JP7486697B2 - FRAME TRANSMISSION SYSTEM, 5G CORE DEVICE, 5G TERMINAL, TRANSLATOR, FRAME TRANSMISSION METHOD, AND FRAME TRANSMISSION PROGRAM - Google Patents

Description

The present disclosure relates to a frame transmission system, a 5G core device, a 5G terminal, a translator, a frame transmission method, and a frame transmission program.

3GPP (registered trademark) is a project by national standardization organizations that studies and adjusts standards for 3G (third generation mobile communication system) and beyond. 3GPP (registered trademark) is developing a standard for integrating 5G (fifth generation mobile communication system) and TSN. TSN is a method for realizing real-time communication over wired Ethernet (registered trademark). TSN is an abbreviation for Time Sensitive Networking.
In the 5G standard technology disclosed by 3GPP (registered trademark), the entire 5G system including the 5G terminal and the base station behaves as a virtual TSN bridge to connect 5G and TSN. This enables TSN communication via 5G.

Patent document 1 discloses an ATM method in which a frame is divided into small fragments and transmitted. ATM is an abbreviation for Asynchronous Transfer Mode.

JP 2006-128859 A

Japanese Patent Laid-Open No. 2003-233633 discloses a technique relating to frame preemption in an ATM system, in which a high-priority frame is transmitted by interrupting the transmission of a low-priority frame.
Fragmentation and restoration of frames by frame preemption requires L1 information of Ethernet (registered trademark). L1 information is information about frame fragmentation. However, in the 5G U-plane function, L1 information is not transferred and only L2 frames are transferred. For this reason, there is a problem that frame preemption cannot be performed by the switch function of the virtual TSN bridge by the 5G system.

The present disclosure aims to transmit Ethernet (registered trademark) Ether frames fragmented by frame preemption via a 5G network bridge in which the 5G network acts as a network bridge.

A frame transmission system according to the present disclosure includes:
In a frame transmission system that transmits an Ethernet frame, which is an Ethernet (registered trademark) frame to be transmitted to a device, via a 5G network bridge in which a 5G network that performs GTP transmission, which is general packet radio service tunneling protocol transmission, by a 5G core device and a 5G terminal operates as a network bridge,
The 5G core device includes:
a switch unit that generates fragmented transmission frames by fragmenting the Ethernet frame using a frame preemption function, the fragmented transmission frames being each provided with fragmentation information indicating fragmentation of the fragmented frames;
The device is equipped with a GTP transmission unit that transmits a GTP transmission frame obtained by adding a GTP header for GTP transmission of the fragmented frame to the fragmented frame, the GTP transmission frame having the fragmentation information embedded therein, to the 5G terminal.

According to the frame transmission system of the present disclosure, Ethernet (registered trademark) Ether frames fragmented by frame preemption can be transmitted via a 5G network bridge in which the 5G network operates as a network bridge.

1 is a schematic diagram showing an overview of a frame transmission system 500 according to a first embodiment. FIG. 1 is a diagram illustrating an example of the overall configuration of a frame transmission system 500 according to a first embodiment. FIG. 2 is a schematic diagram showing a frame preemption function that is a premise of the first embodiment. FIG. 11 is a schematic diagram showing an example of GTP transmission of a comparative example for comparison with the first embodiment. A diagram showing an example of the functional configuration of a 5G core device 110 relating to embodiment 1. A diagram showing an example of a functional configuration of a 5G terminal 130 relating to embodiment 1. A diagram showing an example of a detailed functional configuration of a 5G core device 110 relating to embodiment 1. A flow chart showing the operation of the 5G core device 110 relating to embodiment 1. 1 is a schematic diagram showing an example of frame format conversion by a frame transmission system 500 according to a first embodiment. FIG. 2 is a diagram showing an example of the configuration of a GTP transmission frame 50 according to the first embodiment. FIG. A figure showing an example of a detailed functional configuration of a 5G terminal 130 relating to embodiment 1. A flow diagram showing the operation of a 5G terminal 130 relating to embodiment 1. A diagram showing an example of a hardware configuration of a 5G core device 110 relating to embodiment 1. A diagram showing the configuration of a 5G core device 110 relating to a modified example of embodiment 1. A diagram showing an example of a detailed functional configuration of a 5G core device 110 relating to embodiment 2. A flow chart showing the operation of the 5G core device 110 for embodiment 2. 11 is a schematic diagram showing an example of frame format conversion by frame transmission processing of a frame transmission system 500 according to a second embodiment. FIG. 13 is a diagram showing an example of the configuration of a GTP transmission frame 50 according to a second embodiment. FIG. A figure showing an example of a detailed functional configuration of a 5G terminal 130 relating to embodiment 2. A flow diagram showing the operation of a 5G terminal 130 relating to embodiment 2. FIG. 11 is a diagram illustrating an example of the overall configuration of a frame transmission system 500 according to a third embodiment. FIG. 13 is a diagram illustrating an example of a functional configuration of a translator 30 according to a third embodiment. FIG. 11 is a schematic diagram showing an example of frame format conversion by a frame transmission system 500 according to a third embodiment. FIG. 11 is a flow diagram showing the operation of the translator 30 according to the third embodiment.

