JP2008042244A - Optical cross-connection device and optical cross-connection control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce deterioration in signal quality due to crosstalk between optical paths while taking account of the impact of dynamic crosstalk and intra-crosstalk in an optical switch module. <P>SOLUTION: A wavelength multiplexed optical signal (wavelengths λ1-λn) inputted from a plurality (m) of wavelength multiplexed transmission paths is demultiplexed to optical signals of respective wavelengths and input to each input port. Optical signals of respective wavelengths output from each output port by cross-connection are multiplexed in correspondence with the plurality (m) of wavelength multiplexed transmission paths and output to each wavelength multiplexed transmission path as a wavelength multiplexed signal. In such an optical cross-connection device, I/O port of an optical switch module is divided into m regions for each wavelength multiplexed transmission path and the I/O ports corresponding to respective wavelengths are arranged in the m regions with such a regularity as a predetermined interval uncontiguous at least between the same wavelengths is ensured. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an optical cross-connect device and an optical cross-connect control method that switch a plurality of optical signal paths.

  In general, in an optical network system, an optical cross-connect device is used to switch a plurality of optical signal paths. An optical cross-connect device uniquely connects an arbitrary input line and output line in a switch unit arranged between a plurality of optical signal input units and an optical signal output unit, and changes the connection combination as required. (Patent document 1). For the switch unit used in such an optical cross-connect device, an optical switch that switches the optical signal as it is without converting the optical signal into an electrical signal is used from the viewpoint of simplicity of configuration, cost, and reliability. There are many cases.

  FIG. 4 shows a configuration example of an optical cross-connect device used in a wavelength division multiplexing optical transmission system. In FIG. 4, wavelength multiplexed optical signals S1 to Sm are respectively input from wavelength multiplexed optical transmission lines 1 to m (m is an integer of 2 or more), and wavelengths λ1 to λn are respectively output by wavelength demultiplexers 101-1 to 101-m. The optical signal is split into optical signals (n is an integer of 2 or more) and input to each input port of the optical switch module 100. The optical switch module 100 cross-connects n × m optical signals under the control of a switch control circuit (not shown), and outputs the optical signals to m sets of output ports for each of the wavelengths λ1 to λn. For each wavelength λ1 to λn output from the output port of the optical switch module 100, m sets of optical signals are wavelength multiplexers 102-1 to 102-m respectively corresponding to the wavelength multiplexed optical transmission lines 1 to m on the output side. And output as wavelength multiplexed optical signals S1 to Sm to the wavelength multiplexed optical transmission lines 1 to m, respectively.

  Here, when wavelength multiplexing is performed by the wavelength multiplexer 102, the wavelengths of the respective optical signals need to be different from each other. Generally, the wavelengths used for the wavelength multiplexed optical signals of the respective wavelength multiplexed optical transmission lines are respectively In many cases, λ1 to λn are the same. Therefore, optical signals having the same wavelength may be cross-connected to the n output ports of the optical switch module 100 corresponding to each wavelength multiplexer 102. In such a case, as shown in FIG. 5, a wavelength converter 103 is provided in part or all of the n output ports of the optical switch module 100 corresponding to each wavelength multiplexer 102, and wavelength competition occurs. In such a case, there is a configuration in which either wavelength is converted and then input to the wavelength multiplexer 102 for wavelength multiplexing. There is also a configuration in which the wavelength converter 103 is inserted on the input port side.

  FIG. 6 shows a first configuration example of the optical switch module 100. 6, the optical switch module 100 has a configuration in which an input optical fiber array 3a and an output optical fiber array 3b in which a plurality of (n × m in the example of FIG. 4) optical fibers are two-dimensionally arranged are opposed to each other. The angle of each optical fiber of the input optical fiber array 3a and the angle of each optical fiber of the output optical fiber array 3b are changed by a mechanical variable mechanism so that the optical coupling loss is reduced between the optical fibers to be connected. The light beam is spatially propagated by adjusting to.

