JP2014026052A - Optical switch - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical switch with reduced variation of output power of an optical signal.SOLUTION: An input port part 1001a has a plurality of ports into which optical signals are inputted and an output port part 1001b has a plurality of ports for outputting the optical signals. A beam splitter 1005a divides one optical path extending from the input port part into two optical paths P1, P2 and a beam splitter 1005b synthesizes the two optical paths into one optical path extending toward the output port. The two beam splitters are capable of optically connecting the input port part and the output port part through the two optical paths along with micromirror arrays 1003a, 1003b, 1013a, 1013b. Shutters 1007a, 1009a and a shutter controller 1015 are capable of switching optical paths optically connecting the input port part and the output port part. The micromirror arrays are capable of switching ports for the connected input port part and the output port part.

Description

  The present invention relates to an optical switch.

  An optical switch using an electrostatically driven micromirror is known. Such an optical switch is disclosed in, for example, Patent Document 1 and Patent Document 2.

Japanese Patent No. 4744500 Japanese Patent No. 4464436

  In an electrostatically driven micromirror, when a voltage is applied, the electrode itself and the electrode surrounding insulator may be polarized or charged. This is gradually discharged or charged, and the potential difference between the electrode and the mirror changes with the passage of time, and the phenomenon that the turning angle fluctuates with the passage of time, that is, the turning angle drift occurs. In an optical switch using such a micromirror, the occurrence of rotation angle drift is a factor that fluctuates the incident position of the optical signal with respect to the output port and causes the output power of the optical signal to fluctuate, thereby significantly reducing the communication quality. Become.

  The present invention has been made in consideration of such a situation, and an object of the present invention is to provide an optical switch in which fluctuations in output power of an optical signal due to the occurrence of rotational angle drift are reduced. is there.

  An optical switch according to the present invention includes an input port unit having at least one port to which an optical signal is input, an output port unit having at least one port for outputting an optical signal, the input port unit, and the output port unit. An optical coupling optical system that can be optically coupled through a plurality of optical paths, an optical path switching mechanism that can switch an optical path that optically couples the input port unit and the output port unit, and the plurality of optical paths, respectively. A plurality of provided port switching mechanisms are provided. At least one of the input port portion and the output port portion has a plurality of ports. Each port switching mechanism can switch the ports of the input port unit and the output port unit coupled to each other.

  ADVANTAGE OF THE INVENTION According to this invention, the optical switch by which the fluctuation | variation of the output power of the optical signal resulting from generation | occurrence | production of rotation angle drift was reduced is provided.

1 shows an optical switch according to a first embodiment. It is a disassembled perspective view of an example of a micromirror device. It is sectional drawing of the micromirror device along CC line of FIG. The rotation angle change amount of the micromirror device in the operating state and the timing of switching the optical path in the first embodiment are shown. The rotation angle change amount of the micromirror device in the operating state and the timing of switching the optical path in the second embodiment are shown. The wavelength selective switch which concerns on 3rd embodiment is shown. 10 shows a wavelength selective switch according to a fourth embodiment.

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

[First embodiment]
〔Constitution〕
As shown in FIG. 1, an optical switch 1000 according to this embodiment includes an input port unit 1001a, an output port unit 1001b, a beam splitter 1005a, shutters 1007a and 1009a, fixed mirrors 1011a and 1011b, and a micromirror array. 1003a, 1003b, 1013a, 1013b and a beam splitter 1005b are provided. The optical switch 1000 further includes a shutter control device 1015 that controls the shutters 1007a and 1009a, and a mirror control device 1017 that controls the micromirror arrays 1003a, 1013a, 1003b, and 1013b.

  The input port unit 1001a has a plurality of ports to which optical signals are input, and the output port unit 1001b has a plurality of ports that output optical signals. The ports of the input port unit 1001a and the output port unit 1001b are each composed of a plurality of optical fibers arranged two-dimensionally.

