KR101779178B1 - Controller and method of control and handover based on proxy mobile ipv6 - Google Patents

Abstract

The present invention relates to a proxy mobile IPv6-based controller which includes: a communication module communicating data with a plurality of access points; a BCE database storing BCE information; a memory storing a control program; and a processor executing the control program. At this point, as the control program is executed, the processor generates a packet-out message based on a packet-in message, which is received from an access point connected with a mobile node, and then delivers the packet-out message to the access point connected with the mobile node. Then, the processor updates BCE information, corresponding to the mobile node, based on an RS message and a packet-in message, which are received from a handover target access point, and delivers the packet-out message and an RA message to the handover target access point to exchange packets between the handover target access point and the mobile node. The RS message, corresponding to the handover target access point, is generated in accordance with the RS message delivered from the mobile node to the handover target access point, and the message includes information of the mobile node and information of a destination node that matches the mobile node.

Description

[0001] CONTROLLER AND METHOD OF CONTROL AND HANDOVER BASED ON PROXY MOBILE IPV6 [0002]

The present invention relates to a proxy mobile IPv6-based controller and a control and handover method of a controller.

Proxy Mobile IPv6 is a network-based mobility management protocol that supports seamless service of mobile nodes. Proxy Mobile IPv6 is standardized by Internet Engineering Task Force (IETF) and can perform signaling that can occur during handover without intervention of mobile node. Therefore, Proxy Mobile IPv6 can improve performance and reduce signaling cost compared to the handover in which the mobile node intervenes.

Proxy Mobile IPv6 uses a bidirectional tunnel based on Internet protocol-in-internet protocol (IP-in-IP) for handover. Therefore, proxy mobile IPv6 may require signaling to generate a bidirectional tunnel upon handover.

In this connection, Korean Patent Registration No. 10-1582976 (entitled " Handover method for supporting network mobility in a PMIPv6 network ") discloses a handover method for supporting network mobility in a PMIPv6 network. More specifically, the present invention provides a method for a mobile communication system in which a local mobility anchor (LMA) receives a proxy binding update (PBU) message including an MR connection option from a mobile access gateway (MAG), confirms an MR connection option of a PBU message received from the MAG, Based on the result of the check, it is determined whether or not the MR is handed over. If the MR is handed over, the mobile node and the correlative node are connected without the MR binding procedure.

The present invention provides a proxy mobile IPv6-based controller, a mobile node and an access point control method of a controller, and a handover method for a mobile node of a controller.

It should be understood, however, that the technical scope of the present invention is not limited to the above-described technical problems, and other technical problems may exist.

According to a first aspect of the present invention, there is provided a proxy mobile IPv6-based controller comprising: a communication module for performing data communication with a plurality of access points; A BCE database, a memory for storing a control program, and a processor for executing a control program. At this time, according to the execution of the control program, the processor generates a packet_out message based on the packet_in message received from the access point connected to the mobile node, and forwards the generated packet_out message to the access point connected to the mobile node Updates the BCE information corresponding to the mobile node on the basis of the packet-in-message and the router solicitation (RS) message received from the handover target access point, and handover the access point to the mobile node And transmits a packet-out message and a router advertisement (RA) message to the target access point. The RS message corresponding to the handover target access point is generated in correspondence with the RS message delivered to the handover target access point by the mobile node, and includes the information of the mobile node and the information of the destination node corresponding to the mobile node.

The control method in the controller based on the proxy mobile IPv6 according to the second aspect of the present invention is a control method in a controller for a mobile node that receives a packet_in message and an RS message corresponding to a mobile node from an access point, Determining whether or not the presence of the user exists; Generating BCE information corresponding to a mobile node based on a packet-received message received from an access point when BCE information corresponding to the mobile node does not exist; And forwarding the RA message and the packet_out message to the access point. At this time, the RS message corresponding to the mobile node is generated corresponding to the RS message received from the mobile node by the access point, and includes the information of the mobile node and the information of the destination node corresponding to the mobile node.

