JP2006253868A - Multi-ring type network system and intersection node - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a multi-ring type network system and an intersection node in which data communication can be sustained even upon occurrence of double troubles. <P>SOLUTION: A plurality of nodes are connected in ring by an optical transmission path (two core optical fibers 10) of 0 system and 1 system to form a 0 system route and a 1 system route. A plurality of rings including the 0 system route and 1 system route are interconnected by intersection nodes 01 to constitute a multi-ring type network system. The intersection node 01 is provided with an additional TS termination board 13 for terminating additional TS information of line unit at an additional TS terminating section 14, judging normality of the 0 system route and 1 system route based on the received additional TS information and the data of line unit, selecting a normal route side by controlling a selector 15, and transmitting the received data of line unit and the additional TS information to the 0 system route and 1 system route. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a multi-ring network system in which a plurality of ring networks are connected and an intersection node.

  In a hybrid communication system that supports both a packet-switched communication system such as IP (Internet Protocol) communication and a normal circuit-switched communication system, a ring-type network system that transmits an optical signal is known. In addition, a duplex configuration is applied. For example, a single ring type network system in which a plurality of nodes are connected in a ring shape by an optical transmission line of system 0 and system 1 using a two-core optical fiber is generally used. Data is transmitted in both directions, one and the other, using the optical transmission lines of the 0 system and the 1 system, and the receiving node has a configuration for receiving data from directions in which normal reception is possible for data from both directions. Is. Therefore, even if a failure occurs in, for example, the 0-system optical transmission path between the transmission node and the receiving node, the receiving node can receive data via the 1-system optical transmission path, and the reliability Can be improved.

  Also, in a system for transmitting data by applying an SDH (Synchronous Digital Hierarchy) method, an AIS (Automatic Protection Signal) with AIS (Alarm Indication Signal) and APS (Automatic Protection) using K1 and K2 bytes of a path overhead (POH). There is a means to notify the receiving side using Switch), and it has been proposed to apply this means for efficiently controlling the switching of the optical transmission line by AIS and APS to the single ring network described above. (For example, refer to Patent Document 1).

  There is also known a multi-ring network system in which a plurality of single-ring networks are connected to each other via an intersection node. For example, as shown in FIG. 6, a ring A in which nodes A-02 to A-08 are connected by an optical transmission line and a ring B in which nodes B-02 to B-8 are connected by an optical transmission line are connected to an intersection node. The intersection node 01 has a configuration in which the nodes A-02 and B-08 are connected and the nodes A-08 and B-02 are connected to each other. A large network system is configured by connecting to B. A terminal can be connected to each node. Terminal A is connected to node A-05. Terminal C is connected to node A-03. Terminal B is connected to node B-05. The case where the terminal D is connected to B-03 is shown. Further, a duplex route is formed between the terminals A and B, that is, a 0-system route indicated by a solid line arrow and a 1-system route indicated by a dotted line arrow. Therefore, for example, when a failure occurs between the nodes B-04 and B-05 on the ring B side, the nodes A-05 and B-05 are normal if the intersection node 01 and the nodes B-05 to B-08 are normal. Data transmission between terminals A and B connected between them can be continued.

  FIG. 7 shows a schematic configuration of the above-described conventional intersection node 01. Reference numeral 10 denotes a two-core optical fiber for forming a 0-system optical transmission line and a 1-system optical transmission line, 11A0, 11A1, 11B0, and 11B1 Optical interface units 12A and 12B indicate space switch units. The optical interface units 11A0 and 11B0 perform optical signal transmission / reception processing for the 0-system optical transmission line, and the optical interface units 11A1 and 11B1 perform optical signal transmission / reception processing for the 1-system optical transmission line. 12A and 12B are interlaced with the optical interface units 11A1 and 11B0. When the multi-ring network system shown in FIG. 6 is configured, the paths a, b, c, and d of the space switch units 12A and 12B Control to form. Accordingly, a multi-ring network system in which the rings A and B shown in FIG.