  FIG. 7 shows a second configuration example of the optical switch module 100. 7, the optical switch module 100 includes a collimator array 1a, 1b in which a plurality of (n × m in the example of FIG. 4) collimators are two-dimensionally arranged and a plurality of (n × m in the same number) mirrors two-dimensionally. It is the structure which combined the MEMS (Micro Electric Mechanical System) mirror array 2 arrange | positioned in this. The collimator array 1a forming the input port group is connected to an input optical fiber array in which a plurality of (n × m) optical fibers are two-dimensionally arranged corresponding to each collimator. Connected to the collimator array 1b forming the output port group is an output optical fiber array in which a plurality of (n × m) optical fibers are two-dimensionally arranged corresponding to each collimator.

  The angle of each mirror of the MEMS mirror array 2 is controlled by the MEMS technique, and connection (switching of an optical path) between arbitrary input / output ports is possible depending on the reflection angle of each mirror. The example of FIG. 7 shows a situation where the optical path is switched from the output port 11 to the output port 12 by controlling the angle of the mirror 21 of the MEMS mirror array 2 facing the input port 10.

  FIG. 8 shows a third configuration example of the optical switch module 100. 8, the optical switch module 100 includes a collimator array 1a, 1b in which a plurality of (n × m in the example of FIG. 4) collimators are two-dimensionally arranged and a plurality of (n × m in the same number) mirrors two-dimensionally. This is a combination of the MEMS mirror arrays 2a and 2b arranged in FIG. The collimator array 1a forming the input port group is connected to an input optical fiber array in which a plurality (n × m) of optical fibers are two-dimensionally arranged in correspondence with each collimator. Connected to the collimator array 1b forming the output port group is an output optical fiber array in which a plurality of (n × m) optical fibers are two-dimensionally arranged corresponding to each collimator.

  The angles of the mirrors of the MEMS mirror arrays 2a and 2b are controlled by the MEMS technique, and any input / output port can be connected (switching of optical paths) by a combination of mirrors to be reflected. In the example of FIG. 8 (1), the angle of the mirror a1 of the MEMS mirror array 2a facing the input port is controlled, and the mirror reflected by the MEMS mirror array 2b is switched from the mirror b1 to the mirror b2, thereby changing the optical path to the output port. 11 shows a situation of switching from 11 to the output port 12. In this configuration example, two MEMS mirror arrays 2a and 2b are used, and the mirror b1 and the output port 11 of the MEMS mirror array 2b are opposed to each other, and the mirror b2 and the output port 12 are opposed to each other. The advantage that the incident angle of the light beam can be reduced to 0 is an advantage over the first configuration example and the second configuration example.

  Similarly, as shown in FIG. 8 (2), the optical path can be switched from the output port 11 to the output port 13. In this case, the locus of the light beam on the end face of the MEMS mirror array 2b is from the mirror b1. When the light passes through the mirror b2 and moves to the mirror b3, the light beam reflected by the mirror b2 whose angle is controlled independently of the mirrors b1 and b3 may cause crosstalk to the output port 12, the other output port 14, or the like. is there. Thus, when switching to non-adjacent output ports (for example, 11 to 13), it is necessary to pay attention to crosstalk with respect to other output ports.

  Although the light beam is shown as a line in the figure, the light beam has a predetermined spread (for example, Gaussian distribution). For example, even if the center of the light beam reflected by the mirror b2 is coupled to the output port 14, A situation can be considered in which the skirt portion away from the center of the beam is coupled to the output port 12. In this case, even if the amount of light coupled from the mirror b2 to the output port 12 is small, the incident angle is 0, resulting in a large crosstalk. Therefore, it is preferable not to pass the mirror b2 adjacent to the locus of the light beam by switching the optical path when moving from the mirror b1 to the mirror b3.

