KR101708398B1 - Synchronization method for terminal on profiled network and networking apparatus performing the same - Google Patents

Abstract

The present invention relates to a network technology of a network terminal on a profile network. A method of synchronizing a network terminal on a profile network comprises (a) a step of performing connection through a virtual link defined by the maximum transmission length of a frame and another network terminal and the bandwidth allocation gap between frames; (b) a step of transmitting a current frame via the virtual link; and (C) a step of transmitting a common control frame for communication with the other network terminal until the bandwidth allocation gap elapses if the current frame is transmitted. So, it is possible to transmit control data by predicting an interval in which data is not transmitted between the network terminals.

Description

TECHNICAL FIELD [0001] The present invention relates to a synchronization method of a network terminal on a profile network, and a network device performing the same. [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a network technology of a network terminal on a profile network, and more particularly, to a network technology of a network terminal on a profile network capable of predicting an interval during which data is not transmitted between network terminals, And a network device for performing the same.

ARINC 664 defines a protocol for transmitting and receiving control data in an aircraft using deterministic Ethernet. For example, ARINC 664 Switched Ethernet is used in modern aircraft such as the A380 and B787.

Networks that transmit and receive control data within an aircraft must ensure a very strict and predictable deterministic quality of service (QoS).

For this, ARINC 664 Part 7 standard specifies the maximum transmission length (Lmax) of a frame that can be transmitted at maximum in one virtual link (VL, Virtual Link) and the minimum transmission interval (BAG, Bandwidth Allocation Gap) Setting. Each end system may have one or a plurality of virtual links (VL). Each virtual link (VL) has a preset Lmax and BAG. One or a plurality of virtual links (VL) are connected to the applications of the end system, and data is exchanged through the virtual link.

The data generated by each application is encapsulated into frames according to the specification and transmitted / received according to the Lmax and BAG set in the corresponding virtual link. If a frame is transmitted from the end system without observing this rule, the switch connected to the end system receives the frame and discards it.

The ARINC 664 Part 7 specification does not describe a specific method for synchronizing clocks or dates between network terminals (eg, end systems, switches, etc.). IEEE 1588 or IEEE 802.1AS, or IRIG-B. However, various problems may occur when the conventional time synchronization method is applied to the ARINC 664 Part 7 standard.

IRIG-B requires separate cabling for clock synchronization. However, in the case of IEEE 1588, DATE is synchronized through packet exchange, so that it is not necessary to use a separate cable and can be synchronized through a data communication channel. Systematically IEEE 1588 is simpler than IRIG-B.

For example, when using the IEEE 1588 synchronous scheme, an IEEE 1588 packet is delivered using the virtual link allocated for time synchronization. Applications also communicate control data using virtual links, respectively. At this time, if the time of transmission of the control data and the time of transmission of the IEEE 1588 packet occurs accidentally, the IEEE 1588 packet is delayed due to the precedence of the control data. This delay can increase the error of the time synchronization.

Korean Patent Publication No. 10-2000-0071781 (November 25, 2000) Korean Registered Patent No. 10-1126091 (March 30, 2012)

An embodiment of the present invention is to provide a method of synchronizing a network terminal on a profile network capable of predicting a period during which data is not transmitted between network terminals and transmitting control data, and a network device performing the method.

One embodiment of the present invention provides a synchronization method of a network terminal on a profile network capable of preventing data transmission (e.g., a time synchronization control frame) from being delayed by transmission of control data, and a network device .

An embodiment of the present invention is to provide a synchronization method of a network terminal on a profile network capable of efficiently controlling a network terminal and precisely performing time synchronization, and a network device performing the synchronization method.

(A) connecting through a virtual link defined by a maximum transmission length of a frame with another network terminal and a minimum transmission interval between frames, (b) Transmitting a current frame through the virtual link; and (c) transmitting a common control frame for communication with the other network terminal until the minimum transmission interval elapses when the current frame is transmitted.

