JP4859909B2 - Transparent optical network and transparent optical network fault monitoring method - Google Patents

Description

The present invention relates to a transparent optical network及beauty Transparent Optical Network failure monitoring method, in particular, light from the sending node to the receiving node - failure to monitor whether generated by any node in transparent optical network that does not include the electrical process about transparent optical network及beauty transparent optical network failure monitoring method for.

  In recent years, in optical communications, research and development of transparent optical networks that transfer optical signals as they are without relaying electrical regeneration has been performed in order to increase the speed, cost, and power consumption of optical networks. Yes.

  Conventionally, in a network having a full mesh configuration as shown in FIG. 5, for example, connection setting is performed on an optical path a of node A → node B → node C → node F → node I. Thereafter, as shown in FIG. 6A, when a failure such as an optical switch failure or fiber breakage occurs at node C, an optical path is transmitted using a control plane (C plane) for notifying the path state. After the starting node A detects the failure state, as shown in FIG. 5B, the detour path is calculated, the detour path b is set, and the detour path b is switched to restore.

In a conventional non-transparent optical network, each node has an optical-electrical-optical electrical regenerative repeater. When a failure occurs, after switching the optical path route, a monitoring signal light is generated at each node and transmitted to the subsequent node. By monitoring this monitoring signal, the failure location of the optical path can be identified (path trace). (See Non-Patent Document 1, for example).
Lei Zong et al., "Study on wavelength cross-connect realized with wavelength selective switches", OFC2006, NThC3, March 2006.

  However, if a failure occurs in the full-mesh transparent network as shown in FIG. 5 above, the optical path route is switched, so that the optical signal is not transmitted to the node of the original route, so that the failure occurrence location is specified. I can't. For example, even if a failure occurs in the node C in the optical path a of node A → node B → node C → node F → node I shown in FIG. 5A, there is no optical signal (optical path a) at the time of recovery. Therefore, the monitor signal cannot be monitored at each node, and the location cannot be specified. For example, after the recovery as shown in FIG. 5B, if the optical path b is set as node A → node D → node G → node H → node I, the failure of the node C remains unspecified. End up.

  FIG. 6 shows a node configuration of a conventional transparent optical network. As shown in FIG. 6A, the transmission node includes an input-side WSS 11 and an output-side WSS 12. The WSS 11 has one input port for inputting a wavelength multiplexed signal and a plurality of output ports for outputting the wavelength multiplexed signal, and connects to which output port a signal (optical path) input from the input port for each wavelength. It is a switch that can be selected. When an optical signal is input from the add port to the input side WSS 11c, either the output side WSS 12a or WSS 12b is selected and output to each route. 6B, an optical signal is input from the route 1, the wavelength of the optical signal is selected by the WSS 21a, and the WSS 22a, the WSS 22b, or the WSS 22c is selected. Is output. The optical signal input from the route 2 is wavelength-selected by the WSS 21b and output to either the WSS 22a, the WSS 22b, or the WSS 22c. That is, in the conventional node configuration, the signal light from the add port can be transmitted only to either the route 1 or the route 2 on the output side on the transmission side. On the receiving side, only the route 1 or the route 2 on the input side can be taken out by the drop port.

  Therefore, in the conventional transparent optical network, when a failure occurs, the transmitting node switches the signal light from the add port to another route, and the receiving node drops only the signal light from the switched route. Since the optical signal is not transferred on the path where the failure has occurred and cannot be monitored, there is a problem that it is not known which relay node has the failure.

The present invention has been made in view of the above, if there is a failure in the nodes or the optical fiber transmission path in transparent optical network, where it is possible to identify whether there has been a failure of Transparent Optical Network及beauty trans An object of the present invention is to provide a parent optical network fault monitoring method.

  FIG. 1 is a diagram for explaining the principle of the present invention.

