KR101180223B1 - Method of transceiving data packet in ring network and node terminal of ring network for the same - Google Patents

Abstract

Disclosed are a data packet transmission / reception method in a ring network and a ring network node terminal for the same. A data packet transmission method in a ring network according to the present invention includes analyzing a predetermined area of a data packet to be transmitted through a ring network and determining whether the data packet is bidirectional data; If the data packet is determined to be bidirectional data, copying the data packet to generate a copied data packet; Inserting a tag bit for distinguishing a left ring and a right ring into the data packet and the copied data packet; And transmitting the data packet into which the tag bit is inserted and the copied data packet in both the left and right ring directions. Therefore, stable data transmission is possible in a power system that places importance on reliability.

Description

Method of transceiving data packet in ring network and node terminal of ring network for the same

The present invention relates to a network related technology constituting a redundant network as a management scheme for coping with network failures and performance degradation in a ring network environment.

A ring network is a network where every node must have two branches and there must be two paths between any two nodes.

In a ring network composed of a redundant ring, the communication network operates stably in the event of an accident of the circuit to provide users with uninterrupted service and to maximize the efficiency of the network.

Among the management measures for this purpose, in particular, the management measures to secure survivability can be classified into protection switching and restoration. Protection switching is a method to set up the necessary path and bandwidth between nodes in order to be able to recover quickly in case of network failure. How to restore the original state.

More specifically, the protection switching technology has been mainly applied to optical transmission equipment such as Synchronous Digital Hierarchy (SDH) or Synchronous Optical Network (SONET). Recently, Ethernet-based protection switching technologies such as IEEE 802.17 RPR technology and ITU.T G.8032 have been developed to apply to the Ethernet environment.

1 is a diagram illustrating a protection switching technique for securing survivability in a dual ring network environment according to the prior art.

Referring to FIG. 1, it can be seen that the network environment has a double ring structure including a left ring indicated by a dotted line and a right ring indicated by a solid line.

In this case, the left ring may be a ring for transmitting data to the left, and the right ring may be a ring for transmitting data to the right.

In the network environment shown in FIG. 1, data transmission is generally performed using a left ring (or right ring), and in case of an accident, data transmission can be secured by using a right ring (or left ring) to secure network viability. have.

However, when a circuit accident occurs, it takes a certain time (typically about 50 ms) while performing an operation for recovery such as packet transmission, detour path setting, and notification to a neighboring terminal for line accident recognition and protection switching. There is a problem that data being transmitted through the ring network may be lost during operation.

On the other hand, as the importance of power facilities has recently increased, important data among power data should be delivered within 3ms from a source to a destination. In addition, the loss of important data can cause big problems, so it is very important to reliably transmit important data to the destination without being lost in the middle.

Considering the characteristics of the power network technology, where reliability is important, in case of building a power network using the conventional protection switching technology, data lost during the time when the protection switching is performed may be important data of the power equipment. There is a serious problem that the reliability of the power system can be compromised.

In fact, KEPCO has established and operated a distribution automation system by applying the conventional protection switching technology, but it is impossible to know when data loss will occur due to a network accident, and the lost data may be important data. The need for network construction is urgently needed.

An object of the present invention for solving the above problems is to prevent packet loss during the protection switching and recovery period used to ensure network viability in a ring network.

In addition, an object of the present invention is to build a more stable power network by transmitting an important packet that should not be lost in accordance with the importance or characteristics of the data packet in both directions.

A data packet transmission method in a ring network according to the present invention for achieving the above object, the packet processing module of a ring network node terminal, by analyzing a predetermined area of the data packet to be transmitted through the ring network to the data Determining whether the packet is bidirectional data; If the data packet is determined to be bidirectional data, copying the data packet to generate a copied data packet; Inserting a tag bit for distinguishing a left ring and a right ring into the data packet and the copied data packet; And transmitting the data packet into which the tag bit is inserted and the copied data packet in both the left and right ring directions.