  6 includes, for example, the optical interface units 11A0 and 11A1 and the space switch unit 12A illustrated in FIG. 7, and the optical interface unit 11A1 and the space switch unit 12A are connected to each other. It is what you have. The terminal is connected to the space switch units 12A and 12B via a terminal interface unit (not shown).

In a multi-ring network system, when multiple rings are connected by multiple bridge nodes (corresponding to the above-mentioned intersection nodes) and a failure occurs in the bridge node, multiple detour paths can be formed. There is known a means for selecting a route whose TTL (Time To Live) value does not exceed a set value based on the number of nodes of the detour route or the like (see, for example, Patent Document 2).
JP 2001-298469 A JP 2003-229876 A

  Conventionally, a configuration in which route switching is performed in units of VC (Virtual Container) (minimum of 64 kbps × 24 channels) has been a common problem, and there has been a problem that the line accommodation efficiency is lowered. In addition, when switching in the occurrence of an abnormality or package failure is performed in the terminal interface unit, a means is provided for performing a line unit (for example, 64 kbps × n) on the receiving side. Such switching means can be applied to a single-ring network system, but when applied to a multi-ring network system, it is remedied in the case of a double failure in which failures in different rings occur simultaneously. There is a problem that can not be.

  For example, in FIG. 6, when a failure occurs between the nodes A-04 and A-03 on the ring A side and a failure between the nodes B-05 and B-04 on the ring B side, Since the 0-system route and the 1-system route on the node A-04 side between A and B are disconnected, and the 0-system route and the 1-system route on the node B-04 side are disconnected, the intersection node 01 shown in FIG. Some problems cannot be remedied.

  It is an object of the present invention to monitor additional TS information for each line and to remedy even the occurrence of a double failure in a multi-ring network system by automatic switching corresponding to the line.

  In the multi-ring network system of the present invention, a plurality of nodes are connected in a ring shape by optical transmission lines of 0 and 1 systems to form a 0 and 1 system route, and the 0 system route is formed by an intersection node. In the multi-ring network system in which a plurality of rings including the system 1 route are connected, the intersection node terminates the additional TS information in units of lines, and the received additional TS information and data in units of lines The normality between the 0-system route and the 1-system route is determined based on the data, and the line unit data and the additional TS information received by selecting the normal route side into the 0-system route and the 1-system route. It has a configuration in which an additional TS terminal board for transmission is provided.

  Also, the intersection node of the present invention is a multi-ring that connects a plurality of nodes by connecting a plurality of nodes in a ring shape by means of optical transmission lines of the 0 system and the 1 system to form a 0 system route and a 1 system route. Type additional TS information is terminated at the intersection node in the network system, and the normality of the 0-system route and 1-system route is determined based on the received additional TS information and the data in the circuit unit. In addition, a configuration is provided in which an additional TS termination board is provided for selecting a normal route side and transmitting the received line unit data and additional TS information to the 0-system route and the 1-system route.

  The additional TS termination board includes an additional TS termination section for determining the normality of the 0-system route and the 1-system route based on the parity calculation result of the data for each circuit and the additional TS information for each circuit, and the additional TS termination. And a selector for switching so as to transmit the data and the additional TS information on the normal route side determined on the basis of the route to the 0-system route and the 1-system route.

  The multi-ring network system and the intersection node of the present invention have a configuration in which a plurality of rings having routes of system 0 and system 1 are connected by an intersection node, and the intersection node stores additional TS information for each line unit. An additional TS termination board that terminates is provided, the normality of the route is determined on a line-by-line basis, and when abnormality detection is determined due to the occurrence of a failure, the received data and additional TS information on the normal route side are converted to the 0-system route and 1 Since the data is transmitted to the system route, even if a failure occurs in each of the plurality of rings, data communication can be continued by transmitting normal data and additional TS information in units of lines.

  Referring to FIG. 1, the multi-ring network system and the intersection node according to the present invention connect a plurality of nodes in a ring shape by means of optical transmission lines (two-core optical fiber 10) of the 0 system and the 1 system, and the 0 system route. And a 1-system route, and a plurality of rings including the 0-system route and the 1-system route are connected by an intersection node 01 to form a multi-ring network system. The additional TS information is terminated by the additional TS termination unit 14, the normality between the 0-system route and the 1-system route is determined based on the received additional TS information and data in units of lines, and the normal route side is selected by the selector 15. The additional TS termination board 13 is provided for transmitting the received line unit data and additional TS information to the 0-system route and the 1-system route.