According to a third aspect of the present invention, there is provided a method for handover in a proxy mobile IPv6 based controller, comprising: generating a packet_out message in response to a packet_in message received from an access point connected to a mobile node; Transmitting the generated packet_out message to a connected access point; Updating the BCE information corresponding to the mobile node stored in the BCE database upon receipt of the packet_in message and the RS message from the handover target access point; And forwarding the packet_out message and the RA message to the handover target access point after the step of updating the BCE information. The RS message corresponding to the handover target access point is generated in correspondence with the RS message delivered to the handover target access point by the mobile node, and includes the information of the mobile node and the information of the destination node corresponding to the mobile node.

The present invention enables a mobile node to perform data communication without a bidirectional tunnel. Therefore, the control and handover method of the controller and the controller based on the proxy mobile IPv6 can reduce the signaling cost for the bidirectional tunnel generation.

In addition, the proxy mobile IPv6-based controller and the control and handover method of the controller can integrate and manage the BCE information that has been distributed and managed in the existing MAG and LMA by the controller. Therefore, the control and handover method of the controller and the controller based on the proxy mobile IPv6 can reduce the handover delay time and the handover cost.

1 is a flowchart illustrating a handover process of a conventional proxy mobile IPv6.
Figure 2 is an illustration of a proxy mobile IPv6 domain according to an embodiment of the present invention.
3 is a flowchart illustrating a method of controlling a controller according to an embodiment of the present invention.
4 is a flowchart illustrating a handover method of a controller according to an embodiment of the present invention.
5 is a block diagram of a controller in accordance with an embodiment of the present invention.
6 is a flowchart illustrating a control method in a controller based on a proxy mobile IPv6 according to an embodiment of the present invention.
7 is a flowchart of a handover method in a proxy mobile IPv6-based controller according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "electrically connected" with another part in between . Also, when a part is referred to as "including " an element, it does not exclude other elements unless specifically stated otherwise.

Next, a handover process of the mobile node 100 in the conventional proxy mobile IPv6 will be described with reference to FIG.

A conventional proxy mobile IPv6 domain includes a mobile node 100, an LMA 120 and one or more MAGs 110 and 130.

At this time, the LMA 120 manages the home network prefix (HNP) information of the mobile node 100 and the status of one or more MAGs 110 and 130. The LMA 120 may operate as a kind of home agent for the mobile node 100 in proxy mobile IPv6.

The MAGs 110 and 130 are intended to support the mobility of the mobile node 100 on behalf of the mobile node 100. The MAGs 110 and 130 may register the location information of the mobile node 100 on the LMA 120 on behalf of the mobile node 100. The MAGs 110 and 130 may create a bi-directional tunnel between the LAMs for the mobile node 100.

1 is a flowchart illustrating a handover process of a conventional proxy mobile IPv6.

Referring to FIG. 1, the mobile node 100 may perform data communication through a bi-directional tunnel 140 between the first MAG 110 and the LMA 120, which are connected to each other.

The mobile node 100 may move out of coverage of the first MAG 110 that is connected to the coverage of the second MAG 130. [

When the mobile node 100 leaves the coverage of the first MAG 110 and is disconnected from the first MAG 110 in step S100, the first MAG 110 transmits a DeReg PBU ) Message (S110). At this time, the DeReg PBU message is a message for notifying the first MAG 110 of the movement to the corresponding mobile node 100 to the LMA 120. The LMA 120 may correct the BCE information corresponding to the mobile node 100 set in advance. Then, the LMA 120 may transmit a DeReg PBA (deregister proxy binding acknowledgment) message corresponding to the DeReg PBU message to the first MAG 110 (S115).

Also, the first MAG 110 may receive a DeReg PBA message corresponding to the DeReg PBU message from the LMA 120 (S115).

When the mobile node 100 enters the coverage of the second MAG 130 and is connected to the second MAG 130 in operation S120, the mobile node 100 transmits a router solicitation (RS) message to the second access point (S130). At this time, the RS message may include information of the mobile node 100 and information of a destination node (not shown) corresponding to the mobile node 100.

