KR20190136948A - Access trafic steering/switching/splitting method in a network and network entity performing the same - Google Patents

Abstract

Disclosed are an access traffic steering, switching and splitting (ATSSS) method and a network entity performing the same. According to the present invention, if the performance of an ATSSS from a first access network to a second access network is determined, a session management function (SMF) may transmit a first message requesting confirmation of a connection state of a terminal to the first and second access networks to an access and mobility management function (AMF). The SMF may receive information on the connection state of the terminal from the AMF.

Description

ATSSS method in a network and the network entity performing it {ACCESS TRAFIC STEERING / SWITCHING / SPLITTING METHOD IN A NETWORK AND NETWORK ENTITY PERFORMING THE SAME}

The present invention relates to an ATSSS method in a network and a network entity performing the same.

The 5G network structure allows a terminal to access several access networks at the same time, and provides a common core network regardless of the type of access network. When a user wants to simultaneously transmit and receive traffic by accessing different access networks, an access network suitable for traffic characteristics is selected, and a technology for moving and forwarding traffic is required. Traffic movement technology can provide users with more economical data transmission services and increase the transmission capacity available to users. In addition, it is possible to further improve user convenience by arbitrarily changing the access network currently being serviced.

Recently, standardization on 5G network technology is in progress. In this 5G network, standard work is underway to support access traffic steering, switching and splitting (ATSSS) between the 3GPP access network and the Non-3GPP access network.

Traffic steering refers to the ability to forward new data traffic over a new access network, and traffic switching refers to the ability to transfer all current data traffic that is currently in transit to another access network. Traffic splitting refers to a function of distributing one data traffic through multiple access networks.

In order to provide traffic (data, voice, etc.) to a user equipment (UE) in a 5G network, a packet data unit (PDU) session configuration is basically established between the user equipment (UE) and a data network. need. After the service is provided, the PDU session needs to be released.

Existing PDU session configuration is established only through the terminal and one access network (3GPP access network or Non-3GPP access network), through which a single access PDU session (Single Access PDU Session, SA PDU Session) is established. A plurality of single access PDU sessions (SA PDU Sessions) may be configured in one UE, and a plurality of single access PDU sessions may be distinguished through PDU Session Identifiers, respectively. When the terminal finishes providing a service or needs to modify a user traffic session, the generated PDU session may be triggered by the terminal or the network to be modified or released.

However, since a single access PDU session (SA PDU Session) is configured with only one access network, user traffic belonging to the corresponding PDU session cannot be transmitted or received through two or more access networks. Accordingly, it is difficult to provide a service supporting the ATSSS function. In order to support the ATSSS function, the same PDU session created over two or more access networks is required. Such a PDU session is called a multi-access PDU session (MA PDU session).

An object of the present invention is to provide a method for effectively performing ATSSS and a network entity performing the same.

Another object of the present invention is to provide a method for switching the access state of a terminal to an access network to perform ATSSS.

According to an embodiment of the present invention, a method for performing ATSSS (Access Traffic Steering, Switching and Splitting) in a network is provided. The method may include requesting, by the Session Management Function (SMF), to confirm the connection state of the terminal to the first and second access networks, when the execution of the ATSSS from the first access network to the second access network is determined. The method may include transmitting a first message to an access and mobility management function (AMF), and receiving, by the SMF, information about a connection state of the terminal from the AMF.

The method may include: activating a control plane for the second access network when the connection state of the second access network is CM (Connection Management) _IDLE, and after the control plane is activated, the second access network. The method may further include activating a user plane for.

The method may further include performing modification of a packet data unit (PDU) session to perform the ATSSS.

The first message may include a PDU session modification command message, and the PDU session modification command message may include a modified ATSSS rule.

The method may include: activating a control plane for the second access network if the connection state of the second access network is CM (Connection Management) _IDLE; after the control plane is activated, The user plane is activated, and the AMF sends an N2 Session Request message including the PDU session modification command message to the first access network or the second access network. Can be.

The method may further include the AMF transmitting the PDU session modification command message to the terminal through the first access network.

The PDU session modification command message may include an indicator indicating that the ATSSS and the changed ATSSS rule.

The method may include: performing, by the UE, an RRC resume procedure when the connection state of the second access network is CM (Connection Management) _CONNECTED and the RRC (Radio Resource) state of the second access network is RRC_INACTIVE. It may further include.

The method may further include performing, by the terminal, reconnecting to the second access network when the connection state of the second access network is CM_IDLE.

The method may further include transmitting, by the terminal, a PDU session modification command amount (ACK) message to the AMF.

The receiving may include receiving, by the SMF, a Namf_comm_N1N2Message response message including the information from the AMF.

The first message may further include an indicator indicating that the connection state is confirmed, a type of the first access network, a type of the second access network, and a PDU session identifier (ID) associated with the ATSSS.

The first message may be a Namf_Comm_N1N2MessageTransfer message.

According to another embodiment of the present invention, a method for performing ATSSS (Access Traffic Steering, Switching and Splitting) in a network is provided. The method includes determining that a Session Management Function (SMF) changes the traffic of a first access network to a second access network for the ATSSS, and wherein the SMF includes a first message for the ATSSS request. The method may include transmitting a message to an access and mobility management function (AMF), and receiving, by the SMF, information about a connection state of a terminal from the AMF.

The method may further include the AMF transmitting the first message to the terminal through the first access network.

The method may include transmitting, by the terminal, a service request message to the AMF through the second access network when the connection state of the terminal to the second access network is CM (Connection Management) _IDLE. It may further include.

The first message may be a PDU session modification command message, and the PDU session modification command message may include a type of the first access network, a type of the second access network, and a PDU associated with the ATSSS. Packet Data Unit) may include an identifier (ID).