The present embodiment will be described below with reference to the drawings. In each drawing, the same or corresponding parts are given the same reference numerals. In the description of the embodiment, the description of the same or corresponding parts will be omitted or simplified as appropriate. The arrows in the drawing mainly indicate the flow of data or the flow of processing. In addition, the relationship of the size of each component in the following drawing may differ from the actual one. In addition, in the description of the embodiment, directions or positions such as up, down, left, right, front, back, front, back, etc. may be indicated. These notations are given for the convenience of explanation and do not limit the arrangement, direction, or orientation of devices, instruments, parts, etc.

Embodiment 1.
***Configuration Description***
FIG. 1 is a schematic diagram showing an overview of a frame transmission system 500 according to the present embodiment.
FIG. 2 is a diagram showing an example of the overall configuration of a frame transmission system 500 according to this embodiment.

The frame transmission system 500 provides Ethernet (registered trademark) communication services between the 5G terminal 130 or the device 20 connected to the 5G core device 110 by a 5G system consisting of a 5G core device 110, a base station 120, and a 5G terminal 130. At this time, the 5G system operates as a virtual network bridge. The 5G system operating as a virtual network bridge is called a 5G network bridge 100. It is also possible for multiple 5G terminals 130 to be connected to one base station 120.

The frame transmission system 500 includes a 5G network bridge 100. The frame transmission system 500 is a system that transmits an Ethernet frame between devices 20 via the 5G network bridge 100. The Ethernet frame is an Ethernet (registered trademark) frame.
The device 20 is, for example, a TSN device that communicates by TSN. The device 20 is also called an Ethernet (registered trademark) device. In Fig. 1, the device 20 is simply shown as TSN. Also, in Fig. 1, a virtual network bridge is shown as VB. VB is an abbreviation for Virtual Bridge.

The 5G network bridge 100 includes a 5G core device 110, a base station 120, and a 5G terminal 130. The 5G network bridge 100 is a 5G system consisting of the 5G core device 110, the base station 120, and the 5G terminal 130, which operates as a virtual network bridge. The 5G network bridge 100 operates as a virtual network bridge and transmits an Ethernet frame 40. The 5G network bridge 100 is also called a virtual Ethernet (registered trademark) bridge or a virtual TSN bridge.

In the 5G network bridge 100, GTP transmission is performed between the 5G core device 110 and the 5G terminal 130. GTP is an abbreviation for GPRS Tunneling Protocol. Note that GPRS is an abbreviation for General Packet Radio Service, and GTP is also an abbreviation for General Packet Radio Service Tunneling Protocol.
A GTP transmission is also called a GTP tunnel.
In the 5G network bridge 100, the 5G terminal 130 serves as a port.

FIG. 3 is a schematic diagram showing the frame preemption function that is the premise of this embodiment.
As shown in the upper part of Fig. 3, the frame preemption function is a method of stopping the transmission of an Ethernet Frame 40 that is being transmitted and allowing a high-priority Ethernet Frame 40 to interrupt. The previously transmitted Ethernet Frame 40 is divided into fragment 1, which is transmitted before the interruption, and fragment 2, which is transmitted after the interruption. Here, as shown in the lower part of Fig. 3, each of fragment 1 and fragment 2, which are the fragmented Ethernet Frame 40, is referred to as a fragmented frame 42.

By the frame preemption function, fragmentation information 41 indicating the fragmentation of each fragmented frame 42 is added to fragmented frames 42 obtained by fragmenting an Ethernet frame 40 .
Specifically, the fragmentation information 41 includes at least SMD and frag_count, and may include mCRC. The fragmentation information 41 is L1 information of Ethernet.
The SMD is information indicating the type of frame in frame preemption, such as an interrupted frame, a divided first frame, or a divided subsequent frame.
The Frag count is information indicating the ordinal number of the divided frame.
mCRC is the CRC of the split frame.

Moreover, the fragmented frame 42 to which the fragmentation information 41 is added is specifically L2 information of Ethernet (registered trademark).
The fragmented frame 42 to which the fragmentation information 41 has been added is called a fragmented transmission frame 43 .

FIG. 4 is a schematic diagram showing an example of GTP transmission as a comparative example for comparison with this embodiment.
4, in the GTP transmission of the comparative example, when a GTP header for GTP transmission is added to a fragmented frame 42, fragmentation information 41 is discarded. Therefore, the Ethernet frame 40 cannot be restored.

FIG. 5 is a diagram showing an example of a functional configuration of a 5G core device 110 according to this embodiment.
The 5G core device 110 is a computer.
Here, functional elements of the 5G core device 110 according to the present embodiment will be described with reference to Fig. 5. The hardware configuration of the 5G core device 110 will be described later.

The 5G core device 110 includes, as functional elements, an Ethernet communication unit 111, a switch unit 112, a protocol unit 113, a GTP transmission unit 114, a C-Plane unit 115, and a communication unit 116. The Ethernet communication unit 111 is also referred to as an Ethernet (registered trademark) communication unit. The protocol unit 113 is also referred to as an Ethernet (registered trademark) protocol unit. The switch unit 112 is also referred to as an Ethernet (registered trademark) switch unit.