In one embodiment, the step (c) includes transmitting the common control frame by checking whether the current minimum transmission interval is longer than a specific time period, regardless of whether or not the next frame exists before transmission of the common control frame can do.

In one embodiment, the common control frame may correspond to a time synchronization control frame for controlling time synchronization between the network terminal and the other network terminal.

In one embodiment, the time synchronization control frame may be implemented through a Precision Time Protocol (PTP) of IEEE 1588 or IEEE 802.1AS.

In one embodiment, step (c) may comprise determining a master clock terminal of the endpoints of the virtual link (i.e., the network terminal and the other network terminal).

In one embodiment, the step (c) may further include causing the other network terminal to perform time synchronization if the master clock terminal corresponds to the other network terminal.

In one embodiment, the step (c) may include transmitting the first common control sub-frame of the common control frame until the minimum transmission interval for the current frame elapses, until the minimum transmission interval for the next frame elapses And transmitting a second common control sub-frame of the common control frame.

In one embodiment, the first common control sub-frame corresponds to a frame for message delay adjustment on the PTP, and the second common control sub-frame corresponds to a frame for message delay rebalancing on the PTP.

In one embodiment, a method of synchronizing a network terminal on the profile network may further include the step of (d) transmitting a next frame of the current frame after the common control frame is transmitted.

Among the embodiments, a method of synchronizing a network terminal on a profile network comprises concatenating at least one virtual link defined by a maximum transmission length of a frame with another network terminal and a minimum transmission interval between frames, Analyzing all minimum transmission intervals of the at least one virtual link and transmitting a common control frame for communication with the other network terminals until the nearest minimum transmission interval has elapsed.

Among embodiments, a method of synchronizing a network terminal on a profile network comprises concatenating at least one virtual link defined by a maximum transmission length of a frame with other network terminals and a minimum transmission interval between frames, If the at least one virtual link is not being used based on the virtual link use state map, preparing a virtual link use state map indicating a virtual link and a use state of the at least one virtual link, And transmitting a common control frame for the communication of the base station.

Among the embodiments, the network device includes a first network terminal and a second network terminal connected through a virtual link defined by a maximum transmission length of a frame and a minimum transmission interval between frames with the first network terminal, The first network terminal transmits a current frame to the second network terminal through the virtual link, and if the current frame is transmitted, a common control frame for communication with the second network terminal until the minimum transmission interval elapses send.

The disclosed technique may have the following effects. It is to be understood, however, that the scope of the disclosed technology is not to be construed as limited thereby, as it is not meant to imply that a particular embodiment should include all of the following effects or only the following effects.

A method of synchronizing a network terminal on a profile network according to an embodiment of the present invention and a network terminal performing the method may transmit control data by predicting a period in which data is not transmitted between network terminals.

A method of synchronizing a network terminal on a profile network according to an embodiment of the present invention and a network terminal performing the method can prevent a data transmission (e.g., a time synchronization control frame) from being delayed by transmission of control data have.

The synchronization method of the network terminal on the profile network according to the embodiment of the present invention and the network terminal performing it can efficiently control the network terminal and precisely perform the time synchronization.

1 is a diagram illustrating a profile network including a network terminal connected through a virtual link.
2 is a flowchart illustrating a synchronization method performed by the network terminal shown in FIG.
3 is a view for explaining an example of a specific processing procedure of a synchronization method performed in the network terminal shown in FIG.
4 is a view for explaining a time synchronization control frame according to the PTP protocol.
5 is a view for explaining another example of a specific processing procedure of the synchronization method performed in the network terminal shown in FIG.

The description of the present invention is merely an example for structural or functional explanation, and the scope of the present invention should not be construed as being limited by the embodiments described in the text. That is, the embodiments are to be construed as being variously embodied and having various forms, so that the scope of the present invention should be understood to include equivalents capable of realizing technical ideas. Also, the purpose or effect of the present invention should not be construed as limiting the scope of the present invention, since it does not mean that a specific embodiment should include all or only such effect.

