JP2009038595A - Handover control method between heterogeneous wireless access systems, and its control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a handover control method between heterogeneous wireless access systems capable of allocating an optimum access system at the initiative of a network while assuring a communication condition of a terminal; and its control system. <P>SOLUTION: This handover control method between heterogeneous wireless access systems is structured such that an anchor device 11 acting as an anchor connecting a plurality of heterogeneous wireless access systems A and B executing IP communication confirms conduction of IP layers to terminals 12 in the respective wireless access systems A and B, and handover is executed based on priority between the plurality of heterogeneous wireless access systems A and B. Its control system is also provided. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a handover control method and control system between different types of access systems.

  With the diversification of wireless access systems (WiMAX, WiFi, UTRAN / LTE, etc.), standardization of a configuration for realizing IP mobility between different types of wireless access systems is being promoted by 3GPP (3rd Generation Partnership Project) or the like.

  Among them, the terminal side does not arbitrarily select an access system, but based on the service policy on the network side, the charging disparity for each access system, subscriber information, etc. There is a need to realize mobility.

  For example, Patent Document 1 below discloses a handover method and the like performed across different radio access systems. In this method, the handover destination is determined based on the communication quality of the communication type being communicated, the quality of the communication type provided by the handover destination radio access system, and the usage status of radio resources.

  Patent Document 2 below discloses a handover method in which a mobile terminal switches connection to another radio base station as it moves in one radio access system.

In Patent Document 3 below, a mobile node having a plurality of network interface cards (NICs) can be connected to a plurality of communication link systems by each NIC, and the communication link systems are routed via an access router. A mobile communication system connected to an agent is disclosed.
In this system, an interface manager of a mobile node selects a NIC (communication link system) having a high priority every predetermined time, and an address resolution process is performed between the mobile node and the access router.

  The mobility control system between different networks disclosed in Patent Document 4 below is a foreign agent (FA) provided in a packet data gateway that mediates between a home agent (HA) provided in a GGSN of a 3GPP system, a WLAN system, and the 3GPP system. Are logically or physically connected to each other.

JP 2006-020270 A JP 2004-297130 A JP 2004-0505515 A JP 2004-297130 A

FIG. 3 shows an example of a conventional handover control system between different types of radio access systems, which includes an access system 2 having an access gateway (AGW) 1 and an access system 4 having an access gateway (AGW) 3. And an anchor device (hereinafter simply referred to as “SAE gateway”) 5 such as an SAE (System Architecture Evolution) gateway or HA (Home Agent) serving as an anchor for connecting the AGW 1 and the AGW 3 that perform IP communication. ing.
In this system, when the terminal 6 (provided with the interfaces intf6a and 6b for connecting to the access systems 2 and 4 respectively) moves from the communication area of the access system 2 to the communication area of the access system 4, the following problems are encountered. was there.

“Problem 1” Since the SAE gateway 5 executes IP layer handover triggered by the mobile IP signal from the destination AGW 3, the IP layer path is automatically switched to the destination access system 4 in this case.

“Problem 2” Even if the SAE gateway 5 is given information on the priority order and the handover is performed in accordance with the information, when the mobile IP signal is received from the AGW 3 whose priority order is set low, Since the IP communication state between the terminal 6 and the AGW 1 in the access system 2 cannot be immediately grasped, when the mobile IP signal of the AGW 3 is rejected, if the communication state on the old access system 2 side with a high priority is bad There is a possibility of falling into a communication impossible state.
When the actual wireless access system (WiFi) and a function corresponding to the AGW are loosely coupled, such as 3GPP IWLAN, the AGW cannot grasp the wireless state, and the AGW 1 and the terminal The detection time of the communication state between 6 depends on the conduction confirmation period of the IP protocol adopted in each access system.

“Problem 3” Furthermore, in the above-mentioned problem 2, there is no mechanism for detecting the communication state between AGW1 or AGW3 and the terminal 6 in response to mobility. When the continuity check period is set with the sensitivity corresponding to the mobility that is necessary, but does not know when it occurs, frequent continuity check is required, increasing the load on both the network and the terminal, and the effect of radio resources and battery Use becomes impossible.