The Ethernet communication unit 111 is a physical interface that connects to the device 20 via an Ethernet (registered trademark) cable such as RJ45.
The switch unit 112 has a function of relaying an Ethernet Frame 40 transmitted by the device 20. Furthermore, the switch unit 112 transfers a received Ethernet Frame 40 to an appropriate device 20. The switch unit 112 is also referred to as a virtual Ethernet (registered trademark) switch function unit.

The GTP transmission unit 114 communicates with the 5G terminal 130 via the logical connection GTP via the communication unit 116.
The communication unit 116 is a physical interface that wirelessly connects to a base station 120, a 5G terminal 130, or other devices within the 5G network.

The C-Plane unit 115 performs communication for 5G control between the base station 120, the 5G terminal 130, or other devices within the 5G network via the communication unit 116. The C-Plane unit 115 is also referred to as a C-Plane function unit.
The protocol unit 113 has a function of terminating control protocol messages between devices, such as IEEE802.1AS or IEEE802.1AB. The protocol unit 113 is also called an Ethernet (registered trademark) control protocol unit.

FIG. 6 is a diagram showing an example of a functional configuration of a 5G terminal 130 according to the present embodiment.
The 5G terminal 130 is a computer.
Here, functional elements of the 5G terminal 130 according to the present embodiment will be described with reference to Fig. 6. The hardware configuration of the 5G terminal 130 will be described later.

The 5G terminal 130 has the following functional elements: a wireless communication unit 131, a U-Plane unit 132, a C-Plane unit 133, and an Ethernet communication unit 134.

The wireless communication unit 131 is a physical interface such as an antenna/modem that performs 5G wireless communication.
The Ethernet communication unit 134 is a physical interface that connects to the device 20 via an Ethernet (registered trademark) cable such as an RJ45 cable.
The U-Plane unit 132 communicates with the 5G core device 110 via the wireless communication unit 131 through a logical connection GTP.
The C-Plane unit 133 performs communication for 5G control between the base station 120, the 5G core device 110, or other devices within the 5G network via the wireless communication unit 131. The C-Plane unit 133 is also referred to as a C-Plane function unit.

*** Operation Description ***
Next, an operation of the frame transmission system 500 according to the present embodiment will be described. The operation procedure of the frame transmission system 500 corresponds to a frame transmission method. Also, a program that realizes the operation of the frame transmission system 500 corresponds to a frame transmission program.

<Operation of 5G core device 110>
FIG. 7 is a diagram showing an example of a detailed functional configuration of the 5G core device 110 according to this embodiment.
Figure 8 is a flow diagram showing the operation of the 5G core device 110 in this embodiment.
FIG. 9 is a schematic diagram showing an example of frame format conversion by the frame transmission process of the frame transmission system 500 according to this embodiment.

<Switch processing>
The switch unit 112 of the 5G core device 110 uses a frame preemption function to generate a fragmented transmission frame 43 by fragmenting an Ethernet frame 40 into a fragmented frame 42 and adding fragmentation information 41 indicating the fragmentation of the fragmented frame 42.
Specifically, the following applies:

As shown in Figure 7, the switch unit 112 includes a switch transmission queue 11, a queue monitoring unit 12, and a frame splitting unit 13. The switch transmission queue 11 is also called an Ethernet (registered trademark) switch transmission queue.

In step S101, an Ethernet Frame 40 arrives at the switch transmission queue 11. The queue monitor 12 monitors the switch transmission queue 11.
In step S102, when a high-priority Ethernet Frame 40 arrives at the switch transmission queue 11, the queue monitor 12 notifies the frame divider 13 of the stop of transmission of the Ethernet Frame 40 that is being transmitted. In addition, the queue monitor 12 notifies the frame divider 13 of the leading position of the untransmitted portion of the Ethernet Frame 40 whose transmission has been stopped.
In step S103, when the frame dividing unit 13 is notified of the stop of transmission, it divides the transmitted portion and the unsent portion of the Ethernet Frame 40 whose transmission has been stopped based on the notified information. As shown in Fig. 9, the frame dividing unit 13 generates a fragmented transmission frame 43 by adding fragmentation information 41 to a fragmented frame 42 obtained by fragmenting the Ethernet Frame 40. The frame dividing unit 13 passes the fragmented transmission frame 43 to the GTP transmission unit 114.

<GTP Transmission Processing>
The GTP transmission unit 114 of the 5G core device 110 generates a GTP transmission frame 50 obtained by adding a GTP header 51 for GTP transmission of the fragmented frame 42 to the fragmented frame 42. At this time, the GTP transmission unit 114 embeds fragmentation information 41 in the GTP transmission frame 50.
Specifically, the GTP transmission unit 114 embeds the fragmentation information 41 inside the fragmentation frame 42, and adds a GTP header 51 to the fragmentation frame 42 in which the fragmentation information 41 is embedded, to generate a GTP transmission frame 50. Then, the GTP transmission unit 114 transmits the GTP transmission frame 50 in which the fragmentation information 41 is embedded in the fragmentation frame 42 to the 5G terminal 130.
More specifically, it is as follows.

As shown in FIG. 7, the GTP transmission unit 114 has a U-Plane function unit 14 and a format conversion unit 15.

