JP2005101898A - Network - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a network provided with an active transmission path and a standby system transmission path wherein a band of the transmission path is efficiently used. <P>SOLUTION: A relay station A is explained as below. A network center 1 transmits packets with high importance for the relay station A to the relay station A through the active transmission path A-1. The network center 1 transmits packets with low importance for the relay station A to the relay station A through a route of a standby system transmission path A-2, a standby system transmission path A-3, a standby system transmission path A-4, and a standby system transmission path A-5. Thus, the transmission band in the relay station A can be doubly secured. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a loop network in which an active transmission line and a backup transmission line for failure are provided.

In order to prevent communication from being disabled even if a failure occurs in a high-speed transmission line constituting the network, the applicant loops a network center and a plurality of relay stations as Japanese Patent Application No. 2002-166927. A network having a working transmission line and a backup transmission line for failure in which the directions of transmission between a plurality of relay stations and a network center are reversed is proposed.
In such a network, communication is performed using a standby transmission line in the event of a failure, so that a failure in the line can be avoided. In this case, a working transmission line and a standby transmission line are provided between the network center and the relay station, and between the relay station and the relay station, but the working transmission line is switched to the standby transmission line. In order to secure a transmission band of the same capacity, the band of the working transmission line and the band of the standby transmission line are set to the same transmission band. However, although the bandwidth of the standby transmission line is used at a rare time such as a failure, it is usually prepared without being used, and there is a problem that the transmission line is not used efficiently.

  Therefore, an object of the present invention is to provide a network that can efficiently use the bandwidth of a transmission line in a network in which an active transmission line and a standby transmission line are provided.

  The most important feature of the present invention is that high-priority data is transmitted using the working transmission line and low-importance data is transmitted using the standby transmission line.

  The network according to the present invention transmits high-priority data using the working transmission line and transmits low-priority data using the standby transmission line. It can be used efficiently. As a result, it is possible to use a band that is twice as large as that of the working transmission line, so that even if traffic rises in a burst manner, processing can be performed, and data overflow can be prevented.

  In a network in which an active transmission line and a standby transmission line are provided, the purpose of efficiently using the bandwidth of the transmission line is to transmit highly important data using the active transmission line and This was achieved by transmitting less important data using a transmission line.

A schematic configuration of a network according to an embodiment of the present invention is shown in FIG.
As shown in FIG. 1, the network according to the present invention is configured by connecting a network center 1, a relay station A, a relay station B, a relay station C, and a relay station D in a loop. The network center 1 and the relay station A are connected by a transmission line TL1 composed of working transmission lines A-1, B-1, C-1, and D-1, and between the relay station A and the relay station B. Are connected by a transmission line TL2 comprising active transmission lines B-2, C-2, D-2 and a standby transmission line A-2. Further, the relay station B and the relay station C are connected by a transmission line TL3 composed of active transmission lines C-3 and D-3 and backup transmission lines A-3 and B-3. The relay station D is connected by a transmission line TL4 composed of a working transmission line D-4 and backup transmission lines A-4, B-4, and C-4. The relay station D and the network center 1 are connected by a transmission line TL5 including backup transmission lines A-5, B-5, C-5, and D-5.

  The physical lines of these transmission lines TL1 to TL5 are, for example, optical fibers capable of high-speed transmission. In the example shown in the figure, the working transmission line is a counterclockwise upstream path, and the standby transmission path is a clockwise upstream path. In addition, an equal transmission band (for example, 150 Mb / s) is assigned to the transmission band of each active transmission line and the transmission band of each backup transmission line. The transmission line of the relay station A is usually carried to the network center 1 by the transmission band of the working transmission line A-1. When a failure occurs between the network center 1 and the relay station A, the standby transmission line A-2 → the standby transmission line A-3 → the standby transmission line A-4 → the standby transmission line A-5. The standby transmission line is switched from the active transmission line A-1 to always secure the transmission line bandwidth. Further, the transmission path of the relay station B is normally carried to the network center 1 by the transmission band of the working transmission path B-2 → the working transmission path B-1. When the network center 1 and the relay station B are generated, the active transmission line B is changed from the standby transmission line B-3 to the standby transmission line B-4 to the standby transmission line B-5. The transmission path bandwidth is always secured by switching from -2 and B-2.

