JP5388363B2 - Communications system - Google Patents

Description

  The present invention relates to a technique for transferring transmission data in a communication network connected in a ring.

In TCP (Transmission Control Protocol) communication, as shown in FIG. 15, when the transmission data transmitted by the communication terminal 1100-1 on the transmission side reaches the communication terminal 1100-2 on the reception side, the communication terminal 1100-2 A reception confirmation signal (ACK signal) indicating that the transmission data has been received is transmitted to communication terminal 1100-1. The communication terminal 1100-1 can transmit the transmission data in order while confirming the arrival of the transmission data by the ACK signal transmitted from the communication terminal 1100-2.
FIG. 16 is a diagram illustrating an example of a communication network that performs TCP communication based on a bus topology combined with a ring network. In this communication network, a communication terminal 1100-A1 and a communication terminal 1100-A2 at a site A and a communication terminal 1100-B1 and a communication terminal 1100-B2 at a site B are connected via a plurality of L2 (Layer 2) switches. Communicating with the user divided clockwise and counterclockwise according to the setting of the blocking port. Here, the L2 switch performs routing using an FDB (Forwarding DataBase).

  Patent Document 1 describes a technique for rewriting the FDB routing information of each transfer device so that data is transferred avoiding a failure section when a failure occurs in a ring topology communication network. Patent Document 2 describes a technique that enables unicasting of relearned routing information by managing the registration time for each FDB routing information, and shortening the time during which the bandwidth is compressed by broadcasting. ing.

JP 2006-270169 A JP 2008-148176 A

  However, in such a ring topology communication network, there may be a difference in the transmission distance of the communication path between the clockwise direction and the counterclockwise direction due to the use efficiency of facilities and geographical restrictions on the route. For example, in the above-mentioned figure, when transmitting transmission data from the base A to the base B, the clockwise direction is a long distance and the counterclockwise direction is a short distance. For this reason, the communication between the communication terminal 1100-A1 and the communication terminal 1100-B1 using the clockwise communication path is delayed as compared with the communication between the communication terminal 1100-A2 and the communication terminal 1100-B2. In particular, it is considered that there is a difference in communication quality in a WAN (Wide Area Network) that transfers transmission data via a large number of L2 switches. Therefore, it is desirable to improve the throughput of a route having a low communication quality without affecting the route having a high communication quality as much as possible, and to suppress a variation in the communication quality between clockwise and counterclockwise in the ring topology.

  The present invention has been made in view of such a situation, and provides a communication system that improves the transfer throughput of transmission data in a communication network connected in a ring.

In order to solve the above-described problem, the present invention provides a plurality of transfer apparatuses that receive and transfer transmission data in a communication network that is connected in a ring, and the transmission data is transmitted via the communication network among the plurality of transfer apparatuses. A plurality of site transfer devices that are transfer devices connected to communication terminals that transmit and receive, and a first path by a plurality of transfer devices that connect the plurality of site transfer devices in a predetermined direction in a ring-shaped communication network; The communication system includes a second path that connects a plurality of site transfer apparatuses by a path in a direction opposite to the first path. When the site transfer apparatus receives transmission data from a communication terminal, the transmission data There it is determined whether the acknowledgment signal a predetermined, when it is determined that the an acknowledgment signal, the transmission data, reverse route information indicating that the transmit data through the second path The When the transmission confirmation signal determination unit to be added and the reception confirmation signal determination unit determine that the transmission data is not the reception confirmation signal, the transmission data is transferred to the first path, and the transmission data is the reception confirmation signal. A transmission unit configured to transfer transmission data to the second route when the determination is made, the transfer device includes a first routing table in which routing information in the first route is stored, and a second route A routing table storage unit that stores a second routing table in which routing information is stored, a reverse path information determination unit that determines whether or not reverse path information is included in received transmission data, and reverse path information When the determination unit determines that the reverse route information is not included in the transmission data, the transmission data is transferred with reference to the first routing table, and the transmission data is reversed. If it is determined to contain a road information, characterized in that it comprises a communication control unit for transferring the reference to the transmission data of the second routing table, the.

  In the present invention, the first routing table and the second routing table stored in the routing table storage unit are FDBs (forwarding databases) determined according to the transmission source of the transmission data to be received, and the transfer device Includes an FDB registration unit that stores routing information in the FDB according to a transmission source of transmission data to be received.

