KR20080093726A - An binding update method for mobile ipv6 node node in mobile network and mobile terminal thereof - Google Patents

Abstract

A binding update method in a mobile IPv6 system and a mobile terminal performing the same are provided to reduce a load of binding update at a mobile IPv6 based terminal and therefore to enable the terminal to make an efficient IPv6 process. A mobile terminal performing binding update method in a mobile IPv6 system includes a wireless interface(110), a path optimizer(120), a traffic processor(130), a binding refresh timer(140), a binding list(150), a traffic monitoring timer(160) and a controller(170). The wireless interface provides an interface with a wireless network for making an IPv6 based mobile communication with a CN(Correspondent Node). The path optimizer optimizes a path for directly transmitting or receiving packets to or from the CN not via an HA(Home Agent). The traffic processor performs a traffic process for transmitting or receiving packets to or from the CN via the wireless interface. The binding refresh timer measures the time of a frequency negotiated with the CN when an initial binding is updated. The binding list stores a list of CNs which has performed the binding update. The traffic monitoring timer measures the time passed since the path optimizer performs the path optimization process. The controller controls the path optimization of the path optimizer and packet communication of the traffic processor with the CN after the terminal performs an initial call process.

Description

Binding update method in mobile IP6 and mobile terminal performing the same {AN BINDING UPDATE METHOD FOR MOBILE IPV6 NODE NODE IN MOBILE NETWORK AND MOBILE TERMINAL THEREOF}

1 is a schematic flowchart of a path optimization process in mobile IPv6 of a general mobile communication network.

2 is a schematic flowchart of a path optimization process after binding refresh in mobile IPv6 of a typical mobile communication network.

3 is a diagram schematically illustrating a binding update optimization method in mobile IPv6 according to a first embodiment of the present invention.

4 is a block diagram of a terminal performing binding update in mobile IPv6 according to a first embodiment of the present invention.

5 is a flowchart of a method of performing binding update in mobile IPv6 according to a first embodiment of the present invention.

FIG. 6 is a diagram schematically illustrating a binding update method in mobile IPv6 according to a second embodiment of the present invention.

7 is a block diagram of a terminal performing binding update in mobile IPv6 according to a second embodiment of the present invention.

8 is a flowchart of a method of performing binding update in mobile IPv6 according to a second embodiment of the present invention.

The present invention relates to a mobile IPv6 technology in a mobile communication network, and more particularly, to an optimized binding update method performed in mobile IPv6 and a terminal performing the method.

Due to the demand for add-ons for modern devices and the depletion of available Internet addresses, IPv6 technology has been proposed to support the new Internet addressing system, which has evolved in many ways over IPv4 technology. In the IPv6 technology, various performance, security, and mobility are improved compared to the existing IPv4.

Among these IPv6 technologies, especially in mobile IPv6, which focuses on mobility of terminals, routing optimization is performed to reduce packet transmission overhead and network load of a home agent (hereinafter referred to as "HA") unlike mobile IPv4. I use a technique called).

In the original mobile IP, the HA is deeply involved in call flow and is transmitted between the mobile IP terminal and the correspondent node (hereinafter referred to as CN) connected to the Internet communicating with the mobile IP terminal. Intercept and forward the packet. In this case, IP-in-IP tunneling is drilled between the terminal and the foreign agent, causing unnecessary load on the network.

To improve this, route optimization is used in mobile IPv6.

Referring to FIG. 1, the user terminal 1 performs a point-to-point protocol (PPP) negotiation with a network router 3 or a general packet through a wireless network connection process S1 with a base station 2. Radio Service Tunneling Protocol After acquiring a care of address (CoA) through tunnel local IP allocation process (S2), inform the HA (4) of the acquired CoA through binding update process (S3, S4). Packet transmission between the terminal 1 and the CN 5 is performed via HA (S5). Here, the binding update process is a process in which the user terminal 1 sends a binding update message (Binding Update) to the HA (S3) and receives a binding update response message (Binding Update Ack) from the HA (S4). )

Thereafter, the user terminal 1 may have an HA 4 or CN 5 and a Home Test Init (HoTI) message, a Care-of Test Init (CoTI) message, a Home Test (HoT) message, and a Care-of Test ) After performing the RR (Return Routability) process (S6, S7, S8, S9, S10, S11), which is a verification process for registering CN (5) by sending and receiving messages, respectively, binding update process with CN (5). If the CoA is notified to the CN 5 through S12 and S13, packet transmission between the user terminal 1 and the CN 5 is directly performed without passing through the HA 4 (S14).