Meanwhile, the meaning of the terms described in the present application should be understood as follows.

The terms "first "," second ", and the like are intended to distinguish one element from another, and the scope of the right should not be limited by these terms. For example, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

It is to be understood that when an element is referred to as being "connected" to another element, it may be directly connected to the other element, but there may be other elements in between. On the other hand, when an element is referred to as being "directly connected" to another element, it should be understood that there are no other elements in between. On the other hand, other expressions that describe the relationship between components, such as "between" and "between" or "neighboring to" and "directly adjacent to" should be interpreted as well.

It is to be understood that the singular " include " or "have" are to be construed as including the stated feature, number, step, operation, It is to be understood that the combination is intended to specify that it does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

In each step, the identification code (e.g., a, b, c, etc.) is used for convenience of explanation, the identification code does not describe the order of each step, Unless otherwise stated, it may occur differently from the stated order. That is, each step may occur in the same order as described, may be performed substantially concurrently, or may be performed in reverse order.

The present invention can be embodied as computer-readable code on a computer-readable recording medium, and the computer-readable recording medium includes any type of recording device that stores data that can be read by a computer system . Examples of the computer-readable recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, and the like, and also implemented in the form of a carrier wave (for example, transmission over the Internet) . In addition, the computer-readable recording medium may be distributed over network-connected computer systems so that computer readable codes can be stored and executed in a distributed manner.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used predefined terms should be interpreted to be consistent with the meanings in the context of the related art and can not be interpreted as having ideal or overly formal meaning unless explicitly defined in the present application.

1 is a diagram illustrating a profile network including a network terminal connected through a virtual link.

1, the profile network 100 includes an application 110, an end system 120 and a switch 130, and at least one application 110a, 110b, 110c is connected to the end system 120 . Each of which may be connected via at least one virtual link.

The profile network 100 is a QoS determined network, in which data transmission is predetermined in advance and the problem that the network speed becomes slow or the real time response does not occur is resolved. In one embodiment, the profile network 100 may correspond to an Avionics Full DupleX Switched Ethernet (ARINC 664 Part 7; AFDX) network.

The application 110 may be connected to the end system 120 and may generate data according to the process of the application. Alternatively, the application 110 may receive data and process the data in accordance with the process. For example, in the case of an application that performs time synchronization, control data for time synchronization can be generated. Each application is connected by at least one gashing link and exchanges data via a virtual link.

The end system 120 is connected as at least one virtual link as a destination or source of data. The end system 120 is connected to the switch 130 and transmits and receives a frame according to a maximum transmission length Lmax of a frame set in the connected virtual link and a minimum transmission interval (BAG) between frames.

The switch 130 determines whether the received frame has been transmitted according to the maximum transmission length Lmax of the set frame and the minimum transmission interval BAG between the frames, and switches the received frame to the destination. If the received frame is not transmitted according to the maximum transmission length (Lmax) of the set frame and the minimum transmission interval (BAG) between the frames, the switch 130 discards the frame. The switch 130 may be connected to other end systems or other switches.

In one embodiment, end system 120 transmits the current frame to switch 130 via a virtual link. At this time, the end system 120 predicts an interval in which a frame within a minimum transmission interval is not transmitted, and transmits a common control frame to the switch 130 in an interval in which the frame is not transmitted. When the current frame is transmitted, the end system 120 may transmit a common control frame for communication with another network terminal (e.g., another end system or switch) until the minimum transmission interval elapses.

In another embodiment, the end system 120 transmits the first common control sub-frame of the common control frame until the minimum transmission interval for the current frame has elapsed, until the minimum transmission interval for the latter frame has elapsed, Frame of the second common control sub-frame.

