KR100935637B1 - Fast Route Optimization for PMIPv6Proxy Mobile IPv6 - Google Patents

Abstract

The present invention relates to a fast path optimization method according to a fast handover of a mobile terminal communicating using an optimized path between access routers based on a proxy mobile IPv6 protocol. A route optimization method has been proposed to use an optimized route between access routers instead of via an anchor router in a domain when communicating with a counterpart node using the PMIPv6 protocol of a mobile terminal. However, when the mobile terminal performs a handover to another access router, in the conventional scheme, there is overhead due to the repetition of PMIPv6 and the path optimization process, and the data propagation delay is increased. In order to solve this problem, the present patent seeks to provide a method of speeding up a PMIPv6-based path optimization procedure by detecting movement using a lower link signal. In addition, through the context transfer method between access routers to provide a method for reducing the prediction failure that can appear in the prediction-based procedure for providing high-speed mobility. By utilizing this technique, it is possible to provide high-speed mobility of a mobile terminal using a path optimization method, and improve packet forwarding delay.

PMIPv6, high-speed path optimization, handover context transfer of mobile terminals, use of downlink signals

Description

Fast Route Optimization for Proxy Mobile IP {Fast Route Optimization for PMIPv6}

The present invention supports fast path optimization when a mobile terminal handover occurs in a proxy mobile IP domain that supports path optimization. More specifically, a new AR adjacent to a previous AR detecting a movement of the mobile terminal by using a lower link signal is adjacent to the new mobile terminal. High speed in proxy mobile IP to reduce the signaling overhead caused by repeated PMIPv6 signaling and path optimization during mobile device's movement by delivering the context message of mobile terminal to candidate AR and at the same time It relates to a path optimization method.

Conventionally, the regional mobility management based on PMIPv6, which is carried out by the Internet Engineering Task Force (IETF) NetLMM working group, performs the AR updating of the network and data tunneling of the mobile terminal according to the movement of the mobile terminal. However, when the mobile terminal communicates through the local anchor router of each network, there is a problem that the packet forwarding cost is larger than when directly communicating between the AR. In this regard, the IETF NetLMM Working Group has submitted drafts related to path optimization and proposed methods for direct communication between ARs.

However, in the path optimization state, when the mobile terminal handovers, there is a problem that the repetitive overhead according to the PMIPv6 signaling and the path optimization procedure and the communication delay with the counterpart node increase. Therefore, a method for detecting the movement of the mobile terminal by the AR and optimizing the route at high speed during the movement of the mobile terminal is urgently needed.

In order to solve the above problems, the present invention minimizes the delay with the counterpart node after detecting the movement of the mobile terminal by the AR when the mobile terminal using Proxy Mobile IPv6 is in the path optimization state. It is an object of the present invention to provide a fast path optimization method in a proxy mobile IP which supports fast handover.

In the proposed method for enabling PMIPv6 based high-speed path optimization, the movement detection of the terminal uses a signal attenuation and signal disconnection detection technique using the link signal of the terminal by the access router. In addition, as a method for reducing the delay time occurring after the handover of the terminal, candidate access routers receiving the terminal handover context message during the handover of the terminal may perform an update to the access router of the other node in advance. Use

The effects of the present invention having the above configuration are as follows.

First, since the mobile terminal detects movement of the mobile terminal and transmits handover context information of the mobile terminal to neighboring new candidate ARs, and performs a fast path optimization update process in advance, the signaling cost to be suffered after handover of the mobile terminal is reduced.

Second, when the mobile terminal and the counterpart node in each PMIPv6 domain communicate with each other through the optimized path, the counterpart node and the counterpart node reduce the signaling overhead performed on the network through the fast path optimization method according to the movement of the mobile terminal. Communication delay is reduced.

Third, the handover failure rate according to the movement prediction of the mobile terminal is drastically reduced through the handover context message previously transmitted to the new candidate ARs by the previous AR.