The present invention (Claim 1 ) includes a plurality of optical demultiplexing means 110 provided on the input side for each route,
A plurality of wavelength selective switches 120 provided on the output side;
An optical demultiplexing means 130 for distribution connected to the add port;
Fault monitoring means;
Control means
Consists of
The optical demultiplexing means 110 demultiplexes the optical signal input from the route and outputs it to the wavelength selective switch.
The distribution optical demultiplexing means 130 demultiplexes the optical signal to the wavelength selective switches 120a and 120b connected to the output side paths of both the optical path path and the detour optical path path at the time of failure,
The wavelength selective switches 120a and 120b connected to the output-side route select wavelengths of the optical signals input from the optical demultiplexing unit 110 and the distribution optical demultiplexing unit 130, and output the selected signals to the respective routes.
Among the wavelength selective switches 120 on the output side, the wavelength selective switch 120d connected to the drop port selects the wavelength of the optical signal input from the optical demultiplexing means 110 and outputs the wavelength to the drop port.
Among the wavelength selection switches 120 on the output side, the wavelength selection switch 120c connected to the monitor port selects the wavelength of the optical signal input from the optical demultiplexing means 110 and outputs the wavelength to the monitor port.
The failure monitoring means has a failure monitoring function for receiving the signal light output to the monitor port and monitoring the failure,
The control means has a control information transmission / reception function for transmitting / receiving control information to / from the wavelength selective switch 120, and a control function for controlling the wavelength selective switch 120 based on the control information, and a node device for detecting a failure
Or
For each route, a plurality of wavelength selective switches A provided on the input side,
A plurality of wavelength selective switches B provided on the output side;
An optical demultiplexing means connected to the add port;
Fault monitoring means;
Control means
Consists of
The wavelength selective switch A on the input side selects the wavelength of the optical signal input from the route and outputs it to the wavelength selective switch B on the output side.
The distribution optical demultiplexing means demultiplexes the optical signal to the wavelength selective switch B connected to the output side path of both the optical path path at the time of failure and the detour optical path path,
The wavelength selective switch B connected to the output side path selects the wavelength of the optical signal input from the input side wavelength selective switch A and the distribution optical demultiplexing means, and outputs the optical signal to each path.
Of the wavelength selective switch B on the output side, the wavelength selective switch connected to the drop port selects the wavelength of the optical signal input from the wavelength selective switch A on the input side and outputs it to the drop port.
Of the wavelength selective switch B on the output side, the wavelength selective switch connected to the monitor port selects the wavelength of the optical signal input from the wavelength selective switch A on the input side and outputs it to the monitor port.
The failure monitoring means has a failure monitoring function for receiving the signal light output to the monitor port and monitoring the failure,
The control means includes a control information transmission / reception function for transmitting / receiving control information for the wavelength selective switch A and the wavelength selective switch B, a control function for controlling the wavelength selective switch A and the wavelength selective switch B based on the control information,
A plurality of node devices including a node device for detecting a failure having:
A transmission line connecting input ports and output ports of a plurality of node devices;
A network management device having a function of controlling and managing a node;
A transparent optical network system comprising:
When the network management apparatus changes to an optical path route that is bypassed because a failure has occurred in a certain optical path route, a wavelength selective switch or a wavelength selective switch B is connected to the control means of each node on the optical path route. Control information exchanging means for exchanging control information for controlling
The control means of the node device controls the wavelength selective switch or the wavelength selective switch B after controlling the wavelength selective switch or the wavelength selective switch B based on the control information from the network management device and holding the optical path path at the time of failure. Then, the detouring optical path route is set, and then the optical signal inserted by the distributing optical demultiplexing means is distributed to both the optical path route at the time of failure and the detouring optical path route, and then connected to the drop port. A control means for controlling the wavelength selective switch or the wavelength selective switch B to output an optical signal input from the detour optical path route to the drop port;
The control means of the passing node and receiving node of the optical path path at the time of failure controls the wavelength selective switch or wavelength selective switch B connected to the monitor port to monitor the optical signal input from the optical path path at the time of failure This is an optical network system characterized in that it is a control means that outputs to a communication port and monitors the failure by the failure monitoring means.