In step S104, the format conversion unit 15 of the GTP transmission unit 114 receives the fragmented transmission frame 43 from the frame division unit 13. The format conversion unit 15 embeds fragmentation information 41 inside the fragmented frames 42 in the fragmented transmission frame 43, as shown in FIG.
In step S105, the U-Plane functional unit 14 generates a GTP transmission frame 50 by adding a GTP header 51 to the fragmented frame 42 in which the fragmentation information 41 is embedded, as shown in FIG.
In step S106, the U-Plane functional unit 14 transmits the GTP transmission frame 50 to the 5G terminal 130 via the communication unit 116.

FIG. 10 is a diagram showing an example of the configuration of a GTP transmission frame 50 according to the present embodiment.
10, fragmentation information 41 consisting of an mCRC, a Frag Count, and an SMD is embedded inside a fragmented frame 42. A GTP header is then added to the fragmented frame 42.
The SMD is information indicating the type of frame in frame preemption, such as an interrupted frame, a divided first frame, or a divided subsequent frame.
The Frag count is information indicating the ordinal number of the divided frame.
mCRC is the CRC of the split frame.

As described above, the frame to be interrupted and transmitted by frame preemption and the fragmentation (L1) information of the divided untransmitted portion are embedded in the Ethernet frame before it is GTP encapsulated.
It also issues instructions to the transmission queue and U-Plane section to perform interrupt transmission and transmission of untransmitted fragments.

<Operation of 5G terminal 130>
FIG. 11 is a diagram showing an example of a detailed functional configuration of the 5G terminal 130 according to the present embodiment.
FIG. 12 is a flow diagram showing the operation of the 5G terminal 130 according to the present embodiment.

<Format update process>
As shown in FIG. 11, the Ethernet communication unit 134 includes an Ethernet frame processing unit 341 and a format updating unit 342 .
The format update unit 342 extracts the fragmentation information 41 embedded inside the fragmentation frame 42. Then, the format update unit 342 restores the fragmentation transmission frame 43 by adding the fragmentation information 41 to the outside of the fragmentation frame 42 from which the fragmentation information 41 was extracted.
Specifically, the following applies:

In step S201, the wireless communication unit 131, such as an antenna modem, receives a GTP transmission frame 50.
In step S202, the U-Plane unit 132 deletes the GTP header 51 from the GTP transmission frame 50, and passes the fragmented frame 42 in which the fragmentation information 41 is embedded to the Ethernet communication unit 134.

In step S203, the format update unit 342 receives the fragmented frame 42 having the fragmentation information 41 embedded therein via the Ethernet frame processing unit 341. The format update unit 342 extracts the fragmentation information 41 embedded in the fragmented frame 42. Then, as shown in FIG. 9 , the format update unit 342 restores the fragmented transmission frame 43 by adding the fragmentation information 41 to the outside of the fragmented frame 42 from which the fragmentation information 41 was extracted.
In step S 204 , the format update unit 342 transmits the restored fragmented transmission frame 43 to the device 20 via the Ethernet frame processing unit 341 .

The device 20 receives the fragmented transmission frame 43 and restores the Ethernet frame 40 based on the fragmentation information 41.

***Explanation of Hardware Configuration Example***
FIG. 13 is a diagram showing an example of the hardware configuration of a 5G core device 110 according to this embodiment.

The 5G core device 110 is a computer. The 5G core device 110 includes a processor 910 and other hardware such as a memory 921, an auxiliary storage device 922, an input/output interface 930, and a communication interface 950. The processor 910 is connected to the other hardware via a signal line 80 and controls the other hardware.

The functions of the 5G core device 110, namely the switch unit 112, the protocol unit 113, the GTP transmission unit 114 and the C-Plane unit 115, are realized by software.

The processor 910 is a device that executes a frame transmission program. The frame transmission program is a program that realizes the functions of the frame transmission system 500.
The processor 910 is an IC that performs arithmetic processing. Specific examples of the processor 910 are a CPU, a DSP, and a GPU. IC is an abbreviation for Integrated Circuit. CPU is an abbreviation for Central Processing Unit. DSP is an abbreviation for Digital Signal Processor. GPU is an abbreviation for Graphics Processing Unit.

The memory 921 is a storage device that temporarily stores data. Specific examples of the memory 921 are SRAM and DRAM. SRAM is an abbreviation for Static Random Access Memory. DRAM is an abbreviation for Dynamic Random Access Memory.
The auxiliary storage device 922 is a storage device that stores data. A specific example of the auxiliary storage device 922 is a HDD. The auxiliary storage device 922 may also be a portable storage medium such as an SD (registered trademark) memory card, a CF, a NAND flash, a flexible disk, an optical disk, a compact disk, a Blu-ray (registered trademark) disk, or a DVD. Note that HDD is an abbreviation for Hard Disk Drive. SD (registered trademark) is an abbreviation for Secure Digital. CF is an abbreviation for CompactFlash (registered trademark). DVD is an abbreviation for Digital Versatile Disk.

The input/output interface 930 is an interface for connecting input/output devices. Specific examples of the input/output interface 930 are USB and HDMI (registered trademark) ports. USB is an abbreviation for Universal Serial Bus. HDMI (registered trademark) is an abbreviation for High-Definition Multimedia Interface.