In this case, the determining of whether the data is the bidirectional data may determine whether the data is the bidirectional data in consideration of at least one of the importance and characteristics of the data packet.

In this case, the determining of the bidirectional data may include setting a priority in consideration of at least one of importance and characteristics of the data packet; And determining the bidirectional data when the priority is higher than or equal to a predetermined level, and determining the unidirectional data when the priority is lower than a predetermined level.

In this case, the determining of whether the data is the bidirectional data may determine whether the data is the bidirectional data by analyzing an Ethertype field of an Ethernet frame.

In this case, the step of determining whether the data is the bidirectional data is determined as the bidirectional data if the ether type field has a value corresponding to the sampled value data or goose data, and the ether type field is If it has a value corresponding to the MMS data can be determined as unidirectional data.

In addition, the data packet reception method in a ring network according to another embodiment of the present invention, the packet processing module of the ring network node terminal, receiving a data packet transmitted through the ring network from the optical Ethernet converter; Determining whether the data packet is a data packet sent to the node terminal; If the data packet is a data packet sent to the node terminal, determining whether the data packet is a bidirectional data packet transmitted in both left and right ring directions; And when the data packet is determined to be the bidirectional data packet, performing a reception process corresponding to the data packet.

In this case, the performing of the receiving process may include deleting a tag bit for distinguishing the left ring and the right ring from the data packet received through one of the left ring and the right ring. It can be delivered to the signal processing module of the terminal.

In this case, the performing of the receiving process may include comparing the data packet received through the left ring and the data packet received through the right ring.

At this time, the step of performing the reception process may delete the data packet received through the other of the guilt ring and the right ring.

In this case, the determining of whether the data packet is the bidirectional data packet may be determined by analyzing a predetermined area of the data packet according to the importance or characteristic of the recognized data packet.

In addition, the ring network node terminal according to another embodiment of the present invention, if it is determined that the data packet is a bidirectional data packet as a result of analyzing a predetermined region of the data packet to be transmitted through the ring network, copying the data packet A packet converter for generating a copied data packet and inserting a tag bit for distinguishing a left ring and a right ring into the data packet and the copied data packet; And an optical Ethernet conversion for transmitting the data packet in both the left and right rings when the data packet provided from the packet converter is a bidirectional data packet, and in one of the left and right rings when the data packet is not a bidirectional data packet. Contains wealth.

At this time, the ring network node terminal includes a packet transmission and reception processing unit for receiving a data packet transmitted from the optical Ethernet conversion unit; A packet analyzer which determines whether the transmitted data packet is sent to the node terminal and whether the transmitted data packet is a bidirectional data packet transmitted in both the left and right ring directions; And when the transmitted data packet is not sent to the node terminal, transfer the data packet to the optical Ethernet converter, and when the data packet is a unidirectional data packet sent to the node terminal, transmit the data packet to a signal processing module. The data packet may further include a packet control / management unit that performs bidirectional data packet processing when the data packet is a bidirectional data packet sent to the node terminal.

At this time, if the data packet is a bidirectional data packet sent to the node terminal, the packet control / manger may transmit only one of the data packets received through the left ring and the right ring to the signal processing module.

At this time, if the data packet is a bidirectional data packet sent to the node terminal, the packet control / management unit may compare the data packet received through the left ring and the right ring to determine whether the same.

In this case, the packet converter may determine whether the data packet is the bidirectional data packet according to the importance or characteristics of the recognized data packet by analyzing a predetermined area of the data packet.

According to the present invention, lossless transmission of data packets is possible by preventing packet loss during a protection switching and recovery period used for securing network viability in a ring network.

In addition, the present invention is to set the priority according to the importance or characteristics of the data packet, such as power data, and to transmit data in both directions in the case of high priority data and in one direction in the case of low priority data efficiently discriminating data By performing the transmission, it is possible to build a reliable power network.

