KR102422442B1 - Method and apparatus for transmitting time sensitive networking synchronization information in a mobile communication system - Google Patents

Abstract

The present disclosure relates to a 5G or pre-5G communication system to be provided to support a higher data rate after a 4G communication system such as LTE.
According to an embodiment of the present disclosure, there is provided a method for supporting distributed time-sensitive networking (TSN) in a session management function device of a mobile communication system, from a mobile communication terminal including a first TSN node converter communicating with a first TSN node. receiving a transit time of the mobile communication terminal during PDU session setup (Setup) and storing it as first bridge delay information; identifying performing synchronization between the first TSN node and a second TNS node via the mobile communication network; receiving difference information between the clock of the mobile communication system and the clock of the TSN from a user plane function unit (UPF) of the mobile communication terminal after the synchronization; converting the first bridge delay information from the clock reference of the mobile communication system to the clock reference of the TSN using the difference information; generating second bridge delay information using the converted information; and transmitting the generated second bridge information to a policy and charging function device (PCF).

Description

Method and apparatus for transmitting time-sensitive networking synchronization information in a mobile communication system

To a method and apparatus for supporting time-sensitive networking (TSN) in a wireless communication network, and more particularly to a method and apparatus for providing clock synchronization.

Efforts are being made to develop an improved 5th generation (5G) communication system or a pre-5G communication system in order to meet the increasing demand for wireless data traffic after commercialization of the 4G (4th generation) communication system. For this reason, the 5G communication system or the pre-5G communication system is called a 4G network after (Beyond 4G Network) communication system or an LTE (Long Term Evolution) system after (Post LTE) system.

In order to achieve a high data rate, the 5G communication system is being considered for implementation in a very high frequency (mmWave) band (eg, such as a 60 gigabyte (60 GHz) band). In order to alleviate the path loss of radio waves and increase the propagation distance of radio waves in the ultra-high frequency band, in the 5G communication system, beamforming, massive MIMO, and Full Dimensional MIMO (FD-MIMO) are used. ), array antenna, analog beam-forming, and large scale antenna technologies are being discussed.

In addition, for network improvement of the system, in the 5G communication system, an evolved small cell, an advanced small cell, a cloud radio access network (cloud radio access network, cloud RAN), an ultra-dense network (ultra-dense network) , Device to Device communication (D2D), wireless backhaul, moving network, cooperative communication, Coordinated Multi-Points (CoMP), and reception interference cancellation (interference cancellation) Technology development is underway.

In addition, in the 5G system, Hybrid Frequency Shift Keying and Quadrature Amplitude Modulation (FQAM) and Sliding Window Superposition Coding (SWSC), which are advanced coding modulation (Advanced Coding Modulation, ACM) methods, and Filter Bank Multi Carrier (FBMC), an advanced access technology, ), Non Orthogonal Multiple Access (NOMA), and Sparse Code Multiple Access (SCMA) are being developed.

The 5G system is considering support for various services compared to the existing 4G system. For example, the most representative services include enhanced mobile broad band (eMBB), ultra-reliable and low latency communication (URLLC), and massive device-to-device communication service (mMTC). machine type communication), a next-generation broadcast service (eMBMS: evolved multimedia broadcast/multicast Service), and the like. In addition, the system providing the URLLC service may be referred to as a URLLC system, and the system providing the eMBB service may be referred to as an eMBB system. Also, the terms service and system may be used interchangeably.

Among them, the URLLC service is a service newly considered in the 5G system, unlike the existing 4G system, and has ultra-high reliability (eg, about 10-5 packet error rate) and low latency (eg, about 0.5 msec) requirement to be satisfied. In order to satisfy these strict requirements, the URLLC service may need to apply a shorter transmission time interval (TTI) than the eMBB service, and various operating methods are being considered using this.

On the other hand, the Internet is evolving from a human-centered connection network where humans create and consume information to an Internet of Things (IoT) network that exchanges and processes information between distributed components such as objects. Internet of Everything (IoE) technology, which combines big data processing technology through connection with cloud servers, etc. with IoT technology, is also emerging. In order to implement IoT, technology elements such as sensing technology, wired and wireless communication and network infrastructure, service interface technology, and security technology are required. , M2M), and MTC (Machine Type Communication) are being studied.

In the IoT environment, an intelligent IT (Internet Technology) service that collects and analyzes data generated from connected objects and creates new values in human life can be provided. IoT is a field of smart home, smart building, smart city, smart car or connected car, smart grid, health care, smart home appliance, advanced medical service, etc. can be applied to

Accordingly, various attempts are being made to apply the 5G communication system to the IoT network. For example, technologies such as sensor network, machine to machine (M2M), and MTC (Machine Type Communication) are implemented by 5G communication technologies such as beamforming, MIMO, and array antenna. will be. The application of a cloud radio access network (cloud RAN) as the big data processing technology described above is an example of the convergence of 5G technology and IoT technology.

Meanwhile, in a mobile communication network, time-sensitive networking (TSN) is being discussed. These TSNs are expected to be mainly used in fields such as Audio/Video or factory automation.

Although port management information is also transmitted to the terminal connected to the 3GPP network during the PDU Session Setup for TSN Synchronization, in reality, since the reference time of the 3GPP network and the TSN network is different, the transmitted information is based on the 3GP network reference time. It is inaccurate from the network point of view, and there is not enough information during PDU Session Setup, so this information cannot be converted into the TSN network standard time standard.

A method according to an embodiment of the present disclosure is a method for supporting distributed time-sensitive networking (TSN) in a session management function device of a mobile communication system according to an embodiment of the present disclosure. 1 , the method comprising: receiving a transit time of the mobile communication terminal when setting up a PDU session from a mobile communication terminal including a 1 TSN node converter and storing it as first bridge delay information; identifying performing synchronization between the first TSN node and a second TNS node via the mobile communication network; receiving difference information between the clock of the mobile communication system and the clock of the TSN from a user plane function unit (UPF) of the mobile communication terminal after the synchronization; converting the first bridge delay information from the clock reference of the mobile communication system to the clock reference of the TSN using the difference information; generating second bridge delay information using the converted information; and transmitting the generated second bridge information to a policy and charging function device (PCF).

In addition, the difference information includes a time offset and a transmission rate ratio, the time offset is a difference between the clock of the mobile communication system and the clock of the TSN, and the transmission rate ratio is a frequency of the clock of the mobile communication system and the TSN clock can be a ratio.

In TSN AF of the 3GPP network, inaccurate information may be transmitted, or the conversion may not be possible because the reference time information is unknown. However, when the method and apparatus according to the present disclosure are applied, accurate information may be transmitted to the TSN AF or converted into accurate information.

1 is an exemplary diagram for conceptually explaining a TSN synchronization (Synchronization) support process through a 3GPP network.
2 is an exemplary diagram for explaining the structure of a 3GPP network and transmission of information when 5GS supports TSN in the centralized model of TSN.
3 is an exemplary diagram for explaining that port management information collected from a path on a mobile communication network is collected according to an embodiment of the present disclosure.
4 is a configuration diagram for explaining delivery of Bridge Delay within 5GS when TSN AF is not a TSN Synchronization Client according to the first embodiment of the present disclosure.
FIG. 5 is a configuration diagram for explaining delivery of Bridge Delay within 5GS when TSN AF is a TSN synchronization client according to a second embodiment of the present disclosure.
6 is a case of method 1 of the first embodiment of the present disclosure, and when TSN AF is not a TSN synchronization client, both or one of DS-TT/UE and NW-TT/UPF Bridge Delay It is a signal flow diagram when converting .
7 is a signal flow diagram when SMF converts Bridge Delay when TSN AF is not a TSN synchronization client as method 2 according to the first embodiment of the present disclosure.
FIG. 8 is a signal flow diagram when TSN AF converts Bridge Delay when TSN AF is not a TSN synchronization client as method 3 of the first embodiment of the present disclosure.
9 is a signal flow diagram when TSN AF converts Bridge Delay when TSN AF is a TSN synchronization client according to a second embodiment of the present disclosure.
10 is a functional block diagram of an NF of a wireless communication network according to an embodiment of the present disclosure.
11 is a block diagram of an internal functional block of a terminal according to various embodiments of the present disclosure.

Hereinafter, the operating principle of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the terms described below are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout this specification.

A term for identifying an access node used in the following description, a term referring to network entities, a term referring to messages, a term referring to an interface between network objects, a term referring to various identification information and the like are exemplified for convenience of description. Accordingly, the present invention is not limited to the terms described below, and other terms referring to objects having equivalent technical meanings may be used.