Of the above processes, S6 to S13 correspond to the path optimization process. That is, in the mobile IPv6 through the path optimization process, the HA 4 is not involved in packet transmission between the user terminal 1 and the CN 5.

In the above, the base station 2 may be allocated such that a base station controller (BSC), a packet control function (PCF), a radio network controller (RNC), a serving GPRS support node (SGSN), and the like perform a function. 3) may be allocated such that a Packet Data Serving Node (PDSN), a Gateway GPRS Support Node (GGSN), or the like performs its function.

On the other hand, referring to Figure 2, after a predetermined time after performing the path optimization process as described above between the user terminal 1 and the CN (5), the user terminal 1 re-verify the binding with the CN (5) In order to send the binding refresh message (Binding Refresh) to the CN (5) (S21) and performs the path optimization process (S22, S23, S24, S25, S26, S27, S28, S29) once again with CN (5) shall. Here, a predetermined time until the binding refresh message is sent after the path optimization process is performed is determined by the user terminal 1 and the CN 5 negotiating the next cycle at the initial binding update.

As such, since the binding refresh process is periodically performed after the path optimization between the user terminal and the CN, the burden of the user terminal increases as the CN to which the user terminal communicates increases, and also for maintaining the optimized path with each CN. This leads to wasted elements of the system with increased binding. In particular, even if no traffic is generated because the user terminal does not communicate with the CN, the path optimization process subsequent to the binding refresh process must be performed unconditionally after a predetermined time, and also must be performed without considering the state of the user terminal or CN. The burden on mobile IPv6 processing at a user terminal or CN is increased, which makes it difficult to efficiently perform mobile IPv6 processing.

Therefore, in order to solve this problem, the present invention provides a binding updating method in mobile IPv6 and a terminal performing the method for enabling efficient mobile IPv6 processing between the user terminal and the CN.

In order to achieve the above object, a binding update method according to an aspect of the present invention,

A binding update method in a mobile terminal, comprising: a) performing a path optimization process for a counterpart node; And b) if the traffic with the counterpart node does not occur for a certain time, releasing the binding to the counterpart node.

A mobile terminal according to another feature of the present invention,

A mobile terminal for performing a binding update, the mobile terminal comprising: a path optimization performing unit performing a path optimization process for a counterpart node; A traffic monitoring timer configured to monitor whether traffic with the counterpart node is generated for a predetermined time; And controlling the path optimization execution unit and the traffic monitoring timer, and after the path optimization process is performed by the path optimization execution unit until the predetermined time has elapsed by the traffic monitoring timer. If the traffic does not occur with the node, and includes a control unit for releasing the binding to the partner node.

The binding update method according to another feature of the present invention,

A binding update method in a mobile terminal, comprising: a) performing a path optimization process for a counterpart node; b) sending a binding refresh message to the counterpart node for revalidating the binding with the counterpart node; And c) if there is no response from the counterpart node for a predetermined time with respect to the binding refresh message sent to the counterpart node, releasing the binding to the counterpart node.

A mobile terminal according to another feature of the present invention,

A mobile terminal for performing a binding update, the mobile terminal comprising: a path optimization performing unit performing a path optimization process for a counterpart node and sending a binding refresh message to the counterpart node to re-verify the binding with the counterpart node; A response timer for measuring a predetermined response time after sending the binding refresh message to the counterpart node; And controlling the path optimization execution unit and the response timer, and transmitting the binding refresh message to the counterpart node after the path optimization process for the counterpart node by the path optimization unit. And when the response to the binding refresh message is not received from the counterpart node until the response time has elapsed, the controller may include a control unit releasing the binding to the counterpart node.

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.