The second MAG 130 may exchange proxy binding update (PBU) and proxy binding acknowledgment (PBU) with the LMA 120 after receiving the RS message (S140, S150). And the second MAG 130 may create the bi-directional tunnel 150 with the LMA 120.

The second MAG 130 may forward the RA message corresponding to the RS message of the mobile node 100 (S150). At this time, the RA message is a response message indicating that the second MAG 130 is a router corresponding to the mobile node 100.

The mobile node 100 may perform data communication through the bidirectional tunnel 150 between the second MAG 130 and the LMA 120. [

As described above, in the conventional proxy mobile IPv6, the mobile node 100 performs data communication through a bidirectional tunnel connected between the MAG and the LMA 120. At this time, the bidirectional tunnel may be an IP-to-IP tunnel based on IP (internet protocol).

The MAG must create and manage a bi-directional tunnel while connected to the mobile node 100. In addition, the MAG needs to detect movement of the mobile node 100 and manage movement related signaling. Therefore, the conventional proxy mobile IPv6 may cause additional overhead and cost for managing signaling in the handover process of the mobile node 100. [

Next, a proxy mobile IPv6 domain 200 according to an embodiment of the present invention will be described with reference to FIGS.

The proxy mobile IPv6 domain 200 according to an embodiment of the present invention is based on SDN (software defined network). For example, the proxy mobile IPv6 domain may be based on an open flow protocol. In addition, the controller 210 may be an open network operating system (ONOS) controller.

The proxy mobile IPv6 domain 200 includes a controller 210, one or more access points 220 and 230, and a mobile node 240. In addition, the controller 210 may include one or more switches.

The controller 210 may manage one or more mobile nodes and one or more access points based on a mobility control application and a BCE management application.

For example, the controller 210 may process the handover related signaling of the mobile node 240 based on the mobility management application. In addition, the controller 210 can manage the BCE database through the BCE management application. At this time, the BCE database may store an identifier of the mobile node 240, home network prefix (HNP) information, and an identifier of an access point to which the mobile node 240 is connected.

Also, the switch may be an open virtual switch controlled by the controller 210. That is, the controller 210 can manage the access points 220 and 230 connected through an open virtual switch implemented as a virtual machine.

Access points 220 and 230 are coupled to mobile node 240. Access points 220 and 230 may also relay data communications with a destination node (not shown) corresponding to mobile node 240 and mobile node 240. For example, access point 220, 230 may be based on an open flow protocol. That is, the access points 220 and 230 may be open flow based switches.

2 is an exemplary diagram of a proxy mobile IPv6 domain 200 according to an embodiment of the present invention.

Referring to FIG. 2, the mobile node 240 may be coupled to a first access point 220. The first access point 220 may be connected to the controller 210 through a second switch and a first switch.

As the mobile node 240 moves, the mobile node 240 may enter the coverage 290 of the second access point 230 in the coverage 280 of the first access point 220. At this time, the second access point 230 may be connected to the controller 210 through the third switch and the first switch.

3 is a flowchart illustrating a method of controlling the controller 210 according to an embodiment of the present invention.

The mobile node 240 may generate an RS message to perform data communication with the destination node (not shown) through the first access point 220. At this time, the RS message may include information of the mobile node 240 and information of a destination node (not shown). For example, the RA message may include the IPv6 address of the mobile node 240, the MAC address of the mobile node 240, the IPv6 address of the destination node (not shown), and the MAC address of the destination node (not shown) .

The mobile node 240 may forward the RS message to the first access point 220 (S300).

The first access point 220 may generate a packet_in message corresponding to the RS message received from the mobile node 240. The first access point 220 may then forward the generated packet_ message to the controller 210 (S310). At this time, the packet-wise message may include information of the mobile node 240. For example, the packet-wise message may include an identifier of the mobile node 240.

Also, the first access point 220 may generate an open-flow router solicitation (OF-RS) message corresponding to the RS message received from the mobile node 240 to the controller 210. At this time, the OF-RS message may correspond to the RS message of the mobile node 240. For example, the OF-RS message corresponds to an RS message generated based on a transmission control protocol / internet protocol (TCP / IP) and is generated based on an open flow protocol.

