JP2009296371A - Packet switch type optical transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable an operator to easily make accommodation switching of a section or TDM path in which LSPs classified according to a service are accommodated in the case where an accommodation configuration is changed for a change of service condition. <P>SOLUTION: A system comprises: a client IF section; a path end section; a switch section for switching a frame between the client IF section and the path end section; a section end section; a label/tag control section for making label assignment in mapping to a frame in which QoS and OAM can be achieved by the client IF, and controlling a forwarding table of the switch section to be able to control a label of an internal framer in the client IF section; an accommodation configuration management section for managing an accommodation condition of a TDM signal of the path end section and the section end section; and an operation section for exchanging information with a device monitoring control section including the label/tag control section and the accommodation configuration management section so as to manage a network. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a packet switch type optical transmission system which accommodates various TDM paths or sections which accommodate LSPs classified for each service in an optical transmission system which accommodates various client signals and incorporates a packet switch.

  A label switch such as a layer 2/3 switch or MPLS (multiprotocol label switching) assigns a label to a transfer frame in units of ports, services, and V-LANs. Recently, by integrating the functions of Layer 2/3 switch represented by Ethernet (registered trademark) and MPLS into the optical transmission system, a method of efficiently using the bandwidth using the statistical multiplexing effect has been adopted. Several switch architectures are being considered.

  An optical transmission system including such a packet switch can accommodate various signals. For example, T-MPLS defined in ITU-T G.811.1 uses ETH, PDH (plesiochronous digital hierarchy) as client signals. ), SDH (synchronous digital hierarchy), ATM (asynchronous transfer mode), FR (frame relay), HDLC (high level data link control), PPP (point-to-point protocol), IPv4 (internet protocol version 4), IPv6 (internet protocol version 6) can be accommodated. A technology such as PBB-TE equipped with traffic engineering, which is standardized as IEEE802.1Qay, which is an extension of IEEE802.1ah, is also popular as a technology similar to T-MPLS.

A major feature of these technologies is QoS (Quality of Service), in which client traffic to be transmitted is classified into a plurality of classes, and a queue is provided for each class to perform queuing, scheduling, weighting, discard control, and the like. . Furthermore, OAM (Operation Administration Management) is important to maintain the same operability as transmission networks such as SDH and OTN (Optical transport network), and OAM has been introduced in the same way as a connection-type packet network. Yes.
ITU-T Recommendation G.8110.1 / Y.1370 (2006/11), ITU-T Recommendation G.8110.1 / Y.1370.1 Amdl (2007/7), 6.Functional architecture of T-MPLS networks, 7.Server / client assosiations

  However, in the conventional packet-switched optical transmission system, in order to operate efficiently or flexibly according to the operator's request, the TDM path configuration and the LSP (Label Switched Path) in the connection-oriented packet network are used by the operator. Although it is necessary to be able to change by operation, the tool suitable for operation is not prepared at present. In particular, in the packet switch type optical switch that shares and effectively uses the bandwidth by the statistical multiplexing method, the accommodation destination cannot be flexibly switched even when the accommodation configuration changes due to the change in the service status.

  The present invention provides an optical transmission system that incorporates a packet switch that shares and effectively uses a bandwidth by statistical multiplexing, and accommodates LSPs classified for each service when the accommodation configuration changes due to a change in service status. It is an object of the present invention to provide a packet switch type optical transmission system capable of easily accommodating a TDM path or section to be accommodated by an operator.

  The packet-switched optical transmission system according to the first aspect of the invention maps and outputs an asynchronous or synchronous client signal to a frame capable of QoS and OAM and outputs the received frame capable of QoS and OAM as an asynchronous or synchronous client signal. The client IF unit that outputs after demapping, and the frame is mapped to GFP, further mapped to the TDM path, the frame output from the TDM section is demapped to the TDM path, and further demapped to the GFP frame and output. And a switch unit for switching frames between the client IF unit and the path termination unit, and mapping and outputting the TDM path to the TDM section, and demapping the input TDM section to the TDM path. Output section end A label / tag control unit that controls label allocation performed when mapping to frames capable of QoS and OAM in the client IF, or a forwarding table of the switch unit, and can control the label of the internal framer in the client IF unit; An accommodation configuration management unit that manages the accommodation status of TDM signals at the path termination unit and the section termination unit, and an operation unit that manages information by exchanging information with the device monitoring control unit including the label / tag control unit and the accommodation configuration management unit With.

  In addition to the configuration of the first invention, the packet-switched optical transmission system of the second invention is a TDM that cross-connects and outputs a TDM path to an appropriate path between a path termination unit and a section termination unit. A path cross-connect unit is provided, and the apparatus monitoring control unit includes a cross-connect control unit that controls the topology of the TDM path in the TDM path cross-connect unit.