  Further, the present invention is characterized in that the first route connects a plurality of site transfer devices at a longer distance, and the second route connects the plurality of site transfer devices at a shorter distance.

  In the present invention, the first route connects a plurality of site transfer devices at a shorter distance, the second route connects a plurality of site transfer devices at a longer distance, and the site transfer device is connected to a communication network. A communication status storage unit that stores information indicating the communication status, and a communication status determination unit that compares the communication status with a predetermined threshold and determines whether or not the communication network is in a congested state, The reception confirmation signal determination unit of the base transfer device determines that the received transmission data is a reception confirmation signal, and if the communication status determination unit determines that the communication network is in a congested state, a reverse path to the transmission data It is characterized by adding information.

  As described above, according to the present invention, when the base transfer device in the communication network connected in a ring determines that the transmission data received from the communication terminal is the reception confirmation signal, the transmission data is added to the transmission data. When reverse path information indicating transfer through the second path is added and transferred to the second path and it is determined that the signal is a reception confirmation signal, the transfer is performed to the first path and transferred. The apparatus stores the first routing table in the first route and the second routing table in the second route, and refers to the second routing table when the received transmission data includes reverse route information. When the transmission data is transferred and the reverse path information is not included, the transmission data is transferred with reference to the first routing table. It becomes possible to improve the transfer throughput of data.

It is a figure which shows the structure of the communication system by one Embodiment of this invention. It is a block diagram which shows the structure of the computer with which the communication system by one Embodiment of this invention is provided. It is a figure which shows the data example of FDB memorize | stored in the routing memory | storage part by one Embodiment of this invention. It is a figure explaining the learning operation | movement of FDB by one Embodiment of this invention. It is a figure explaining the operation | movement by which transmission data is transferred by one Embodiment of this invention. It is a figure which shows the example of the transmission data which the reception confirmation signal determination part by one Embodiment of this invention adds reverse path information. It is a flowchart which shows the operation example which the base transfer apparatus by one Embodiment of this invention transfers the transmission data transmitted from a communication terminal. It is a flowchart which shows the operation example which the transfer apparatus by one Embodiment of this invention transfers the transmitted transmission data. It is a figure which shows the example which the transmission terminal by one Embodiment of this invention transmits transmission data by a normal path | route. It is a figure which shows the example which the communication terminal by one Embodiment of this invention transmits an ACK signal by a reverse path | route. It is a figure which shows the example which the communication terminal by one Embodiment of this invention transmits an ACK signal in a normal path | route. It is a figure which shows the example which the transmission terminal by one Embodiment of this invention transmits transmission data by a reverse path | route. It is a figure which shows the example of the transmission data which the reception confirmation signal determination part by one Embodiment of this invention adds reverse path information. It is a block diagram which shows the structure of the computer with which the communication system by one Embodiment of this invention is provided. It is a figure which shows the sequence of TCP communication. It is a figure which shows the structure of the communication system by a prior art.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of a communication system 1 according to the present embodiment. The communication system 1 includes a plurality of transfer devices 300-N (transfer devices 300-1, transfer devices 300-2,...) That receive and transfer transmission data in a communication network connected in a ring, and ring communication. A plurality of site transfer devices 200-N (site transfer devices 200-1) that are transfer devices connected to communication terminals 100-N (communication terminals 100-1 and 100-2) that transmit and receive transmission data via the network. And a base transfer device 200-2). Since the plurality of transfer devices 300-N have the same configuration, the transfer device 300 will be described when it is not necessary to distinguish between them. Similarly, a plurality of communication terminals 100-N will be described as communication terminals 100, and a plurality of site transfer devices 200-N will be described as site transfer devices 200. Here, two communication terminals 100, two base transfer devices 200, and six transfer devices 300 are illustrated and described. However, the communication system 1 may include more computer devices than illustrated. .

  The communication system 1 is a communication network that performs TCP communication based on a bus topology combined with a ring network. The communication system 1 performs communication based on a VLAN frame format defined in IEEE 802.1Q. Here, a normal path that connects the base transfer apparatus 200-1 and the base transfer apparatus 200-2 clockwise by a plurality of transfer apparatuses 300, and the base transfer apparatus 200-1 by a path opposite to the normal path. A reverse path connecting the base transfer device 200-2 in the counterclockwise direction is configured. The normal route connects the base transfer device 200-1 and the base transfer device 200-2 at a longer distance than the reverse route, and the reverse route connects the base transfer device 200-1 and the base transfer device 200-2 from the normal route. Connect to a short distance. Such a route is designed and determined according to the use efficiency of facilities, geographical restrictions on the route, and the like.