The first access point 220 may then transmit the generated OF-RS message to the controller 210 (S320).

The controller 210 may extract information of the mobile node 240 from the packet-based message based on the mobility control application. Then, the controller 210 can check the BCE information stored in the BCE database based on the information of the mobile node 240 (S330).

At this time, if BCE information corresponding to the mobile node 240 is not present in the BCE database, the controller 210 uses the information of the extracted mobile node 240 and the BCE management application, BCE information can be newly generated. At this time, the BCE identifies the identifier of the mobile node 240 extracted from the information of the mobile node 240 included in the packet_in message, the identifier of the first access point 220 that transmitted the packet_in message, and the HNP information Lt; / RTI > At this time, the HNP information may be address information of the HNP or the like mobile node 240. The controller 210 may store the generated BCE information in the BCE database.

After generating the BCE information, the controller 210 may generate a packet_out message corresponding to the packet_in message. In addition, the controller 210 may generate an OF-RA message corresponding to the OF-RS message.

The controller 210 may forward the packet_out message and the OF-RA message to the first access point 220 (S315, S325).

The first access point 220 may receive the packet-out message and the OF-RA message from the controller 210 and may forward the RA message to the mobile node 240 (S305). At this time, the OF-RA message is based on the open flow protocol, and the RA message can be based on TCP / IP. Therefore, the first access point 220 can convert the OF-RA message based on the open flow protocol into the RA message based on the TCP / IP and deliver it to the mobile node 240.

After receiving the RA message, the mobile node 240 may perform data communication through the first access point 220 (S330).

4 is a flowchart illustrating a handover method of the controller 210 according to an embodiment of the present invention.

As the mobile node 240 moves from the coverage 280 of the first access point 220 to the coverage 290 of the second access point 230, The connection state may be less than or equal to a predetermined value, or the connection with the first access point 220 may be released (S400).

The first access point 220 may detect a handover of the mobile node 240 when the first access point 220 is disconnected from the mobile node 240. The first access point 220 may then forward the packet_in message to the controller 210 for handover (S410).

When the controller 210 receives the packet_in message from the first access point 220, the controller 210 may update the BCE information in response to the packet_n message (S420). For example, the controller 210 may update the BCE information corresponding to the mobile node 240 based on the DeReg PBU and the DeReg PBA (S420).

Specifically, the controller 210 can exchange DeReg PBU messages and DeReg PBA messages on its own, similar to exchanging DeReg PBU messages and DeReg PBA messages between LMA and MAG in the conventional proxy mobile IPv6 domain. The controller 210 may then modify the BCE information as the mobile node 240 moves from the first access point 220 to another access point. For example, the controller 210 may remove the identifier of the first access point 220 included in the BCE information corresponding to the mobile node 240. Alternatively, the controller 210 may update the state included in the BCE information corresponding to the mobile node 240 with information corresponding to the handover.

Then, the controller 210 may forward the packet_out message corresponding to the packet_in message to the first access point 220 (S415). At this time, the packet_out message may be a message that the controller 210 has updated the BCE information corresponding to the first access point 220.

If the mobile node 240 approaches the coverage 290 of the second access point 230, the mobile node 240 may forward the RS message for connection to the second access point 230 (S440).

The second access point 230 may generate a message that is packet_in response to the RS message received from the mobile node 240. [ At this time, the packet_in message may include the identifier of the mobile node 240. In addition, the second access point 230 may generate an OF-RS message corresponding to the RS message.

The second access point 230 may forward the packet-in-OF-message and the OF-RS message to the controller 210 (S450).

The controller 210 may extract the identifier of the mobile node 240 and the identifier of the second access point 230 from the packet-wise message from the second access point 230. The controller 210 may check and update the BCE information corresponding to the mobile node 240 stored in the BCE database (S460).

For example, the controller 210 may update the identifier of the access point included in the BCE information corresponding to the mobile node 240 from the first access point 220 identifier to the second access point 230 identifier. When the BCE information is updated, the controller 210 may generate a packet_out message corresponding to the packet_in message and an OF-RA message corresponding to the OF-RS message. The controller 210 may forward the packet-out message and the OF-RA message to the second access point 230 (S455).

