KR100942647B1 - Mobility management system and mobility management method using host name and rerouting at visited network - Google Patents

Abstract

The present invention relates to a mobility management system and a mobility management method using rerouting in a host name and a destination network. The mobility management system according to the present invention comprises: a first mobility manager in which a first IP address allocated to a mobile terminal by entering a first network is registered; A name server that registers the first IP address and the host name of the mobile terminal from the mobile terminal and transmits the first IP address to the communication terminal according to a request based on the host name from the communication terminal, The communication terminal connects to the mobile terminal belonging to the first network based on the first IP address transmitted from the name server, and the mobile terminal enters a second network while connected to the communication terminal. Receives a second IP address from the second network and notifies the first mobility manager, wherein the first mobility manager is transmitted from the communication terminal to the mobile terminal when the second IP address is notified from the mobile terminal. Data packets destined are routed to the second network so that the mobile terminal Rerouting is performed on the data packet to be receivable.

Description

MOBILITY MANAGEMENT SYSTEM AND MOBILITY MANAGEMENT METHOD USING HOST NAME AND REROUTING AT VISITED NETWORK}

The present invention relates to a mobility management system and a mobility management method, and more particularly, to a mobility management system and a mobility management method on the Internet using a host name of a mobile terminal and rerouting in a visited network.

Guaranteed mobility on the Internet means that a data packet transmitted by a communication terminal, which is the opposite terminal, can be received regardless of the location of the mobile terminal on the network, and communication is not interrupted even during the movement.

Basically, the Internet has a characteristic of a wired network that transmits data between fixed terminals based on a fixed IP (Internet Protocol) address determined by a geopolitical and physical location on a network, such as a public telephone network. In other words, unlike in the case of a mobile phone, in the public telephone network, the mobility of the data terminal on the Internet can not be received by moving a phone to another telephone line during a call and continuing a call or connecting a telephone to another telephone line and receiving a call using an existing telephone number. This is not guaranteed.

This is because phone numbers and IP addresses are network addresses assigned to physical access points between the network and subscribers, unlike mobile communication networks where numbers are assigned to mobile phones themselves.

In relation to the characteristics of the Internet, the Internet Engineering Task Force (IETF), which is in charge of standardizing Internet technology to guarantee mobility on the Internet, has standardized mobile IP (hereinafter referred to as 'MIP'). 1 is a diagram illustrating a conventional Internet structure supporting MIP.

First, the main terms defined in MIP and their meanings are defined as follows.

* Mobile Node: A terminal that is the target of mobility management and can change the network connection point.

* Correspondent Node: Terminal that wants to communicate with mobile terminal

* Home Network: The network to which the mobile terminal originally belonged

* Home Address: IP address belonging to the residential network, the address given to the mobile terminal

* Foreign Network: Foreign network to which mobile terminal is currently connected

* Care-of Address: An IP address belonging to the visited network, which is given to the mobile terminal in the visited network when the mobile terminal is connected to the visited network.

* Home Agent: Node that manages location information of mobile terminal in residential network and relays data packet from communication terminal to mobile terminal when mobile terminal moves to other network

In general, MIP supports mobility through a dual address system. The residential address is a fixed address assigned to the mobile terminal in the residential network to satisfy that a connection-oriented session established once must maintain the same IP address for that set time. The whole school address is assigned by the visited network as the address for delivering the data packet to the moved area when the mobile terminal moves. Therefore, the whole school address keeps changing as the mobile terminal moves and the destination network changes, ensuring the connection between the communication terminal and the mobile terminal.

In more detail with reference to FIG. 1, when the mobile terminal 120 moves and enters a specific visited network (hereinafter, referred to as 'first visited network FN-a'), the first visited network FN- From a) is assigned a school address (hereinafter referred to as 'first school address'), the mobile terminal 120 registers the first school address to the residence manager 150.

The communication terminal 110 that wants to connect with the mobile terminal 120 does not have information about the current location of the mobile terminal 120 when it wants to communicate with the mobile terminal 120. ) Sends the data packet to the assigned IP address.

