KR20050099148A - Fast hand-off method using mobility prediction in hierarchical hmipv6 network - Google Patents

Abstract

The present invention relates to a fast handover method through mobility prediction in a hierarchical Mobile IPv6 network. In the hierarchical mobile IPv6 network capable of predicting mobility of a wireless terminal, when the mobile node moves, the present invention predicts an average moving speed of the mobile node. According to the predicted moving speed, the fast moving speed and the slow moving speed are classified, and a separate handover is performed accordingly. The present invention reduces the packet loss generated in a fast-moving wireless terminal by registering the wireless terminal in the mobile network by predicting the average moving speed of the mobile node and performing a separate handover according to the fast and slow moving speed. Has

Description

 Fast hand-over method using mobility prediction in hierarchical mobile IPVICE network {Fast hand-off method using mobility prediction in hierarchical HMIPv6 network}

The present invention relates to a fast handover method through mobility prediction in a hierarchical Mobile IPv6 network. More specifically, mobility in a hierarchical Mobile IPv6 (HMIPv6) network that predicts mobility of a mobile station in a fast mobility region and a slow mobility region and performs an appropriate handover according to each region. It relates to a fast handover method through prediction.

Internet users want to use high-quality Internet services anytime, anywhere, and the number of users is increasing due to the improvement of the performance of mobile terminals such as portable computers and PDAs and the development of wireless communication technology.

An IP address, an Internet address system, consists of a network identifier field and a host identifier field. The network identifier field is a part for identifying a network, that is, a network, and the host identifier field is a part for identifying a host in a network. When the mobile communication terminal moves to another network, the network identifier is changed and thus the IP address of the mobile communication terminal is changed. In the IP layer, packets are routed according to the network identifier of the destination address, so that the mobile terminal cannot receive the packet when the mobile terminal moves to another network. If you want to continue to communicate with other networks, you need to change the IP address to have the network identifier of the network every time you move the network. In this case, higher layer connections such as TCP connections are not guaranteed. Therefore, a protocol called Mobile IP is used to guarantee mobility in order to enable communication while maintaining the existing address.

Meanwhile, as the number of wireless Internet users increases, the existing IPv4 addressing system cannot satisfy the increasing amount of IP, thus providing mobility using the IPv6 protocol, which is attracting attention as the next generation Internet protocol.

The basic operation of IPv6 is as follows. When a mobile terminal moves from a home network to an external network, a mobile node (MN) obtains a temporary address from an agent of a currently located subnet. Also, when a mobile station moves from one external subnet to another, the mobile node obtains a new care-of-address (CoA) from the new subnet. The mobile node binds a home address and the temporary address and registers them with corresponding nodes (CNs) in communication with the home agent of the home network. Thereafter, the counterpart nodes set the destination of the packet to be transmitted to the mobile node as the temporary address and transmit the packet to the mobile node. A home agent (HA) of a home network intercepts a packet transmitted to the mobile node and tunnels the mobile node using the original home address as a destination. In addition, the Mobile IPv6 as described above has a smooth handover scheme for supporting handover, but there is a problem that packet loss is not possible because a fast message cannot be processed when the wireless terminal moves quickly.

In order to solve this problem, a hierarchical Mobile IPv6 scheme has been proposed.

1 illustrates a fast handover protocol for reducing handover time in a conventional Mobile IPv6 network.

The mobile node detects a handover through the L2 trigger and sends a router request message to a previous access router (pAR) to obtain a new temporary address to be used in the new network (step 103). In response to the router request message, pAR sends a Router Advertisement message to the mobile node that contains the three layers of information needed to configure a new temporary address in the new network (step 106). The three-layer information here means the network layer and is used to determine the address and route.

The pAR sends a handoff message to the new access router (nAR) (step 109). This message preferably contains the new temporary address and the old temporary address requested in the new network. When a new access router (nAR) receives a handoff message, the nAR assigns a new care-of-address (nCoA) in the handoff message if there is no nCoA, and if so, checks it.

nAR sends a handoff acknowledgment message to pAR that includes whether nCoA has been allocated and whether nCoA received from the handoff message is valid (step 112). The mobile node sends a fast binding update (F-BU) before moving to the new network (step 115). The pAR informs the mobile node MN and the nAR of the acknowledgment of the F-BU through a fast binding update acknowledgment (F-BACK) (step 118). As soon as the pAR receives the F-BU, it forms a temporary tunnel for the life of the F-BACK and forwards the packet to the nAR (step 124).