Also. When a part is said to "include" a certain component, this means that it can further include other components, except to exclude other components unless specifically stated otherwise.

3 is a diagram schematically illustrating a binding update optimization method in mobile IPv6 according to a first embodiment of the present invention.

Referring to FIG. 3, in the binding update optimization method in mobile IPv6 according to the first embodiment of the present invention, after the terminal 100 performs a path optimization process (S100) through an initial call processing procedure with the CN 500. When no traffic is generated for a predetermined time between the terminal 100 and the CN 500, the terminal 100 does not send a binding refresh message to the CN 500 to re-validate the binding. .

To this end, the terminal 100 is provided with a timer that can measure a predetermined time from that time when the path optimization process (S100) is completed, the timer is a time from when the path optimization process (S100) is completed to a predetermined time In the meantime, if traffic is generated between the terminal 100 and the CN 500 in the meantime, the measured time is reset and measured again from the beginning.

Therefore, when the terminal 100 sends the binding refresh message to the CN 500 after the path optimization process (S100), the terminal 100 checks whether the time measured by the timer is a predetermined time, and generates the binding refresh message only if it is not a predetermined time. Will be sent to (500). That is, if the time measured by the timer is a certain time, this means that no traffic is generated between the terminal 100 and the CN 500 for a predetermined time after the path optimization process (S100), and thus binds to the CN 500. There is no need to send a refresh message. In this case, the terminal 100 removes the CN 500 from the binding list storing the list of the CN 500 to which the binding refresh message should be sent (S110). Don't even check whether a binding's binding message is sent. Here, it is determined whether the binding refresh message is sent by the expiration of the binding refresh timer which measures the time of the next cycle after the path optimization process.

Hereinafter, a binding update optimization method in mobile IPv6 according to the first embodiment of the present invention and a terminal performing the method will be described with reference to a specific example.

4 is a block diagram of a terminal performing binding update in mobile IPv6 according to a first embodiment of the present invention.

As shown in FIG. 4, the terminal performing binding update in mobile IPv6 according to the first embodiment of the present invention includes an air interface 110, a path optimization execution unit 120, a traffic processing unit 130, and a binding refresh. The timer 140 includes a binding list 150, a traffic monitoring timer 160, and a controller 170.

The wireless interface 110 provides an interface with a wireless network for allowing the terminal 100 to perform mobile communication based on the IPv6 with the CN 500 through the mobile network. To this end, the air interface 110 may be connected to a base station 200 corresponding to various mobile communication networks, for example, BSC, PCF, RNC, SGSN, or the like through a wireless network. Since the connection method between the air interface 110 and the base station 200 is well known, a detailed description thereof will be omitted.

The path optimization performing unit 120 performs path optimization for allowing the terminal 100 to directly transmit and receive a packet with the CN 500 without passing through the HA 400. The path optimization process is an RR process and a CN, which is a verification process for registering the CN 500 by exchanging the HA 400 or the CN 500 with the HoTI message, the CoTI message, the HoT message, and the CoT message, respectively. Through the binding update process with the 500, it means a process of informing its CoA to the CN (500).

The traffic processor 130 performs traffic processing for transmitting and receiving a packet with the CN 500 through the air interface 110.

The binding refresh timer 140 is a timer that measures the time of a cycle negotiated with the CN 500 upon initial binding update. The binding refresh timer 140 preferably outputs a binding refresh timer expiration signal notifying when the time of the negotiated period elapses during the initial binding update. Here, the binding refresh timer 140 should be provided as many as the number of more than two CN 500 that the terminal 100 has performed the binding update.

The binding list 150 stores a list of the CNs 500 in which the terminal 100 performs a binding update.

The traffic monitoring timer 160 is a timer for measuring a predetermined time after the path optimization process is performed by the path optimization execution unit 120. The traffic monitoring timer 160 monitors whether traffic is generated between the terminal 100 and the CN 500, and resets the time to be measured when the traffic is generated to measure time from the beginning. In this case, the traffic generation is described on the assumption that the traffic monitoring timer 160 monitors and recognizes the traffic transmission and reception state between the traffic processing unit 130 and the air interface 110, but in addition, the control unit 170 controls the traffic processing unit 130. By transmitting a traffic processing command for transmitting and receiving packets at the same time and informs the traffic monitoring timer 160.