In one embodiment, the common control frame may correspond to a time synchronization control frame that controls time synchronization between network terminals. In one embodiment, the time synchronization control frame may be implemented via IEEE 1588 or Precision Time Protocol (PTP) of IEEE 802.1AS.

2 is a flowchart illustrating a synchronization method performed by the network terminal shown in FIG.

Referring to FIG. 2, a network terminal (e.g., an end system) is connected to another network terminal (e.g., a network terminal) via a virtual link defined by a maximum transmission length Lmax of a frame and a minimum transmission interval , Switch or other end system) (step S210).

The network terminal transmits the current frame through the connected virtual link (step S220). For example, the end system 120 encapsulates data generated in the application 110 into a frame, and transmits the maximum transmission length Lmax of the frame set for the virtual link to which the frame is to be transmitted and the minimum transmission interval BAG) to the switch 130.

The network terminal transmits a current frame and predicts a period in which a frame within the minimum transmission interval is not transmitted in the virtual link (step S230), and transmits a common control frame in a period in which the frame is not transmitted in the virtual link (step S240 ). In one embodiment, the network terminal can predict a period in which a frame is not transmitted based on a size of a frame to be transmitted, a maximum transmission length (Lmax) of a frame set in a virtual link, and a minimum transmission interval (BAG) between frames.

For example, if the maximum transmission length (Lmax) of the frame of the virtual link to which the current frame is to be transmitted is 64 bytes, the minimum transmission interval (BAG) between frames is set to 1 ms, It is assumed that a frame of 64 bytes is transmitted through the frame. If 5.12 us is required to transmit a 64-byte frame through the virtual link, the network terminal (end system) can predict that 995.88 us remains until the next frame is transmitted after the current frame is transmitted.

If it is determined that the remaining time is enough to transmit the common control frame, the network terminal transmits the common control frame immediately after the transmission of the current frame is completed. In one embodiment, the network terminal may determine whether the remaining time is sufficient depending on the type or size of the common control frame.

In one embodiment, the network terminal can transmit a common control frame by checking whether the current minimum transmission interval has remained longer than a specific time before transmission of the common control frame. The network terminal does not transmit the common control frame and prevents the transmission of the next frame from being delayed due to the transmission of the common control frame. In an embodiment, when the network terminal is at least one The network terminal may analyze all the minimum transmission intervals of at least one virtual link and transmit the common control frame until the nearest minimum transmission interval has elapsed.

In one embodiment, it is assumed that the first virtual link is used to transmit the data (frame) and the common control frame, and the second virtual link is used to transmit only the common control frame.

It is assumed that a network terminal (end system) is connected to another network terminal (switch) through a plurality of virtual links, and each virtual link has a different directionality. For example, the first virtual link is connected through two virtual links and the first virtual link is a direction for transmitting a frame from a network terminal (end system) to another network terminal (switch), and the second virtual link is connected to another network terminal This is the direction in which frames are transmitted to the network terminal (end system).

The maximum transmission length (Lmax) of the frame of the first virtual link is 64 bytes, the minimum transmission interval (BAG) between the frames is set to 1 ms, and the maximum transmission length (Lmax) of the frame of the second virtual link is 64 bytes , The minimum transmission interval BAG between frames is set to 1 ms, and the time required for exchanging a common control frame (for example, a time synchronization control frame) is 500 us.

If 5.12 us is required to transmit the current frame of 64 bytes through the first virtual link, 994.88 us remains to transmit the next frame through the first virtual link. It can be predicted that the frame will not be transmitted or received during 994.88 us. That is, it can be predicted that 994.88 us remains until the minimum transmission interval closest to the current time (minimum transmission interval of the first virtual link) elapses.

994.88us is sufficient to exchange a common control frame (e.g., a time synchronization control frame), so that the network terminal (end system) can share a common control frame (e.g., a time synchronization control frame) with another network terminal And exchange them.

