KR20180106836A - Method and apparatus for management session based on reallocation of pdu session anchor apparatus - Google Patents

Abstract

Disclosed are a session management method based on relocation of a protocol data unit (PDU) session anchor (PSA) apparatus and an apparatus for performing the method. The method of the present invention comprises the following steps of: determining performance of relocation of PSA; establishing a new PSA apparatus through the relocation of the PSA; and releasing an existing PSA apparatus, wherein traffic to the existing PSA apparatus is transferred to the new PSA apparatus through the relocation of the PSA.

Description

TECHNICAL FIELD [0001] The present invention relates to a session management method based on relocation of a protocol data unit session anchor device, and a device that performs the method.

The present invention relates to a session management method based on relocation of a protocol data unit session anchor device and an apparatus for performing the method.

A mobile edge computing (MEC) technique has been proposed to provide a low-latency data service to a user equipment (UE). The MEC technique is used to minimize the round trip time (RTT) between the user equipment and the server providing the service requested by the user equipment. The MEC technique is concerned with placing the geographical location of the server close to the user equipment, as well as reducing the number of routing hops between the user equipment and the server.

The 5G mobile communication network requires that various services be provided to the user equipment via 5G network technology. Thus, the 5G mobile communication network also supports edge computing technology to provide improved quality of service over existing network schemes.

The present invention provides a load balance between edge clouds by changing the edge cloud when there are multiple edge clouds in a 5G core network system or by resetting the 5G local gateway to support the lifecycle of the virtualized 5G local gateways And more particularly,

The present invention relates to a method and an apparatus for providing a continuous service to a load of a user apparatus by flexibly loading a 5G local gateway even when a new user apparatus is connected in addition to an existing user apparatus in a 5G core network system.

A method for performing a session management function (SMF) in a network according to an exemplary embodiment of the present invention is a method for performing a relocation of a protocol data unit session anchor (PSA) to a session of a protocol data unit (PDU) Determining whether to perform the operation; Establishing a new protocol data unit (PDU) anchor device through relocation of the protocol data unit session anchor; And releasing an existing protocol data unit session anchor device, wherein the reassignment of the protocol data unit session anchor causes traffic to the existing protocol data unit session anchor device to be sent to a new protocol data unit (PDU) Device.

The session management functional device may perform relocation of a protocol data unit session anchor (PSA) to an IPv6 multi-homing or an uplink classifier.

The session management functional device can perform relocation of a protocol data unit session anchor (PSA) when there is a request from an event or application function that benefits from relocation of a protocol data unit session anchor for an IPv6 multi-home or uplink delimiter have.

Wherein the session management function device transmits a session establishment request to the new protocol data unit session anchor device, and transmits to the new protocol data unit session anchor device a tunnel ID, an uplink identifier, a packet detection, Rules can be provided.

The session management function device includes a user plane function corresponding to a branching point or an uplink delimiter according to a new IPv6 prefix allocated to a new protocol data unit session anchor device, Functionality: UPF) devices.

The session modification request may include an identifier of a traffic filter that needs to be relocated by the protocol data unit session anchor, and a tunnel ID of the new protocol data unit session anchor device.

Wherein the user plane functional apparatus corresponding to the branching point or the uplink delimiter further includes a session deleting unit that, when the user plane functional apparatus corresponding to the branching point or uplink delimiter successfully updates all the traffic filters requested to be modified by the session management functional unit, You can acknowledge a modified response.

The session management functional device sends a session release request having a session ID to an existing protocol data unit session anchor device, and the existing protocol data unit session anchor device can release the tunnel resources and the contexts associated with the session.

The existing protocol data unit session anchor device may send a session release response with the session ID to the session management function device upon successful release of the tunnel resources and context associated with the session.

Wherein the network supports a session and service continuity (SSC) mode associated with the protocol data unit session and the session and service continuity mode may not be changed during the lifetime of the protocol data unit session .

A session management function (SMF) apparatus in a network according to an embodiment of the present invention performs a relocation of a PDU Session Anchor (PSA) to a session of a protocol data unit (PDU) Establishing a new protocol data unit (PDU) anchor device through relocation of the protocol data unit session anchor, releasing an existing protocol data unit session anchor device, The traffic to the existing protocol data unit session anchor device can be moved to the new protocol data unit (PDU) anchor device through relocation of the session anchor.

The session management functional device may perform relocation of a protocol data unit session anchor (PSA) to an IPv6 multi-homing or an uplink classifier.

The session management functional device can perform relocation of a protocol data unit session anchor (PSA) when there is a request from an event or application function that benefits from relocation of a protocol data unit session anchor for an IPv6 multi-home or uplink delimiter have.

Wherein the session management function device transmits a session establishment request to the new protocol data unit session anchor device, and transmits to the new protocol data unit session anchor device a tunnel ID, an uplink identifier, a packet detection, Rules can be provided.

The session management function device includes a user plane function corresponding to a branching point or an uplink delimiter according to a new IPv6 prefix allocated to a new protocol data unit session anchor device, Functionality: UPF) devices.