  FIG. 1 is an explanatory diagram of the main part of an intersection node according to the first embodiment of the present invention. For example, the main part of an intersection node 01 that configures a multi-ring network system by connecting the rings A and B shown in FIG. 10 is a two-core optical fiber for forming a 0-system optical transmission line and a 1-system optical transmission line, 11A0, 11A1, 11B0, 11B1 are optical interface units, 12A, 12B are spatial switch units, Reference numeral 13 denotes an additional TS (Time Slot) termination board, reference numeral 14 denotes an additional TS termination section, and reference numeral 15 denotes a selector (DSEL) for switching in line units. That is, the additional TS terminal board 13 is provided and connected to the space switch units 12A and 12B.

  The additional TS terminal board 13 has a register (not shown). For each line unit, for example, 3240TS (time slot) = 200 Mbps is assigned, and information indicating which line is assigned to which time slot. Therefore, the line can be identified. Then, additional TS information is transmitted for each line unit, terminated by the additional TS termination board 13, parity operation is performed for each line in the additional TS termination unit 14, and compared with the parity bit in the additional TS, Determine whether there is a parity error. This process is performed for all lines. Then, the selector (DSEL) 15 is controlled according to the determination result of the presence / absence of the parity error in the additional TS termination unit 14 to select and output the line having no parity error. That is, the additional TS terminal board 13 can select and transmit a normal system for each line.

  FIG. 2 shows an example of additional TS information, which has a 1-byte (bits b0 to b7) configuration. Bit b0 indicates a parity (odd parity) P in units of lines, and this parity P is in units of lines. This is for determining the normality of the 0-system route and the 1-system route by comparing with the parity obtained by performing the parity calculation processing of the data. Based on this normality determination result, the additional TS terminal board 13 performs switching so as to select a normal route side corresponding to the line. The bit b1 other than the bit b0 is the in-device reception alarm * BAIS on the opposite station side, the bit 2 is the path direction F, the bit 3 is the bit * AV indicating the validity / invalidity of the time slot, and the bit b4 is Bit * S indicating validity / invalidity of CD / RS transfer, bit b5 is a bit RRT indicating passage of a detour line (other than an optical transmission line), bit b6 is terminal side signaling information * ST, bit b7 is opposite The station side line terminal alarm FAIS may be configured.

  As described above, the additional TS termination unit 14 performs a parity calculation process on the reception data in units of lines, compares the calculation result with the above-described parity P of the additional TS information in units of lines, and performs the same operation. If it is different, it is determined to be abnormal, and if it is determined to be abnormal, the selector 15 is controlled to switch the 0 system / 1 system route and select the normal route. As a result, the additional TS information includes the normal parity P, and the normal additional TS information and the normal data are transferred via the space switch units 12A and 12B and the optical interface units 11A0, 11A1, 11B0, and 11B1. It transmits to 0 system route and 1 system route. That is, normal data and additional TS information are transmitted from one ring to the other ring.

  FIG. 3 is an explanatory diagram of the main part of a node other than the intersection node 01. For example, the main part of the nodes B-03 and B-04 in FIG. 6 is shown. In the figure, 21B0, 21B1, 31B0, 31B1 are optical interface units, 22B0, 22B1, 32B0, 32B1 are space switch units, and 24, 34 are terminal interface units. Nodes B-03 and B-04 are connected by a 0-system optical transmission line and a 1-system optical transmission line together with other nodes not shown. In addition, the terminal interface units 24 and 34 have a parity calculation function and a comparison check function between the parity P in the additional TS information and the calculated parity only for the lines corresponding to the nodes B-03 and B-04. Parity processing means is provided, and this parity check processing means is provided only for lines to terminals connected to the nodes B-03 and B-04.