According to another embodiment of the present invention, a network entity for performing ATSSS (Access Traffic Steering, Switching and Splitting) in a network is provided. The method determines a performance of the ATSSS, a processor constituting a first message requesting confirmation of a connection status of a terminal to an access network related to the ATSSS, and transmitting the first message to another network entity. It may include a network interface for receiving information on the connection state of the terminal from the other network entity.

The network entity may be a Session Management Function (SMF), and the other network entity may be an Access and Mobility Management Function (AMF).

The first message may be a Namf_Comm_N1N2MessageTransfer message, the Namf_Comm_N1N2MessageTransfer message may include a PDU session modification command message, and the PDU session modification command message may include a modified ATSSS rule.

According to the embodiment of the present invention, the ATSSS can be effectively provided by switching the access state of the access network related to performing the ATSSS to the activated state.

1 is a diagram illustrating a 5G network according to an embodiment of the present invention.
2 is a flowchart generally illustrating an ATSSS method according to an embodiment of the present invention.
3 is a flowchart showing an ATSSS method according to the first embodiment of the present invention.
4 is a flowchart illustrating a service invoking method according to an exemplary embodiment of the present invention.
5 is a flowchart illustrating a service invoking method according to another exemplary embodiment of the present invention.
FIG. 6 is a flowchart illustrating the ATSSS method of FIG. 3 in detail.
7 is a flowchart illustrating an operation of the AMF 310 according to an embodiment of the present invention.
8 is a flowchart showing the operation of the terminal 100 according to an embodiment of the present invention.
9 is a flowchart illustrating an ATSSS method according to a second embodiment of the present invention.
10 is a flowchart illustrating an ATSSS method according to a third embodiment of the present invention.
11 illustrates a computing system in accordance with an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, a user equipment (UE) is a mobile terminal (MT), a mobile station (MS), an advanced mobile station (AMS), a high reliability mobile station (HR). -MS), subscriber station (SS), portable subscriber station (PSS), access terminal (AT), etc., and may be referred to as a terminal, MT, AMS, HR-MS, SS May include all or part of the functionality of a PSS, AT, UE, or the like.

In addition, a base station (BS) may be an advanced base station (ABS), a high reliability base station (HR-BS), a node B (node B), an advanced node B (evolved node B, eNodeB), access point (AP), radio access station (RAS), base transceiver station (BTS), mobile multihop relay (MMR) -BS, relay serving as a base station station, RS), a high reliability relay (HR-RS) serving as a base station, etc., and may also be referred to as BS, ABS, Node B, eNodeB, AP, RAS, BTS, MMR-BS, RS It may also include all or part of the function, such as HR-RS.

1 is a diagram illustrating a 5G network according to an embodiment of the present invention.

As shown in FIG. 1, the 5G network 1000 according to an embodiment of the present invention includes a terminal (UE) 100, an access network (AN) 200, and an access mobility management function (AMF). Management Function (310), Session Management Function (SMF, Session Management Function) (320), User Plane Function (UPF, User Plane Function) (330), Data Network (DN, Data Network) 400, Policy Control Function (PCF, Policy Control Function) 500, and Unified Data Management (UDM) 600.

The terminal (UE) 100 may access the network via the access network 200. Access network 200 includes a 3GPP access network 210 and a Non-3GPP access network 220. The terminal may connect to the cellular mobile radio access network via the 3GPP access network 210. In addition, the terminal 100 may access the WLAN access network through the Non-3GPP access network 220. Non-3GPP access network 220 includes Non-3GPP InterWorking Function (N3IWF) 221 for N3 and N2 interfaces with UPF 330 and AMF 310 by the 5G core network common interface principle.

AMF 310 and SMF 320 are network entities that process control signals. The AMF 310 and the SMF 320 correspond to the terminal 100 and have N1 which is a non-access stratum (NAS) signal interface. The AMF 310 performs authentication, access, and mobility control functions through the N1 interface. The SMF 320 has a session control function (set / modify / release of a session) through an N1 interface with a UE (UE) 100 and an N4 interface with a UPF 330, and manages traffic path setting and traffic movement management. Carry out a signaling procedure.

The UPF 330 is a network entity in the data plane that collectively accommodates multiple access networks 210, 220 through the N3 interface. The UPF 330 connects a data plane between the multiple access networks 210 and 220 and the DN 400, through which traffic of the terminal 100 (ie, a user) may be transmitted and received.

The UPF 330 and the access network 200 receive a control rule for traffic between the terminal 100 and the UPF 330 through the N4 and N2 interfaces from the SMF 320, respectively, and receive the received control rule. (Rule) performs functions such as traffic detection, routing, and QoS control.

The PCF 500 is connected to the SMF 320 via the N7 signal interface and controls session, mobility, and QoS related policies. The PCF 500 may transmit a policy and charging control rule (PCC) policy required for the SMF 320 to generate an ATSSS rule to the SMF 320.

The UDM 600 is connected to the SMF 320 through the N10 signal interface and manages user information management such as subscription information of the UE 100 and a policy of the UE. The UDM 600 may transmit information on the profile and subscription of the UE 100 for the ATSSS to the SMF 320.

As such, the 5G network system according to the embodiment of the present invention is an integrated structure that simultaneously accommodates the 3GPP access network 210 and the Non-3GPP access network 220. In such an integrated structure, the terminal 100 may simultaneously access two access networks 210 and 220 to receive a service. ATSSS refers to a service that steers, switches, and splits an access network related to traffic to another access network. Select traffic from the core network to change the access network from the first access network to the second access network and perform ATSSS. Here, the change of the access network may mean switching of the Radio Access Technoloy (RAT). Hereinafter, for convenience of description, it is assumed that the 3GPP access network 210 is a 'first access network' and the Non-3GPP access network 220 is a 'second access network'. And for convenience of description, the traffic is changed from the first access network 210 to the second access network 220 for traffic steering, and the traffic is changed from the first access network 210 to the second access network ( It is assumed that the case is changed to 220 and traffic is simultaneously transmitted to the first access network 210 and the second access network 220 for traffic splitting.

