KR100932280B1 - How to Provide Mobility Support Between Networks - Google Patents

Abstract

The present invention is a method for providing mobility for a terminal without a mobile IP function to perform authentication with the first communication network using the identifier of the terminal to support mobility between communication networks, and after performing authentication, the MAC of the terminal (MAC) Delivers the router discovery message of the first communication network including the address) to the control station of the first communication network. Then, using the identifier of the terminal as a key, a message including prefix information assigned by the local mobility control manager is received from the control station to set an IP address. When the terminal accesses the new second communication network, authentication is performed with the second communication network by using the identifier of the terminal. After authentication with the second communication network is performed, a message including prefix information of the terminal assigned by the local mobility control manager is received from the router of the second communication network in a unicast manner to provide IP mobility support service of the terminal. .

Broadband Wireless Access Network, WLAN Network, Prefix, Router, Identifier

Description

How to Provide Mobility Support Between Networks {METHOD FOR SUPPORTING MOBILITY BETWEEN COMMUNICATION SYSTEMS}

The present invention relates to a method for supporting mobility between communication networks, and more particularly, to a method for providing support for IP (Internet Protocol) mobility support based on proxy MIP between a broadband wireless access system and a wireless local area network system. It is about.

Generally used IP address has the characteristics of locality to know the region to which the terminal belongs and uniqueness to identify the terminal.

Due to the characteristics of the IP address, when the current terminal moves from the point of access to another point, the feature of locality can no longer be maintained, and thus continuity of services cannot be guaranteed. In order to solve this problem, client mobile IPv6 (CMIP) has been proposed in the IPv6 protocol, and standardization of proxy MIPv6 (PMIPv6, PMIP) has been progressed.

In this case, the PMIP is a method for providing IP mobility to a terminal having only a general IPv6 protocol function which does not include a module for providing IP mobility to the terminal.

As such, PMIP currently supports only Per-MN-Prefix policy in dedicated link environment and does not support Shared-Prefix policy in shared link environment. For this reason, the terminal may be provided with continuous IP connection service in a broadband wireless access network or 3GPP (3GPP) network, which is a dedicated link environment of PMIP, but moves to a mobile communication network such as a wireless LAN using a shared link beyond the dedicated link. In some cases, there is a problem in that continuous IP mobility support service cannot be provided.

The technical problem to be achieved by the present invention is to provide a continuous IP mobility support service regardless of the movement of the terminal.

In order to solve this problem, in a method in which a terminal is provided with mobility between a first communication network and a second communication network, performing authentication with the first communication network using an identifier of the terminal, after performing the authentication, the terminal Delivering a router discovery message of the first communication network including a MAC address of the first communication network to a control station of the first communication network, the prefix information being assigned by a local mobility control manager according to an identifier of the terminal; Receiving a message from the control station, performing authentication with a second communication network using an identifier of the terminal, and after performing authentication with the second communication network, the terminal of the terminal assigned by the local mobility control manager. Receiving from the router of the second communication network a message containing the prefix information.

According to another aspect of the present invention, in the method for supporting mobility between the first communication network and the second communication network in the local mobility control manager of the first communication network, the first message including the identifier of the terminal is sent to the first communication network. Receiving from a control station, assigning prefix information to the terminal based on the identifier of the terminal, delivering a second message including the assigned prefix information to the control station, comprising the identifier of the terminal Receiving a third message from a router of the second communication network, retrieving the prefix information allocated by the first communication network based on the identifier of the terminal, and transferring the retrieved prefix information to the router; do.

According to an embodiment of the present invention, even if a terminal is moved to a wireless LAN network such as a mobile communication network out of a broadband wireless access network or a 3GPP network, which is a dedicated link environment, a continuous IP mobility support service may be provided without setting a new network address. That is, regardless of the movement of the terminal can provide a continuous IP mobility support service.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

In the present specification, a terminal is a portable subscriber station (PSS), a mobile terminal (MT), a subscriber station (SS), a mobile station (MS), user equipment (User Equipment). It may also refer to a user equipment (UE), an access terminal (AT), and the like, and may include all or some functions of a mobile terminal, a subscriber station, a portable subscriber station, a user device, and the like.

In the present specification, a base station (BS) and an access point (access point, AP) are a radio access station (Radio Access Station, RAS), a Node B (Node B), a base transceiver station (Base Transceiver Station, BTS), MMR ( Mobile Multihop Relay) -BS and the like, and may include all or part of functions such as a radio access station, a NodeB, a base transceiver station, and an MMR-BS.