For convenience of description, in the present invention, terms and names defined in 5GS and NR standards, which are the latest standards defined by the 3rd Generation Partnership Project (3GPP) organization among existing communication standards, are used. However, the present disclosure is not limited by the terms and names, and may be equally applied to a wireless communication network conforming to other standards. In particular, the present disclosure is applicable to 3GPP 5GS/NR (5th generation mobile communication standard).

Time Sensitive Networking (TSN) supports time synchronization and low latency to support audio/video and/or factory automation, resource management, and reliability improvement It is a set of several standards related to Methods have been proposed to support this TSN in the 3GPP network.

1 is an exemplary diagram for conceptually explaining a TSN synchronization (Synchronization) support process through a 3GPP network.

Before examining with reference to FIG. 1, in order to support time synchronization in the wired network TSN, each TSN node has a time stamp based on the TSN grand master (GM) clock. Stamp) can be added to transmit a Synchronization Frame. The GM clock may be provided from a specific node such as TSN GM#1 101 in the example of FIG. 1 . Accordingly, the TSN node 0 111 may transmit a synchronization message or a synchronization frame to the next node after adding the GM clock received from the TSN GM#1 101 as a time stamp. In this way, the TSN node that has received the sync message or sync frame reflects the link propagation delay and the residence time, which is the delay time in its own node, in the correction field of the synchronization frame, and then It can be transmitted to one TSN node. Through this process, all TSN nodes can achieve time synchronization based on the TSN GM Clock.

Meanwhile, in order to support such TSN synchronization in the 3GPP network, a method in which the 3GPP network operates as one TSN node has been proposed. In a scheme in which the 3GPP network operates as one TSN node, all UEs/gNBs/UPFs in the 3GPP network must be synchronized to the 5G GM Clock. For this, it is assumed that the RAN (gNB, base station) is connected to the 3GPP GM, and the UPF connected to the RAN and the wired network is also assumed to be synchronized with the 5G GM Clock by using the wired network TSN Synchronization method or other methods.

In the 3GPP network, the RAN and the UE are connected through the 5G Air Protocol. In this process, the RAN precisely supports synchronization with the UE (for example, so that the time error is less than 656ns). A number of additional features must be provided. Examples of functions that should be additionally provided include Accurate Timing Delivery by RRC/SIB, Fine TA (Timing Advance) Granularity, and Propagation Delay Compensation. etc. may exist.

Then, the configuration of FIG. 1 will be looked at, and then the operation according to FIG. 1 will be looked at.

Referring to FIG. 1 , the GM clock may be provided from a specific node for providing the GM Clock such as TSN GM#1 101 in the example of FIG. 1 to at least one TSN node existing on the TSN wired network. 1 exemplifies a case in which the GM Clock is provided from the TSN GM#1 (101) to the TSN node 0 (111). Also, the next node may be a 3GPP network, for example, a 5G network 120 . It is exemplified that a first link (Link 1) is established between the TSN node 0 111 and the 5G network 120 . Therefore, the TSN node 0 111 may use the GM Clock provided by the TSN GM#1 101 as a timestamp to generate a synchronization message or a synchronization frame 131 and then provide it to the 5G network 120 as the next node. . The 5G network 120 may process this to generate a synchronization message or a synchronization frame 133 through the next TSN node, the TSN node 2 112 and the second link Link 2, and transmit it.

Then, the internal configuration of the 5G network 120 will be briefly described with reference to FIG. 1 . The first node, the TSN node 0 111 and the node of the 5G network 120 that receives the synchronization message or the synchronization frame through the first link, the user plane function device (User Plane Function, UPF) 121, the terminal 123 or 124) may serve as a gateway for transmitting packets transmitted and received. The UPF 121 may be a PDU Session Anchor (PSA) UPF serving as an anchor of a PDU Session connected to a data network. All data sent by the terminal to the Data Network can be delivered through this Anchor UPF.

The UPF 121 may also include a Network Side TSN Translator (NW-TT) for operation of the TSN network. NW-TT can be in charge of some functions of Ethernet-related protocols required for 5GS to support TSN. Synchronization Frame interpretation and processing, port information management, Link Layer Discovery Protocol (LLDP) It is possible to collect and manage information on neighboring nodes through Hereinafter, in all embodiments according to the present disclosure, it is assumed that the UPF 121 includes the NW-TT unless otherwise stated.

The UPF 121 generates a new sync message or sync frame 132 in which information such as link delay and propagation delay is added to the sync message or sync frame 131 received from the TSN node 0 111 as described above. , may be transmitted to the base station 122 in the 5G network 120 . In this case, the base station 122 and the UPF 121 may be connected by wire, and at least one other network function device may be included therebetween.

The base station 122 may add information such as link delay and propagation delay to the sync message or sync frame received from the UPF 121 and provide it to the terminal 123 . In this case, a message or frame may be transmitted between the base station 122 and the terminal 123 through a radio channel as is well known.

Therefore, the terminal 123 may generate a synchronization message or synchronization frame 133 including information such as propagation delay and link delay in the synchronization message or synchronization frame provided from the base station 122 and provide the synchronization message or synchronization frame 133 to the TSN node 2 112 . have. In this case, the terminal 123 and the TSN node 2 112 may be connected by wire, and a synchronization message or a synchronization frame may be transmitted through the second link Link 2 .

Based on the above, we will look at the process of synchronization in the downlink direction.

The downlink may be a case in which data is transmitted from the TSN node to the final TSN node through the 3GPP network. In FIG. 1 , the direction from the TSN node 0 111 to the TSN node 2 112 is referred to as a downlink.

In a state in which all entities or nodes in the 3GPP network are synchronized to the 5G GM Clock, when the UPF 121 receives a Synchronization Frame, the 5G GM-based Ingress Time Stamp is displayed as a sync frame or a sync message 132 ) can be included. In addition, the UPF 121 puts the link delay measured/calculated and managed in advance with the TSN node 0 111 that has transmitted the sync frame or the sync message in the sync frame or the sync message 132 . It can transmit to the next node in the 5G network, gNB 122 . Accordingly, the gNB 122 may forward it to the UE 123 .

When the UE 123 receives a sync frame or a sync message from the gNB 122, it calculates a time to transmit it to the external TSN node based on the 5G GM Clock, calculates a difference from the reception time (Ingress Time), and stays there The TSN Synchronization operation can be completed by reflecting in the Correction Field as a residence time. The generated sync message or sync frame 133 may be provided to the TSN node 2 112 .

Next, synchronization in the uplink direction will be described. The uplink may be a case in which data is transmitted from the last TSN node in the downlink to the first TSN node that performs control or transmits data through the 3GPP network. In FIG. 1 , the direction from TSN node 2 112 to TSN node 0 111 is referred to as an uplink.

For uplink synchronization, the Ingress Time, which is the time based on 5G GM, when the UE 123 received the Synchronization Frame from the previous TSN node, TSN Node 0 111, and the Link Delay with TSN Node 2 112 are included in the Synchronization Frame to the gNB (122). ) through the UPF 121 . Then, the UPF 121 may calculate the transmission time to the external TSN node, TSN node 0 111 , based on the 5G GM Clock, calculate the difference from the Ingress Time, and reflect this as the Residence Time in the Correction Field. Through this process, the 3GPP network can maintain the TSN Synchronization Time Error to less than 1 μs.

2 is an exemplary diagram for explaining the structure of a 3GPP network and transmission of information when 5GS supports TSN in the centralized model of TSN.

Referring to FIG. 2 , the second TSN system 210 may include a centralized network configuration (CNC) server 230 . Also, the wireless communication network 220 may operate as one TSN bridge. Here, the wireless communication network may be a 3GPP network as described above, and in particular, a network according to 5G or NR standards. However, the present disclosure is not limited thereto, and other wireless networks may be equally applied if they include the functions described in the present disclosure.

Referring to FIG. 2 , the wireless communication network 220 is located between the second TSN system 210 and the first TSN system 230 to operate as one TSN bridge. The core network of 5G can consist of the following network functions. Here, each of the network functions may be one network node. One network node may take a form that is physically and/or logically independent, and may be configured together with other specific nodes. Also, each of the network functions may be implemented by a specific device. As another example, each of the network functions may be implemented in a form in which a device and software are combined. As another example, each of the network functions may be implemented in software in a device on a specific collective network. Hereinafter, each network function will be denoted as “~ function device”. Next, we will look at the network functions of the core network of 5G below.