The second access point 230 may forward the RA message corresponding to the OF-RA message to the mobile node 240 (S445).

After receiving the RA message, the mobile node 240 may perform packet exchange with the second access point 230 for data communication with a destination node (S470).

Next, a controller 210 according to an embodiment of the present invention will be described with reference to FIG.

5 is a block diagram of a controller 210 in accordance with one embodiment of the present invention.

The controller 210 includes a communications module 500 BCE database, a memory 510, and a processor 520. At this time, the controller 210 may be based on an open flow protocol.

The communication module 500 may perform data communication with an access point connected to the controller 210.

The BCE database stores BCE information corresponding to a plurality of mobile nodes 240 connected to the controller 210.

The memory 510 stores a control program. At this time, the memory 510 collectively refers to a non-volatile storage device that keeps stored information even when power is not supplied, and a volatile storage device that requires power to maintain stored information.

The processor 520 may receive a packet-in message from the first access point 220 via the communication module 500 and an OF-RS message corresponding to the mobile node 240. For example, the packet-in-first message of the first access point 220 may correspond to the mobile node 240 that has not performed packet communications with another access point. In addition, the OF-RS message corresponding to the mobile node 240 may be the one transmitted by the first access point 220 in response to the RS message that the mobile node 240 delivered to the first access point 220.

The processor 520 may determine whether BCE information of the corresponding mobile node 240 exists among the BCE information corresponding to the plurality of mobile nodes 240 stored in the BCE database. If there is no matching BCE information stored in the BCE database with the corresponding mobile node 240, the processor 520 may generate the BCE information of the corresponding mobile node 240.

At this time, the BCE information may be generated based on the information of the mobile node 240 included in the packet-wise message. For example, the BCE information may include the identifier of the mobile node 240, the HNP information corresponding to the mobile node 240, and the identifier of the first access point 220 that carried the packet-in-message.

The processor 520 may update the BCE information of the mobile node 240 if there is information matching the corresponding mobile node 240 among the BCE information previously stored in the BCE database.

The processor 520 may store the BCE information corresponding to the mobile node 240 in the BCE database. In addition, the processor 520 may forward the packet-out message corresponding to the packet-in-message and the OF-RA message corresponding to the OF-RS message to the first access point 220 through the communication module 500.

After receiving the OF-RA message from the controller 210, the first access point 220 may forward the RA message corresponding to the OF-RA message to the mobile node. And the mobile node may exchange packets through the first access point 220. [

On the other hand, when the mobile node 240 moves to the coverage of the second access point 230, the first access point 220 may deliver the packet_in message to the controller 210. At this time, the packet_in message may be to inform the controller 210 that the handover of the mobile node 240 can be performed.

The processor 520 may receive the packet of the first access point 220 via the communication module 500. The processor 520 may then perform DeReg PBU and DeReg PBA corresponding to the mobile node 240 to update the BCE information corresponding to the mobile node 240. [

The processor 520 may generate a packet-out message in response to the packet-in-message received from the first access point 220. The processor 520 may then forward the packet-out message to the first access point 220.

When the mobile node 240 approaches the coverage 290 of the second access point 230 to be handed over, the mobile node 240 may forward the RS message to the second access point 230. And the second access point 230 may forward the OF-RS message and the packet-ID message corresponding to the RS message to the controller 210.

The processor 520 may receive the packet-in-OF-message and the OF-RS message from the second target access point via the communication module 500.

The processor 520 may then update the BCE information corresponding to the mobile node 240. For example, the processor 520 may change the information corresponding to the access point in the BCE information of the mobile node 240 from the identifier of the first access point 220 to the identifier of the second access point 230, Can be updated.

The processor 520 may forward the packet-out message and the OF-RA message to the second access point 230.

The second access point 230 may forward the RA message corresponding to the OF-RA message to the mobile node 240. And the mobile node 240 may perform data communication with the second access point 230 through packet exchange.