Hereinafter, a method of providing a continuous IP mobility support service regardless of the location of a terminal according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3.

1 is a diagram illustrating a broadband wireless access network and a wireless LAN network according to an embodiment of the present invention.

As shown in FIG. 1, the broadband wireless access network includes terminals 100a and 100b, base stations 200a and 200b, control stations 300a and 300b, authentication, authorization and accounting (AAA) server 400, and local mobility control. It includes an administrator (Local Mobility Agent, 410).

The terminals 100a and 100b include a broadband wireless access interface and a wireless LAN access interface. In addition, the terminals 100a and 100b may move between cells in the base stations 200a and 200b, between the base stations 200a and 200b and between the control stations 300a and 300b during service execution.

The base stations 200a and 200b control the terminals 100a and 100b in a wireless section, and are disposed in an urban area to manage the terminals 100a and 100b in the area.

The control stations 300a and 300b directly connect to the broadband wireless access network, and control the base stations 200a and 200b by wire. The control stations 300a and 300b have a hierarchical structure for centrally managing the base stations 200a and 200b. In this case, the control stations 300a and 300b include a Mobility Access Gateway (MAG) functional module of PMIP, and perform a function for providing IP mobility support service of the terminals 100a and 100b. The control stations 300a and 300b operate in conjunction with the local mobility control manager 410 and the AAA server 400 for user authentication for the IP mobility support service. In addition, the control stations 300a and 300b control radio resource states of cells in the base stations 200a and 200b and perform control for quality of service.

The WLAN network includes a terminal 100c, an access point 500A, 500b, a router 600a, 600b, and an AAA server 700.

The access points 500a and 500b include a wireless LAN interface and control the terminal 100c.

The routers 600a and 600b directly access the WLAN network and control the access points 500a and 500b. In addition, the routers 600a and 600b include a MAG function module of PMIP, and when the user of the broadband wireless access network service requests the IP mobility support service, the router 600a and 600b provide the service in conjunction with the local mobility control manager 410.

The AAA server 700 performs wireless LAN network user authentication in a wireless LAN network, performs user authentication in connection with the AAA server 400 of a broadband wireless access network, and receives user information when the broadband wireless access network subscriber is authenticated.

 At this time, the information elements (Attribute Value Pair, AVP) added during authentication of the user subscribed to the broadband wireless access network in the WLAN network are shown in Table 1.

In the embodiment of the present invention, the control station (300a, 300b) and the AAA server 400, the access point (500a, 500b) and the AAA server 700 and the AAA server 400 and the AAA server 700 at the time of user authentication The Radius or Diameter protocol can be used, and the information elements shown in Table 1 are added according to the protocol upon successful authentication of the user.

The LMA-FQDN (Local Mobility Agent-Full Qualified Domain Name) is a domain address of the local mobility control manager 410 assigned to the terminal, and the MN-MAC-ID is an IEEE MAC having a terminal composed of 6 bytes in ASCII format. Institute of Electrical and Electronics Engineers Media Access Control.

2 is a diagram illustrating a procedure for performing an IP mobility support service by accessing a WLAN network after the release of the broadband wireless access network according to an embodiment of the present invention.

In the embodiment of the present invention, the IP mobility support service will be described using the terminal 100a among the terminals 100a and 100b of the broadband wireless access network.

As shown in FIG. 2, the terminal 100a performs user authentication to access the broadband wireless access network (S300). The user authentication performed here is based on the Extensible Authentication Protocol (EAP) and uses a network access identifier (NAI) as an identifier.

Assuming that the control station 300a and the AAA server 400 operate in the Radius protocol, the control station 300a operates as an authentication client for authentication, and the PKMv2 authentication EAP message (Authenticated Extensible Authentication) transmitted from the terminal 100a. Protocol message) to the AAA server 400. Then, the AAA server 400 operates as a node that performs authentication for the terminal 100a. If the authentication is successful, the AAA server 400 transmits an access-accept message to the control station 300a at the end of the authentication. (S301). At this time, the access-permit message includes the domain address LMA-FQDN of the local mobility control manager 410 which performs location management of the terminal 100a that is currently requesting access for the operation of the PMIP, and the address of the terminal 100a in the broadband wireless access network. MN-MAC-ID indicating that is included.