In a different embodiment, it is assumed that both the first virtual link and the second virtual link are used to transmit data (frame) and a common control frame. When a network terminal (end system) And a plurality of virtual links, and it is assumed that each virtual link has a different directionality. For example, the first virtual link is connected through two virtual links and the first virtual link is a direction for transmitting a frame from a network terminal (end system) to another network terminal (switch), and the second virtual link is connected to another network terminal This is the direction in which frames are transmitted to the network terminal (end system).

The maximum transmission length (Lmax) of the frame of the first virtual link is 64 bytes, the minimum transmission interval (BAG) between the frames is set to 1 ms, and the maximum transmission length (Lmax) of the frame of the second virtual link is 1518 bytes , The minimum transmission interval BAG between frames is set to 1 ms, and the time required for exchanging a common control frame (for example, a time synchronization control frame) is 500 us.

If 5.12 us is required to transmit the current frame of 64 bytes through the first virtual link, 994.88 us remains to transmit the next frame through the first virtual link. However, since the frame can be received via the second virtual link, the network terminal (end system) waits for a certain period of time. If a frame of 1518 bytes is received through the second virtual link after 100 microseconds after transmission of the current frame and 121.55 microseconds is required to receive the frame, the network terminal (end system) It can be predicted that the frame will not be transmitted or received during 773.33 us (1000us - (5.12us + 100us + 121.55us)) in the second virtual link. That is, it can be predicted that 773.33 us remains until the minimum transmission interval closest to the current time (minimum transmission interval of the first virtual link) elapses.

773.33us is sufficient to exchange a common control frame (e.g., a time synchronization control frame), the network terminal (end system) can communicate with other network terminals (switches) in a common control frame (e.g., And exchange them.

In one embodiment, the network terminal (end system) may split and exchange a common control frame if there is insufficient time to exchange a common control frame.

For example, the first virtual link is connected through two virtual links and the first virtual link is a direction for transmitting a frame from a network terminal (end system) to another network terminal (switch), and the second virtual link is connected to another network terminal This is the direction in which frames are transmitted to the network terminal (end system).

The maximum transmission length (Lmax) of the frame of the first virtual link is 64 bytes, the minimum transmission interval (BAG) between the frames is set to 1 ms, and the maximum transmission length (Lmax) of the frame of the second virtual link is 1518 bytes , The minimum transmission interval BAG between frames is set to 1 ms, and the time required for exchanging a common control frame (for example, a time synchronization control frame) is 500 us.

If 5.12 us is required to transmit the current frame of 64 bytes through the first virtual link, 994.88 us remains to transmit the next frame through the first virtual link. If a frame of 1518 bytes is received through the second virtual link after 400 us after transmitting the current frame and 121.55us is required to receive the frame, the network terminal (end system) It is predicted that the frame will not be transmitted or received during 473.33 us (1000us - (5.12us + 400us + 121.55us)) in the second virtual link. However, since 473.33us is not sufficient to exchange a common control frame (e.g., a time synchronization control frame), the common control frame is divided and exchanged.

For example, the network terminal (end system) transmits the first common control sub-frame of the common control frame until the minimum transmission interval for the current frame elapses, and until the minimum transmission interval for the next frame elapses, Frame of the second common control sub-frame.

In one embodiment, if the common control frame corresponds to a time synchronization control frame that controls time synchronization, the first common control sub-frame corresponds to a frame for message delay adjustment on the PTP, and the second common control sub- May correspond to a frame for message delay rebalance on the PTP.

In another embodiment, when a network terminal is connected to another network device via at least one virtual link, the network terminal generates (or prepares) a virtual link usage state map indicating at least one virtual link and a usage state of each virtual link, )can do. If at least one virtual link among the virtual links is not used based on the virtual link use state map, the network terminal can transmit the common control frame through the corresponding virtual link until the minimum transmission interval of the unused virtual link elapses .