On the other hand, if no traffic occurs between the CN 500, the traffic monitoring timer 160 measures up to a certain time. Preferably, the traffic monitoring timer 160 outputs a traffic monitoring timer expiration signal when the measurement is completed by a predetermined time.

After performing the initial call processing of the terminal 100, the controller 170 performs the path optimization through the path optimization performing unit 120, and transmits and receives packets to and from the CN 500 through the traffic processing unit 130. Perform. When the path optimization is completed, time measurement of the binding refresh timer 140 and the traffic monitoring timer 160 is started. In addition, when the binding refresh timer expiration signal is output from the binding refresh timer 140, the binding refresh message is transmitted to the corresponding CN 500, and then the path optimization is performed again through the path optimization execution unit 120. In addition, when the traffic monitoring timer expiration signal is output from the traffic monitoring timer 160, even if the binding refresh timer expiration signal is generated, the corresponding CN 500 stored in the binding list 150 without transmitting the binding refresh message to the CN 500. Delete the list of).

Hereinafter, a binding update method in mobile IPv6 according to the first embodiment of the present invention will be described with reference to FIG. 5.

First, the terminal 100 obtains a CoA through a PPP negotiation with a network router 300 or a GTP tunnel local IP allocation process through a wireless network access process with the base station 200, and then performs a binding update process with the obtained CoA. It will be described on the assumption that an initial call processing process informing the HA 400 is performed.

Thereafter, the terminal 100 performs a path optimization process for transmitting and receiving a packet with the CN 500 (S200). More specifically, the controller 170 exchanges various messages with the HA 400 and the CN 500 through the path optimization performing unit 120 and the air interface 110 to perform path optimization. The control unit 170 stores the list in the binding list 150 with respect to the CN 500 on which the path optimization has been performed so that a subsequent binding refresh operation may be continuously performed.

As such, when path optimization is performed, the terminal 100 may directly transmit traffic with the CN 500 without passing through the HA 400 thereafter. That is, the controller 170 may transmit a packet to the CN 500 through the traffic processor 130 and the air interface 110, or may receive a packet transmitted from the CN 500.

In addition, when path optimization is performed, the controller 171 drives the binding refresh timer 140 corresponding to the CN 500 to start time measurement up to the next period. At the same time, the controller 170 drives the traffic monitoring timer 160 to monitor whether traffic is generated for a predetermined time after path optimization (S210).

Next, the controller 170 checks whether the binding refresh timer expiration signal indicating that the next cycle time has elapsed is detected from the binding refresh timer 140 (S220). If the binding refresh timer expiration signal is generated from the binding refresh timer 140, the controller 170 checks whether the traffic monitoring timer expiration signal is generated from the traffic monitoring timer 160 again (S230). If traffic is generated between the terminal 100 and the CN 500 within a predetermined time after the path optimization step S200, the traffic monitoring timer expiration signal is not generated. 120 and transmits the binding refresh message to the CN 500 through the air interface 110 (S240), and performs path optimization to re-verify the binding with the CN 500 (S250).

However, the traffic monitoring timer expiration signal indicating that traffic does not occur between the terminal 100 and the CN 500 until a predetermined time elapses after the path optimization step S200 in step S230 is performed. ), The control unit 170 does not transmit the binding refresh message to the CN 500, and the binding of the CN 500 in the binding list 150 does not need to be maintained. By deleting the list (S260), the binding with the corresponding CN 500 is released.

As described above, in the first embodiment of the present invention, if no traffic occurs between the terminal 100 and the CN 500 for a predetermined time after the path optimization process, the expiration signal by the binding refresh timer 140 is generated. Efficient IPv6 processing by eliminating the burden on the terminal by eliminating the binding by deleting the list of the CN 500 stored in the binding list 150 without transmitting the binding refresh message to the CN 500, thereby eliminating the wasteful elements of the system. Becomes possible.

Next, a second embodiment of the present invention will be described.