The session modification request may include an identifier of a traffic filter that needs to be relocated by the protocol data unit session anchor, and a tunnel ID of the new protocol data unit session anchor device.

Wherein the user plane functional apparatus corresponding to the branching point or the uplink delimiter further includes a session deleting unit that, when the user plane functional apparatus corresponding to the branching point or uplink delimiter successfully updates all the traffic filters requested to be modified by the session management functional unit, Modification response can be notified.

The session management functional device sends a session release request having a session ID to an existing protocol data unit session anchor device, and the existing protocol data unit session anchor device can release the tunnel resources and the contexts associated with the session.

The existing protocol data unit session anchor device may send a session release response with the session ID to the session management function device upon successful release of the tunnel resources and context associated with the session.

The network supports a session and service continuity (SSC) mode associated with the protocol data unit session and the session and service continuity mode is unchanged during the lifetime of the protocol data unit session.

According to an embodiment of the present invention, by changing the edge cloud when a plurality of edge clouds exist in the 5G core network system, or by resetting the 5G local gateway to support the lifecycle of the virtualized 5G local gateway, You can provide load balancing across the cloud.

According to an embodiment of the present invention, even if a new user device is connected in addition to an existing user device in a 5G core network system, the 5G local gateway can be reconfigured to provide a flexible load and a continuous service for the mobility of the user device.

1 is a diagram illustrating a core network including a user plane functional device corresponding to an uplink delimiter according to an embodiment of the present invention.
2 is a diagram illustrating a core network including a user plane functional apparatus corresponding to a branching point for service continuity according to an exemplary embodiment of the present invention.
3 is a diagram illustrating a core network including a user plane functional device corresponding to a branching point for local access to the same data network according to an embodiment of the present invention.
4 is a diagram illustrating a protocol stack for a protocol data unit session according to an embodiment of the present invention.
5 is a diagram illustrating a process of relocating a protocol data unit session anchor according to an embodiment of the present invention.
6 shows a basic situation of a core network according to one embodiment of the present invention.
7 is a diagram illustrating a scenario 1 for load balancing according to an embodiment of the present invention.
8 is a diagram illustrating a scenario 2 for load balancing according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The terms used in the present invention are as follows.

5G Access Network (AN): Includes an NG-RAN or non-3GPP access network connected to a 5G core network.

5G Core Network: Connected to a 5G access network.

Protocol Data Unit (PDU) connectivity service: A service that provides exchange of protocol data units between a user equipment (UE) and a data network (DN).

Protocol Data Unit Session (PDU Session): An association between a user equipment and a data network to provide PDU connectivity services.

Protocol Data Unit Session Type (PDU Session Type): It refers to the PDU session type and includes IPv4, IPv6, Ethernet, and so on.

The Session Management Function (SMF), the Access and Mobility Management Function (AMF), and the User Plane Function (UPF) described in the present invention are software functions, Or may be installed or executed on each of a plurality of hardware.

Reference points in the 5G system shown in Figs. 1 to 3 are defined as follows.

N1: Reference point between the UE and the AMF.

N2: Reference point between the (R) AN and the AMF.

N3: Reference point between the (R) AN and the UPF.

N4: Reference point between SMF and the UPF.

N6: Reference point between the UPF and a Data Network.

At N6, the traffic is forwarded between the UPF device operating as an uplink delimiter and the local data network.

N9: Reference point between two UPFs.

<Session Management>

The 5G core network supports the PDU connectivity service. The PDU connectivity service provides for the exchange of PDUs between the user equipment and the data network. The PDU connectivity service is supported through PDU sessions established in response to a request from the user equipment.

The subscription information includes a plurality of data network names and a default data network name. If a valid data network name is not provided in the PDU session establishment request sent to the 5G core network, the user equipment is assigned to the default data network name

Each PDU session supports one PDU session type. The PDU session supports the exchange of a single type of PDU session requested by the user equipment in establishing the PDU session.

In a 5G core network, a PDU session is established at the request of the user equipment, modified according to the request of the user equipment and the 5G core network, and released according to the request of the user equipment and the 5G core network. .

<User plane management>

User plane management deals with the user plane path of PDU sessions. A PDU session is placed into a single UPF device or a plurality of UPF devices for a given PDU session. The number of UPF devices for a PDU session is unlimited.

For a PDU session of IPv4 or IPv6 type, the PDU session anchor is the IP anchor point of the IP address / prefix assigned to the user equipment. For a PDU session of an IPv4 type PDU session or an IPv6 type multi-homed method, when a plurality of PDU session anchors are used by using an uplink delimiter, one PDU session anchor becomes an IP anchor point for a PDU session . For an IPv6 multi-homed PDU session, there may be multiple IP anchor points.