  In general, in the optical switch module shown in FIGS. 6 to 8 configured by a spatial optical system, the crosstalk between the input and output ports is set to a very low value, but this is static except when the optical path is switched. It means crosstalk. As described above, the phenomenon that the light beam is output to the other output port when the optical path is switched (the light beam reflected by the mirror b2 in FIG. 8 (2) is coupled to the output port 14 and the output port 12) is dynamic crossing. This is called “talk”, and shows a very large value in comparison with static crosstalk even in the moment when the optical path is switched in time, which is a factor causing degradation of optical signal quality (Non-Patent Document 1). ).

FIG. 9 shows the measurement result of the crosstalk characteristic of the optical switch module. Although the static crosstalk level becomes −60 dB or more after 10 ms or more, it can be seen that the maximum crosstalk of about −40 dB occurs instantaneously due to dynamic crosstalk.
Japanese Patent Laid-Open No. 06-292246 Electronics Letters, Vol.39, No.8, pp.678-679, 2003

By the way, the crosstalk in the optical switch module includes intracrosstalk in which the wavelengths of the crosstalk signal and the crosstalk signal are the same, and intercrosstalk in which the wavelengths are different from each other. In the case of intra crosstalk, when the crosstalk power ratio is x and the number of crosstalk signals is N, the optical signal power penalty is
-10log (1-2N√x)
Given in. On the other hand, the optical signal power penalty due to intercrosstalk is
-5log (1-2Nx)
Given in.

  FIG. 10 shows the relationship between crosstalk and optical signal power penalty. With respect to intra crosstalk and inter crosstalk, the case where noise depends on signal power (solid line) and the case where noise does not depend (broken line) are shown. It can be seen that the optical signal power penalty is greatly affected by intra-crosstalk that occurs when the wavelengths are the same.

  Here, at the input port of the optical switch module 100 of the optical cross-connect device shown in FIG. 4, the wavelengths input from the wavelength division multiplexing optical transmission lines 1 to m and demultiplexed by the wavelength demultiplexers 101-1 to 101-m, respectively. The optical signals of λ1 to λn and the wavelength assignment of each input port are generally arbitrary. If the wavelength multiplexed optical transmission lines 1 to m and the wavelengths λ1 to λn input by the switch control circuit are associated with the input ports, Good. Therefore, at the input port of the optical switch module 100, for example, the input port of the optical signal of wavelength λ1 demultiplexed by the wavelength demultiplexer 101-1, and the light of wavelength λ1 demultiplexed by the wavelength demultiplexer 101-2. Signal input ports may be adjacent.

  Similarly, the optical signals of wavelengths λ1 to λn respectively combined by the wavelength multiplexers 102-1 to 102-m corresponding to the wavelength multiplexed optical transmission lines 1 to m on the output side, and the allocation of the wavelengths of the output ports Is generally arbitrary, and it is sufficient that the wavelength multiplexed optical transmission lines 1 to m and the wavelengths λ1 to λn output from the switch control circuit correspond to the output ports. Therefore, at the output port of the optical switch module 100, for example, the output port of the optical signal having the wavelength λ1 combined by the wavelength demultiplexer 102-1, and the light having the wavelength λ1 combined by the wavelength multiplexer 102-2. Signal output ports may be adjacent.

  In the optical cross-connect device having the wavelength converter 103 shown in FIG. 5 as well, input ports for optical signals having the same wavelength may be adjacent to each other at the input port of the optical switch module 100. Furthermore, optical signals of the same wavelength may be cross-connected to each of the n output ports corresponding to the wavelength division multiplexing optical transmission lines 1 to m of the optical switch module 100, and these output ports may be adjacent to each other. is there.

  Here, in the input port and the output port of the optical switch module 100, the crosstalk power is determined by the distance between the port that gives the crosstalk and the port that receives the crosstalk, and the incident angle. In addition to being greatly affected by intra-crosstalk, the influence of dynamic crosstalk is also increased.