  In addition, the terminal interface units 24 and 34 determine whether or not each line-unit data received via the 0-system transmission path and the 1-system transmission path is normal based on the additional TS information by the above-described parity processing means. If the parity is abnormal, the selector switches between the 0-system and 1-system routes, selects the normal route, and transmits it to the terminal. The data from the terminal is transmitted to both the 0-system transmission path and the 1-system transmission path, including the additional TS information including the parity P of the parity calculation result of the line unit data. Therefore, the normality is determined for each line at the intersection node 01 described above, and normal line-unit data and additional TS information are transmitted to the 0-system route and the 1-system route. Data communication between terminals can be continued.

  In addition, in the optical interface units 21B0, 21B1, 31B0, 31B1, or the space switch units 22B0, 22B1, 32B0, 32B1, if the data is not addressed to the own node, a return path is formed and relayed. As such control means, already known means can be applied. For example, in the case of a failure in the optical transmission line between the node B-04 and the node B-05 (not shown), in the node B-04, the terminal interface unit 34 communicates with the node B-03. The data on the 1-system optical transmission line between them is selected and transmitted to the terminal, and the additional TS information of the data transmitted via the optical interface unit 31B0 and the space switch unit 32B0 is used as the content indicating the occurrence of abnormality as the node B- Transmit to the 03 side via the 0-system optical transmission line.

  In the node B-03, since the data received via the 0-system optical transmission line can be determined to have an abnormality based on the additional TS information, the terminal interface unit 24 uses the 1-system optical transmission line. The data received from is selected and transmitted to the terminal. Accordingly, it becomes possible to relieve the occurrence of a failure in the optical transmission line, and the additional TS termination board 13 is provided at the intersection node 01, so that when a failure occurs in each of the rings A and B, that is, a double failure occurs. In this case, a normal route can be selected.

  FIG. 4 is an explanatory diagram of a multi-ring network system according to a second embodiment of the present invention, in which nodes A-02 to A-04 are connected by optical transmission lines that form a 0-system route and a 1-system route. Ring B, which connects A and nodes B-02 to B-04 through optical transmission lines forming a 0-system route and a 1-system route, and nodes C-02 to C-04, a 0-system route and a 1-system A ring C connected by an optical transmission line forming a route and a ring D connecting nodes D-02 to D-04 by an optical transmission line forming a 0-system route and a 1-system route are connected to an intersection node 01 Shows a multi-ring network system in which they are connected to each other. A configuration in which terminals A, B, C, and D are connected to nodes A-03, B-03, C-03, and D-03 of rings A, B, C, and D, respectively, is shown. Note that a single or a plurality of terminals can be connected to other nodes.

  FIG. 5 is an explanatory diagram of a main part of the intersection node 01 connecting the rings A, B, C, and D shown in FIG. 4 described above, 51 is an optical interface unit, and 52-0 and 52-1 are space switch units. , 53 is an additional TS termination board, 54 is an additional TS termination section, and 55 is a selector (DSEL). The additional TS terminal board 53 has the same function as that of the additional TS terminal board 13 shown in FIG. 1, and holds information on the relationship between the time slot and the line in the transmission band by a register not shown. Yes. The optical interface unit 51 is provided corresponding to each of the 0-system optical transmission line and the 1-system optical transmission line of the rings A, B, C, and D, and the space switch unit 52-0 is provided via the optical interface unit 51. Port P2, P4, P6, and P8 for transferring data to and from the 0-system optical transmission line, and a port P1 for connecting the additional TS terminal board 53, and a space switch unit 52-1. Includes ports P3, P5, P7, and P9 for transferring data to and from the 1-system optical transmission line via the optical interface unit 51, and a port P1 for connecting between the additional TS terminal board 53. ing.

  Therefore, the 0-system optical transmission line between the ring A and the ring B is connected via the optical interface unit 51, the ports P2 and P4 of the space switch unit 52-0, and the additional TS terminal board 53. The 1-system optical transmission line between ring A and ring B is connected via the optical interface unit 51, ports P3 and P5 of the space switch unit 52-1, and the additional TS terminal board 53. Similarly, the other rings C and D are connected to each other through the optical interface unit 51, the space switch units 52-0 and 52-1, and the additional TS terminal board 53. Then, the additional TS termination unit 54 and the selector 55 in the additional TS termination board 53 check the normality of the path for each line using the parity calculation processing and the additional TS information for each line. When the 0 system of a certain line is abnormal, the selector 55 is controlled so that normal data of the 1 system of that line and its additional TS information are transmitted via both the space switches 52-0 and 52-1. , To the 0 system and 1 system of the line.

