KR20190022292A - Method and wireless communication system for traffic mobility between heterogeneous access networks - Google Patents

Abstract

A method for moving traffic between heterogeneous access networks in a wireless communication system comprises the steps of: setting a first transmission path corresponding to a first access network and a second transmission path corresponding to a second access network to a terminal by a gateway, as the terminal performs multi-access to the first access network and the second access network; determining, by a control entity, whether a traffic for each traffic flow is moved, based on a traffic movement policy of each traffic flow served to the terminal through the first transmission path and a transmission state of the second access network; and changing, by the gateway, a transmission path of the traffic flow, in which the traffic movement is determined, from the first transmission path to the second transmission path.

Description

TECHNICAL FIELD [0001] The present invention relates to a method for moving traffic between heterogeneous access networks, and a wireless communication system for performing the method.

An embodiment of the present invention relates to a method for moving traffic between heterogeneous access networks and a wireless communication system for performing the method.

Prior to the arrival of the 5G network environment, various wireless network environments such as 3GPP based 4G LTE and 802.11 based WiFi coexist in the mobile wireless network environment.

Accordingly, there is a growing demand for optimal service according to coexistence of various wireless networks in the 5G network. In particular, when users want to connect to different radio access networks (RANs) to transmit and receive traffic, techniques are required to support the mobile terminals to select a radio access network that matches the traffic attributes and to transmit traffic have. Traffic mobility technology can support users to receive more economical data transmission services and can support increase of transmission capacity available to users.

In 4G mobile communication, data offloading technology using access network discovery and selection function (ANDSF) is introduced to support traffic movement in LTE and WiFi multiple access environments.

A problem to be solved through embodiments of the present invention is to provide a method for supporting traffic movement between access networks when a terminal accesses a plurality of access networks at the same time and transmits / receives traffic in an environment where heterogeneous wired / wireless access networks are mixed together To a wireless communication system.

According to another aspect of the present invention, there is provided a method for moving a traffic between heterogeneous access networks in a wireless communication system, the method comprising the steps of: Setting a first transmission path corresponding to the first access network and a second transmission path corresponding to the second access network, respectively, wherein the control entity is configured to transmit, for each traffic flow served to the terminal via the first transmission path, The method comprising the steps of: determining whether to move traffic for each traffic flow based on a traffic movement policy and a transmission state of the second access network; and determining, by the gateway, whether the traffic flow is a traffic flow, To the second transmission path.

The first access network and the second access network may be connection networks using different radio access technologies.

Wherein the setting step comprises setting the first transmission path between the terminal and the first base station managing the first access network and the gateway as the terminal connects to the first access network And setting the second transmission path between the terminal and the second base station managing the second access network and the gateway as the terminal connects to the second access network .

The traffic moving method according to the exemplary embodiment includes connection network preferences of each traffic flow, and the determining step may include: determining a traffic flow for a traffic flow having a high preference to the second access network And a step of determining whether the received signal is a signal.

The traffic moving method according to the embodiment includes whether or not QoS of each traffic flow is guaranteed, and the determining step may include determining whether or not the traffic is moved according to the total traffic amount of the second access network, Based on the result of the determination.

The traffic moving method according to the embodiment includes the steps of receiving from the base station of the second access network information indicating the load status of the second access network measured by the base station, And acquiring the transmission status of the second access network based on the information indicating the status of the second access network.

The traffic moving method according to the embodiment is characterized in that when the transmission path of the traffic flow changes from the first transmission path to the second transmission path, the control entity transmits a message requesting to dynamically change the path policy for the traffic flow To the mobile station.

The traffic moving method according to the embodiment may further include receiving from the terminal a response message including whether the control entity has succeeded or failed to change the path policy of the terminal.

The traffic movement may include the current service traffic flow switching by switching the access network or dynamically selecting and starting the access network when a new traffic flow begins service initiation.

The traffic movement may include individual movement or group movement of the IP flow.

The method according to one embodiment of the present invention includes the steps of the gateway transmitting a message reporting the load status of the first access network and the second access network to the control entity, Determining whether to move traffic for each traffic flow served to the terminal based on a load state of the access network and the second access network, And changing the transmission path of the traffic flow.

If the wireless communication system is a 5G system, the gateway includes a UPF (User Plane Function), and the control entity may include an Access & Mobility Management Function (AMF) and a Session Management Function (SMF).

According to another aspect of the present invention, there is provided a method of moving traffic between heterogeneous access networks in a wireless communication system, the method comprising: when a terminal connected to a first access network attempts multiple access to a second access network, Determining whether a change in a first IFOM and a routing rule is required based on a first IFOM and a routing rule is determined; Changing a path rule to a second IFOM and a path rule, performing a traffic transmission path change procedure for the terminal based on the second IFOM and the path rule, and determining, based on the second IFOM and the path rule, And transmitting and receiving a traffic flow to and from the terminal.

The method may further include receiving a PDU Session Establishment Request message for a multiple access PDU session shared by the first and second access networks from the terminal, And when the approval for the multiple access PDU session is completed, transmitting a response to the PDU Session Establishment Request message to the terminal, wherein the response includes the second IFOM and the path You can include rules.

In the traffic moving method according to another embodiment, when the terminal receives the second IFOM and the path rule, the terminal determines an uplink path for traffic flows currently being serviced or serviced according to the second IFOM and the path rule Can be set.

The traffic moving method according to another embodiment may include at least one of a connection state of the terminal to the first and second access networks, a load state of the first and second access networks, and a QoS guarantee of each traffic flow Generating a third rule IFOM and a path rule if a change to the second IFOM and the path rule is required, determining whether a change to the second IFOM and the path rule is necessary based on the third IFOM and the path rule, , Performing a traffic transmission path change procedure for the terminal, and transmitting and receiving a traffic flow to the terminal based on the third IFOM and the path rule

The method further includes transmitting the third IFOM and the path rule to the terminal when the third IFOM and the path rule are received in the PDU Session Modification Command according to another embodiment of the present invention. According to the third IFOM and the path rule, an uplink path for the traffic flows currently in service or after the service can be established.

According to another embodiment of the present invention, as the terminal requests the connection release to the second access network, the terminal performs a PDU session release procedure to transmit the first IFOM and the path rule to the fourth IFOM and the path rule And transmitting and receiving a traffic flow with the terminal based on the fourth IFOM and the path rule.

The method further includes transmitting the PDU Session Release Command message including the fourth IFOM and the path rule to the UE, wherein the UE receives the fourth IFOM and the path rule , It is possible to set an uplink path for traffic flows that are currently in service or are subsequently served according to the fourth IFOM and the path rule.

In the traffic moving method according to another embodiment, the determining and changing may be performed by a session management function (SMF).

According to the embodiment of the present invention, in a mixed environment of heterogeneous wireless access networks, when a terminal accesses a plurality of access networks at the same time and transmits / receives traffic, traffic can be supported between access networks.

