KR102619365B1 - 5g system operating as tsn bridge and traffic transmission method - Google Patents

Abstract

A 5G system and traffic transmission method operating as a Time Sensitive Network (TSN) bridge are provided. The traffic transmission method includes the steps of a User Plane Function (UPF) receiving traffic transmission type information from a Session Management Function (SMF); Based on traffic transmission type information, the UPF determines whether Time Sensitive Communication (TSC) traffic coming into the TSN bridge is User Equipment (UE) to UE (UE-UE) TSC traffic; And when it is determined that the TSC traffic coming into the TSN bridge is UE-UE TSC traffic, the UPF performs local switching between Protocol Data Unit (PDU) sessions for transmitting UE-UE TSC traffic. can do.

Description

5G system and traffic transmission method operating as a TSN bridge {5G SYSTEM OPERATING AS TSN BRIDGE AND TRAFFIC TRANSMISSION METHOD}

The present invention provides a traffic processing method for efficient time sensitive communication (TSC) in a 5G network, specifically, a traffic processing method for efficient time sensitive communication (TSN) in a 5G system operating as a time sensitive network (TSN) bridge. sensitive traffic) transmission method.

3GPP (3rd Generation Partnership Project) SA2 has begun standardization work on 5G systems supporting TSC in Rel-16 to meet the requirements for application of 5G systems to various vertical industries. According to 3GPP TS 23.501, in order to provide vertical services by linking the 5G system with the TSN network, the 5G system was defined as a logical TSN bridge. Afterwards, Rel-17 expanded the functionality of Rel-16 and introduced FS_IIoT (TR 23.700-20, Study on enhanced support of Industrial Internet of Things (IIoT) in the 5G System (5GS)) as a Study Item (SI). ), standardization of additional features of the 5G system that provides high reliability, low delay, and guaranteed delay is in progress.

The problem to be solved by the present invention is to provide a traffic processing method capable of transmitting TSC traffic optimized according to the traffic transmission type for efficient TSC traffic transmission in a 5G system.

The traffic transmission method according to an embodiment of the present invention is a traffic transmission method in a 5G system operating as a Time Sensitive Network (TSN) bridge, where the User Plane Function (UPF) receives traffic transmission type information from the Session Management Function (SMF). receiving; Based on the traffic transmission type information, the UPF determines whether Time Sensitive Communication (TSC) traffic coming into the TSN bridge is User Equipment (UE) to UE (UE-UE) TSC traffic; And when it is determined that the TSC traffic coming into the TSN bridge is the UE-UE TSC traffic, the UPF performs local switching between PDU (Protocol Data Unit) sessions for transmitting UE-UE TSC traffic. May include steps.

In one embodiment, performing the local switching includes determining, by the UPF, UE-UE transmission of the TSC traffic using a Packet Detection Rule (PDR)/Forwarding Action Rule (FAR); And the UPF may include performing local switching between PDU sessions for UE-UE transmission of the TSC traffic using PDR/FAR information of the PDU session.

In one embodiment, receiving the traffic transmission type information may include the UPF receiving the traffic transmission type information from the SMF using an N4 Session Establishment procedure.

In one embodiment, receiving the traffic transmission type information may include the UPF receiving the traffic transmission type information from the SMF using an N4 Session Modification procedure.

In one embodiment, receiving the traffic transmission type information may include, by the UPF, receiving the traffic transmission type information set in the Destination Interface field of FAR from the SMF.

In one embodiment, receiving the traffic transmission type information may include, by the UPF, receiving the traffic transmission type information set in the Source Interface field of the PDR from the SMF.

In one embodiment, receiving the traffic transmission type information may include, by the UPF, receiving the traffic transmission type information set as TSC information from the SMF.

In one embodiment, the traffic transmission type information may include a predetermined value indicating that TSC traffic coming into the TSN bridge is the UE-UE TSC traffic.