&Lt; Single PDU session with multiple PDU session anchors >

In order to support selective traffic routing on a data network (DN) or to support SSC mode 3, a Session Management Function (SMF) device sends a Protocol Data Unit (PDU) session to a plurality of N6 interfaces Lt; RTI ID = 0.0 &gt; PDU &lt; / RTI &gt; session. A User Plane Function (UPF) device may terminate a plurality of N6 interfaces to support a PDU session anchor function. Each PDU session anchor supporting a PDU session provides different access to the same data network. Each PDU session anchor corresponds to a UPF device. And the PDU session anchor assigned to establish the PDU session is associated with the SSC mode of the PDU session. And the additional PDU session anchors allocated to the same PDU session are independent of the SSC mode of the PDU session for selective traffic routing to the data network.

Optional traffic routing to the data network is supported. Some selected traffic is forwarded from the N6 interface to a data network close to the access network provided to the user equipment.

There are two processing methods for the PDU session as follows.

(1) Figure 1: UL CL mode according to UL Classifier functionality for PDU session

(2) Figures 2 and 3: IPv6 multi-homing mode for IPv6 multi-homing for PDU session

<Handling of uplink delimiter for PDU session: UL CL mode>

As shown in FIG. 1, in an IPv4, IPv6, or Ethernet PDU session, the SMF device may insert an uplink classifier (UL CL) in the data path of a PDU session. Here, inserting the uplink delimiter means inserting UPF apparatus corresponding to the uplink delimiter into the data path from the user apparatus to the data network in the 5G core network.

  The uplink delimiter is a feature supported by the UPF and is used to locally divert some traffic matching the traffic filters provided by the SMF device. The insertion and removal of uplink delimiters is determined or controlled by the SMF device using conventional N4 and UPF capabilities. The SMF device includes one or more UPF devices that support uplink delimiter functionality in the data path of the PDU session.

The user equipment does not recognize the traffic switching by the uplink delimiter. And, the user equipment does not involve both insertion and removal of uplink delimiters. In a PDU session according to the IP type, the user equipment associates a PDU session with either a single IPv4 address assigned by the network or a single IPv6 prefix.

When an uplink delimiter function is inserted into the data path of a PDU session, there are a plurality of PDU session anchors for the PDU session. These PDU session anchors provide different access to the same data network (DN). Referring to FIG. 1, the UPF apparatus is an UPF apparatus supporting an uplink delimiter function and a UPF apparatus supporting a PDU session anchor function.

The uplink delimiter provides forwarding of uplink traffic towards different PDU session anchors. The uplink delimiter then merges downlink traffic to the user equipment. Here, traffic is integrated on the link to the user equipment by different PDU session anchors. The integration of traffic is based on traffic detection and traffic forwarding rules provided by the SMF device.

The uplink delimiter applies a filtering rule and determines how the packet is to be routed. Here, the filtering rule means to check the prefix of the destination IP address or the uplink IP packets transmitted by the user equipment. A UPF device supporting uplink delimiters can be controlled by an SMF device that supports traffic measurement for LI and traffic measurement to charge bit rate enforcement per PDU session AMBR have.

For a PDU session for the uplink delimiter, the uplink and downlink session-AMBR are defined in the SMF device selected by the UPF device supporting the uplink delimiter function.

In addition, UPF devices supporting uplink delimiters support PDU session anchors for connectivity of local access to the data network. For example, the UPF device supports tunneling or NAT on the N6. The UPF device can be controlled by the SMF device.

Additional uplink delimiters or additional PDU session anchors may be inserted into the data path of the PDU session to create new data paths for the same PDU session. The way to organize the data path of all uplink delimiters in a PDU session is based on operator configuration and SMF logic. There is one UPF device supporting an uplink identifier for connecting an access network (AN) through the N3 interface.

The process by which a UPF device is inserted into the data path of a PDU session is shown in FIG. The same UPF can support both uplink delimiter and PDU session anchor functions. The user equipment does not participate in the procedure for service continuity in the UL CL mode shown in FIG. Here, and the SMF device can selectively release an existing PDU session anchor in UL CL mode.

<Handling of IPv6 multihoming for PDU session: IPv6 multi-home mode>

A PDU session is associated with a plurality of IPv6 prefixes. This is referred to as a multi-home PDU session. A multi-home PDU session provides access to the data network via one or more PDU session anchors. Other user plane paths leading to other PDU session anchors are branched out in a common UPF referred to as a UPF that supports a "Branching Point Function ". The branching point provides forwarding of uplink traffic towards other PDU session anchors and merges traffic from different PDU session anchors on the link to the user equipment.

A UPF device supporting the branching point function can be controlled by an SMF device supporting traffic measurement for traffic replication for the LI and for charging the bit rate enforcement per PDU session AMBR. have. The insertion and removal of UPF devices supporting branching points are determined or controlled by the SMF device using generic N4 and UPF capabilities. The SMF device may decide to insert a UPF that supports the branch point function into the data path of the PDU session during the establishment of the PDU session or after the PDU session is established. The SMF device may then decide to remove the UPF supporting the branch point function from the data path of the PDU session after the PDU session is established.