FIG. 6 is a diagram schematically illustrating a binding update method in mobile IPv6 according to a second embodiment of the present invention.

Referring to FIG. 6, in the binding update method in mobile IPv6 according to the second embodiment of the present invention, after the terminal 100 performs a path optimization process (S300) through an initial call processing procedure with the CN 500, If a binding refresh message is sent to the CN 500 to re-validate the binding after the negotiated cycle has elapsed upon initial binding update, but there is no response, then CN 500 Is sent to the CN 500 by removing the CN 500 list from the binding list that stores the CN 500 list to which the binding refresh message should be sent. To prevent this from happening.

In the conventional IPv6 technology, since the CN is not required to respond to the binding refresh message from the terminal, in the second embodiment of the present invention, a response mandatory bit (ACK) for the CN 500 to respond in the binding refresh message is required. The Mandatory Bit is set so that the CN 500 responds to the binding refresh message sent by the terminal 100. This response mandatory bit may preferably be used by allocating one bit that is not used in the binding refresh message. For example, if the response mandatory bit is set to a value of "1", the CN 500 may be designed to respond to the binding refresh message sent from the terminal 100.

On the other hand, the terminal 100 is provided with a timer that can measure a certain time to confirm that there is no response from the CN 500 for the binding refresh message sent to the CN 500, and the terminal 100 is also CN And a counter for counting the number of times the binding refresh message has been retransmitted. Here, the timer is a timer for measuring a predetermined time since the terminal 100 sends the binding refresh message to the CN 500, and the counter is the terminal 100 sends the first binding refresh message to the CN (500). The counter counts the number of retransmissions of the binding refresh message when the binding refresh message is retransmitted to the CN 500 when there is no response from the CN 500.

Accordingly, the terminal 100 sends a binding refresh message to the CN 500, and if there is no response from the CN 500 so that the time measured by the timer becomes a predetermined time, the terminal 100 increases the number of counters and then binds again the binding refresh. Send a message to CN 500. As such, if there is no response from the CN 500 so that the number of binding refresh messages retransmitted to the CN 500 is a certain number of times by the counter, it means that an error has occurred in the CN 500. In order to release, the list of the CN 500 is removed from the binding list (S310).

If the CN 500 fails to respond to the binding refresh message sent from the terminal 100, the CN 500 is determined to be down due to an abnormal state or the mobile IP stack is down. To unbind.

Hereinafter, a binding update method in mobile IPv6 according to a second embodiment of the present invention and a terminal performing the method will be described with one specific example.

7 is a block diagram of a terminal performing binding update in mobile IPv6 according to a second embodiment of the present invention.

The same reference numerals are used for the convenience of the description of the components shown in FIG. 4 and the same functions as those shown in FIG. 4 that describe the first embodiment of the present invention.

As shown in FIG. 7, the terminal performing binding update in mobile IPv6 according to the second embodiment of the present invention includes an air interface 110, a path optimization performing unit 120, a binding refresh timer 140, and a binding. The list 150 includes a response timer 180, a retransmission counter 190, and a controller 171.

The air interface 110, the path optimization execution unit 120, the binding refresh timer 140, and the binding list 150 are described in detail with reference to FIG. 4 related to the first embodiment of the present invention. As it can be seen here, it will be briefly described here.

The wireless interface 110 provides an interface with a wireless network for allowing the terminal 100 to perform mobile communication based on the IPv6 with the CN 500 through the mobile network.

The path optimization performing unit 120 performs path optimization for allowing the terminal 100 to directly transmit and receive a packet with the CN 500 without passing through the HA 400. The path optimization performing unit 120 sets a response mandatory bit for the CN 500 to respond in the binding refresh message when the binding refresh message for the binding verification with the CN 500 is transmitted. The CN 500 must respond to the binding refresh message sent.

The binding refresh timer 140 is a timer that measures the time of a cycle negotiated with the CN 500 upon initial binding update. The binding refresh timer 140 preferably outputs a binding refresh timer expiration signal notifying when the time of the negotiated period elapses during the initial binding update. Here, the binding refresh timer 140 should be provided as many as the number of more than two CN 500 that the terminal 100 has performed the binding update.