  The beam splitter 1005a has a function of transmitting part of the optical signal incident from the input port unit 1001a and reflecting the other part. That is, the beam splitter 1005a constitutes an optical path splitting element that splits one optical path extending from the input port unit 1001a into a plurality of optical paths, for example, two optical paths P1 and P2. The beam splitter 1005b has a function of transmitting an optical signal incident along the optical path P1 and reflecting an optical signal incident along the optical path P2. That is, the beam splitter 1005b constitutes an optical path combining element that combines the optical paths P1 and P2 to form one optical path extending toward the output port portion 1001b.

  The beam splitter 1005a, fixed mirrors 1011a and 1011b, micromirror arrays 1003a, 1003b, 1013a and 1013b, and the beam splitter 1005b optically couple the input port unit 1001a and the output port unit 1001b via two optical paths P1 and P2. An optical coupling optical system to be obtained is configured.

  The shutters 1007a and 1009a and the shutter control device 1015 constitute an optical path switching mechanism that can switch an optical path that optically couples the input port unit 1001a and the output port unit 1001b. The shutters 1007a and 1009a are made of transmissive liquid crystal, for example. The shutter control device 1015 performs control so that one of the shutters 1007a and 1009a is selectively opened or transmitted, and the other shutter is closed or blocked. As a result, the input port unit 1001a and the output port unit 1001b are optically coupled through one optical path, that is, one of the optical paths P1 and P2.

  Each of the micromirror arrays 1003a, 1003b, 1013a, and 1013b includes a plurality of micromirror devices 1002a, 1002b, 1012a, and 1012b that are two-dimensionally arranged. Each of the micromirror devices 1002a, 1002b, 1012a, and 1012b includes a mirror surface whose direction can be changed two-dimensionally and can deflect an optical signal incident thereon in a two-dimensional manner. The mirror control device 1017 controls the orientation of the mirror surfaces of the micromirror devices 1002a, 1002b, 1012a, and 1012b. The arrows shown in FIG. 1 indicate the traveling direction of the optical signal.

  The micromirror arrays 1003a and 1003b are arranged on the optical path P1, and the micromirror arrays 1013a and 1013b are arranged on the optical path P2. One port of the input port unit 1001a is coupled to one port of the output port unit 1001b via the micromirror arrays 1003a and 1003b on the optical path P1 or via the micromirror arrays 1013a and 1013b on the optical path P2. The The port of the output port unit 1001b to which the port of the input port unit 1001a is coupled can be switched by changing the orientation of the mirror surfaces of the micromirror devices 1002a, 1002b, 1012a, and 1012b. That is, the micromirror arrays 1003a, 1003b, 1013a, 1013b and the mirror control device 1017 constitute a port switching mechanism that can switch the ports of the input port unit 1001a and the output port unit 1001b that are coupled to each other.

  2 and 3 show an example of the micromirror device 1002a. Here, the micromirror device 1002a is typically illustrated and described, but the other micromirror devices 1002b, 1012a, and 1012b are similar to the micromirror device 1002a. 2 is an exploded perspective view of the micromirror device, and FIG. 3 is a cross-sectional view taken along line CC in FIG.

  The micromirror device 1002a includes a mirror unit 310 and an electrode substrate 340.

  The mirror unit 310 includes a fixed portion 312, a pair of composite torsion bars 314, a movable support portion 316, a pair of composite torsion bars 318, and a movable portion 320.

  The fixed portion 312 has a rectangular shape, and the movable support portion 316 has a rectangular frame shape. The movable support part 316 is located at an interval so as to surround the fixed part 312, and a pair of composite torsion bars 314 are located between the movable support part 316 and the fixed part 312. The pair of composite torsion bars 314 are located on both sides of the fixed portion 312. The pair of composite torsion bars 314 mechanically connect the movable support portion 316 and the fixed portion 312 such that the movable support portion 316 can be rotationally displaced, that is, inclined about the rotation shaft 322 with respect to the fixed portion 312. Yes.