  Furthermore, the transmission line of the relay station C is usually carried to the network center 1 by the transmission band of the working transmission line C-3 → the working transmission line C-2 → the working transmission line C-1. When the network center 1 and the relay station C are connected, the active transmission lines C-1, C-2, C are changed from the standby transmission line C-4 to the standby transmission line C-5. The transmission band is always secured by switching from -3. Furthermore, the transmission line of the relay station D is normally carried to the network center 1 by the transmission band of the working transmission line D-4 → the working transmission line D-3 → the working transmission line D-2 → the working transmission line D-1. ing. When a failure occurs between the network center 1 and the relay station D, the active transmission lines D-1, D-2, D-3, D-4 are added to the standby transmission line of the standby transmission line D-5. The transmission band is always secured by switching from

  The network according to the present invention is characterized in that highly important data is transmitted using the working transmission line and at the same time low importance data is transmitted using the standby transmission line. That is, when the relay station A is described, the network center 1 transmits a highly important packet for the relay station A to the relay station A through the working transmission line A-1. At the same time, the network center 1 sends a low-priority packet for the relay station A to the standby transmission line A-2 → the standby transmission line A-3 → the standby transmission line A-4 → the standby transmission line A-5. To relay station A. Thereby, it is possible to secure twice the transmission band at the relay station A. The same applies to the relay stations B to D. In the network according to the present invention, high-priority data is transmitted by the working transmission line, and at the same time, low-importance data is transmitted by the standby transmission line, so that not only the relay station A but also all relay stations in the network. A double transmission band can be secured. However, if a failure occurs in the working transmission line and the transmission line is switched to the standby transmission line, high-priority data is transmitted through the standby transmission line, and all low-importance packets are discarded. It becomes.

  By the way, a branch network can be provided between the relay stations separately from the transmission lines TL1 to TL5. FIG. 2 is a diagram showing a network configuration of the present invention by paying attention to a branch network transmission path provided between the relay station C and the relay station D. In FIG. 2, a branch network is provided between one transmission line on the low speed side of the first selection unit 12a of the relay station C and one transmission line on the low speed side of the second selection unit 13b of the relay station D. The switch unit ATM-a, the switch unit ATM-b, the switch unit ATM-c, and the switch unit ATM-d, each accommodating a base station, are connected in cascade by this branch network. That is, the switch unit ATM-a is connected to the first selection unit 12a of the relay station C by the transmission line L5, and the switch unit ATM-a and the switch unit ATM-b are connected by the transmission line L6. The part ATM-b and the switch part ATM-c are connected by a transmission line L7, the switch part ATM-c and the switch part ATM-d are connected by a transmission line L8, and the switch part ATM-d is relayed The transmission line L9 is connected to the second selection unit 13b at the location D.

  The switch unit ATM-a accommodates the base station a via the incoming transmission path LI3, and the switch unit ATM-b accommodates the base station b via the incoming transmission path LI4. The base station c is accommodated in the ATM-c via the incoming transmission path LI5, and the base station d is accommodated in the switch unit ATM-d via the incoming transmission path LI6. In addition, the 1st selection part and 2nd selection part in each relay station have the high speed side and the low speed side like the relay station A shown in FIG. 2, and the high speed side is shown by one elongate rectangle, and one A transmission path is provided, and the low-speed side is indicated by four rectangles and has four transmission paths. The maximum transmission speed on the high speed side is 600 Mb / s, for example, and the maximum transmission speed of each transmission path on the low speed side is 150 Mb / s.