  The present invention provides an optical cross-connect device and an optical cross-connect control method capable of reducing signal quality degradation due to crosstalk between optical paths in consideration of the effects of dynamic crosstalk and intra-crosstalk in an optical switch module. The purpose is to do.

  A first invention includes an optical switch module having a plurality of m × n input ports and a plurality of m × n output ports, and wavelength multiplexed optical signals (wavelengths λ1 to λn) input from a plurality of m wavelength multiplexed optical transmission lines. : N is an integer greater than or equal to 2) is demultiplexed into optical signals of each wavelength and input to each input port, and multiple m optical signals of each wavelength output from each output port by cross-connect connection In an optical cross-connect device that multiplexes and outputs wavelength multiplexed optical signals (wavelengths λ1 to λn) to each wavelength multiplexed optical transmission line corresponding to the optical transmission line, the input and output ports of the optical switch module are connected to each wavelength multiplexed light. Each transmission line is divided into m areas, and the input / output ports corresponding to the respective wavelengths are arranged with regularity so as to ensure at least a predetermined interval that is not adjacent between the same wavelengths. It is formed.

  A second invention includes an optical switch module having a plurality of m × n input ports and a plurality of m × n output ports, and wavelength multiplexed optical signals (wavelengths λ1 to λn) input from a plurality of m wavelength multiplexed optical transmission lines. : N is an integer greater than or equal to 2) is demultiplexed into optical signals of each wavelength and input to each input port, and multiple m optical signals of each wavelength output from each output port by cross-connect connection In an optical cross-connect device that multiplexes and outputs wavelength multiplexed optical signals (wavelengths λ1 to λn) to each wavelength multiplexed optical transmission line corresponding to the optical transmission path, each wavelength multiplexed optical transmission is performed at the input port of the optical switch module. Each road is divided into m areas, and the input ports corresponding to the wavelengths λ1 to λn in the m areas have regularity so that a predetermined interval that is not adjacent to each other is secured between the same wavelengths. When the wavelength converter that performs wavelength conversion is connected to the output port of the optical switch module and the same wavelength is cross-connected to the n output ports in the region corresponding to each wavelength multiplexing optical transmission line In addition, the cross-connect control is performed so that a predetermined interval that is not adjacent to at least the output port of the same wavelength is secured.

  Here, a configuration may be adopted in which the input port interval and the output port interval corresponding to the same wavelength are uniform for each wavelength.

  The optical switch module is configured to reflect the light beam input from the input port by a mirror and output the light beam to an arbitrary output port by controlling the angle of the mirror, and the mirror includes a plurality of mirrors formed on the substrate by MEMS technology. It is a micro mirror of a mirror array with a variable reflection angle formed by a micro mirror, and the reflection angle may be changed by applying a voltage to the micro mirror.

  A third invention includes an optical switch module having a plurality of m × n input ports and a plurality of m × n output ports, and wavelength multiplexed optical signals (wavelengths λ1 to λn) input from a plurality of m wavelength multiplexed optical transmission lines. : N is an integer greater than or equal to 2) is demultiplexed into optical signals of each wavelength and input to each input port, and multiple m optical signals of each wavelength output from each output port by cross-connect connection In an optical cross-connect control method of multiplexing and corresponding to each optical transmission line and outputting each wavelength multiplexed optical signal (wavelength λ1 to λn) to each wavelength multiplexed optical transmission line, the input port of the optical switch module is connected to each wavelength multiplexed light. Each transmission line is divided into m areas, and the input ports corresponding to the wavelengths λ1 to λn in the m areas have regularity so that at least a predetermined interval between the same wavelengths is not adjacent. When a wavelength converter that performs wavelength conversion is connected to the output port of the optical switch module, and the same wavelength is cross-connected to n output ports in a region corresponding to each wavelength multiplexing optical transmission line, Cross-connect control is performed so as to ensure at least a predetermined interval that is not adjacent to the output port of the same wavelength.