  The movable portion 320 has an opening, is positioned so as to accommodate the movable support portion 316 in the opening, and a pair of composite torsion bars 318 are positioned in the opening of the movable portion 320. The pair of composite torsion bars 318 are located on both outer sides of the movable support portion 316. The pair of composite torsion bars 318 mechanically connect the movable portion 320 and the movable support portion 316 so that the movable portion 320 can be rotationally displaced, that is, inclined around the rotation shaft 324 with respect to the movable support portion 316. Yes. The rotation shaft 322 and the rotation shaft 324 are orthogonal to each other.

  The pair of composite torsion bars 314 are disposed symmetrically with respect to the rotational shaft 324, and the movable support portion 316 is disposed symmetrically with respect to both the rotational shaft 322 and the rotational shaft 324, and a pair of composite torsion bars 314 are disposed. The bar 318 and the movable part 320 are arranged symmetrically with respect to the rotation shaft 322. The fixed portion 312, the composite torsion bar 314, the movable support portion 316, the composite torsion bar 318, and the movable portion 320 can be integrally formed of, for example, silicon.

  The movable part 320 has a mirror surface 326 on the surface opposite to the surface facing the electrode substrate 340. The mirror surface 326 is provided on at least one of the two end portions 320 a and 320 b of the movable portion 320 that is positioned symmetrically with respect to the rotation shaft 322. For example, the mirror surface 326 is provided at one end 320 a of the movable unit 320. Of course, the mirror surface 326 may be provided on the entire movable portion 320. The mirror surface 326 can be formed, for example, by forming a highly reflective metal thin film on the movable portion 320. Alternatively, the mirror surface 326 may be formed by applying a mirror finish to the surface of the movable portion 320. The fixed portion 312 is provided with a spacer 328 that defines a distance between the movable portion 320 and the electrode substrate 340 on a surface facing the electrode substrate 340.

  The electrode substrate 340 has four fixed electrodes 342A, 342B, 342C, and 342D on the surface facing the movable portion 320, which are rotationally displaced, that is, tilted around the rotation shaft 322 and the rotation shaft 324. Is provided. That is, the fixed electrodes 342A, 342B, 342C, and 342D constitute a driving unit for driving the movable portion 320. In the following description, when it is not necessary to distinguish between the fixed electrodes 342A, 342B, 342C, and 342D, these are collectively referred to simply as the fixed electrode 342. The fixed electrode 342 is not limited to this, and is made of, for example, gold. The fixed electrodes 342A and 342B are opposed to one end portion 320a of the movable portion 320, and the fixed electrodes 342C and 342D are opposed to the other end portion 320b of the movable portion 320. The fixed electrodes 342A and 342B and the fixed electrodes 342C and 342D are arranged symmetrically with respect to the straight line of the rotation shaft 322 projected onto the electrode substrate 340. The fixed electrodes 342A and 342C and the fixed electrodes 342B and 342D are arranged symmetrically with respect to the straight line of the rotation shaft 324 projected onto the electrode substrate 340.

  The mirror unit 310 and the electrode substrate 340 are arranged such that the fixed electrode 342 faces the ends 320 a and 320 b of the movable portion 320, and the spacer 328 is joined to the electrode substrate 340. As a result, as shown in FIG. 3, the movable portion 320 is supported at a certain distance from the fixed electrode 342.

  In such a micromirror device 1002a, the movable part 320 is driven as follows.

  In order to rotate the movable portion 320 around the rotation shaft 322, that is, to tilt the movable portion 320, the movable portion 320 is kept at the ground potential and the fixed electrode 342 located on one side with respect to the rotation shaft 322, for example, the fixed electrode 342A, A voltage is applied to 342B. An electrostatic attractive force is generated between the fixed electrodes 342A and 342B to which the voltage is applied and the movable portion 320. The magnitude of the electrostatic attraction generated depends on the magnitude of the applied voltage. The movable portion 320 has a side facing the fixed electrodes 342A and 342B to which a voltage is applied attracted to the electrode substrate 340, and a side facing the fixed electrodes 342C and 342D to which no voltage is applied from the electrode substrate 340. Move away. As a result, the composite torsion bar 314 is torsionally deformed, and the movable portion 320 is rotationally displaced, that is, inclined around the rotational shaft 322 depending on the magnitude of the applied voltage.