FIG. 2 is a block diagram illustrating configurations of the communication terminal 100, the base transfer device 200, and the transfer device 300 included in the communication system 1.
The communication terminal 100 is a computer device that transmits and receives transmission data via a communication network constituted by a plurality of site transfer devices 200 and transfer devices 300. In the present embodiment, description will be made assuming that communication terminal 100-1 in FIG. 1 is a transmission side that transmits transmission data, and communication terminal 100-2 is a reception side that receives transmission data. That is, the communication terminal 100-1 transmits transmission data, the communication terminal 100-2 receives the transmitted transmission data, and the communication terminal 100-2 receives an acknowledgment signal (ACK signal) indicating that the transmission data has been received. ) Is generated and transmitted to the communication terminal 100-1.

The site transfer device 200 is a transfer device connected to the communication terminal 100, and includes a transmission / reception unit 210, a routing storage unit 220, an FDB registration unit 230, a reception confirmation signal determination unit 240, and a reverse path information determination unit 250. The communication control unit 260 is provided. Although the configuration of the transfer device 300 will be described later, the configuration is the same as that of the site transfer device 200 except that the reception confirmation signal determination unit 240 included in the site transfer device 200 is not provided.
The transmission / reception unit 210 transmits / receives transmission data to / from a computer device such as the communication terminal 100 or the transfer device 300. The transmission / reception unit 210 includes a first port 211, a second port 212, and a third port 213. These ports are interfaces for inputting and outputting transmission data, and are connected to different computer devices via communication lines.

  The routing storage unit 220 stores a first routing table in which routing information in a normal route is stored, and a second routing table in which routing information in a reverse route is stored. Here, the first routing table and the second routing table are FDB (forwarding database) determined according to the transmission source of the transmission data to be received (first FDB, second FDB). FIG. 3 is a diagram illustrating an example of FDB data stored in the routing storage unit 220. In the FDB, a port number and a MAC (Media Access Control) address of the communication terminal 100 connected via the port indicated by the port number are stored in association with each other.

  Returning to FIG. 2, the FDB registration unit 230 stores the routing information in the FDB stored in the routing storage unit 220 according to the transmission source of the received transmission data. Here, the learning operation of the FDB will be described with reference to the drawings. FIG. 4 is a diagram illustrating an FDB learning operation when transmission data is transferred from communication terminal 100-1 to communication terminal 100-2. Here, the MAC address of the communication terminal 100-1 installed at the site A is A, and the MAC address of the communication terminal 100-2 installed at the site B is B. The communication terminal 100-1 transmits transmission data whose destination is the MAC address “B” indicating the communication terminal 100-2 at the site B (step S101). Upon receiving the transmission data transmitted from the communication terminal 100-1, the site transfer apparatus 200-1 connected to the communication terminal 100-1 via the port having the port number “1” receives the received port number “1”. Then, “A”, which is the MAC address of the transmission source of the transmission data, is associated and stored in the routing storage unit 220 (step S102).

  At this point, the base transfer device 200-1 does not store the port number corresponding to the MAC address “B” that is the destination of the transmission data in the routing storage unit 220. Therefore, the base number “2” and the port number “3” The transmission data is transmitted from the port “” (step S103). The operation of transmitting from all ports other than the port that received the transmission data when the destination port number is not found is called flooding. The transfer device 300-1 that has received the transmission data transmitted from the base transfer device 200-1 associates the port number “1” that has received the transmission data with “A” that is the MAC address of the transmission data source. In addition, it is stored in the routing storage unit 320 (step S104).

  On the other hand, when receiving the transmission data, the site transfer apparatus 200-2 that has received the transmission data transmitted from the site transfer apparatus 200-1 receives the received port number “1” and the MAC address of the transmission data transmission source. “A” is associated and stored in the routing storage unit 220 (step S105). The site transfer device 200-2 transmits the transmission data from the port having the port number “2” and the port number “3” (step S106). The transfer device 300-2 that has received the transmission data transmitted from the site transfer device 200-2 associates the port number “1” that has received the transmission data with “A” that is the MAC address of the transmission data source. Then, it is stored in the routing storage unit 320 (step S107). On the other hand, the communication terminal 100-2 receives the transmission data transmitted from the port number “3” of the site transfer device 200-2 (step S108). In this way, the transmission data reaches the communication terminal 100-2. With such an operation, a learning operation is performed in which routing information is stored in the FDBs of the transfer devices 300 and the base transfer device 200 in the communication network.