1 schematically illustrates a service network of a wireless communication system according to an exemplary embodiment of the present invention.
2 schematically shows a method of moving traffic between heterogeneous access networks in a wireless communication system according to an embodiment.
FIG. 3 illustrates an example of a signaling procedure for traffic movement in a wireless communication system according to an embodiment.
FIG. 4 illustrates another example of a signaling procedure for traffic movement in a wireless communication system according to an embodiment.
FIG. 5 is a schematic view of a service network of a wireless communication system according to another embodiment, and shows an example of a 5G wireless system environment.
6 shows an example of a signaling procedure for traffic movement in a wireless communication system according to another embodiment.
FIG. 7 illustrates an example of a signaling procedure for traffic movement in a wireless communication system according to another embodiment.
FIG. 8 shows an example of a signaling procedure for traffic movement in a wireless communication system according to another embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out 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 order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification and claims, when a section is referred to as " including " an element, it is understood that it does not exclude other elements, but may include other elements, unless specifically stated otherwise.

Throughout the specification, a terminal is referred to as a mobile terminal (MT), a mobile station (MS), an advanced mobile station (AMS), a high reliability mobile station (HR- A subscriber station (SS), a portable subscriber station (PSS), an access terminal (AT), a user equipment (UE) , HR-MS, SS, PSS, AT, UE, and the like.

Also, a base station (BS) is an advanced base station (ABS), a high reliability base station (HR-BS), a node B, an evolved node B, eNodeB), an access point (AP), a radio access station (RAS), a base transceiver station (BTS), a mobile multihop relay (MMR) (RS), a relay node (RN) serving as a base station, an advanced relay station (ARS) serving as a base station, a high reliability relay station (HR) A femto BS, a home Node B, a HNB, a pico BS, a metro BS, a micro BS, ), Etc., and all or all of ABS, Node B, eNodeB, AP, RAS, BTS, MMR-BS, RS, RN, ARS, HR- And may include negative functionality.

Throughout the specification, a transceiver may be a terminal, a mobile terminal (MT), a mobile station (MS), an advanced mobile station (AMS), a high reliability mobile station , An HR-MS, a subscriber station (SS), a portable subscriber station (PSS), an access terminal (AT), user equipment (UE) MS, AMS, HR-MS, SS, PSS, AT, UE, and the like.

In addition, the transceiver includes a base station (BS), an advanced base station (ABS), a high reliability base station (HR-BS), a node B, an evolved node B, an eNodeB, an access point (AP), a radio access station (RAS), a base transceiver station (BTS), a mobile multihop relay (MMR) And may be referred to as a relay station (RS), a high reliability relay station (HR-RS) serving as a base station, etc., and may be referred to as an ABS, a Node B, an eNodeB, an AP, a RAS, a BTS, BS, RS, HR-RS, and the like.

Hereinafter, a method for moving traffic between heterogeneous access networks according to embodiments of the present invention and a wireless communication system for performing the method will be described in detail with reference to necessary drawings.

In this document, the traffic movement technology is classified and classified according to its internal properties such as traffic steering, traffic switching, or traffic splitting. Traffic steering is the start of the traffic service by newly selecting the access network (Traffic Steering) dynamically when the traffic service starts. Traffic switching is to ensure service durability of the current service traffic and to switch the access network to perform traffic switching. Traffic splitting is a service that guarantees the service durability of current traffic and extends traffic from a single access network to multiple access networks to perform multi-path traffic transmission.

In addition, the traffic mobility in this document may include individual mobility and group mobility of IP flows.

FIG. 1 is a schematic view of a service network of a wireless communication system according to an exemplary embodiment of the present invention. Referring to FIG. 1, a cellular mobile access network and a wireless LAN access network are integrated in an environment in which a cellular mobile access network and a wireless LAN access network are mixed. Service network.

In an exemplary wireless communication system, an edge unified control entity (eUCE) 210 performs a signaling procedure for authentication, access procedures, traffic routing, and traffic mobility management of the terminal 100 . In addition, the eUCE 210 can determine the state of each access network and set and change a traffic transmission path for movement and distributed transmission of user traffic in a multiple access network environment.

The convergence gateway (CGW) 220 is connected to one or more base stations and can transmit and receive user traffic of the terminal 100. 1, in an environment where heterogeneous wireless access networks are mixed, the CGW 220 can be connected to the base stations of different access networks, respectively.

1, the CGW 220 is connected to a cellular BS 231 that manages an LTE-based mobile access network AN1 via a U1 interface, and is connected to a Wi-Fi-based WLAN access network (WiFi BS, 232) that manages the base station (AN2) through the U2 interface.

The CGW 220 is connected to the eUCE 210 via the C3 interface and can transmit and receive the traffic path control message with the eUCE 210 via the C3 interface. Also, the CGW 220 can set up a path for transmitting / receiving user traffic of the terminal 100 on the interface with each base station based on the traffic path control message received through the eUCE 210.

1, the CGW 220 sets up a traffic transmission path PATH1 for the terminal 100 in the U1 interface connected to the cellular base station 231 and transmits the traffic transmission path PATH1 to the terminal 100 on the U2 interface connected to the Wi- It is possible to set the traffic transmission path PATH2.

The CGW 220 having such a structure can receive and transmit user traffic by collectively accommodating base stations that manage heterogeneous wireless access networks in an environment where heterogeneous wireless access networks are mixed.

The terminal 100 may have one or more Medium Access Control (MAC) supporting different radio access technologies, and may be connected to one or more access networks.

1, the terminal 100 can access the mobile access network AN1 managed by the cellular base station 231. [ In this case, the terminal 1000 accesses the eUCE 210 via the radio link and the C1 interface of the mobile access network AN1, and the eUCE 210 establishes a session for traffic transmission with the terminal 100 The terminal 100 may instruct the CGW 220 to set the path PATH1 for traffic transmission between the CGW 220 and the mobile access network AN1 to the terminal 100. In addition, The terminal 100 may be connected to a wireless LAN (WLAN) access network AN2 managed by the Wi-Fi base station 232. In this case, And the eUCE 210 is connected to the eUCE 210 through the C2 interface and the eUCE 210 connects the CGW 220 to the wireless LAN access network AN2) - the setting of the path (PATH2) for the traffic transmission between the terminals 100.

As described above, in the wireless communication system according to one embodiment, heterogeneous access networks are integrally accommodated and managed by a single control entity (eUCE 210) and a single CGW 220. 1, when the terminal 100 is connected to the heterogeneous access networks AN1 and AN2 in multiple connections, the terminals 100 and 200 are connected to each other in accordance with the states of the access networks AN1 and AN2 and the characteristics of each traffic flow, The user traffic of the mobile terminal 100 can be moved and transmitted, thereby providing the optimal traffic service to the user.