  In the configuration of the network center 1 shown in FIG. 2, the illustrated transmission path is a transmission path that is sent to a branch network provided between the relay station C and the relay station D. The network center 1 has an exchange 2, and the importance of the switch part ATM-A is different from each other via two incoming transmission lines LI1 and LI2 entering the low speed side of the switching part ATM-A from the exchange 2. Packetized data flows in mixed. The packetized data is data to be sent to a branch network provided between the relay station C and the relay station D. N transmission lines with a transmission speed of 150 Mb / s, 600 Mb / s, etc. are prepared as transmission lines for the base station entering the switch unit ATM-A from the exchange 2. The maximum transmission rate of packetized data flowing through the incoming transmission path LI1 and the incoming transmission path LI2 is, for example, 135 Mb / s at the maximum. In the switch unit ATM-A, the input data packet is distributed to the transmission path L1 only with a high importance packet (hereinafter referred to as “high importance packet”), and a low importance packet (hereinafter referred to as “high importance packet”). A transmission path dividing function based on a packet grade that distributes “low importance packets” to the transmission path L2. The maximum packet transmission rate in the transmission line L1 and the transmission line L2 is, for example, 135 Mb / s at the maximum. The importance of each packet is added to the packet as header information, and the switch unit ATM-A looks at the header of each packet, and each of the transmission lines L1 and L2 is assigned to either of the transmission lines L1 and L2. The packet is distributed. However, when the active transmission line is switched to the standby transmission line due to a failure in the transmission lines TL1 to TL5, the high importance packet is sent to the transmission line L2, and therefore all the low importance packets are sent to the switch unit ATM-A. Will be discarded.

  Further, when a packet coming from the base station is sent to the exchange 2 through the switch unit ATM-A, a high importance packet is input from the transmission line L1, and a low importance packet is input from the transmission line L2. Become. These packets are a transmission path that sends out a packet in which a high importance packet and a low importance packet, which are synthesized by reading the packet header, to the destination exchange 2 or the like to the incoming transmission path LI1, the incoming transmission path LI2, or the like. A synthesizing function is provided in the switch unit ATM-A.

  The high importance packet that has flowed into the selection unit 3 via the transmission line L1 is sent from the selection unit 3 to the transmission line TL1. The low importance packet that has flowed into the selection unit 3 via the transmission line L2 is sent out from the selection unit 3 to the transmission line TL5. That is, the high importance packet flowing into the selection unit 3 via the transmission line L1 is sent out from the selection unit 3 to the active transmission line, and the low importance packet flowing into the selection unit 3 via the transmission line L1 is selected by the selection unit 3. To the standby transmission line. The high importance packet sent to the transmission line TL1 is sent from the relay station A to the transmission line TL2 via the transmission line L3 provided between the first selection unit 10a and the second selection unit 10b of the relay station A. The high importance packet sent to the transmission line TL2 is sent from the relay station B to the transmission line TL3 via the transmission line L4 provided between the first selection unit 11a and the second selection unit 11b of the relay station B. The high importance packet sent to the transmission line TL3 is branched by the first selection unit 12a of the relay station C and sent to the branch network provided between the relay station C and the relay station D via the transmission line L5. It is done. Further, the high importance packet from the branch network is sent to the selection unit 3 of the network center 1 through the reverse route. Note that the high-importance packet sent out from the selection unit 3 is logically the working transmission line D-1, the relay station A, the working transmission line D-2, the relay station B, the working transmission line D-3, and the relay station. It is sent to the branch network provided between the relay station C and the relay station D through the route C → transmission path L5.

  Further, the low importance packet that has flowed into the selection unit 3 via the transmission line L2 is branched by the second selection unit 13b of the relay station D, and between the relay station C and the relay station D via the transmission line L9. It is sent to the established branch network. Further, the low importance packet from the branch network is sent to the selection unit 3 of the network center 1 through the reverse route. The low-importance packet sent out from the selector 3 is logically provided between the relay station C and the relay station D in the route of the standby transmission line D-5 → the relay station D → the transmission path L9. Sent to the branch network.