When the data packet transmitted from the communication terminal 110 arrives in the residential network HN, the residence manager 150 intercepts the data packet and adds the first whole school address to the packet header of the data packet to reroute back to the Internet I. Rerouting). Here, encapsulation means that the first whole address is appended to the packet header of the data packet.

Data packets encapsulated by the residence manager 150 and rerouted to the Internet I are routed to the first destination network FN-a by the first school address, and the first destination network FN-a. Is received by the mobile terminal 120 entering. As a result, the data packet from the communication terminal 110 passes through the process R1 arriving at the mobile terminal 120 via the route R1 via the residence manager 150, from the residence manager 150 to the mobile terminal. The process of arriving at 120 is called tunneling.

When the data packet arrives at the mobile terminal 120, the first school address added by the residence manager 150 is removed and processed by the application layer based on the residence address which is the original destination address.

Here, when the mobile terminal 120 continues to move during communication and enters another visited network (hereinafter referred to as 'second visited network FN-b'), the mobile terminal 120 moves to a location of the second visited network FN-b. Another corresponding school address (hereinafter referred to as 'second second school address') is assigned from the second visiting network FN-b.

At this time, the mobile terminal 120 registers the second school address assigned from the second visited network FN-b to the residence manager 150 as in the case of the first school address. When the second school address is registered in the residence manager 150, the residence manager 150 attaches the second school address to the packet header of the data packet transmitted from the communication terminal 110 instead of the first school address. By sending the packet, a new route R2 shown in FIG. 1 is formed to deliver the data packet to the mobile terminal 120 belonging to the second visited network FN-b.

At this time, when the data packet arrives at the mobile terminal 120, as described above, the second school address is removed and the data packet is processed at the application layer based on the residential address which is the original destination address. As a result, in the application layer, even if the mobile terminal 120 moves and is changed from the first visited network FN-a to the second visited network FN-b, the packets are processed based on the residential address. Although the address of the application layer does not change even when the location of the server 120 is changed, connection-based sessions such as Transmission Control Protocol (TCP) can be maintained.

Although the mobility of the mobile terminal 120 is guaranteed in the MIP through the above process, all data packets are routed through the route (R1 and R2 of FIG. 1) via the residence manager 150 to have a structural disadvantage. do.

For example, when the communication terminal 110 and the mobile terminal 120 are located in the same building, and the residence manager 150 is located far from the building, the data packets may be transferred to the residence manager 150 located at the remote location. The mobile terminal 120 arrives at the destination. This phenomenon is called triangular routing, which increases the delay of data packets and the load on the network.

In order to compensate for the triangular routing phenomenon, a method called route optimization has been proposed. In the route optimization method, after the communication terminal 110 and the mobile terminal 120 are connected, the communication terminal 110 informs the communication terminal 110 of information about the whole school address so that the communication terminal 110 performs encapsulation. The packet is transmitted directly to the mobile terminal 120. Through this, an optimum route is established between the communication terminal 110 and the mobile terminal 120 so that data packets are delivered. However, the route optimization method has a disadvantage in that the IP layer must be changed so that the communication terminal 110 has a function of encapsulating data packets.

Meanwhile, the Internet Engineering Task Force (IETF) also proposes a mobility support method using another protocol, Session Initiation Protocol (SIP).

SIP has a function of supporting a person's mobility as a protocol for transmitting and receiving control signals for generating and releasing a multimedia call. That is, when the mobile terminal 120 using the SIP moves out of the residential network HN to another visiting network, new location information is registered in the SIP server.

And when the communication terminal 110 wants to communicate with the mobile terminal 120, the communication terminal 110 first informs the SIP server about the current position of the mobile terminal, for example, of the mobile terminal 120 registered in the current SIP. After inquiring the school address, a session may be established between the communication terminal and the mobile terminal 120 by requesting the multimedia call to be set up based on the current location of the mobile terminal 120. Through this, the triangular routing phenomenon of MIP does not occur in SIP.

In addition, when the mobile terminal 120 moves to another visited network to obtain a new school address while the communication is in progress, the mobile terminal 120 sends the new terminal address, which is the new IP address, to the communication terminal 110. Accordingly, it is possible for the communication terminal 110 to send a data packet to the new whole address of the mobile terminal 120. Accordingly, in SIP, some mobility is guaranteed during the call, but the two IP addresses, i.e., two whole school addresses are different, have a fundamental problem that mobility of connection-based sessions such as TCP cannot be guaranteed.