When determining to perform the ATSSS in the core network, it is necessary to check the connection state of the access network 200 associated with the terminal 100. In addition, activation of the control plane and the user plane for all access networks 200 participating in the ATSSS is required. Hereinafter, a method of effectively performing ATSSS will be described.

In the ATSSS method according to an embodiment of the present invention, in order to perform ATSSS from a first access network to a second access network, a network access state and a radio activation state of each access network of the terminal are checked, and the terminal accesses each access network. Enable traffic movement.

2 is a flowchart generally illustrating an ATSSS method according to an embodiment of the present invention.

First, the core network decides to perform the ATSSS and invokes the service to inform the AMF 310 of starting the ATSSS (S210). For example, the SMF 320 may trigger the performance of the ATSSS and inform the AMF 310 to start the ATSSS.

The AMF 310 prepares a connection state of the terminal to the access network 200 performing the ATSSS, and the core network, the terminal 100, and the access network 200 prepare the ATSSS (S220).

A signaling procedure for performing ATSSS is performed between the core network, the terminal 100, and the access network 200 (S230).

After the signaling procedure by step S230 is completed, the access path of the traffic is changed to start the service of the ATSSS (S240). That is, the ATSSS is completed.

There are two ways in which the SMF 320 decides to perform the ATSSS and invokes the service for ATSSS preparation with the AMF 310.

The first method is a method in which a control message including the changed ATSSS rule is transmitted to the terminal 100 after the access network 200 participating in the ATSSS is activated. This is described in more detail in FIG. 3 below.

The second method is a method in which a control message including the changed ATSSS rule is first transmitted to the terminal 100 and the control plane and data plane of the access network 200 participating in the ATSSS are activated. This is described in more detail in FIG. 9 below.

3 is a flowchart showing an ATSSS method according to the first embodiment of the present invention.

The ATSSS method of FIG. 3 is a method of first performing a control plane activation and a user plane activation process for an access network of a terminal and performing an ATSSS control procedure in order to perform ATSSS by a request of a core network. The ATSSS method of FIG. 3 is shown in more detail in FIG. 6.

First, the SMF 320 determines to perform the ATSSS (S310).

The SMF 320 requests the AMF 310 to check the connection status (Connection Management) _CONNECTED or CM_IDLE of the terminal with respect to the access networks 210 and 220 (S320). To this end, the SMF 320 performs service invoking with the AMF 310, and the following three methods may be used for the service invoking method.

In the first service invoking method, when the SMF 320 transmits an N1 message transmitted to the terminal 100 to the AMF 310, the SMF 320 includes a connection state inquiry or activation request of each access network 210 or 220 together. It is a way. Here, a Namf_Comm_N1N2MessageTransfer (Network interface AMF_Commuincation_N1N2MesssageTransfer) message may be used. The first service invoking method will be described in more detail with reference to FIG. 4 below.

In the second service invoking method, the SMF 320 first performs a connection status inquiry or activation request of each access network 210 or 220 before transmitting an N1 message transmitted to the terminal 100 to the AMF 310. to be. Here, a Namf_Comm_UEContextTransfer (Network interface AMF_Communication_UEContextTransfer) message may be used. The second service invoking method will be described in more detail with reference to FIG. 5 below.

The third service invoking method is a method in which the SMF 320 requests only the access status inquiry of each access network 210 or 220 to the AMF 310 and does not request an activation request based on the policies of the network and the terminal.

When the SMF 320 performs service invoking with the AMF 310 in the step S320, the SMF 320 indicates an ATSSS to be performed by the AMF 310 (ATSSS_Indication) and a source PDU session ID. A message including a target PDU session ID, a source access network type (source AN type), and a target access network type (target AN type) may be transmitted. Here, when the PDU session set in the terminal 100 is a MA PDU session, the source PDU session ID and the target PDU session ID may be set to the same ID, in which case one may be omitted. The source access network type may be set to a first access network (3GPP access network) and the target access network type may be set to a second access network (Non-3GPP access network).

4 is a flowchart illustrating a service invoking method according to an exemplary embodiment of the present invention. 4 is the first service invoking method.

As illustrated in FIG. 4, the SMF 320 that determines to perform ATSSS transmits a Namf_Comm_N1N2MessageTransfer message to the AMF 310 (S410). Here, the Namf_Comm_N1N2MessageTransfer message includes ATSSS_indication, source PDU session ID, target PDU session ID, source access network type, source AN type, target AN type, N1 message, and control plane redirection. It contains an activation policy (CP). Here, the N1 message is a message including a changed ATSSS rule and an ATSSS execution request and may be a PDU session modification command message. The control plane reactivation policy (CP_reactivation policy) is a control plane reactivation policy for each access network. If this policy is absent, the default policy promised may be replaced.

When the AMF 310 receives the Namf_Comm_N1N2MessageTransfer message in step S410, the AMF 310 inquires the terminal connection status of the access network (i.e., the access type) associated with the PDU session ID and includes the query result in the Namf_comm_N1N2MessageResponse message to include the SMF 320. Transmit to (S420). Here, the AMF 310 activates and switches to CM_CONNECTED when the connection state of the terminal to the target access network is CM_IDLE. The AMF 310 transmits the changed ATSSS rule and the N1 message (for example, PDU session command message) that commands the ATSSS to the terminal 100.

5 is a flowchart illustrating a service invoking method according to another exemplary embodiment of the present invention. 5 is the second service invoking method.

As shown in FIG. 5, the SMF 320 that determines to perform the ATSSS transmits a Namf_Comm_UEContextTransfer message to the AMF 310 (S510). Here, the Namf_Comm_UEContextTransfer message may include ATSSS_indication, a source PDU session ID, a target PDU session ID, a source access network type, and a target access network type as a first input type. It may include. The Namf_Comm_UEContextTransfer message is a second input type and includes a state-specific access inquiry (GET_ACCESS_CM_STATE), a source PDU session ID, a target PDU session ID, a source AN network type, and a source access network type (source AN type). target AN type).

