JP4545327B2 - Switching device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a switching device for switching a large-capacity signal path such as an ADM (Add / Drop Multiplexer) device in a ring network or a cross connect device in a mesh network.
[0002]
[Prior art]
FIG. 3 is a diagram showing an example of a configuration of a conventional switching device having a redundant configuration (see Japanese Patent Laid-Open No. 10-257580). In FIG. 3, the receiving-side IF board 101 includes a processing unit 101a and a branching unit 101b. The processing unit 101a performs interface processing of signals sent from other devices, and the branching unit 101b is connected to the processing unit 101a. Each processed signal is branched and sent to the active switching unit 102 and the standby switching unit 104.
[0003]
The switching units 102 and 104 both perform switching processing with the same connection pattern, and send signals to the transmission side IF board 103 connected to the working path and the transmission side IF board 105 connected to the backup path. The transmission side IF board 103 includes a selection unit 103a and a processing unit 103b, and the transmission side IF board 105 includes a selection unit 105a and a processing unit 105b. The selection units 103a and 105a select one of the signals sent from the switching units 102 and 104, and the processing units 103b and 105b perform interface processing on the selected signals, respectively. Output to the backup path.
[0004]
Here, when the active switching unit 102 is operating normally, the reception-side IF board 101, the switching unit 102, and the transmission-side IF boards 103 and 105 operate. On the other hand, when a failure occurs in the working system switching unit 102, the working system switching unit 102 is switched to the standby system switching unit 104. In SDH (Syncronous Digital Hyerachy) and the like, in APS (Automatic Protection Switching) switching that automatically switches when a transmission path failure occurs, there are two paths, a working path and a backup path, as connection patterns of the switching unit during the failure switching operation. There is a need for a bridge connection for branching signals. When the switching units 102 and 104 perform this bridge connection, the signal sent from the reception side IF board 101 is branched inside the switching parts 102 and 104 and is output to the transmission side IF boards 103 and 105.
[0005]
4 and 5 are diagrams for explaining connection contents in a conventional redundant switch configuration. FIG. 4A is a diagram showing a ring switching bridge connection form of an add / drop signal in an ADM device used in a ring network. In FIG. 4A, the optical signal input from the W-side add / drop port to the switch SW is branched and output to the working transmission line W0 and the backup transmission line E1. On the other hand, FIG.4 (b) is a figure which shows a span switching bridge connection form. In FIG. 4B, the optical signal input from the working transmission line W0 to the switch SW is output to the working transmission line E0 and the standby transmission line E1.
[0006]
FIG. 5 shows a connection form when the switch SW shown in FIGS. 4A and 4B is used as a working switch and a spare switch for redundancy. In Fig 5, the active switches SW100 and spare switch SW101 has an output function of each output to two output ports branches the input signal in the interior. For example, the working switch SW100 branches and outputs the signal input from the working transmission line W0 to the selection switches SS100 and SS101 by the internal branching unit 130. Further, when the active switch SW100 and the spare switch SW101 are operating normally, they are switched and output with the same connection pattern.
[0007]
The selection switches SS100 and SS101 are for selectively outputting the input optical signals to the outside. When the current switch SW100 is operating normally, the signals input from the current switch SW100 are selected and output. When only SW100 fails, the signal input from spare switch SW101 is selectively output.
[0008]
[Problems to be solved by the invention]
By the way, the above-described conventional switching device is suitable for electrical signal switching processing. However, in recent years, the capacity has increased with the spread of various multimedia including the Internet, and wavelength multiplexing by the WDM communication system has been promoted. When a switching device using an optical switch is applied to an optical network in which path switching for each wavelength is required due to conversion, there are the following problems.
[0009]
First, it is easy to branch a signal by an electric signal. However, in the case of an optical signal, there is a problem that the optical intensity is attenuated by half each time the optical signal is branched, and the signal state of the optical signal deteriorates. . For example, in the conventional switching device shown in FIG. 3, the optical signal is attenuated by half at two points of the branching unit 101 b of the receiving IF board 101 and the branching unit (not shown) in each switching unit 102 and 104. In addition, the light intensity of the optical signal is switched to 1/4 or less. Similarly, in the switching device shown in FIG. 5, the optical signal is branched twice by the branching unit 120 and the branching unit 130 in the working switch SW100. As a result, the light intensity of the optical signal is ¼ or less. The output is switched.
[0010]
Further, a general optical switch applicable to a switching device has a problem that branching of an optical signal is essentially difficult because an optical path is switched by reflection of a movable mirror or the like. Furthermore, it is necessary to incorporate an optical component such as an optical coupler as a branching portion of the optical signal, which makes it difficult to reduce the size of the switching device and increases the cost.
