KR20090119709A - Method for processing handover between asns and asn-gw supporting that method - Google Patents

Abstract

PURPOSE: A method for processing handover between ASNs(Access Service Networks), and an ASN-GW supporting the same are provided to supply the same service to a terminal continuously by clearly performing a handover processing procedure between an ASN that support an ROHC(RObust Header Compression) and an ASN that does not support the ROHC. CONSTITUTION: An anchor DPF(Data Path Function) handover is performed an anchor DPF and a serving DPF(S100), and a service flow to be supplied to a terminal judges whether or not an ROHC is a service flow. When the ROCH capability of the anchor DPF is the ROCH capability of the serving DPF, the data route for supplying a service flow to which the ROHC is not applied is maintained(S110). The data route for supplying a service flow to which the ROHC is applied is released.

Description

Method for Processing Handover Between ASNs and ASN-GW Supporting That Method}

The present invention relates to a radio access system, and more particularly, to an inter-ASN handover process of a radio access system.

In order to utilize the limited radio resources as efficiently as possible in a wireless communication system, there is a demand for a header compression method suitable for packet transmission over various IP protocols and air interfaces, and especially in a condition where the bit error rate and delay are greatly increased. There is a need for an efficient header compression method that can be utilized.

For this reason, the Internet Engineering Task Force (IETF) has recently standardized ROHC (Robust Header Compression) as one of the header compression techniques, and the WiBro technology and the WiMAX NWG: Worldwide Interoperability for Microwave Access Forum. Network Working Group) attempts to provide a wireless communication service to a terminal through header compression using such a ROHC technique based on the IEEE 802.16 technical standard.

One of the important reasons for the development of ROHC is to solve this problem because there are many duplicates not only in packets but also between packets or between several IP headers used for packet transmission.

Therefore, in order to support handover so as to provide a wireless communication service to a terminal in a wireless communication network without disconnection, handover must be supported even when ROHC is supported on the wireless communication network.

In particular, when ROHC is supported in an access service network (hereinafter referred to as ASN) of a wireless communication network, handover between ASNs should be supported.

Here, the inter-ASN handover is also referred to as fixed mobility (CSN Anchored Mobility) of the Connected Service Network (hereinafter referred to as 'CSN'), and the inter-BS handover is also referred to as ASN Anchored Mobility. do.

However, like the existing ASN, the ASN may not support ROHC, and the new ASN may support ROHC. In addition, the ROHC support capability of each ASN may be different. However, despite such differences in ASN capabilities or ASN ROHC support capabilities, no solution for handling handovers between ASNs has been proposed.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and provides a method capable of efficiently handling handover between ASNs and a technical problem of providing an ASN-GW supporting the method.

 Another object of the present invention is to provide a handover processing method between an ASN supporting ROHC and an ASN not supporting ROHC and an ASN-GW supporting the method.

Another object of the present invention is to provide a handover processing method between ASNs having different levels of ROHC support, and an ASN-GW supporting the method.

An ASN handover processing method according to an aspect of the present invention for achieving the above object comprises the steps of performing an anchor DPF handover between an anchor DPF and a serving DPF; And a data path for maintaining a data path for providing a service flow to which no ROHC is applied and providing a service flow to which the ROHC is applied among the service flows to be provided to the terminal when the anchor DPF and the serving DPF have different ROHC capabilities. Includes the step of releasing.

In accordance with another aspect of the present invention, there is provided a method for processing between ASN handovers. An anchor DPF handover trigger including information indicating ROHC capability of the target ASN from a target Access Service Network (ASN). Receiving a message; And determining whether to allow anchor DPF handover based on the ROHC capability of the anchor ASN.

ASN-GW of the ASN to support the inter-ASN handover processing method according to another aspect of the present invention for achieving the above object, the data path management means for managing a data path for the data service to the terminal; Message receiving means for receiving from the target ASN-GW an anchor DPF handover trigger message comprising first capability information indicating the ROHC capability supporting capability; And handover determination means for comparing the first capability information of the anchor DPF handover trigger message with second capability information indicating the ROHC capability support capability and determining whether to relocate the data path. do.