A network entity according to an embodiment of the present invention is a network entity of a 5G system operating as a TSN bridge, and includes a network interface that receives traffic transmission type information from another network entity; And based on the traffic transmission type information, determines whether the TSC traffic flowing into the TSN bridge is UE-UE TSC traffic, and when it is determined that the TSC traffic flowing into the TSN bridge is the UE-UE TSC traffic, the UE- It may include a processor that performs local switching between PDU sessions for UE TSC.

In one embodiment, the processor determines UE-UE transmission of the TSC traffic using PDR/FAR, and uses PDR/FAR information of the PDU session to determine a PDU session for UE-UE transmission of the TSC traffic. Local switching can be performed between them.

In one embodiment, the network interface may receive the traffic transmission type information from the other network entity using the N4 Session Establishment procedure.

In one embodiment, the network interface may receive the traffic transmission type information from the other network entity using the N4 Session Modification procedure.

In one embodiment, the network interface may receive the traffic transmission type information set in the Destination Interface field of FAR from the other network entity.

In one embodiment, the network interface receives the traffic transmission type information set in the Source Interface field of the PDR from the other network entity.

In one embodiment, the network interface may receive the traffic transmission type information set as TSC information from the other network entity.

In one embodiment, the traffic transmission type information may include a predetermined value indicating that TSC traffic coming into the TSN bridge is the UE-UE TSC traffic.

According to embodiments of the present invention, in a 5G system operating as a TSN bridge, TSC traffic transmission between UEs within the same UPF is handled differently from other transmission types (e.g., TSC traffic transmission between UE and outside the UPF). By setting PDR/FAR corresponding to the TSC traffic control rules of UPF, TSC traffic between UEs in UPF can be transmitted efficiently and easily without going through NW-TT.

Figure 1 is a diagram to explain the 5G system architecture operating as a TSN bridge.
Figure 2 is a diagram for explaining a conventional TSC traffic processing flow.
Figure 3 is a diagram for explaining a method of transmitting UE-UE TSC traffic according to the transmission type of TSC traffic according to an embodiment of the present invention.
Figures 4A to 5B are diagrams for explaining a method of setting a traffic transmission type using the N4 interface according to an embodiment of the present invention.
Figures 6 and 7 are diagrams for explaining a method of setting a traffic transmission type using the N4 interface according to an embodiment of the present invention.
Figure 8 is a block diagram for explaining a computing device according to an embodiment of the present invention.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification and claims, when a part is said to “include” a certain component, this means that it may further include other components rather than excluding other components, unless specifically stated to the contrary.

Figure 1 is a diagram to explain the 5G system architecture operating as a TSN bridge.

Referring to Figure 1, the 5G system architecture operating as a TSN bridge includes a 5G system 10 operating as a logical TSN bridge, and a TSN endpoint that exchanges data and performs communication using the 5G system 10 as a TSN bridge. A node (TSN End Node) may include a TSN system 20 and a TSN network 30.

That is, the architecture of FIG. 1 is an architecture expanded to support TSC in the 5G system 10. The 5G system 10 operates as a TSN bridge for integration with an external TSN network, and uses the existing UE 100, UPF 104, RAN (Radio Access Network) 108, and PCF (Policy) for communication with the TSN network. Converter ( TTs) (102, 106) and TSN AF (Application Function) (110) were added. The TSN converters 102 and 106 for interworking with the TSN network include a DS-TT 102 and a NW-TT 106, and each of the DS-TT 102 and NW-TT 106 is connected to the TSN network. It has transmitting and receiving ports for communication. In addition, in addition to the converter in the user plane, the TSN AF (110) in the control plane communicates with the CNC (Centralized Network Configuration) of the TSN network to transmit and receive control information between the 5G system and the TSN network. .

Specifically, the TSN-AF 110 is a function for controlling the 5G bridge system 10 by transmitting and receiving control information for the TSN network (e.g., CNC) and the 5G system 10 to operate as a logical TSN bridge. And the DS-TT (102) and NW-TT (104) process TSC traffic through transparent connection with a TSN system outside the 5G system (10) on the UE (100) side and the network side, respectively. It is a TSN converter.