  FIG. 5 is a diagram illustrating an operation in which transmission data is transferred from the communication terminal 100-2 to the communication terminal 100-1 based on the FDB learned in this way and storing the routing information. The communication terminal 100-2 transmits transmission data destined for the MAC address “A” indicating the communication terminal 100-1 (step S110). The site transfer device 200-2 performs a learning operation in which the port number “3” that has received the transmission data and “B” that is the MAC address of the transmission data are associated with each other and stored in the routing storage unit 220. Further, the site transfer device 200-2 refers to the routing storage unit 220 and reads the routing information corresponding to the MAC address “A” that is the destination of the transmission data (step S111). Here, since the routing information corresponding to the MAC address “A” is already stored in the routing storage unit 220, the base transfer device 200-2 transmits the transmission data from the port number “1” corresponding to the MAC address “A”. Send. Here, flooding of transmission data does not occur. Similarly, site transfer apparatus 200-1 receives transmission data transmitted from site transfer apparatus 200-2, learns routing information corresponding to the MAC address of communication terminal 100-2, and corresponds to MAC address “A”. The routing information to be read is read from the routing storage unit 220 and the transmission data is transmitted from the port number “1”. Thereby, transmission data reaches | attains the communication terminal 100-1 without flooding (step S113).

  Returning to FIG. 2, when receiving the transmission data transmitted from the communication terminal 100, the reception confirmation signal determination unit 240 determines whether the received transmission data is a predetermined ACK signal, and is an ACK signal. If it is determined, reverse path information indicating that the transmission data is transferred via the reverse path is added to the transmission data. FIG. 6 is a diagram illustrating an example of transmission data to which the reception confirmation signal determination unit 240 adds reverse path information. FIG. 6A is a diagram illustrating an example of transmission data generated based on the VLAN frame format defined in the IEEE 802.1Q described above. The VLAN frame includes a destination MAC address (DA: 48 bits (6 bytes)), a transmission source MAC address (SA: 48 bits (6 bytes)), and a service identification tag (S-TAG: 32 bits (4 bytes)). ), Data (DATA: 48 to 1502 bytes), and FCS (Frame Check Sequence) (4 bytes) which is frame error check data. For example, a CRC (Cyclic Redundancy Checking) code can be applied to the FCS. The reception confirmation signal determination unit 240 reads the DATA portion included in the received transmission data, and determines whether or not the DATA portion is an ACK signal. When the reception confirmation signal determination unit 240 determines that the DATA part is an ACK signal, reverse path information (R-TAG: 32 bits (4 bytes)) as shown in FIG. 6B is added. . When the reception confirmation signal determination unit 240 determines that the DATA part is not an ACK signal, the reception confirmation signal determination unit 240 does not add the reverse path information.

Returning to FIG. 2, the reverse path information determination unit 250 determines whether reverse path information is included in the received transmission data.
When the reverse path information determination unit 250 determines that the reverse path information is not included in the transmission data, the communication control unit 260 refers to the first FDB, and transmits the transmission data via the transmission / reception unit 210 using the corresponding port. When it is determined that the reverse data is included in the transmission data, the second FDB is referred to and the transmission data is transferred via the transmission / reception unit 210 by the corresponding port. Accordingly, when the reverse path information determination unit 250 determines that the transmission data is not an ACK signal, the transmission / reception unit 210 transfers the transmission data to the normal path and determines that the transmission data is an ACK signal. The transmission data is transferred to the reverse path.

  The transfer device 300 is a computer device that forms a communication network in the communication system 1, and includes a transmission / reception unit 310, a routing storage unit 320, an FDB registration unit 330, a reverse path information determination unit 350, and a communication control unit 360. I have. As described above, each unit included in the transfer device 300 is the same as the functional unit having the same name included in the site transfer device 200.