In order to meet the above technical demands, the present invention guarantees mobility of connection-based sessions such as TCP, while minimizing triangular routing, thereby reducing mobility of data packets and reducing network load. Its purpose is to provide a system and mobility management method.

According to an aspect of the present invention, there is provided a mobile device comprising: a first mobility manager in which a mobile station enters a first network and is assigned a first IP address; A name server that registers the first IP address and the host name of the mobile terminal from the mobile terminal and transmits the first IP address to the communication terminal according to a request based on the host name from the communication terminal, The communication terminal connects to the mobile terminal belonging to the first network based on the first IP address transmitted from the name server, and the mobile terminal enters a second network while connected to the communication terminal. Receives a second IP address from the second network and notifies the first mobility manager, wherein the first mobility manager is transmitted from the communication terminal to the mobile terminal when the second IP address is notified from the mobile terminal. Destined data packets are rerouted to the second network to The terminal is achieved by a mobility management system, characterized in that for performing the encapsulation for the data packet to be received.

The matching between the host name and the first IP address may be implemented by any one of a session initiation protocol (SIP) scheme and a dynamic domain name system (DNS) scheme.

And a second mobility manager for registering the second IP address from the mobile terminal entering the second network; The mobile terminal registers the second IP address in the second mobility manager when entering the second network when the communication terminal is disconnected from the communication terminal, and the first IP address registered in the name server is determined by the mobile terminal. The second IP address and the host name may be registered in the name server so as to be changed to a second IP address, and the registration as the first mobility manager may be released.

And a second mobility manager for registering the second IP address from the mobile terminal entering the second network; The mobile terminal registers the second IP address with the second mobility manager when the connection with the communication terminal is released after being connected with the communication terminal through rerouting of the first mobility manager. The second IP address and the host name may be registered in the name server so that the first IP address registered in the name server is changed to the second IP address, and the registration as the first mobility manager may be released. .

The apparatus may further include a first network manager and a second network manager allocating the first IP address and the second IP address to the mobile terminals entering the first network and the second network, respectively.

The first network manager and the second network manager may allocate the first IP address and the second IP address to the mobile terminal according to a dynamic host configuration protocol (DHCP).

On the other hand, the object is a mobility management method between the mobile terminal and the communication terminal to be interconnected according to another embodiment of the present invention, when the mobile terminal enters a first network, the first IP assigned from the first network Registering an address from the mobile terminal to a first mobility manager; Registering the first IP address and the host name with a name server from the mobile terminal; The communication terminal accessing the name server to request the first IP address based on the host name, and transmitting the first IP address from the name server to the communication terminal; Connecting the communication terminal with the mobile terminal belonging to the first network based on the first IP address transmitted from the name server; When the mobile terminal enters a second network while connected to the communication terminal, assigning a second IP address to the mobile terminal from the second network; Notifying the first mobility manager of the second IP address from the mobile terminal; When the second IP address is notified from the mobile terminal, the first mobility manager transmits a data packet transmitted from the communication terminal to the mobile terminal to be rerouted to the second network so that the mobile terminal can receive it. May comprise performing encapsulation.

The matching between the host name and the first IP address may be implemented by any one of a session initiation protocol (SIP) scheme and a dynamic domain name system (DNS) scheme.

Here, when the mobile terminal enters the second network when the connection between the mobile terminal and the communication terminal is released, registering the second IP address from the mobile terminal to the second mobility manager; Registering the second IP address and the host name with the name server from the mobile terminal such that the first IP address registered with the name server is changed to the second IP address; The method may further include canceling registration with the first mobility manager according to a request of the mobile terminal.

The method may further include: registering the second IP address with the second mobility manager from the mobile terminal when the connection between the mobile terminal and the communication terminal is released during the encapsulation process; Registering the second IP address and the host name with the name server from the mobile terminal such that the first IP address registered with the name server is changed to the second IP address; The method may further include canceling registration with the first mobility manager according to a request of the mobile terminal.