[0011]
The present invention has been made in view of the above, and an object of the present invention is to obtain a switching device that can reduce the loss of an optical signal and can reduce the size and cost of the device.
[0012]
[Means for Solving the Problems]
In order to achieve the above object, a switching device according to the present invention has a plurality of input ports and a plurality of output ports, and a first switching means for switching and connecting between an input port and an output port according to a switching instruction, A second switching unit having a plurality of input ports and a plurality of output ports, and switching and connecting between the input port and the output port in accordance with a switching instruction; and an external input-side working transmission line of the first switching unit. A first switching means side first input port that is one of the input ports and a second switching means side first input port that is one of the input ports of the second switching means; The first branching means for branching and outputting the optical signal input from the two first input ports, and the first input port of the first switching means for the external input side spare transmission line. Switching means side second input port And the second switching means side second input port which is one of the input ports of the second switching means, and the optical signal input from the input side auxiliary transmission line is connected to the two second input ports. A second branching means for branching output, a first switching means-side first output port that is one of the output ports of the first switching means, and a second that is one of the output ports of the second switching means. A first selection for input-connecting the switching means side first output port, selecting one of the two optical signals output from the first output port, and outputting the selected one to the external output side working transmission line And a second switching means side second output port which is one of the output ports of the first switching means and one of the output ports of the second switching means. Are connected to each other, and the optical signals output from the two second output ports When the operation of the second selection means for selecting one of the optical signals and outputting it to the external output side auxiliary transmission line and the operation of the first and second switching means are normal, the first and second The optical signal branched by the first branching means to the first input port on the first switching means side is switched to the first selection means via the first output port on the first switching means side. Connecting the optical signal branched to the first input port on the second switching means side by the first branching means to the second selection means via the second output port on the second switching means side, Switching control means for performing control, wherein the first selection means selects an optical signal input from the first output port on the first switching means side of the first switching means, and the output-side working transmission line And the second selecting means outputs the second switching means. When the optical signal input from the second switching means side second output port of the stage is selected and output to the output side auxiliary transmission path, the switching control means operates the first and second switching means. When a failure occurs in the output-side working transmission line in a normal state and then a failure occurs in the second switching unit, the first switching unit in which no failure has occurred The optical signal branched to the first input port on the first switching means side by the branching means is switched and connected to the second selection means connected to the output side auxiliary transmission line in which no failure has occurred. And the first switching unit connects the optical signal branched to the first input port on the first switching unit side to the output-side active transmission line in which a failure has occurred under the control of the switching control unit. From the first selection means, the failure Switched to the second selection means connected to the output side spare transmission line that has not occurred, and the second selection means is an optical signal input from the first switching means in which no failure has occurred. Is output to the output side auxiliary transmission line .
[0014]
The switching device according to the next invention is characterized in that, in the above invention, the first and second switching means are optical switches.
[0016]
The switching device according to the next invention is characterized in that, in the above invention, the first and second branching means are optical couplers.
[0018]
The switching device according to the next invention is characterized in that, in the above invention, the first and second selection means are optical switches.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Exemplary embodiments of a switching device according to the present invention will be explained below in detail with reference to the accompanying drawings.
[0023]
FIG. 1 is a diagram showing a configuration of a switching device according to an embodiment of the present invention. In FIG. 1, this switching device is a switching device that functions as an ADM device applied to a ring network. Each of the west side, the east side, and the add / drop side has branch units 10, 11, 20, 21, 30, and 31 that branch the input optical signal. It is output to each of SW1. Further, selection switches SS10, SS11, SS0 that select optical signals output from the switches SW 0 , SW 1 and output them to the transmission lines to be connected to the west side, the east side, and the add / drop side, respectively. , SS1, SS30, SS31.
[0024]
The switches SW0 and SW1 have a redundant configuration, and switch the optical signal input to the input port from each of the branch portions 10, 11, 20, 21, 30, and 31 on the west side, east side, and add / drop side, The data is output to the destination output port, and is output to each transmission line via each selection switch SS10, SS11, SS0, SS1, SS30, SS31.
[0025]
Therefore, the switches SW0 and SW1 are connected in advance to all the branch portions 10, 11, 20, 21, 30, and 31 and the selection switches SS10, SS11, SS0, SS1, SS30, and SS31 on the west side, east side, and add drop side, respectively. It is connected.