Meanwhile, the processor 520 may exchange messages with the first access point 220 and the second access point 230 based on the open flow protocol. For example, the packet_in message, the packet_out message, the OF_RS message, and the OF_RA message described above may be based on an open flow protocol.

Next, a control method and a handover method in the proxy mobile IPv6-based controller 210 according to an embodiment of the present invention will be described with reference to FIG. 6 and FIG.

6 is a flowchart illustrating a control method in a controller 210 based on a proxy mobile IPv6 according to an exemplary embodiment of the present invention.

The controller 210 may receive a packet-in message from the access point and an OF-RS message corresponding to the mobile node 240. The controller 210 then determines whether BCE information corresponding to the mobile node 240 exists in the BCE database. At this time, the OF-RS message may be generated in response to the RS message received from the mobile node 240 by the access point (S600).

If the BCE information corresponding to the mobile node 240 does not exist, the controller 210 generates BCE information corresponding to the mobile node 240 based on the packet-received message from the access point (S610).

Then, the controller 210 delivers the OF-RA message and the packet_out message to the access point (S620).

7 is a flowchart of a handover method in a proxy mobile IPv6-based controller 210 according to an embodiment of the present invention.

The controller 210 generates a packet_out message in response to a packet_in message received from an access point connected to the mobile node 240 (S700). At this time, the OF-RS message corresponding to the handover target access point may be generated based on the RS message that the mobile node 240 transmits to the handover target access point.

The controller 210 may then perform a DeReg PBU and DeReg PBA corresponding to the mobile node 240 based on the packet-in-message received from the access point associated with the mobile node 240.

Then, the controller 210 delivers the generated packet_out message to the connected access point (S710).

Upon receipt of the packet_in message and the OF-RS message from the handover target access point, the controller 210 updates the BCE information corresponding to the mobile node 240 stored in the BCE database (S720).

After the step of updating the BCE information, the controller 210 transmits a packet_out message and an OF-RA message to the handover target access point (S730).

The controller 210 and the controller 210 of the proxy mobile IPv6-based control and handover method according to an embodiment of the present invention can perform data communication without the bidirectional tunnel by the mobile node 240. Therefore, the control and handover method of the controller 210 based on the proxy mobile IPv6, and the controller 210 can reduce the signaling cost of creating a bidirectional tunnel.

In addition, the controller 210 and the controller 210 based on the proxy mobile IPv6 can control the BCE information managed by the MAG and the LMA by the controller 210 in a coordinated manner. Therefore, the control and handover method of the controller 210 based on the proxy mobile IPv6 and the controller 210 can reduce the handover delay time and the handover cost.

One embodiment of the present invention may also be embodied in the form of a recording medium including instructions executable by a computer, such as program modules, being executed by a computer. Computer readable media can be any available media that can be accessed by a computer and includes both volatile and nonvolatile media, removable and non-removable media. The computer-readable medium may also include computer storage media. Computer storage media includes both volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer readable instructions, data structures, program modules or other data.

While the methods and systems of the present invention have been described in connection with specific embodiments, some or all of those elements or operations may be implemented using a computer system having a general purpose hardware architecture.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

200: Proxy Mobile IPv6 Domains
210:
220: first access point
230: second access point
240: mobile node

Claims (14)