  Therefore, the present invention solves the above-described problems, confirms the continuity state of the IP packet while reducing the IP packet transmission traffic for continuity confirmation and the processing capability, and based on the priority information between the access systems. It is an object of the present invention to provide a handover control method and a control system between different types of radio access systems in which an optimum access system can be allocated by network initiative while guaranteeing a communication state of a terminal by executing a handover.

  According to the first aspect of the present invention, an anchor device 11 serving as an anchor for connecting a plurality of heterogeneous radio access systems A and B that perform IP communication is connected to a terminal 12 in each of the radio access systems A and B. This is a handover control method between heterogeneous radio access systems that performs confirmation and executes handover based on the priority order between the plurality of heterogeneous radio access systems A and B.

  The invention according to claim 2 is the handover control method between heterogeneous radio access systems according to claim 1, wherein the anchor device 11 performs continuity confirmation of the IP layer for the terminal 12 in each of the radio access systems A and B. It is.

  According to a third aspect of the present invention, the anchor device 11 checks the continuity of the IP layer with respect to the terminal 12 when receiving the IP mobility signal from each of the radio access systems A and B. This is a handover control method between radio access systems.

  According to the fourth aspect of the present invention, the access gateways 13 and 14 of the wireless access systems A and B check the continuity of the IP layer with the terminal 12, and the anchor device 11 transmits the IP layer to the access gateways 13 and 14. The handover control method for heterogeneous radio access systems according to claim 1 inquiring about the continuity of.

  According to a fifth aspect of the present invention, the anchor device 11 controls switching of an IP path between the radio access systems A and B based on a result of confirming the continuity of the IP layer. A handover control method between different types of radio access systems according to any one of the above.

  The present invention according to claim 6 is an anchor that connects the access gateways 13 and 14 to a plurality of heterogeneous wireless access systems A and B each having access gateways 13 and 14 each having an IP mobility client function. A handover control system between different types of radio access systems, comprising an anchor device 11 that retains priority information of systems A and B, and a terminal 12 connected to the anchor device 11 via one of the access systems A and B It is.

  The present invention according to claim 7 is the heterogeneous radio access according to claim 6, wherein the anchor device 11 or each of the access gateways 13 and 14 has an IP layer continuity confirmation function between the anchor device 11 and the terminal 12. It is an inter-system handover control system.

  The handover control method between heterogeneous radio access systems according to claim 1 is characterized in that an anchor device serving as an anchor for connecting a plurality of heterogeneous radio access systems that perform IP communication is configured to Since the continuity is confirmed and the handover based on the priority order among the plurality of different types of wireless access systems is executed, the optimum access system can be assigned by the network initiative.

  In the handover control method between heterogeneous radio access systems according to claim 2, since the anchor device performs IP layer continuity confirmation with respect to a terminal in each radio access system by itself, a load is applied to each radio access system. It can be executed without spending time.

  The handover control method between heterogeneous radio access systems according to claim 3 is characterized in that the anchor device confirms the continuity of the IP layer for the terminal when receiving the IP mobility signal from each of the radio access systems. The handover can be executed while reducing the IP packet transmission traffic and the processing capacity.

  5. The handover control method between heterogeneous radio access systems according to claim 4, wherein the access gateway of each radio access system confirms the continuity of the IP layer with the terminal, and the anchor device inquires the continuity of the IP layer to the access gateway. Therefore, the load on the anchor device can be reduced.

  The handover control method between heterogeneous radio access systems according to claim 5 is characterized in that the anchor device controls switching of an IP path with each radio access system based on a result of confirming the continuity of the IP layer. Handover can be executed while guaranteeing the communication state.

  The inter-heterogeneous radio access system handover control system according to claim 6 is an anchor for connecting a plurality of heterogeneous radio access systems each having an access gateway having an IP mobility client function and the access gateways. Since it comprises an anchor device that holds priority information and a terminal connected to the anchor device via any of the access systems, the anchor device transmits an IP layer to a terminal in each of the radio access systems. By confirming the continuity and performing a handover based on the priority order among the plurality of different types of wireless access systems, an optimal access system can be assigned on a network initiative basis.