In FIG. 1, a service network of a wireless communication system includes a LTE-based mobile access network and a WiFi-based wireless LAN access network. However, the present invention is not limited thereto. According to another embodiment, the service network of the wireless communication system may be a 5G (millimeter wave), LTE-Advanced, Licensed Assisted Access (LAA), LTE / Wi-Fi Aggregation (LWA) Based access network based on the new wireless transmission technology, a cellular-based access network such as WiMax and WiBro, and the like.

2 schematically shows a method of moving traffic between heterogeneous access networks in a wireless communication system according to an embodiment.

Referring to FIG. 2, in the wireless communication system according to the embodiment, the eUCE 210 is connected between the AT 100 and the mobile access network AN 1 as the AT 100 attempts to access the mobile access network AN 1. Lt; / RTI > The eUCE 210 also sets a traffic transmission path PATH1 between the terminal 100 and the mobile access network AN1 and the CGW 220 in the process of establishing a session for traffic transmission with the AT 100 The CGW 220 is controlled (S100).

As the traffic transmission path PATH1 between the terminal 100 and the mobile access network AN1 and the CGW 220 is newly set through the step S100, the eUCE 210 transmits the traffic transmission path PATH1 for the added traffic transmission path PATH1 The traffic load is added to the total amount of traffic being served by the mobile access network AN1 (S110).

Then, as the terminal 100 attempts to access the Wi-Fi-based wireless LAN access network AN2, the eUCE 210 establishes and initiates a connection between the terminal 100 and the wireless LAN access network AN2. Also, the eUCE 210 transmits a traffic transmission path (PATH2) between the terminal 100, the wireless LAN access network AN2, and the CGW 220 in the process of establishing a session for traffic transmission with the AT 100 The CGW 220 is controlled (S120).

As the traffic transmission path PATH2 between the terminal 100, the wireless LAN access network AN2 and the CGW 220 is newly set through the above step S120, the eUCE 210 transmits the traffic transmission path PATH2 of the added traffic transmission path PATH2 The traffic load is added to the total amount of traffic being served by the wireless LAN access network AN2 (S130).

Meanwhile, when the terminal 100 accesses the mobile access network AN1 and accesses the wireless LAN access network AN2 in a multiplexed manner, the eUCE 210 transmits the traffic flow to the terminal 100, Based on the mobility policy and the transmission state of each of the access networks AN1 and AN2 to which the AT 100 is connected, it is determined whether traffic movement is necessary for each traffic flow served through the mobile access network AN1 (S140).

The traffic movement policy of each traffic flow indicates a traffic movement rule when the terminal 100 accesses multiple access networks.

Table 1 below shows an example of the movement policy of individual traffic flows.

Table 1. Movement policy example of traffic flow

The traffic movement policy corresponding to each traffic flow may be held by the eUCE 210 or may be held by the terminal 100 and transmitted to the eUCE 210. [

In Table 1, the correspondent node (CN) corresponds to the server on the terminal 100 side, and the CN address indicates the address of the server. The terminal address (UE address) is an address of the terminal 100 and may share the same address in all the access networks to which the terminal 100 accesses. In addition, different addresses may be assigned depending on the access network to which the terminal 100 accesses .

Quality of Service (QoS) is a rate to be guaranteed when a corresponding traffic flow is transmitted, and can be set to a maximum bit rate or a guaranteed bit rate.

The access network preference indicates the access network priority that can be selected when traffic is moved in the multiple access environment. For example, as shown in Table 1, when the terminal 100 is connected to a LTE-based mobile access network and is connected to a WiFi-based wireless LAN access network, the traffic flow in which the WiFi is set to the highest priority is LTE Based mobile access network to a wireless LAN access network.

The QoS Guaranteed Flag is a flag indicating whether the corresponding traffic flow requires QoS assurance and can be set to true or false. The traffic flow in which the QoS guarantee flag is set to TRUE can be performed only when the transmission state of the access network to be moved can guarantee the QoS of the traffic flow. On the other hand, in the traffic flow in which the QoS Guaranteed Flag is set to False, the traffic movement can be performed irrespective of the transmission state of the access network to be moved.

In step S140, the eUCE 210 analyzes the traffic policy of each traffic flow, and determines whether or not the access network priority of the access network AN2 to which the corresponding traffic flow is to be transferred is different from the access network priority of the access network AN1), it is possible to determine the traffic movement of the corresponding traffic flow.

In step S140, if the traffic flow to be moved is a traffic flow requiring QoS guarantee, the eUCE 210 determines that the transmission state of the access network AN2, The traffic movement of the corresponding traffic flow can be determined only when QoS can be guaranteed. the eUCE 210 can determine whether to guarantee the QoS of the traffic flow based on the transmission state of the access network AN2 to which the traffic flow is to be moved, that is, the total traffic amount. For example, if the total amount of traffic of the wireless LAN access network AN2 to which the traffic flow is to be moved is below the threshold value, the eUCE 210 can guarantee the QoS of the traffic flow to which the state of the wireless LAN access network AN2 is to be moved It can be determined that the state is possible. For example, if the total amount of traffic of the wireless LAN access network AN2 to which the traffic flow is to be moved is greater than the threshold value, the eUCE 210 determines that the state of the traffic flow of the wireless LAN access network AN2 It can be determined that the QoS guarantee is difficult.

In step S140, the eUCE 210 may determine the traffic movement of the traffic flow based on the load metric information of the access network AN2 to which the traffic is to be moved. eUCE 210 may periodically receive load metric information from a base station belonging to each access network.

Table 2 below shows an example of load metric information, which represents load metric information received from Wi-Fi base station 232.

Table 2. Example of load metric information

Referring to Table 2, the load metric information is information indicating the degree of load of the corresponding access network, and may include one or more parameters obtained by the corresponding base stations. The load metric information includes information such as the number of terminals connected to the base station (or access point AP), the retransmission rate, the channel utilization rate, the frame discard rate in the Tx Queue, the congestion delay in queues and channels, Load, and the like.

When the base station generating the load metric information is the Wi-Fi base station 232, the number of terminals connected to the base station (or AP) indicates the number of terminals currently connected to the Wi-Fi base station 232, The utilization rate indicates the traffic re-transmission rate and the channel utilization rate between the Wi-Fi base station 232 and the terminals connected thereto. In addition, the frame discard rate in the receive queue represents the frame discard rate in the receive queue of the Wi-Fi base station 232, and the congestion delay in the queue and channel is the congestion delay in the receive / transmit queue of the Wi- And the degree of congestion of the channel between the Wi-Fi base station 232 and the terminals connected thereto. The rate / bandwidth represents the data rate or channel bandwidth between the Wi-Fi base station 232 and the terminals connected thereto, and the average load represents an average load amount at the Wi-Fi base station 232.

the eUCE 210 can acquire the transmission status of the corresponding access network AN2 based on the load metric information of the access network AN2 to which the traffic is to be moved and determine the traffic movement based on the transmission status.

In step S150, the eUCE 210 controls the CGW 220 to perform traffic movement from PATH1 to PATH2 for the traffic flow determined to require traffic movement through step S140. Here, the traffic movement may be performed by a method such as flow mobility, traffic steering, traffic switching, traffic splitting, and the like.