According to the 3GPP TS 23.501 specification, in the architecture of Figure 1, Rel-16 provides TSC communication between TSN end nodes, TSC to TSN nodes connected to UE 100/DS-TT 102 and UPF 104/NW. -It was limited to TSC communication between TSN nodes connected to the outside of TT (106), but in Rel-17, UE (100)/DS-TT (102) inside one UPF (104)/NW-TT (106) It has been expanded to TSC communication between TSN nodes connected to . UE-UE TSC communication referred to in the present invention is TSC traffic transmission between two TSN nodes under any UE (100) / DS-TT (102) existing within the same UPF (104) / NW-TT (106). refers to the communication that takes place.

Figure 2 is a diagram for explaining conventional TSC traffic processing.

Referring to FIG. 2, for TSC traffic processing, the 5G system bridge (or TSN bridge) 12 includes a plurality of UEs (100a, 100b, 100c), a plurality of DS-TTs (102a, 102b, 102c), and UPF (104). ), NW-TT (106), and RAN (108).

UPF 104 may handle user traffic for PDU sessions. To this end, the UPF 104 may include a PDR/FAR 105 used for detection and forwarding of packets belonging to the session. Here, the PDR may include information for classifying traffic arriving at the UPF 104, and the FAR may include information on whether to apply forwarding, dropping, or buffering to the traffic identified by the PDR. May contain information. For further details on this, please refer to section 5.8 of 3GPP TS 23.501.

Meanwhile, the NW-TT (106) functions to transmit TSC traffic to a specific port within the TSN bridge 12, and for this purpose, the NW-TT (106) transmits TSC traffic through 5G internal signaling from the TSN-AF (110). A static filter entry may be received.

Referring to FIG. 2, the processing flow of TSC traffic flowing into the TSN bridge 12 is briefly described as follows. All TSC traffic received from multiple DS-TTs (102a, 102b, 102c) or ports (107a, 107b) of the TSN network must pass through the NW-TT (106). Accordingly, based on the static filter entry, the NW-TT (106) transmits the received TSC traffic to the external TSN network if it matches the ports (107a, 107b) of the NW-TT (106), and does not match. If not, it is transmitted to the UPF (104) and transmitted to the target DS-TT through the PDR/FAR (105).

To explain this in more detail, the TSC traffic coming into the 5G system bridge (or TSN bridge) 12 can be divided into three transmission types: uplink TSC traffic, downlink TSC traffic, and UE-UE TSC traffic. You can. Here, uplink TSC traffic is TSC traffic transmitted from UE (100a, 100b, 100c) to UPF (104), and downlink TSC traffic is TSC traffic transmitted from UPF (104) to UE (100a, 100b, 100c). , UE-UE TSC traffic is TSC traffic transmitted between two TSN nodes under any UE (100) / DS-TT (102) existing within the same UPF (104) / NW-TT (106), e.g. , It may be TSC traffic transmitted from UE (100a) to UE (100b).

First, the uplink traffic arrives at the UPF 104 from the UE (100a, 100b, 100c)/DS-TT (102a, 102b, 102c) via the RAN 108, and then performs packet detection and forwarding unique to the UPF 104. After going through the PDR/FAR (105) corresponding to the rule, it is delivered to the NW-TT (106). Thereafter, the uplink TSC traffic passes the static filter within the NW-TT 106 and is then transmitted to the external TSN network through the determined ports 107a and 107b.