The communication interface 950 is an interface for communicating with an external device. Specific examples of the communication interface 950 include an Ethernet (registered trademark) port, or a device for performing wireless communication. The above-mentioned Ethernet communication unit 111 and communication unit 116 are realized by the communication interface 950.
Although not shown, other hardware such as device management, power supply, and a management interface may also be provided. The device management is hardware such as a CPU that executes all functions other than the communication function. The management interface is a user interface that accepts setting input from the user or outputs and displays information such as the device status. The management interface may be included in the input/output interface 930.

The frame transmission program is executed in the 5G core device 110. The frame transmission program is loaded into the processor 910 and executed by the processor 910. The memory 921 stores not only the frame transmission program but also the OS. The OS is an abbreviation for Operating System. The processor 910 executes the frame transmission program while executing the OS. The frame transmission program and the OS may be stored in the auxiliary storage device 922. The frame transmission program and the OS stored in the auxiliary storage device 922 are loaded into the memory 921 and executed by the processor 910. Note that a part or all of the frame transmission program may be incorporated into the OS.

The 5G core device 110 may include multiple processors that replace the processor 910. These multiple processors share the execution of the frame transmission program. Each processor is a device that executes the frame transmission program in the same manner as the processor 910.

Data, information, signal values and variable values used, processed or output by the frame transmission program are stored in memory 921, auxiliary storage device 922, or in a register or cache memory within processor 910.

The "part" of each part of the 5G core device 110 may be read as a "circuit", "step", "procedure", "process", or "circuitry". The frame transmission program causes a computer to execute each process in which the "part" of each part of the 5G core device 110 is read as a "process". The "process" of each process of the 5G core device 110 may be read as a "program", "program product", "computer-readable storage medium storing a program", or "computer-readable recording medium recording a program". The frame transmission method is a method performed by the 5G core device 110 executing the frame transmission program.
The frame transmission program may be provided by being stored in a computer-readable recording medium, or may be provided as a program product.

In addition, the description of the hardware configuration of the 5G core device 110 can also be adopted as appropriate for the hardware configuration of the 5G terminal 130.

***Other configurations***
<Modification>
In this embodiment, the functions of each unit of the 5G core device 110 are realized by software. As a modified example, the functions of each unit of the 5G core device 110 may be realized by hardware.
Specifically, the 5G core device 110 includes an electronic circuit 909 instead of a processor 910.

FIG. 14 is a diagram showing the configuration of a 5G core device 110 relating to a modified example of this embodiment.
The electronic circuit 909 is a dedicated electronic circuit that realizes the functions of each part of the 5G core device 110. Specifically, the electronic circuit 909 is a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, a logic IC, a GA, an ASIC, or an FPGA. GA is an abbreviation for Gate Array. ASIC is an abbreviation for Application Specific Integrated Circuit. FPGA is an abbreviation for Field-Programmable Gate Array.

The functions of each part of the 5G core device 110 may be realized by a single electronic circuit, or may be distributed across multiple electronic circuits.

As another modification, some of the functions of each part of the 5G core device 110 may be realized by electronic circuits, and the remaining functions may be realized by software. Also, some or all of the functions of each part of the 5G core device 110 may be realized by firmware.

Each of the processor and electronic circuitry is also called a processing circuitry. In other words, the functions of each part of the 5G core device 110 are realized by the processing circuitry.

In addition, the description of the modified hardware configuration of the 5G core device 110 can also be adopted as appropriate for the modified hardware configuration of the 5G terminal 130.

***Description of Effects of This Embodiment***
As described above, according to the frame transmission system 500 of the present embodiment, fragmentation information generated by frame preemption can be transmitted in a GTP tunnel by U-plane. Therefore, according to the frame transmission system 500 of the present embodiment, it is possible to perform frame preemption in a 5G core device of a virtual 5G network bridge.
Furthermore, the frame transmission system 500 according to the present embodiment has the advantage that it is not necessary to change the format of the GTP header in a GTP tunnel in the U-plane.

Embodiment 2.
In this embodiment, differences from and additions to the first embodiment will be mainly described.
In this embodiment, components having the same functions as those in the first embodiment are given the same reference numerals, and the description thereof will be omitted.

In the first embodiment, the GTP transmission unit 114 embedded the fragmentation information 41 inside the fragmentation frame 42 to generate the GTP transmission frame 50. In the present embodiment, a manner in which the GTP transmission unit 114 embeds the fragmentation information 41 in the GTP header 51 will be described.

***Configuration Description***
The overall configuration of the frame transmission system 500 in this embodiment, the functional configuration and hardware configuration of the 5G core device 110, and the functional configuration and hardware configuration of the 5G terminal 130 are the same as those in embodiment 1.

*** Operation Description ***
Next, an operation of the frame transmission system 500 according to the present embodiment will be described. The operation procedure of the frame transmission system 500 corresponds to a frame transmission method. Also, a program that realizes the operation of the frame transmission system 500 corresponds to a frame transmission program.

<Operation of 5G core device 110>
FIG. 15 is a diagram showing an example of a detailed functional configuration of the 5G core device 110 according to this embodiment.
Figure 16 is a flow diagram showing the operation of the 5G core device 110 in this embodiment.
FIG. 17 is a schematic diagram showing an example of frame format conversion by the frame transmission process of the frame transmission system 500 according to this embodiment.