The control station 300a stores the information of the LMA-FQDN and MN-MAC-ID included in the access-permit message, detects the PKMv2 authentication EAP-Transfer message included in the access-permit message, and transmits the information to the terminal 100a. (S302).

If the authentication is successful, the terminal 100a generates an IPv6 link local address using its MN-MAC-ID or otherwise, and then sends a Router Solicitation (RS) message to find the default router. It transmits to the control station 300a (S303). In this case, the terminal 100a transmits the MAC address to the control station 300a by including its MAC address in the link layer option field of the RS message. Make it possible to distinguish local addresses.

The control station 300a obtains the domain address of the regional mobility control manager 410 using the stored LMA-FQDN information, and sends a PBU message to the regional mobility control manager 410 corresponding to the obtained domain address. Transmit (S304). At this time, the identifier included in the PBU message becomes the NAI of the terminal 100a, and the home network prefix option field value is 0.

The local mobility control manager 410 verifies whether the NAI included in the PBU message belongs to the registered terminal 100a. At this time, if the NAI is of the registered terminal 100a and is not currently in service, the local mobility control manager 410 registers the terminal 100a in the binding cache, allocates one usable prefix information, and then the control station ( Set up a two-way tunnel with 300a). The local mobility control manager 410 registers routing information to be routed to the generated tunnel, and then generates a PBA (Proxy Binding Acknowledge) message including the assigned prefix information and transmits it to the control station 300a (S305).

The control station 300a stores the assigned prefix information by using the home network prefix option field value included in the PBA message, and establishes a bidirectional tunnel with the local mobility control manager 410. The control station 300a then registers the assigned prefix in the routing table to be routed to the generated bidirectional tunnel. The control station 300a transmits a Router Advertisement (RA) message including the assigned prefix information to the terminal 100a (S306). At this time, the terminal 100a generates a network address using the prefix information included in the RA message, and receives a traffic service based on the generated network address.

The terminal 100a first releases the connection with the currently serving broadband wireless access network.

When the connection between the terminal 100a and the broadband wireless access network is released, the control station 300a sets the NAI of the terminal 100a as an identifier, and sends the PBU message having the life time set to 0 to the local mobility control manager 410. By transmitting, the local mobility control manager 410 and the terminal 100a request to disconnect (S307). Then, the local mobility control manager 410 sets the binding expiration timer for the terminal 100a at a predetermined time, and deletes the corresponding tunnel and routing table. The local mobility control manager 410 transmits the PBA message whose life time is set to 0 to the control station 300a (S308). At this time, the control station 300a deletes the corresponding tunnel and writing table.

The terminal 100a connected to the WLAN network interworks with the access points 500a and 500b, the router 600a, the AAA server 700 and the AAA server 400 of the broadband wireless access network through the 802.1X process. User authentication for) is performed (S309).

If authentication for the terminal 100a is successfully performed in the WLAN network, the AAA server 400 of the broadband wireless access network transmits an access-authorization message to the AAA server 700 in the last step of authentication (S310). Then, the AAA server 700 forwards the access-authorization message to the router 600a (S311). At this time, the access-permit message includes the domain address LMA-FQDN of the local mobility control manager 410 which performs location management of the terminal 100a that is currently requesting access for the operation of the PMIP, and the address of the terminal 100a in the broadband wireless access network. MN-MAC-ID indicating that is included.

The router 600a stores the information of the LMA-FQDN and the MN-MAC-ID included in the access-permission message, detects the EAP-Success message included in the access-permission mesh, and transmits the information to the terminal 100a (S312). ).

If the authentication is successful, the terminal 100a generates an IPv6 link local address using its MN-MAC-ID or another method, and then transmits an RS message to the router 600a to find a default router (S313). ). In this case, the terminal 100a includes the MAC address of the link layer option field of the RS message and transmits the MAC address to the router 600a so that the router 600a can distinguish the terminal 100a. . The router 600a stores the link local address of the terminal 100a for use as a destination address when transmitting the RA message.

The router 600a acquires the domain address of the local mobility control manager 410 using the stored LMA-FQDN information, and transmits a PBU message to the regional mobility control manager 410 corresponding to the obtained domain address (S314). . At this time, the identifier included in the PBU message becomes the NAI of the terminal 100a, and the home network prefix option field value is 0.