On the other hand, in step S160, the eUCE 210 controls the corresponding traffic flows to be serviced without traffic movement for the traffic flows that are not permitted to move traffic through step S140.

FIG. 3 illustrates an example of a signaling procedure for traffic movement in a wireless communication system according to an embodiment. In the service network shown in FIG. 1, when a terminal is connected to a mobile access network AN1, And when traffic is newly connected to the access network AN2, the traffic movement is performed subsequently.

Referring to FIG. 3, in the wireless communication system according to the embodiment, the terminal 100 accesses the cellular base station 231 to access the mobile access network AN1 (S200) (PATH_CREAT_REQ (PATH1)) requesting the setting (S201).

The eUCE 210 receiving the message transmits a control message SWITCH_ADD_REQ requesting the CGW 220 to set the traffic transmission path PATH1 between the terminal 100 and the mobile access network AN1 and the CGW 220 S202). Accordingly, the CGW 220 sets a traffic transmission path PATH1 between the terminal 100 and the mobile access network AN1 to the CGW 220 and outputs a response indicating that the setting of the traffic transmission path PATH1 is completed (SWITCH_ADD_RSP) to the eUCE 210 (S203).

the eUCE 210 transmits the newly set traffic transmission path PATH1 as the traffic transmission path PATH1 between the terminal 100 and the mobile access network AN1 and the CGW 220 is completed by the CGW 220 (PATH_CREAT_RSP (PATH1)) including information on the established traffic transmission path (PATH1) to the terminal 100 so that user traffic of the terminal 100 can be transmitted / received through the terminal 100 (S204).

The downlink / uplink user traffic of the terminal 100 is transmitted / received through the traffic transmission path PATH1 between the terminal 100 and the mobile access network AN1 to the CGW 220 (S205, S206).

Meanwhile, when the terminal 100 is connected to the mobile access network AN1 and connects to the WiFi base station 232 to perform multiple access to the wireless LAN access network AN2 (S207) (PATH_CREAT_REQ (PATH2)) requesting the setting (S209).

The eUCE 210 receiving the message transmits a control message (SWITCH_ADD_REQ) requesting the CGW 220 to set the traffic transmission path PATH2 between the terminal 100, the wireless LAN access network AN2, and the CGW 220 (S210). The CGW 220 sets the traffic transmission path PATH2 between the terminal 100 and the wireless LAN access network AN2 and the CGW 220 and notifies that the setting of the traffic transmission path PATH2 is completed And transmits a response message (SWITCH_ADD_RSP) to the eUCE 210 (S211).

the eUCE 210 transmits the newly set traffic transmission path PATH2 as the traffic transmission path PATH2 between the terminal 100 and the wireless LAN access network AN2 and the CGW 220 is completed by the CGW 220. [ (PATH_CREAT_RSP (PATH2)) including information on the traffic transmission path (PATH2) set so that the user traffic of the terminal 100 can be transmitted / received through the terminal 100 (S212).

Meanwhile, FIG. 3 illustrates an example in which the transmission of the PATH_CREAT_RSP (PATH2) message (S212) of the eUCE 210 is performed prior to the step of determining whether the movement of the traffic flow is required (S213). However, The eUCE 210 determines whether the movement of the traffic flow is necessary or not in step S213 and performs a PATH_CREAT_RSP (PATH2) message on the terminal 100 (step S214) ). In this case, the eUCE 210 can transmit a response message (PATH_CREAT_RSP (PATH2)) containing information on the newly set traffic transmission path (PATH2) to the terminal 100 irrespective of the traffic movement determination result in step S213 have.

the eUCE 210 transmits the existing traffic transmission path PATH1 as the traffic transmission path PATH2 between the terminal 100 and the wireless LAN access network AN2 and the CGW 220 is completed by the CGW 220. [ (Step S213). In step S213, it is determined whether a traffic movement is necessary for traffic flows to be provided to the terminal 100 through the network.

In step S213, the eUCE 210 determines whether or not the mobility policy of each traffic flow to be transmitted to the mobile station 100 based on the mobility policy of each traffic flow served to the mobile station 100 and the transmission state of each of the access networks AN1 and AN2, It is possible to determine whether or not a traffic movement is required for each traffic flow served through the access network AN1.

For example, the eUCE 210 analyzes the movement policy of each traffic flow and determines that the access network priority of the access network AN2 to which the corresponding traffic flow is to be moved is different from that of the other access network AN1 ), It is possible to determine the traffic movement of the corresponding traffic flow.

In addition, for example, when the traffic flow to be moved is a traffic flow requiring QoS guarantee, the eUCE 210 determines that the transmission state of the access network AN2, which is intended to move the corresponding traffic flow, The traffic flow of the corresponding traffic flow can be determined. the eUCE 210 can determine whether to guarantee the QoS of the traffic flow based on the transmission state of the access network AN2 to which the traffic flow is to be moved, that is, the total traffic amount. When the total amount of traffic of the WLAN access network AN2 to which the traffic flow is to be shifted is below the threshold value, the eUCE 210 is in a state where the state of the WLAN access network AN2 can guarantee the QoS of the traffic flow to be shifted . When the total amount of traffic of the WLAN access network AN2 to which the traffic flow is to be moved is greater than the threshold value, the eUCE 210 determines that the QoS of the traffic flows to which the state of the WLAN access network AN2 is to move is difficult .

In step S213, the eUCE 210 may determine the traffic movement of the traffic flow based on the load metric information of the wireless LAN access network AN2 to which the traffic is to be transferred. The load metric information is information indicating the degree of load of the wireless LAN access network AN2 measured by the WiFi base station 232. The eUCE 210 receives load metrics information from the WiFi base station 232, By periodically receiving a message (BS Load Report) including metric information (S208), load metric information of the wireless LAN access network AN2 can be obtained. the eUCE 210 can estimate the transmission state of the wireless LAN access network AN2 based on the load metric information of the wireless LAN access network AN2 to which the traffic flow is to be moved and determine the traffic movement based on the transmission state.

The eUCE 210 transmits a control message (SWITCH_MOD_REQ) requesting traffic movement to the CGW 220 in response to the traffic flow determined to require the traffic movement, when it is determined that the traffic movement from PATH1 to PATH2 is required through step S213 (S214). Accordingly, the CGW 220 changes the transmission path of the corresponding traffic flow from PATH1 to PATH2, and transmits a corresponding response message (SWITCH_MOD_RSP) to the eUCE 210 (S215).

Typically, the terminal 100 sets up a traffic path by selecting an access network according to a policy pre-established with the network at the start of the traffic flow service. However, according to an embodiment of the present invention, the eUCE 210 determines whether traffic movement is necessary through step S213, and changes the transmission path of the traffic flow already served according to the determination result (S214, S215).

In step S213, the eUCE 210 transmits a message (ROUTING_POLICY_CHANGE_REQ) requesting to change the path policy of the traffic flow dynamically in response to the transmission path change of the traffic flow currently being serviced, 100) (S216).