Referring again to FIG. 2, a process of determining a master clock terminal among end points (i.e., network terminals and other network terminals) of the virtual link may be performed before step S230. The determined master clock terminal predicts an interval in which the frame is not transmitted and performs time synchronization. For example, if another network terminal is determined as a master clock terminal through a master clock terminal determination process, the other network terminal performs time synchronization.

3 is a view for explaining an example of a specific processing procedure of a synchronization method performed in the network terminal shown in FIG.

Referring to FIG. 3, the end system 120 transmits the generated first frame, and transmits the second frame after the minimum transmission interval BAG, T2 between the frames. The reception of the first frame is started to the switch 130 after the Tp (propagation time) has elapsed from the transmission of the first frame at the end system 120.

The end system 120 transmits the frame (second frame) from the time when transmission of the first frame ends to the time when the transmission of the next frame (the second frame) is started Can be predicted as an interval in which the frame is not transmitted. For example, the corresponding interval corresponds to T3 in the IDLE interval.

The end system 120 transmits a common control frame for communication with another network terminal when the time of the corresponding interval is sufficient to transmit the common control frame. In one embodiment, the end system 120 may send a time synchronization control frame implemented via the PTP (Precision Time Protocol) of IEEE 1588 or IEEE 802.1 AS to the switch 130.

For example, the time synchronization control frame according to the PTP protocol may include a Sync message, a Follow_up message, a Delay_Req message, and a Delay_Resp message.

4 is a view for explaining a time synchronization control frame according to the PTP protocol.

The end system 120 (master clock terminal) sends a frame for message delay adjustment on the PTP to the switch 130 (slave clock terminal). That is, the end system 120 (master clock terminal) transmits the first Sync message 410 to the switch 130 (slave clock terminal), and transmits the first Follow_UP message 420 after a predetermined time elapses . The first Follow_UP message 420 includes time t1 when the end system 120 (master clock terminal) transmits the first Sync message. The switch 130 (slave clock terminal) uses the time t2 at which the first Sync message 410 is received and the time t1 at which the first Sync message included in the first Follow_UP message 420 is transmitted , And calculates the first time difference (t2-t1) (delay time from the master clock terminal to the slave clock terminal). The time difference represents the offset (O, offset) of the switch 130 (slave clock terminal) and the message transmission delay time (D, Delay).

The switch 130 (slave clock terminal) adjusts the local clock by the calculated first time difference t2-t1.

After transmitting the frame for message delay adjustment, the end system 120 (master clock terminal) sends a frame for message delay rebalancing to the switch 130 (slave clock terminal) on the PTP. That is, the switch 130 (slave clock terminal) transmits a Delay_req message 430 to the end system 120 (master clock terminal).

The end system 120 (master clock terminal) sends a Delay_resp message 440 to the switch 130 (slave clock terminal). The Delay_resp message 440 includes information on the time t4 at which the end system 120 (master clock terminal) receives the Delay_req message 430. [ The switch 130 (slave clock terminal) uses the time t4 at which the end system 120 (master clock terminal) received the Delay_req message 430 and the time t3 at which the end system 120 , And a second time difference (t4-t3) (delay time from the master clock terminal to the slave clock terminal). The switch 130 (slave clock terminal) can adjust the local clock by the calculated second time difference t4 - t3.

Time synchronization between the end system 120 (master clock terminal) and the switch 130 (slave clock terminal) is possible through the above process. More precise synchronization between the end system 120 (master clock terminal) and the switch 130 (slave clock terminal) is possible when the frame transmission / reception process for message delay re-calibration is repeatedly performed.

For example, after receiving a frame for message delay rebalancing, the switch 130 (slave clock terminal) sends a Delay_Req message 450 to the end system 120 (master clock terminal). When receiving the Delay_Req message, the end system 120 (master clock terminal) transmits the time t6 at which the Delay_Req message 450 is received to the switch 130 (slave clock terminal) in the Delay_Resp message 460 do.