The local mobility control manager 410 verifies whether the NAI included in the PBU message belongs to the registered terminal 100a. At this time, if the NAI is registered to the terminal 100a, and the terminal 100a is currently in service, the local mobility control manager 410 searches for the information allocated in the broadband wireless access network and finds the bidirectional tunnel to the router 600a. After changing the routing information so that the assigned prefix information can be routed to the changed tunnel, a PBA message is generated and transmitted to the router 600a (S315).

The router 600a stores the assigned prefix information by using the home network prefix option field value included in the PBA message, and establishes a bidirectional tunnel with the local mobility control manager 410. Router 600a then registers the assigned prefix in the routing table to be routed to the generated bidirectional tunnel. The router 600a transmits the RA message including the assigned prefix information to the terminal 100a in a unicast transmission method using the link local address of the terminal 100a as a destination address (S316). In this case, since the prefix information allocated from the router 600a to the terminal 100a is the same as the prefix information used in the broadband wireless access network, the terminal 100a receives the traffic service using the network address used in the broadband wireless access network. Can be.

3 is a diagram illustrating a procedure of performing an IP mobility support service by releasing a connection with a broadband wireless access network after accessing a wireless LAN network according to an embodiment of the present invention.

After the connection to the wireless LAN network according to an embodiment of the present invention, the process of receiving traffic service in the broadband wireless access network (S400-S406) during the procedure of releasing the connection with the broadband wireless access network to perform the IP mobility support service will be described. Since the process is the same as shown in the detailed description thereof will be omitted.

As shown in FIG. 3, the terminal 100a accesses the WLAN network without releasing the connection with the currently serving broadband wireless access network. The terminal 100a connected to the WLAN network interworks with the access points 500a and 500b, the router 600a, the AAA server 700 and the AAA server 400 of the broadband wireless access network through the 802.1X process. User authentication for) is performed (S407).

If authentication for the terminal 100a is successfully performed in the WLAN network, the AAA server 400 of the broadband wireless access network transmits an access-authorization message to the AAA server 700 in the last step of authentication (S408). Then, the AAA server 700 forwards the access-authorization message to the router 600a (S409). At this time, the access-permit message includes the domain address LMA-FQDN of the local mobility control manager 410 which performs location management of the terminal 100a that is currently requesting access for the operation of the PMIP, and the address of the terminal 100a in the broadband wireless access network. MN-MAC-ID indicating that is included.

The router 600a stores the information of the LMA-FQDN and the MN-MAC-ID included in the access-permit message, detects the EAP-Success message included in the access-permit message, and transmits it to the terminal 100a (S410). ).

If the authentication is successful, the terminal 100a generates an IPv6 link local address using its MN-MAC-ID or another method, and then transmits an RS message to the router 600a to find a default router (S411). ). In this case, the terminal 100a includes the MAC address of the link layer option field of the RS message and transmits the MAC address to the router 600a so that the router 600a can distinguish the terminal 100a. . The router 600a stores the link local address of the terminal 100a for use as a destination address when transmitting the RA message.

The router 600a acquires the domain address of the local mobility control manager 410 using the stored LMA-FQDN information, and transmits a PBU message to the local mobility control manager 410 corresponding to the obtained domain address (S412). . At this time, the identifier included in the PBU message becomes the NAI of the terminal 100a, and the home network prefix option field value is 0.

The local mobility control manager 410 verifies whether the NAI included in the PBU message belongs to the registered terminal 100a. At this time, if the NAI is registered to the terminal 100a, and the terminal 100a is currently in service, the local mobility control manager 410 searches for the information allocated in the broadband wireless access network and finds the bidirectional tunnel to the router 600a. After changing the routing information so that the assigned prefix information can be routed to the changed tunnel, a PBA message is generated and transmitted to the router 600a (S413).

The router 600a stores the assigned prefix information by using the home network prefix option field value included in the PBA message, and establishes a bidirectional tunnel with the local mobility control manager 410. Router 600a then registers the assigned prefix in the routing table to be routed to the generated bidirectional tunnel. The router 600a transmits the RA message including the assigned prefix information to the terminal 100a in a unicast transmission method using the link local address of the terminal 100a as a destination address (S414).

Since the terminal 100a has not deleted the binding information from the previous control station 300a, the local mobility control manager 410 deletes the binding information for the terminal 100a from the previous control station 300a. A PBD (Proxy Binding Delete) message is transmitted to the control station 300a (S415).

The control station 300a deletes the binding cache, tunnel, and routing information for the terminal 100a, and transmits a PBDA (Proxy Binding Delete Acknowledge) message indicating that the connection with the broadband wireless access network has been released (S416).