  Therefore, between the terminal A of the ring A and the terminal C of the ring C in the multi-ring network system shown in FIG. 4, for example, between the node A-04 of the ring A and the intersection node 01 Even if a double failure occurs between the nodes C-02 and C-03 of the ring C, the data from the terminal A at the intersection node 01 is transferred from the 1-system route via the node A-02 to the ring C. It is sent to the 0-system route on the node C-02 side and the 1-system route on the node C-04 side, and the node C-03 transmits the data via the normal 1-system route on the ring C to the terminal C, The data from the terminal C is transmitted from the node C-03 to the route of the 0 system and the 1 system. At the intersection node 01, the 1 system route through the node C-02 is selected and the ring is selected. A is transmitted to the route of system 0 and system 1. Node A-03 of ring A selects normal data via node A-02 and transmits it to terminal A. Thus, even when a double failure occurs, normal route selection can be performed on a line basis by the function of the additional TS terminal board 53 of the intersection node 01, so that communication between terminals can be continued.

  The additional TS termination boards 13 and 53 at the intersection node 01 described above are applied to the 600 Mbps band, for example, in the case where the configuration is such that a line operation parity calculation process can be performed for a maximum of 810 lines in the case of a 200 Mbps band. In this case, by providing the above-mentioned three additional TS termination boards 13 and 53, normality determination processing and route switching can be performed by the parity operation processing corresponding to the line. When a single ring network system is constructed, the additional TS terminal boards 13 and 53 for connecting the space switch sections of the intersection node 01 can be omitted or the structure shown in FIG. Accordingly, a node configuration corresponding to the network system configuration can be obtained, so that a flexible response is possible.

It is principal part explanatory drawing of the intersection node of Example 1 of this invention. It is explanatory drawing of additional TS information. It is principal part explanatory drawing of the node of Example 1 of this invention. It is explanatory drawing of Example 2 of this invention. It is principal part explanatory drawing of the intersection node of Example 2 of this invention. It is explanatory drawing of a multi-ring type network system. It is principal part explanatory drawing of the conventional intersection node.

Explanation of symbols

01 Intersection node 10 Two-core optical fiber 11A0, 11A1, 11B0, 11B1 Optical interface unit 12A, 12B Spatial switch unit 13 Additional TS termination board 14 Additional TS termination unit 15 Selector (DSEL)

Claims (3)

A plurality of nodes are connected in a ring shape by the optical transmission lines of the 0 system and the 1 system to form a 0 system route and a 1 system route, and a plurality of rings including the 0 system route and the 1 system route by the intersection node In a multi-ring network system that connects
The intersection node terminates the additional TS information for each line, determines the normality of the 0-system route and the 1-system route based on the received additional TS information and the data for each circuit, and the normal route side A multi-ring network system comprising: an additional TS terminal board for transmitting the line unit data and the additional TS information received by selecting to the 0 system route and the 1 system route. Nodes in a multi-ring network system in which multiple nodes are connected in a ring by means of optical transmission lines of system 0 and system 1 to form a system 0 route and system 1 route, and a plurality of rings are connected. In
Terminate the additional TS information per line, determine the normality of the 0-system route and the 1-system route based on the received additional TS information and the data per circuit, select the normal route side, An intersection node characterized in that an additional TS terminal board is provided for transmitting the received line unit data and the additional TS information to the 0-system route and the 1-system route.   The additional TS termination board includes an additional TS termination unit that determines normality of the 0-system route and the 1-system route based on the parity calculation result of the data in the circuit unit and the additional TS information in the circuit unit, and the additional TS terminal. 2. The intersection according to claim 1, further comprising a selector for switching transmission of the normal route side data and additional TS information determined by the termination unit to the 0-system route and the 1-system route. node.

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