When the AMF 310 receives the Namf_Comm_UEContextTransfer message including the first input type in step S510, the AMF 310 recognizes the ATSSS_Indication indicator to activate the access state of the terminal 100 together with the status inquiry of the access network 200. On the other hand, when receiving the Namf_Comm_UEContextTransfer message including the second input type in step S510, the AMF 310 recognizes the access status inquiry (GET_ACCESS_CM_STATE) indicator and performs only the status inquiry of the access network 200.

The AMF 310 inquires the connection state of the access network 200 and transmits the inquiry result to the SMF 320 (S520). When there is a network that is not connected among the access networks in the connection state result received in step S520, the SMF 320 requests the activation of the corresponding network to the AMF 310 (S530).

Next, referring to FIG. 3, reactivation of the control plane is performed (S330). That is, the terminal 100 activates the connection state of each access network to make the network connection state. If the access state for each access network 200 is IDLE, the AMF 310 requests the terminal 100 to access the network through the access network. The terminal 100 accesses the network through a corresponding access network (ie, an inactive access network) in a service request procedure and acquires location information of the terminal for each access network (ie, node information of the accessed access network). To the net. The AMF 310 switches the state of each access network of the terminal 100 to a network access state.

Meanwhile, the control plane reactivation policy may have a different policy for each access network of the terminal. That is, when the terminal 100 receives the reactivation command of the access network from the AMF 310, the terminal 100 does not perform the reconnection process according to the reactivation policy or is transmitted by the AMF 310 or the SMF 320. The reconnection process can be performed only for the selected access network. Here, the control plane rehabilitation policy may have three policies. As a first policy, the terminal 100 may activate control planes of all access networks, thereby bringing all access networks into a network connection state. As a second policy, in the master / slave access network structure, the terminal 100 may activate only the control plane of the master access network to make a network connection. As a third policy, the terminal 100 may activate the control plane of the access network selected and delivered from the network to make the network connected. According to the three policies, the terminal 100 performs access through the selected access network. The control signal message for performing ATSSS in step S350 is exchanged through the control plane path activated in step S330.

In order to perform data transmission through the path to the access network reconnected by the terminal 100 in step S330, a user plane is activated (S340). A wireless access section is set between the terminal 100 and the reconnected access network, and an N3 tunnel between the reconnected access network and the UPF 330 is set.

After the preparation for performing the ATSSS is completed by the steps S330 and S340, a control procedure for the ATSSS is performed (S350). Here, the core network requests the terminal 100 to change the data transmission rule for performing ATSSS from the first access network 210 to the second access network 220 by transmitting the N1 message to the terminal 100. The core network requests the first access network 210 and the second access network 220 to modify (add / delete / change) the amount of resources related to the changed traffic.

FIG. 6 is a flowchart illustrating the ATSSS method of FIG. 3 in detail.

In the ATSSS method of FIG. 6, before the PDU session modification procedure is performed, the connection state of the first access network 210 and the second access network 220 is confirmed, and the access network in the CM_IDLE state is changed to the CM_CONNECTED state. In order to be converted, a service request procedure is performed.

First, it is assumed that a PDU session is established through a PDU session establishment procedure (S601). That is, the terminal 100 may establish a PDU session through the first and second access networks 210 and 220, and the PDU session may be a MA PDU session. The PDU session establishment procedure can be known to those skilled in the art to which the present invention pertains, and thus a detailed description thereof will be omitted.

The session management policy change by the PCF 500 or the UDM 600 may be performed (S602). By following the session management policy change, the following step S603 may be performed.

The SMF 320 determines to perform the ATSSS (S603). There may be various conditions under which the SMF 320 determines to perform the ATSSS. The SMF 320 may monitor the load for each access network and determine that the ATSSS is performed when the load exceeds a predetermined threshold. The SMF 320 may determine to perform the ATSSS when a change of the ATSSS rule is requested from the PCF 500 or the UDM 600 by the step S602. In addition, when downlink traffic arrives from the DN 400 to the UPF 330 but the connection state of the first access network 210 of the associated PDU session is not CM_CONNECTED, the SMF 320 moves to the second access network 220. In this case, the ATSSS may be determined to transmit downlink traffic.

In FIG. 6, for convenience of description, it is assumed that the SMF 320 determines to perform ATSSS by changing from the first access network 210 to the second access network 220.

When the SMF 320 determines to perform ATSSS in step S603, the SMF 320 transmits a Namf_Comm_N1N2MessageTransfer message to the AMF S310 (S604). Here, the Namf_Comm_N1N2MessageTransfer message includes an ATSSS_indication, a source PDU session ID, a target PDU session ID, a source access network type, a target AN network type, and a N1 message. ATSSS_indication is an indicator for instructing AMF 310 to prepare for a connection state for each access network before starting to perform ATSSS. The source PDU session ID and the target PDU session ID indicate PDU session information to perform ATSSS. Such PDU session information may be one MA PDU session ID and may be different source PDU session IDs and target PDU session IDs. The source access network type may be set to a first access network (3GPP access network) and the target access network type may be set to a second access network (Non-3GPP access network). Meanwhile, the N1 message transmitted to the terminal 100 includes modified (updated) ATSSS rules, and the N1 message may be a PDU session modification command message. The modified (updated) ATSSS rule may be included inside the N1 message (eg, a PDU session modification command message) or outside the N1 message. The ATSSS rule is a path rule for access traffic to the access network to be switched. Here, the access traffic may be IP flow information, service data flow (SDF), quality of service flow identifier (QFI), or the PDU session itself. The ATSSS rule is a rule for selecting an access network in the transmission of traffic. When a change in access status for each access network occurs, the access network is selected based on the access preference of the target traffic, and the network and the terminal may transmit and receive traffic by sharing the ATSSS rules.