Upon receiving the ROUTING_POLICY_CHANGE_REQ message in step S216, the AT 100 can dynamically change the path policy for the current traffic flow through the uplink path setup for the current traffic flow. When the service for the corresponding traffic flow is started for the traffic flow not currently being serviced by the terminal 100, the terminal 100 also determines the access network path (for example, PATH1 Or PATH2).

Meanwhile, the terminal 100 may transmit a ROUTING_POLICY_CHANGE_RSP message to the eUCE 210 in response to the ROUTING_POLICY_CHANGE_REQ message (S217). The ROUTING_POLICY_CHANGE_RSP message may be selectively transmitted by the terminal 100 and may include the success / failure of the path policy change for the traffic flow of the terminal 100.

If the transmission path is determined to be one of PATH1 and PATH2 through the steps S213 to S215 for the individual traffic flows constituting the user traffic of the terminal 100, The traffic flows for which the traffic movement is determined are transmitted and received through the traffic transmission path PATH2 between the terminal 100, the wireless LAN access network AN2, and the CGW 220 in steps S218 and S219.

FIG. 4 shows another example of a signaling procedure for traffic movement in a wireless communication system according to an embodiment. In the service network shown in FIG. 1, when a terminal is connected to a mobile access network AN1 and a wireless LAN access network AN2 ), The signaling procedure for traffic movement is performed dynamically when the traffic service is continued.

Referring to FIG. 4, in a wireless communication system according to an exemplary embodiment of the present invention, a terminal 100 is connected to a mobile access network AN1 and a wireless LAN access network AN2 in a downlink / The link user traffic is transmitted from the traffic transmission path PATH1 between the terminal 100 to the mobile access network AN1 to the CGW 220 and the traffic between the terminal 100 and the wireless LAN access network AN2 to CGW 220 And transmitted / received through the transmission path PATH2 (S300, S301, S302, S303).

Meanwhile, the CGW 220 transmits a message (AN Load Report) reporting the traffic load status of each of the access networks AN1 and AN2 to the eUCE 210 periodically or aperiodically (S304). The AN Load Report message may include information indicating the load status of the traffic transmission paths PATH1 and PATH2 between the CGW 220 and each of the access networks AN1 and AN2, for example, a load measurement value.

The eUCE 210 receiving the message determines whether traffic movement is necessary for the traffic flows to the terminal 100 based on the load state of each traffic transmission path (PATH1, PATH2) included in the message (S305).

The eUCE 210 transmits a control message (SWITCH_MOD_REQ) requesting the traffic movement to the CGW 220 for the traffic flow determined to require the traffic movement, in step S306, . Accordingly, the CGW 220 changes the transmission path of the corresponding traffic flow from PATH1 to PATH2 or PATH2 to PATH1, and transmits the corresponding response message (SWITCH_MOD_RSP) to the eUCE 210 (S307).

Typically, the terminal 100 sets up a traffic path by selecting an access network according to a policy pre-established with the network at the start of the traffic flow service. However, in the embodiment of the present invention, the eUCE 210 determines whether the traffic movement is required through the step S305 as described above, and performs a procedure for changing the transmission path of the traffic flow already served according to the determination result (S306, S307).

When the transmission path of the traffic flow currently being serviced is changed through the steps S305 to S307, the eUCE 210 transmits a message (ROUTING_POLICY_CHANGE_REQ) requesting dynamic change of the path policy of the traffic flow to the terminal 100) (S308).

Upon receiving the ROUTING_POLICY_CHANGE_REQ message in step S308, the AT 100 can dynamically change the path policy for the current traffic flow through the uplink path setup for the current traffic flow. When the service for the corresponding traffic flow is started for the traffic flow not currently being serviced by the terminal 100, the terminal 100 also determines the access network path (for example, PATH1 Or PATH2).

Meanwhile, the terminal 100 may transmit the ROUTING_POLICY_CHANGE_RSP message to the eUCE 210 in response to the ROUTING_POLICY_CHANGE_REQ message (S309). The ROUTING_POLICY_CHANGE_RSP message may be selectively transmitted by the terminal 100 and may include the success / failure of the path policy change of the terminal 100. For example, the ROUTING_POLICY_CHANGE_RSP message can be transmitted in the terminal 100 by distinguishing the movement type of the traffic flows whose route policy is changed and by specifying a flag (traffic steering, traffic switching, traffic splitting, or the like).

If the transmission path is determined to be one of PATH1 and PATH2 through steps S305 to S307 for the individual traffic flows constituting the user traffic of the terminal 100, the individual traffic flows constituting the user traffic of the terminal 100 (S310, S311, S312, S313) through the corresponding traffic transmission path among the traffic transmission path (PATH1) and the traffic transmission path (PATH2).

3 and 4, in the wireless communication system according to the embodiment, when the terminal 100 has multiple connections to different types of access networks AN1 and AN2, By supporting the movement of user traffic between the access networks according to the load state and characteristics of each traffic flow, it is possible to provide the optimal traffic service to the users.

2 to 4, the terminal 100 is connected to the LTE-based mobile access network AN1 and the Wi-Fi-based WLAN access network AN2 through multiple connections. However, But the present invention is not limited thereto. In another embodiment of the present invention, the access network to which the terminal 100 is multi-connected is a millimeter wave (mmWave), an LTE-Advanced, a licensed assisted access (LAA), an LTE / Wi-Fi aggregation (LWA) of Thing), cellular-based access networks such as WiMax, WiBro, and so on.

Table 1 below shows the components of the 5G system environment as defined by 3GPP TS 23.501.

Table 1. Components of the 5G System Environment

Table 2 below shows reference points between functions of the 5G system defined by 3GPP TS 23.501.

Table 2. Reference points between functions of the 5G system

Hereinafter, a traffic moving method in the wireless communication system according to another embodiment will be described in detail with reference to Tables 1 and 2.

FIG. 5 is a schematic view of a service network of a wireless communication system according to another embodiment, and shows an example of a 5G wireless system environment.

In the 5G system environment, Access and Mobility Management Function (AMF) and Session Management Function (SMF) 310 perform functions of the integrated control entity (eUCE 210) of FIG. 1 in a traffic movement procedure, ) 320 may perform the functions of the integrated gateway (CGW 220) of FIG.

That is, the movement of the traffic flows constituting the user traffic of the AT 100 in the 5G system environment can be determined based on the AMF and the SMF 310 may determine. In addition, the traffic movement procedure may be performed by exchanging a signaling procedure for changing a traffic path policy or a rule by the AT 100, the AMF and the SMF 310 and the UPF 320.

Referring to FIG. 5, the MS 100 is connected to a 5G access network, a WLAN access network, and a fixed network, and is provided with a traffic service from a public data network (PDN). Accordingly, the AMF and the SMF 310 can receive the traffic flows constituting the user traffic of the terminal 100 according to the change of the access network to which the terminal 100 is multiplexed and the load status of the access networks to which the terminal 100 has multi- The movement can be determined individually or collectively. In the case of group movement for traffic flows, the entire traffic flow belonging to one DN (Data Network) may be moved.