The wireless communication network 220 may include a terminal 123 of a bridge, and in the case of a terminal of a 3GPP network, a user equipment (UE) and a Device Side TSN Translator (DS-TT). In addition, DS-TT may be called a TSN converter, may be implemented in physical hardware, may be driven in an application of a UE or in a communication processor (CP). As another example, the DS-TT has separate hardware, but may be controlled by an application of the UE or a lower layer of the application. DS-TT can be in charge of some functions of Ethernet-related protocols required for 5GS to support TSN. Interpretation and processing of synchronization frames, management of port information, and information on neighboring nodes through LLDP (Link Layer Discovery Protocol) Aggregation and management can be performed. Here, the UE 123 may be a device including a wireless communication unit (not illustrated in FIG. 2 ) for transmitting and receiving a 5G network and control signals and data, and a controller (not illustrated in FIG. 2 ) for controlling the same. In addition, the UE 123 may further include various input/output devices for an interface with a user, for example, a display unit, an input unit (a touch screen and/or a key input unit), and a memory. In addition, if necessary, the UE 123 may further include various communication devices such as various sensors, a GPS receiving module, a camera module, and other wireless communication protocols, for example, WiFi and Bluetooth.

The RAN 122 may be a base station of a 5G network. Although FIG. 2 describes the base station of the 5G network as the RAN, the 5G standard calls it gNB, so the gNB and the RAN may be the same component. Therefore, hereinafter, gNB and RAN will be mixed and used.

Accordingly, the terminal 123 and the RAN 122 may transmit/receive data and control signals using a 5G radio channel. The user plane function (UPF) 121 may serve as a gateway for transmitting packets transmitted and received by the terminal 1223 . The UPF 121 may be a PDU Session Anchor (PSA) UPF serving as an anchor of a PDU Session connected to the Data Network. All data sent by the terminal to the Data Network can be delivered through this Anchor UPF. Data packets destined for Centralized Data Network or Internet Data Network are delivered to the PSA UPF of the corresponding PDU Session.

The access and mobility management function (AMF) 232 may perform a network function for managing the mobility of the terminal. The session management function (SMF) 224 may perform a network function of managing a packet data network connection provided to the terminal. This connection may be called a PDU (protocol data unit) session.

The policy and charging function (PCF) 227 may perform a network function for applying a service policy of a mobile communication operator to the terminal 123, a charging policy, and a policy for a PDU session. The unified data management apparatus (unified data management, UDM) 224 may perform a network function storing information about subscribers. The network exposure function (NEF) 229 can access information for managing the terminal 321 in the 5G network, so that the user subscribes to the mobility management event of the corresponding terminal, and manages the session of the terminal (session management) subscription to an event, a request for session-related information, setting of charging information of a corresponding terminal, and a request to change a PDU session policy for a corresponding terminal may be made.

A case in which the 3GPP network 220 is modeled as a Logical Bridge using the configuration of FIG. 2 salpin above will be described.

DS-TT/UE (123) and NW-TT/UPF (121) of 3GPP network 220 operate as input and output ports of 5GS Logical Birdge, respectively, and information of the corresponding port is transmitted to TSN AF (228) can be passed to Since the present disclosure illustrated in FIG. 2 relates to a process of collecting Bridge Port Management Information, it will be described in response thereto. TSN AF 228 may forward this aggregated information to TSN's CNC 230 server. The TSN AF 228 may set 5GS Bridge Port Management Information using the information received from the CNC 230 . In this case, the necessary information for each port can be set to use the same path. For example, DS-TT/UE 123 is DS-TT/UE 123 <-> gNB 122 <-> AMF 223 <-> SMF 224 <-> as shown in reference numeral 201 The path of PCF 227 <-> TSN AF 228 may be used. In addition, the NW-TT / UPF (121) using the path of the NW-TT / UPF (121) <-> SMF (224) <-> PCF (227) <-> TSN AF (228) as shown in reference numeral 202 The necessary information may be sent to the TSN AF 228 , or, conversely, the necessary information may be received from the TSN AF 228 in the reverse direction. This process can be made by applying the PDU Session Establish and Modification procedures.

As described above, when management information is exchanged with the TSN 210 using the path indicated by reference numeral 201 or the path indicated by reference numeral 121, necessary bridge management information may be collected.

3 is an exemplary diagram for explaining that port management information collected from a path on a mobile communication network is collected according to an embodiment of the present disclosure.

3 is an exemplary diagram for explaining the configuration of a bridge delay, which is one of port management information, in particular according to the present disclosure.

In FIG. 3, the configuration of the UE 123 is exemplified by separating the DS-TT 123b corresponding to the input/output port between the UE 123a performing wireless communication in the 5G network and the TSN node, and for the UPF 121 In FIG. 5G network, the UPF 121a performing data transmission and reception and operation in the 5G network and the NW-TT 121b corresponding to the input/output port between the TSN node and the TSN node are separately illustrated. DS-TT may be implemented separately from the UE or may be implemented together. The NW-TT may be implemented separately from the UPF or may be implemented together. DS-TT or NW-TT can handle Ethernet-related protocol processing for 5GS to interwork with TSN. For example, DS-TT or NW-TT may be in charge of receiving, interpreting, and updating a Synchronization Ethernet Frame from an external TSN node. In addition, DS-TT or NW-TT may be in charge of a port information management function.

In general, the DS-TT-UE residence time (Residence Time) 301 in the UE 123 is the elapsed time between the DS-TT 123b and the UE 123a, and the packet delay budget (PDB) ( 302) means the elapsed time from the UE (123a) to the NW-TT / UPF (121). The DS-TT-UE Residence Time 301 according to the present disclosure may be preset in the DS-TT/UE. Also, the PDB 302 may be a value determined according to a QoS setting value during PDU Session Setup. The DS-TT-UE Residence Time 301 may be provided from the UE 123a during PDU Session Setup or may be a value known in advance from the 3GPP network. The DS-TT-UE Residence Time 301 may be a value based on the 5GS GM (Grand Master) Clock. At this time, the PDB 302 may also be a value based on the 5GS GM (Grand Master) Clock.

If necessary, the PDB may be divided into a CN (Core Network) PDB and an AN (Access Network) PDB. The CN PDB is an elapsed time corresponding to the section from NW-TT/UPF to just before gNB, and may include elapsed time in NW-TT/UPF and elapsed time in link (backhaul) between UPF and gNB. . The AN PDB is an elapsed time corresponding to a section other than the CN PDB in the PDB, and may include an elapsed time in the gNB and an elapsed time in a radio link between the gNB and the UE.

Therefore, as described above, the total delay time (Bridge Delay) 304 in the 5G network may be composed of the sum of the DS-TT-UE Residence Time 301 and the PDB 302 .

4 is a configuration diagram for explaining delivery of Bridge Delay within 5GS when TSN AF is not a TSN Synchronization Client according to the first embodiment of the present disclosure.

Referring first to FIG. 4 , the wireless communication network 220 between the TSN node 0 111 and the TSN node 2 112 may operate as one TSN bridge. Here, the wireless communication network may be a 3GPP network as described above, and in particular, a network according to 5G or NR standards. However, the present disclosure is not limited thereto, and other wireless networks may be equally applied if they include the functions described in the present disclosure.

Referring to FIG. 4 , the wireless communication network 220 is located between the TSN node 0 111 and the TSN node 2 112 to operate as one TSN bridge. The core network of 5G can consist of the following network functions. Here, each of the network functions may be one network node. One network node may take a form that is physically and/or logically independent, and may be configured together with other specific nodes. Also, each of the network functions may be implemented by a specific device. As another example, each of the network functions may be implemented in a form in which a device and software are combined. As another example, each of the network functions may be implemented in software in a device on a specific collective network. Hereinafter, each network function will be denoted as “~ function device”. Next, we will look at the network functions of the core network of 5G below.

The wireless communication network 220 may include a terminal 123 of a bridge, and in the case of a terminal of a 3GPP network, may include a user equipment (UE) and a DS-TT. Here, the UE 123 includes a wireless communication unit (not illustrated in FIG. 4) for transmitting and receiving a 5G network and control signals and data, and a control unit (not illustrated in FIG. 4, but may be configured by a microprocessor) for controlling the same. It may be a device that contains

The gNB 122 may be a base station of a 5G network. 4 illustrates a base station of a 5G network as a gNB, the gNB and the RAN may be the same component. Therefore, hereinafter, gNB, RAN, and base station will be used together.