In a Proxy Mobile IPv6-based controller,
A communication module for performing data communication with a plurality of access points,
A BCE database for storing binding cache entry (BCE) information,
The control program stores the memory and
And a processor for executing the control program,
The processor generates a packet_out message based on a packet_in message received from an access point connected to the mobile node in accordance with execution of the control program,
Transmits the generated packet_out message to an access point connected to the mobile node,
Updates the BCE information corresponding to the mobile node based on a packet_in message received from the handover target access point and an open flow router solicitation (OF-RS) message based on the open flow protocol,
(OP-RA) message based on a packet-out message and an open-flow protocol to the handover target access point so that the handover target access point exchanges a packet with the mobile node,
The OF-RS message corresponding to the handover target access point is converted from the RS message transmitted by the mobile node to the handover target access point based on the TCP / IP protocol, and the information of the mobile node and the mobile node Wherein the OF-RA message is generated in response to the OF-RS message and is converted into an RA message based on the TCP / IP protocol by the handover target access point, Lt; / RTI > The method according to claim 1,
Wherein a packet-in message received from the connected access point and a packet-received message from the handover target access point comprise an identifier of the mobile node. The method according to claim 1,
Wherein the processor updates information corresponding to the connected access point included in the BCE information corresponding to the mobile node to information corresponding to the handover based on a packet_in message received from an access point connected to the mobile node, controller. The method according to claim 1,
Wherein the BCE information corresponding to the mobile node comprises an identifier of the mobile node, home network prefix (HNP) information corresponding to the mobile node, and an identifier of an access point associated with the mobile node. 5. The method of claim 4,
The processor identifies an identifier of an access point connected to the mobile node included in the BCE information corresponding to the mobile node based on the packet_in message received from the handover target access point and the OF- To the identifier of the access point. The method according to claim 1,
Wherein the processor determines whether BCE information corresponding to the mobile node is included in the BCE database upon receipt of a packet-in message and an OF-RS message corresponding to the mobile node from the access point,
If the BCE information corresponding to the mobile node is not included in the BCE database, generates BCE information corresponding to the mobile node based on the packet-in-message and instructs the access point to exchange packets with the mobile node And delivers the packet-out message and the OF-RA message to the handover target access point. The method according to claim 6,
Wherein the processor, when the BCE corresponding to the mobile node is included in the BCE database, transmits the OF-RA message and the packet_out message to the access point after updating the BCE corresponding to the mobile node. . The method according to claim 6,
The processor performing data communication with the plurality of access points based on an open flow protocol. delete A control method in a proxy mobile IPv6-based controller,
Upon receiving a packet_in message from the access point and an open flow router solicitation (OF-RS) message based on the open flow protocol corresponding to the mobile node, it is checked whether BCE information corresponding to the mobile node exists in the binding cache entry ;
Generating BCE information corresponding to the mobile node based on a packet_in message received from the access point when BCE information corresponding to the mobile node does not exist; And
Forwarding an open flow router advertisement (OF-RA) message and a packet-out message based on an open flow protocol to the access point,
Wherein the OF-RS message corresponding to the mobile node is a conversion from the RS message received by the access point based on the TCP / IP protocol from the mobile node, and the information of the mobile node and the destination node corresponding to the mobile node Wherein the OF-RA message is generated in response to the OF-RS message and is converted to an RA message based on the TCP / IP protocol by the access point to be delivered to the mobile node Way. A method for handover in a proxy mobile IPv6 based controller,
Generating a packet_out message in response to a packet_in message received from an access point connected to the mobile node;
Delivering the generated packet_out message to the connected access point;
Updating the BCE information corresponding to the mobile node stored in the binding cache entry (BCE) database upon receipt of a packet_in message and an open flow router solicitation (OF-RS) message based on the open flow protocol from the handover target access point ; And
And forwarding a packet-out message and an open flow router advertisement (OF-RA) message based on an open flow protocol to the handover target access point after the step of updating the BCE information,
The OF-RS message corresponding to the handover target access point is converted from the RS message transmitted by the mobile node to the handover target access point based on the TCP / IP protocol, and the information of the mobile node and the mobile node Wherein the OF-RA message is generated in response to the OF-RS message and is converted into an RA message based on the TCP / IP protocol by the handover target access point, To the handover method of the controller. 12. The method of claim 11,
Prior to transmitting a packet-out message to an access point connected to the mobile node,
And updating the information corresponding to the connected access point included in the BCE information corresponding to the mobile node with information corresponding to the handover based on the packet_in message received from the access point connected to the mobile node A method of handover of a controller. A computer-readable recording medium recording a program for performing the method according to any one of claims 10 to 12 on a computer. The method according to claim 1,
Wherein the controller itself exchanges a DeReg delegation proxy binding update (DePeg PBU) message and a DeReg PBA (deregister proxy binding acknowledgment) message, and updates the BCE information based on the DeReg PBU message and the DeReg PBA message.

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