  According to the present invention, at the input / output ports of the optical switch module, a predetermined interval that is not adjacent to each other between the same wavelengths is ensured, so that crosstalk between optical signals of the same wavelength, that is, intra crosstalk is reduced, resulting from this. Optical signal degradation can be suppressed. In addition, since predetermined intervals are provided between the input ports and the output ports to which the same wavelength is assigned, the influence of dynamic crosstalk can be reduced as compared with the case where they are adjacent or very close to each other.

(First embodiment)
FIG. 1 shows an example of wavelength allocation of input / output ports of an optical switch module according to the first embodiment of the present invention. The example shown here and the example shown below are cross sections of the input optical fiber array 3a and the output optical fiber array 3b shown in FIG. 6, or the input optical fiber arrays accommodated in the collimator arrays 1a and 1b shown in FIGS. And corresponds to the cross section of the output optical fiber array.

  Here, the number m of wavelength multiplexed optical transmission lines connected to the optical cross-connect device (number of input routes, number of output routes) is 4, and the number of wavelengths n of wavelength multiplexed optical signals to be input / output is 64. . At this time, the number of input ports and the number of output ports of the optical switch module are 256, respectively.

  In this embodiment, the input / output ports of the optical switch module are divided into four regions (2 × 2) for each route, and the input / output ports corresponding to wavelengths λ1 to λ64 in the regions corresponding to each route. Are assigned to the same position for each wavelength. For example, in the region corresponding to the route 1, when λ1 to λ8 are arranged in the first row, λ9 to λ16 in the second row, .lamda.57 to λ64 in the eighth row, the other routes 2 , 3 and 4 are similarly arranged. As a result, the light beams having the same wavelength between the respective paths can secure D / 2 or more as the same wavelength interval at all wavelengths, where D is the length of one side of the optical fiber array having a square arrangement. it can.

  What is important here is that when random wavelength allocation is performed, if the interval at one wavelength exceeds D / 2, the interval at other wavelengths becomes less than D / 2, and the influence of crosstalk. Varies depending on the wavelength. On the other hand, the configuration of this embodiment is characterized in that there is no variation in crosstalk for each wavelength because the minimum value of the interval between the same wavelengths is D / 2.

(Second Embodiment)
FIG. 2 shows an example of wavelength assignment of input / output ports of an optical switch module according to the second embodiment of the present invention.

  Here, the number m of wavelength multiplexed optical transmission lines connected to the optical cross-connect device (the number of input routes and the number of output routes) is 8, and the number of wavelengths n of wavelength multiplexed optical signals to be input / output is 32. . At this time, the number of input ports and the number of output ports of the optical switch module are 256, respectively.

  In this embodiment, the input / output ports of the optical switch module are divided into eight regions (4 × 2) for each route, and the input / output ports corresponding to the wavelengths λ1 to λ32 in the regions corresponding to each route. Are assigned to the same position for each wavelength. For example, in the region corresponding to the route 1, when λ1 to λ4 are arranged in the first row, λ5 to λ8 are arranged in the second row, and λ29 to λ32 are arranged in the eighth row in order, the other route 2 -8 are similarly arranged. As a result, the light beams of the same wavelength between the respective paths ensure at least D / 4 as the same wavelength interval at all wavelengths, where D is the length of one side of the optical fiber array having a square arrangement. Can do. Also in this embodiment, there is no variation in the influence of crosstalk for each wavelength.

(Third embodiment)
FIG. 3 shows an example of wavelength allocation of input / output ports of an optical switch module according to the third embodiment of the present invention.

  Here, the number m of wavelength multiplexed optical transmission lines connected to the optical cross-connect device (the number of input routes and the number of output routes) is 5, and the number of wavelengths n of the wavelength multiplexed optical signals to be input / output is 54. . At this time, the number of input ports and the number of output ports of the optical switch module is 270, respectively.