Accordingly, the terminal 123 and the gNB 122 may transmit/receive data and control signals using a 5G radio channel. The user plane function (UPF) 121 may serve as a gateway for transmitting packets transmitted and received by the terminal 1223 . The UPF 121 may be a PDU Session Anchor (PSA) UPF serving as an anchor of a PDU Session connected to the Data Network. All data sent by the terminal to the Data Network can be delivered through this Anchor UPF. Data packets destined for Centralized Data Network or Internet Data Network are delivered to the PSA UPF of the corresponding PDU Session.

The access and mobility management function (AMF) 232 may perform a network function for managing the mobility of the terminal. The session management function (SMF) 224 may perform a network function of managing a packet data network connection provided to the terminal. This connection may be called a PDU (protocol data unit) session. The policy and charging function (PCF) 227 may perform a network function for applying a service policy of a mobile communication operator to the terminal 123, a charging policy, and a policy for a PDU session.

A case in which the 3GPP network 220 is modeled as a Logical Bridge will be described using the configuration of FIG. 4 salpin above.

A path through which the Bridge Port Management Information from the DS-TT/UE 123 is provided to the SMF 224 is exemplified by reference numeral 424 . This information may be transmitted from the SMF 224 to the PCF 227 through the TSN AF 228 as indicated by reference numeral 423 . Bridge Port Management Information from the NW-TT/UPF 121 may also be provided to the SMF 224 as indicated by reference numeral 422 . The SMF 224 may forward this information to the TSN AF 228 via the PCF 227 as indicated by reference numeral 425 . At this time, the DS-TT-UE Residence Time (301) and PDB (302) values set inside 5GS are both values based on the 5GS GM Clock, whereas the TSN AF (228) is transmitted to the CNC (230) of the TSN. These values are based on the TSN GM Clock. Therefore, the Bridge Delay must be converted from the 5GS GM Clock reference to the TSN GM Clock reference before the TSN AF 228 transmits the Bridge Delay Information to the CNC 230 . According to the subject of conversion, the detailed method can be divided into the following three types.

In method 1, the DS-TT/UE 123 and the NW-TT/UPF 121 perform the conversion. In this way, the TSN AF 228 does not have to bear the burden of converting Bridge Delay information. In addition, since information is transmitted transparently between DS-TT/UE 123 and TSN AF 228 and between NW-TT/UPF 226 and TSN AF 228, the SMF 224 transmits Bridge Delay information in the middle. There is no need for separate management.

In method 2, the SMF 224 performs the conversion. In this way, the TSN AF 228 does not have to bear the burden of converting Bridge Delay information. DS-TT/UE (123) or NW-TT/UPF (121) also does not need to have the burden of converting Bridge Delay information. In method 1, the Bridge Delay information, which transparently transmitted information between DS-TT/UE (123) and TSN AF (228) and between NW-TT/UPF (121) and TSN AF (228), was transferred to SMF (224) in method 2 ) must be managed separately in the middle. In this case, the NW-TT/UPF 121 should deliver the difference information between the 5GS GM Clock and the TSN GM Clock to the SMF 224 . Therefore, since the NW-TT/UPF 121 only needs to use the N4 interface, the difference information between the clocks is relatively easier than the DS-TT/UE 123, which has to transmit signaling through the RAN (gNB) 122 section. can transmit

In method 3, the TSN AF performs the conversion. In this method, the DS-TT/UE 123 or the NW-TT/UPF 121 or the SMF 224 has the burden of converting the Bridge Delay information to the TSN AF 228 instead of the SMF 224 . Since information is transparently transmitted between DS-TT/UE(123) and TSN AF(228) and between NW-TT/UPF(121) and TSN AF(228), SMF(224) separates Bridge Delay information in the middle. No need to manage However, in this case, the NW-TT/UPF 121 must deliver the difference information between the 5GS GM Clock and the TSN GM Clock to the SMF 224 to the TSN AF 228 through the SMF and the PCF.

In method 4, the PCF performs the conversion. In this method, the PCF 227 instead of the DS-TT/UE 123 or the NW-TT/UPF 121, the SMF 224 or the TSN AF 228 has the burden of converting Bridge Delay information. Since the PCF 227 is located on the path of the information provided to the TSN AF 228 , it can acquire all the information provided to the TSN AF 228 . Therefore, when the PCF 227 converts the Bridge Delay information, the load of the TSN AF 228 may be reduced.

5 is a configuration diagram for explaining delivery of Bridge Delay within 5GS when TSN AF is a TSN synchronization client according to a second embodiment of the present disclosure.

FIG. 5 has the same configuration as that of FIG. 4 described above, and has some differences because the TSN AF 228 operates as a synchronization client. For example, the TSN AF 228 is connected to the 5G GM as shown by reference numeral 532 to perform Clock Synchronization, and at the same time, as shown by the reference numeral 533, it must also be connected to the TSN GM to perform Clock Synchronization.

Bridge Port Management Information from the DS-TT/UE 123 is provided to the SMF 224 as shown in reference numeral 524, and is transmitted from the SMF 224 to the PCF 227 through the PCF 228 as shown in 523 to the TSN AF 228. can be Bridge Port Management Information from the NW-TT/UPF 121 may also be transmitted to the TSN AF 228 via the SMF 244 as shown by reference numeral 522 . At this time, the DS-TT-UE Residence Time (301) and PDB (302) values set inside 5GS are both values based on the 5GS GM Clock, whereas the TSN AF (228) is transmitted to the CNC (230) of the TSN. The value 521 is a value based on the TSN GM Clock. Therefore, the Bridge Delay must be converted from the 5GS GM Clock reference to the TSN GM Clock reference before the TSN AF 228 transmits the Bridge Delay Information to the CNC 230 .

At this time, as described above, since the TSN AF 228 already has information on both the 5G GM Clock and the TSN GM Clock, it is possible to secure the Bridge Delay based on the TSN GM Clock in the PDU session establishment step.

6 is a case of method 1 of the first embodiment of the present disclosure, and when TSN AF is not a TSN synchronization client, both or one of DS-TT/UE and NW-TT/UPF is Bridge Delay It is a signal flow diagram when converting .

In the description of FIG. 6 , the same reference numerals are used for the same components as those described with reference to FIGS. 1 to 5 . However, TSN Node1 and TSN Node2 will be described with new reference numerals respectively. This is to identify the TSN Node2 described in FIG. 1 because it exists.

If the NW-TT/UPF 121 performs a separate DS-TT/UE 123 and TSN synchronization process and TSN synchronization is not already stabilized, the PDU session is set ( Setup), the DS-TT/UE 123 and the NW-TT/UPF 121 may transmit Bridge Delay information to the TSN AF 228 . In this case, the value transmitted by the DS-TT/UE 123 may be the DS-TT-UE Residence Time 301 , and the value transmitted by the NW-TT/UPF 121 may be the value of the PDB 302 . However, since this information is based on the 5GS standard, it can have the following three operation options.

(1) Do not convey this information.

(2) This information is transmitted, but the information based on the 5GS Clock is marked with a separate flag or indication and transmitted to the TSN AF 228 .

(3) It may transmit Bridge Delay information, but may not indicate that it is based on 5GS Clock. This means that the Bridge Delay information transmitted to the TSN AF 227 has a default value of 5GS GM Clock.

After the NW-TT/UPF 121 performs a separate DS-TT/UE 123 and TSN Synchronization process, the PDU session establishment process of step 1 with the corresponding DS-TT/UE 123 is performed. may have been done In this case, the NW-TT/UPF 121 may transmit the Bridge Delay based on the TSN Clock in step 1. In this case, the NW-TT/UPF 121 converts the DS-TT-UE Residence Time 301 received from the DS-TT/UE 123 and the value of the PDB 302 it owns based on the TSN GM Clock and converts the TSN AF 228 may be forwarded. There are two ways to indicate whether the delivered Bridge Delay is based on 5GS Clock or TSN Clock, either using Flag/Indication or setting the default value based on TSN GM Clock and not sending Flag/Indication. The former may correspond to (2)-A or (3) of the third step to be described later, and the latter may correspond to (1) or (2)-B of the third step to be described later. In this case, since the TSN AF 228 secures the Bridge Delay based on the TSN GM Clock in step 1, step 7 can be performed immediately.