  The operation unit in the packet-switched optical transmission system of the first or second invention includes a client IF unit, a path termination unit, and an identifier that can uniquely identify a section termination unit, and the client IF unit, path termination unit, and section It has a function to hold and display the correspondence between the identifiers of the terminal part, the capacity of each path, and the section capacity as data. The operation unit includes a user interface that can change the LSP route by changing the setting of the label or tag of the client IF unit, changing the setting of the forwarding table of the switch unit, or both. In addition, the operation unit includes an automatic bandwidth control unit that performs autonomous accommodation switching of the LSP, the TDM path, or the TDM section based on the retained data based on the retained data.

  The operation unit in the packet-switched optical transmission system of the second invention includes a user interface capable of setting a TDM path accommodation destination (TDM section) by changing the setting of the TDM path cross-connect unit.

  In the packet switch type optical transmission system of the present invention, three connections of a frame-based LSP, a TDM path, and a TDM section are managed by the same device, and setting from an operator becomes possible. In addition, by managing the configuration information of each connection and displaying the information as a user interface, flexible operation based on the operator's judgment becomes possible. Furthermore, for regular operations, automatic control is possible by creating a policy and providing the operation function.

  In addition, in an optical transmission system with a built-in packet switch expected in the future, the operator can arbitrarily change the topology of the LSP based on the usage efficiency and operational circumstances of the TDM layer path and section that have not been available so far. The operability in the packet network can be improved.

(First embodiment)
FIG. 1 shows a first embodiment of a packet switch type optical transmission system of the present invention.
In the figure, one or more client IF units 100 and one or more network IF units 200 are connected via an internal frame switch 300.

  The client IF unit 100 includes a client terminal unit 101, an internal framer unit 102, and a frame processing unit 103. The client termination unit 101 terminates various client signals such as a MAC frame. The internal framer unit 102 maps and outputs the terminated client signal to an internal frame such as a T-MPLS frame or a PBB-TE frame and assigns a label / tag, and demaps the input internal frame. To extract the client signal. The frame processing unit 103 classifies traffic into multiple classes (classification), discard control of traffic exceeding the CIR and EIR (policing), traffic flow measurement (monitoring), permutation for each class (queuing), queue Read priority control (scheduling) of inserted traffic and insertion / branching of OAM internal frames (OAM frame processing).

  The network IF unit 200 includes one or more path termination units 210 and one section termination unit 220. Further, the path termination unit 210 includes a frame processing unit 211, a GFP framer 212, and a TDM path termination unit 213. The section termination unit 220 includes a TDM path division multiplexing unit 221 and a TDM section termination unit 222.

  The frame processing unit 211 performs internal frame policing, monitoring, queuing, scheduling, and OAM frame processing. The GFP framer 212 maps the inner frame to the GFP frame and demaps the GFP frame to the inner frame. The TDM path termination unit 213 maps the GFP frame to the SDH LO (Low Order) path or HO (High Order) path, or the OTN ODUx (ODU1, ODU2,...) Path, and the SDH LO path or HO path, Alternatively, the GFP frame is demapped from the OTN ODUx path.

  The TDM path division multiplexing unit 221 converts a TDM path input from one or more TDM path termination units 213 into a TDM section such as STM-X (1, 4, 16, 64, 256) or OTU-X (1, 2, 3). Multiplexed transmission is performed, and the TDM path is separated from the TDM section and transmitted to one or more TDM path termination units 213. The TDM section termination unit 222 includes a PHY that performs physical layer processing on the TDM section.

  The internal frame switch 300 includes a T-MPLS frame or the like between the frame processing unit 103 of one or more client IF units 100 and the frame processing unit 211 of one or more path termination units 210 of one or more network IF units 200. An internal frame such as a PBB-TE frame is switched based on a label or a tag.

  The device monitoring control unit 400 includes a label / tag control unit 401 and a storage configuration management unit 402. The label / tag control unit 401 controls label / tag assignment during internal framing in the internal framer 102 of the client IF unit 100 and also controls forwarding of the internal frame switch 300. The accommodation configuration management unit 402 manages the status of the TDM signal accommodation state of the path termination unit 210 and the section termination unit 220 of the network IF unit 200 (the identifier of the termination unit, the location of the time slot to be used, and the number of time slots (bandwidth)). )) Manage.

  The operation unit 500 includes means for exchanging control messages with the label / tag control unit 401. Further, a label value assigned to the frame and a packet transmission destination (forwarding table) determined for each label are set via the label / tag control unit 401. Further, it is possible to set the bandwidth (time slot) of the TDM path and the accommodation destination (TDM section termination unit 222) via the accommodation configuration management unit 402. When setting the accommodation destination of the TDM path, an identifier is set for the path and the section to establish a correspondence relationship.