The binding list 150 stores a list of the CNs 500 in which the terminal 100 performs a binding update.

The response timer 180 measures a time from when the binding refresh message is sent from the path optimization performing unit 120 to the CN 500, and outputs a response timer expiration signal when measured by a predetermined time. Preferably, the control unit 171 instructs the route optimization execution unit 120 to send the binding refresh message and then starts time measurement of the response timer 180.

The retransmission counter 190 counts the number of binding refresh messages retransmitted by the terminal 100 to the CN 500, and outputs a retransmission counter expiration signal when the terminal 100 counts up to a predetermined number. Preferably, the controller 171 increases the number of retransmission counters 190 after retransmitting the binding refresh message.

The controller 171 performs an initial call processing process of the terminal 100 and then performs path optimization through the path optimization execution unit 120. When the path optimization is completed, time measurement of the binding refresh timer 140 is started. In addition, when the binding refresh timer expiration signal is output from the binding refresh timer 140, the binding refresh message is transmitted to the corresponding CN 500, and at the same time, the time measurement of the response timer 180 is started. At this time, the controller 171 controls the path optimization performing unit 120 to set a response mandatory bit in the binding refresh message so that the CN 500 responds to the binding refresh message. If the response to the binding refresh message is not received from the CN 500 until the response timer expiration signal indicating that the time measurement from the response timer 180 to the predetermined time is completed, resend the binding refresh message to the CN 500. The number of retransmission counters 190 is increased. In addition, when a response to the retransmitted binding refresh message is not received from the CN 500 until a retransmission counter expiration signal indicating that the retransmission counter 190 counts up to a certain number of times is received, the corresponding CN stored in the binding list 150. Delete the list of 500.

Hereinafter, a binding update method in mobile IPv6 according to a second embodiment of the present invention will be described with reference to FIG. 8.

First, the terminal 100 obtains a CoA through a PPP negotiation with a network router 300 or a GTP tunnel local IP allocation process through a wireless network access process with the base station 200, and then performs a binding update process with the obtained CoA. It will be described on the assumption that an initial call processing process informing the HA 400 is performed.

Thereafter, the terminal 100 performs a path optimization process for transmitting and receiving a packet with the CN 500 (S400). More specifically, the controller 171 exchanges various messages with the HA 400 and the CN 500 through the path optimization performing unit 120 and the air interface 110 to perform path optimization. The control unit 171 stores the list in the binding list 150 for the CN 500 on which the path optimization has been performed so that a subsequent binding refresh operation may be continuously performed.

As such, when path optimization is performed, the terminal 100 may directly transmit traffic with the CN 500 without passing through the HA 400 thereafter.

In addition, when path optimization is performed, the controller 171 drives the binding refresh timer 140 corresponding to the CN 500 to start measurement of time until the next period (S410).

Next, the controller 171 checks whether the binding refresh timer expiration signal, which indicates that the next cycle time has elapsed, is generated from the binding refresh timer 140 (S420). If the binding refresh timer expiration signal is generated from the binding refresh timer 140, the controller 171 transmits a binding refresh message for verifying the binding with the CN 500 to the path optimization performing unit 120 and the air interface 110. Send to the CN (500) through (S430), and starts the time measurement of the response timer 180 to determine whether the response from the CN (500) (S440).

Thereafter, the controller 171 checks whether a response to the binding refresh message is received from the CN 500 (S450), and if a response is received from the CN 500, the controller 171 performs path optimization as in the prior art. Path optimization with the CN 500 is performed through the unit 120 and the air interface 110 (S460).

However, if a response is not received from the CN 500 in step S450, it is checked whether a predetermined time is measured by the response timer 180 (S470). This is confirmed by the response timer expiration signal output from the response timer 180. If the measurement is not yet performed by the response timer 180 until a predetermined time, the reception of the response from the CN 500 is confirmed until the measurement expires until the predetermined time (S450).

On the other hand, if the response timer expiration signal is output from the response timer 180 in step S70, this means that the response to the binding refresh message has not been received from the CN 500 until a predetermined time, so that the retransmission process for the binding refresh message is performed. Perform. That is, it is checked whether the binding refresh message in which no response is received is retransmitted (S480).