  The handover control system between different types of radio access systems according to claim 7, wherein the anchor device or each access gateway has an IP layer continuity confirmation function between the anchor device and the terminal. Handover can be executed while guaranteeing.

  An anchor device 11 serving as an anchor for connecting a plurality of heterogeneous radio access systems A and B that perform IP communication confirms the continuity of the IP layer for the terminals 12 in the radio access systems A and B, and A handover control method between different types of radio access systems for executing a handover based on a priority order between different types of radio access systems A and B.

A plurality of heterogeneous wireless access systems A and B each having access gateways 13 and 14 each having an IP mobility client function, and the priority information of the access systems A and B serving as anchors connecting the access gateways 13 and 14. A handover control system between different types of radio access systems, comprising an anchor device 11 to be held and a terminal 12 connected to the anchor device 11 via one of the access systems A and B.

  Examples of the present invention will be described.

Referring to FIG. 1, a heterogeneous radio IP layer mobility system (heterogeneous radio access system handover control system) is shown as an embodiment of the present invention.
In the present embodiment, it is assumed that Proxy Mobile IPv4 is applied.

  The SAE gateway 11 is an anchor device that serves as an anchor for connecting the access systems A and B, which are heterogeneous radio access systems that perform IP communication, has an IP mobility anchor function, and the IP mobility between the access systems A and B And priority information that makes the access system A higher priority than the access system B. Also, when establishing a communication bearer with the access systems A and B, an IP packet for continuity confirmation is transmitted to the terminal 12 via the access system A and the access system B when the mobility signal is received from the AGWs 13 and 14. And has a function of confirming the continuity of the IP layer.

  In addition, when the AGW 13 or 14 of the access system A or B has an IP layer continuity confirmation / management unit with the terminal 12, the SAE gateway 11 includes the AGW 13, By providing the function of inquiring about the continuity state of the IP layer between the terminal 14 and the terminal 12, it is possible to provide an alternative to the function of performing the continuity confirmation by transmitting the continuity confirmation IP packet.

The AGWs 13 and 14 have a network-based IP mobility client function. When a communication bearer with the terminal 12 is established in each of the access systems A and B, an IP path is routed to the own path by the SAE gateway 11 instead of the terminal 12. Make a request to switch
When the network-based IP mobility is Proxy Mobile IP, this function corresponds to a PMIP client.
The AGWs 13 and 14 have a function of sending a mobile IP signal to the SAE gateway 11 on behalf of the terminal 12 when the communication bearer with the terminal 12 is established.

  The terminal 12 individually has a communication interface intf12a with the access system A and a communication interface intf12b with the access system B. The same priority information as that of the SAE gateway 11 is preliminarily provided as service information of the terminal, in which the access system A is given priority in a state where it can communicate with both access systems A and B.

  The basic operation of Proxy Mobile IPv4 is being standardized by WiMAX Forum and IETF, and is well known to those skilled in the art. In addition, the present invention is not limited to Proxy Mobile IPv4 as network-based mobility, and detailed description thereof is omitted.

  Next, an operation example of this system (handover control method between different types of radio access systems) will be described with reference to the sequence diagram of FIG.

  Step S1 shows a state in which the terminal 12 is communicating using the access system A. That is, the communication bearer of the access system A is established between the AGW 13 and the terminal 12, and the SAE gateway 11 selects the IP path with the AGW 13.

Step S2 shows a state in which a communication bearer with the access system B is newly established as the terminal 12 moves.
In the following steps S6a, S7a, and S8a, the existing communication bearer with the access system A continues even when the communication bearer with the access system B is established. Communication with the bearer is impossible.

  In step S3, when a new communication bearer is established between the AGW 14 and the terminal 12, the AGW 14 transmits an RRQ (Registration Request) signal of Proxy Mobile IPv4 and issues a request for switching the IP path to its own route. Is going.

  In step S4, the SAE gateway 11 that has received the RRQ signal determines that the access system A has high priority based on the priority information held by itself.

  In step S5, a continuity confirmation IP packet is sent to the terminal 12 to confirm whether the L3 communication path in the access system A can be continued based on the determination in step S4.

  In step S6a, it is determined that communication with the access system A can be maintained by receiving an IP packet response from the terminal 12 via the AGW 13.