In this case, since the prefix information allocated from the router 600a to the terminal 100a through the RA message is the same as the prefix information used in the broadband wireless access network, the terminal 100a uses the network address used in the broadband wireless access network. You can get services.

 As described above, when the mobile station moves from the broadband wireless access network to the wireless LAN network, the terminal performs the Make-before-break method of first connecting to the wireless LAN network or first releases the connection setting of the broadband wireless access network. Break-before-make method for LAN connection can be performed.

In the exemplary embodiment of the present invention, the first terminal registered in the wireless LAN network receives the continuous IP mobility support service regardless of the movement of the terminal using the prefix information of the RA message transmitted from the broadband wireless access network. The present invention is not limited thereto, and a terminal registering for the first time in a broadband wireless access network may also receive continuous IP mobility support service regardless of the movement of the terminal using the prefix information of the RA message transmitted from the WLAN network.

The embodiments of the present invention described above are not implemented only through the apparatus and the method, but may be implemented through a program for realizing a function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded. Implementation may be easily implemented by those skilled in the art from the description of the above-described embodiments.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1 is a diagram illustrating a broadband wireless access network and a wireless LAN network according to an embodiment of the present invention.

2 is a diagram illustrating a procedure for performing an IP mobility support service by accessing a WLAN network after the release of the broadband wireless access network according to an embodiment of the present invention.

3 is a diagram illustrating a procedure of performing an IP mobility support service by releasing a connection with a broadband wireless access network after accessing a wireless LAN network according to an embodiment of the present invention.

Claims (14)

In the method that the terminal is provided with mobility between the first communication network and the second communication network, Performing authentication with a first communication network using an identifier of the terminal; After performing the authentication, transmitting a router discovery message of the first communication network including a MAC address of the terminal to a control station of the first communication network; Receiving from the control station a message containing prefix information assigned by a local mobility control manager according to the identifier of the terminal; Performing authentication with a second communication network using an identifier of the terminal, and And after performing authentication with the second communication network, receiving a message from the router of the second communication network, the message including the prefix information of the terminal assigned by the local mobility control manager. The method of claim 1, Receiving from the control station, Generating a network address using the prefix information, and And providing a traffic service in the first communication network using the network address. The method of claim 2, Receiving from the router, And providing a traffic service in the second communication network by using the network address. The method of claim 1, Receiving from the router, And forwarding a router discovery message of the second communication network including the MAC address of the terminal to the router of the second communication network. The method of claim 1, The prefix information, And registering in the routing table of the control station to be routed to a bidirectional tunnel established between the local mobility control manager and the control station. The method of claim 5, The prefix information, And registering in the routing table of the router to be routed to a bidirectional tunnel established between the local mobility control manager and the router. The method of claim 1, The first communication network is a broadband wireless access network, the second communication network is a WLAN support method. The method of claim 1, The router, Stores the link local address of the terminal, distinguishes the terminal using the MAC address of the terminal, and transmits a message including the prefix information to the link local address of the terminal as a unicast transmission method. Mobility support method for transmitting to the terminal. A method of supporting mobility between a first communication network and a second communication network in a local mobility control manager of a first communication network, Receiving a first message including an identifier of a terminal from a control station of the first communication network, Allocating prefix information to the terminal based on the identifier of the terminal; Delivering a second message containing the assigned prefix information to the control station, Receiving a third message including an identifier of the terminal from a router of the second communication network, Retrieving prefix information allocated by the first communication network based on the identifier of the terminal, and And forwarding a fourth message including the retrieved prefix information to the router. The method of claim 9, The allocated prefix information and the searched prefix information are the same. The method of claim 9, The first and third messages are proxy binding update (PBU) messages, respectively. Wherein the second and fourth messages are Proxy Binding Acknowledge (PBA) messages, respectively. The method of claim 9, Delivering to the router, Delivering a fifth message to the control station to release a connection between the terminal and the first communication network; and And receiving a sixth message from the control station indicating that the connection between the terminal and the first communication network has been released. The method of claim 9, Delivering to the control station, And registering the prefix information in a routing table of the control station to be routed to a bidirectional tunnel established between the local mobility control manager and the control station. The method of claim 9, Delivering to the router, And registering the prefix information in a routing table of the router to be routed through a bidirectional tunnel established between the local mobility control manager and the router.

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