The multi-home of the PDU session may be applied to PDU sessions of the IPv6 type. The request of the PDU session type "IP" or "IPv6 " implies supporting a multi-home PDU session for IPv6 at the user equipment.

The use of multiple IPv6 prefixes in a PDU session has the following characteristics.

The UPF supporting the branching point function is constituted by an SMF device that spreads uplink traffic between IP anchors based on the source prefix of the PDU. Here, the source prefix of the PDU may be selected by the user equipment based on the routing information and preferences received from the network.

IETF RFC 4191 is used to configure routing information and preferences that affect the selection of source prefixes on user devices. This corresponds to scenario 1 "IPv6 Multi-homing without Network Address Translation" defined in the IETF RFC. This allows the data network to create a branching point without recognizing the routing table and maintains the first hop router function in the IP anchors.

The multi-home PDU session shown in Figure 2 is used to support make-before-break service continuity to support SSC mode 3

In addition, the multi-home PDU session shown in Fig. 3 is used to support cases where the user equipment needs to access both local service (e.g., local server) and central service (ex. Internet).

If a multi-home PDU session is used to support a service continuity case, or if a multi-home PDU session is used to support local access to the data network, then the user device will "Relocation of SSC mode 3 PDU Session Anchor with IPv6 Multi homed PDU session ".

In the present invention, the UPF apparatus can support both the branching point and the PDU session anchor function.

<Session and service continuity>

Supporting session and service continuity in the 5G system architecture can address various continuity requirements of different applications and services for the user equipment. 5G systems support different session and service continuity modes (SSCs). The SSC mode associated with the PDU session is not changed during the lifetime of the PDU session.

In SSC mode 1, the network preserves the continuity service to be provided to the user equipment. In an IPv4, IPv6 type PDU session, the IP address is preserved.

In SSC mode 2, the network may release a continuity service to be transmitted to the user equipment and a PDU session corresponding to the continuity service. In the IPv4, IPv6 type, the network may release the IP addresses assigned to the user equipment.

In SSC mode 3, changes in the user plane are visible to the user device. On the other hand, the network ensures that the user equipment does not incur any loss of connectivity. The connection through the new PDU session anchor is established before the previous connection is disconnected for even better service continuity. The IP address is not preserved in SSC mode 3 when the PDU session anchor is changed for IPv4, IPv6 type.

The process of adding or removing additional PDU session anchors in a PDU session for local access to the data network is independent of the SSC mode of the PDU session.

<Service & Session Continuity mode>

(1) SSC mode 1

For a PDU session in SSC mode 1, the UPF, acting as a PDU session anchor in establishing a PDU session, is maintained regardless of the access mechanism (ex / access type, cells) for the user device to successfully access the network.

For IPv4 and IPv6 type PDU sessions, IP continuity is supported regardless of the mobility event of the user equipment.

If the IPv6 multi-home or uplink delimiter is applied to a PDU session in SSC mode 1, the network assigns additional PDU session anchors to the PDU session based on the local policy. Further PDU session anchors are released or allocated. The user equipment does not expect that additional IPv6 prefixes will be maintained during the lifetime of the PDU session. SSC mode 1 can be applied to any PDU session type or any access type.

(2) SSC mode 2

If the PDU session in SSC mode 2 has a single PDU session anchor, the network can trigger the release of the PDU session and instruct the user device to immediately establish a new PDU session to the same data network. The trigger condition depends on an operator policy (e.g., a request from an application function based on load conditions). When a new PDU session is established, a new UPF acting as a PDU session anchor may be selected.

On the other hand, if the PDU session in SSC mode 2 has multiple PDU session anchors (e.g., in the case of a multi-home PDU session applied to a PDU session in SSC mode 2 or an uplink delimiter), the additional PDU session anchor May be released or allocated.

SSC mode 2 can be applied to any PDU session type and any access type. In the uplink delimiter mode, the user equipment does not participate in the relocation procedure of the PDU session anchor, so that the presence of a plurality of PDU session anchors is not visible to the user equipment.

(3) SSC mode 3

For a PDU session in SSC mode 3, before the connection between the user device and the old PDU session anchor is released, the network allows to establish connectivity of the user device to the same data network via the new PDU session anchor . When applying a trigger condition, the network may determine whether to select a UPF that supports a suitable PDU session anchor for new conditions of the user equipment (e.g., a point of attachment of the network).

SSC mode 3 applies to any PDU session type or any access type.

For a PDU session of IPv4 or IPv6 type, the process of changing the PDU session anchor is performed. The new IP prefix anchored at the PDU session anchor is dependent on the IPv6 multihoming and is allocated within the same PDU session. Alternatively, the new IP prefix is applied to the setup process of the PDU session in SSC mode 3 or to the additional PDU session anchors of the PDU session established in SSC mode 1. The new IP address or new IP prefix may be assigned to a new PDU session triggered by the user equipment to establish.

After a new IP address or a new IP prefix is assigned, the old IP address or the old IP prefix is maintained for the specified time indicated by the user device and released thereafter.