EMBODIMENT OF THE INVENTION Hereinafter, this invention of the said structure is demonstrated in detail, referring an accompanying drawing. However, about the element which has the same structure, and has the same function, detailed description is abbreviate | omitted by keeping the same code | symbol even if drawing differs.

FIG. 1 is a conceptual diagram illustrating a network structure that becomes an operating environment of PMIPv6. The mobile terminal 100 includes a mobile terminal 100, a previous AR 310, a new candidate AR # 1 320, and a new candidate AR # 2. 330 and the partner node 200 communicating with the mobile terminal in the partner node network 400 and the partner node AR 410 are shown.

According to the present invention, when the conventional AR 310 and the counterpart node AR 410 perform path optimized communication, the mobile terminal 100 is different from the access router 330. The present invention relates to a technique for supporting path optimization at high speed during low handover.

2 is a flowchart illustrating a handover procedure using PMIPv6 in a specific local area network 300. When the ID of the mobile terminal is transmitted to the AR 310, the conventional AR 310 requests the regional policy server 360 to verify the authentication of the mobile terminal. If the authentication is successful, the network prefix and AR ( 310 informs the address of the anchor router 350 to be connected. After receiving the prefix of the home network, the mobile terminal generates an address through an automatic IPv6 address setting process, and then registers the address, ID information, and the home network prefix of the mobile terminal with the anchor router using the Proxy Binding Update process. The same procedure is performed in the other AR 330 at the handover of the mobile terminal, and the address is not generated again except when the network prefix is first received.

By using PMIPv6, when the mobile terminal 100 and the counterpart node 200 communicate with each other, the mobile terminal 100 prevents tunneling overhead occurring through a wireless tunnel, and the mobile terminal detects a change in the network when moving. There is an advantage that does not need to handle the signaling update. However, when the mobile terminal 100 and the counterpart node 200 communicate with each other via the anchor router 350 of each network, there is a problem in that a packet forwarding cost is large. In order to solve this problem, a path optimization method for supporting direct communication between ARs 310 and 340 without passing through the anchor router 350 of each network is required.

3 is a personal draft currently proposed to the IETF, and the conventional AR 310 and the anchor node 350 in the mobile terminal network 300 and the partner node AR 410 in the partner node network 400 in a structure using PMIPv6. ) And a path optimization process between the anchor router 420.

The mobile terminal network anchor router 350 requests a route optimization attempt to the anchor router 420 of the partner node network 400, and when the anchor router 420 receives the request, the mobile terminal network anchor router 350 accepts the request. An initialization procedure is performed. The counterpart node AR receives the route optimization request and the corresponding response directly to the previous AR and reports it to its anchor router. In addition, as the results are exchanged between the anchor routers, data communication is possible through an optimized path between the conventional AR and the counter node AR.

4 is a personal draft currently proposed to the IETF, and shows a PBU / PBAck process with the anchor router 350 and a signaling update process for path optimization after the mobile terminal hands over to a new AR. This process requires a considerable signaling cost to communicate through the optimized path between the mobile terminal and the counterpart node, and additional delay occurs because the data is passed through the anchor router in each proxy mobile IP domain.