Subsequently, the downlink traffic is TSC traffic coming from the TSN network to the TSN bridge 12, passes through the static filter in the NW-TT (106), and then the TSC traffic is transmitted to the ports of the DS-TT (102a, 102b, 102c). If it is determined to be transmitted, the NW-TT (106) transmits the corresponding TSC traffic to the UPF (104), and the UPF (104) goes through the internal PDR/FAR (105), determines the target PDU session, and then sends the TSC traffic to the RAN ( 108) and transmitted to the UE/DS-TT corresponding to the target PDU session among the UEs (100a, 100b, 100c)/DS-TTs (102a, 102b, 102c).

Next, UE-UE TSC traffic processing goes through both uplink and downlink TSC traffic processing. From UE (100a, 100b, 100c)/DS-TT (102a, 102b, 102c) via RAN 108, arrives at UPF 104 and then PDR/FAR corresponding to packet detection and forwarding rules unique to UPF 104 After passing through (105), it is delivered to NW-TT (106). After passing the static filter in the NW-TT (106), if the TSC traffic is determined to be transmitted to the ports in the DS-TT (102a, 102b, 102c) in the UPF/NW-TT (106), the NW-TT (106) transmits the corresponding TSC traffic to the UPF (104), and the UPF (104) passes through the internal PDR/FAR (105), determines a target PDU session, and then passes the RAN (108) to the UE (100a, 100b). , 100c)/DS-TT (102a, 102b, 102c) is transmitted to the UE/DS-TT corresponding to the target PDU session.

However, in this NW-TT-centered TSC traffic processing method, all traffic must go through NW-TT regardless of the transmission type (e.g., uplink TSC traffic, downlink TSC traffic, UE-UE TSC traffic, etc.). This is not a problem in TSC communication between the TSN node under DS-TT/UE and the TSN node in the TSN network, but there is a problem of inefficiency in UE-UE TSC communication.

In order to solve this problem and realize efficient TSC traffic transmission, embodiments of the present invention provide the SMF 114 to the UPF 106 through the N4 interface between the SMF 114 and the UPF 106. It provides a method of transmitting information to distinguish and transmit UE TSC traffic and traffic that does not correspond to it (i.e., uplink TSC traffic, downlink TSC traffic), and through this, UE-UE TSC traffic is transmitted through NW-TT. Enables efficient processing without going through .

Figure 3 is a diagram for explaining a method of transmitting UE-UE TSC traffic according to the transmission type of TSC traffic according to an embodiment of the present invention.

A traffic transmission method in a 5G system operating as a TSN bridge according to an embodiment of the present invention includes the steps of the UPF 104 receiving traffic transmission type information from the SMF 114, and based on the traffic transmission type information, UPF ( 104) may include determining whether the TSC traffic coming into the TSN bridge 12 is UE-UE TSC traffic. Here, the traffic transmission type information may include a predetermined value indicating that the TSC traffic coming into the TSN bridge 12 is UE-UE TSC traffic. Accordingly, if the predetermined value is set in the traffic transmission type information, it may indicate UE-UE TSC traffic, and if not set, it may indicate uplink TSC traffic or downlink TSC traffic.

Of course, the traffic transmission type information may be implemented in other ways to distinguish uplink TSC traffic, downlink TSC traffic, and UE-UE TSC traffic. For example, the traffic transmission type information may be implemented to include any one of a first value representing uplink TSC traffic, a second value representing downlink TSC traffic, and a third value representing UE-UE TSC traffic.

Referring to FIG. 3, when the UPF 104 determines that the TSC traffic incoming to the TSN bridge 12 is UE-UE TSC traffic, the method is such that the UPF 104 establishes a PDU session for the UE-UE TSC. The step of performing local switching may be further included. Here, the step of performing local switching includes the UPF 104 determining UE-UE transmission of TSC traffic using the PDR/FAR 105 and the UPF 104 determining PDR/FAR information of the PDU session. It may include performing local switching between PDU sessions for UE-UE transmission of TSC traffic using . In this case, UE-UE TSC traffic may be transmitted to the target DS-TT without passing through the NW-TT 106.