  A switch unit ATM-a to a switch unit ATM-d that accommodates base stations connected in cascade to a branch network provided between the relay station C and the relay station D are base stations a to d. A transmission band that can be secured between the two will be described with reference to FIG. FIG. 3 is a diagram illustrating an extracted configuration of a branch network provided between the relay station C and the relay station D in FIG. As shown in FIG. 3, as a packet for the base station a flowing into the switch unit ATM-a constituting the branch network, a high-importance packet arrives from the transmission line L5 and decreases from the transmission line L6. An importance packet arrives. The switch unit ATM-a has a transmission path combining function that combines both of these packets and flows them into the base station a via the incoming transmission path LI3. Further, the packet from the base station a destined for the exchange 2 of the network center 1 flows into the switch unit ATM-a through the incoming transmission line LI3 with a packet amount of a maximum of 135 Mb / s in a state where packets of different importance are mixed. come. The switch unit ATM-a sorts out the high importance packets by looking at the header of each packet and sends them out to the transmission band (for example, 30 Mb / s) of the assigned transmission line L5. Further, the switch unit ATM-a sends out the low importance packets sorted by looking at the header of each packet to the transmission line L6. In this case, the maximum packet amount sent from the base station a to the exchange 2 of the network center 1 is equal to the maximum transmission rate of the incoming transmission line LI3, but the maximum transmission rate of the incoming transmission line LI3 is the same as that of the assigned transmission line L5. The transmission speed may exceed the transmission speed obtained by adding the transmission speed and the transmission speed of the transmission line L6. For this reason, in order to minimize the packet discard due to the inability to send out, the switch unit ATM-a has a burst traffic countermeasure as large as possible for temporarily storing packets when bursty traffic occurs. Buffer memory is provided. Note that when the active transmission line is switched to the standby transmission line due to a failure between the transmission line L5 and the transmission line TL1, the high importance packet is sent to the transmission line L6. It is discarded in the switch unit ATM-a.

  As a packet for the base station b flowing into the switch unit ATM-b constituting the branch network, a high importance packet arrives from the transmission line L6 and a low importance packet arrives from the transmission line L7. The switch unit ATM-b has a transmission path combining function that combines both of these packets and flows them into the base station b via the incoming transmission path LI4. Further, the packet from the base station b destined for the exchange 2 of the network center 1 has a packet amount of a maximum of 135 Mb / s flowing into the switch unit ATM-b through the incoming transmission line LI4 in a state where packets of different importance are mixed. Come on. The switch unit ATM-b sorts out the high importance packets by looking at the header of each packet, and sends them out to the transmission band (for example, 20 Mb / s) of the assigned transmission line L6. Further, the switch unit ATM-b sends out the low importance packets distributed by looking at the header of each packet to the transmission line L7. In this case, the maximum packet amount sent from the base station b to the exchange 2 of the network center 1 is equal to the maximum transmission rate of the incoming transmission line LI4, but the maximum transmission rate of the incoming transmission line LI4 is the same as that of the assigned transmission line L6. Since the transmission rate may exceed the transmission rate obtained by adding the transmission rate and the transmission rate of the transmission line L7, in order to minimize the packet discard due to the unsuccessful sending, when the burst traffic occurs in the switch unit ATM-b A buffer memory for measures against burst traffic that is as large as possible for temporarily storing packets is provided. Note that when the active transmission line is switched to the standby transmission line due to a failure between the transmission line L6 and the transmission line TL1, etc., since the high importance packet is sent to the transmission line L7, all the low importance packets are It is discarded in the switch unit ATM-b.

  As a packet for the base station c flowing into the switch unit ATM-c constituting the branch network, a high importance packet arrives from the transmission line L7 and a low importance packet arrives from the transmission line L8. The switch unit ATM-c has a transmission path combining function that combines both of these packets and flows them into the base station c via the incoming transmission path LI5. Further, the packet from the base station c destined for the exchange 2 of the network center 1 has a packet amount of a maximum of 135 Mb / s flowing into the switch unit ATM-c through the incoming transmission line LI5 in a state where packets of different importance are mixed. Come on. The switch unit ATM-c sorts the high importance packets by looking at the header of each packet, and sends them out to the transmission band (for example, 30 Mb / s) of the assigned transmission line L7. Further, the switch unit ATM-c sends out the low importance packet distributed by looking at the header of each packet to the transmission line L8. In this case, the maximum packet amount sent from the base station c to the exchange 2 of the network center 1 is equal to the maximum transmission rate of the incoming transmission line LI5, but the maximum transmission rate of the incoming transmission line LI5 is the same as that of the assigned transmission line L7. Since the transmission rate may exceed the transmission rate obtained by adding the transmission rate and the transmission rate of the transmission line L8, in order to minimize the packet discard due to the unsendability, the switch unit ATM-c has a bursty traffic. A buffer memory for measures against burst traffic that is as large as possible for temporarily storing packets is provided. Note that when the active transmission line is switched to the standby transmission line due to a failure between the transmission line L7 and the transmission line TL1, etc., since the high importance packet is sent to the transmission line L8, all the low importance packets are It will be discarded in the switch unit ATM-c.