ASN AG-GW of the ASN supporting the inter-ASN handover processing method according to another aspect of the present invention for achieving the above object, the ability to support the ROHC function from the anchor ASN-GW in response to the anchor DPF handover trigger message Message receiving means for receiving an anchor DPF handover request message comprising first capability information indicating a; Handover determination means for comparing the first capability information of the anchor DPF handover request message with the second capability information indicating the ROHC capability support capability and determining whether to relocate the data path; And data path management means for controlling the data path according to the determination result of the handover determination means.

According to the present invention, there is an effect that a method of efficiently handling handover between ASNs in a wireless access system and an ASN-GW supporting the method can be implemented.

According to the present invention, the handover processing procedure between the ASN supporting the ROHC and the ASN not supporting the ROHC and the handover processing procedure between the ASNs having different levels of the ROHC support are made clear so that the same service is maintained to the terminal or the hand is handed. The effect is that the optimal path can be set when over.

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

An Access Service Network (ASN) is a set of network functions that provide wireless access to subscribers of a wireless communication system and includes at least one base station (BS) and at least one network component such as an ASN GateWay (ASN-GW). As such, the ASN may be shared by at least one Connective Service Network (hereinafter referred to as 'CSN').

This ASN is defined as the network functions that a subscriber needs to provide wireless access. ASN provides the following main basic functions.

Layer-2 connection establishment function between base station and terminal, Home Network Service Provider (H-NSP) of wireless communication system subscriber for authentication, authorization, and accounting for subscriber session AAA message forwarding function, network discovery and network selection function of preferred NSP (Preferred Network Service Provider) of wireless communication system subscriber, and relay function for establishing Layer-3 connection with MS ( For example, an IP address allocation function and a radio resource management function are provided.

Meanwhile, in addition to the above-described functions, ASN provides ASN Anchor Mobility, CSN Anchor Mobility, Paging and Location for Portable and Mobile environments. It can support additional functions such as management function, ASN-CSN tunneling function.

In this case, the ASN-GW is located in the ASN and transmits to the home network service provider (H-NSP) of the wireless communication system subscriber for authentication / authorization / accounting for the subscriber session. The ability to forward AAA messages, the Mobile Agent's Foreign Agent (MIP) capabilities for mobility and / or relay functionality, the PMIP client functionality, DHCP Relay / Proxy functionality, Session mobility management and data It may further include a data path function (hereinafter referred to as 'DPF'), a location management function, and a paging function.

In this case, the data path function may include a ROHC function. The ROHC function includes a channel negotiation function with the ROHC function of the terminal, a ROHC compressor, and a ROHC decompressor. ROHC Compressor provides the function to compress the IP header of received data into ROHC packet header using ROHC header context, and ROHC Decompressor provides the function to restore the compressed header to original IP header using ROHC header context. .

The above-described ASN-GW functions can be selectively and recombined into additional or other forms as necessary.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following drawings, since R1.5 ASN means anchor ASN, hereinafter, it is referred to as anchor ASN, and R1 ASN means a new serving ASN or a target ASN because it is a handover target. The new serving ASN will be described.

1 is a diagram schematically illustrating a method for processing handover between ASNs according to a first embodiment of the present invention. In the first embodiment illustrated in FIG. 1, the anchor ASN supports the ROHC, and the new serving ASN does not support the ROHC.

When the handover between the base stations due to the movement of the terminal is completed, the DPF of the new serving ASN (hereinafter referred to as' new serving DPF ') is negotiated for relocation of the anchor ASN (hereinafter referred to as anchor DPF') (Negotiation). ), An anchor DPF handover trigger message (Anchor_DPF_HO_Trigger) is transmitted to the anchor DPF (S100).

In one embodiment, the anchor DPF handover trigger message may include a PrePaid Access Capability (PPAC) parameter and a ROHC capability parameter that defines the ROHC capability of the new serving DPF. In the first embodiment, since the new serving DPF does not support ROHC, the ROHC capability parameter includes information indicating that the new serving DPF does not support ROHC.