5, the AMF and the SMF 310 determine to maintain the service through the 5G access network for Flow 1 among the traffic flows constituting the user traffic of the AT 100, Services. On the other hand, the AMF and the SMF 310 decide to move from the 5G access network to the WLAN for Flow 2, and the flow 3 from the WLAN access network to the wired network, 2 is moved to a wireless LAN access network, and Flow 3 is moved to a wired network to be served. At this time, the traffic movement pattern may include traffic steering, traffic switching, traffic splitting, and the like.

In FIG. 5, the terminal 100 is connected to a single DN to provide a service. However, the terminal 100 may be simultaneously connected to a plurality of DNs to receive services.

FIG. 6 illustrates a signaling procedure for traffic movement in a wireless communication system according to another embodiment. FIG. 6 illustrates a case where a traffic movement is performed through a PDU Session Establishment procedure in the 5G system environment of FIG. 5 as an example For example,

In this document, 'PDU Connectivity Service' represents a service providing exchange of PDU (Protocol Data Unit) between a terminal and a DN (Data Network), and 'PDU Session' The relationship between the terminal providing the service and the DN is shown. The PDU session type is divided into IP, Ethernet, or unstructured form.

The 5G Core Network supports the PDU connection service, and the PDU connection service provides the PDU exchange between the terminal and the DN. The PDU connection service is supported through PDU sessions established from the terminal's request. (Non-Access Stratum) SM signaling (Session Initiation Protocol) on the interface N1 between the terminal and the SMF when PDU sessions are set up at the request of the terminal, or when the PDU session is changed or released due to the request of the terminal or the request by the 5G core network Management signaling procedure is performed.

FIG. 6 is a flowchart illustrating a procedure of establishing a PDU session to connect to a first RAT (Radio Access Technology) to access a corresponding access network, and then maintaining a connection with an existing RAT, 6, a new PDU session independent from a previously established PDU session is established in order to access the new access network 330. In this case, instead of establishing a new PDU session, Use the session to share. In this document, a PDU session type in which multiple access networks are concurrently connected to one PDU session is referred to as a multiple access PDU session.

Referring to FIG. 6, the MS 100 transmits a PDU Session Establishment Request message to the AMF 311 in order to access the new access network while maintaining connection to the existing access network (S400).

In step S400, the PDU Session Establishment Request message may include a PDU session ID, existing PDU session information, multiple access PDU session information, a newly added RAT type, and the like. In step S400, since the PDU Session Establishment Request message is for multiple access, it can be set to request a multiple access PDU session.

On the other hand, the AMF 311 receiving the PDU Session Establishment Request message from the terminal 100 performs the SMF selection based on the PDU Session Establishment Request message (S401).

In step 400, the AMF 311 extracts a PDU session ID, an existing PDU session information, a multiple access PDU session information, a newly added RAT type, and the like from the PDU Session Establishment Request message and selects the SMF 312 .

If the SMF 312 is selected in step S401, the AMF 311 transmits an SM Request message, i.e., a PDU Session Establishment Request message received from the subscriber station 100, to the selected SMF 312 in step S402.

Thereafter, an authentication / authorization procedure for the multiple access PDU session requested by the terminal 100 is performed, and it is determined whether the terminal 100 has approved the establishment of the PDU session requested by the terminal 100 (S403).

The SMF 312 transmits an SM Response message, i.e., a PDU Session Establishment Accept message, to the AMF 311 when the authentication / authorization process for the PDU session requested by the SS 100 is successfully completed (S405).

Before transmitting the PDU Session Establishment Accept message, the SMF 312 calculates the load status of the corresponding DN and determines whether the movement of the traffic flow is required based on the calculated load status, that is, the Internet protocol flow mobility (IFOM) (Step S404).

In step S404, if it is determined that the IFOM and the route rule need to be changed, the SMF 312 performs an IFOM update trigger to change the IFOM and the path rule. In addition, the PDU includes the changed IFOM and the path rule in the PDU Session Establishment Accept message (S405), which is a response message for establishing the PDU session, and transmits it.

Thereafter, the PDU Session Establishment Accept message including the changed IFOM and the path rule is transmitted to the access network 330 through the N2 PDU Session Request message (S406) transmitted from the AMF 311 to the base station of the access network 330, (AN-specific resource setup) procedure (S407).

The terminal 100 that has received the modified IFOM and the route rule applies it to its own traffic transmission / reception. That is, the MS 100 can dynamically change the path policy for the traffic flow currently in service through the uplink path setting for the current traffic flow. When the service for the corresponding traffic flow is started for the traffic flow not currently being serviced by the terminal 100, the terminal 100 also determines the access network path (for example, PATH1 Or PATH2).

On the other hand, the base station of the access network 330 receiving the N2 PDU Session Request message from the AMF 311 transmits a response message (N2 PDU Session Request Ack) to the AMF 311.

Thereafter, the SMF 312 transmits an SM Request message (N2 information) transmitted from the AMF 311 to the SMF 312 by transmitting the uplink user data to the DN, that is, the UPF 320 (S409) And confirms that the PDU Session Establishment Accept message has been successfully transmitted to the UE 100 through the N4 Session Modification procedures S411 and S412.

Upon receiving the SM Request message from the AMF 311, the SMF 312 includes the modified IFOM and the route rule in the N4 Session Modification Request message and transmits the modified IFOM and the route rule to the UPF 320 (S411). The UPF 320 that has received the N4 Session Modification procedure applies the N4 Session Modification procedure. In other words, based on the changed IFOM and the path rule, a change procedure for the traffic transmission path is performed. Then, in response to the N4 Session Modification Request message, the N4 Session Modification Response message is transmitted to the SMF 312 (S412). In step S413, the SMF 312 receives the SM Request message and transmits an SM Response message to the AMF 311 in response to the SM Request message received in step S410.

Subsequently, the downlink user data (traffic flow) is transmitted from the DN (UPF 320) to the terminal 100 according to the newly changed IFOM and path rule (S414).

As described above, the traffic flows between the terminal 100 and the DN can be relocated and moved in a plurality of access networks connected to the terminal 100 through the PDU session establishment procedure.

Meanwhile, the procedure for calculating the load state of the access network and changing the IFOM and the route rule in step S404 of FIG. 6 may correspond to step S213 of FIG. 3 described above. That is, in step S404, the SMF 312 determines whether or not the function of the eUCE 210 in step S213, that is, the mobility policy of each traffic flow served to the terminal 100, Based on the transmission state of the network, it is possible to determine whether traffic movement is required for each traffic flow.

Generally, a terminal selects a connection network and establishes a traffic path according to a policy promised beforehand when starting a traffic flow service. However, in the embodiment of the present invention described with reference to FIG. 6, it is determined whether traffic movement is necessary according to the load status of the DN in the SMF 312 as described above. (S411, S412) for changing the transmission path.

