a direction, and a data path info.

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