FIG. 5 is a flow chart for the fast path optimization proposed by the present invention and is described in the following procedure. In a situation in which communication between the ARs 310 and 410 in each of the networks 300 and 400 is performed through an optimized path, when the mobile terminal tries to move to another place in the mobile terminal network 300, the lower link signal attenuation is performed. The previous AR 310 that detects the movement of the mobile terminal sends a fast path optimization attempt request to the anchor router 350 of the network and is also transmitted to the anchor router 420 of the partner node network. When the anchor router 420 of the partner node network permits this, a fast path optimization attempt response message is transmitted to the mobile terminal network anchor router 350, and the message is transmitted to the previous AR again to know that the fast path optimization attempt is allowed. . Thereafter, the previous AR 310 detects that the lower link signal of the mobile terminal is disconnected, sends a handover context message of the mobile terminal to neighboring new candidate ARs 320 and 330, and receives the new candidate ARs 320 and 330. ) Updates the information of the mobile terminal 100 in advance by sending a fast path optimization update request message to the counterpart node AR 410, and the counterpart node AR 410 informs the new candidate ARs 320 and 330 that sent the message. Perform the fast path optimization update response procedure. After receiving the response, the ARs 320 and 330 wait for a specific time to enter the mobile terminal, and the mobile terminal 100 receives a new candidate AR # 2 330 among the adjacent new candidate ARs 320 and 330 within a specific time. Upon arrival, the new candidate AR # 2 330 that detects the mobile terminal 100 that performed the handover sends a fast path optimization update completion message to the counterpart node AR 410 so that the mobile terminal hands the corresponding AR 410. Indicate that it is over. The new candidate AR # 2 330 may perform path optimized communication with the counterpart node 200 via the counterpart node AR 410.

The counterpart node AR 410 performs the fast path optimization completion procedure on the anchor router 420 of the counterpart node network, indicating that the AR 330 of the mobile terminal has been changed, and the anchor router 420 is again mobile. Send to the anchor router 340 of the terminal network, and performs the fast path optimization complete response process in the opposite path.

Through the above procedure, in performing the handover of the mobile terminal 100, the delay between the mobile terminal 100 and the counterpart node 200 is minimized without incurring additional signaling update overhead until the basic procedure of PMIPv6 and path optimization. It provides high speed path optimization service.

6 illustrates a process of transferring handover context information of the mobile terminal 100 from the previous AR 310 to the adjacent new candidate ARs 320 and 330 in preparation for where the mobile terminal 100 moves. The previous AR 310 has list information on adjacent ARs, and the handover context information is delivered to the new candidate ARs 320 and 330 corresponding thereto.

FIG. 7 illustrates a fast path optimization attempt sent by an AR 310 that detects an attempt to move a mobile terminal through a lower link signal attenuation, and the anchor router 350 to a counterpart node network anchor router 420. Indicates a request message. The message includes an IPv6 header, a mobility option, a fast path optimization option included in the mobility option, a new candidate AR address option to establish a connection, and a partner node AR address option.

FIG. 8 is a handover context message of a mobile terminal sent by a previous AR 310 for detecting a fast path optimization update request of new candidate ARs 320 and 330 by detecting a movement of the mobile terminal through a lower link signal disconnection. The message includes a UDP header, a handover context message header of a terminal, a home network prefix of a mobile terminal, a home network prefix and a MAC address for directly forwarding a packet without finding the mobile terminal, and a network access identifier (NAI) for identifying a mobile terminal. The new candidate AR address, the partner node AR address, and the anchor router address of the new candidate AR to be connected are included.

9 is a path fast path optimization update request, response, and completion message that new candidate ARs exchange with a corresponding node AR. Request and response messages include IPv6 Header, Mobility Options, Fast Path Optimization Options, Mobile Network Home Prefix Options, Mobile Terminal NAI Options, New Candidate AR Address Options, and Partner Node AR Address Options. The messages are separated by. The update completion message is given the MAC address of the mobile terminal instead of the home network prefix option so that the opposite node AR can directly forward the packet.

10, after completing the fast path optimization update procedure, a new node for communicating with the mobile terminal is a message for notifying each anchor router of the fast path optimization completion so that packets are delivered to the new AR. This includes IPv6 Header, Mobility Options, Fast Path Optimization Options, Mobile Network Home Prefix Options, Mobile Terminal NAI Options, New Candidate AR Address Options, and Counter Node AR Address Options.

In the above, the present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited thereto, and improvements and modifications within the scope not departing from the gist of the present invention should be interpreted to belong to the present invention. Do.