When the mobile node moves to a new network (step 127), it sends a Fast Neighbor Advertisement (F-NA) message to nAR (step 130), where nAR requests a forwarded packet from pAR. nAR transmits the requested packet to the mobile node (step 133). As such, the mobile node detects handover quickly and performs fast handover to secure packet loss. However, if a mobile terminal attached to a fast moving means such as a vehicle moves, moving to a new network before completing the handover operation may cause packet loss.

To complement this, a hierarchical mobile IPv6 network has been proposed to manage mobility hierarchically. In a hierarchical mobile IPv6 network, a hierarchical top-level router manages mobility in its domain. Therefore, the home agent or the counter node does not manage the mobility of the mobile node in the MAP domain, thereby reducing the processing of the handover message caused by the movement of the mobile node. However, when a mobile terminal attached to a fast moving means such as a vehicle moves, there is a problem that packet loss occurs because a new temporary address must be configured and registered before entering a new network before completing the handover operation process.

The present invention has been made in view of this point, and predicts the average mobile speed of the wireless terminal and predicts mobility in a hierarchical Mobile IPv6 network which reduces packet loss by performing separate handovers according to fast and slow moving speeds. It is to provide a fast handover method through.

The present invention for achieving the above object, in the hierarchical mobile IPv6 network capable of predicting the mobility of the wireless terminal, when the mobile node moves, predicts the average moving speed of the mobile node. According to the predicted moving speed, the fast moving speed and the slow moving speed are distinguished and separate handover is performed accordingly.

The handover according to the fast movement speed may include: a first step of receiving an access router list from a new access router when a mobile node storing a mobility prediction table moves to another network; Update the mobility prediction table including the IP address of the network where the mobile node that received the access router list was previously located, the IP address of the network where the mobile node is currently located, and the IP address of the network to which the mobile node is to be moved. Second step; Updating the mobility prediction table, determining a next network to which the mobile node will move, and performing a handover;

After the mobile node determines the next network to move, it sends a handoff start message containing the new temporary address and the old temporary address required by the new network to the new access router as it passes through the midpoint of the predicted network. Making; The new access router receiving the transmitted handoff start message sends a handoff acknowledgment message to the previous access router, including whether the new temporary address is valid; If the mobile node enters the overlapping network, sending a fast binding update to the previous access router; The previous access router receiving the quick binding update sends a quick binding update approval message to the mobile node and the new access router; Forwarding the packet to the new access router by the previous access router receiving the quick binding update acknowledgment message; Requesting a forwarded packet to the previous access router by sending a fast neighbor advertisement message to the new access router when the mobile node moves to the new network; Sending a binding update message to the MAP upon receiving a packet from the new access router receiving the packet request; Registering the mobile node with the MAP and sending a binding acknowledgment message to the mobile node; The mobile node receiving the advertisement message from the new access router further updates the mobility prediction table.

In addition, the handover according to the slow moving speed is a fast handover protocol that obtains a temporary address from a new access router and forwards the packet to the new access router through tunneling, and a top-level router having a hierarchical structure is located within its own domain. This is accomplished by combining the combined structure of hierarchical mobility management to manage the mobility of the handover.

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

Looking at the mobility of a wireless terminal (mobile node), it is divided into an area where the movement of the wireless terminal is rapid and an area where the movement of the wireless terminal is slow. That is, the area where the wireless terminal occurs quickly is an area where a vehicle can travel, such as a road, and the area where the wireless terminal moves relatively slowly is a public place and a street where people can walk.

However, in the case of supporting the mobility of the wireless terminal with the conventional handover scheme, there is a disadvantage in that mobility management in the region showing the fast mobility is difficult. In order to compensate for this, the present invention provides a method for performing handover by dividing a region showing fast mobility and a region showing slow mobility.