Specifically, the UPF 104, for TSC traffic arriving at the UPF 104 from a source UE (e.g. 100a)/DS-TT (e.g. 102a) via the RAN 108, determines which TSC traffic the TSC traffic belongs to. A specific information element field of the N4 FAR (e.g., “Destination Interface” field of the FAR) or a specific information element field of the N4 PDR (e.g., the “Destination Interface” field of the PDR), which is the delimiter of the forwarding of the PDR/FAR 105 with respect to the PDU session. If implemented using the "Source Interface" field), whether it contains a value indicating UE-UE forwarding (e.g., "5G VN internal", "5G UEtoUE internal", or a predetermined value depending on the specific implementation purpose) You can check to see if local switching is indicated. Details regarding this will be described later with reference to FIGS. 4A to 5B.

Alternatively, the UPF 104 may check whether the TSN information indicates local switching by checking whether it includes a value indicating UE-UE forwarding (eg, “local switch”). Details regarding this will be described later with reference to FIGS. 6 and 7.

If the value included in the PDR/FAR field or TSN information is confirmed to indicate local switching, the UPF 104 performs the Media Access (MAC) of the target UE (e.g. 100b)/DS-TT (e.g. 102b). Control) address, etc. to find the target PDU session through the PDR/FAR (105), and then use the forwarding information for the PDU session to reach the target UE (e.g. 100b)/DS-TT via the RAN (108). UE-UE TSC traffic may be transmitted to (for example, 102b).

Hereinafter, with reference to FIGS. 4A to 7, embodiments for the SMF 114 to provide traffic transmission type information to the UPF 104 will be described.

The N4 Session Establishment and N4 Session Modification procedures described in FIGS. 4A to 7 are N4 signaling procedures performed between SMF and UPF among the PDU Session Establishment or PDU Session Modification procedures performed between the UE and the 5G core network, and are a PDU session It can be used to create a new N4 session that is mapped to or to update the context of an already created N4 session. For more detailed information on the PDU Session Establishment or PDU Session Modification procedures, please refer to sections 4.3.2 and 4.3.3 of 3GPP TS23.502.

Figures 4A to 5B are diagrams for explaining a method of setting a traffic transmission type using the N4 interface according to an embodiment of the present invention.

In this embodiment, the traffic transmission method of the 5G system operating as a TSN bridge involves the UPF 104 receiving traffic transmission type information from the SMF 114 using the N4 Session Establishment procedure or the N4 Session Modification procedure. May include steps. In particular, the method includes the step of the UPF 104 receiving traffic transmission type information set in the “Destination Interface” field of the FAR from the SMF 114, or receiving traffic transmission type information set in the “Source Interface” field of the PDR from the SMF. It may include receiving from (114).

Referring to FIG. 4A, the traffic transmission method using the N4 interface according to this embodiment includes the steps of the SMF 114 performing triggering to set up a PDU session or relocate the UPF (S401); The UPF 104 receives an N4 Session Establishment Request message from the SMF 114 along with traffic transmission type information set in the Destination Interface field of the FAR (S403); It may include steps in which the UPF 104 transmits an N4 Session Establishment Response message to the SMF 114 (S405) and the SMF 114 interacts with other network functions (S407). In step S403, if the value set in the Destination Interface field of FAR is '5G VN internal', it can be interpreted as indicating local switching for UE-UE TSC traffic transmission. The value set in the Destination Interface field is not necessarily limited to '5G VN internal', and the value '5G UEtoUE internal' may be set, or any appropriately defined value may be set depending on the specific implementation purpose. The SMF 114 uses the value set in the Destination Interface field of the FAR to inform the UPF 104 that the TSC traffic received from the UE is UE-UE TSC traffic, and the UPF 104 sends the corresponding TSC traffic to UPF ( 104)/NW-TT (106) can be forwarded to the target UE for transmission.