The first IP address and the second IP address may be allocated to the mobile terminal according to a dynamic host configuration protocol (DHCP).

According to the present invention, a triangular routing phenomenon is achieved by a direct communication address assigned from a visited network to which a mobile terminal currently belongs is registered in a name server, and a communication terminal directly connects to the mobile terminal through a whole school address registered in a name server. As a result, data packet propagation delay and network load can be reduced.

In addition, even if the mobile network is moved and the destination network is changed, the mobility manager in the previous destination network is turned into tunneling, thereby minimizing the negative effects even when triangular routing occurs, and providing mobility of connection-based sessions such as TCP. It can be guaranteed.

Further, even when the mobile terminal moves between destination networks, the previous destination network manages tunneling, thereby reducing the hand-off time required for the mobile terminal to move between networks. .

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

2 is a diagram illustrating a configuration of a mobility management system according to the present invention. The mobility management system according to the present invention manages mobility between the mobile terminal 20 and the communication terminal 10 on the Internet I by using the host name of the mobile terminal 20 and rerouting in the visited network. do.

Referring to FIG. 2, the mobility management system according to the present invention includes a mobile terminal 20, a communication terminal 10, a first mobility manager 30a, and a name server 50.

The mobile terminal 20 is a terminal which is a target of mobility management in the mobility management system according to the present invention and is a terminal capable of changing a network connection point, and the communication terminal 10 is a terminal that wants to connect with the mobile terminal 20.

The mobile terminal 20 also has a host name that is its own unique identifier. When the mobile terminal 20 enters the first network FN-1 or the second network FN-2, an IP address is allocated from each network.

Here, the IP address is assigned from a network administrator who manages location information of the mobile terminal 20 in the service area of each network on each network. Here, the network manager according to the present invention is provided in the form of a DHCP server to assign an IP address to the mobile terminal 20 according to the Dynamic Host Configuration Protocol (DHCP).

Hereinafter, a network where the mobile terminal 20 is initially located is called a first network FN-1, and a network where the mobile terminal 20 moves and newly enters is called a second network FN-2. The network managers belonging to the network FN-1 and the second network FN-2, respectively, are referred to as the first network manager 40a and the second network manager 40b, and the first network manager 40a and the second network. The address assigned to the mobile terminal 20 from the manager 40b is defined and described as a 1st IP address and a 2nd IP address, respectively.

Meanwhile, when the mobile terminal 20 enters the first network FN-1, the first mobility manager 30a receives the first IP address allocated from the first network manager 40a from the mobile terminal 20. Register.

The mobile terminal 20 registers the first IP address and its host name assigned by the first network manager 40a in the name server 50. The name server 50 transmits the IP address of the mobile terminal 20 to the communication terminal 10 when a request for the current IP address of the mobile terminal 20 is received from the communication terminal 10.

In this case, the communication terminal 10 requests the name server 50 for the IP of the mobile terminal 20 by using the host name of the mobile terminal 20. The first mobility manager 30a and the name server 50 may request the IP of the mobile terminal 20. And a method of matching the host name and the first IP address (or the second IP address to be described later) in the communication terminal 10, that is, the host name and the first IP address (or the second IP address to be described later) to the name server 50. Is registered and the communication terminal 10 acquires the first IP address (or the second IP address to be described later) based on the host name in a Session Initiation Protocol (SIP) scheme and a dynamic DNS. Domain Name System) can be implemented by any one of the methods. In addition, if the communication terminal 10 is a protocol capable of obtaining a first IP address (or a second IP address to be described later), other protocols may be applied, and it is natural that a new protocol may be used if necessary.

As described above, the communication terminal 10 receives the first IP address which is the current address of the mobile terminal 20 from the name server 50 based on the host name of the mobile terminal 20, and the name server 50. The mobile station 20 connects to the mobile terminal 20 belonging to the first network FN-1 based on the first IP address transmitted from the first IP address. That is, the communication terminal 10 sets the data packet on the Internet I using the destination address to be recorded in the packet header of the data packet (or signal packet, hereinafter same) transmitted to the mobile terminal 20 as the first IP address. Send it out.