The detailed configurations of the switch unit 112 and the GTP transmission unit 114 according to this embodiment are similar to those of the first embodiment.
Moreover, the processes from step S101 to step S103 are the same as those in embodiment 1. As in embodiment 1, the switch unit 112 generates a fragmented transmission frame 43 and transmits it to the GTP transmission unit 114.

<GTP Transmission Processing>
The GTP transmission unit 114 embeds the fragmentation information 41 inside the GTP header 51 , and adds the GTP header 51 with the embedded fragmentation information 41 to the fragmented frame 42 to generate a GTP transmission frame 50 .
Specifically, the following applies:

In step S104a, the format conversion unit 15 of the GTP transmission unit 114 receives the fragmented transmission frame 43 from the frame division unit 13. The format conversion unit 15 also passes the fragmented transmission frame 43 to the U-Plane functional unit 14, and receives a GTP header 51 from the U-Plane functional unit 14. As shown in FIG. 9, the format conversion unit 15 embeds fragmentation information 41 in the GTP header 51, and passes the GTP header 51 with the embedded fragmentation information 41 to the U-Plane functional unit 14.
In step S105a, the U-Plane functional unit 14 generates a GTP transmission frame 50 by adding a GTP header 51, in which the fragmentation information 41 is embedded, to the fragmented frame 42, as shown in FIG.
The process of step S106 is the same as in the first embodiment.

FIG. 18 is a diagram showing an example of the configuration of a GTP transmission frame 50 according to this embodiment.
FIG. 18 shows the format of a GTP header in which fragmentation information 41 is embedded.
An extension header including SMD, Frag Count, and mCRC is embedded in the GTP header as fragmentation information 41. The mCRC may be omitted. In Fig. 18, the information in the fragmentation information 41 is indicated by hatching.

<Operation of 5G terminal 130>
FIG. 19 is a diagram showing an example of a detailed functional configuration of a 5G terminal 130 according to the present embodiment.
FIG. 20 is a flow diagram showing the operation of the 5G terminal 130 according to the present embodiment.

The U-Plane unit 132 in this embodiment comprises a GTP processing unit 321 and a format update unit 322.

The format update unit 322 of the 5G terminal 130 extracts the fragmentation information 41 embedded inside the GTP header 51 and restores the fragmented transmission frame 43 by adding the fragmentation information 41 to the outside of the fragmented frame 42.
Specifically, the following applies:

Moreover, the process of step S201 is the same as that of embodiment 1. As in embodiment 1, the wireless communication unit 131, such as an antenna/modem, receives the GTP transmission frame 50. The wireless communication unit 131 passes the GTP transmission frame 50 to the U-Plane unit 132.
In step S202a, the GTP processing unit 321 of the U-Plane unit 132 passes the GTP transmission frame 50 to the format updating unit 322. The format updating unit 322 extracts the fragmentation information 41 from the GTP header 51.
17, the format update unit 322 restores the fragmented transmission frame 43 by adding the fragmentation information 41 to the outside of the fragmented frame 42. The format update unit 322 passes the restored fragmented transmission frame 43 to the GTP processing unit 321.
In step S204, the GTP processing unit 321 transmits the restored fragmented transmission frame 43 to the device 20 via the Ethernet communication unit 134.

The device 20 receives the fragmented transmission frame 43 and restores the Ethernet frame 40 based on the fragmentation information 41.

***Description of Effects of This Embodiment***
As described above, according to the frame transmission system 500 of the present embodiment, in the GTP tunnel by U-plane, the fragmentation information generated by frame preemption can be embedded in the GTP header and transmitted. Therefore, according to the frame transmission system 500 of the present embodiment, it is possible to perform frame preemption in the 5G core device of the virtual 5G network bridge.

Embodiment 3.
In this embodiment, differences from and additions to the first embodiment will be mainly described.
In this embodiment, components having the same functions as those in the first embodiment are given the same reference numerals, and the description thereof will be omitted.

In the first embodiment, the 5G terminal 130 has a function of restoring the fragmented transmission frame 43. In the present embodiment, a translator 30 is provided between the 5G terminal 130 and the device 20, and an aspect in which the translator 30 restores the fragmented transmission frame 43 will be described.

***Configuration Description***
FIG. 21 is a diagram showing an example of the overall configuration of a frame transmission system 500 according to this embodiment.
FIG. 22 is a diagram showing an example of a functional configuration of the translator 30 according to the present embodiment.

The frame transmission system 500 according to this embodiment includes a translator 30 disposed between the 5G terminal 130 and the device 20.
The translator 30 includes an Ethernet communication unit 301 and a format update unit 302 .

The Ethernet communication unit 301 is a physical interface that connects to the device 20 or the 5G terminal 130 via an Ethernet (registered trademark) cable such as RJ45.
The format update unit 302 has a function of removing the fragmentation information 41 embedded in the fragmentation frame 42 and adding the fragmentation information 41 to the fragmentation frame 42 as an L1 header.

In addition, the description of the hardware configuration of the translator 30 can also be adopted as appropriate for the hardware configuration of the translator 30.

