KR101310910B1 - Network based internet protocol mobility system for performing handover of each flow and method thereof - Google Patents

Abstract

Disclosed are a network-based IP mobility system for performing a flow-by-flow handover, and a flow-by-flow handover method in the system.

The network-based IP mobility system performs a handover to a different access network for each flow based on the access network information preferred for each flow in which the multi-mode mobile terminal communicates. The network-based IP mobility system determines whether handover is available for each flow when a multi-mode mobile terminal accesses through a new access network, and if a flow capable of handover exists, the flow is preferred to the access network. Perform a handover. In addition, the network-based IP mobility system periodically determines whether handover is possible based on preferred access network information per flow for a flow in which a multi-mode mobile terminal communicates, and if a flow capable of handover exists, Handover to the preferred access network. At this time, if the access network preferred by the flow is not connected, the network-based IP mobility system requests a connection to the access network and performs handover after linking with the multi-mode mobile terminal.

Flow, mobility system, handover, multi-mode mobile terminal, multi-interface

Description

Network-based IP mobility system performing handover by flow and handover method by flow in the system {NETWORK BASED INTERNET PROTOCOL MOBILITY SYSTEM FOR PERFORMING HANDOVER OF EACH FLOW AND METHOD THEREOF}

The present invention relates to a network-based Internet protocol (hereinafter referred to as "IP") mobility system. In particular, the present invention relates to a network-based IP mobility system capable of performing handover for each service flow and a method for handover for each flow in the system.

With the recent establishment of PMIPv6 as a standard in the IETF, the demand for managing IP mobility by network-based mobility management is increasing for each mobile operator.

In a conventional network-based IP mobility system, when a media connection of a mobile terminal is detected through an access system implemented in an access router of a mobile terminal, handover is performed for each access network (eg, WiFi, 3G, Wibro, LTE, etc.). .

Meanwhile, as wireless access technologies, such as WLAN, CDMA, and WiBro, are diversified in recent years, interfaces of mobile terminals are also multiplexed.

In a conventional network-based IP mobility system, when a multi-mode mobile terminal having one or more network interfaces performs a handover between interfaces, only a part of various service flows opened in the interface before the handover is performed is selected. There is no solution to a method of moving to an interface, that is, a handover method for each service flow.

So, various methods have been proposed in the IETF NetExt WG to solve such flow-specific handovers. However, most of the proposed methods have a problem that flow binding is possible only when a function is added to the mobile terminal even in the network-based IP mobility protocol. .

However, since network-based IP mobility is a method of supporting mobility in a network without the involvement of a mobile terminal, handover by flow should be possible only by the function of network equipment without adding a function in the mobile terminal, and improved service quality may be achieved. To do this, it is necessary to select an appropriate access network for each service application.

The technical problem to be achieved by the present invention is a network for performing a handover by flow to provide a service flow in an optimal wireless environment by handing over to an appropriate access network for each service flow according to the movement of a mobile terminal or a change in a wireless environment. To provide a base IP mobility system and a handover method for each flow in the system.

Handover method according to an aspect of the present invention,

A multi-mode mobile terminal having IP mobility for a multi-mode mobile terminal having a plurality of network interfaces connected through an access network, wherein the multi-mode mobile terminal performs handover for each flow in communication with a counterpart terminal. Recognizing a connection via a new access network from a mobile terminal; Determining, by the multi-mode mobile terminal, whether handover is possible for each flow communicating with the counterpart terminal through an existing access network; And if there is a flow capable of handover, performing a handover to the new access network for the flow.

Handover method according to another aspect of the present invention,

A method of performing handover for each flow in which a multi-mode mobile terminal communicates with a counterpart terminal by a mobility system that provides IP mobility for a multi-mode mobile terminal having a plurality of network interfaces connected through an access network,

Determining whether handover is possible for all flows in communication; If there is a handoverable flow, determining whether the multi-mode mobile terminal is connected to an access network to which the flow is to be handed over; If the multi-mode mobile terminal is not connected to an access network to which the flow is to be handed over, performing a connection with the multi-mode mobile terminal through an access network to which the flow is to be handed over; And performing a handover to the access network to which the corresponding flow will handover to the corresponding flow.