The data packet sent from the communication terminal 10 has its destination address set to the first IP address, and is directly transmitted to the mobile terminal 20 belonging to the first network FN-1, whereby the mobile terminal 20 The optimum route R4 is formed at the initial connection of the communication terminal 10 with each other.

On the other hand, when the mobile terminal 20 enters the second network FN-2 by moving in the state connected to the communication terminal 10 through the above-described method, the mobile terminal 20 enters the second network FN. A second IP address is allocated from the second network manager 40b of -2).

At this time, the mobile terminal 20 notifies the first mobility manager 30a of the second IP address allocated from the second network manager 40b. When the first mobility manager 30a is notified of the second IP address from the mobile terminal 20, the first mobility manager 30a is transmitted from the communication terminal 10 to the mobile terminal 20 moved to the second network FN-2. Rerouting is performed on data packets destined.

That is, the first mobility manager 30a receives a communication terminal after the mobile terminal 20 enters the second network FN-2 and is notified of the second IP address allocated from the second network FN-2. 10) Intercept the data packet sent from the first network (FN-1) and attach the second IP address to the packet header. That is, the first mobility manager 30a performs encapsulation.

Then, when the first mobility manager 30a sends the encapsulated data packet back to the Internet I, the data packet is routed to the second network FN-2 by the second IP address and eventually the second network ( Since the mobile terminal 20 entering the FN-2 receives the data packet, mobility on the Internet I is guaranteed. In this case, the mobile terminal 20 removes the second IP address attached to the received data packet and processes the application layer based on the first IP address, which is a destination address at the time of initial connection, thereby transmitting TCP (Transmission Control Protocol) and the like. This allows you to maintain the same connection oriented session.

Through the above configuration, the communication terminal 10 obtains the first IP address which is the current location of the mobile terminal 20 registered in the name server 50 by using the host name, thereby optimally matching the mobile terminal 20 with the mobile terminal 20. By connecting through the route (R3), it is possible to prevent the triangular routing phenomenon that occurs in the conventional MIP, significantly reducing the delay of data packet transmission and the network load.

In addition, when the mobile terminal 20 and the communication terminal 10 are connected, the network is changed by moving the mobile terminal 20, that is, the first network FN-1 to the second network FN-2. Even if the location is changed, the first mobility manager 30a of the first network FN-1 adjacent to the second network FN-2 manages the tunneling, so that it requests rerouting and executes it. It also reduces the hand-off time it takes.

In addition, the tunneling of the first mobility manager 30a is performed while reducing the connection through the routes R3 and R4, the delay of data packet transmission, the reduction of network load, and the hand-off time. Tunneling enables connection-oriented sessions such as Transmission Control Protocol (TCP).

Meanwhile, the mobility management system according to the present invention may include a second mobility manager 30b as shown in FIG. 2. The second mobility manager 30b moves the mobility of the mobile terminal 20 when the mobile terminal 20 moves back to another network (for example, a third network) after entering the second network FN-2. Manage.

First, when the mobile terminal 20 enters the second network FN-2 in a state in which the mobile terminal 20 is disconnected from the communication terminal 10, the mobile terminal 20 is assigned by the second network manager 40b. 2 Register the IP address in the second mobility manager 30b. Herein, when the mobile terminal 20 enters the second network FN-2, the mobile terminal 20 notifies the first mobility manager 30a to release the registration to the second mobility manager 30b. In addition, the process of assigning the second IP address to the mobile terminal 20 by the second network manager 40b is the same as the process of assigning the first IP address to the mobile terminal 20.

The mobile terminal 20 registers its host name and the second IP address in the name server 50. At this time, the name server 50 changes the first IP address corresponding to the host name of the pre-registered mobile terminal 20 to the second IP address registered from the second mobility manager 30b.

Through this process, when the mobile terminal 20 enters the second network FN-2, a second IP address corresponding to the second network FN-2 is registered in the name server 50, When the connection from the communication terminal 10 is attempted while the mobile terminal 20 belongs to the second network FN-2, the mobile terminal 20 moves in the same manner as the case of belonging to the first network FN-1 described above. The terminal 20 and the communication terminal 10 can communicate with each other. As such, when the connection initiated in the second network FN-2 continues until the mobile terminal 20 moves back to another network (eg, the third network), the first mobility manager 30a is connected to the second network. As in the rerouting (FN-2), the second mobility manager 30b of the second network FN-2 reroutes to the third network to support mobility management.