[0026]
The network switching control unit 1 determines the state of the entire network in which this switching device is used, and determines the switching connection pattern of the switches SW0 and SW1. That is, the network switching control unit 1 grasps the failure state of the transmission path constituting the network and the failure state of each switching device, and outputs an instruction corresponding to this failure to the device redundancy switching unit 2.
[0027]
The device redundancy switching unit 2 switches the switches SW0 and SW1 and the selection switches SS10, SS11, SS0, SS1, and SS30 based on the device failure information 3 such as the failure of the switches SW0 and SW1 and the switching instruction from the network switching control unit 1. , SS31 switching state is determined and switching control is performed. For example, the device failure information 3 monitors the optical signal intensity input to the selection switches SS10, SS11, SS0, SS1, SS30, and SS31, and detects the state of each switch SW0 and SW1 based on the monitoring result. It is obtained by doing.
[0028]
Here, the apparatus redundancy switching unit 2 can instruct different switches and connection states to the switches SW0 and SW1 as necessary, and each of the switches SW0 and SW1 is a light such as a coupler that performs optical branching therein. Does not have a branch.
[0029]
In FIG. 1, the optical signal input from the working transmission line LW0 on the west side is input to each input port of the switches SW0 and SW1. The optical signal input to the switch SW0 is switched by the switch SW0 and output to the selection switch SS0 connected to the east-side working transmission line LE0. The optical signal input to the switch SW1 is switched by the switch SW1 and output to the selection switch SS1 connected to the standby transmission line LE1 on the east side. The selection switch SS0 selects the optical signal input from the switch SW0 and outputs this optical signal to the working transmission line LE0 (see route R0 in FIG. 1). In addition, the selection switch SS1 selects the optical signal input from the switch SW1, and outputs this optical signal to the backup transmission line LE1 (see the route R1 in FIG. 1).
[0030]
That is, for the optical signals branched by the branching unit 10, the switches SW0, SW1 are switched output to different selection switch S S0, SS1. In this case, the optical signal from the switch SW1 is not input to the selection switch SS0. Further, the optical signal from the switch SW0 is not input to the selection switch SS1. As a result, this switching device branches and outputs the optical signal input from the working transmission line LW0 to the working transmission line LE0 and the standby transmission line LE1, even if each of the switches SW0 and SW1 does not have an optical branching unit. Can do.
[0031]
Here, when the switches SW0 and SW1 are operating normally and a failure occurs in the working transmission line LE0, the network can be maintained by the redundant configuration of the backup transmission line LE1.
[0032]
FIG. 2 is a diagram illustrating a connection configuration in the case where a failure occurs due to a failure of the switch SW1 in the switching device illustrated in FIG. In FIG. 2, when a failure occurs in the switch SW1, the device redundancy switching unit 2 detects the occurrence of the failure in the switch SW1 based on the device failure information 3, and with respect to the normally operating switch SW0, The route R0 that has been connected to the selection switch SS0 is switched to the route R10 that connects the branch unit 10 to the selection switch SS1 that connects the backup transmission line LE1 in which no failure has occurred. This is because the branch unit 10 → switch SW0 → selection switch SS1 route and the branch unit 10 → switch SW1 → selection switch SS0 route are not connected, and so-called bridge connection is not established.
[0033]
As a result, the optical signal input from the working transmission line LW0 is output to the standby transmission line LE1 in which no failure has occurred via the normally operating switch SW0 and selection switch SS1. That is, the switching pattern by the switches SW0 and SW1 is changed so that a path through which the optical signal is conducted end-to-end.
[0034]
In this embodiment, even if the switches SW0 and SW1 do not have an optical branching unit such as a coupler, the switches SW0 and SW1 branch the optical signal input by the switching pattern for switching output to different selection switches SS0 and SS1. Even if a failure occurs in either of the switches SW0 and SW1, the switching pattern of the switches SW0 and SW1 can be changed to secure an end-to-end route, and one branching unit can be provided. Since switching connection is used, switching connection with little loss of optical signal can be realized.
[0035]
【The invention's effect】
As described above, according to the present invention, when the operation of the first and second switching means is normal , the switching control means uses the first branching means with respect to the first and second switching means. The optical signal branched to the first switching means side first input port is switched and connected to the first selection means, and the optical signal branched to the second switching means side first input port by the first branching means is second. When a failure occurs in the output working transmission line when the operation of the first and second switching means is normal, and then a failure occurs in the second switching means. Second selection for connecting the optical signal branched to the first switching means side first input port by the first branching means with respect to the first switching means to the output side backup transmission line in which no failure has occurred by connection switching to the means, the first and second Even if the switching unit does not have a branching unit such as an optical coupler, the input signal is redundantly branched and output, so that even when one of the first and second switching units is abnormal, it is ensured. Since the end-to-end conduction path is ensured, the number of branch portions is reduced, switching with less signal loss can be performed, and a switching device that is reduced in size and cost can be realized. There is an effect.