1 is a conceptual diagram showing a network structure serving as an operation environment of PMIPv6;

2 is a flowchart when a mobile terminal performs handover using PMIPv6;

3 is a flowchart illustrating a path optimization procedure of PMIPv6;

4 is a flowchart illustrating a path optimization procedure according to handover of a mobile terminal in a path optimization state;

5 is a flowchart illustrating a fast path optimization procedure according to handover of a mobile terminal in a path optimization state according to the present invention;

6 is a conceptual diagram of handover context message delivery of a mobile terminal sent to new candidate ARs sent by previous ARs during handover of the mobile terminal in the path optimization state according to the present invention;

7 is a fast path optimization attempt request message sent to a local mobility anchor in a domain by an AR detecting a lower link signal of a mobile terminal according to the present invention;

8 is a handover context transfer message of a mobile terminal delivered to new candidate ARs by a previous AR detecting disconnection of a lower link signal of the mobile terminal according to the present invention;

9 is a message for performing a fast path optimization update request, response, and completion during a mobile terminal handover between new candidate ARs and a counterpart node AR according to the present invention;

10 is a message for conveying a fast path optimization complete and complete response between a counterpart node AR and each local mobility anchor according to the present invention.

<Description of the reference numerals for the main parts of the drawings>

100: mobile terminal

200: relative node

300: mobile terminal network

310: Previous AR

320: new candidate AR # 1

330: new candidate AR # 2

340: new AR

350: mobile terminal network anchor router

360: mobile terminal network regional policy server

400: partner node network

410: relative node AR

420: partner node network anchor router

500: Internet network

Claims (8)

In the fast path optimization method in proxy mobile IP, A first step of detecting a lower link signal attenuation of a mobile terminal transmits a fast route optimization attempt request message to an anchor router, and the receiving anchor router transmits the request to the anchor router of the partner node network or receives the opposite path through the opposite path. Wow; A second step of the previous AR detecting the loss of the lower link signal of the mobile terminal, transmitting a handover context message of the mobile terminal to adjacent new candidate ARs; Receiving, by the neighboring new ARs receiving the handover context message of the mobile terminal, a fast path optimization update request message to the counterpart node AR, and receiving a fast path optimization update response thereto; A fourth step of, after the mobile terminal handovers to a new AR, sending a fast path optimization update complete message to the counterpart node AR by the new AR; Sending a fast path optimization complete message to the anchor router based on the fast path optimization update complete message; The anchor router receiving the fast path optimization complete message sends a fast path optimization complete message to the anchor router of the mobile terminal network, receives a fast path optimization complete response message thereto, and sends the message back to the counterpart node AR. And a sixth step of transmitting the fast path optimization method in the proxy mobile IP. delete delete delete The method of claim 1, The fast path optimization attempt request and response message includes an IPv6 header, a mobility option, a fast path optimization option, a new candidate AR address option, and a partner node AR address option. The method of claim 1, The handover context message of the mobile terminal may include a UDP header, a handover context message header of the terminal, a home network prefix of the mobile terminal, a MAC address of the mobile terminal, a NAI of the mobile terminal, a new candidate AR address, a partner node AR address, and a mobile terminal. Fast route optimization method in a proxy mobile IP, characterized in that it comprises a network local mobility anchor address. The method of claim 1, Fast Path Optimization update request and response and completion messages include IPv6 Header, Mobility Option, Fast Path Optimization Option, Mobile Network Home Prefix Option, Mobile Device MAC Address Option, Mobile Device NAI Option, New Candidate AR Address Option, Relative Fast route optimization method in a proxy mobile IP, characterized in that it comprises a node AR address option. The method of claim 1, The fast path optimization complete and completion response message includes an IPv6 header, mobility options, fast path optimization options, a home network prefix option of a mobile terminal, a NAI option of a mobile terminal, a new candidate AR address option, and a partner node AR address option. A fast route optimization method for proxy mobile IPs.

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