If the PDU session in SSC mode 3 has a plurality of PDU session anchors (e.g., in the case of multi-home PDU sessions, or in the case of an uplink delimiter applied to a PDU session in SSC mode 3) Or may be assigned.

<SSC mode selection>

The SSC mode selection policy is used to determine (i) the type of session or (ii) the type of session and service continuity mode (SSC mode) associated with a group of applications or applications for the user equipment.

It is possible for the operator to provide the SSC mode selection policy to the user equipment. The SSC mode selection policy may include one or more SSC mode selection policy rules that may be used by the user device to determine the type of SSC mode associated with the application or groups of applications. The SSC mode selection policy may then include a default SSC mode selection policy rule matching all applications of the user equipment.

If the application does not specify the SSC mode by itself while the application is requesting data transfer (e.g., opening a network socket), the user device may select the SSC mode associated with the application using the SSC mode selection policy. In addition, operations applied to the user equipment and the network are described below.

a) If the user equipment has already established PDU session matching the SSC mode associated with the application, then the user equipment will not be able to use the already established PDU &lt; RTI ID = 0.0 &gt; Routes the application's data within the session. Conversely, if the user equipment does not have an already established PDU session matching the SSC mode associated with the application, the user equipment may request to establish a new PDU session matching the SSC mode associated with the application.

b) The SSC mode associated with the application is either the SSC mode included in the non-default SSC mode selection policy rule that matches the application, or the SSC mode included in the default SSC mode selection policy rule. If the SSC mode selection policy does not include a default mode selection policy rule and no other SSC mode selection policy rules match the application, the user equipment may request a PDU session that does not provide SSC mode. In this case, the network can determine the SSC mode of the PDU session.

The SSC mode selection policy rules provided by the user device may be updated by the operator.

The SMF device receives a list of SSC modes per DNN (Data Network Name) and a default SSC mode as part of the subscription information from a Unified Data Management (UDM) device.

If the user equipment provides the SSC mode when a new PDU session is requested, the SMF device can either accept the requested SSC mode based on subscription or local configuration, or modify the requested SSC mode, Select the mode.

If the user equipment does not provide SSC mode when a new PDU session is requested, the SMF device may apply the local configuration to select the default SSC mode for the data network listed in the subscription or to select the SSC mode.

When a static IP address / IP prefix is assigned to a PDU session, SSC mode 1 sends a PDU session &lt; RTI ID = 0.0 &gt; (SSN) &lt; / RTI &gt; based on a static IP address / IP prefix subscription for DNN (Data Network Name) and S- NSSAI Lt; / RTI &gt;

4 is a diagram illustrating a protocol stack for a protocol data unit session according to an embodiment of the present invention.

Referring to FIG. 4, a protocol stack for user plane transport associated with a PDU session is disclosed.

PDU layer: The PDU layer corresponds to a PDU transmitted between a user equipment and a data network via a PDU session. If the PDU session type is IPv6, then the PDU layer corresponds to an IPv6 packet. If the PDU session type is Ethernet, the PDU layer corresponds to the Ethernet frame.

GPRS Tunneling Protocol (GTP U) for the User Plane: The GTP U protocol allows different PDU sessions (different PDU session types) by tunneling user data over N3 (interface between 5G access network node and UPF device) ) Of the traffic of the mobile station.

GTP encapsulates PDUs. And GTP provides encapsulation per PDU session level. The GTP then transmits the marking associated with the QoS flow.

5G encapsulation: The 5G encapsulation layer multiplexes traffic in different PDU sessions corresponding to different PDU session types through N9, the interface between the different UPFs in the 5G core network. 5G encapsulation provides encapsulation per PDU session level. The 5G encapsulation layer then transmits the marking associated with the QoS flow.

5G Access Network (AN) protocol stack: This stack is a collection of protocols and layers that depend on the access network.

The number of UPF devices in the data path is not limited. For an uplink classifier (UL CL) or branching point in the data path of a PDU session, the uplink delimiter or branching point behaves like a UPF device corresponding to a non-PDU session anchor. There are a plurality of N9 interfaces branching out at the uplink delimiter or branching point that respectively lead to different PDU session anchors.

5 is a diagram illustrating a process of relocating a protocol data unit session anchor according to an embodiment of the present invention.

The relocation procedure of the PDU Session Anchor (PSA) anchor (PDU Session Anchor: PSA) shown in FIG. 5 is triggered by the session management function device. The reordering process of the additional PDU session anchor described in FIG. 5 is independent of the SSC mode of the PDU session.

At this time, if it is necessary to modify the IPv6 multi-home or uplink delimiter rule, the session management apparatus performs the relocation procedure of the PDU session anchor. Here, the IPv6 multi-home or uplink delimiter rule may be a traffic filter inside the IPv6 multi-home or uplink delimiter.