Meanwhile, after the mobile terminal 20 is connected to the communication terminal 10 in a state belonging to the first network FN-1, the mobile terminal 20 enters the second network FN-2 through the movement of the mobile terminal 20 and is described above. As described above, when the connection with the communication terminal 10 is terminated while connected with the communication terminal 10 through the turnneling of the first mobility manager 30a, the mobile terminal 20 has a second IP address. The second mobility manager 30b registers the second mobility manager 30b, and as described above, the second mobility manager 30b is responsible for this.

In the same manner as when the mobile terminal 20 enters the second network FN-2 in a state where the connection with the communication terminal 10 is released, the host name and the second IP address are assigned from the mobile terminal 20. By registering with the server 50, when the connection from the communication terminal 10 is attempted while the mobile terminal 20 belongs to the second network FN-2, the first network FN-1 described above. The mobile terminal 20 and the communication terminal 10 can communicate with each other in the same manner as if they belong.

In addition, the mobile terminal 20 performs a procedure of releasing registration with the first mobility manager 30a.

The first network FN-1 or the second network FN-2 in the above-described embodiment may be applied to either a home network or a home network in a conventional MIP environment. For example, referring to FIG. 1 and FIG. 2, the mobile terminal 20 is currently located in the residential network (HN in FIG. 1) and moves to the visiting network (Fn-a in FIG. 1) during connection with the communication terminal 10. In this case, the residential network (HN in FIG. 1) and the home address in the MIP environment become the first network FN-1 and the first IP address according to the present invention, respectively, and the visited network in the MIP environment (FIG. FN-a and Care-of Address of 1 become the second network FN-2 and the second IP address, respectively. And of course, the reverse is also possible.

In addition, when the mobile terminal 20 is currently located in the first visited network (FN-a of FIG. 1) and moves to the second visited network (FN-b of FIG. 1) while connecting to the communication terminal 10, the MIP environment The first visited network (FN-a in FIG. 1) and the first whole address under the network become the first network FN-1 and the first IP address according to the present invention, respectively, and the first visited network under the MIP environment (FIG. 1). FN-b) and the second whole school address become the second network FN-2 and the second IP address, respectively.

Hereinafter, a mobility management method according to the present invention will be described in detail with reference to FIGS. 3 to 6. Here, in the mobility management method according to the present invention, the configuration of the mobility management system described above is applied, and a description thereof may be partially omitted as necessary.

First, when the mobile terminal 20 enters the first network FN-1, the mobile terminal 20 detects that the mobile terminal 20 enters another network, and the first network manager located in the first network FN-1. A request is made to assign 40a to the first IP address to receive the first IP address (S10). Then, the mobile terminal 20 registers the first IP address and host name allocated from the first network manager 40a to the first mobility manager 30a located in the first network FN-1 (S11). The first mobility manager 30a responds to this (S11a).

When the registration to the first mobility manager 30a is completed, the mobile terminal 20 registers the first IP address and its host name assigned from the first network manager 40a in the name server 50 (S12). The name server 50 responds with this (S12a). Here, the name server 50 registered with the first IP address and the host name of the mobile terminal 20 configures and manages a database that associates the first IP address with the host name.

On the other hand, when the communication terminal 10 wants to communicate with the mobile terminal 20 in the state that the registration process as described above, the communication terminal 10 first to the name server 50 host name of the mobile terminal 20 Request a first IP address that is information about the current location of the mobile terminal 20 by using (S13). In response to the request of the communication terminal 10, the name server 50 searches for a first IP address corresponding to the host name requested by the communication terminal 10 and transmits it to the communication terminal 10 (S14). ).

Then, the communication terminal 10 establishes an initial session along the direct mobile terminal 20 and the optimal route (R3 in FIG. 2) based on the first IP address currently assigned to the mobile terminal 20 and additional signals. By transmitting a data packet for transmitting user data, the mobile terminal 20 is connected to communicate with the mobile terminal 20 (S15).