  As a packet for the base station d flowing into the switch unit ATM-d constituting the branch network, a high importance packet arrives from the transmission line L8 and a low importance packet arrives from the transmission line L9. The switch unit ATM-d has a transmission path combining function that combines both of these packets and flows them into the base station b via the incoming transmission path LI6. Further, the packet from the base station d destined for the exchange 2 of the network center 1 has a packet amount of a maximum of 135 Mb / s flowing into the switch unit ATM-d through the incoming transmission line LI6 in a state where packets of different importance are mixed. Come on. The switch unit ATM-d sorts the high importance packets by looking at the header of each packet, and sends them out to the transmission band (for example, 40 Mb / s) of the assigned transmission line L8. Further, the switch unit ATM-d sends out the low importance packet distributed by looking at the header of each packet to the transmission line L9. In this case, the maximum packet amount sent from the base station d to the exchange 2 of the network center 1 is equal to the maximum transmission rate of the incoming transmission line LI6, but the maximum transmission rate of the incoming transmission line LI6 is the same as that of the assigned transmission line L8. Since the transmission rate may exceed the transmission rate obtained by adding the transmission rate and the transmission rate of the transmission line L9, in order to minimize the packet discard due to the unsuccessful sending, the switch unit ATM-d has a bursty traffic. A buffer memory for measures against burst traffic that is as large as possible for temporarily storing packets is provided. Note that when the active transmission line is switched to the standby transmission line due to a failure between the transmission line L8 and the transmission line TL1, the high importance packet is sent to the transmission line L9. It is discarded in the switch unit ATM-d.

  In the example shown in the figure, 20 to 40 Mb / s is assigned to each of the transmission bands of high importance packets to the base stations a to d. However, since the maximum transmission rate of the packet on the transmission line L1 from which the high importance packet is sent out from the network center 1 is, for example, a maximum of 135 Mb / s, the total transmission rate assigned to the base station a to the base station d Becomes a maximum of 135 Mb / s. For example, the base station a is assigned a transmission band of 30 Mb / s for a high importance packet, the base station b is assigned a transmission band for a high importance packet of 20 Mb / s, and the base station c is assigned a high importance packet. A transmission band of 30 Mb / s is allocated, and a transmission band of high importance packets is allocated to the base station d by 40 Mb / s. The transmission band of this high-importance packet is a band that is always guaranteed even if the active transmission path is switched to the standby transmission path when a failure occurs.

In addition, since the maximum transmission speed of the transmission line L2 and the transmission line L9 is, for example, a maximum of 135 Mb / s, the transmission band of the low importance packet can be assigned 0 to 135 Mb / s in the base station d. In c, since the maximum transmission rate of the transmission line L8 is, for example, 135 Mb / s at the maximum and the transmission rate of the high importance packet allocated to the base station d is 40 Mb / s, 135-40 = 95 Mb. / S and 0 to 95 Mb / s can be allocated. In the base station b, the maximum transmission rate of the transmission line L7 is set to, for example, 135 Mb / s at the maximum, and the transmission rate of the high importance packet assigned to the base station d is set to 40 Mb / s. Since the transmission rate of the high-priority packet being set is 30 Mb / s, 135− (40 + 30) = 65 Mb / s, and 0 to 65 Mb / s can be allocated. Further, in the base station a, the maximum transmission rate of the transmission line L6 is set to, for example, a maximum of 135 Mb / s, and the transmission rate of the high importance packet assigned to the base station d is set to 40 Mb / s. 135- (40 + 30 + 20) = 45 Mb because the transmission rate of the high-importance packet being assigned is 30 Mb / s and the transmission rate of the high-importance packet assigned to the base station b is 20 Mb / s. / S and 0 to 45 Mb / s can be allocated. That is, when the transmission rates of the high importance packet and the low importance packet are summed up to the base station a, a maximum transmission band of 75 Mb / s is allocated, and at the base station b, a maximum transmission band of 85 Mb / s is allocated. In c, a maximum transmission band of 125 Mb / s is allocated, and in the base station d, a maximum transmission band of 175 Mb / s is allocated.
In a network that uses a standby transmission line only when a failure occurs, 20 to 40 Mb / s is the maximum amount of packets that can be sent to each base station. However, in the network according to the present invention, the configuration of the base station and the assignment of high importance packets However, as described above, a transmission band of about 2 to 10 times can be secured in the normal state.