Thereafter, the anchor DPF rejects the anchor DPF handover to the new serving DPF because the ROHC capability parameter of the new serving DPF received from the new serving DPF includes information that the new serving DPF does not support the ROHC (S110). Therefore, the anchor DPF relocation from the anchor DPF to the new serving DPF does not occur, and the anchor DPF continues to perform the function of the anchor DPF for the terminal.

The new serving DPF determines that the anchor DPF rejects the anchor DPF handover when a response message to the anchor DPF handover trigger message is not received from the anchor DPF for a predetermined time (S120).

In the above-described embodiment, it has been described that the new serving DPF determines that the anchor DPF handover is rejected when the response message to the anchor DPF handover trigger message is not received from the anchor DPF for a predetermined time. The anchor DPF may generate and send an anchor DPF handover rejection message to the new serving DPF to notify the new serving DPF of the anchor DPF handover rejection. In this case, the new serving DPF may determine that the anchor DPF handover from the anchor DPF to the new serving DPF is rejected when the anchor DPF handover rejection message is received from the anchor DPF.

As described above, according to the first embodiment described above, the anchor DPF does not perform an anchor DPF handover between the anchor DPF that supports ROHC and the new serving DPF that does not support the ROHC, and the terminal device continues to function as the anchor DPF. The same ROHC service can be provided without interruption.

Next, FIG. 2 schematically illustrates a method for processing handover between ASNs according to a second embodiment of the present invention. In the second embodiment shown in FIG. 2, as in FIG. 1, an anchor DPF supports ROHC, and a new serving DPF does not support ROHC.

First, when the handover between base stations due to the movement of the terminal is completed, the new serving DPF transmits an anchor DPF handover trigger message to the anchor DPF to start the anchor DPF relocation negotiation (S200). In one embodiment, the anchor DPF handover trigger message may include the PPAC parameter and the ROHC capability parameters of the serving DPF as in the first embodiment.

In the second embodiment, since the new serving DPF does not support ROHC, as in the first embodiment, the ROHC capability parameter includes information indicating that the new serving DPF does not support ROHC.

Thereafter, the anchor DPF determines whether to perform the anchor DPF handover to the new serving DPF even if the ROHC capability parameter of the new serving DPF received from the new serving DPF includes information that the new serving DPF does not support the ROHC (S210).

Thereafter, the anchor DPF transmits an anchor DPF handover request message (Anchor_DPF_HO_Req) to the new serving DPF to start anchor DPF handover to the new serving DPF (S220). In one embodiment, the anchor DPF handover request message includes an ROHC capability parameter that defines the ROHC capability of the anchor DPF, an Authentication ID, an FA1-CoA that is a CoA of the new serving ASN, and an AnchorMM with DHCP related information. This may include.

Subsequently, when the new serving DPF sends a Registration ReQuest (RRQ) message to a Home Agent (HA) for MIP registration of the UE (S230), the Home Agent transmits a Registration RePly (RRP) to the new serving DPF. The MIP (Mobile IP) registration is notified (S240).

Thereafter, the new serving DPF transmits an anchor DPF handover response message (Anchor_DPF_HO_Rsp) to the anchor DPF to inform the successful relocation of the anchor DPF (S250).

In the above-described embodiment, the case of PMIP (Proxy Mobile IP) has been described as an example. In the case of CMIP (Client Mobile IP), an RRQ / RRP message transmission / reception process between the terminal and the new serving DPF may be additionally included.

When the anchor DPF handover from the anchor DPF to the new serving DPF is completed, the new serving DPF checks whether each service flows being serviced from the anchor DPF to the terminal are service flows to which the ROHC is applied (S260).

As a result, in the case of the service flow to which the ROHC is applied, the serving new DPF does not support the ROHC and thus cannot compress the data transmitted from the upper layer or decompress the data received from the terminal. Releases all data paths for the flow (S270). That is, the R6 data path for the service flow to which the ROHC is applied between the current base station (not shown) and the new serving DPF is released, and an 802.16e Dynamic Service Deletion (DSD) procedure is performed between the current base station and the terminal.