Since the binding refresh message sent in the step S430 is the first sent message and is not retransmitted, the controller 171 retransmits the binding refresh message (S490) and increases the number of retransmission counters 190 (S500). For example, since the retransmission is first performed here, the number of retransmission counters 190 is increased to one.

Next, the controller 171 repeatedly performs the steps S440, S450, S470, and S480 and confirms that a response to the binding refresh message retransmitted in the step S490 is not received. Of course, if a response is received from the CN 500 while performing the steps S440 and S450, the controller 171 may optimize the path with the CN 500 through the path optimization performing unit 120 and the air interface 110. Perform (S460).

However, if the response is not received from the CN 500 while performing the steps S440, S450, S470, and S480, it is again checked whether the retransmission is performed in the step S480, and here, a single binding refresh message is retransmitted ( S490), so it is confirmed as retransmission and it is checked in the retransmission counter 190 whether a certain number of counts have expired (S510).

If the retransmission counter 190 has not expired a certain number of times, i.e., in the above example, the number of times that is a certain number of times has not expired and only one number has been counted, the above steps (S490, S500, S440, S450, S470, S480, and S510 are repeated to check whether the retransmission counter 190 expires a certain number of times.

If a response from the CN 500 is not continuously received and is counted until a predetermined number of times are expired at the retransmission counter 190, the controller 171 does not need to keep the binding with the CN 500. The binding of the CN 500 is released (S520) by releasing the binding of the CN 500 (S520).

As described above, according to the second embodiment of the present invention, when no response is received from the CN 500 for a predetermined time after sending the binding refresh message, the list of the CN 500 stored in the binding list 150 is returned. By releasing and removing the binding, the burden on the terminal is reduced, and the wasteful elements of the system are eliminated, thereby enabling efficient IPv6 processing.

Meanwhile, in the first embodiment of the present invention described above, if no traffic is generated between the terminal 100 and the CN 500 for a predetermined time after the path optimization, the binding refresh message is not sent. However, the technical scope of the present invention is described. The present invention is not limited thereto, and although the traffic is not generated between the terminal 100 and the CN 500 for a predetermined time, the terminal 100 sends a binding refresh message to the CN 500, and a response thereof is a response of the present invention. As in the second embodiment, it is possible to delete the list of the CN 500 from the binding list 150 when it is not from the CN 500 for a certain time and until the number of retransmissions is a certain number of times. This configuration will be readily understood by those skilled in the art when referring to the first and second embodiments of the present invention described with reference to FIGS. 3 to 8.

Although the present invention has been described with reference to the most practical and preferred embodiments, the present invention is not limited to the above-described embodiments, but includes various modifications and equivalents within the scope of the following claims.

According to the present invention, the burden of binding update in a mobile IPv6-based terminal can be greatly reduced, thereby enabling efficient IPv6 processing in the terminal.

Claims (16)