In one embodiment, the switch 130 (slave clock terminal) is configured to receive a bidirectional delay time (a delay time from the master clock terminal to the slave clock terminal (first time difference or second time difference), from the slave clock terminal to the master clock terminal (The third time difference)), and the local clock can be adjusted by the calculated average delay time.

5 is a view for explaining another example of a specific processing procedure of the synchronization method performed in the network terminal shown in FIG.

Fig. 5 shows an example of a case where a common control frame is divided and exchanged when a time that is not enough to exchange a common control frame remains. Referring to FIG. 5, the end system 120 determines the time at which the next frame (second frame) can be transmitted after the transmission of the first frame is terminated (the minimum transmission interval (BAG) The elapsed time) can be predicted as a period in which the frame is not transmitted. For example, the corresponding interval corresponds to T3 in the IDLE interval.

If the time of the corresponding interval is not sufficient to transmit the common control frame, the end system 120 may wait until the minimum transmission interval for the current frame (first frame) elapses before the first common control sub- Frame, and transmits the second one of the common control frames until the minimum transmission interval for the latter frame (second frame) elapses.

For example, when transmitting a time synchronization control frame according to the PTP protocol, the first common control sub-frame corresponds to a frame (first sync message and first Follow_Up message) for message delay adjustment on the PTP, The common control sub-frame may correspond to a frame (second Sync message, second Follow_Up message, Delay_Req message, and Delay_Resp message) for message delay rebalancing on the PTP.

In the case of the present invention, since the time synchronization is performed with respect to the network terminals at both ends even if the time synchronization is performed through only one virtual link among the plurality of virtual links, other virtual links can be automatically time synchronized.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the present invention as defined by the following claims It can be understood that

100: Profile Network
110: Application
120: End System
130: switch

Claims (12)

(a) connecting through a virtual link defined through a maximum transmission length of a frame with another network terminal and a minimum transmission interval between frames;
(b) transmitting a current frame via the virtual link; And
(c) if the current frame is transmitted, transmitting a common control frame for communication with the other network terminal until the minimum transmission interval elapses,
Wherein the step (c) comprises the step of transmitting the common control frame by checking whether the current minimum transmission interval is longer than a specific time period regardless of the presence or absence of a next frame before transmission of the common control frame A method of synchronizing a network terminal.
delete 2. The method of claim 1,
Wherein the time synchronization control frame corresponds to a time synchronization control frame for controlling time synchronization between the network terminal and the other network terminal.
4. The method of claim 3, wherein the time synchronization control frame
IEEE 1588 or IEEE 802.1AS Precision Time Protocol (PTP).
2. The method of claim 1, wherein step (c)
Determining a master clock terminal among the end points of the virtual link (i.e., the network terminal and the other network terminal).
6. The method of claim 5, wherein step (c)
Further comprising causing the other network terminal to perform time synchronization if the master clock terminal corresponds to the other network terminal.
2. The method of claim 1, wherein step (c)
Frame of the common control frame until the minimum transmission interval for the current frame elapses and until the minimum transmission interval for the latter frame elapses, the second common control sub- The method comprising the steps of: (a) sending a first message to the network terminal;
8. The method of claim 7,
Wherein the first common control sub-frame corresponds to a frame for message delay adjustment on the PTP and the second common control sub-frame corresponds to a frame for message delay rebalancing on the PTP. A method of synchronizing a network terminal.
2. The method of claim 1,
(d) transmitting the next frame of the current frame after the common control frame is transmitted.
delete delete A first network terminal; And
And a second network terminal connected through the virtual link defined by the maximum transmission length of the frame and the minimum transmission interval between frames of the first network terminal,
The first network terminal transmits a current frame to the second network terminal through the virtual link, and when the current frame is transmitted, until the minimum transmission interval elapses, a common control frame for communication with the second network terminal And transmits the common control frame by checking whether the current minimum transmission interval is longer than a predetermined time regardless of whether or not the next frame exists before transmission of the common control frame.

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