According to the present invention (claim 2 ), a plurality of optical branching means, wavelength selecting means, failure monitoring means, control means, and distributing optical demultiplexing connected to an add port are provided on the input side for each route. Means,
Have
The optical branching unit has a function of demultiplexing an optical signal input from another node and outputting it to the wavelength selecting unit,
The distribution light branching unit has a function of branching signal light incident from an add port and outputting the branched signal light to the wavelength selecting unit.
The wavelength selection means has a wavelength selection function of switching the branched signal light based on the wavelength and outputting it to the output port, drop port or monitor port ,
The failure monitoring means includes a fault monitoring function of monitoring the fault that has received the optical signal output to the monitor port,
The control means has a control information transmission / reception function for transmitting / receiving control information for the wavelength selection function of the wavelength selection means, and a control function for controlling the wavelength selection means based on the control information,
A transparent optical network having a network management device that has a function of controlling and managing nodes by connecting a plurality of nodes whose input ports and output ports are connected to other communication devices via the transmission route. In
The network management device
When changing to an optical path that bypasses because a failure has occurred in the path of an optical path,
A control information exchanging step for exchanging control information for selecting the wavelength selection means with the control means of each node on the optical path route;
The node group control means, based on the control information received in the control information exchange step, to control the wavelength selection means to hold the optical path path at the time of failure;
A node group control means for setting an optical path route that controls and bypasses the wavelength selection means;
The optical branching means of the transmission node distributes the inserted optical signal to both the optical path path at the time of failure and the detour optical path path;
The control means of the receiving node controls the drop port wavelength selection means to select the optical signal input from the detour optical path route and output to the drop port;
The control means of the passing node and the receiving node of the optical path path at the time of the failure controls the wavelength selecting means for monitoring, selects the optical signal input from the optical path path at the time of the failure, and outputs it to the monitoring port, And a step of monitoring the failure by the failure monitoring means.

  As described above, in a transparent optical network, the optical signal inserted at the transmitting node is distributed to both the optical path route at the time of failure and the detouring optical path route, and the wavelength selection function for monitoring is used at the passing node and the receiving node. By outputting the optical signal from the optical path at the time of failure to the monitor port and monitoring it, the failure location can be specified.

  In addition, an optical coupler for distribution of the node device is provided in the add port, a plurality of wavelength selective switches (WSS) are provided on the output side, and one of the WSSs is used for monitoring that is connected to the monitor port. Whether or not a failure has occurred can be determined based on the output from the WSS.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<First Embodiment of Node Configuration>
FIG. 2 is a diagram showing a node configuration according to an embodiment of the present invention.

  FIG. 4A shows the configuration of the transmitting node, and FIG. 4B shows the configuration of the receiving node. As shown in the figure, an optical coupler for distribution is provided at a transmission side node, a plurality of WSSs are provided at a reception side node, and one WSS is used for monitoring.

  The transmission side node 100 is provided with an optical coupler 110a on the path 1 on the input side, an optical coupler 110b on the path 2, and a distribution optical coupler 130 to which an optical signal on which optical path information is superimposed is input from the add port. A plurality of WSSs 120 are provided on the output side, and among them, optical signals from the optical couplers 110a, 110b, and 130 are input to the WSSs 120a and 120b. The WSS 120c receives the optical signals from the optical couplers 110a and 110b, and outputs the wavelength-selected optical signal to the monitor port. The WSS 120d receives optical signals from the optical couplers 110a and 110b, and outputs wavelength-selected signal light to the drop port.

  The reception side node 200 has the same configuration as that of the transmission node 100.

  Each WSS of the transmission side node 100 and the reception side node 200 selects a wavelength from the input signal light by control from a management control function unit (not shown).

  In the above configuration, in the transmission side node 100, for example, when an optical signal is input from the path 1 to the input side optical coupler 110a, it is distributed to the output side WSS 120a, WSS 120b, WSS 120c, and WSS 120d. On the other hand, when an optical signal is input from the add port to the distribution optical coupler 130, it is distributed to the WSS 120a and WSS 120b and output. Thus, the WSS 120a and the WSS 120b select wavelengths of the optical signals input from the optical couplers 110a and 110b and the distribution optical coupler 130, and output the optical signals to the route 1 and the route 2, respectively.

  In the receiving side node 200, the optical signal from the route 1 is input to the input side optical coupler 210a, and the optical coupler 210a outputs it to the output side WSS 220a, WSS 220b, WSS 220c, and WSS 220d. Similarly, the optical signal from the route 2 is input to the optical coupler 210b, and the optical coupler 210b outputs the output signal to the WSS 220a, WSS 220b, WSS 220c, and WSS 220d on the output side. When the optical path information is input from the add port, the distribution optical coupler 230 to be connected distributes and outputs the optical signal to the WSS 220a connected to the route 1 and the WSS 220b connected to the route 2. Note that tone modulation or the like can be used for superimposing the optical path information.