On the other hand, when the mobile terminal 20 continues to move in the state of maintaining the connection with the communication terminal 10 and enters the second network FN-2, the mobile terminal 20 detects that the mobile terminal 20 has entered another network. The second network manager 40b located in the second network FN-2 is requested to receive the second IP address (S16).

Then, the mobile terminal 20 assigned the second IP address determines whether it is currently connected to the communication terminal 10 (S17), and in the state connected to the communication terminal 10, the second network ( If it is determined that the access to the FN-2) is entered, the first mobility manager 30a is notified of the assigned second IP address (S18), and the first mobility manager 30a responds to this (S18a).

When the first IP address is updated to the second IP address in the first mobility manager 30a as described above, the first mobility manager 30a arrives at the first network FN-1 using the first IP address as the destination address. The first mobility manager 30a intercepts the data packet, attaches the second IP address to the packet header of the data packet, and sends the data packet back to the Internet I, that is, rerouting (S20). The data packet is routed to the second network FN-2 corresponding to the second IP address and is eventually received by the mobile terminal 20 (S19).

At this time, the mobile terminal 20 receiving the data packet in the second network FN-2 by the rerouting of the first mobility manager 30a is attached by the first mobility manager 30a. By removing the second IP address and processing it at the application layer based on the first IP address, which is the original destination address, the first IP address, which is the destination address at the time of initial session establishment, is not changed, thereby ensuring mobility of the connection-based session. . In this way, when the mobile terminal which maintains the connection started from the first network continues to move to another network (for example, the third network), a new IP address is assigned and the first IP address is allocated in the same manner as when entering the second network. Register with the mobility manager so that the rerouting is to a third network instead of a second network so that the connection is maintained.

Meanwhile, when the mobile terminal 20 enters the second network FN-2 in step S17 and receives a second IP address from the second network manager 40b (S16), the connection with the communication terminal 10 is released. In this case, the mobile terminal 20 registers the allocated second IP address to the second mobility manager 30b (S30), and the second mobility manager 30b responds thereto (S30a).

When the registration with the second mobility manager 30b is completed, the mobile terminal 20 names the second IP address and the host name so that the first IP address registered in the name server 50 can be changed to the second IP address. It registers with the server 50 (S31), and the name server 50 responds to this (S31a). Here, the name server 50 configures a database that associates the second IP address with the host name, so that the subsequent new session setup is performed based on the second IP address.

Then, the mobile terminal 20 requests the first mobility manager 30a to release its registration in order to deregister it from the previous first mobility manager 30a (S32), and the first mobility manager attaches thereto. In response (S32a), the mobile terminal 20 is deregistered (S33).

Meanwhile, after step S20 of FIG. 4, that is, the communication terminal 10 communicates with the mobile terminal 20 belonging to the second network FN-2 by the rerouting of the first mobility manager 30a. When the communication is terminated (S21), as shown in FIG. 6, the mobile terminal 20 releases the registration to the first mobility manager 30a and registers for mobility management by the second mobility manager 30b. Will be performed. This proceeds similar to the procedure shown in FIG.

Referring to FIG. 6, when communication with the communication terminal 10 is terminated (S21), the mobile terminal 20 sets the second IP address allocated from the second network manager 40b to the second mobility manager 30b. Register (S22), and the second mobility manager 30b responds.

When the registration with the second mobility manager 30b is completed, the mobile terminal 20 names the second IP address and the host name so that the first IP address registered in the name server 50 can be changed to the second IP address. It registers with the server 50 (S23), and the name server 50 responds to this. In this case, the name server 50 modifies the database corresponding to the second IP address and the host name, so that a subsequent new session setup is performed based on the second IP address.

Then, the mobile terminal 20 requests the first mobility manager 30a to release its registration in order to deregister it from the previous first mobility manager 30a (S24), and the first mobility manager 30a. In response thereto, the mobile station 20 deregisters the mobile terminal 20 (S25).

On the other hand, in the above description of the present invention has been described with respect to specific embodiments, there can be various embodiments within the scope of various modifications do not depart from the gist of the present invention. Therefore, the scope of the present invention should not be defined by the described embodiments, but by the claims and equivalents of the claims.