  Next, an operation example of the communication system 1 according to the present embodiment will be described. FIG. 7 is a flowchart illustrating an operation example in which the site transfer device 200 transfers transmission data transmitted from the communication terminal 100. When the transmission / reception unit 210 of the site transfer device 200 receives transmission data transmitted from the communication terminal 100 (step S1), the reception confirmation signal determination unit 240 indicates that the DATA portion included in the received transmission data is an ACK signal. It is determined whether or not (step S2). If the reception confirmation signal determination unit 240 determines that the received transmission data is not an ACK signal (step S2: NO), the process proceeds to step S4. On the other hand, if the reception confirmation signal determination unit 240 determines that the received transmission data is an ACK signal (step S2: YES), reverse path information (R-TAG) is added to the transmission data (step S3).

  The reverse path information determination unit 250 determines whether reverse path information is included in the transmission data (step S4). If the reverse path information determination unit 250 determines that the reverse path information is included in the transmission data (step S4: YES), the communication control unit 260 starts from the second FDB stored in the routing storage unit 220. The routing information is read (step S5). If the reverse path information determination unit 250 determines that the reverse path information is not included in the transmission data (step S4: NO), the communication control unit 260 starts from the first FDB stored in the routing storage unit 220. The routing information is read (step S6). The communication control unit 260 transfers the transmission data based on the read routing information (step S7).

  FIG. 8 is a flowchart illustrating an operation example in which the transfer device 300 transfers transmission data transferred from the site transfer device 200 or another transfer device 300. The transfer processing from step S11 to step S15 by the transfer device 300 is the same as the transfer processing by the site transfer device 200 described with reference to FIG. 7 except that the processing of step S2 and step S3 is not performed.

  Next, an example in which transmission data is transferred by the communication system 1 of the present embodiment will be described. FIG. 9 is a diagram illustrating an example in which the communication terminal 100-1 transmits transmission data to the communication terminal 100-2 through a normal route. Here, for example, the first FDB stored in the routing storage unit 220 included in the site transfer apparatus 200-1 is denoted by reference numeral 200-1a, and the second FDB is denoted by reference numeral 200-1b. For the other transfer devices 300 or base transfer devices 200-2 as well, the first FDB and the second FDB are similarly denoted by reference symbol a or reference symbol b.

  When communication terminal 100-1 transmits transmission data destined for MAC address “B” indicating communication terminal 100-2, base transfer apparatus 200-1 receives the transmission data from the port with port number “3”. . Since the reverse path information is not added to the transmission data received by the site transfer device 200-1, the site transfer device 200-1 stores the routing information in the first FDB (200-1a). Here, the site transfer apparatus 200-1 does not refer to the second FDB (200-1b). Since the destination MAC address “B” is not stored in the first FDB (200-1a), the transmission data is flooded and transmitted to the transfer device 300-3 and the transfer device 300-6. In each transfer device 300, the first FDB is referred to and flooded, the transmission data that has followed the reverse path is discarded by the blocking port of the base transfer device 200-2, and the transmission data that has followed the normal path is the communication terminal 100. -2.

  FIG. 10 is a diagram illustrating an example in which the communication terminal 100-2 that has received the transmission data from the communication terminal 100-1 transmits an ACK signal to the communication terminal 100-1 through the reverse path. When communication terminal 100-2 receives the transmission data from communication terminal 100-1, communication terminal 100-2 generates transmission data including an ACK signal indicating reception, and receives MAC address “A” indicating communication terminal 100-1 as a destination. Send as. Reverse path information is added to the transmission data by the site transfer device 200-2. Since the destination MAC address “A” is not stored in the second FDB (200-2b) included in the base transfer device 200-2, the transmission data is flooded. However, since the port number “2” is a blocking port in the site transfer apparatus 200-2, the transmission data is discarded and the transmission data is transmitted from the port number “1”. The transmission data is transferred to the transfer device 300-6, the site transfer device 200-1, and the transfer device 300-3, and flooded in each. Thereby, the transmission data follows the reverse path and reaches the communication terminal 100-1. At the time of transfer, the site transfer device 200 and the transfer device 300 learn by storing routing information in the second FDB. The transmission data transferred from the transfer device 300-3 to the site transfer device 200-2 is discarded at the blocking port.