If it is necessary to modify the IPv6 multi-home or uplink delimiter rules, the additional PDU session anchor is established by the IPv6 multi-home or uplink delimiter, and some or all of the traffic moves to the additional PDU session anchor. In FIG. 5, PSA1 (PDU session anchor 1) and PSA2 (PDU session anchor 2) represent additional PDU session anchors. PSA1 means an existing PDU session anchor, and PSA2 means a new PDU session anchor. Both PSA1 and PSA2 may be established by the same branching point or uplink delimiter.

Hereinafter, the branching point or uplink delimiter may mean a user plane function (UPF) device corresponding to a branching point or an uplink delimiter.

(Stage 1

The SMF device may either (i) benefit from relocation of the PDU session anchor for the IPv6 multi-home or uplink delimiter, or (ii) relocate the additional PDU session anchor (PSA) if there is a request from the application function via the SMF device relocation &lt; / RTI &gt;

(2) Step

The SMF device sends an N4 session establishment request to the PDU session anchor 2 and transmits a session establishment request to the PDA session anchor 2 by sending a session establishment request to the PDA session anchor 2, Enforcement and reporting rules. If the tunnel ID is assigned by the SMF, the tunnel ID is provided in step (2). PSA2 acknowledges by transmitting a N4 session establishment response. The tunnel ID of PSA2 is provided to the SMF device at this stage.

In the IPv6 multihoming scheme for a PDU session, the SMF device may allocate a new IPv6 prefix corresponding to PSA2.

(3a)

The SMF device updates the UL Traffic Filter according to uplink delimiter rules associated with (i) the IPv6 prefix assigned to PSA2 or (ii) the SMF device is interested in moving the traffic flow from PSA1 to PSA2 A session modification request may be transmitted to the branching point or the uplink delimiter. The N4 session modification request includes the identifier of the traffic filter that the PSA needs to relocate, and the tunnel ID of PSA2. This is because the branching point or uplink separator updates the PSA2 to the N9 interface for traffic filters that need to relocate the PDU session anchor.

The identifier of the traffic filter may be an index of the traffic filter, a single value of the information filter of the traffic filter (e.g., a tunnel ID of the next hop), a combination of several information filters of the traffic filter value) (e.g., the tunnel ID of the next hop with the source port number).

(3b)

If the branching point or uplink deleter successfully updates all traffic filters requested by the SMF device, the branch point or uplink delimiter informs the N4 session modification response.

(4) Step

In an IPv6 multihoming PDU session, the SMF device may notify the user device that a new IP prefix is available in the PSA2. This process can be performed using an IPv6 Router Advertisement Message. In addition, the SMF device may transmit a routing rule having an IPv6 prefix to a user device using an IPv6 router advertisement message. In the PDU session of the uplink delimiter, step (4) may be omitted.

(5)

In an IPv6 multihoming PDU session, the SMF device may re-configure the user device for the source IP prefix at PSA0. The SMF device may transmit a routing rule having an IPv6 prefix to the user equipment using the IPv6 router advertisement message.

(6)

This step is performed when the branching point or the uplink separator has no traffic filter for the PDU session forwarding the traffic flow to PSA1. The SMF device may optionally release an existing PSA (PDU Session Anchor).

(6a)

The SMF device transmits an N4 session release request having the N4 session ID to PSA1. PSA1 releases all tunnel resources and contexts associated with the N4 session.

(6b)

When PSA1 successfully releases the tunnel resources and context associated with the N4 session, it sends a session release response with the session ID to the SMF device.

FIGS. 6 to 8 illustrate a process of adjusting load through edge computing.

The edge cloud and the central cloud for edge computing in the present invention correspond to the data network described in Figs. 1-5. The edge cloud corresponds to a local data network, and the central cloud corresponds to a common data network such as the Internet.

Referring to FIG. 6, a user device is receiving service from an edge cloud and a central cloud through a 5G core network.

Hereinafter, operations of the respective components shown in Figs. 6 to 8 will be described.

One) UL CL (uplink classifier): An uplink classifier exists between the RAN and the 5G gateway in a virtualized UPF. It sends the uplink traffic of the user equipment to the designated gateway according to the established rules, and the downlink traffic coming through the different gateways Synthesized and sent to the user device.

2) UPF (user plane function 0) device: PSA0 acts as a gateway of the 5G network for connecting the user's device and the central cloud, and has an IP address for the session.

3) UPF (user plane function 1) device: PSA1 serves as a gateway of a 5G network for connecting the user's device to the edge cloud 1 and has the same IP address as UPF 0 for the session.

4) Edge Cloud 1: A 5G external data network with the same DNN (data network name) as the central cloud, providing some of the services in the central cloud or services specific to the region.

5) SMF (session management function) device: It is a function to manage the session of the user device inside the 5G core, and controls the UPFs through SMF to connect the user device to the central cloud and the edge cloud.

Referring to FIG. 7, there is shown a situation in which a new gateway UPF2 connecting a new edge cloud 2 in a 5G core network is set up for the purpose of distributing loads in a central cloud or edge cloud 1.

8, when there is the generation (UPF (PSA2)) and the extinction (UPF (PSA1)) of the gateway due to the load cycle of the load-distributed or virtualized 5G gateway (UPF) Service is provided in place of the UPF (PSA2).