  Only the optical signal from the input-side optical coupler connected to the path used in the bypass optical path is selected by the output-side WSS 220d and output to the drop port.

  The transmission side node of the present invention includes a distribution optical coupler, and the reception side node includes a monitor port. Even if an optical path to be detoured after a failure occurs in the optical network, the optical signal is distributed to both the optical path route at the time of the failure and the detour optical path route at the transmitting side node. In the receiving node, the optical signal input from the optical path route at the time of failure is output to the monitor port by the WSS 200c to monitor the optical path information. Therefore, in the present invention, an optical signal can be transmitted and received through the optical path at the time of failure even after the bypass optical path is set.

<Second Embodiment of Node Configuration>
In the above embodiment, an optical coupler is provided on the input side of the nodes 1 and 2 to distribute optical signals. However, as another configuration example, a transmission node and a reception node are as shown in FIG. It is possible to adopt a configuration in which a WSS is provided on the input side.

  The configuration shown in FIG. 3 is a configuration in which a WSS 310a connected to the input-side route 1 and a WSS 310b connected to the route 2 are provided instead of the optical couplers 110a, 110b, 210a, and 210b in the above-described embodiment. It is.

  In the case of this configuration, the WSS 310a selects the wavelength of the optical signal input from the route 1, and outputs the wavelength to the WSSs 320a, 320b, 320c, and 320d on the output side. The WSS 310b selects the wavelength of the optical signal input from the route 2 and outputs it to the output WSSs 320a, 320b, 320c, and 320d.

  The distribution optical coupler 330 distributes the optical signal in which the optical path information is superimposed on the WSS 320a connected to the output-side route 1 and the WSS 320b connected to the route 2 in the same manner as the above-described embodiment. Output.

  The WSS 320 on the output side performs the same operation as in the previous embodiment.

  The transmission side node of the present invention includes a distribution optical coupler, and the reception side node includes a monitor port. Even if an optical path to be detoured after a failure occurs in the optical network, the optical signal is distributed to both the optical path route at the time of the failure and the detour optical path route at the transmitting side node. In the receiving node, the optical signal input from the optical path path at the time of failure is output to the monitoring port by the WSS 320c, and the optical path information is monitored. Therefore, in the present invention, an optical signal can be transmitted and received through the optical path at the time of failure even after the bypass optical path is set.

<Embodiment of network system>
FIG. 4 is a diagram for explaining a case where the present invention is applied to a transparent optical network. This figure shows a transparent optical network in which nodes A to I are connected by an optical fiber transmission line and transferred as an optical signal without performing electrical regenerative relay.

  The network includes optical branching means (for example, optical couplers 110a, 110b, 210a, and 210b in FIG. 2), wavelength selection means (for example, WSS 120a, 120b, 220a, and 220b in FIG. 2), and failure monitoring means (for example, , 220c) of FIG. 2 and a control unit 400, and there are a plurality of nodes whose input ports and output ports are connected via a transmission line. Accordingly, each node has the following functions.

  The optical branching unit has a function of branching signal light incident from the add port. The wavelength selection unit has a wavelength selection function of switching the branched signal light based on the wavelength and outputting the switched signal light to the output port or the drop port. The failure monitoring means has a failure monitoring function for receiving the signal light output to the monitor port and monitoring the failure. A control information transmission / reception function for transmitting / receiving control information for the wavelength selection function of the wavelength selection unit; and a control function for controlling the wavelength selection unit based on the control information.

  Further, the network includes a network management device 500 having a function of controlling and managing each of the above nodes.

  When the network management apparatus 500 changes to a detoured optical path route because a failure has occurred in a certain optical path route, the following operation is performed.

  1) Exchange control information for selecting wavelength selection means with the control unit 400 of each node on the optical path route.

  2) The node group control unit 400 controls the wavelength selection unit based on the control information exchanged in 1) to hold the optical path path at the time of failure.