  Here, when transmission data destined for the communication terminal 100-1 is not transmitted from the communication terminal 100-2, the FDB of the normal path from the communication terminal 100-2 to the communication terminal 100-1 is not learned, and communication is performed. The FDB of the reverse path from the terminal 100-1 to the communication terminal 100-2 is not learned. Therefore, in order to realize bidirectional unicast communication, the communication terminal 100-2 transmits a small amount of ACK signal to the communication terminal 100-1 via a normal path, and the communication terminal 100-1 transmits a small amount of transmission data. May be communicated between the communication terminal 100-1 and the communication terminal 100-2. For example, a method of determining such communication using a round robin method or a method of determining a hash value using FCS, FCS, or the like can be considered.

  FIG. 11 is a diagram illustrating an example in which the communication terminal 100-2 transmits an ACK signal to the communication terminal 100-1 through a normal path. When communication terminal 100-2 receives the transmission data from communication terminal 100-1, communication terminal 100-2 generates transmission data including an ACK signal indicating reception, and receives MAC address “A” indicating communication terminal 100-1 as a destination. Send as. Here, the transmission data is an ACK signal, but the reception confirmation signal determination unit 240 of the site transfer apparatus 200 transfers the transmission data without adding the reverse path information. Thereby, the transmission data including the ACK signal follows the normal path and is transferred to the communication terminal 100-1. When the transfer is performed, the transfer device 300-3 on the normal route stores the routing information in the first FDB and learns.

  FIG. 12 is a diagram illustrating an example in which the communication terminal 100-1 transmits transmission data to the communication terminal 100-2 through a reverse path. When communication terminal 100-1 transmits transmission data destined for MAC address “B” indicating communication terminal 100-2, site transfer apparatus 200-1 receives the transmission data. Here, although the transmission data is not an ACK signal, the reception confirmation signal determination unit 240 of the base transfer device 200 adds reverse path information to the transmission data and transfers the transmission data. Thereby, the transmission data follows the reverse path and is transferred to the communication terminal 100-2. At the time of transfer, the reverse path transfer device 300-6 stores the routing information in the second FDB for learning.

  In this embodiment, the reception confirmation signal determination unit 240 adds the reverse path information by adding R-TAG to the transmission data. However, the reverse path information is embedded in the transmission data by another method. May be. For example, as shown in FIG. 13A, flag information indicating whether transmission data is transmitted through the normal route or the reverse route is stored in one bit of the S-TAG of the transmission data. good. However, in this case, one bit of VLAN-ID included in the S-TAG is used, so the number of VLANs that can be created decreases from 4096 (12 bits) to 2048 (11 bits). Alternatively, as shown in FIG. 13B, an R-TAG is added regardless of whether or not the transmission data is an ACK signal, and the transmission data is transmitted through the normal path in the R-TAG or vice versa. You may make it store the flag information which shows whether it transmits by a path | route.

  As described above, according to the present embodiment, by transmitting the ACK signal via the reverse path that is a short distance, the delay of the ACK signal can be reduced and the transfer throughput can be improved. Furthermore, by increasing the transfer priority of the ACK signal from the receiving side, the delay may be further reduced and the transfer throughput may be further improved. As described above, since the ACK signal that is a response to the transmission data arrives earlier, delivery confirmation can be obtained in a shorter time, and therefore, transmission data can be transferred earlier. Here, since the traffic volume of the ACK signal is very small compared to the traffic volume of the transmission data, even if the ACK signal is transmitted via the reverse path, it is considered that the facility design is not greatly affected. Further, according to the present embodiment, it is possible to suppress variations in communication quality for each user without changing the content of transmission data at all.

  As another embodiment of the present invention, the normal path connects the communication terminal 100-1 and the communication terminal 100-2 closer to each other than the reverse path, and the reverse path is the communication terminal 100-1 and the communication terminal 100-2. In the communication system 1 that connects to a longer distance than the normal route, communication control may be performed to alleviate the communication state at the time of congestion. FIG. 14 is a diagram illustrating a configuration of the communication system 1 according to such an embodiment. The site transfer device 200 according to the present embodiment includes a communication status storage unit 270 and a communication status determination unit 280 in addition to the functional units included in the site transfer device 200 described above.

The communication status storage unit 270 stores information indicating the communication status of the communication network. The information indicating the communication status stored in the communication status storage unit 270 may be, for example, information indicating the number of transmission data discarded by the base transfer device 200 due to congestion, or a communication status measured by another network monitoring device or the like It may be a value indicating.
The communication status determination unit 280 compares the communication status stored in the communication status storage unit 270 with a predetermined threshold value and determines whether or not the communication network is in a congestion state.
Here, the reception confirmation signal determination unit 240 determines that the received transmission data is an ACK signal, and when the communication status determination unit 280 determines that the communication network is in a congested state, it reverses the transmission data. Add information.