1 is a diagram illustrating a protection switching technique for securing survivability in a dual ring network environment according to the prior art.
2 is a block diagram illustrating a ring network node terminal according to an embodiment of the present invention.
3 is a block diagram illustrating an example of the packet processing module illustrated in FIG. 2.
4 is an operation flowchart illustrating an example of an operation of a ring network node terminal in transmitting data.
5 is an operation flowchart illustrating an example of an operation of a ring network node terminal when receiving data.
6 illustrates data packet transmission / reception in a ring network according to an embodiment of the present invention.

The present invention will now be described in detail with reference to the accompanying drawings. Hereinafter, a repeated description, a known function that may obscure the gist of the present invention, and a detailed description of the configuration will be omitted. Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shape and size of elements in the drawings may be exaggerated for clarity.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram illustrating a ring network node terminal according to an embodiment of the present invention.

2, a ring network node terminal according to an embodiment of the present invention includes an optical Ethernet converter 210, a packet processing module 220, a signal processing module 230, and a management processor 240.

Although not shown in FIG. 2, the ring network node terminal may further include an Ethernet switch unit, a memory, and an expansion interface.

Data to be transmitted through the ring network may be delivered to the terminal through the Ethernet switch unit or expansion interface not shown in FIG. The transmitted data performs the processing and modification of the packet to be delivered to the ring network according to the importance of the packet in the signal processing module 230, the processed data is delivered to the packet processing module 220.

The packet processing module 220 determines whether to transmit data in one direction or two directions according to the importance of the packet, and transmits the transmitted data only in a predetermined direction when transmitting in one direction, and copies the transmitted packet when transmitting in both directions. To pass in both directions.

In addition, the ring network node terminal shown in Figure 2 checks the problems of the circuit and equipment in real time. If a problem occurs, the signal processing module 230 of the ring network node terminal generates a protection switching packet and transmits it to the packet processing module 220 to perform the protection switching function.

The management processor 240 may control an operation of each module, check a current state, and perform a management operation required for each module to perform a necessary operation, and data corresponding to an execution result may be stored in a memory.

The optical Ethernet converter 210 receives the data packet from the packet processing module 220 and performs optical Ethernet conversion to transmit to the ring network or to generate a data packet using a signal received from the ring network to process the packet processing module 220. ) As will be described in detail below, the optical Ethernet converter 210 consequently transmits the data packet to both the left and right ring rings of the ring network when the data packet provided from the packet processing module 220 is a bidirectional data packet. If it is not a bidirectional data packet, it may be transmitted in one of the left ring and the right ring.

3 is a block diagram illustrating an example of the packet processing module illustrated in FIG. 2.

Referring to FIG. 3, the packet processing module includes a packet transmission / reception processing unit 310, a packet analysis unit 320, a packet control / management unit 330, and a packet conversion unit 340.

When the packet converter 340 analyzes a predetermined area of a data packet to be transmitted through a ring network and determines that the data packet is a bidirectional data packet, the packet converter 340 generates a copied data packet by copying the data packet. A tag bit for inserting a left ring and a right ring is inserted into the data packet and the copied data packet.

In this case, the packet converter 340 may analyze the predetermined area of the data packet and determine whether the packet is the bidirectional data packet according to the importance or characteristic of the recognized data packet.

The packet transmission / reception processor 310 may receive a data packet transmitted from the optical Ethernet converter 210.

The packet analyzer 320 may determine whether the transmitted data packet is sent to the node terminal and whether the transmitted data packet is a bidirectional data packet transmitted in both the left ring and the right ring. That is, the packet analyzer 320 checks the validity of the received packet and determines whether the packet corresponds to a corresponding terminal or a packet to be re-delivered to an adjacent terminal. In addition, when the received packet is a packet corresponding to the terminal, the packet analyzer 320 may determine whether the data is transmitted in both directions for the packet lossless transmission or the data is transmitted only in one direction.

The packet control / management unit 330 transmits the data packet to the optical Ethernet converter when the transmitted data packet is not sent to the node terminal, and the data packet when the data packet is a unidirectional data packet sent to the node terminal. The packet may be transmitted to the signal processing module, and the bidirectional data packet processing may be performed when the data packet is a bidirectional data packet sent to the node terminal.