[0036]
According to the next invention, since the first and second switching means are constituted by optical switches and an optical branching unit such as an optical coupler is not required, the switching is simplified and reduced in size and cost is reduced. There exists an effect that an apparatus is realizable.
[0037]
According to the next invention, the first and second branching means are constituted by optical couplers, and branch output is made with the optical signal, so that the switching device that can be switched and connected without changing the optical signal is provided. There is an effect that it can be realized.
[0038]
According to the next invention, since the first and second selection means are configured by optical switches and are selected and output as optical signals, a switching device that can be switched and connected without changing the optical signal is provided. There is an effect that it can be realized.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a switching device according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a connection state when a failure occurs in a switch in the switching device illustrated in FIG. 1;
FIG. 3 is a diagram illustrating an example of a configuration of a conventional switching device.
FIG. 4 is a diagram for explaining the operation of a switch used in a conventional switching device.
FIG. 5 is a diagram showing a configuration of a conventional switching device using the switch shown in FIG. 4;
[Explanation of symbols]
1 network switching control unit, 2 device redundancy switching unit, 3 device failure information, 10, 11, 20, 21, 30, 31 branching unit, SW0, SW1 switch, SS10, SS11, SS0, SS1, SS30, SS31 selection switch, LW0, LE0 Working transmission line, LW1, LE1 Backup transmission line, R0, R1, R10 route.

Claims (4)

A first switching means that has a plurality of input ports and a plurality of output ports, and switches and connects between the input port and the output port according to a switching instruction;
A second switching means having a plurality of input ports and a plurality of output ports, and switching and connecting between the input port and the output port according to a switching instruction;
The first input port of the first switching means, which is one of the input ports of the first switching means, and the second switching means, which is one of the input ports of the second switching means, on the external input side working transmission line. A first branching unit connected to the first input port on the side and branching and outputting the optical signal input from the input-side working transmission line to the two first input ports;
An external input side spare transmission line is a first switching means side second input port which is one of the input ports of the first switching means and a second switching means which is one of the input ports of the second switching means. A second branching unit connected to the second input port on the side, and branching and outputting the optical signal input from the input side auxiliary transmission line to the two second input ports;
The first switching means side first output port which is one of the output ports of the first switching means and the second switching means side first output port which is one of the output ports of the second switching means are input-connected. First selecting means for selecting one of the two optical signals output from the first output port and outputting the selected optical signal to an external output side active transmission line;
The first switching means side second output port which is one of the output ports of the first switching means and the second switching means side second output port which is one of the output ports of the second switching means are input-connected. Second selecting means for selecting one of the two optical signals output from the second output port and outputting the selected optical signal to an external output side auxiliary transmission line;
When the operations of the first and second switching means are normal, the first and second switching means are branched to the first input port on the first switching means side by the first branching means. The optical signal is switched and connected to the first selection means via the first output port on the first switching means side, and the optical signal branched to the first input port on the second switching means side by the first branching means Switching control means for performing control to switch and connect to the second selection means via the second output port on the second switching means side ;
With
The first selection means selects an optical signal input from the first switching means side first output port of the first switching means and outputs the optical signal to the output side working transmission line, and the second selection means In the case where the optical signal input from the second switching means side second output port of the second switching means is selected and output to the output side auxiliary transmission line,
Said switch control means, before Symbol fault occurs in the output-side active transmission line in operation is normal states of the first and second switching means, then, if the second switching means fails, to said first switching means no failure occurs, the optical signal branched to the first switching means side first input port by the first branching means, said output side spare fault has not occurred causes switch connected to said second selecting means for connecting to the transmission line, have line control,
The first switching unit connects the optical signal branched to the first input port on the first switching unit side to the output-side active transmission line where a failure has occurred under the control of the switching control unit. Switching from the selection means to the second selection means connected to the output side auxiliary transmission line in which no failure has occurred,
The switching device characterized in that the second selection means outputs the optical signal input from the first switching means in which no failure has occurred to the output side spare transmission line .   The switching device according to claim 1, wherein the first and second switching means are optical switches. The switching device according to claim 1 or 2, wherein the first and second branching means are optical couplers. The switching device according to claim 1, wherein the first and second selection units are optical switches.

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