TSN Synchronization Frame is exchanged between TSN and 5GS using User Plane Path formed by PDU Session in step 2, and DS-TT/UE and NW-TT/UE of 5GS achieve synchronization with TSN GM will do

In step 3, when the synchronization with the TSN of DS-TT/UE (123) and NW-TT/UPF (121) enters the stable stage, the Bridge Delay information is converted from the 5GS GM Clock standard to the TSN GM Clock standard, and then again TSN AF (228). In this case, it may have the following operation options.

(1) If the bridge delay information is not transmitted in step 1 ((1) in step 1), there is no need to distinguish whether this information is based on the 5GS clock or the TSN clock to the TSN AF 228. Therefore, there is no need to send a separate Flag/Indication in step 3. This is because it can be seen that the TSN AF 228 is always transmitted only on the basis of the TSN GM.

(2) If Bridge Delay is transmitted in step 1, but information based on 5GS Clock is indicated and transmitted to TSN AF (228) ((2) in step 1), Bridge Delay value transmitted in step 3 is TSN Clock standards should be specified. In this case, it may have the following additional operation options.

(2)-A: Bridge Delay value can be indicated through Flag or Indication that is based on TSN Clock.

(2)-B: Can be sent without any Flag/Indication. In this case, the default value of Bridge Delay transmitted from DS-TT(123b) or NW-TT(121b) to TSN AF(228) is based on TSN GM Clock, and if it is not default, it is based on 5GS Clock. do.

(3) Deliver Bridge Delay in step 1, but if there is no separate Flag/Indication of information based on 5GS Clock ((3) in step 1), in DS-TT(123b) or NW-TT(121b) Since it means that the default value of Bridge Delay transmitted to TSN AF 228 is based on 5GS GM Clock, there must be a Flag/Indication that Bridge Delay transmitted in step 3 is based on TSN GM Clock.

In step 3, there are the following two operation options, which can be operated in combination with operation options (1), (2)-A, (2)-B, and (3) described above.

(i) Both DS-TT and NW-TT may be transmitted to the TSN AF 228 by converting the Bridge Delay to the TSN Clock standard after synchronization is stabilized. In this case, steps 3a/4a/5a/6a and 3b/4b/5b/6b are made.

(ii) only one of the DS-TT (123b) and the NW-TT (121b) may transmit information. The NW-TT/UPF 121 stores the DS-TT-UE Residence Time 301 delivered by the DS-TT/UE 123 in step 1, and after the TSN synchronization is stabilized in step 2, These values may be converted based on the TSN GM Clock and then transmitted to the TSN AF 228 . In this case, only steps 3a/4a/5a/6a are performed.

The criterion for judging whether synchronization is stabilized may be determined by reference to the TSN performance criterion. For example, the rateRatio, which is the ratio of the frequencies of the TSN GM Clock and the Local Clock (5G GM Clock), may be used. If the rateRatio value obtained by the j-th measurement is expressed as rateRatio(j), when this rateRatio value becomes 0.1 PPM or less, it can be determined that the stabilization stage has been entered. That is, “|rateRatio(j) - rateRatio(j-1)| When / rateRatio(j) < 10E-7” is satisfied, it can be judged that the stabilization stage has been entered.

In step 4a, the NW-TT/UPF 121 may compensate 5GS Bridge Info, NW-TT Port, Bridge Delay, and Flag/Indication to the SMF 224. At this time, Bridge Delay is based on TSN GM Clock, and the method to indicate that this value is based on TSN GM Clock is (1), (2), (3) in Step 1 and (1), (2)-A in Step 3 described above. , (2)-B, and (3) vary depending on the case.

In step 4b, the DS-TT/UE 123 may send 5GS Bridge Info, DS-TT Port, Bridge Delay, and Flag/Indication to the SMF 224 . At this time, Bridge Delay is based on TSN GM Clock, and the method to indicate that this value is based on TSN GM Clock is (1), (2), (3) in Step 1 and (1), (2)-A in Step 3 described above. , (2)-B, and (3) vary depending on the case.

In step 5a, the SMF 224 may send 5GS Bridge Info, NW-TT Port, Bridge Delay, and Flag/Indication to the PCF 227 . At this time, Bridge Delay is based on TSN GM Clock, and the method to indicate that this value is based on TSN GM Clock is (1), (2), (3) in Step 1 and (1), (2)-A in Step 3 described above. , (2)-B, and (3) vary depending on the case.

In step 5b, the SMF 224 may send 5GS Bridge Info, DS-TT Port, Bridge Delay, and Flag/Indication to the PCF 227 . At this time, Bridge Delay is based on TSN GM Clock, and the method to indicate that this value is based on TSN GM Clock is (1), (2), (3) in Step 1 and (1), (2)-A in Step 3 described above. , (2)-B, and (3) vary depending on the case.

In step 6a, the PCF 227 may send 5GS Bridge Info, NW-TT Port, Bridge Delay, and Flag/Indication to the TSN AF 228 . At this time, Bridge Delay is based on TSN GM Clock, and the method to indicate that this value is based on TSN GM Clock is (1), (2), (3) in Step 1 and (1), (2)-A in Step 3 described above. , (2)-B, and (3) vary depending on the case.

In step 6b, the PCF 227 sends 5GS Bridge Info, DS-TT Port, Bridge Delay and Flag/Indication to the TSN AF 228. At this time, Bridge Delay is based on TSN GM Clock, and the method to indicate that this value is based on TSN GM Clock is (1), (2), (3) in Step 1 and (1), (2)-A in Step 3 described above. , (2)-B, and (3) vary depending on the case.

In step 7, the TSN AF 228 may obtain the Bridge Delay based on the TSN GM Clock. The detailed operation differs according to the cases of (1), (2)-A, (2)-B, and (3) of step 3 described above.

If step (1) of step 3 described above is performed, the TSN AF 228 knows that this Bridge Delay value is based on the TSN GM Clock even without Flag/Indication. Therefore, the TSN AF 228 stores the received value as a Bridge Delay and uses it to transmit information with the CNC 230 later.

When step (2)-A of step 3 described above is performed, the TSN AF 228 knows that this Bridge Delay value is the TSN GM Clock standard through the Flag/Indication indicating that it is the TSN GM Clock standard. Accordingly, the TSN AF 228 stores the received value(s) as Bridge Delay and uses it for information transmission with the CNC 230 later.

If step (2)-B of step 3 described above is performed, the TSN AF 228 can know that this Bridge Delay value is based on the TSN GM Clock without a separate Flag/Indication. Accordingly, the TSN AF 228 stores the received value(s) as Bridge Delay and later uses it for information transmission with the CNC 230 .

When step (3) of step 3 described above is performed, the TSN AF 228 can know that this Bridge Delay value is based on the TSN GM Clock through Flag/Indication indicating that it is based on the TSN GM Clock. Accordingly, the TSN AF 228 stores the received value(s) as Bridge Delay and later uses it to transmit information to and from the CNC.

Step 8 is a process in which the TSN AF (228) reports the Bridge Delay to the CNC (230). The Bridge Delay delivered at this time is the value based on the TSN GM Clock.

7 is a signal flow diagram when SMF converts Bridge Delay when TSN AF is not a TSN synchronization client as method 2 according to the first embodiment of the present disclosure.

Unless the NW-TT/UPF 121 performs a separate DS-TT/UE 123 and TSN Synchronization process and TSN Synchronization is already stabilized, in the process of setting up the PDU Session in step 1, the DS-TT /UE 123 may transmit DS-TT-UE Residence Time 301 to SMF 224 as Bridge Delay. In step 1a, the SMF 224 may transmit the DS-TT/UE 123 information and the DS-TT-UE Residence Time 301 while requesting a session setup to the NW-TT/UPF 121 . . In step 1b, the NW-TT/UPF 121 includes the port number assigned to the DS-TT/UE 123 and MAC/Port information of the NW-TT 121b, and the SMF 224 including the PDB 302. ) can be answered. In this case, the SMF 224 may store the DS-TT-UE Residence Time and PDB values as Bridge Delay based on 5GS GM. In step 1c, the SMF 224 transmits DS-TT MAC/Port information, NW-TT MAC/Port information, DS-TT-UE Residence Time, and PDB values as Bridge Delay. At this time, the SMF 224 allocated in step 1d, which is the Bridge Delay information delivered in the following three ways, may transmit the allocated DS-TT port information to the DS-TT/UE.

(1) Do not convey this information.

(2) This information is transmitted, but the information based on the 5GS Clock is marked with a separate flag or indication and transmitted to the TSN AF 228 .

(3) It may transmit Bridge Delay information, but may not indicate that it is based on 5GS Clock. This means that the Bridge Delay information transmitted to the TSN AF 228 has a default value based on 5GS GM Clock.