Next, referring to FIG. 4B, the traffic transmission method using the N4 interface according to this embodiment includes the steps of the SMF 114 performing triggering to set up a PDU session or relocate the UPF (S411); The UPF 104 receives an N4 Session Establishment Request message from the SMF 114 along with traffic transmission type information set in the Source Interface field of the PDR (S413); It may include steps in which the UPF 104 transmits an N4 Session Establishment Response message to the SMF 114 (S415) and the SMF 114 interacts with other network functions (S417). In step S413, if the value set in the Source Interface field of the PDR is '5G VN internal', it can be interpreted as indicating local switching for UE-UE TSC traffic transmission. As in the case of Figure 4a, the value set in the Source Interface field is not necessarily limited to '5G VN internal', and the value '5G UEtoUE internal' is set, or any appropriately defined value depending on the specific implementation purpose. A value may also be set. The SMF 114 can use the value set in the Source Interface field of the PDR to detect UE-UE TSC traffic among TSC traffic received from the UE and determine the target UE to which it wishes to transmit.

Meanwhile, referring to FIG. 5A, the traffic transmission method using the N4 interface according to this embodiment includes the steps of the SMF 114 performing triggering to change the PDU session (S501); The UPF 104 receives an N4 Session Modification Request message from the SMF 114 along with traffic transmission type information set in the Destination Interface field of the FAR (S503); It may include steps in which the UPF 104 transmits an N4 Session Modification Response message to the SMF 114 (S505) and the SMF 114 interacts with other network functions (S507). In step S503, if the value set in the Destination Interface field of FAR is '5G VN internal', it can be interpreted as indicating local switching for UE-UE TSC traffic transmission. As in the case of Figure 4a, the value set in the Destination Interface field is not necessarily limited to '5G VN internal', and the value '5G UEtoUE internal' is set, or any appropriately defined value depending on the specific implementation purpose. A value may also be set. The SMF (114) uses the value set in the Destination Interface field of the FAR to inform the UPF (104) that the TSC traffic received from the UE is UE-UE TSC traffic, and the UPF (104) sends the TSC traffic to the UPF (104). )/NW-TT (106) can be forwarded to the target UE to be transmitted.

Next, referring to FIG. 5B, the traffic transmission method using the N4 interface according to this embodiment includes the steps of the SMF 114 performing triggering to set up a PDU session or relocate the UPF (S511); The UPF 104 receives an N4 Session Modification Request message from the SMF 114 along with traffic transmission type information set in the Source Interface field of the PDR (S513); It may include steps in which the UPF 104 transmits an N4 Session Modification Response message to the SMF 114 (S515) and the SMF 114 interacts with other network functions (S517). In step S513, if the value set in the Source Interface field of the PDR is '5G VN internal', it can be interpreted as indicating local switching for UE-UE TSC traffic transmission. As in the case of Figure 4b, the value set in the Source Interface field is not necessarily limited to '5G VN internal', and the value '5G UEtoUE internal' is set, or any appropriately defined value depending on the specific implementation purpose. A value may also be set. The SMF 114 can use the value set in the Source Interface field of the PDR to detect UE-UE TSC traffic among TSC traffic received from the UE and determine the target UE to which it wishes to transmit.

Figures 6 and 7 are diagrams for explaining a method of setting a traffic transmission type using the N4 interface according to an embodiment of the present invention.

In this embodiment, the traffic transmission method of the 5G system operating as a TSN bridge involves the UPF 104 receiving traffic transmission type information from the SMF 114 using the N4 Session Establishment procedure or the N4 Session Modification procedure. May include steps. In particular, the method may include the UPF 104 receiving traffic transmission type information set as TSC information from the SMF 114.

Referring to FIG. 6, the traffic transmission method using the N4 interface according to this embodiment includes the steps of the SMF 114 performing triggering to establish a PDU session or relocate a UPF (S601); The UPF 104 receives an N4 Session Establishment Request message from the SMF 114 along with traffic transmission type information set as TSC information (S603); It may include a step of the UPF 104 transmitting an N4 Session Establishment Response message to the SMF 114 (S605) and a step of the SMF 114 interacting with another network function (S607). In step S603, if the value set in the TSN information is 'local switch', it can be interpreted as indicating local switching for UE-UE TSC traffic transmission.