  In step S7a, an error code is given to RRA (Registration Request Acknowledge) and notified to AGW 14 in order to reject the RRQ from AGW 14 based on the determination in step S6a.

  With the above processing, it is possible to maintain IP communication via the high priority access system A even in the phase of step S8a.

  On the other hand, when the communication state of the access system A is deteriorated as the terminal 12 moves, the phase after step S6a is the process after step S6b.

  In step S6b, since the IP continuity confirmation packet from the SAE gateway 11 does not reach the terminal 12, the continuity confirmation response from the terminal 12 cannot be obtained.

  In step S7b, it is determined that the access system A having high priority cannot be used, and the RRA is normally responded to switch to the access system B in accordance with the RRQ of the AGW 14.

  By such processing, in the phase of step S8b, the IP path is switched between the SAE gateway 11 and the AGW 14, and IP communication via the access system B becomes possible.

  In this control method, in steps S6a and S6b, the SAE gateway 11, which is an anchor device that performs network-based IP mobility, confirms the continuity of IP packets in each access system, and then accesses the access systems A and B. Since the handover based on the priority order information between them is executed, an optimal access system can be allocated by network initiative while guaranteeing the communication state of the terminal 12.

  In addition, in order to realize handover based on priority information between different access systems, the SAE gateway 11 solves the above “Problem 1” and uses a mobile IP signal as an IP path switching request from a certain AGW as a trigger. Since the continuity check of the IP layer on the currently used access system is performed, the above “Problem 2” and “Problem 3” can be solved.

That is, this system and method have the following effects.
The first effect is that the SAE gateway 11 executes IP mobility between the access systems A and B based on the priority information of the access system. It can be provided.

  The second effect is that the SAE gateway 11 has a continuity confirmation function in the IP layer, and realizes IP mobility between different access systems A and B after grasping the IP layer communication state. The IP mobility control can be executed while guaranteeing not only the information but also the communication states of the access systems A and B.

  The third effect is that since the SAE gateway 11 confirms the IP communication state on the access system in response to a mobility signal from the client, it is not necessary to always perform processing for confirming the IP layer communication state. To achieve it effectively.

It is a block diagram of a handover control system between different types of radio access systems according to an embodiment of the present invention. It is a sequence diagram which shows the process of a system same as the above. It is a block diagram of the conventional handover control system between different radio access systems.

Explanation of symbols

A, B Heterogeneous wireless access system 11 Anchor device 12 such as SAE gateway Terminal 12a, 12b Interface 13, 14 Access gateway (AGW)

Claims (7)

  An anchor device serving as an anchor for connecting a plurality of heterogeneous radio access systems performing IP communication confirms the continuity of the IP layer for the terminals in each radio access system, and the priority order among the plurality of heterogeneous radio access systems A handover control method between different types of radio access systems, characterized in that a handover based on the method is executed.   2. The handover control method between heterogeneous radio access systems according to claim 1, wherein the anchor device itself performs continuity confirmation of an IP layer with respect to a terminal in each radio access system.   3. The handover control method between heterogeneous radio access systems according to claim 2, wherein the anchor device confirms the continuity of the IP layer with respect to the terminal when receiving the IP mobility signal from each radio access system.   2. The inter-heterogeneous radio access system hand according to claim 1, wherein the access gateway of each of the radio access systems confirms the continuity of the IP layer with the terminal, and the anchor device inquires the continuity of the IP layer to the access gateway. Over control method.   The heterogeneous wireless access according to any one of claims 1 to 4, wherein the anchor device controls switching of an IP path to each of the wireless access systems based on a result of confirming the continuity of the IP layer. Inter-system handover control method.   One of a plurality of heterogeneous wireless access systems each having an access gateway having an IP mobility client function, an anchor device that serves as an anchor for connecting the access gateways and holds priority information of each access system, and any of the access systems A handover control system between different types of radio access systems, comprising: a terminal connected to the anchor device via a network.   7. The handover control system between heterogeneous radio access systems according to claim 6, wherein the anchor device or each access gateway is provided with an IP layer continuity confirmation function between the anchor device and the terminal.

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