The NW-TT/UPF 121 performs a separate DS-TT/UE 123 and TSN Synchronization process, and then performs the PDU session establishment process of step 1 with the corresponding DS-TT/UE 123. may have been done In this case, the NW-TT/UPF 121 may transmit the Bridge Delay based on the TSN Clock already in step 1. In this case, the NW-TT/UPF converts the DS-TT-UE Residence Time (301) received from the DS-TT/UE and the PDB (302) it owns based on the TSN GM Clock and passes through steps 1b and 1c. TSN AF (228). There are two ways to indicate whether the delivered Bridge Delay is based on 5GS Clock or TSN Clock, either using Flag/Indication or setting the default value based on TSN GM Clock and not sending Flag/Indication. The former corresponds to (2)-A or (3) in steps 5 and 6 to be described later, and the latter corresponds to (1) or (2)-B in steps 5 and 6 to be described later. In this case, since the TSN AF 228 secures the Bridge Delay based on the TSN GM Clock in step 1, step 7 can be performed immediately.

In step 2, TSN Synchronization Frame is exchanged between TSN and 5GS using the User Plane Path formed by PDU Session, and DS-TT/UE and NW-TT/UPF 121 of 5GS communicate with TSN GM. Synchronization is achieved.

In step 3, when the synchronization with the TSN of the NW-TT/UPF 121 enters a stable stage, the NW-TT/UPF 121 transmits information about the difference between the 5GS GM Clock and the TSN GM Clock to the SMF 224. can This information largely includes Time offset and rateRatio. Time offset refers to the difference between the two times, and rateRatio is the ratio of the frequencies of the TSN GM Clock and the Local Clock (5G GM Clock). After TSN Synchronization is stabilized through Step 2, this information is transmitted.

The criterion for judging whether synchronization is stabilized may be determined by reference to the TSN performance criterion. For example, rateRatio, which is a ratio of the frequencies of the TSN GM Clock and the Local Clock (5G GM Clock), may be used. If the rateRatio value obtained by the j-th measurement is expressed as rateRatio(j), when this rateRatio value becomes 0.1 PPM or less, it can be determined that the stabilization stage has been entered. That is, “|rateRatio(j) - rateRatio(j-1)| When / rateRatio(j) < 10E-7” is satisfied, it can be judged that the stabilization stage has been entered.

In step 4, the SMF 224 converts the stored Bridge Delay from the 5GS GM Clock standard to the TSN GM Clock standard using the difference information between the 5GS GM Clock and the TSN GM Clock.

In step 5, the SMF 224 transmits the Bridge Delay to the PCF, and in step 6, the PCF 227 transmits it to the TSN AF 228 again. It has the following action options:

(1) If the bridge delay information is not transmitted in step 1 ((1) in step 1), there is no need to distinguish whether this information is based on the 5GS clock or the TSN clock to the TSN AF 228. There is no need to include a separate Flag/Indication in steps 5 and 6. This is because it can be seen that the TSN AF 228 is always transmitted only on the basis of the TSN GM.

(2) If the Bridge Delay is transmitted in step 1, but information based on 5GS Clock is indicated and transmitted to the TSN AF (228) ((2) in step 1), the Bridge Delay value transmitted in steps 5 and 6 It should be specified whether this is the TSN clock standard. At this time, the (2)-A Bridge Delay value can be indicated through a flag or indication that is based on the TSN clock. Alternatively, it can be sent without any Flag/Indication as in (2)-B. In this case, the Bridge Delay transmitted to the TSN AF 228 through the SMF 224 corresponds to a case in which it is specified that the default is the TSN GM Clock standard, and if it is not the default, the 5GS Clock standard is specified. (3) If Bridge Delay is transmitted in step 1, but there is no separate Flag/Indication of information based on 5GS Clock, the default value of Bridge Delay delivered to TSN AF(228) through SMF(224) is 5GS GM As it means that it is based on the clock, there must be a Flag/Indication that the Bridge Delay transmitted in steps 5 and 6 is based on the TSN GM Clock.

In step 7, the TSN AF 228 obtains the Bridge Delay based on the TSN GM Clock. The detailed operation differs according to the cases of (1), (2)-A, (2)-B, and (3) of steps 5 and 6 described above.

If step (1) of steps 5 and 6 described above is performed, the TSN AF 228 knows that this Bridge Delay value is based on the TSN GM Clock even without Flag/Indication. Accordingly, the TSN AF 228 may store the received value as a Bridge Delay and use it to transmit information with the CNC 230 later.

When step (2)-A of steps 5 and 6 described above is performed, the TSN AF 228 knows that this Bridge Delay value is based on the TSN GM Clock through Flag/Indication indicating that it is based on the TSN GM Clock. Therefore, TSN AF stores the received value(s) as Bridge Delay and uses it to transmit information to and from the CNC later.

If step (2)-B of step 6 of 5 steps described above is performed, the TSN AF 228 can know that this Bridge Delay value is based on the TSN GM Clock without a separate Flag/Indication. Accordingly, the TSN AF 228 may store the received value(s) as Bridge Delay and use it to transmit information with the CNC 230 later.

When step (3) of step 6 of 5 steps described above is performed, the TSN AF 228 can know that this Bridge Delay value is based on the TSN GM Clock through Flag/Indication indicating that it is based on the TSN GM Clock. Accordingly, the TSN AF 228 may store the received value(s) as Bridge Delay and use it to transmit information to and from the CNC later.

Step 8 is a process in which the TSN AF (228) reports the Bridge Delay to the CNC (230). The Bridge Delay delivered at this time is the value based on the TSN GM Clock.

8 is a signal flow diagram when TSN AF converts Bridge Delay when TSN AF is not a TSN synchronization client as method 3 of the first embodiment of the present disclosure.

If the NW-TT/UPF 121 performs a separate DS-TT/UE 123 and TSN Synchronization process and TSN Synchronization is not already stabilized, in the process of setting up the PDU Session in step 1, the DS-TT /UE 123 and NW-TT/UPF 121 may transmit Bridge Delay information to TSN AF 228 . At this time, the value delivered by the DS-TT/UE 123 is the DS-TT-UE Residence Time 301 , and the value delivered by the NW-TT/UPF 121 is the value of the PDB 302 . However, since this information is based on the 5GS standard, it must be displayed. There are two operation options as follows.

(1) This information is transmitted, but the information based on the 5GS Clock is marked with a separate flag or indication and transmitted to the TSN AF 228 .

(2) It transmits Bridge Delay information, but may not indicate that it is based on 5GS Clock. This means that the Bridge Delay information transmitted to the TSN AF 228 has a default value based on 5GS GM Clock.

The NW-TT/UPF 121 performs a separate DS-TT/UE 123 and TSN Synchronization process, and then performs the PDU session establishment process of step 1 with the corresponding DS-TT/UE 123. may have been done In this case, the NW-TT/UPF 121 may transmit information on the difference between the 5GS GM Clock and the TSN GM Clock as well as the Bridge Delay in step 1 to the TSN AF 228 . Difference information between 5GS GM Clock and TSN GM Clock may include time offset and rateRatio. Time offset refers to the difference between the two times, and rateRatio is the ratio of the frequencies of the TSN GM Clock and the Local Clock (5G GM Clock). If the NW-TT/UPF 121 has already achieved TSN synchronization by performing a separate DS-TT/UE 123 and TSN synchronization process, step 6 may be performed immediately after step 1.

TSN Synchronization Frame is exchanged between TSN and 5GS using User Plane Path formed by PDU Session in step 2, and DS-TT/UE 123 and NW-TT/UPF 121 of 5GS Synchronization with TSN GM will be achieved.

In step 3, when the synchronization with the TSN of the NW-TT/UPF 121 enters a stable stage, the NW-TT/UPF 121 transmits information on the difference between the 5GS GM Clock and the TSN GM Clock to the SMF 224. can This information may include time offset and rateRatio. Time offset refers to the difference between the two times, and rateRatio is the ratio of the frequencies of the TSN GM Clock and the Local Clock (5G GM Clock). After the TSN synchronization is stabilized through the second step, the NW-TT/UPF 121 may transmit this information to the SMF 224 .