On the other hand, as a result of the verification, since the service flow does not require ROHC compression or data decompression is required, a new serving DPF that does not support ROHC according to the anchor DPF handover will also serve the service flow to the terminal. It may be (S280).

As described above, according to the second embodiment, the anchor DPF is performed as the new serving DPF to which the base station is currently connected in the anchor DPF by performing the anchor DPF handover between the anchor DPF supporting ROHC and the new serving DPF not supporting ROHC. Since the relocation of is performed, it is possible to optimize the data path.

3 is a diagram schematically illustrating a method for processing handover between ASNs according to a third embodiment of the present invention. 3 illustrates an anchor DPF handover processing method when both the anchor DPF and the new serving DPF support ROHC but the ROHC support level of the anchor DPF is different from the ROHC support level of the serving DPF. .

Here, the ROHC support level means a compression support level for protocols such as IP, UDP, and RTP. This level of compression support may be set within a range defined by a communication standard. In the present invention, the compression support level may be set within a range defined by a WiMAX or IEEE standard.

First, when the handover between base stations due to the movement of the terminal is completed, the new serving DPF transmits an anchor DPF handover trigger message to the DPF of the anchor ASN to start the relocation negotiation of the anchor DPF (S300).

In one embodiment, the anchor DPF handover trigger message may include the ROAC capability parameters of the PPAC parameter and the new serving DPF as in the first embodiment. In this case, the ROHC capability parameter of the new serving DPF includes information indicating the compression support level of the new serving DPF.

Thereafter, the anchor DPF checks the ROHC support level of the new serving DPF using the ROHC capability parameter of the new serving DPF received from the new serving DPF, and determines to perform the anchor DPF handover to the new serving DPF (S310).

Thereafter, the anchor DPF transmits an anchor DPF handover request message (Anchor_DPF_HO_Req) to the new serving DPF to start a handover to the new serving DPF (S320). In one embodiment, the anchor DPF handover request message may include an ROHC capability parameter that defines the ROHC capability of the anchor DPF, an authenticator ID, FA1-CoA which is a CoA of the new serving DPF, and an AnchorMM associated with DHCP information. .

Then, when the new serving DPF transmits the RRQ message to the home agent for MIP registration of the terminal (S330), the home agent notifies the registration of the new MIP by transmitting the RRP to the new serving DPF (S340).

Thereafter, the new serving DPF transmits an anchor DPF handover response message (Anchor_DPF_HO_Rsp) to the anchor DPF to inform the successful relocation of the anchor DPF (S350).

In the third embodiment, as in the second embodiment, an RRQ / RRP message transmission / reception process between the UE and the new serving ASN may be additionally included for the case of the CMIP.

When the anchor DPF handover is completed from the anchor DPF to the new serving DPF, the new serving DPF is included in the anchor DPF handover request message and uses the ROHC capability parameter of the anchor DPF transmitted and the ROHC support of the anchor DPF. Check whether the levels are different.

As a result, if the ROHC support level of the anchor DPF and the ROHC support level are different from each other, the ROHC is applied, so that the ROHC is not able to compress or decompress the data to the same level as the anchor DPF. Releases all data paths for service flows to which S is applied (S370).

That is, the R6 data path for the service flow to which the ROHC is applied between the current base station (not shown) and the new serving DPF is released, and the 802.16e DSD procedure is performed between the current base station and the terminal to perform all the service flows to which the ROHC is applied. Release the data path.

On the other hand, as a result of the check, in the case of the service flow to which the ROHC is not applied, since the data is not compressed or decompressed, the new serving DPF may serve the corresponding service flow to the terminal (S380).

Next, FIG. 4 is a diagram schematically illustrating a method for processing handover between ASNs according to a fourth embodiment of the present invention. In the fourth embodiment shown in FIG. 4, as in the third embodiment shown in FIG. 3, both the anchor DPF and the new serving DPF support ROHC, but the ROHC support level of the anchor DPF and the ROHC support level of the new serving DPF. The anchor DPF handover processing method in this different case is shown.