*** Operation Description ***
Next, an operation of the frame transmission system 500 according to the present embodiment will be described. The operation procedure of the frame transmission system 500 corresponds to a frame transmission method. Also, a program that realizes the operation of the frame transmission system 500 corresponds to a frame transmission program.

FIG. 23 is a schematic diagram showing an example of frame format conversion by the frame transmission system 500 according to the present embodiment.
The operation of the 5G core device 110 is the same as that described in embodiment 1. That is, the 5G core device 110 transmits to the 5G terminal 130 a GTP transmission frame 50 in which a GTP header 51 is added to a fragmented frame 42 in which fragmentation information 41 is embedded.

The 5G terminal 130 performs normal GTP transmission processing. That is, the 5G terminal 130 deletes the GTP header 51 from the GTP transmission frame 50 and transmits the fragmented frame 42 with the fragmentation information 41 embedded therein to the translator 30.

FIG. 24 is a flow diagram showing the operation of the translator 30 according to the present embodiment.
In step S301, the Ethernet communication unit 301 of the translator 30 receives a fragmented frame 42 with fragmentation information 41 embedded therein from the 5G terminal 130.
In step S302, the format update unit 302 of the translator 30 extracts the fragmentation information 41 embedded inside the fragmentation frame 42. Then, the format update unit 302 restores the fragmentation transmission frame 43 by adding the fragmentation information 41 to the outside of the fragmentation frame 42 from which the fragmentation information 41 was extracted.
In step S 302 , the Ethernet communication unit 301 transmits the fragmented transmission frame 43 to the device 20 .

The device 20 receives the fragmented transmission frame 43 and reconstructs the Ethernet frame 40 based on the fragmentation information 41 .
***Description of Effects of This Embodiment***
As described above, the frame transmission system 500 according to this embodiment has the effect of eliminating the need to modify the 5G terminal, in addition to the effect of the first embodiment.

In the above first to third embodiments, each unit of each device in the frame transmission system has been described as an independent functional block. However, the configuration of each device in the frame transmission system does not have to be as in the above-mentioned embodiments. The functional blocks of each device in the frame transmission system may have any configuration as long as they can realize the functions described in the above-mentioned embodiments. Furthermore, each device in the frame transmission system may not be a single device, but may be a system composed of multiple devices.
In addition, a combination of multiple parts of the first to third embodiments may be implemented. Alternatively, one part of these embodiments may be implemented. In addition, any combination of these embodiments may be implemented as a whole or in part.
That is, in the first to third embodiments, the embodiments can be freely combined, any of the components in each embodiment can be modified, or any of the components in each embodiment can be omitted.

Note that the above-described embodiments are essentially preferred examples and are not intended to limit the scope of the present disclosure, the scope of application of the present disclosure, or the scope of use of the present disclosure. The above-described embodiments can be modified in various ways as necessary. For example, the procedures described using flow charts or sequence diagrams may be modified as appropriate.

11 Switch transmission queue, 12 Queue monitoring unit, 13 Frame division unit, 14 U-Plane function unit, 15 Format conversion unit, 20 Equipment, 30 Translator, 40 Ethernet frame, 41 Fragmentation information, 42 Fragmented frame, 43 Fragmented transmission frame, 50 GTP transmission frame, 51 GTP header, 80 Signal line, 100 5G network bridge, 110 5G core device, 111, 134, 301 Ethernet communication unit, 112 Switch unit, 113 Protocol unit, 114 GTP transmission unit, 115, 133 C-Plane unit, 116 Communication unit, 120 Base station, 130 5G terminal, 131 Wireless communication unit, 132 U-Plane unit, 321 GTP processing unit, 341 Ethernet frame processing unit, 302, 322, 342 Format update unit, 500 frame transmission system, 909 electronic circuit, 910 processor, 921 memory, 922 auxiliary storage device, 930 input/output interface, 950 communication interface.

Claims (12)