The criterion for judging whether synchronization is stabilized may be determined by reference to the TSN performance criterion. For example, rateRatio, which is a ratio of the frequencies of the TSN GM Clock and the Local Clock (5G GM Clock), may be used. If the rateRatio value obtained by the j-th measurement is expressed as rateRatio(j), when this rateRatio value becomes 0.1 PPM or less, it can be determined that the stabilization stage has been entered. That is, “|rateRatio(j) - rateRatio(j-1)| When / rateRatio(j) < 10E-7” is satisfied, it can be judged that the stabilization stage has been entered.

In step 4, the SMF 224 transmits the difference information between the 5GS GM Clock and the TSN GM Clock to the PCF 227, and in step 5, the PCF 227 may transmit it back to the TSN AF 228. Among the difference information between these two clocks, the time offset information is not used to convert the Bridge Delay from the 5GS GM Clock standard to the TSN GM Clock standard, so steps 4 and 5 may include only rateRatio.

In step 6, the TSN AF 228 may convert the Bridge Delay from the 5GS GM Clock standard to the TSN GM Clock standard. At this time, Bridge Delay is a value that indicates the length of time, not the time, so it can be converted using only rateRatio information among the difference information between two clocks.

In step 7, you can save the Bridge Delay based on the TSN Clock. Bridge Delay information based on the 5GS Clock can also be stored to recalculate the Bridge Delay based on the TSN Clock when the difference information between the 5GS GM Clock and the TSN GM Clock is updated and transmitted.

Step 8 is a process in which the TSN AF (228) reports the Bridge Delay to the CNC (230). The Bridge Delay delivered at this time may be a value based on the TSN GM Clock.

Method 4 will be further examined with reference to FIG. 8 . Unless the NW-TT/UPF 121 performs a separate DS-TT/UE 123 and TSN Synchronization process and TSN Synchronization has already been stabilized, in the process of setting up the PDU Session in step 1, the DS-TT The /UE 123 and the NW-TT/UPF 121 may transmit Bridge Delay information to the TSN AF 228 . At this time, the value delivered by the DS-TT/UE 123 is the DS-TT-UE Residence Time 301 , and the value delivered by the NW-TT/UPF 121 is the value of the PDB 302 . In this case, the PCF 227 may be located on a path through which the Bridge Delay information is transmitted to the TSN AF 228 . That is, as described above with reference to FIG. 4 , the DS-TT/UE 123 may transmit the DS-TT-UE Residence Time 301 to the SMF 224 through the gNB 122 and the AMF 223 . Also, the NW-TT/UPF 121 may transmit the PDB 302 value to the SMF 224 as described with reference to FIG. 4 .

In response to this, the SMF 224 transmits the DS-TT-UE Residence Time 301 and the PDB 302 values to the TSN AF 228 through the PCF 227 . Accordingly, the PCF 227 may receive and store both the DS-TT-UE Residence Time 301 and the PDB 302 values.

Also, as described in method 3, since the information is information based on 5GS, it must be displayed. The following two operation options are possible.

(1) This information is transmitted, but the information based on the 5GS Clock is marked with a separate flag or indication and transmitted to the TSN AF 228 .

(2) It transmits Bridge Delay information, but may not indicate that it is based on 5GS Clock. This means that the Bridge Delay information transmitted to the TSN AF 228 has a default value based on 5GS GM Clock.

The NW-TT/UPF 121 performs a separate DS-TT/UE 123 and TSN Synchronization process, and then performs the PDU session establishment process of step 1 with the corresponding DS-TT/UE 123. may have been done In this case, the NW-TT/UPF 121 may transmit information on the difference between the 5GS GM Clock and the TSN GM Clock as well as the Bridge Delay in step 1 to the TSN AF 228 . Even in this case, information on the difference between the 5GS GM Clock and the TSN GM Clock as well as the Bridge Delay may be provided through the PCF 227 . Therefore, the PCF 227 may receive and store the difference information between the 5GS GM Clock and the TSN GM Clock as well as the Bridge Delay.

Difference information between 5GS GM Clock and TSN GM Clock may include time offset and rateRatio. Time offset refers to the difference between the two times, and rateRatio is the ratio of the frequencies of the TSN GM Clock and the Local Clock (5G GM Clock).

If the NW-TT/UPF 121 has already achieved TSN Synchronization by performing a separate DS-TT/UE 123 and TSN Synchronization process, the PCF 227 performs the 6-step operation of FIG. 8 after step 1 can do. For example, the PCF 227 may convert the Bridge Delay from the 5GS GM Clock standard to the TSN GM Clock standard. At this time, Bridge Delay is a value that indicates the length of time, not the time, so it can be converted using only rateRatio information among the difference information between two clocks.

Thereafter, the PCF 227 may perform the operation of step 7 of FIG. 8 . For example, the PCF 227 may store a Bridge Delay based on the TSN Clock. Bridge Delay information based on the 5GS Clock can also be stored to recalculate the Bridge Delay based on the TSN Clock when the difference information between the 5GS GM Clock and the TSN GM Clock is updated and transmitted.

The PCF 227 may provide this information to the TSN AF 228 by forming an update message as in step 5 of FIG. 8 . Accordingly, the TSN AF 228 may store the information received from the PCF 227 and transmit it to the CNC 230 as in step 8 .

Steps 2, 3, and 4 described above with reference to FIG. 8 may be performed in the same manner as described with reference to FIG. 8 . However, when method 4 is used, steps 6 and 7 performed in the TSN AF 228 may be performed in the PCF 227 , and then step 5 may be performed.

The TSN AF 228 may perform an operation of storing the information provided in step 5 as in step 7 and perform step 8 .

9 is a signal flow diagram when TSN AF converts Bridge Delay when TSN AF is a TSN synchronization client according to a second embodiment of the present disclosure.

In the process of setting up the PDU Session in step 1, the DS-TT/UE 123 and the NW-TT/UPF 121 may deliver Bridge Delay information to the TSN AF 228 . At this time, the value delivered by the DS-TT/UE 123 is the DS-TT-UE Residence Time 301 , and the value delivered by the NW-TT/UPF 121 is the value of the PDB 302 . However, since this information is based on the 5GS standard, one of the options below can be used.

(1) This information is transmitted, but the information based on the 5GS Clock is marked with a separate flag or indication and transmitted to the TSN AF 228 .

(2) Brdige Delay information may be transmitted, but may not indicate that it is based on 5GS Clock. This means that the Bridge Delay information transmitted to the TSN AF 228 has a default value based on 5GS GM Clock.

Before the PDU session setup between the NW-TT/UPF 121 and the DS-TT/UE 123, which is the first step, the TSN AF 228 performs the TSN Synchronization process to know the difference information between the 5GS GM Clock and the TSN GM Clock. there may be Difference information between 5GS GM Clock and TSN GM Clock may include time offset and rateRatio. Time offset refers to the difference between the two times, and rateRatio is the ratio of the frequencies of the TSN GM Clock and the Local Clock (5G GM Clock). In this case, step 3 may be performed immediately after step 1.

In step 2, the TSN AF 228 acquires the TSN GM Clock and Synchronization by performing the TSN Synchronization process.

In step 3, the TSN AF 228 converts the Bridge Delay from the 5GS GM Clock standard to the TSN GM Clock standard. At this time, Bridge Delay is a value that indicates the length of time, not the time, so it can be converted using only rateRatio information among the difference information between two clocks.

In step 4, the TSN AF 228 may store the Bridge Delay based on the TSN Clock. Bridge Delay information based on the 5GS Clock can also be stored to recalculate the Bridge Delay based on the TSN Clock when the difference information between the 5GS GM Clock and the TSN GM Clock is updated and transmitted.

Step 5 is a process in which the TSN AF (228) reports the Bridge Delay to the CNC (230). The Bridge Delay delivered at this time may be a value based on the TSN GM Clock.

10 is a functional block diagram of an NF of a wireless communication network according to an embodiment of the present disclosure.

Referring to FIG. 10 , a network interface 1010 may communicate with other network entities and/or at least one TSN node of a mobile communication core network. For example, when the NF is the RAN 122 , communication may be performed with the UPF 121 , the AMF 223 , and the like. As another example, when the NF is the UPF 121 , communication may be performed with the RAN 122 , the SMF 224 , and the like. As another example, if the NF is the TSN AF 228, it may communicate with the CNC 230 of the TSN and/or at least one node of the TSN system, and may communicate with the NEF 229 and/or the PCF 227 at the same time. can Similarly, when the NF is one specific network entity, the network interface 1010 may communicate with another entity of the mobile communication network and/or at least one node of the TSN system. Accordingly, the network interface 1010 according to the present disclosure may include the function of NW-TT in a specific case, for example, when included in the UPF 326 .