When the AMF 310 receives the Namf_Comm_N1N2MessageTransfer message in step S604, the AMF 310 transmits a Namf_comm_N1N2MessageResponse message to the SMF 320 including the result of inquiring and inquiring the access status of the terminal to the access network (S605). Here, the query result may be specified in a cause field. When all accesses are in a connected state, cause = SUCCESS may be set, and in this case, steps S606 and S607 below may be omitted. If a target access network (ie, the second access network 220 as the access network to which the traffic path is to be changed) is not connected and a preparation step is necessary, cause = reaching target AN may be set, in which case, the following steps S606 and S607 Step is performed.

The AMF 310 checks the ATSSS_Indication included in the Namf_Comm_N1N2MessageTransfer received in step S604, and then activates the control plane for the access network associated with the PDU session of the terminal 100, thereby preparing the control message to be transmitted and received. The AMF 310 prepares data traffic to be transmitted by activating a user plane for an access network associated with a PDU session of the terminal 100. If the control plane is activated in step S606 below and the user plane is activated in step S607 below, in step S608 or step S609 below, the AMF 310 transmits an N1 message to the terminal 100 to perform ATSSS.

When the connection of the terminal 100 to the second access network 220 is inactivated, the AMF 310 connects the terminal 100 to the second access network 200 using a service request. Activate (S606). In this case, a network triggered service request procedure may be used as a method of activating a connection state of the terminal to the second access network 220 (that is, transition from CM_IDLE to CM_CONNECTED). The network triggered service request procedure is described in the 3GPP TS 23.502 standard and will be omitted by those skilled in the art to which the present invention pertains.

Meanwhile, when the user plane of the terminal 100 with respect to the second access network 220 is in an inactive state, the user plane UP is activated (S607). That is, an N3 tunnel is established between the second access network 220 and the UPF 330. Access network (AN) tunnel information, core network (CN) tunnel information, allowed Quality of Service Flow Identifier (QFI), and Quality of Service (QoS) flow list information include the second access network 220 and the UPF 330. Exchanged between The method of activating the user plane can be known to those skilled in the art to which the present invention pertains, and thus a detailed description thereof will be omitted.

After the control plane is activated by the step S606 and the data plane (that is, the user plane) is activated by the step S607, the AMF 310 sends an N2 Session Request message to the second access network 220. Or it transmits to the first access network 210 (S608, S609). The AMF 310 encodes the PDU session modification command received in step S604 to N1, encodes the CN (Core Network) N3 tunnel information into the N2 information, and then N2 session request message. Include it in That is, the N2 session request message includes a PDU session modification command message and CN N3 tunnel information. In addition, the PDU session modification command message includes the changed (updated) ATSSS rule. Meanwhile, the PDU session modification command message including the changed ATSSS rule (for example, the traffic movement path is changed from the first access network 210 to the second access network 220) may be transmitted to the second access network 220 or the second access network 220. 1 is transmitted to the terminal 100 through the access network 210.

Next, the core network starts a PDU modification request procedure and performs a change of the PDU session for the ATSSS (S610). The PDU modification request procedure is described in the 3GPP TS 23.502 standard and will be omitted by those skilled in the art to which the present invention pertains. Meanwhile, the changed ATSSS rule is applied between the first access network 210 and the UPF 330 through the PDU modification request procedure.

In order to apply the changed ATSSS rule to the N3 tunnel established between the second access network 220 and the UPF 330, an N4 session change procedure is performed (S611). That is, the SMF 320 transmits an N4 Session Modification Request message to the UPF 330 and receives an N4 Session Modification Response message from the UPF 330. That is, the SMF 320 generates an N4 rule mapped to the changed (updated) ATSSS rule and transmits the generated N4 rule to the UPF 330 through an N4 Session Modification Request message. Receive a response.

7 is a flowchart illustrating an operation of the AMF 310 according to an embodiment of the present invention. In more detail, FIG. 7 is a diagram illustrating the operation of the AMF 310 before the step S608 or the step S609.

The AMF 310 inquires the connection (CM) status of the source access network type and the target access network type included in the Namf_Comm_N1N2MessageTransfer message received in step S604. That is, the AMF 310 inquires about the connection state between the first access network 210 and the second access network 220.

The AMF 310 checks the connection state of the first access network 210 (S710). When the connection state of the first access network 210 is CM (Connection Management) _CONNECTED, the AMF 310 sends an N2 PDU Session Request message to the first access network 210 as in step S609. Transmit (S720, S730).

The AMF 310 checks the connection state of the second access network 220 when the first access network 210 is CM_IDLE instead of CM_CONNECTED (S740). When the connection state of the second access network 220 is CM (Connection Management) _CONNECTED, the AMF 310 sends an N2 PDU Session Request message to the second access network 220 as in step S608. Transmit (S750, S760).

When the connection state of the first access network 210 and the second access network 220 is CM_IDLE, the AMF 310 waits to perform ATSSS until the control plane is activated (S770).

8 is a flowchart showing the operation of the terminal 100 according to an embodiment of the present invention. In more detail, FIG. 8 illustrates access state and radio resource control of an access network when the terminal 100 receives an ATSSS (that is, when the terminal 100 receives an N1 message after S608 or S609 in FIG. 6). It shows how to operate according to the state.

When the terminal 100 wants to switch the traffic path from the first access network 210 to the second access network 220, the terminal 100 checks the access state of the second access network 220 (S810).

If the access state of the second access network 220 is not CM_CONNECTED in step S810, the terminal 100 performs a service request procedure to the second access network 220, the second access network 200 ) Is converted to CM_CONNECTED (S820, S830).

When the connection state of the second access network 220 is CM_CONNECTED, the terminal 100 checks a radio resource control (RRC) state of the second access network 220 (S820 and S840).