A mobility system according to another aspect of the present invention,

A mobility system for providing IP mobility for a multi-mode mobile terminal having a plurality of network interfaces connected through an access network, the mobility system comprising: a wireless access manager configured to control a binding to a mobile access gateway providing access to an access network; And network-based IP mobility for a multi-mode mobile terminal through binding with a mobile access gateway connected through the wireless access manager, and determines whether handover is possible for each flow being communicated by the multi-mode mobile terminal. If there is a flow that can be handed over, the mobility management unit for performing a handover to the new access network for the flow.

According to the present invention, a preferred access network may be selected for each flow and handovered for each flow.

As a result, it is possible to provide communication of improved quality of service as compared with the related art.

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. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted for simplicity of explanation, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise. Also, the terms " part, "" module," and " module "in the specification mean units for processing at least one function or operation and can be implemented by hardware or software or a combination of hardware and software .

In the present specification, a mobile terminal (MT) is a terminal, a mobile station (MS), a subscriber station (SS), a portable subscriber station (PSS), a user device (User Equipment). It may also refer to a user equipment (UE), an access terminal (AT), and the like, and may include all or some functions of a mobile terminal, a subscriber station, a portable subscriber station, a user device, and the like.

Now, a network-based IP mobility system for performing flow-by-flow handover according to an embodiment of the present invention and a flow-by-flow handover method in the system will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating a network-based IP mobility environment to which an embodiment of the present invention is applied.

As shown in FIG. 1, a multi-mode mobile terminal 10 equipped with a multi-interface is provided by mobile access gateways 30 and 40 when communicating with a counterpart terminal 20 to connect with various access networks. It is possible to connect to various access networks through different radio links WL1 and WL2, and to be connected to the network-based IP mobility system 60 via such an access network, resulting in communication with the counterpart terminal 20. Become.

Since all mobile traffic between the multi-mode mobile terminal 10 and the counterpart terminal 20 is transmitted through the network-based IP mobile system 60, the connected mobile access gateways 30 and 40 and the network-based IP mobility system 60 By the binding process between the tunnels (T1, T2) are made and traffic transmission occurs through the tunnels (T1, T2).

The multi-mode mobile terminal 10 may be handed over by network selection in a region accessible to multiple access networks at the same time through the mobile access gateways 30 and 40, and one by the movement of the multi-mode mobile terminal 10. A handover can also occur by a connection from one access network to another access network.

In the case of handover by network selection, the multi-mode mobile terminal 10 simultaneously communicates with the counterpart terminal 20 through the mobile access gateway 40 while the multi-mode mobile terminal 10 communicates with the counterpart terminal 20 through the mobile access gateway 30. Or when changing the communication path from the path through the mobile access gateway 30 to the path through the mobile access gateway 40.

In the case of a handover by the movement of the multi-mode mobile terminal 10, the multi-link mobile terminal 10 moves so that the radio link WL3 is moved by the mobile access gateway 50 different from the mobile access gateways 30 and 40. This occurs when the multi-mode mobile terminal 10 communicates with the counterpart terminal 20 through the mobile access gateway 50 when it is located in another provided access network. At this time, the mobile access gateway 50 performs traffic transmission through the tunnel T3 generated through the binding process between the network-based IP mobility system 60.

Although the multi-mode mobile terminal 10 is able to access the network-based IP mobility system 60 through both the mobile access gateways 30 and 40 during the above handover, especially in the case of handover by network selection, Without adding a function in the multi-mode mobile terminal 10, it was not possible to select only a part of various service flows opened in the interface before performing the handover and move to a new interface.

Therefore, a network-based IP mobility system 60 that receives a policy suitable for each flow from a policy server, classifies flows, and hands over to an appropriate access network for each flow to be distinguished will be described.

2 is a block diagram of a network-based IP mobility system according to an embodiment of the present invention.

As shown in FIG. 2, the network-based IP mobility system 60 according to an embodiment of the present invention includes a flow manager 610, a mobility manager 620, and a wireless access manager 630.

The flow management unit 610 receives the criteria for classifying flows from an external policy server (not shown) and preferred access network information in order to ensure the performance of the flows, and thus, the multi-mode mobile terminal 10 and the counterpart terminal 20 are provided. Distinguish the flow of mobility traffic between Here, a variety of criteria may be used as a criterion for dividing the flow. For example, 5 tuples may be the criterion. At this time, 5 tuples correspond to source and destination IP address, source and destination port number, and protocol ID. That is, the flow manager 610 classifies each flow based on five tuples.

The flow manager 610 transmits the preferred access network information for each flow to the mobility manager 620.