FIG. 7 illustrates a signaling procedure for traffic movement in a wireless communication system according to another embodiment of the present invention. In the 5G system environment of FIG. 5, it is determined that traffic movement and dynamic path change are required by the 5G core network, And a case where a traffic movement is performed through a PDU Session Modification procedure as an example.

Referring to FIG. 7, the SMF 312 determines that it is necessary to change the IFOM and the route rule and performs an IFOM Update Trigger (S500), and a PDU session modification procedure for moving the traffic flow is started .

In step S500, the SMF 312 determines whether it is necessary to change the IFOM and the path rule on the basis of the connection state of the terminal 100 to the multiple access network, the load state of each access network, the QoS guarantee of each traffic flow, can do.

The SMF 312 generates a new IFOM and path rule if it is determined that a change of the IFOM and the path rule is necessary. (UPF 320, UDM 340, PCF (Policy Control Function) 350) and the newly generated rule are transmitted to the current network and the terminal 100 through the PDU-CAN (Connectivity Access Network) (S501). ≪ tb > < TABLE >

When the negotiation is completed, the SMF 312 generates a PDU Session Modification Command including the newly modified IFOM and the path rule, and transmits the SMU 312 to the AMF 311 (S502) . Subsequently, the PDU Session Modification Command is transmitted from the AMF 311 to the base station of the access network 330 through the N2 Session Request message (S503) transmitted from the AMF 311 to the base station of the access network 330, And is transmitted to the terminal 100 through an AN-specific resource setup procedure (S504).

Upon receiving the PDU Session Modification Command, the terminal 100 applies the IFOM and the path rule included in the PDU Session Modification Command to its own traffic transmission / reception. That is, the MS 100 can dynamically change the path policy for the traffic flow currently in service through the uplink path setting for the current traffic flow. When the service for the corresponding traffic flow is started for the traffic flow not currently being serviced by the terminal 100, the terminal 100 also determines the access network path (for example, PATH1 Or PATH2).

When the application of the IFOM and the path rule is completed, the AT 100 transmits a PDU Session Modification Command Ack message through an AN-specific resource setup procedure between the base station of the access network 330 and the AT 100 To the access network 330. Subsequently, the PDU Session Modification Command Ack message includes an N2 Session Response message S505 transmitted from the access network 330 to the AMF 311, an SM Request Ack message S506 transmitted from the AMF 311 to the SMF 312, Lt; RTI ID = 0.0 > SMF 312 < / RTI >

Thereafter, the SMF 312 performs the movement of the user traffic and the change of the route rule through the N4 Session Modification procedure (S507, S508).

Upon receipt of the SM Request Ack message from the AMF 311, the SMF 312 includes the changed IFOM and the route rule in the N4 Session Modification Request message and transfers the modified IFOM and the route rule to the UPF 320 (S507). The UPF 320 that has received the N4 Session Modification procedure applies the N4 Session Modification procedure. That is, based on the changed IFOM and the path rule, a change procedure for the user data (traffic flow) transmission path is performed. Then, in response to the N4 Session Modification Request message, the N4 Session Modification Response message is transmitted to the SMF 312 (S508).

Thereafter, the SMF 312 may change the IFOM and path rules in accordance with the multiple access PDU session change procedure, if necessary, and perform PDU-CAN session change for all entities including the affected PCF 340 (S509).

Accordingly, downlink user data (traffic flows) occurring thereafter can be transmitted to the AT 100 according to the newly changed IFOM and path rule.

FIG. 8 illustrates a signaling procedure for traffic movement in a wireless communication system according to another embodiment. 8 is a diagram illustrating a PDU session release (PDU session release) for moving a service traffic in an access network to be released according to release of one connection in a multi-connection PDU session in a 5G system environment to another unallocated access network, An example in which traffic is moved through a procedure is shown as an example.

In a multi-access PDU session where one terminal 100 is connected to two or more multiple RATs and multiple access networks are shared and managed in a single PDU session, one of the RATs managed in the PDU session The PDU session release procedure is used even when releasing the RAT of the PDU.

The PDU session release procedure is to release all resources associated with the corresponding PDU session. To this end, the SMF 312 should inform the PDU session of the release of all objects associated with the PDU session to be released, such as the PCF 350, the DN, and so on.

The PDU session release procedure may be initiated by the terminal 100 or the DN. It is possible to use a PDU session release procedure when one connection is released in a multiple access environment and to designate and release a specific access network through a PDU session release procedure.

8, it is assumed that the terminal 100 is in multiple access to two RATs (RAT1, RAT2), and the networks 331, 332 to which the terminal 100 is multiplexed are shared and managed in one multi-access PDU session State (S600). Here, RAT1 corresponds to the first access network (AN1, 331), and RAT2 corresponds to the second access network (AN2, 332).

In this state, when the terminal 100 desires to release a connection to any one RAT (RAT2), the terminal 100 specifies the RAT type (RAT2) to be released in the multiple access PDU session in the PDU Session Release Request message, (S601). Accordingly, the AMF 311 transmits the received PDU Session Release Request to the SMF 312 managing the PDU session to be released in the N11 message (S602).

The SMF 312 that has received the RAT2 deletes the RAT2 service from the RAT2 to terminate the traffic in service according to the IFOM policy. The PDU-CAN session modification procedure is performed (S603).

The SMF 312 changes the IFOM and the path rule through the IFOM update trigger as the new IFOM and the path rule are generated through the PDU-CAN session modification procedure (S604), and updates the NOM including the changed IFOM and the path rule And transfers the Session Release Resource message to the UPF 320 (S605). The UPF 320, which has received the request, performs a procedure for releasing the RAT2 requested to be released, and newly sets the IFOM and the path rule to move the traffic that is being serviced in the RAT2 to another RAT (RAT1). Then, the N4 Session Release Response message is transmitted to the SMF 312 (S606).

Thereafter, the SMF 312 configures a PDU Session Release Command message including the updated IFOM and the path rule to deliver the updated IFOM and the route rule to the UE 100 according to the release of the RAT2, and transmits the N11 Request message And transmits it to the AMF 311 (S607).

Accordingly, the AMF 311 transmits and receives the N2 Session Request message (S608) and the N2 Session Response message (S609), and performs a procedure for changing the path according to the traffic movement with the access network 331 that has not been disconnected do. In response to the release of the connection to the RAT2, the N2 Resource Release Request message is transmitted to the base station of the second access network 332 to request release of the resource allocated to the AT 100 (S610).

Accordingly, the base station of the second access network 332 releases resources corresponding to the second access network 332. [ Also, the terminal 100 and the AN-specific resource setup procedure S611 are performed to notify the changed IFOM and the path rule and the terminal 100 that the resource release is completed. That is, the base station of the second access network 332 transmits a PDU session including the changed IFOM and path rules through the AN-specific resource setup procedure and information (Ack) And transmits a release command (PDU Session Release Command) to the terminal 100.