If the RRC_INACTIVE in step S840, the terminal 100 performs the RRC Resume procedure to switch to the RRC_ACTIVE state (S850, S860).

If the second access network 220 is CM_CONNECTED and RRC_ACTIVE, the second access network 220 transmits an N2 PDU Session Response message to the core network (ie, the AMF 310) (S870). . At this time, access tunnel information (AN tunnel info) of the first and second access networks 210 and 220 are also transmitted. The N2 PDU session response is a response message to the N2 Session Request transmitted in step S608 or S609 and is transmitted in step S610.

9 is a flowchart illustrating an ATSSS method according to a second embodiment of the present invention.

The ATSSS method of FIG. 9 is similar to the ATSSS method of FIG. 6, but differs in the manner in which the AMF 310 processes a PDU session modification command message. In FIG. 6, after the AMF 310 receives an N1 message (ie, a PDU Session Modification Command) from the SMF 320, the AMF 310 activates the control plane and the user plane of the terminal, and then transmits the N1 message to the terminal 100. do. In contrast, in FIG. 9, immediately after the AMF 310 receives the N1 message from the SMF 320, the AMF 310 immediately transmits the N1 message to the terminal 100, after which the terminal 100 activates the control plane and the user plane. To start. In FIG. 9, the terminal 100 responds to the PDU session modification command Ack to the SMF 320, and the SMF 320 requests the UPF 330 to change the ATSSS rule and the AN (Access Network) tunnel. do. The ATSSS method of FIG. 9 will be described in more detail below.

First, it is assumed that a PDU session is established through a PDU session establishment procedure (S901). That is, the terminal 100 may establish a PDU session through the first and second access networks 210 and 220, and the PDU session may be a MA PDU session.

The session management policy change by the PCF 500 or the UDM 600 may be performed (S902). By the session management policy change, the following S903 step may be performed.

The SMF 320 determines to perform the ATSSS (S903). There may be various conditions under which the SMF 320 determines to perform the ATSSS. The SMF 320 may monitor the load for each access network and determine to perform ATSSS when the load exceeds a predetermined threshold. The SMF 320 may determine to perform the ATSSS when a change of the ATSSS rule is requested from the PCF 500 or the UDM 600 by the step S902. In addition, when downlink traffic arrives from the DN 400 to the UPF 330 but the connection state of the first access network 210 of the associated PDU session is not CM_CONNECTED, the SMF 320 moves to the second access network 220. In this case, the ATSSS may be determined to transmit downlink traffic.

In FIG. 9, for convenience of description, it is assumed that the SMF 320 determines to perform ATSSS by changing from the first access network 210 to the second access network 220.

When the SMF 320 determines to perform ATSSS in step S903, the SMF 320 transmits a Namf_Comm_N1N2MessageTransfer message to the AMF S310 (S904). The Namf_Comm_N1N2MessageTransfer message includes ATSSS_indication, source access network type (source AN type), target access network type (target AN type), source PDU session ID, target PDU session ID, and N1 message. ATSSS_indication is an indicator for instructing the AMF 310 to prepare for connection status for each access network before starting to perform ATSSS. The source PDU session ID and the target PDU session ID indicate PDU session information to perform ATSSS. Such PDU session information may be one MA PDU session ID and may be a source PDU session ID and a target PDU session ID. The source access network type may be set to a first access network (3GPP access network) and the target access network type may be set to a second access network (Non-3GPP access network). The N1 message may be a PDU session modification command message. Here, the PDU session modification command message is ATSSS_indication for instructing the terminal 100 to activate the target access network in an inactive state, a target access type indicating the second access network 220 in the CM_IDLE state, and changed. ATSSS rules that indicate access traffic and path.

The AMF 310 transmits a Namf_comm_N1N2MessageResponse message to the SMF 320 in response to the Namf_Comm_N1N2MessageTransfer message received in step S904 (S905). Here, the Namf_comm_N1N2MessageResponse message includes a cause field, a source CM state field, and a target CM state field. If all access networks are accessible, cause = SUCCESS may be set. If the target access network is not accessible, cause = reaching target access may be set. The access state of the first access network 210 associated with the PDU session of the terminal 100 may be set in the source CM state field, and the access state of the second access network 220 may be set in the target CM state field. have.

The AMF 310 transmits an N1 message (PDU session modification command message) to the first access network 210, and the first access network 210 transmits an N1 message (PDU session modification command message) to the terminal 100. (S906). When the PDU session modification command message includes the ATSSS_indication field, the terminal 100 activates the control plane of the target access network (ie, the second access network) corresponding to the target access type. Here, the activation process is performed differently according to the access state of the second access network 220. When the connection state of the second access network 200 is CM_CONNECTED and the RRC state is RRC_ACTIVE, steps S907 and S908 below are omitted and step S909 is performed. If the connection state of the second access network 200 is CM_CONNECTED and the RRC state is RRC_INACTIVE, the following step S907 is performed. If the access state of the second access network 220 is CM_IDLE, step S908 is performed.

If the connection state of the second access network 200 is CM_CONNECTED and the RRC state is RRC_INACTIVE, the terminal 100 performs an RRC resume procedure (S907). RRC Resume (RRC Resume) procedure is known to those of ordinary skill in the art to which the present invention will be omitted a detailed description.

When the connection state of the second access network 200 is CM_IDLE, the terminal 100 performs a service request procedure to reconnect to the second access network 200 (S908). Here, the service request procedure is described in the 3GPP TS 23.502 standard as a UE triggered service request procedure, and those skilled in the art to which the present invention pertains know a detailed description thereof. do. By the service request procedure, the AMF 310 knows the location of the terminal 100 in the second access network 220 and the control signal because the connection state of the terminal 100 to the second access network 220 is CM_CONNECTED. Can be transmitted and received. That is, the control plane is activated by the service request procedure. After the control plane is activated, a user plane reactivation process for the second access network 220 is performed (S908). In the user plane reactivation process, radio resources are established between the terminal 100 and the second access network 220, and an N3 tunnel is established between the second access network 220 and the UPF 330.