  In this way, by transmitting the ACK signal via a reverse path that is a long distance at the time of congestion, it is possible to increase the delay of the ACK signal and temporarily reduce the transfer throughput. As a result, the opportunity to issue transmission data is reduced and the opportunity for discarding packets is also reduced, so that communication quality can be maintained while alleviating temporary congestion. That is, it is considered that the communication quality can be maintained by increasing the delay of the ACK signal and reducing the transmission data generation opportunity, rather than the frequent retransmission processing due to the packet discard due to congestion. In addition, since the traffic volume of the ACK signal is very small compared to the traffic volume of the transmission data, it is considered that even if the ACK signal is transmitted via the reverse path, the facility design is not greatly affected.

  Note that a program for realizing the function of the processing unit in the present invention is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed to perform communication control. May be. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer system” includes a WWW system having a homepage providing environment (or display environment). The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Further, the “computer-readable recording medium” refers to a volatile memory (RAM) in a computer system that becomes a server or a client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. In addition, those holding programs for a certain period of time are also included.

  The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the “transmission medium” for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

DESCRIPTION OF SYMBOLS 1 Communication system 100 Communication terminal 200 Base transfer apparatus 210 Transmission / reception part 211 1st port 212 2nd port 213 3rd port 220 Routing memory | storage part 230 FDB registration part 240 Reception confirmation signal determination part 250 Reverse path information determination part 260 Communication Control unit 270 Communication status storage unit 280 Communication status determination unit 300 Transfer device 310 Transmission / reception unit 311 First port 312 Second port 313 Third port 320 Routing storage unit 330 FDB registration unit 350 Reverse path information determination unit 360 Communication control Part

Claims (4)

A plurality of transfer devices for receiving and transferring transmission data in a communication network connected in a ring, and the transfer device connected to a communication terminal for transmitting / receiving transmission data via the communication network among the plurality of transfer devices A first route by the plurality of transfer devices that connect the plurality of site transfer devices in a direction determined in the annular communication network, and the first route, A communication system including a second path connecting the plurality of site transfer devices by a reverse path,
The site transfer device is
When receiving the transmission data from the communication terminal, when the transmission data is equal to or a reception confirmation signal a predetermined determines that the a reception confirmation signal, the transmission data to the transmission data A reception confirmation signal determination unit for adding reverse path information indicating that transfer is performed via the second path;
When the transmission confirmation signal determination unit determines that the transmission data is not the reception confirmation signal, the transmission data is transferred to the first path, and the transmission data is determined to be the reception confirmation signal. A transmission unit that transfers the transmission data to the second path,
The transfer device is
A routing table storage unit that stores a first routing table in which routing information in the first route is stored; and a second routing table in which routing information in the second route is stored;
A reverse path information determination unit that determines whether or not the transmission data to be received includes the reverse path information;
When the reverse path information determination unit determines that the reverse path information is not included in the transmission data, the reverse path information is transferred to the transmission data by referring to the first routing table. A communication control unit that transfers the transmission data with reference to the second routing table;
A communication system comprising: The first routing table and the second routing table stored in the routing table storage unit are FDB (forwarding database) determined according to a transmission source of transmission data to be received,
The transfer device is
The communication system according to claim 1, further comprising: an FDB registration unit that stores routing information in the FDB according to a transmission source of transmission data to be received. The first route connects the plurality of site transfer devices at a longer distance, and the second route connects the plurality of site transfer devices at a shorter distance. 2. The communication system according to 2. The first route connects the plurality of site transfer devices at a shorter distance, the second route connects the plurality of site transfer devices at a longer distance,
The site transfer device is
A communication status storage unit for storing information indicating the communication status of the communication network;
A communication status determination unit that compares the communication status with a predetermined threshold and determines whether the communication network is in a congested state,
The reception confirmation signal determination unit of the base transfer device determines that the received transmission data is the reception confirmation signal, and the communication status determination unit determines that the communication network is in a congestion state, The communication system according to claim 1 or 2, wherein the reverse path information is added to transmission data.

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