The mobility manager 620 supports network-based IP mobility for the mobile terminal through binding with the mobile access gateways 30, 40, and 50. In particular, the mobility management unit 620 manages binding entries for each flow, and determines preferred handover for each flow by managing preferred access network information for each flow.

If the flow is not bound to the mobile access gateway to be handed over, the mobility manager 620 requests a new wireless connection to the wireless access manager 630 to bind to the mobile access gateway and through the mobile access gateway. Link connection with the multi-mode mobile terminal 10 can be performed.

The radio access manager 630 controls the network-based IP mobility system 60 and the mobile access gateway 30, 40, 50 to be connected through binding. In particular, the wireless access manager 630 requests a link connection to the mobile access gateway according to the request of the mobility manager 620 for the mobile access gateway that is not bound to the connection, and connects through binding between the mobile access gateways. In this case, a link connection with the multi-mode mobile terminal 10 is performed through the corresponding mobile access gateway.

Meanwhile, the mobility manager 620 determines whether there is a binding request from the multi-mode mobile terminal 10 through the new mobile access gateway through the radio connection manager 630. If there is a binding request through the new mobile access gateway, it is determined whether there is a mobile access gateway already having a binding connection with the multi-mode mobile terminal 10, and if so, traffic flows provided through the mobile access gateway. It is determined whether handover to the new mobile access gateway based on the flow-specific preferred access network information for. If a handover is determined to the new mobile access gateway, the mobility manager 620 controls the handover to be provided through the new mobile access gateway for the determined flow.

In addition, the mobility manager 620 periodically determines whether to handover all the flows provided to the multi-mode mobile terminal 10. Here, handover is determined based on preferred access network information for each flow provided through one mobile access gateway. That is, when the access network through which the flow is connected through another mobile access gateway is the preferred access network of the flow, the handover is determined so that the flow is transmitted through the other mobile access gateway.

Hereinafter, a handover method for each flow according to the first embodiment of the present invention will be described with reference to FIG. 3.

The multi-mode mobile terminal 10 is equipped with a multi interface for connecting with various access networks. In particular, the multi-mode mobile terminal 10 is equipped with an interface connectable to each access network through the mobile access gateways 30 and 40.

First, the network-based IP mobility system 60 prefers flow policy information from the policy server (not shown) provided outside or inside, for example, to distinguish the flow policy and flow performance to ensure the performance of the flow. It is assumed that the access network information is received (S10). Here, the flow policy may include information such as a criterion for distinguishing flows and access network information preferred by each flow as described above. Since this is information that can be changed at any time in a wireless environment design, the network-based IP mobility system 60 May receive flow policy information from the policy server from time to time.

When the multi-mode mobile terminal 10 requests the mobile access gateway 30 to connect to the counterpart terminal 20 through the radio link WL1, the multi-mode mobile terminal 10 between the multi-mode mobile terminal 10 and the mobile access gateway 30 is connected. A layer 2 connection is established at step S100.

The tunnel T1 is generated between the mobile access gateway 30 and the network-based IP mobility system 60 by the mobile access gateway 30 performing a binding process (S110) with the network-based IP mobility system 60. It becomes (S120).

Thereafter, the multi-mode mobile terminal 10 communicates with the counterpart terminal 20 through the mobile access gateway 30 and the network-based IP mobility system 60 (S130). For example, as shown in FIG. 3, the multi-mode mobile terminal 10 and the counterpart terminal 20 have two flows (flows 1, 2) through the mobile access gateway 30 and the network-based IP mobility system 60. Communication is performed in flow 2).

As such, while the multi-mode mobile terminal 10 communicates with the counterpart terminal 20 only through the mobile access gateway 30, the multi-mode mobile terminal 10 moves or changes in the radio environment of the access network. When the multi-mode mobile terminal 10 becomes accessible to the mobile access gateway 40, the multi-mode mobile terminal 10 links the mobile access gateway 40 to the mobile access gateway 40 via the wireless link WL2 with the counterpart terminal 20. Request a connection. By this request, another layer 2 connection is established between the multi-mode mobile terminal 10 and the mobile access gateway 40 (S140).

Thereafter, the mobile access gateway 40 performs the binding process S150 with the network-based IP mobility system 60, and as a result, a tunnel T2 is generated between the network-based IP mobility system 60. (S160).