The terminal 100 transmits an N1 message (PDU session modification command ACK) to the AMF 310 through the first access network 210 (S909).

Next, the AMF 310 performs a procedure after S909 in the PDU modification request procedure to change the PDU session for the ATSSS (S910). That is, in order for the changed ATSSS rule to be applied to the UPF 330, the SMF 320 transmits an N4 Session Modification Request message to the UPF 330 to transfer the user traffic forwarding rule to the UPF 330. send. The N4 Session Modification Request message may include a forwarding rule (PDR (Packet Detection Rule = {IP 5 tuple set, forwarding path}) of the traffic that will change the access network, and an N4 session ID associated with the PDU session ID. have.

The SMF 320 transmits a Namf_comm_N1N2MessageTransfer message to the AMF 310 (S911). The Namf_comm_N1N2MessageTransfer message contains ATSSS completion, an indicator that the ATSSS signaling procedure has been completed. The Namf_comm_N1N2MessageTransfer message further includes a source access network type (source AN type), a target access network type (target AN type), a source PDU session ID, a target PDU session ID, and N2 Session Management (SM) information. It may include. Here, the N2 SM information (info) includes a PDU session ID, a Quality of Service Flow Identifier (QFI), and a remove command indicator.

The AMF 310 transmits an N2 Request message including the N2 SM information received in step S910 to the first access network 210 (S912). The first access network 210 removes the QFI list from the PDU session ID and releases resources allocated thereto using the received N2 SM information. That is, the first access network 210 changes the resource of the first access network 210 by using the N2 SM information received in step S912.

10 is a flowchart illustrating an ATSSS method according to a third embodiment of the present invention.

In FIG. 10, the data forwarding rule change function of the UPF 330 reflecting the ATSSS rule changed in the access control activation process by the service request procedure is also performed. When the AMF 310 receives a service request for activating the second access network 220, the SMF 320 requests the UPF 330 to set up and change an N4 session. The ATSSS method of FIG. 10 may omit the PDU session change procedure from the ATSSS method of FIG. 9.

One function of the core network, for example, the SMF 320 determines to perform ATSSS (S1000). That is, as shown in FIG. 6 or FIG. 9, the PCF 500, the UDM 600, or the SMF 320 may determine to perform ATSSS.

The SMF 320 decides to service by changing the traffic of the first access network 210 to the second access network 220, constructs an N1 message for an ATSSS request, and converts the N1 message into an AMF communication message transfer ( The AMF 310 is invoked by inclusion in the transfer (S1001). Here, the AMF communication message transfer may be a Namf_Comm_N1N2MessageTransfer message, and the Namf_Comm_N1N2MessageTransfer message may include a PDU session modification command message as an ATSSS request message.

When the AMF 310 receives the AMF communication message transfer from the SMF 320, the AMF 310 checks the connection state of the terminal 100 to the second access network 220 to be changed. When the connection state of the terminal 100 to the second access network 220 is CM_IDLE, the AMF 310 indicates that the terminal of the second access network 220 is being searched for in the cause field and enters the target access network. The connection state is also transmitted to the SMF 320 (S1002). That is, the AMF 310 sends an AMF communication message response to the SMF 320. The AMF communication message response may be a Namf_comm_N1N2MessageResponse message, and the Namf_comm_N1N2MessageResponse message may include a field indicating a cause (field) and a connection status of the target access network.

The AMF 310 transmits an N1 message for the ATSSS request to the terminal 100 through the first access network 210 (S1003). Here, the N1 message may be a PDU session modification command message, and the PDU session modification command message may be a source access network type (source AN type) or a target access network type (target AN type). ), A source PDU session ID, a target PDU session ID, ATSSS information, and cause.

When the connection state of the terminal 100 to the second access network 220 is CM_IDLE, the terminal 100 transmits a service request message to the AMF 310 through the second access network 220. (S1004). The service request message includes new PDU session information (target PDU session or active PDU session) related to the traffic to be moved and transmitted. The service request message may further include an ATSSS Access Network (AN) Activation Indicator, an ATSSS information (Info), and an N2 parameter (user location information). Here, the ATSSS information (info) is composed of the target traffic information (Service Data Flow (SDF), source PDU session ID, target PDU session ID, source access network type, target access network type, ATSSS path rule, etc. Can be.

When the AMF 310 receives the service request message in step S1004, the AMF 310 transmits an SMF PDUSession_SM (Session Management) context update message to the SMF 320 (S1005). Here, the SMF PDUSession_SM (Session Management) context update message may be an Nsmf_PDUsession_UpdateSM (Session Management) context message. The Nsmf_PDUsession_UpdateSMcontext message may include an ATSSS Access Network (AN) Activation Indicator, an active PDU session, and ATSSS information included in the service request message.

The SMF 320 applies the changed ATSSS rule and transmits an N4 session establishment and change request message to the UPF 330 (S1006). The UPF 330 changes the transmission path (ie, access network, N3 tunnel information, AN tunnel information, CN tunnel information, etc.) for the designated traffic.

The UPF 330 allocates a Core Network (CN) tunnel of N3 to a target PDU session associated with the second access network 220 and transmits an N4 session response message to the SMF 320 (S1007). Here, the N4 session response message includes CN N3 tunnel information and an amount (ACK).

The SMF 320 transmits an SMF PDUSession_SM (Session Management) context response message to the AMF 310 in response to the step S1005 (S1008). The SMF PDUSession_SM (Context Management) context response message may include an ATSSS Access Network (AN) Activation Indicator, CN N3 tunnel info of the N3 tunnel, and an ACK. The SMF PDUSession_SM (Session Management) context response message may be an Nsmf_PDUsession_UpdateSMcontext Response message.