The process described above is specified as follows.

(i) the SMF device determines that there is a need to connect a new local gateway UPF (PSA2) device to the PDU session in consideration of the central cloud, the load of the edge cloud 1, or the lifecycle of the UPF (PSA1) device. That is, the SMF apparatus judges that it is necessary to relocate the PSA.

(ii) The SMF device selects a 5G gateway UPF (PSA2) device for connection with a new local gateway and sets the tunnel ID of the corresponding UPF device.

(iii) the SMF device requests the uplink delimiter to set up a rule to select the traffic to be sent to the UPF (PSA2) newly set for the edge cloud 2 or 1, the rule being the index of the previous rule or the tunnel ID of the next hop A port number, or the like, or a combination of each value.

the SMF apparatus releases the UPF (PSA1) when all the traffic is transferred to the UPF (PSA0) or the UPF (PSA2) through (iv) (iii). If the user equipment receives a service from the edge cloud 1 via the UPF (PSA1) after the step (iii), the SMF apparatus does not perform the process (iv) and does not cancel the UPF (PSA1).

According to the present invention, it is possible to distribute the load between the UPFs of the edge cloud or the 5G core network, thereby improving the quality of the edge service through the 5G core network.

According to the present invention, an edge service is provided by proposing a 5G edge computing signaling method capable of adapting to network dynamics such as lifecycle change (e.g., UPF generation, scale up / down, extinction) of a virtualized UPF Can support virtualization of 5G core networks.

 Meanwhile, the method according to the present invention may be embodied as a program that can be executed by a computer, and may be embodied as various recording media such as a magnetic storage medium, an optical reading medium, and a digital storage medium.

Implementations of the various techniques described herein may be implemented in digital electronic circuitry, or in computer hardware, firmware, software, or combinations thereof. Implementations may be implemented in a computer program product, such as an information carrier, e.g., a machine readable storage device, such as a computer readable storage medium, for example, for processing by a data processing apparatus, Apparatus (computer readable medium) or as a computer program tangibly embodied in a propagation signal. A computer program, such as the computer program (s) described above, may be written in any form of programming language, including compiled or interpreted languages, and may be stored as a stand-alone program or in a module, component, subroutine, As other units suitable for use in the present invention. A computer program may be deployed to be processed on one computer or multiple computers at one site or distributed across multiple sites and interconnected by a communications network.

Processors suitable for processing a computer program include, by way of example, both general purpose and special purpose microprocessors, and any one or more processors of any type of digital computer. Generally, a processor will receive instructions and data from a read-only memory or a random access memory or both. The elements of a computer may include at least one processor for executing instructions and one or more memory devices for storing instructions and data. Generally, a computer may include one or more mass storage devices for storing data, such as magnetic, magneto-optical disks, or optical disks, or may receive data from them, transmit data to them, . &Lt; / RTI &gt; Information carriers suitable for embodying computer program instructions and data include, for example, semiconductor memory devices, for example, magnetic media such as hard disks, floppy disks and magnetic tape, compact disk read only memory A magneto-optical medium such as a floppy disk, an optical disk such as a DVD (Digital Video Disk), a ROM (Read Only Memory), a RAM , Random Access Memory), a flash memory, an EPROM (Erasable Programmable ROM), an EEPROM (Electrically Erasable Programmable ROM), and the like. The processor and memory may be supplemented or included by special purpose logic circuitry.

In addition, the computer-readable medium can be any available media that can be accessed by a computer, and can include both computer storage media and transmission media.

While the specification contains a number of specific implementation details, it should be understood that they are not to be construed as limitations on the scope of any invention or claim, but rather on the description of features that may be specific to a particular embodiment of a particular invention Should be understood. Certain features described herein in the context of separate embodiments may be implemented in combination in a single embodiment. Conversely, various features described in the context of a single embodiment may also be implemented in multiple embodiments, either individually or in any suitable subcombination. Further, although the features may operate in a particular combination and may be initially described as so claimed, one or more features from the claimed combination may in some cases be excluded from the combination, Or a variant of a subcombination.

Likewise, although the operations are depicted in the drawings in a particular order, it should be understood that such operations must be performed in that particular order or sequential order shown to achieve the desired result, or that all illustrated operations should be performed. In certain cases, multitasking and parallel processing may be advantageous. Also, the separation of the various device components of the above-described embodiments should not be understood as requiring such separation in all embodiments, and the described program components and devices will generally be integrated together into a single software product or packaged into multiple software products It should be understood.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of specific examples for the purpose of understanding and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

Claims (20)