In the binding update method in a mobile terminal, a) performing a path optimization process for the counterpart node; And b) in the path determined through the path optimization process, if the traffic with the counterpart does not occur for a predetermined time, releasing the binding to the counterpart node; Binding update method comprising a. The method of claim 1, And the predetermined time elapses before sending a binding refresh message to the counterpart node to re-verify the binding with the counterpart node in step b). The method of claim 2, And b) removing the binding of the counterpart node from the binding list storing the counterpart node to which the binding refresh message is sent in step b) and releasing the binding with the counterpart node. The method of claim 1, Step b), i) determining whether it is time to send a binding refresh message to the counterpart node to re-verify the binding with the counterpart node; ii) if it is determined that it is time to send the binding refresh message to the counterpart node, determining whether traffic with the counterpart node has occurred until the predetermined time elapses; And iii) if it is determined that traffic with the counterpart node has not occurred until the predetermined time has elapsed, releasing binding to the counterpart node; Binding update method comprising a. In the mobile terminal performing the binding update, A path optimization performing unit performing a path optimization process for the counterpart node; A traffic monitoring timer for monitoring whether traffic with the counterpart node occurs in a path determined through the path optimization process for a predetermined time; And The path optimization execution unit and the traffic monitoring timer are controlled, and the path optimization is performed until the predetermined time has elapsed by the traffic monitoring timer after the path optimization process for the counterpart node is performed. The controller releases the binding to the counterpart node when traffic with the counterpart node does not occur in the path determined through the process. A mobile terminal comprising a. The method of claim 5, The apparatus may further include a binding refresh timer measuring a predetermined cycle time after the path optimization process is performed by the path optimization execution unit. The controller may be configured to check a monitoring result of the traffic monitoring timer after the predetermined cycle time is measured by the binding refresh timer. Mobile terminal, characterized in that. The method according to claim 5 or 6, And further comprising a binding list that stores a list of partner nodes to which to send a binding refresh message to re-validate the binding. If it is determined by the traffic monitoring timer that traffic with the counterpart node has not occurred until the predetermined time has elapsed, the controller deletes the list of the counterpart node from the binding list and performs binding with the counterpart node. Released Mobile terminal, characterized in that. The method according to claim 5 or 6, The controller may be configured to send a binding refresh message through the path optimization execution unit to re-verify the binding with the counterpart node when the traffic monitoring timer determines that traffic with the counterpart node occurs before the predetermined time elapses. Mobile terminal, characterized in that sent to the counter node. In the binding update method in a mobile terminal, a) performing a path optimization process for the counterpart node; b) sending a binding refresh message to the counterpart node for revalidating the binding with the counterpart node through the path determined by the path optimization process; And c) in the path determined through the path optimization process, if there is no response from the counterpart node for a predetermined time with respect to the binding refresh message sent to the counterpart node, releasing the binding to the counterpart node; Binding update method comprising a. The method of claim 9, The predetermined time does not respond to the binding refresh message sent in the step b) until the predetermined response time has elapsed from the counterpart node, and thus, responds from the counterpart node to the predetermined number of binding refresh messages resent to the counterpart node. The binding update method, characterized in that the time corresponding to confirm that there is no. The method of claim 9 or 10, And c) canceling the binding with the counterpart node by deleting the counterpart list from the binding list storing the counterpart node to which the binding refresh message is sent in step c). The method of claim 10, Step c), i) determining whether there is no response from the counterpart node until the predetermined response time elapses for the binding refresh message sent to the counterpart node; ii) if there is no response from the counterpart node until the predetermined response time elapses, retransmitting a binding refresh message to the counterpart node; iii) determining whether there is no response from the counterpart node until the predetermined response time elapses for the retransmitted binding refresh message; And iv) if there is no response from the counterpart node until the predetermined response time elapses in step iii), releasing the binding with the counterpart node; Binding update method comprising a. The method of claim 12, Steps ii) and iii) are repeated for a predetermined number of times when there is no response from the counterpart node. In the mobile terminal performing the binding update, A path optimization performing unit configured to perform a path optimization process for a counterpart node and to send a binding refresh message to the counterpart node to re-verify the binding with the counterpart node through the path determined by the path optimization process; A response timer for measuring a predetermined response time after sending the binding refresh message to the counterpart node; And The schedule response is controlled by the response timer since the path optimization execution unit and the response timer are controlled, and the binding refresh message is sent to the counterpart node after the path optimization process is performed by the path optimization execution unit. The controller releases the binding to the counterpart node when a response to the binding refresh message is not received from the counterpart node in the path determined through the path optimization process until time passes. A mobile terminal comprising a. The method of claim 14, And a retransmission counter for counting the number of retransmissions of the binding refresh message sent by the control unit to the counterpart node through the path optimization execution unit. The control unit releases the binding with the counterpart node when a certain number of times is counted by the retransmission counter. Mobile terminal, characterized in that. The method of claim 15, The apparatus may further include a binding list that stores a list of counterpart nodes to which the binding refresh message is to be sent. The controller is configured to cancel the binding with the counterpart node by deleting the counterpart list from the binding list when the predetermined number of times is counted by the retransmission counter. Mobile terminal, characterized in that.

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