1 is a diagram showing an Internet structure supporting a conventional MIP,

2 is a view showing the configuration of a mobility management system according to the present invention,

3 to 6 are diagrams for describing the mobility management method according to the present invention.

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

10: communication terminal 20: mobile terminal

30a: first mobility manager 30b: second mobility manager

40a: first network administrator 40b: second network administrator

50: Name Server

Claims (11)

A first mobility manager in which the mobile terminal enters the first network and registers the allocated first IP address; Register and store the first IP address and the host name of the mobile terminal from the mobile terminal, and if the request is based on the host name from the communication terminal, the first IP matched with the host name to the communication terminal. Includes a name server for sending addresses, The communication terminal connects to the mobile terminal based on the first IP address transmitted from the name server, When the mobile terminal enters the second network while connected to the communication terminal, the mobile terminal receives a second IP address from the second network and notifies the first mobility manager. And when the first mobility manager is notified of the second IP address from the mobile terminal, rerouting data packets transmitted from the communication terminal to the mobile terminal to the second network. The method of claim 1, The matching between the host name and the first IP address is implemented by any one of a Session Initiation Protocol (SIP) scheme and a Dynamic Domain Name System (DSN) scheme. The method of claim 2, A second mobility manager for registering the second IP address from the mobile terminal entering the second network; The mobile terminal registers the second IP address in the second mobility manager when entering the second network when the communication terminal is disconnected from the communication terminal, and the first IP address registered in the name server becomes And registering the second IP address and the host name with the name server so as to be changed to a second IP address, and releasing registration with the first mobility manager. The method of claim 2, A second mobility manager for registering the second IP address from the mobile terminal entering the second network; The mobile terminal registers the second IP address with the second mobility manager when the connection with the communication terminal is released after being connected with the communication terminal through rerouting of the first mobility manager. Registering the second IP address and the host name in the name server so that the first IP address registered in the name server is changed to the second IP address, and releasing registration as the first mobility manager. Mobility management system. The method according to claim 3 or 4, And a first network manager and a second network manager for allocating the first IP address and the second IP address to the mobile terminal entering the first network and the second network, respectively. system. The method of claim 5, The first network manager and the second network manager assigns the first IP address and the second IP address to the mobile terminal according to a dynamic host configuration protocol (DHCP). system. In the mobility management method between the mobile terminal and the communication terminal interconnected, When the mobile terminal enters a first network, registering a first IP address assigned from the first network to the first mobility manager from the mobile terminal; Registering, by the mobile terminal, the first IP address and the host name of the mobile terminal in a name server; When the communication terminal accesses the name server and requests the first IP address based on the host name, the name server transmitting a first IP address matching the host name to the communication terminal; Connecting the communication terminal with the mobile terminal based on the first IP address transmitted from the name server; When the mobile terminal enters a second network while connected to the communication terminal, assigning a second IP address to the mobile terminal from the second network; Notifying the first mobility manager of the second IP address from the mobile terminal; And if the first mobility manager is notified of the second IP address from the mobile terminal, rerouting data packets transmitted from the communication terminal to the mobile terminal to the second network. How to manage. The method of claim 7, wherein The matching between the host name and the first IP address is implemented by any one of a Session Initiation Protocol (SIP) scheme and a Dynamic Domain Name System (Dynamic Domain Name System) scheme. The method of claim 8, Registering the second IP address with the second mobility manager from the mobile terminal when the mobile terminal enters the second network while the mobile terminal and the communication terminal are disconnected; Registering the second IP address and the host name with the name server from the mobile terminal such that the first IP address registered with the name server is changed to the second IP address; And removing the registration as the first mobility manager according to the request of the mobile terminal. The method of claim 8, When the connection between the mobile terminal and the communication terminal is released in the course of performing the rerouting, registering the second IP address with the second mobility manager from the mobile terminal; Registering the second IP address and the host name with the name server from the mobile terminal such that the first IP address registered with the name server is changed to the second IP address; And removing the registration as the first mobility manager according to the request of the mobile terminal. The method of claim 9 or 10, Wherein the first IP address and the second IP address are allocated to the mobile terminal according to a Dynamic Host Configuration Protocol (DHCP).

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