In step S1004 to step S1008, the control plane including the second access network 220 is activated.

Next, an N3 data path including the second access network 220 is established (S1009). That is, the second access network 220 receives CN tunnel information CN N3 tunnel info allocated by the UPF 330, and allocates an AN tunnel corresponding to the CN tunnel. The second access network 220 configures the assigned AN tunnel as AN tunnel information and transmits the information to the UPF 330. Then, an N2 resource addition request is performed (S1009). That is, modification to the added QFI resource corresponding to the changed PDU session of the ATSSS is requested to the second access network 220.

Meanwhile, an N2 resource release request for the first access network 210 is performed (S1010). That is, the first access network 210 is requested to modify the QFI resource deleted or modified in response to the changed ATSSS PDU session.

11 illustrates a computing system in accordance with an embodiment of the present invention.

The computing system 1100 of FIG. 11 may include a terminal 100, an access network 200, an AMF 310, an SMF 320, an UPF 330, a DN 400, a PCF 500, or a UDM of FIG. 1. (600). Such terminal 100, access network 200, AMF 310, SMF 320, UPF 330, DN 400, PCF 500, or UDM 600 may be a computer system, for example a computer. It may be implemented in a readable medium.

The computer system 1100 may include at least one of a processor 1110, a memory 1130, a user interface input device 1140, a user interface output device 1150, and a storage device 1160 that communicate over a bus 1120. It may include. Computer system 1100 may also include a network interface 1170 coupled to a network. The network interface 1170 may transmit or receive signals with other entities through the network.

The processor 1110 may be a central processing unit (CPU) or a semiconductor device that executes instructions stored in the memory 1130 or the storage device 1160. The processor 1110 may be configured to implement the functions and methods described with reference to FIGS. 1 to 10.

The memory 1130 and the storage device 1160 may include various types of volatile or nonvolatile storage media. For example, the memory may include read only memory (ROM) 1131 and random access memory (RAM) 1132. In an embodiment of the present invention, the memory 1130 may be located inside or outside the processor 1110, and the memory 1130 may be connected to the processor 1110 through various known means.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (20)

As a method of performing ATSSS (Access Traffic Steering, Switching and Splitting) in a network,
When it is determined that the ATSSS is performed from the first access network to the second access network, the Session Management Function (SMF) receives a first message requesting confirmation of the access state of the terminal to the first and second access networks. Transmitting to AMF (Access and Mobility Management Function), and
Receiving, by the SMF, information about a connection state of the terminal from the AMF. The method of claim 1,
Activating a control plane for the second access network when the connection state of the second access network is CM (Connection Management) _IDLE, and
After the control plane is activated, the user plane for the second access network is further activated. The method of claim 2,
Modifying a packet data unit (PDU) session to perform the ATSSS. The method of claim 1,
The first message includes a PDU session modification command message,
And the PDU session modify command message includes a modified ATSSS rule. The method of claim 4, wherein
When the connection state of the second access network is CM (Connection Management) _IDLE, activating a control plane for the second access network;
After the control plane is activated, a user plane for the second access network is activated, and
And sending, by the AMF, an N2 Session Request message including the PDU session modification command message to the first access network or the second access network. The method of claim 4, wherein
And sending, by the AMF, the PDU session modification command message to the terminal through the first access network. The method of claim 6,
The PDU session modification command message includes an indicator indicating that the ATSSS, and the modified ATSSS rule. The method of claim 6,
If the connection state of the second access network is CM (Connection Management) _CONNECTED and the radio resource (RRC) state of the second access network is RRC_INACTIVE, the terminal further includes performing an RRC resume procedure Way. The method of claim 6,
If the connection state of the second access network is CM_IDLE, the method further comprising the terminal performing a reconnection to the second access network. The method of claim 9,
And transmitting, by the terminal, a PDU session modification command amount (ACK) message to the AMF. The method of claim 1,
The receiving step includes the SMF receiving a Namf_comm_N1N2Message response message from the AMF that includes the information. The method of claim 4, wherein
The first message further includes an indicator indicating that the connection status is confirmed, a type of the first access network, a type of the second access network, and a PDU session identifier (ID) associated with the ATSSS. The method of claim 4, wherein
And the first message is a Namf_Comm_N1N2MessageTransfer message. As a method of performing ATSSS (Access Traffic Steering, Switching and Splitting) in a network,
Determining, by the Session Management Function (SMF), to change the traffic of the first access network to a second access network for the ATSSS;
Sending, by the SMF, a second message including a first message for the ATSSS request to an access and mobility management function (AMF), and
Receiving, by the SMF, information on a connection state of a terminal from the AMF. The method of claim 14,
And sending, by the AMF, the first message to the terminal via the first access network. The method of claim 15,
The terminal further comprises the step of transmitting a service request (Service Request) message to the AMF via the second access network when the connection state of the terminal to the second access network is CM (Connection Management) _IDLE. Way. The method of claim 14,
The first message is a PDU session modification command message,
The PDU session modify command message includes a type of the first access network, a type of the second access network, and a Packet Data Unit (PDU) identifier associated with the ATSSS. A network entity that performs ATSSS (Access Traffic Steering, Switching and Splitting) in a network.
A processor that determines to perform the ATSSS and configures a first message requesting confirmation of a connection state of a terminal to an access network related to the ATSSS; and
And a network interface which transmits the first message to another network entity and receives information on the connection state of the terminal from the other network entity. The method of claim 18,
The network entity is a Session Management Function (SMF), and the other network entity is an Access and Mobility Management Function (AMF). The method of claim 18,
The first message is a Namf_Comm_N1N2MessageTransfer message,
The Namf_Comm_N1N2MessageTransfer message includes a PDU session modification command message.
The PDU session modify command message includes a modified ATSSS rule.

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