As such, when a connection is made between the network-based IP mobility system 60 and the multi-mode mobile terminal 10 via the new mobile access gateway 40, the network-based IP mobility system 60 has previously connected. It is determined whether or not handover should be performed for each flow in which communication is performed through the mobile access gateway 30, that is, flow 1 and flow 2 (S170). Here, the determination of whether to perform the handover for each flow is based on the preferred access network information for each flow among the flow policies transmitted from the policy server (not shown). For example, to the flow-specific preferred access network information transmitted from the policy server (not shown) to the network-based IP mobility system 60, the access network to which the preferred access network of flow 1 is connected by the mobile access gateway 30 is provided. It is assumed that the preferred access network of flow 2 is an access network connected by the mobile access gateway 40. In this case, the network-based IP mobility system 60 determines that the flow 2 of the flows is handed over to the new access network, that is, the access network connected by the newly connected mobile access gateway 40.

Accordingly, the network-based IP mobility system 60 determines whether there is a flow to perform handover based on the determination of whether to perform the handover (S180).

If it is determined in step S180 that there is a flow that needs to be handed over, that is, if it is necessary to perform handover for flow 2 in the above example, the network-based IP mobility system 60 moves to the mobile access gateway. (30, 40) and in cooperation with the multi-mode mobile terminal 10 performs a handover for the flow (flow 2 in the above example) (S190). In the above example, handover from mobile access gateway 30 to mobile access gateway 40 is performed for flow2.

Thereafter, the multi-mode mobile terminal 10 transmits the flow 1 through the mobile access gateway 30 as before, but the flow 2 on which the handover is performed through the new mobile access gateway 40 ( S200).

Therefore, due to the handover, the flow 2 transmits the multi-mode mobile terminal 10 and the counterpart terminal 20 through the tunnel 2 (T2) generated between the mobile access gateway 40 and the network-based IP mobility system 60. Communication between and is performed.

As described above, according to the first embodiment of the present invention, it is possible to select a preferred access network for each flow and perform handover, thereby providing communication of improved quality of service as compared with the related art.

Meanwhile, in the above description, only the flow-by-flow handover is performed when the multi-mode mobile terminal 10 is connected to the mobile access gateway 40 in a state of being connected to the mobile access gateway 30. The scope is not limited thereto, and the multi-mode mobile terminal 10 is previously connected even when newly connected to the mobile access gateway 40 in a state of being connected to two or more mobile access gateways including the mobile access gateway 30. It is also possible that the handover is determined for all the flows in which the two or more mobile communication gateways are communicating, and if necessary, flow-by-flow handover to the mobile access gateway 40 may be performed.

Next, a flow handover method according to a second embodiment of the present invention will be described with reference to FIGS. 4 and 5.

First, the network-based IP mobility system 60 receives and stores the preferred access network information for each flow in order to ensure the performance of the flow and the criteria for classifying flows from a policy server (not shown) provided outside or inside (S30). Is the same as in the first embodiment described above.

In addition, the multi-mode mobile terminal 10 is connected to the mobile access gateway 30 via a wireless link (WL1) (S300), the mobile access gateway 30 is bound to the network-based IP mobility system 60 ( When the tunnel T1 is generated by performing S310 (S320), the multi-mode mobile terminal 10 flows two flows with the counterpart terminal 20 through the mobile access gateway 30 and the network-based IP mobility system 60. The process of performing communication in (flow 1, flow 2) (S330) is also the same as the steps (S100 to S130) in the above-described first embodiment, detailed description thereof will be omitted here.

Meanwhile, the network-based IP mobility system 60 determines whether handover is possible for all flows in communication through the mobile access gateway 30 periodically or at a request of an administrator (S340). In this case, it is determined whether handover for the flow is possible based on the flow policy received in the step S30, in particular, the access network information for each flow.

The network-based IP mobility system 60 checks whether the access network currently communicating for all flows is the preferred access network. Otherwise, the access network preferred by the flow is determined by the multi-mode mobile terminal 10. It is determined whether or not handover is possible by determining whether the access network is accessible.

For example, for the multi-mode mobile terminal 10, it is determined whether handover is performed for flow 1 and flow 2.

As in the first embodiment described above, in the preferred access network information for each flow among the policy information transmitted from the policy server (not shown) to the network-based IP mobility system 60, the preferred access network of the flow1 is the mobile access gateway. Assume that it is an access network connected by 30, and that the preferred access network of flow 2 is an access network connected by the mobile access gateway 40. In this case, since the network-based IP mobility system 60 performs the above step S340, among the flows, flow 1 corresponds to the access network to which the preferred access network is currently communicating, so handover is not possible for the flow 1. Judging by it.