In the network of the present invention described above, a plurality of working transmission lines and a plurality of backup protection transmission lines are multiplexed by assigning a predetermined transmission band to each. Also, the total transmission band of the active transmission lines is equal to the total transmission band of the standby transmission lines.
For example, when the low importance packet is sent from the exchange 2 to the base station a, the low importance packet is sent to the base station a using the standby transmission line. When there is a margin in the transmission path, even a low-importance packet may be sent to the base station a using the active transmission path. In this way, the transmission path for transmitting the low importance packet may be used as an overflow countermeasure transmission path when the transmission path for transmitting the high importance packet overflows.

  In the above description, the loop network has been described. However, the present invention uses the active transmission line and the standby transmission line not only in the loop network but in a network in which the active transmission line and the standby transmission line are provided. Can be applied.

It is a figure which shows schematic structure of the network of the Example of this invention. It is a figure which shows the structure of the network of this invention paying attention to the transmission line of the branch network provided between the relay station C and the relay station D. FIG. It is a figure which shows the structure of the branch network provided between the relay station C and the relay station D in the network of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Network center 2 Switch 3 Selection part 10a, 11a, 12a, 13a 1st selection part 10b, 11b, 12b, 13b 2nd selection part L1 Transmission path L2 Transmission path L3 Transmission path L4 Transmission path L5 Transmission path L6 Transmission path L7 Transmission Path L8 transmission path L9 transmission path LI1 incoming transmission path LI2 incoming transmission path LI3 incoming transmission path LI4 incoming transmission path LI5 incoming transmission path LI6 incoming transmission path TL1 transmission path TL2 transmission path TL3 transmission path TL4 transmission path TL5 transmission path a base station b Base station c base station d base station

Claims (5)

A working transmission line in which a network center and a plurality of relay stations are connected in a loop and the transmission direction between the network center and the plurality of relay stations is reversed, and a backup transmission for failure A network composed of roads,
Between the network center and the plurality of relay stations, high-priority data is transmitted using the working transmission line, and low-importance data is transmitted using the standby transmission line. A network characterized by   The network center includes an exchange, and distributes data of high importance from data in which data of different importance for the plurality of relay stations is mixed from the exchange, and sends the data to the working transmission line side. The data is sent to the standby transmission line side, and the highly important data from the working transmission line and the low importance data from the standby transmission line are combined and sent to the exchange. The network according to claim 1.   A branch network can be provided between the adjacent relay stations, and a plurality of switch devices can be cascade-connected to the branch network, and the working transmission line is used between the network center and the switch device. 2. The network according to claim 1, wherein data having high importance is transmitted and data having low importance is transmitted using the standby transmission line.   The switch device in the branch network accommodates a base station of a mobile communication network, and the switch device receives high importance data from the working transmission line side and low importance data from the backup transmission line side. Combining and sending the data to the base station, distributing data having high importance from data in which data of different importance from the base station are mixed and sending the data to the working transmission line side, and distributing the data having low importance 4. The network according to claim 3, wherein the network is sent to the backup transmission line side. 5. The network according to claim 4, wherein the switch device includes a buffer memory that absorbs bursty traffic from the base station.

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