  3) The node group control unit 400 controls the wavelength selection unit to set an optical path route to be bypassed.

  4) The optical branching means (for example, the optical coupler 130 in FIG. 2) of the transmission node converts the optical signal to be inserted into both the optical path path at the time of failure and the detour optical path path (for example, the path 1 in FIG. Distribute to route 2).

  5) The control unit 400 of the receiving node controls the drop port wavelength selecting means (for example, WSS 220d in FIG. 2) to select the optical signal input from the detour optical path route and output it to the drop port.

  6) The control unit 400 of the passing node and receiving node of the optical path path at the time of the failure controls the monitoring wavelength selection means (for example, WSS 220c in FIG. 2) to output the optical signal input from the optical path path at the time of the failure. Select and output to the monitor port, and the failure is monitored by the failure monitoring means.

  Only the optical signal from the input-side optical coupler connected to the path used in the optical path at the time of the failure is selected by the output-side WSS 220c and output to the monitor port. The output from the monitoring port is monitored at all nodes on the optical path path at the time of failure. If an optical path monitor signal is output at a certain node and output from a subsequent node cannot be obtained, it is determined that a failure has occurred between the output side WSS of the node and the optical coupler of the subsequent node. be able to.

  With the node configuration as shown in the above embodiment, when a failure occurs in node C in the network (FIG. 4A), and an optical path b that bypasses in each node is set and recovered (FIG. 4) In (B)), since the optical path a remains, it is possible to specify the location of the failure.

  The present invention is not limited to the above-described embodiment, and various modifications and applications can be made within the scope of the claims.

  The present invention is applicable to a failure monitoring technique for a transparent optical network.

It is a figure for demonstrating the principle of this invention. It is a block diagram of the transmission node and the reception node in one embodiment of this invention. It is a node block diagram in other embodiment of this invention. It is a figure for demonstrating the case where this invention is applied to a transparent optical network. It is a figure for demonstrating the conventional problem. It is the conventional node block diagram.

Explanation of symbols

100 node, transmitting node 110, first optical demultiplexing means, optical coupler 120 wavelength selective switch (WSS)
130 optical demultiplexing means for distribution, optical coupler for distribution 200 receiving side node 210 optical coupler 220 wavelength selective switch (WSS)
230 Optical coupler for distribution 300 Node 310 Wavelength selective switch (WSS)
320 Wavelength selective switch (WSS)
330 Distribution Optical Coupler 400 Control Unit 500 Network Management Device

Claims (2)