However, for flow 2, the preferred access network is not the access network connected by the mobile access gateway 30, but the preferred access network is the mobile access gateway 40 to which the multi-mode mobile terminal 10 can connect. It is determined that handover is possible since the access network is provided through the access network. Therefore, it is determined that it is better to perform a handover to the new access network, that is, the access network connected by the mobile access gateway 40, for the flow2.

Accordingly, the network-based IP mobility system 60 determines whether there is a flow to perform handover based on the determination of whether to perform the handover (S350).

On the other hand, when it is determined that it is better to be transmitted through the mobile access gateway 40 as in flow 2, the flow 2 is connected by the mobile access gateway 40 from the access network connected by the mobile access gateway 30 to flow 2. Handover must be performed to the access network.

However, if the access network to be handed over, i.e., the access network connected by the mobile access gateway 40 is not connected between the network-based IP mobility system 60 and the multi-mode mobile terminal 10, the flow 2 Handover is impossible.

Therefore, if there is a flow to perform the handover in step S350, it is determined whether the access network to handover to the flow is connected to the network-based IP mobility system 60 (S360).

If the access network to which the flow is to be handed over is not connected, the network-based IP mobility system 60 requests a connection from the mobile access gateway that provides access of the access network to be handed over to the multi-mode mobile terminal 10. Perform the connection of. More specifically, and with an example of flow 2, network-based IP mobility system 60 moves multi-mode to mobile access gateway 40 for access to an access network accessible by mobile access gateway 40. The terminal 10 specifies a binding request (S370).

Therefore, the mobile access gateway 40 requests a link connection to the multi-mode mobile terminal 10 (S380), and performs a link 2 connection with the multi-mode mobile terminal 10 (S390).

Thereafter, the mobile access gateway 40 performs a binding process (S400) with the network-based IP mobility system 60 to generate a tunnel T2 between the network-based IP mobility system 60 (S410). .

As such, when the network-based IP mobility system 60 is connected with the multi-mode mobile terminal 10 through the mobile access gateway 40, the network-based IP mobility system 60 is connected to the mobile access gateways 30 and 40 and the multi-mode. In cooperation with the mode mobile terminal 10, a handover is performed for the flow 2 (S420). In the above example, handover from mobile access gateway 30 to mobile access gateway 40 is performed for flow2.

Meanwhile, if the access network to which the flow 2 is to be handed over in step S360 is connected, the network-based IP mobility system 60 also provides the mobile access gateways 30 and 40 and the multi-mode mobile terminal 10 for the flow 2. ) And performs a handover with respect to flow 2 (S420).

Thereafter, the multi-mode mobile terminal 10 transmits the flow 1 through the mobile access gateway 30 as before, but the flow 2 through which the handover is performed through the newly connected mobile access gateway 40. (S430).

Therefore, due to the handover, the flow 2 transmits the multi-mode mobile terminal 10 and the counterpart terminal 20 through the tunnel 2 (T2) generated between the mobile access gateway 40 and the network-based IP mobility system 60. Communication between and is performed.

As described above, even in the second embodiment of the present invention, it is possible to select a preferred access network for each flow and perform handover, thereby providing communication of improved quality of service compared to the conventional art.

Meanwhile, in the above description, only the handover is determined for each flow to the mobile access gateway 40 while the multi-mode mobile terminal 10 is connected to the mobile access gateway 30. However, the technical scope of the present invention is described herein. In this case, the handover of each flow to the two or more mobile access gateways including the mobile access gateway 40 is determined, and handover to the preferred access network for each flow is required. It is also possible to perform a handover per flow.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

1 is a diagram illustrating a network-based IP mobility environment to which an embodiment of the present invention is applied.

2 is a block diagram of a network-based IP mobility system according to an embodiment of the present invention.

3 is a flowchart of a handover method for each flow according to a first embodiment of the present invention.

4 and 5 are flowcharts of a flow-specific handover method according to a second embodiment of the present invention.