  As a result, when the topology and bandwidth usage efficiency of the TDM section or TDM path deteriorates, or when it is desired to temporarily save traffic to another route for maintenance, the topology of the LSP in the TDM network at the discretion of the operator Can be changed.

  The operation unit 500 includes identifiers that can uniquely identify the plurality of client IF units 100, the path termination unit 210, and the section termination unit 220. Each of the client IF unit 100, the path termination unit 210, and the section termination unit 220 includes It has a function of storing and displaying identifier correspondence, capacity of each path, and section capacity as data. As a result, the operator can monitor the bandwidth used by the TDM section, TDM path, and LSP, the bandwidth usage efficiency of the TDM section and TDM path, and the network topology.

  In addition, the operation unit 500 includes an automatic bandwidth control unit that performs autonomous accommodation switching of an LSP, a TDM path, or a TDM section on the basis of the retained data based on a predetermined policy. As a result, the operator can automatically change the topology of the LSP and TDM paths by applying a specific policy.

  Also, the operation unit 500 changes the setting of the label or tag in the internal framer unit 102 of the client IF unit 100 or sets the forwarding table of the internal frame switch 300 via the label / tag control unit 401 of the device monitoring control unit 400. A user interface is provided that can change the route of the LSP by changing or both.

  As a result, the operator can freely change the topology of the LSP for the purpose of improving the usage efficiency and maintenance based on the bandwidth usage efficiency of the TDM section, TDM path, LSP section, TDM section, TDM path, and network topology. It becomes possible.

(Second Embodiment)
FIG. 2 shows a second embodiment of the packet switch type optical transmission system of the present invention.
In the figure, one or more client IF units 100 and one or more path termination units 210 are connected via an internal frame switch 300. One or more path termination units 210 and one or more section termination units 220 are connected via a TDM path cross-connect unit 600.

  The client IF unit 100 includes a client terminal unit 101, an internal framer unit 102, and a frame processing unit 103. The path termination unit 210 includes a frame processing unit 211, a GFP framer 212, and a TDM path termination unit 213. The section termination unit 220 includes a TDM path division multiplexing unit 221 and a TDM section termination unit 222. The device monitoring control unit 400 includes a label / tag control unit 401, a storage configuration management unit 402, and a cross-connect control unit 403.

  In this embodiment, a TDM path cross-connect unit 600 capable of cross-connecting TDM paths is arranged between one or more path termination units 210 and one or more section termination units 220, and the cross-connect of the device monitoring control unit 400 is performed. The control unit 403 is characterized in that the TDM path cross-connect unit 600 can be controlled. Other configurations are the same as those of the first embodiment.

  As a result, when the topology and bandwidth usage efficiency of the TDM section or TDM path deteriorates, or when it is desired to temporarily compare the traffic with another route for maintenance, the TDM path of the TDM network is at the discretion of the operator. You can change the topology.

  The operation unit 500 also includes a user interface that can set a TDM path by changing the setting of the TDM path cross-connect unit 600. Thereby, the operation unit 500 can change the topology of the TDM path.

  FIG. 3 shows an operation example of the packet switch type optical transmission system of the present invention. FIG. 3 (1) shows the state before the path accommodation change, and FIG. 3 (2) shows the state after the path accommodation change.

  In FIG. 3 (1), service A and service B are accommodated in TDM path 1 of TDM section 1, service C is accommodated in TDM path 2 of TDM section 2, and service D is accommodated in TDM path 3 of TDM section 3. Has been. In this state, for example, when it is desired to make the TDM section 2 and the TDM section 3 empty due to trouble relocation, it is necessary to replace the TDM path 2 and the TDM path 3 with the TDM section 1.

  In the present invention, by changing the route of the LSP at this time, it is possible to quickly change the accommodation to the TDM section 1. First, a TDM path 4 and a TDM path 5 having the same band as the TDM path 2 and the TDM path 3 are generated in the TDM section 1. Thereafter, the service C accommodated in the TDM path 2 is replaced with the TDM path 4, and the service D accommodated in the TDM path 3 is replaced with the TDM path 5.

  Here, FIGS. 4 and 5 show examples in which the above-described LSP accommodation change is performed under the control of the label / tag control unit 401. FIG. 4 and 5 are examples of DBs held by the configuration management unit 402 of the device monitoring control unit 400. FIG.