  In order to rotate the movable portion 320 around the rotation shaft 324, that is, to tilt the movable portion 320, the movable portion 320 is kept at the ground potential, and a voltage is applied to the fixed electrodes 342A and 342C located on one side with respect to the rotation shaft 324. Apply. An electrostatic attractive force is generated between the fixed electrodes 342A and 342C to which the voltage is applied and the movable portion 320. The magnitude of the electrostatic attraction generated depends on the magnitude of the applied voltage. The movable portion 320 is drawn from the electrode substrate 340 on the side facing the fixed electrodes 342A and 342C to which a voltage is applied, and from the electrode substrate 340 on the side facing the fixed electrodes 342B and 342D to which no voltage is applied. Move away. As a result, the composite torsion bar 318 undergoes torsional deformation, and the movable part 320 rotates together with the composite torsion bar 314 and the movable support part 316 around the rotation shaft 324 depending on the magnitude of the applied voltage. Is done.

  In this micromirror device, the movable part 320 is rotated around two rotation axes 322 and 324 orthogonal to each other by controlling the selection of the fixed electrode 342 to which the voltage is applied and the magnitude of the applied voltage. The optical signal reflected by the mirror surface 326 can be deflected two-dimensionally.

[Action]
The optical signal emitted from the input port unit 1001a is divided by the beam splitter 1005a into an optical signal traveling along the optical path P1 and an optical signal traveling along the optical path P2. For example, the shutter control device 1015 opens the shutter 1007a and closes the shutter 1009a. As a result, the path of the optical signal is set to the optical path P1. The optical signal from the input port unit 1001a travels along only the optical path P1, is reflected and deflected by the micromirror device 1002a of the micromirror array 1003a, and subsequently reflected and deflected by the micromirror device 1002b of the micromirror array 1003b, and is then used as a beam splitter. It is coupled to the output port unit 1001b through 1005b.

  The micromirror arrays 1003a and 1003b on the optical path P1 are in an operating state, and the micromirror devices 1002a and 1002b are supplied with voltage and the mirror surfaces are set in a desired direction. On the other hand, the micromirror arrays 1013a and 1013b on the optical path P2 are in a non-operating state, and the micromirror devices 1012a and 1012b are not supplied with voltage.

  Further, the ports of the input port unit 1001a and the output port unit 1001b coupled to each other can be switched by changing the orientation of the mirror surfaces of the micromirror devices 1002a and 1002b, that is, by changing the deflection direction of the optical signal. it can.

  In the following description, the directions of the mirror surfaces of the micromirror devices 1002a, 1002b, 1012a, and 1012b are simply expressed as the rotation angles of the micromirror devices 1002a, 1002b, 1012a, and 1012b. For example, the orientation of the mirror surfaces of the micromirror devices 1002a, 1002b, 1012a, and 1012b is set to a desired orientation, which is synonymous with simply setting the micromirror devices 1002a, 1002b, 1012a, and 1012b to desired rotation angles. It is.

  The rotation angles of the micromirror devices 1002a and 1002b in the operating state change with time as shown in FIG. That is, rotation angle drift occurs in the micromirror devices 1002a and 1002b in the operating state. For this reason, in the micromirror devices 1002a and 1002b in the operating state, the rotation angle shifts from the desired rotation angle. This rotation angle change amount, that is, the drift amount, in other words, the deviation amount from the desired rotation angle has an allowable range corresponding to the allowable range of optical power.