Next, referring to FIG. 7, the traffic transmission method using the N4 interface according to this embodiment includes the steps of the SMF 114 performing triggering to modify the PDU session (S701); The UPF 104 receives an N4 Session Modification Request message from the SMF 114 along with traffic transmission type information set as TSC information (S703); It may include steps in which the UPF 104 transmits an N4 Session Modification Response message to the SMF 114 (S705) and the SMF 114 interacts with other network functions (S707). In step S703, if the value set in the TSN information is 'local switch', it can be interpreted as indicating local switching for UE-UE TSC traffic transmission.

Figure 8 is a block diagram for explaining a computing device according to an embodiment of the present invention.

Referring to Figure 8, computing device 50 is a network entity of a 5G system, e.g., UE 100, DS-TT 102, UPF 104, NW-TT 106, RAN 108. , TSN AF (110), PCF (112), SMF (114), AMF (116), UDM (118), and NEF (120). Additionally, the 5G system and traffic transmission method operating as a TSN bridge according to embodiments of the present invention may be implemented using the computing device 50.

Computing device 50 includes at least one of a processor 510, a memory 530, a user interface input device 540, a user interface output device 550, and a storage device 560 that communicate over a bus 520. can do. Computing device 50 may also include a network interface 570 that is electrically connected to a network 40, such as a wireless network. Network interface 570 may transmit or receive signals via network 40 to and from other network entities.

The processor 510 may be implemented in various types such as an Application Processor (AP), Central Processing Unit (CPU), Graphic Processing Unit (GPU), etc., and executes instructions stored in the memory 530 or storage device 560. It may be any semiconductor device. The processor 510 may be configured to implement the functions and methods described in FIGS. 1 to 7 .

Memory 530 and storage device 560 may include various types of volatile or non-volatile storage media. For example, the memory may include read-only memory (ROM) 531 and random access memory (RAM) 532. In one embodiment of the present invention, the memory 530 may be located inside or outside the processor 510, and the memory 530 may be connected to the processor 510 through various known means.

In addition, the 5G system and traffic transmission method operating as a TSN bridge according to embodiments of the present invention may be implemented as a program or software running on the computing device 50, and the program or software may be stored in a computer-readable medium. You can.

Additionally, the 5G system and traffic transmission method operating as a TSN bridge according to embodiments of the present invention may be implemented with hardware that can be electrically connected to the computing device 50.

In particular, network entities UE 100, DS-TT 102, UPF 104, NW-TT 106, RAN 108, TSN AF 110, and SMF 114 refer to FIGS. 1 to 7. You can perform the operations described with reference.

For example, a network entity in a 5G system operating as a TSN bridge (i.e., UPF 104) may have a network interface 570 that receives traffic transmission type information from another network entity (SMF 114) and a traffic transmission type. Based on the information, it is determined whether the TSC traffic coming into the TSN bridge is UE-UE TSC traffic, and when it is determined that the TSC traffic coming into the TSN bridge is UE-UE TSC traffic, between PDU sessions for UE-UE TSC It may include a processor 510 that performs local switching. Additionally, the processor 510 and the network interface 570 may be implemented to perform the operations described with reference to FIGS. 3 to 7 .

According to the embodiments of the present invention described so far, in a 5G system operating as a TSN bridge, TSC traffic transmission between UEs within the same UPF is divided into other transmission types (e.g., TSC traffic transmission between UE and outside the UPF). By setting PDR/FAR corresponding to the TSC traffic control rules of UPF to handle it differently, TSC traffic between UEs in UPF can be transmitted efficiently and easily without going through NW-TT.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and common knowledge in the technical field to which the present invention pertains using the basic concept of the present invention defined in the following claims. Various modifications and improvements of those who have also fall within the scope of the present invention.