Claims (16)

In a method in which a mobility system providing Internet Protocol (IP) mobility for a multi-mode mobile terminal having a plurality of network interfaces connected through an access network performs handover for each flow in which the multi-mode mobile terminal communicates with a counterpart terminal. In The mobile system recognizing that the multi-mode mobile terminal, which is already connected to the mobility system via an existing access network, connects through the new access network while maintaining the connection through the existing access network; When it is recognized that the multi-mode mobile terminal accesses through a new access network, the mobility determines whether the multi-mode mobile terminal can handover to the new access network for each flow communicating with the counterpart terminal through the existing access network. Determining by the system; And If there is a flow capable of handover, the mobility system performing a handover to the new access network for the flow / RTI > The method of claim 1, After the step of performing, Causing the multi-mode mobile terminal to communicate with the counterpart terminal through the new access network for the corresponding flow; The handover method further comprising: The method according to claim 1 or 2, Before the step of recognizing, further comprising the step of receiving the preferred access network information per flow from the policy server, And in the determining step, determining whether the handover is possible based on preferred access network information for each flow. The method of claim 3, When a tunnel is created through a binding process between a mobile access gateway providing access to the new access network, a handover method for recognizing a connection through the new access network from the multi-mode mobile terminal. . In a method in which a mobility system providing Internet Protocol (IP) mobility for a multi-mode mobile terminal having a plurality of network interfaces connected through an access network performs handover for each flow in which the multi-mode mobile terminal communicates with a counterpart terminal. In Determining whether handover is possible for all flows in communication; If there is a handoverable flow, determining whether the multi-mode mobile terminal is connected to an access network to which the flow is to be handed over; If the multi-mode mobile terminal is not connected to an access network to which the flow is to be handed over, performing a connection with the multi-mode mobile terminal through the access network to which the flow is to be handed over; And Performing a handover to the access network to which the corresponding flow will hand over to the corresponding flow; / RTI > The method of claim 5, After the step of performing, Causing the multi-mode mobile terminal to communicate with the counterpart terminal through the access network to which the flow is to be handed over; The handover method further comprising: The method according to claim 5 or 6, Receiving preferred access network information for each flow from a policy server before the step of determining whether the handover is possible, Handover method characterized in that it is determined whether the handover is possible based on the access network information preferred for each flow The method of claim 7, wherein In the determining of whether the handover is possible, if the access network preferred by the flow being communicated is not the access network to which the communicating flow is connected, the multi-mode mobile terminal is accessible to the preferred access network. Handover method characterized in that it is determined that the over is possible. The method of claim 7, wherein The step of performing the connection, Requesting, by the mobility system, a binding to a mobile access gateway that provides access to an access network to which the flow will handover; The mobile access gateway performing a link connection with the multi-mode mobile terminal; The mobile system performing a binding process with the mobile access gateway; And The mobility system creating a tunnel with the mobile access gateway / RTI > A mobility system for providing IP (Internet Protocol) mobility for a multi-mode mobile terminal having a plurality of network interfaces connected through an access network, A wireless access manager configured to control a connection to a mobile access gateway providing a connection to an access network through a binding; And Supports network-based IP mobility for a multi-mode mobile terminal through binding with a mobile access gateway connected through the wireless access manager, determines whether handover is possible for each flow being communicated by the multi-mode mobile terminal, If there is a flow capable of handover includes a mobility management unit for performing a handover to the new access network for the flow, When the mobility management unit recognizes that the multi-mode mobile terminal, which is already connected to the wireless access manager through the existing access network, connects through the new access network while maintaining the connection through the existing access network, The multi-mode mobile terminal determines whether it is possible to handover to the new access network for each flow communicating with the counterpart terminal through the existing access network, and performs handover to the new access network for the possible flow. Mobility system, characterized in that. delete The method of claim 10, The mobility management unit, A mobility system, characterized in that it is determined periodically whether the handover is possible for all flows in communication through the existing access network. 13. The method according to claim 10 or 12, The mobility system further comprises a flow management unit for receiving the preferred access network information for each flow from the policy server to the mobility management unit. 14. The method of claim 13, The mobility management unit, And determining whether the handover is possible based on the access network information preferred for each flow. The method of claim 14, The mobility management unit, The method may determine that handover is possible for the flow when the access network preferred by the flow is not an access network to which the flow is connected and the multi-mode mobile terminal is accessible to the access network preferred by the flow. Mobility system. 16. The method of claim 15, And the mobility management unit performs a connection to the access network to which the flow is to be handed over to, if the access network to which the flow is to be handed over is not connected.

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