The handover process in the region showing slow mobility is desirable to predict the mobility of the wireless terminal in the overlapping region of the network and to end the handover before the mobile terminal moves to the next network where the mobile is expected to move. Therefore, a combination of conventional fast handover protocol and hierarchical mobility management is used. By using the technique of the fast handover protocol, the packet loss is reduced by acquiring a care of address (CoA) from a new access router (nAR) faster than the existing Mobile IP protocol and forwarding the packet to nAR through tunneling. Also, hierarchical mobility management can reduce packet loss by delaying registration time than the existing Mobile IPv6 protocol. In other words, handover according to the slow movement speed is a fast handover protocol that obtains a temporary address from a new access router and forwards the packet to a new access router through tunneling, and a top-level router having a hierarchical structure is used within its own domain. A handover is performed by combining the combined structure of hierarchical mobility management that manages the mobility of the.

2 is a diagram illustrating a mobility prediction table stored in a wireless terminal in a region showing fast mobility according to the present invention.

In areas where fast mobility is seen, wireless terminals move quickly. Therefore, even if the next network to be detected is moved in the overlapping area of the network and the network, a handover cannot be performed before moving to the next mobile network. Accordingly, the present invention provides a mobility prediction method using only three layer information. In order to predict the mobility of the wireless terminal using the three-layer information, each wireless terminal preferably stores a mobility prediction table. Preferably, the mobility prediction table of the wireless terminal includes an address list of access routers. The IP address of the access router of the network, the IP address of the access router of the network where the current terminal is located, It is preferable to include the IP address of the access router of the network to be moved next.

3 is a screen example illustrating a process of updating a mobility prediction table of a mobile node.

4 is another screen example illustrating an update process of a mobility prediction table of a mobile node.

If the mobile node moves from the previous network to the next network, the access router 2 transmits the advertisement message to the wireless terminal by including the access router address list including the IP addresses of the access router 1, the access router 2, and the access router 3. Receiving this, the wireless terminal updates the mobility prediction table and determines the next mobile network. That is, if it was previously at the address of access router 1 and is currently at the address of access router 2, the access route is predicted to determine the network to which the wireless terminal will move next to the access router 3.

Similarly in FIG. 4, if the mobile node moves from the previous network to the next network, the access router 2 includes an access router address list including IP addresses of the access router 1, the access router 2, the access router 3, and the access router 4 in the advertisement message. Including mobile node transmits. Receiving this, the wireless terminal updates the mobility prediction table and determines the next mobile network. In other words, if it was previously at the address of access router 1, and is currently at the address of access router 2, it predicts the movement path and determines the next network to be moved by the access router 3 and the access router 4.

5 is a diagram illustrating a routing operation process in a region showing fast mobility of the present invention.

 The previous access router (pAR) sends a Router Advertisement (RA) including a list of access routers to the mobile node (MN) (step 503). The mobile node receiving the router advertisement message including the access router list updates its mobility prediction table (step 537) and predicts a network to be moved next.

When the mobile node moves from the current network to the next network and calls the midpoint of the network, it transmits a hand off initiation (HI) message to a new access router (nAR) (step 506). . This message contains the new care-of-address (nCoA) and the old care-of-address (oCoA) requested in the new network. When the new access router receives the handoff start message, the new access router checks nCoA if there is nCoA in the message and assigns nCoA if it does not.

The new access router sends a handoff acknowledgment message to the pAR containing the result of checking whether there is nCoA in the message (step 509). That is, a message including whether nCoA is allocated or nCoA is valid is transmitted to pAR.

When the mobile node enters the overlapping network, it sends a fast binding update (F-BU) to the pAR (step 512). Upon receipt of the fast binding update, the previous access router I (pAR) sends a fast binding update acknowledgment (F-BACK) to the mobile node and the new access router (step 515). As soon as the pAR receives the F-BU, it forms a temporary tunnel for the life of the F-BACK and forwards the packet to the nAR (step 521).