Since S400 to S470 illustrated in FIG. 4 are the same as S300 to S370 illustrated in FIG. 3, detailed descriptions thereof will be omitted in order to avoid duplication of description.

After releasing all the data paths for the service flow to which the ROHC is applied in S470, the new serving DPF is connected with the current base station (not shown) to provide the terminal with the service flow to which the ROHC is applied according to its ROHC support level. The R6 data path is newly set in the S6 and an 802.16e DSA (Dynamic Service Addition) procedure is currently performed between the base station and the terminal (S480).

On the other hand, although not shown in Figure 4, in the case of the service flow to which the ROHC is not applied, the new serving DPF continues because the compression or decompression of data is not required as in the third embodiment shown in FIG. The service flow to the terminal.

As described above, according to the fourth embodiment, the new serving DPF can provide the same services provided to the UE by the anchor DPF after the anchor DPF handover from the anchor DPF to the new serving DPF while optimizing the data path. Will be.

Next, FIG. 5 is a diagram schematically illustrating a method for processing handover between ASNs according to a fifth embodiment of the present invention. In the fifth embodiment shown in FIG. 5, as in the third embodiment shown in FIG. 3, both the anchor DPF and the new serving DPF support ROHC, but the ROHC support level of the anchor DPF and the ROHC support level of the new serving DPF. The anchor DPF handover processing method in this different case is shown.

First, when the handover between base stations due to the movement of the terminal is completed, the new serving DPF transmits an anchor DPF handover trigger message to the anchor DPF to start the relocation negotiation of the anchor DPF (S500).

In one embodiment, the anchor DPF handover trigger message may include a ROHC capability parameter that defines the PPAC parameter and the ROHC capability of the serving DPF as described above, wherein the ROHC capability parameter of the new serving DPF is the new serving DPF. Contains information indicating the level of compression support for.

Then, when the anchor DPF confirms that the ROHC support level of the new serving DPF included in the ROHC capability parameter of the new serving DPF received from the new serving DPF is different from the ROHC support level of the new serving DPF, the anchor DPF handover to the new serving DPF is performed. Reject (S510). Therefore, relocation of the anchor DPF from the anchor DPF to the new serving DPF does not occur, and the anchor DPF continues to perform the function of the anchor DPF for the terminal.

If the new serving DPF does not receive a response message for the anchor DPF handover trigger message from the anchor DPF for a predetermined time, the new serving DPF determines that the anchor DPF handover from the anchor DPF to the new serving DPF is rejected (S520).

At this time, as in the first embodiment described above, the anchor DPF generates an anchor DPF handover rejection message and sends it to the new serving DPF to notify the new serving DPF of the anchor DPF handover rejection, and the new serving DPF from the anchor DPF. When the anchor DPF handover rejection message is received, it may be determined that the anchor DPF handover from the anchor DPF to the new serving DPF is rejected.

As such, according to the fifth embodiment, the anchor DPF does not perform an anchor DPF handover between the anchor DPF and the new serving DPF having different levels of ROHC support, and provides the same service to the UE without disconnection since the anchor DPF continues to function as the anchor DPF. You can do it.

Hereinafter, the ASN-GW supporting the above-described inter-ASN handover processing method will be described. The ASN-GW may include message receiving means, handover determining means, and data path management means for handling handover between ASNs.

First, a case in which the ASN-GW performs the role of the anchor ASN-GW will be described.

The message receiving means receives from the target ASN-GW an anchor DPF handover trigger message (Anchor_DPF_HO_Triger) including first capability information indicating ROHC support capability of the target ASN-GW.

The handover judging means compares the first capability information of the anchor DPF handover trigger message received through the message receiving means with the second capability information indicating the ROHC support capability, and according to the comparison result, for the data service for the terminal. Determine whether to relocate data paths.

That is, the handover determination means compares the ROHC support capability of the target ASN-GW with its ROCH support capability and determines whether to handover the anchor DPF according to the result. Here, the ROHC support capability indicates a compression protocol that the ASN-GW can support.