  FIG. 4 shows an example in which the setting of the label assigned by the internal framer unit 102 of the client IF unit 100 is changed and the setting of the forwarding table of the internal frame switch 300 is changed. 4 (1) shows the state before the path accommodation change corresponding to FIG. 3 (1), and FIG. 4 (2) shows the state after the path accommodation change corresponding to FIG. 3 (2). The label / tag control unit 401 changes the label assigned by the internal framer unit 102, thereby changing the label C and label D assigned in FIG. 4 (1) to the label E and label D shown in FIG. 4 (2), respectively. Change to F. Further, the label E is changed to the TDM path 4 of the TDM section 1 by changing the label E to the TDM path 4 and changing the label F to the TDM path 5 in the forwarding table of the internal frame switch 300. Can be accommodated to the TDM path 5 of the TDM section 1.

  FIG. 5 is an example in which only the setting of the forwarding table of the internal frame switch 300 is changed without changing the setting of the label assigned by the internal framer unit 102 of the client IF unit 100. 5 (1) shows the state before the path accommodation change corresponding to FIG. 3 (1), and FIG. 5 (2) shows the state after the path accommodation change corresponding to FIG. 3 (2). The label / tag control unit 401 changes the label C to the TDM path 4 and changes the label D to the TDM path 5 in the forwarding table of the internal frame switch 300, thereby changing the label C to the TDM path 4 of the TDM section 1. The label D can be accommodated and changed to the TDM path 5 of the TDM section 1.

The figure which shows 1st Embodiment of the packet switch type | mold optical transmission system of this invention. The figure which shows 2nd Embodiment of the packet switch type | mold optical transmission system of this invention. The figure which shows the operation example of the packet switch type | mold optical transmission system of this invention. The figure which shows the structure management DB in the LSP accommodation replacement example 1. The figure which shows the structure management DB in the LSP accommodation replacement example 2.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Client IF part 101 Client termination part 102 Internal framer part 103 Frame processing part 200 Network IF part 210 Path termination part 211 Frame processing part 212 GFP framer 213 TDM path termination part 220 Section termination part 221 TDM path division multiplexing part 222 TDM section termination Unit 300 internal frame switch 400 device monitoring control unit 401 label / tag control unit 402 accommodation configuration management unit 403 cross-connect control unit 500 operation unit 600 TDM path cross-connect unit

Claims (6)

A client IF unit that maps and outputs an asynchronous or synchronous client signal to a frame capable of QoS and OAM, and demaps and outputs a received QoS and OAM capable frame to an asynchronous or synchronous client signal;
A path termination unit that maps the frame to GFP, further maps to the TDM path, demaps the frame output from the TDM section to the TDM path, and further demaps and outputs to the GFP frame;
A switch unit that switches the frame between the client IF unit and the path termination unit;
A section termination unit that maps and outputs the TDM path to a TDM section, and demaps and outputs the input TDM section to the TDM path;
Label / tag control unit capable of controlling label allocation performed when mapping to frames capable of QoS and OAM in the client IF, or a forwarding table of the switch unit, and controlling the label of the internal framer in the client IF unit When,
An accommodation configuration management unit for managing the accommodation status of the TDM signal at the path termination unit and the section termination unit;
A packet switch type optical transmission system comprising: an operation monitoring unit for exchanging information and managing a network with an apparatus monitoring control unit including the label / tag control unit and the accommodation configuration management unit. In the packet switch type optical transmission system according to claim 1,
A TDM path cross-connect unit that cross-connects and outputs the TDM path to an appropriate path between the path termination unit and the section termination unit,
The packet monitoring type optical transmission system, wherein the device monitoring control unit includes a cross-connect control unit that controls a topology of the TDM path in the TDM path cross-connect unit. In the packet switch type optical transmission system according to claim 1 or 2,
The operation unit includes an identifier that can uniquely identify the client IF unit, the path termination unit, and the section termination unit, and correspondence between each identifier of the client IF unit, the path termination unit, and the section termination unit. A packet-switched optical transmission system, which has a function for storing and displaying the capacity of each path and section capacity as data. In the packet switch type optical transmission system according to claim 1 or 2,
The operation unit includes a user interface capable of changing the LSP route by changing the setting of the label or tag of the client IF unit, changing the setting of the forwarding table of the switch unit, or both. Packet switch type optical transmission system. The packet switch type optical transmission system according to claim 2,
The packet switching type optical transmission system, wherein the operation unit includes a user interface capable of setting a TDM path accommodation destination (TDM section) by changing a setting of the TDM path cross-connect unit. In the packet switch type optical transmission system according to claim 3,
The operation unit includes an automatic bandwidth control unit that performs autonomous accommodation switching of an LSP, a TDM path, or a TDM section based on a specific policy based on retained data according to claim 3. Packet switch type optical transmission system.

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