Upon receiving the PDU Session Release Command, the terminal 100 applies the IFOM and the path rule included in the PDU Session Release Command to its own traffic transmission / reception. That is, the MS 100 can dynamically change the path policy for the traffic flow currently in service through the uplink path setting for the current traffic flow. Also, the terminal 100 can select an access network path according to the changed path policy when the service for the corresponding traffic flow is started with respect to traffic flows that are not currently being served to the terminal 100.

Upon completion of the resource release, the base station of the second access network 332 transmits an N2 Resource Release Ack message to the AMF 311 to notify the AMF 311 that the resource release is completed (S612).

The AMF 311 receives an ACK including the success or failure of the PDU session release in the N11 Response message and transmits the N11 Response message to the SMF 312 in step S613. 311 (S614).

In addition, the SMF 312 may change the IFOM and path rules in accordance with the multiple access PDU session release procedure if necessary, and may also perform PDU-CAN session changes for all entities including the affected PCF 340 (S615).

As the PDU session release procedure is completed through the above-described process, the downlink user data (traffic flows) occurring thereafter can be transmitted to the AT 100 according to the newly changed IFOM and path rule.

The embodiment of the present invention is not limited to the above-described apparatus and / or method, but may be applied to a program recorded on a recording medium or a recording medium on which the program is recorded to realize a function corresponding to the configuration of the embodiment of the present invention And the present invention can be easily implemented by those skilled in the art from the description of the embodiments described above.

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.

100: terminal
210: euCE
220: CGW
231: cellular base station
232: Wi-Fi base station
311: AMF
312: SMF
320: UPF
330, 331, 332:
340: UDM
350: PCF

Claims (20)

A method of moving traffic between heterogeneous access networks in a wireless communication system,
The terminal accesses the first access network and the second access network in a multiple access manner so that the gateway transmits to the terminal a first transmission path corresponding to the first access network and a second transmission path corresponding to the second access network Setting step,
The control entity determining whether to move traffic for each traffic flow based on a traffic movement policy of each traffic flow served to the terminal over the first transmission path and a transmission state of the second access network, And
The gateway changing the transmission path of the traffic flow in which the traffic movement is determined from the first transmission path to the second transmission path. The method according to claim 1,
Wherein the first access network and the second access network are access networks using different wired and wireless connection technologies. The method according to claim 1,
Wherein the setting step comprises:
Setting the first transmission path between the terminal and the first base station managing the first access network and the gateway as the terminal connects to the first access network;
And establishing the second transmission path between the terminal and a second base station managing the second access network and the gateway as the terminal connects to the second access network. The method according to claim 1,
Wherein the traffic movement policy includes an access network preference of each traffic flow,
Wherein the determining comprises determining a traffic movement for a traffic flow with a higher preference for the second access network than the first access network. The method according to claim 1,
Wherein the traffic movement policy includes whether QoS of each traffic flow is guaranteed,
Wherein the determining comprises determining whether to move traffic according to the total traffic amount of the second access network for a traffic flow requiring QoS guarantee. The method according to claim 1,
Receiving information indicating a load status of the second access network measured by the base station from a base station of the second access network;
And acquiring a transmission status of the second access network based on information indicating a load status of the second access network. The method according to claim 1,
Further comprising: when the transmission path of the traffic flow changes from the first transmission path to the second transmission path, transmitting to the terminal a message requesting the control entity to dynamically change the path policy for the traffic flow How to move traffic. 8. The method of claim 7,
The control entity further receiving a response message including the success / failure of the change of the path policy of the terminal from the terminal in response to the message. The method according to claim 1,
Wherein the traffic movement comprises dynamically selecting and initiating an access network when a current service traffic flow moves by switching the access network or when a new traffic flow begins service initiation. The method according to claim 1,
Wherein the traffic movement comprises traffic movement and individual movement and group movement of an IP flow. The method according to claim 1,
The gateway sending a message reporting the load status of the first access network and the second access network to the control entity,
The control entity determining whether to move traffic for each traffic flow served to the terminal based on a load state of the first access network and the second access network;
Further comprising changing the transmission path of each traffic flow served to the terminal according to the determination of the control entity by the gateway. The method according to claim 1,
Wherein the gateway includes a UPF (User Plane Function) when the wireless communication system is a 5G system, and the control entity includes an Access & Mobility Management Function (AMF) and a Session Management Function (SMF). A method of moving traffic between heterogeneous access networks in a wireless communication system,
As the terminal connected to the first access network attempts multiple access to the second access network, the first access network is connected to the first IFOM (internet protocol flow mobility) and the routing rule based on the load state of the data network Determining whether a change is necessary,
Changing the first IFOM and the path rule to a second IFOM and path rule if it is determined that a change is needed in the first IFOM and the path rule,
Performing a traffic transmission path change procedure for the terminal based on the second IFOM and the path rule; and
And transmitting and receiving a traffic flow to and from the terminal based on the second IFOM and the path rule. 14. The method of claim 13,
Receiving a PDU Session Establishment Request message for a multiple access PDU session shared by the first and second access networks from the terminal,
Performing an authentication / authorization procedure for the multiple access PDU session, and
When the approval for the multiple access PDU session is completed, transmitting a response to the PDU Session Establishment Request message to the UE,
Wherein the response comprises the second IFOM and the path rule. 15. The method of claim 14,
Wherein the terminal sets an uplink path for traffic flows currently being serviced or serviced after the second IFOM and the path rule according to the second IFOM and the path rule. 14. The method of claim 13,
A change to the second IFOM and the route rule based on at least one of a connection state of the terminal to the first and second access networks, a load state of the first and second access networks, and a QoS guarantee of each traffic flow, ,
If a change to the second IFOM and the path rule is required, generating a third rule IFOM and a path rule,
Performing a traffic transmission path change procedure for the terminal based on the third IFOM and the path rule; and
And transmitting and receiving a traffic flow to and from the terminal based on the third IFOM and the path rule. 17. The method of claim 16,
PDU Session Modification Command including the third IFOM and the path rule to the UE,
Wherein the terminal sets an uplink path for traffic flows currently being serviced or subsequently serviced according to the third IFOM and the path rule upon receiving the third IFOM and the path rule. 14. The method of claim 13,
Changing the first IFOM and the path rule to a fourth IFOM and path rule by performing a PDU session release procedure as the terminal requests the disconnection to the second access network,
And transmitting and receiving a traffic flow to and from the terminal based on the fourth IFOM and the path rule. 19. The method of claim 18,
PDU Session Release Command message including the fourth IFOM and the path rule to the UE,
Wherein the terminal sets an uplink path for traffic flows that are currently being serviced or which are subsequently serviced according to the fourth IFOM and the path rule upon receiving the fourth IFOM and the path rule. 14. The method of claim 13,
Wherein the determining and modifying are performed by a Session Management Function (SMF).

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