The controller 1011 may be implemented as at least one processor and/or a program for performing the NF operation. For example, when the NF is the UPF 121 , the controller 1011 may perform the above-described operation of the UFF 121 . As another example, when the NF is the TSN AF 228 , the above-described operation of the TSN AF 228 may be performed. In the case of other network entities, controls necessary for the above-described operations may be performed in the same manner.

The memory 1012 may store programs and various control information required by the controller 1011 , and may store each information described in the present disclosure in addition.

In addition to the configuration described above, the NF may further include various interfaces for connection with the operator. In the present disclosure, no special restrictions are placed on such an additional configuration.

11 is a block diagram of an internal functional block of a terminal according to various embodiments of the present disclosure.

Referring to FIG. 11 , the terminal 123 may include a transceiver 1110 , a controller 1120 , and a memory 1130 . The terminal 123 may additionally have more components according to an implementation method. For example, various additional devices such as a display for a user interface, an input unit, and a sensor may be further included. In the present disclosure, no restrictions are placed on such an additional configuration.

The transceiver 1110 may be connected to the base station 122 through a wireless channel based on each of the embodiments described in FIGS. 1 to 9 , and transmit/receive signals and/or messages with the base station 122. can When the terminal 123 communicates with the 5G network, the transceiver 1110 may be a device capable of transmitting/receiving with the 5G communication network. In addition, the transceiver 1110 may include a communication processor as necessary. When the transceiver 1110 does not include a communication processor, all signals and/or messages may be processed by the controller.

Also, according to the present disclosure, the transceiver 1110 may communicate with at least one node of the TSN system. In this case, at least one node of the TSN system may be one of a Talker and/or a Listener or another Bridge as described above. Therefore, the transceiver 1110 according to the present disclosure may include both a configuration for communicating with a mobile communication system in a wireless format and a configuration for DS-TT.

The controller 1120 may control the basic operation of the terminal 123 , and may control reception, delivery, transmission, and storage of the messages described above.

The memory 1130 may store various data necessary for the control of the terminal 123, and store a message received from the base station 122 and/or a specific NF of the core network in order to communicate using the network slice described above. You can have an area for

Methods according to the embodiments described in the claims or specifications of the present invention may be implemented in the form of hardware, software, or a combination of hardware and software.

When implemented in software, a computer-readable storage medium storing one or more programs (software modules) may be provided. One or more programs stored in the computer-readable storage medium are configured to be executable by one or more processors in an electronic device (device). One or more programs include instructions for causing an electronic device to execute methods according to embodiments described in a claim or specification of the present invention.

Such programs (software modules, software) include random access memory, non-volatile memory including flash memory, read only memory (ROM), electrically erasable programmable ROM (EEPROM: Electrically Erasable Programmable Read Only Memory), magnetic disc storage device, Compact Disc-ROM (CD-ROM), Digital Versatile Discs (DVDs), or any other form of It may be stored in an optical storage device or a magnetic cassette. Alternatively, it may be stored in a memory composed of a combination of some or all thereof. In addition, each configuration memory may be included in plurality.

In addition, the program is transmitted through a communication network consisting of a communication network such as the Internet, an intranet, a local area network (LAN), a wide LAN (WLAN), or a storage area network (SAN), or a combination thereof. It may be stored on an attachable storage device that can be accessed. Such a storage device may be connected to a device implementing an embodiment of the present invention through an external port. In addition, a separate storage device on the communication network may be connected to the device performing the embodiment of the present invention.

In the specific embodiments of the present invention described above, elements included in the invention are expressed in the singular or plural according to the specific embodiments presented. However, the singular or plural expression is appropriately selected for the context presented for convenience of description, and the present invention is not limited to the singular or plural element, and even if the element is expressed in plural, it is composed of a singular or singular. Even an expressed component may be composed of a plurality of components.

101: TSN GM
111, 120, 112: TSN Node
121: UPF
122: gNB
123, 124: UE
230: CNC (Centralized Network Configuration)
223: AMF 224: SMF
225: UDM 227: PCF
228: TSN AF 229: NEF

Claims (14)

A method for reporting a delay time of a mobile communication system to a TSN server in a time sensitive networking (TSN) application function device of a mobile communication system, the method comprising:
receiving a residence time based on a grand master (GM) clock of the mobile communication system from a UE communicating with a first TSN node;
Receive a packet delay budget (PDB) based on the GM clock of the mobile communication system from a user plane function (UPF) device communicating with a second TSN node, wherein the PDB is the first TSN node is the elapsed time of packet or message transmission between the UE communicating with and the UPF device;
receiving difference information between the GM clock of the mobile communication system and the TSN GM clock from the UPF device;
calculating a bridge delay using the residence time and the PDB;
converting the bridge delay based on the difference information into a bridge delay based on the TSN GM clock; and
Transmitting bridge information including a bridge delay converted based on the TSN GM clock to a TSN server; a method for reporting a delay time from a mobile communication system to a TSN server of a TSN network. According to claim 1, wherein the difference information,
A method for reporting a delay time from a mobile communication system to a TSN server of a TSN network, comprising a ratio of a frequency of the TSN GM clock and the GM clock of the mobile communication system. According to claim 2, wherein the difference information,
A method for reporting a delay time from a mobile communication system to a TSN server of a TSN network, further comprising a time difference value between the TSN GM clock and the GM clock of the mobile communication system. According to claim 1, wherein the TSN server,
A method for reporting latency from a mobile communication system, which is a Centralized Network Configuration (CNC) server of the TSN network, to a TSN server of a TSN network. The method of claim 1,
The method for reporting a delay time from a mobile communication system to a TSN server of a TSN network, further comprising the step of storing the bridge delay converted into the TSN GM clock. The method of claim 1,
The difference information received from the UPF device is received through a session management function (SMF) device and a policy and charging function (PCF) device, from a mobile communication system to a TSN server of a TSN network A method for reporting latency. The method of claim 1,
A method for reporting delay time to a TSN server of a TSN network in a mobile communication system, comprising receiving a PDB from an anchor UPF when transmitting/receiving a TSN packet or message with the UE through two or more UPFs. In a time sensitive networking (TSN) application function device for reporting a delay time of a mobile communication system to a TSN server,
a network interface for communicating with nodes of the mobile communication system and a TSN node;
a memory for storing delay times of TSN data; and
at least one processor;
The at least one processor comprises:
receiving a residence time based on a grand master (GM) clock of the mobile communication system from the UE communicating with the first TSN node through the network interface;
Receive a packet delay budget (PDB) based on the GM clock of the mobile communication system from a user plane function (UPF) device communicating with a second TSN node through the network interface, the PDB comprising: Elapsed time of packet or message transmission between the UE and the UPF device communicating with the first TSN node,
Receive difference information between the GM clock of the mobile communication system and the TSN GM clock from the UPF device,
calculating a bridge delay using the residence time and the PDB,
converting the bridge delay based on the difference information into a bridge delay based on the TSN GM clock, and
A TSN AF apparatus for transmitting bridge information including a bridge delay converted based on the TSN GM clock to a TSN server, for reporting a delay time from a mobile communication system to a TSN server of a TSN network. The method of claim 8, wherein the difference information,
A TSN AF apparatus for reporting a delay time from a mobile communication system to a TSN server of a TSN network, comprising a ratio of a frequency of the TSN GM clock and the GM clock of the mobile communication system. 10. The method of claim 9, wherein the difference information,
A TSN AF apparatus for reporting a delay time from a mobile communication system to a TSN server of a TSN network, further comprising a time difference value between the TSN GM clock and the GM clock of the mobile communication system. The method of claim 8, wherein the TSN server,
A TSN AF device for reporting a delay time from a mobile communication system, which is a Centralized Network Configuration (CNC) server of the TSN network, to a TSN server of the TSN network. The method of claim 8, wherein the at least one processor comprises:
A TSN AF apparatus for reporting a delay time from a mobile communication system to a TSN server of a TSN network, controlling to store the bridge delay converted into the TSN GM clock in the memory. The method of claim 8, wherein the difference information received from the UPF device,
A TSN AF device for reporting a delay time from a mobile communication system to a TSN server of a TSN network, which is received through a session management function (SMF) device and a policy and charging function (PCF) device. The method of claim 8, wherein the PDB,
A TSN AF apparatus for reporting a delay time from a mobile communication system to a TSN server of a TSN network, which receives a PDB from an anchor UPF when transmitting/receiving a TSN packet or message with the UE through two or more UPFs.

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