As a result of the comparison, when the first capability information and the second capability information are different, the handover judging means determines to reject the relocation of the data path, thereby continuing to function as the anchor ASN-GW. Here, the difference between the first capability information and the second capability information means that the target ASN-GW does not support the ROHC and the ROHC support level is different even if the target ASN-GW and the target ASN-GW and both support the ROHC. Include.

The handover determining means may transmit a message indicating the rejection of the data path relocation, that is, the handover rejection of the anchor DPF, to the target ASN-GW when it is determined that the data path relocation is rejected.

On the other hand, when the handover determining means determines to relocate the data path, by sending the anchor DPF handover request message (Anchor_DPF_HO_Req) to the target ASN-GW in response to the anchor DPF handover trigger message, the target ASN-GW Enables data path relocation, that is, handover of anchor DPFs.

The data path means manages a data path for a data service to the terminal.

Next, a case in which the ASN-GW receives the anchor DPF handover request from the anchor ASN-GW and performs the role of a new serving ASN-GW performing handover of the anchor DPF will be described.

The message receiving means receives from the anchor ASN-GW an anchor DPF handover request message comprising first capability information indicating the ROHC support capability of the anchor ASN-GW in response to the anchor DPF handover trigger message.

The handover determining means compares the first capability information of the anchor DPF handover request message received through the message receiving means with the second capability information indicating the ROHC support capability and determines whether to relocate the data path.

That is, the handover determining means determines whether to perform the anchor DPF handover according to the comparison result of the first capability information and the second capability information.

The data path management means controls the data path for the data service to the terminal according to the determination result by the handover determination means.

In detail, when the data path management means determines that the first capability information and the second capability information are different from each other and the data provided to the terminal has a service flow to which the ROHC is applied, the data path management means provides the corresponding data. Release the data path. In this case, when the first capability information and the second capability information are different, the anchor ASN-GW supports the ROHC and does not support the ROHC, or if the anchor ASN-GW supports the ROHC but the support level is different. It includes.

Here, the data path management means may release the data path for providing the corresponding data by releasing the R6 data path with the current base station (not shown) or by performing an 802.16e DSD procedure between the current base station and the terminal.

On the other hand, when both the anchor ASN-GW and itself support the ROHC, but the support level is different, the above-described data path management means releases the data path for providing the data, and then the new data path for the service flow to which the ROHC is applied. You can add

Here, the data path management unit may add a new data path for a service flow to which ROHC is applied by establishing a new R6 data path between the current base station and allowing the 802.16e DSA procedure to be performed between the current base station and the terminal. .

On the other hand, those skilled in the art will understand that the present invention described above 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 flowchart showing a method for processing handover between ASNs according to a first embodiment of the present invention.

2 is a flowchart showing a method for processing handover between ASNs according to a second embodiment of the present invention.

3 is a flowchart showing a method of processing handover between ASNs according to a third embodiment of the present invention.

4 is a flowchart showing a method for processing handover between ASNs according to a fourth embodiment of the present invention.

5 is a flowchart showing a method for processing handover between ASNs according to a fifth embodiment of the present invention.

Claims (24)