Claims (16)

A method of transmitting traffic in a 5G system operating as a Time Sensitive Network (TSN) bridge,
A User Plane Function (UPF) receiving traffic transmission type information from a Session Management Function (SMF);
Based on the traffic transmission type information, the UPF determines whether Time Sensitive Communication (TSC) traffic coming into the TSN bridge is User Equipment (UE) to UE (UE-UE) TSC traffic; and
When it is determined that the TSC traffic coming into the TSN bridge is the UE-UE TSC traffic, the UPF performs local switching between PDU (Protocol Data Unit) sessions for transmitting the UE-UE TSC traffic. Including,
The traffic transmission type information is a predetermined value indicating that the TSC traffic coming into the TSN bridge is UE-UE TSC traffic,
How traffic is transmitted. According to paragraph 1,
The step of performing the local switching is:
The UPF determining UE-UE transmission of the TSC traffic using Packet Detection Rule (PDR)/Forwarding Action Rule (FAR); and
A traffic transmission method comprising the step of the UPF performing local switching between PDU sessions for UE-UE transmission of the TSC traffic using PDR/FAR information of the PDU session. According to paragraph 1,
The step of receiving the traffic transmission type information is,
A traffic transmission method comprising the step of the UPF receiving the traffic transmission type information from the SMF using an N4 Session Establishment procedure. According to paragraph 1,
The step of receiving the traffic transmission type information is,
A traffic transmission method comprising the step of the UPF receiving the traffic transmission type information from the SMF using an N4 Session Modification procedure. According to paragraph 1,
The step of receiving the traffic transmission type information is,
A traffic transmission method comprising the step of the UPF receiving, from the SMF, the traffic transmission type information set in the Destination Interface field of FAR. According to paragraph 1,
The step of receiving the traffic transmission type information is,
A traffic transmission method comprising the step of the UPF receiving, from the SMF, the traffic transmission type information set in the Source Interface field of the PDR. According to paragraph 1,
The step of receiving the traffic transmission type information is,
A traffic transmission method comprising the step of receiving, by the UPF, the traffic transmission type information set as TSC information from the SMF. According to paragraph 1,
The traffic transmission type information is,
A traffic transmission method comprising a predetermined value indicating that TSC traffic coming into the TSN bridge is the UE-UE TSC traffic. As a network entity in a 5G system operating as a TSN bridge,
a network interface that receives traffic transmission type information from other network entities; and
Based on the traffic transmission type information, determine whether TSC traffic coming into the TSN bridge is UE-UE TSC traffic,
When it is determined that the TSC traffic coming into the TSN bridge is the UE-UE TSC traffic, a processor that performs local switching between PDU sessions for UE-UE TSC,
The traffic transmission type information is a predetermined value indicating that the TSC traffic coming into the TSN bridge is UE-UE TSC traffic,
Network entity. According to clause 9,
The processor,
Determine UE-UE transmission of the TSC traffic using PDR/FAR,
A network entity that performs local switching between PDU sessions for UE-UE transmission of the TSC traffic using PDR/FAR information of the PDU session. According to clause 9,
The network interface is,
A network entity that receives the traffic transmission type information from the other network entity using the N4 Session Establishment procedure. According to clause 9,
The network interface is,
A network entity that receives the traffic transmission type information from the other network entity using an N4 Session Modification procedure. According to clause 9,
The network interface is,
A network entity that receives the traffic transmission type information set in the Destination Interface field of FAR from the other network entity. According to clause 9,
The network interface is,
A network entity that receives the traffic transmission type information set in the Source Interface field of the PDR from the other network entity. According to clause 9,
The network interface is,
A network entity that receives the traffic transmission type information set as TSC information from the other network entity. According to clause 9,
The traffic transmission type information is,
A network entity comprising a predetermined value indicating that TSC traffic incoming to the TSN bridge is the UE-UE TSC traffic.

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