A plurality of optical demultiplexing means provided on the input side for each route;
A plurality of wavelength selective switches provided on the output side;
An optical demultiplexing means connected to the add port;
Fault monitoring means;
Control means
Consists of
The optical demultiplexing unit demultiplexes the optical signal input from the path, and outputs the demultiplexed signal to the wavelength selective switch.
The distribution optical demultiplexing means demultiplexes the optical signal to the wavelength selective switch connected to the output side of both the optical path path and the detour optical path path at the time of failure,
The wavelength selective switch connected to the output side path selects the wavelength of the optical signal input from the optical demultiplexing means and the distribution optical demultiplexing means, and outputs the wavelength to each path,
Among the wavelength selective switches on the output side, the wavelength selective switch connected to the drop port selects the wavelength of the optical signal input from the optical demultiplexing means and outputs the wavelength to the drop port.
Among the wavelength selection switches on the output side, the wavelength selection switch connected to the monitor port selects the wavelength of the optical signal input from the optical demultiplexing means and outputs the wavelength to the monitor port.
The failure monitoring means has a failure monitoring function of receiving a signal light output to the monitor port and monitoring the failure,
The control means has a control information transmission / reception function for transmitting / receiving control information for the wavelength selective switch, and a control function for controlling the wavelength selective switch based on the control information, and a node device for detecting a failure
Or
For each route, a plurality of wavelength selective switches A provided on the input side,
A plurality of wavelength selective switches B provided on the output side;
An optical demultiplexing means connected to the add port;
Fault monitoring means;
Control means
Consists of
The wavelength selective switch A on the input side selects the wavelength of the optical signal input from the route and outputs it to the wavelength selective switch B on the output side.
The distribution optical demultiplexing means demultiplexes the optical signal to the wavelength selective switch B connected to the output side of both the optical path path at the time of failure and the detour optical path path,
The wavelength selective switch B connected to the output side path selects the wavelength of the optical signal input from the input side wavelength selective switch A and the distributing optical demultiplexing means, and outputs the optical signal to each path. ,
Of the wavelength selective switch B on the output side, the wavelength selective switch connected to the drop port selects the wavelength of the optical signal input from the wavelength selective switch A on the input side and outputs the wavelength to the drop port.
Of the wavelength selection switch B on the output side, the wavelength selection switch connected to the monitor port selects the wavelength of the optical signal input from the wavelength selection switch A on the input side and outputs the wavelength to the monitor port.
The failure monitoring means has a failure monitoring function of receiving a signal light output to the monitor port and monitoring the failure,
The control means includes a control information transmission / reception function for transmitting / receiving control information for the wavelength selective switch A and the wavelength selective switch B, a control function for controlling the wavelength selective switch A and the wavelength selective switch B based on the control information,
A plurality of node devices including a node device for detecting a failure having:
A transmission line connecting input ports and output ports of the plurality of node devices;
A network management device having a function of controlling and managing a node;
A transparent optical network system comprising:
When the network management device changes to an optical path route that bypasses because a failure has occurred in a certain optical path route, the wavelength selective switch or wavelength between the control means of each node on the optical path route is changed. Comprising control information exchanging means for exchanging control information for controlling the selection switch B;
After the control means of the node device controls the wavelength selective switch or wavelength selective switch B based on control information from the network management device and holds the optical path path at the time of failure, the wavelength selective switch or wavelength An optical path route to be bypassed is set by controlling the selection switch B, and then the optical signal inserted by the distributing optical demultiplexing means is distributed to both the optical path route at the time of failure and the bypass optical path route. Control means for controlling a wavelength selective switch or wavelength selective switch B to be connected to the drop port later and outputting an optical signal input from the detour optical path route to the drop port;
An optical signal input from the optical path route at the time of failure by the control means of the passing node and the receiving node of the optical path route at the time of failure controlling the wavelength selective switch or wavelength selective switch B connected to the monitor port Is a control means for outputting a fault to a monitoring port and monitoring the fault by the fault monitoring means.
An optical network system characterized by that. For each route, a plurality of optical branching means provided on the input side , wavelength selection means, failure monitoring means, control means, and distribution optical demultiplexing means connected to the add port,
Have
The optical branching unit has a function of demultiplexing an optical signal input from another node and outputting it to the wavelength selecting unit,
The distribution light branching unit has a function of branching signal light incident from an add port and outputting the branched signal light to the wavelength selecting unit.
The wavelength selection means has a wavelength selection function of switching the branched signal light based on the wavelength and outputting it to the output port, drop port or monitor port ,
The failure monitoring means includes a fault monitoring function of monitoring the fault that has received the optical signal output to the monitor port,
The control means has a control information transmission / reception function for transmitting / receiving control information for the wavelength selection function of the wavelength selection means, and a control function for controlling the wavelength selection means based on the control information,
A transparent optical network having a network management device that has a function of controlling and managing nodes by connecting a plurality of nodes whose input ports and output ports are connected to other communication devices via the transmission route. In
The network management device is
When changing to an optical path that bypasses because a failure has occurred in the path of an optical path,
A control information exchange step for exchanging control information for selecting the wavelength selection means with the control means of each node on the optical path route;
A step wherein said control means of said node group, based on said control information received by the control information exchange step, holding the optical path route at the time of failure by controlling the wavelength selection means,
The control means of the node group setting an optical path route that controls and bypasses the wavelength selection means;
The optical branching means of the transmission node distributes the inserted optical signal to both the optical path path at the time of the failure and the detour optical path path;
The control means of the receiving node controls the drop port wavelength selection means to select an optical signal input from the detour optical path route and output to the drop port;
Wherein the control means of the passing and receiving nodes of the failure time of the optical path route, and selects and outputs the optical signal inputted from the optical path route at the time of failure by controlling the wavelength selection means for monitoring to the monitoring port And monitoring the failure by the failure monitoring means;
A transparent optical network fault monitoring method characterized by comprising:

Images