In a method performed by a session management function (SMF) device in a network,
Determining to perform a relocation of a PDU Session Anchor (PSA) to a session of a Protocol Data Unit (PDU);
Establishing a new protocol data unit (PDU) anchor device through relocation of the protocol data unit session anchor;
Releasing an existing protocol data unit session anchor device
Lt; / RTI &gt;
Wherein traffic to an existing protocol data unit session anchor device is moved to a new protocol data unit (PDU) anchor device through relocation of the protocol data unit session anchor. The method according to claim 1,
Wherein the session management function device comprises:
A method for performing a relocation of a protocol data unit session anchor (PSA) for an IPv6 multi-homing or an uplink classifier. The method according to claim 1,
Wherein the session management function device comprises:
A method for performing a relocation of a protocol data unit session anchor (PSA) when there is a request from an event or application function that benefits from relocation of a protocol data unit session anchor for an IPv6 multi-home or uplink delimiter. The method according to claim 1,
Wherein the session management function device comprises:
Transmitting a session establishment request to the new protocol data unit session anchor device, and providing a tunnel ID, uplink identifier, packet detection, enforcement and reporting rule of the branching point to be installed in the new protocol data unit session anchor device. The method according to claim 1,
Wherein the session management function device comprises:
To update the uplink traffic filter, a session modification request is transmitted to a User Plane Functionality (UPF) device corresponding to the branching point or the uplink delimiter according to the new IPv6 prefix assigned to the new protocol data unit session anchor device How to. 6. The method of claim 5,
The session modification request includes:
An identifier of a traffic filter that needs to be relocated by the protocol data unit session anchor, and a tunnel ID of the new protocol data unit session anchor device. 6. The method of claim 5,
Wherein the user plane functional apparatus corresponding to the branching point or uplink delimiter comprises:
And when the user plane functional apparatus corresponding to the branching point or the uplink delimiter successfully updates all the traffic filters requested by the session management functional device to modify, the session modification functional unit acknowledges the session modification response. The method according to claim 1,
Wherein the session management function device comprises:
Transmits a session release request having a session ID to an existing protocol data unit session anchor device,
Wherein the existing protocol data unit session anchor device comprises:
How to release the tunnel resources and contexts associated with the session. 9. The method of claim 8,
Wherein the existing protocol data unit session anchor device comprises:
And upon successful release of the tunnel resources and context associated with the session, sending a session release response with the session ID to the session management functional device. The method according to claim 1,
The network comprising:
A session and service continuity (SSC) mode associated with the protocol data unit session,
The session and service continuity mode comprises:
Wherein the protocol data unit does not change during the lifetime of the protocol data unit session. 1. A session management function (SMF) device in a network,
Wherein the session management function device comprises:
Decides to perform a relocation of a PDU Session Anchor (PSA) for a session of a Protocol Data Unit (PDU)
Establishing a new protocol data unit (PDU) anchor device through relocation of the protocol data unit session anchor,
Releases an existing protocol data unit session anchor device,
Wherein traffic to an existing protocol data unit session anchor device is moved to a new protocol data unit (PDU) anchor device through relocation of the protocol data unit session anchor. 12. The method of claim 11,
Wherein the session management function device comprises:
A method for performing a relocation of a protocol data unit session anchor (PSA) for an IPv6 multi-homing or an uplink classifier. 12. The method of claim 11,
Wherein the session management function device comprises:
A session management function device that relocates a protocol data unit session anchor (PSA) when there is a request from an event or application function that benefits from relocation of a protocol data unit session anchor for an IPv6 multi-home or uplink delimiter. 12. The method of claim 11,
Wherein the session management function device comprises:
A session management function for transmitting a session establishment request to the new protocol data unit session anchor device and providing a tunnel ID, an uplink identifier, a packet detection, an enforcement and a reporting rule of a branching point to be installed in the new protocol data unit session anchor device Device. 12. The method of claim 11,
Wherein the session management function device comprises:
To update the uplink traffic filter, a session modification request is transmitted to a User Plane Functionality (UPF) device corresponding to the branching point or the uplink delimiter according to the new IPv6 prefix assigned to the new protocol data unit session anchor device A session management function device. 16. The method of claim 15,
The session modification request includes:
An identifier of a traffic filter that needs to be relocated by the protocol data unit session anchor, and a tunnel ID of the new protocol data unit session anchor device. 16. The method of claim 15,
Wherein the user plane functional apparatus corresponding to the branching point or uplink delimiter comprises:
And when the user plane functional apparatus corresponding to the branching point or the uplink delimiter successfully updates all the traffic filters requested by the session management functional device, the session management functional device acknowledges the session modification response. 12. The method of claim 11,
Wherein the session management function device comprises:
Transmits a session release request having a session ID to an existing protocol data unit session anchor device,
Wherein the existing protocol data unit session anchor device comprises:
A session management facility device that releases the tunnel resources and contexts associated with the session. 19. The method of claim 18,
Wherein the existing protocol data unit session anchor device comprises:
And upon successful release of the tunnel resources and context associated with the session, sends a session release response having the session ID to the session management functional device. 12. The method of claim 11,
The network comprising:
A session and service continuity (SSC) mode associated with the protocol data unit session,
The session and service continuity mode comprises:
Wherein the protocol data unit session does not change during the lifetime of the protocol data unit session.

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