  In this embodiment, the input / output port of the optical switch module is divided into five regions for each route. The area corresponding to the routes 1 to 3 is 6 × 9, and the area corresponding to the routes 4 to 5 is 9 × 6. In the region corresponding to the routes 1 to 3, the input / output ports corresponding to the wavelengths λ1 to λ54 are assigned so as to be in the same position for each wavelength. For example, in the region corresponding to the route 1, when λ1 to λ6 are arranged in the first row, λ7 to λ12 in the second row, .lamda.49 to λ54 in the ninth row, the other routes 2 , 3 are similarly arranged. In addition, the input / output ports corresponding to the wavelengths λ1 to λ54 in the region corresponding to the routes 4 and 5 are assigned to the same position for each wavelength. For example, in the region corresponding to the route 4, when λ1 to λ9 are arranged in the first row, λ10 to λ18 in the second row, .lamda.46 to λ54 in the sixth row, the other routes 5 are arranged. The same arrangement is applied to As a result, the light beams having the same wavelength between the respective paths have the same wavelength interval between the paths 1 and 2 and between the paths 2 and 3, where D is the length of one side of the optical fiber array having a square arrangement. However, it is possible to ensure D / 3 or more as the same wavelength interval at all wavelengths.

  In this example, the same wavelength interval at all wavelengths is not the same condition as in the example of FIG. 1, but the minimum value of the same wavelength interval in the paths 1 to 5 is secured as D / 3. That is, the configuration according to the present embodiment has no variation due to the wavelength, but the variation is reduced by securing the minimum same wavelength interval as compared with the random arrangement.

(Fourth embodiment)
In the first to third embodiments, assuming the optical cross-connect device shown in FIG. 4, a cross-connect is made to each of n output ports corresponding to the wavelength division multiplexing optical transmission lines 1 to m of the optical switch module 100. Corresponding to the case where the wavelengths are all different from λ1 to λn.

  On the other hand, the optical cross-connect device shown in FIG. 5 is the same as that of the first to third embodiments on the input port side, but wavelength conversion is possible on the output port side. In each of the n output ports corresponding to the optical transmission lines 1 to m, the relationship between the output port and the wavelength is not unique, and the output wavelength may be the same. In this case, the cross-connect control is performed so as to ensure at least a predetermined interval not adjacent to the output port of the same wavelength. In the example shown in FIG. 5, two optical signals having a wavelength λ2 are output to n output ports corresponding to the wavelength multiplexing optical transmission line 1, and the wavelength λ2 is output to n output ports corresponding to the wavelength multiplexing optical transmission line 2. However, it is sufficient to control so that these output ports are not adjacent to each other.

The figure which shows the example of wavelength allocation of the input-output port of the optical switch module in 1st Embodiment. The figure which shows the wavelength allocation example of the input-output port of the optical switch module in 2nd Embodiment. The figure which shows the example of wavelength allocation of the input-output port of the optical switch module in 3rd Embodiment. The figure which shows the structural example of the optical cross-connect apparatus used for a wavelength division multiplexing optical transmission system. The figure which shows the structural example of the optical cross-connect apparatus used for a wavelength division multiplexing optical transmission system. 1 is a diagram illustrating a first configuration example of an optical switch module 100. FIG. The figure which shows the 2nd structural example of the optical switch module 100. FIG. The figure which shows the 3rd structural example of the optical switch module 100. FIG. The figure which shows the measurement result of the crosstalk characteristic of an optical switch module. The figure which shows the relationship between crosstalk and an optical signal power penalty.