  The shutter control device 1015 closes the shutter 1007a and opens the shutter 1009a at the time T1 immediately before the rotation angle change amount of the micromirror devices 1002a and 1002b in the operating state exceeds the permissible range. Is switched to the optical path P2. At the same time, the mirror control device 1017 operates the micromirror arrays 1013a and 1013b, supplies a voltage to the micromirror devices 1012a and 1012b, and sets a desired rotation angle. As a result, the optical signal from the input port unit 1001a is coupled to the output port unit 1001b via the micromirror arrays 1013a and 1013b on the optical path P2.

  In addition, after switching the optical path, the mirror control device 1017 returns the micromirror arrays 1003a and 1003b to the non-operating state, returns the supply voltage to the micromirror devices 1002a and 1002b to 0 V, and releases the accumulated charges. Thereafter, the mirror control device 1017 keeps the micromirror arrays 1003a and 1003b in a non-operating state until the next operation.

  Thereafter, in the same manner as described above, at time T2 immediately before the change in the rotation angle of the micromirror devices 1012a and 1012b exceeds the allowable range, the shutter control device 1015 switches the optical signal path from the optical path P2 to the optical path P1 again. At the same time, the mirror control device 1017 operates the micromirror arrays 1003a and 1003b on the optical path P1. As a result, the optical signal from the input port unit 1001a is coupled to the output port unit 1001b via the micromirror arrays 1003a and 1003b on the optical path P1.

  The mirror control device 1017 returns the micromirror arrays 1013a and 1013b to the non-operating state after switching the optical path, and keeps the micromirror arrays 1013a and 1013b in the non-operating state until the next operation.

  Thereafter, the shutter control device 1015 and the mirror control device 1017 repeat the same control.

  That is, the mirror control device 1017 operates the micromirror arrays 1003a, 1003b, 1013a, and 1013b on the optical paths P1 and P2 that optically couple the input port unit 1101a and the output port unit 1101b simultaneously with the switching of the optical paths P1 and P2. Let Further, the mirror control device 1017 maintains the micromirror arrays 1003a, 1003b, 1013a, and 1013b on the optical paths P1 and P2 that are not optically coupled to the input port unit 1001a and the output port unit 1001b in a non-operating state.

〔effect〕
An optical switch is provided in which fluctuations in the output power of an optical signal due to the occurrence of rotational angle drift are reduced. The optical switch of the present embodiment can reduce fluctuations in the output power of the optical signal even with a micromirror that shows any rotation angle change, for example, a rotation angle change that does not reach a steady state within a certain time. it can.

[Modification]
The micromirror array may be a comb-type actuator as long as it is an electrostatic actuator, and is not limited to a parallel plate type.

In this embodiment, the shutter is a transmissive liquid crystal element. However, the shutter is not limited to a liquid crystal element as long as it can control light transmission and blocking.
In this embodiment, an example of 4 mirrors × 4 mirrors (16 micromirror devices) is shown in the micromirror array, but the present invention is not limited to this.

  In the present embodiment, an example in which a parallel plate type actuator is used in the micromirror array device has been shown, but a comb-type actuator may be used. Furthermore, the composite torsion bar is in the same layer as the mirror, but may be provided between the mirror and the electrode.

[Second Embodiment]
〔Constitution〕
The apparatus configuration of this embodiment is the same as that of the first embodiment, but the control method in the shutter control device 1015 and the mirror control device 1017 is different from that of the first embodiment.

[Action]
Similar to the above description, it is assumed that the optical signal from the input port unit 1001a is coupled to the output port unit 1001b via the micromirror arrays 1003a and 1003b on the optical path P1. The rotation angles of the micromirror devices 1002a and 1002b in the operating state change with time as shown in FIG.

  Prior to the start of the optical signal coupling between the input port unit 1001a and the output port unit 1001b, the mirror control device 1017 operates the micromirror arrays 1003a and 1003b in advance to move the micromirror devices 1002a and 1002b to a desired rotation angle. Set to. Thereafter, at time T1, the shutter control device 1015 opens the shutter 1007a and closes the shutter 1009a. As a result, the path of the optical signal is set to the optical path P1, and the optical signal from the input port unit 1001a is coupled to the output port unit 1001b via the micromirror arrays 1003a and 1003b on the optical path P1.