When the mobile node moves to a new network, it sends a Fast Neighbor Advertisement (F-NA) message to the nAR (step 524), requesting to send a forwarded packet from the pAR. After receiving the request, the nAR transmits a packet to the mobile node (step 527), and the mobile node registers with the MAP by sending a binding update (BU) message to the mobile anchor point (step 530) (step 540). .

The MAP registers the mobile node in its binding list (BL) (step 540) and sends a binding acknowledgment (BA) message to the mobile node (step 533) to inform that the registration is completed. Afterwards, the MAP sends a packet sent to the mobile node to nAR. The nAR sends an RA message to the mobile node (step 534) and the mobile node updates a mobility prediction table (MPT) (step 543).

As mentioned above, although this invention was demonstrated to the several example, this invention is not limited to a specific Example. Those skilled in the art will appreciate that various modifications and changes can be made without departing from the spirit of the invention.

As described above, according to the present invention, packet loss can be reduced by predicting the average moving speed of the wireless terminal and performing a separate handover according to the fast moving speed and the slow moving speed.

In addition, another effect of the present invention is to provide a fast handover method through mobility prediction in a hierarchical Mobile IPv6 network, thereby reducing packet loss generated in a fast-moving wireless terminal by registering the wireless terminal with a mobile network in advance.

1 illustrates a fast handover protocol for reducing handover time in a conventional Mobile IPv6 network.

2 is a diagram illustrating a mobility prediction table stored in a wireless terminal in a region showing fast mobility according to the present invention.

3 is a screen example illustrating a process of updating a mobility prediction table of a mobile node.

4 is another screen example illustrating an update process of a mobility prediction table of a mobile node.

5 is a diagram illustrating a routing operation process in a region showing fast mobility of the present invention.

Claims (4)

In a hierarchical mobile IPv6 network capable of predicting mobility of a wireless terminal, A first step of predicting an average moving speed of a wireless terminal when the mobile node moves; A second step of performing a separate handover according to a fast moving speed and a slow moving speed; Fast handover method through mobility prediction in a hierarchical Mobile IPv6 network comprising a. The method of claim 1, wherein the handover according to the fast moving speed, Step 2-1 of receiving an access router list from the new access router when the mobile node storing the mobility prediction table moves to another network; Updates the mobility prediction table including the IP address of the network where the mobile node that received the access router list was previously located, the IP address of the network where the mobile node is currently located, and the IP address of the network to which the mobile node is to be moved. Step 2-2; Updating the mobility prediction table, determining a next network to which the mobile node is to move, and performing handover; Fast handover method through mobility prediction in a hierarchical Mobile IPv6 network comprising a. The method of claim 2, wherein step 2-3 is After the mobile node determines the next network to move, it sends a handoff start message containing the new temporary address and the old temporary address required by the new access router to the new access router as it passes through the midpoint of the predicted network. Step 2-3-1; Receiving the handoff start message, the new access router sends a handoff acknowledgment message to the previous access router including whether the new temporary address is valid; When the mobile node enters the overlapping network, it sends a fast binding update to the previous access router, and the old access router which receives the fast binding update sends the quick binding update acknowledgment message to the mobile node and the new access router. step; Step 2-3-5, in which the previous access router receiving the fast binding update approval message forwards the packet to the new access router; Step 2-3-6, when the mobile node moves to a new network, requesting a forwarded packet to the previous access router by transmitting a fast neighbor advertisement message to the new access router; Step 2-3-7, upon receiving a packet from the new access router receiving the packet request, transmitting a binding update message to the MAP; MAP registers the mobile node in its binding list and transmits a binding acknowledgment message in steps 2-3-8; Step 2-3-9 of the mobile node receiving the advertisement message from the new access router to update the mobility prediction table; Fast handover method through mobility prediction in a hierarchical Mobile IPv6 network comprising a. The handover according to the slow movement speed of claim 2, Combination of fast handover protocol that obtains ephemeral address from new access router and forwards packet to new access router through tunneling, and hierarchical mobility management, where hierarchical top-level router manages mobility in its domain Fast handover method through mobility prediction in a hierarchical Mobile IPv6 network, characterized in that the handover is performed by combining the structures.