Explanation of symbols

1-m Wavelength multiplexed optical transmission line 1a, 1b Collimator array 2, 2a, 2b MEMS mirror array 3a Input optical fiber array 3b Optical optical fiber array 10 Input port 11-14 Output port 100 Optical switch module 101 Wavelength demultiplexer 102 Wavelength Multiplexer 103 Wavelength converter

Claims (5)

An optical switch module having a plurality of m × n input ports and a plurality of m × n output ports is provided, and a wavelength multiplexed optical signal (wavelengths λ1 to λn: n is 2 or more) input from a plurality of m wavelength multiplexed optical transmission lines. (Integer) is demultiplexed into each wavelength optical signal and input to each input port, and each wavelength optical signal output from each output port by cross-connect connection corresponds to multiple m wavelength multiplexing optical transmission lines. In an optical cross-connect device that multiplexes and outputs to each wavelength-multiplexed optical transmission line as wavelength-multiplexed optical signals (wavelengths λ1 to λn),
The input / output ports of the optical switch module are divided into m areas for each wavelength multiplexing optical transmission line, and the input / output ports corresponding to the respective wavelengths in the m areas are at least adjacent to each other between the same wavelengths. An optical cross-connect device characterized by being arranged with regularity so as to ensure an interval. An optical switch module having a plurality of m × n input ports and a plurality of m × n output ports is provided, and a wavelength multiplexed optical signal (wavelengths λ1 to λn: n is 2 or more) input from a plurality of m wavelength multiplexed optical transmission lines. (Integer) is demultiplexed into each wavelength optical signal and input to each input port, and each wavelength optical signal output from each output port by cross-connect connection corresponds to multiple m wavelength multiplexing optical transmission lines. In an optical cross-connect device that multiplexes and outputs to each wavelength multiplexed optical transmission line as wavelength multiplexed optical signals (wavelengths λ1 to λn),
The input / output port of the optical switch module is divided into m areas for each wavelength division multiplexing optical transmission line, and the input ports corresponding to the wavelengths λ1 to λn in the m areas have a predetermined interval between the same wavelengths. Is arranged with regularity to ensure
When a wavelength converter that performs wavelength conversion is connected to the output port of the optical switch module, and the same wavelength is cross-connected to n output ports in a region corresponding to each wavelength multiplexing optical transmission line, An optical cross-connect device configured to perform cross-connect control so as to ensure a predetermined interval not adjacent to at least an output port. The optical cross-connect device according to claim 1 or 2,
The optical cross-connect device, wherein the input port interval and the output port interval corresponding to the same wavelength are arranged so as to be uniform for each wavelength. The optical cross-connect device according to claim 1 or 2,
The optical switch module is configured to reflect a light beam input from an input port with a mirror and output the light beam to an arbitrary output port by controlling the angle of the mirror.
The mirror is a micromirror of a mirror array with a variable reflection angle formed by a plurality of micromirrors formed on a substrate by MEMS technology, and the reflection angle is changed by applying a voltage to the micromirror. An optical cross-connect device. An optical switch module having a plurality of m × n input ports and a plurality of m × n output ports, and wavelength-multiplexed optical signals input from a plurality of m wavelength-multiplexed optical transmission lines (wavelengths λ1 to λn: n is 2 or more) (Integer) is demultiplexed into each wavelength optical signal and input to each input port, and each wavelength optical signal output from each output port by cross-connect connection corresponds to a plurality of m wavelength multiplexing optical transmission lines. In each of the optical cross-connect control methods of combining and outputting to each wavelength multiplexing optical transmission line as wavelength multiplexed optical signals (wavelengths λ1 to λn),
The input / output port of the optical switch module is divided into m areas for each wavelength multiplexing optical transmission line, and the input ports corresponding to the wavelengths λ1 to λn in the m areas are not adjacent at least between the same wavelengths. It is arranged with regularity so that a predetermined interval is secured,
When a wavelength converter that performs wavelength conversion is connected to the output port of the optical switch module, and the same wavelength is cross-connected to n output ports in a region corresponding to each wavelength multiplexing optical transmission line, An optical cross-connect control method, wherein cross-connect control is performed so as to ensure a predetermined interval that is not adjacent to at least an output port.

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