At this time, if the data packet is a bidirectional data packet sent to the node terminal, the packet control / management unit 330 may transmit only one of the data packets received through the left ring and the right ring to the signal processing module. In this case, the packet control / management unit 330 may transfer only the data packet received first to the signal processing module.

In addition, if the data packet is a bidirectional data packet sent to the terminal, the packet control / management unit 330 may compare the data packet received through the left ring and the right ring to determine whether the same.

The data packet transmitted / received through the ring network may include an identifier that distinguishes a data type to distinguish bidirectional data and unidirectional data. If the identifier is analyzed, the packet processing module of the terminal can easily distinguish whether the corresponding data is bidirectional data or unidirectional data.

In addition, in the case of bidirectional data, a tag bit may be included in the data packet to distinguish data received through the left ring and data received through the right ring. In this case, the tag bit does not only indicate a field consisting of 1 bit, but the bit or byte configuration may vary as long as it indicates whether the data is received through the left ring or the data received through the right ring.

That is, the signal processing module may insert an identifier that distinguishes the data type to inform the packet processing module whether it is bidirectional data or unidirectional data. In the case of unidirectional data, the packet processing module transmits data directly to the optical Ethernet converter by using a packet transmission / reception processing function. In the case of bidirectional data, the packet processing module copies and receives the received packet from the signal processing module in both directions. Tag bits are inserted into the copied packets to distinguish whether they are sent to the left ring or the right ring, and are transmitted in both directions through the optical Ethernet converter.

4 is an operation flowchart illustrating an example of an operation of a ring network node terminal in transmitting data.

Referring to FIG. 4, first, a packet processing module of a ring network node terminal receives a data packet to be transmitted through a ring network from a signal processing module (S410).

In addition, the packet processing module of the ring network node terminal analyzes a predetermined area of the received data packet to determine whether the data packet is bidirectional data (S420).

That is, the packet processing module of the ring network node terminal determines whether the received data is important data to apply bidirectional transmission.

In this case, step S420 may determine whether the bidirectional data in consideration of one or more of the importance and characteristics of the data packet.

In this case, the step S420 may include setting a priority in consideration of at least one of importance and characteristics of the data packet, and determining the data packet as the bidirectional data when the priority is higher than or equal to a predetermined level. If the rank is less than the predetermined level may include determining the one-way data.

In operation S420, the Ethernet type field of the Ethernet frame may be analyzed to determine whether the data is bidirectional data.

In step S420, if the Ethertype field has a value corresponding to sampled value data or Goose data, the S2 type data is determined to be bidirectional data, and the Ethertype field corresponds to MMS data. It can be determined as one-way data when the value is

If it is determined in step S420 that the data is important data and needs to be transmitted in both directions, the packet processing module of the ring network node terminal copies the data packet to generate a copied data packet, and the data packet and the copied data packet. A tag bit is inserted into the data packet to distinguish the left ring and the right ring (S430).

In addition, the packet processing module of the ring network node terminal transmits the data packet to the packet transmission and reception processing unit (S440), and transmits the data packet to the ring network through the optical Ethernet conversion unit (S450).

That is, the data packet into which the tag bit is inserted and the copied data packet are transmitted in both the left ring and the right ring.

If it is determined in step S420 that the data is not important data and not to be transmitted in both directions, the packet processing module of the ring network node terminal proceeds to step S440 such that the data packet is transmitted to the packet transmission / reception processor. do.

5 is an operation flowchart illustrating an example of an operation of a ring network node terminal when receiving data.

Referring to FIG. 5, first, a packet processing module of a ring network node terminal receives a data packet transmitted through a ring network from an optical Ethernet converter (S510).

In addition, the packet processing module of the ring network node terminal determines whether the received data packet is a data packet sent to the node terminal (S520).

If it is determined in step S520 that the received data packet is a data packet sent to the node terminal, the packet processing module of the ring network node terminal determines whether the data packet is a bidirectional data packet transmitted in both left and right ring directions. Determine (S540).