Performing an anchor DPF handover between an anchor anchor data path function (DPF) and a serving DPF; And When the anchor DPF and the serving DPF have different ROHC capabilities, among the service flows to be provided to the terminal, the data path for providing a service flow to which no ROHC is applied is maintained and the data path for providing a service flow to which the ROHC is applied is And disabling the inter-ASN handover processing. The method of claim 1, Wherein the serving DPF does not support ROHC and the anchor DPF supports ROHC. The method of claim 1, The serving DPF and the anchor DPF support ROHC, but the serving DPF and the anchor DPF have different ROHC support levels. The method of claim 1, wherein after performing the anchor DPF handover, And determining whether the service flow to be provided to the terminal is a service flow to which ROHC is applied. The method of claim 1, wherein after performing the anchor DPF handover, And determining whether the anchor DPF and the serving DPF have different ROHC capabilities. The method of claim 1, To release the data path for providing the service flow to which the ROHC is applied, release the data path between the serving DPF and the current base station, and perform an 802.16e Dynamic Service Deletion (DSD) procedure between the current base station and the terminal. A method for handling handover between ASNs. The method of claim 1, wherein performing the anchor DPF handover is performed. Exchanging an ROHC capability message of the serving DPF and an ROHC capability message of the anchor DPF between the serving DPF and the anchor DPF. The method of claim 1, wherein performing the anchor DPF handover is performed. Transmitting, by the anchor DPF, an ROHC capability message of the serving DPF in an anchor DPF handover trigger message; If a handover from the anchor DPF to the serving DPF is determined, receiving an anchor DPF handover request message including an ROHC capability message of the anchor DPF from the anchor DPF; And And notifying completion of anchor DPF handover by transmitting a response message to the anchor DPF handover request to the anchor DPF. The method of claim 1, After releasing the data path for providing the service flow to which the ROHC is applied, new data between the serving DPF and the current base station to provide the terminal with the service flow to which the ROHC is applied based on the ROHC capability of the serving DPF. And establishing a path and performing an 802.16e Dynamic Service Addition (DSA) procedure between the current base station and the terminal. Receiving an anchor DPF handover trigger message including information indicating ROHC capability of the target ASN from a target Access Service Network (ASN); And Determining whether to allow anchor DPF handover based on the ROHC capability of the anchor ASN. The method of claim 10, wherein the determining of the anchor DPF handover, And when the ROHC capability of the anchor ASN is different from the ROHC capability of the target ASN, rejecting the anchor DPF handover. The method of claim 11, If the anchor ASN rejects the anchor DPF handover, the anchor ASN maintains the anchor function for the terminal. The method of claim 11, The target ASN further comprises the step of detecting the anchor DPF handover rejection, and abandon anchor DPF relocation. The method of claim 13, The target ASN detects the anchor DPF handover rejection when there is no response from the anchor ASN for a predetermined time or when a message indicating the anchor DPF handover rejection is received from the anchor ASN. Treatment method. The method of claim 10, The target ASN does not support ROHC and the anchor ASN supports ROHC. The method of claim 10, And the target ASN and the anchor ASN support ROHC, and the target ASN and the anchor ASN have different ROHC support levels. In ASN-GW of ASN in wireless communication network, Data path management means for managing a data path for a data service to a terminal; Message receiving means for receiving from the target ASN-GW an anchor DPF handover trigger message comprising first capability information indicating the ROHC capability supporting capability; And And handover determination means for comparing the first capability information of the anchor DPF handover trigger message with second capability information indicating the ROHC capability support capability and determining whether to relocate the data path. ASN-GW. The method of claim 17, The handover judging means rejects the relocation of the data path if the first capability information and the second capability information are different from each other as a result of the comparison of the first capability information and the second capability information. . The method of claim 17, The ROHC function support capability indicates a protocol capable of compression support. ASN-GW. In the ASN-GW of the ASN in a wireless communication network, Message receiving means for receiving, from the anchor ASN-GW, an anchor DPF handover request message including first capability information indicating ROHC capability support capability in response to the anchor DPF handover trigger message; Handover determination means for comparing the first capability information of the anchor DPF handover request message with the second capability information indicating the ROHC capability support capability and determining whether to relocate the data path; And And data path management means for controlling the data path according to the result of the determination of the handover determination means. The method of claim 20, If it is determined by the handover determining means that the first capability information and the second capability information are different, the data path management means releases the data path when the data path has a service flow to which ROHC is applied. ASN-GW characterized. The method of claim 21, And the data path management means releases the data path by releasing the R6 data path from the base station and performing an 802.16e DSD procedure between the base station and the terminal. The method of claim 20, If it is determined by the handover determining means that the first capability information and the second capability information are different, the data path management means adds a new data path for a service flow to which ROHC is applied. GW. The method of claim 23, wherein And the data path managing means adds the new data path by establishing a new R6 data path between the base station and performing an 802.16e DSA procedure between the base station and the terminal.

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