In a frame transmission system that transmits an Ethernet frame, which is an Ethernet (registered trademark) frame to be transmitted to a device, via a 5G network bridge in which a 5G network that performs GTP transmission, which is general packet radio service tunneling protocol transmission, by a 5G core device and a 5G terminal operates as a network bridge,
The 5G core device includes:
a switch unit that generates fragmented transmission frames by fragmenting the Ethernet frame using a frame preemption function, the fragmented transmission frames being each provided with fragmentation information indicating fragmentation of the fragmented frames;
A frame transmission system comprising: a GTP transmission unit that transmits a GTP transmission frame obtained by adding a GTP header for GTP transmission of the fragmented frame to the fragmented frame, the GTP transmission frame having the fragmentation information embedded therein, to the 5G terminal. The GTP transmission unit
The frame transmission system according to claim 1 , wherein the fragmentation information is embedded inside the fragmented frame, and the GTP transmission frame is generated by adding the GTP header to the fragmented frame in which the fragmentation information is embedded. The 5G terminal is
3. The frame transmission system according to claim 2, further comprising a format update unit that extracts the fragmentation information embedded within the fragmented frame and restores the fragmented transmission frame by adding the fragmentation information to the outside of the fragmented frame from which the fragmentation information was extracted. The GTP transmission unit
2. The frame transmission system according to claim 1, wherein the fragmentation information is embedded inside the GTP header, and the GTP header in which the fragmentation information is embedded is added to the fragmented frame to generate the GTP transmission frame. The 5G terminal is
The frame transmission system according to claim 4, further comprising a format update unit that extracts the fragmentation information embedded within the GTP header and restores the fragmented transmission frame by adding the fragmentation information to the outside of the fragmented frame. The frame transmission system includes:
A translator is provided between the 5G terminal and the device,
The translator:
The frame transmission system of claim 2, further comprising a format update unit that receives the fragmented frame from the 5G terminal, extracts the fragmentation information embedded within the fragmented frame, and restores the fragmented transmission frame by adding the fragmentation information to the outside of the fragmented frame from which the fragmentation information was extracted. In a frame transmission system that transmits an Ethernet frame, which is an Ethernet (registered trademark) frame to be transmitted to a device via a 5G network bridge in which a 5G network that performs GTP transmission, which is general packet radio service tunneling protocol transmission, by a 5G core device and a 5G terminal, operates as a network bridge, the 5G core device is included in
a switch unit that generates fragmented transmission frames by fragmenting the Ethernet frame using a frame preemption function, the fragmented transmission frames being each provided with fragmentation information indicating fragmentation of the fragmented frames;
A 5G core device comprising: a GTP transmission unit that transmits a GTP transmission frame obtained by adding a GTP header for GTP transmission of the fragmented frame to the fragmented frame, the GTP transmission frame having the fragmentation information embedded therein, to the 5G terminal. In a 5G terminal included in a frame transmission system that transmits an Ethernet frame, which is an Ethernet (registered trademark) frame to be transmitted to a device, via a 5G network bridge in which a 5G network that performs GTP transmission, which is general packet radio service tunneling protocol transmission, by a 5G core device and a 5G terminal operates as a network bridge,
A switch unit that generates a fragmented transmission frame by fragmenting the Ethernet frame using a frame preemption function, and a GTP transmission unit that transmits a GTP transmission frame in which the fragmented frame is obtained by adding a GTP header for transmitting the fragmented frame via GTP to the fragmented frame and in which the fragmentation information is embedded, and an Ethernet communication unit that receives the GTP transmission frame from the 5G core device;
A 5G terminal comprising: a format update unit that extracts the fragmentation information embedded in the GTP transmission frame and restores the fragmented transmission frame by adding the fragmentation information to the fragmented frame. A 5G network bridge that operates as a network bridge in which a 5G network performs GTP transmission, which is a general packet radio service tunneling protocol transmission, between a 5G core device and a 5G terminal, transmits an Ethernet frame, which is an Ethernet (registered trademark) frame, to a device, and a translator disposed between the 5G terminal and the device,
A switch unit that generates a fragmented transmission frame by fragmenting the Ethernet frame using a frame preemption function and adding fragmentation information indicating the fragmentation of the fragmented frame to the fragmented frame, and a GTP transmission unit that embeds the fragmentation information inside the fragmented frame and transmits a GTP transmission frame to the 5G terminal by adding a GTP header for the GTP transmission to the fragmented frame with the embedded fragmentation information, from the 5G core device, an Ethernet communication unit that receives the fragmented frame with the embedded fragmentation information via the 5G terminal;
a format update unit that extracts the fragmentation information embedded inside the fragmented frame and restores the fragmented transmission frame by adding the fragmentation information to the outside of the fragmented frame from which the fragmentation information was extracted. The Ethernet communication unit is
The translator according to claim 9, wherein the GTP header is removed from the GTP transmission frame received from the 5G core device, and the fragmented frame obtained by removing the GTP header is transmitted from the 5G terminal. In a frame transmission method used in a frame transmission system, a 5G network bridge that operates as a network bridge in a 5G network that performs GTP transmission, which is a general packet radio service tunneling protocol transmission, between a 5G core device and a 5G terminal transmits an Ethernet frame, which is an Ethernet (registered trademark) frame, to a device,
a computer using a frame preemption function to generate fragmented transmission frames by fragmenting the Ethernet frame and adding fragmentation information indicating fragmentation of the fragmented frames to the fragmented frames;
A frame transmission method in which a computer transmits to the 5G terminal a GTP transmission frame obtained by adding a GTP header for GTP transmission of the fragmented frame to the fragmented frame, the GTP transmission frame having the fragmentation information embedded therein. A frame transmission program used in a frame transmission system that transmits an Ethernet frame, which is an Ethernet (registered trademark) frame to be transmitted to a device, via a 5G network bridge in which a 5G network that performs GTP transmission, which is general packet radio service tunneling protocol transmission, between a 5G core device and a 5G terminal operates as a network bridge,
a switch process for generating fragmented transmission frames by fragmenting the Ethernet frame using a frame preemption function, the fragmented transmission frames being provided with fragmentation information indicating the fragmentation of the fragmented frames;
A frame transmission program that causes a computer to execute a GTP transmission process to transmit a GTP transmission frame obtained by adding a GTP header for GTP transmission of the fragmented frame to the fragmented frame, the GTP transmission frame having the fragmentation information embedded therein, to the 5G terminal.

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