In this case, step S540 may determine whether the data packet is the bidirectional data packet according to the importance or characteristic of the recognized data packet by analyzing a predetermined area of the data packet.

If it is determined in step S520 that the received data packet is not a data packet sent to the node terminal, the packet processing module of the ring network node terminal transfers the data packet to the optical Ethernet converter (S530).

If it is determined in step S540 that the data packet is a bidirectional data packet, the packet processing module of the ring network node terminal performs reception processing corresponding to the data packet (S560, S570, S580, S590).

That is, when the data packet determines the bidirectional data packet, the packet processing module of the ring network node terminal determines whether the data packet is the first received packet (S560).

If it is determined in step S560 that the data packet is the first received packet, the packet processing module of the ring network node terminal deletes a tag bit for distinguishing the left ring and the right ring from the data packet and stores the memory. Store in (S580). In addition, the packet processing module of the ring network node terminal transfers the data packet from which the tag bit is deleted (S590).

If it is determined in step S560 that the data packet is the second received packet, the packet processing module of the ring network node terminal discards the data packet (S570).

If it is determined in step S540 that the data packet is not a bidirectional data packet, the packet processing module of the ring network node terminal transfers the received data packet to the signal processing module (S550).

That is, when the packet processing module of the ring network node terminal performs the reception process for the bidirectional data packet, tag bits for distinguishing the left ring and the right ring from the data packet received through either the left ring or the right ring The tag bit may be deleted and transmitted to the signal processing module of the ring network node terminal. At this time, the signal processing module of the node terminal may delete the data packet received through any one of the left ring and the right ring.

According to an embodiment, the packet processing module of the ring network node terminal may compare the data packet received through the left ring and the data packet received through the right ring when performing a reception process on a bidirectional data packet.

The ring network node terminal and its operation for lossless delivery of data packets and effective data discrimination service described above may be applied to a smart distribution system.

The data of the smart power distribution system is composed of sampled value data, Goose data, and MMS data having non real-time characteristics. When the data is to be transmitted through the ring network, each generated data may be classified using an Ethertype value, and may be delivered to the packet processing module through the signal processing module.

The packet processing module checks the Ethertype value of the received data, copies the received packet in case of data requiring real-time, and checks the left and right rings of the original and copied packets. tag bit) and insert in both directions. When the received data is a packet requiring non-real time, the packet processing module delivers data using only one of the left ring and the right ring.

6 illustrates data packet transmission / reception in a ring network according to an embodiment of the present invention.

Referring to FIG. 6, data packets transmitted / received through a ring network are classified into important ones (Service 1 and Service 3) and insignificant ones (Service 2) according to their service types.

The data transmission / reception method through the ring network according to the present invention transmits / receives data in both directions by using the left and right rings of the ring network together for important data, and the left ring of the ring network (for less important data). Or right ring) to send / receive data.

Recently, power facilities require a differential service for transmission, lossless, and various power information within 3ms between terminals. The present invention selectively supports bidirectional transmission and unidirectional transmission according to the characteristics of data, thereby providing transmission and lossless transmission within 3ms for important data. In addition, the present invention can provide the best service through the one-way transmission for the data of low importance and can effectively control the traffic load of the network, thereby enabling a stable power service.

The present invention can be applied to a power system that provides a power service based on a dual ring network, and in particular, can be applied to distribution automation, power distribution, smart distribution, digital transformation system and the like.

As described above, the data packet transmission / reception method and the ring network terminal in the ring network according to the present invention are not limited to the configuration and method of the embodiments described as described above, but the embodiments are various modifications. All or some of the embodiments may be selectively combined in order to accomplish this.

210: optical Ethernet converter
220: packet processing module
230: signal processing module
240: management processor
310: packet transmission and reception processing unit
320: packet analysis unit
330: packet control / management unit
340: packet conversion unit

Claims (15)

The packet processing module of the ring network node terminal,
Analyzing a predetermined area of a data packet to be transmitted through the ring network and determining whether the data packet is bidirectional data;
If the data packet is determined to be bidirectional data, copying the data packet to generate a copied data packet;
Inserting a tag bit for distinguishing a left ring and a right ring into the data packet and the copied data packet; And
Transmitting the data packet into which the tag bit is inserted and the copied data packet in both the left and right ring directions;
Determining whether or not the bidirectional data is
And determining whether the data is bidirectional in consideration of at least one of importance and characteristics of the data packet. delete The method according to claim 1,
Determining whether or not the bidirectional data is
Setting priorities in consideration of at least one of importance and characteristics of the data packet; And
Determining the data packet as the bidirectional data when the priority is greater than or equal to a predetermined level, and determining the unidirectional data when the priority is less than a predetermined level.
Method of transmitting a data packet in a ring network comprising a. The method according to claim 1,
Determining whether or not the bidirectional data is
A method of transmitting a data packet in a ring network, characterized in that it is determined whether the data is bidirectional data by analyzing an Ethertype field of an Ethernet frame. The method of claim 4,
Determining whether or not the bidirectional data is
If the ether type field has a value corresponding to sampled value data or goose data, it is determined as the bidirectional data, and if the ether type field has a value corresponding to MMS data, it is unidirectional. A data packet transmission method in a ring network, characterized in that determined by data. The packet processing module of the ring network node terminal,
Receiving a data packet transmitted through the ring network from an optical Ethernet converter;
Determining whether the data packet is a data packet sent to the node terminal;
If the data packet is a data packet sent to the node terminal, determining whether the data packet is a bidirectional data packet transmitted in both left and right ring directions; And
If it is determined that the data packet is the bidirectional data packet, performing a reception process corresponding to the data packet;
Determining whether or not the bidirectional data packet is
And analyzing the predetermined area of the data packet to determine whether the data packet is the bidirectional data packet according to the recognized importance or characteristic of the data packet. The method of claim 6,
The step of performing the reception process is
A tag bit for distinguishing the left ring and the right ring is deleted from the data packet received through one of the left ring and the right ring, and transmitted to a signal processing module of the ring network node terminal. A method of receiving data packets in a ring network. Claim 6
The step of performing the reception process is
And comparing the data packet received through the left ring and the data packet received through the right ring. Claim 7
The step of performing the reception process is
And deleting the data packet received through the other one of the left ring and the right ring. delete After analyzing a predetermined area of a data packet to be transmitted through a ring network, if the data packet is determined to be a bidirectional data packet, the data packet is copied to generate a copied data packet, and the data packet and the copied data are generated. A packet converter which inserts a tag bit for distinguishing a left ring and a right ring into a packet; And
If the data packet provided from the packet converter is a bidirectional data packet, the optical Ethernet converter for transmitting the data packet in both the left and right ring, and if not the bidirectional data packet to one of the left and right ring. Including,
The packet converter
And analyzing the predetermined area of the data packet to determine whether the data packet is the bidirectional data packet according to the recognized importance or characteristic of the data packet. The method according to claim 11
The ring network node terminal
A packet transmission / reception processor for receiving a data packet transmitted from the optical Ethernet converter;
A packet analyzer which determines whether the transmitted data packet is sent to the node terminal and whether the transmitted data packet is a bidirectional data packet transmitted in both the left and right ring directions; And
If the transmitted data packet is not sent to the node terminal, the data packet is transferred to the optical Ethernet converter, and if the data packet is a unidirectional data packet sent to the node terminal, the data packet is transmitted to a signal processing module. And a packet control / management unit that performs bidirectional data packet processing when the data packet is a bidirectional data packet sent to the node terminal.
Ring network node terminal further comprises. The method according to claim 12
The packet control / management unit
And if the data packet is a bidirectional data packet sent to the node terminal, only one of the data packets received through the left ring and the right ring is transmitted to the signal processing module. The method according to claim 12
The packet control / management unit
And if the data packet is a bidirectional data packet sent to the node terminal, comparing the data packet received through the left ring and the right ring to determine whether the data packet is the same. delete

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