  That is, no optical signal is input to the micromirror devices 1002a and 1002b in the time zone indicated by the hatched portion 3001 in FIG. 5, and the optical signal is input at a timing when the rotation angle change amount, that is, the drift amount converges to some extent. .

  Thereafter, at time T2 prior to time T3 when the optical signal path is switched from the optical path P1 to the optical path P2, the mirror control device 1017 operates the micromirror arrays 1013a and 1013b so that the micromirror devices 1012a and 1012b can be Set the rotation angle.

  In the example of FIG. 5, the time T2 for operating the micromirror arrays 1013a and 1013b is set after the time T1 when the optical signal is input to the micromirror devices 1002a and 1002b, but the time T2 is later than the time T1. It may be set before.

  Thereafter, at time T3 before the rotation angle change amount of the micromirror devices 1002a and 1002b in the operating state exceeds the allowable range, the shutter control device 1015 closes the shutter 1007a and opens the shutter 1009a. As a result, the path of the optical signal is switched from the optical path P1 to the optical path P2, and the optical signal from the input port unit 1001a is coupled to the output port unit 1001b via the micromirror arrays 1013a and 1013b on the optical path P2.

  That is, no optical signal is input to the micromirror devices 1012a and 1012b in the time zone indicated by the hatched portion 3003 in FIG. 5, and an optical signal is input at a timing when the rotation angle change amount converges to some extent.

  In addition, after switching the optical path, the mirror control device 1017 returns the micromirror arrays 1003a and 1003b to the non-operating state, returns the supply voltage to the micromirror devices 1002a and 1002b to 0 V, and releases the accumulated charges. Thereafter, the mirror control device 1017 keeps the micromirror arrays 1003a and 1003b in a non-operating state until the next operation.

  Thereafter, in the same manner as described above, at time T4 before the optical signal path is switched from the optical path P2 to the optical path P1, the mirror control device 1017 operates the micromirror arrays 1003a and 1003b, and the micromirror device 1002a. , 1002b is set to a desired rotation angle.

  Thereafter, at time T5 before the amount of change in the rotation angle of the micromirror devices 1012a and 1012b in the operating state exceeds the allowable range, the shutter control device 1015 opens the shutter 1007a and closes the shutter 1009a. As a result, the path of the optical signal is switched from the optical path P2 to the optical path P1, and the optical signal from the input port unit 1001a is coupled to the output port unit 1001b via the micromirror arrays 1003a and 1003b on the optical path P1.

  The mirror control device 1017 returns the micromirror arrays 1013a and 1013b to the non-operating state after switching the optical path, and keeps the micromirror arrays 1013a and 1013b in the non-operating state until the next operation.

  Thereafter, the shutter control device 1015 and the mirror control device 1017 repeat the same control.

  That is, the mirror control device 1017 changes the micromirror arrays 1003a, 1003b, 1013a, and 1013b on the optical paths P1 and P2 that are next optically coupled to the input port unit 1001a and the output port unit 1001b before switching the optical paths P1 and P2. To work. Further, the mirror control device 1017 provides micromirror arrays 1003a, 1003b, 1013a, and 1013b on the optical paths P1 and P2 that optically couple the input port unit 1001a and the output port unit 1001b after the switching of the optical paths P1 and P2. Return to non-operational state.

  As a result of such control, the amount of change in the rotation angle of the micromirror devices 1002a and 1002b actually used for deflection of the optical signal falls within the range indicated by Δθ in the drawing. That is, the amount of change in the rotation angle that affects the optical power can be suppressed sufficiently small.

〔effect〕
In addition to the effects of the first embodiment, it is possible to provide an optical switch that can further reduce fluctuations in the output power of an optical signal and can perform high-quality optical communication.

[Third embodiment]
〔Constitution〕
As shown in FIG. 6, the wavelength selective switch 1200 of this embodiment includes an input port unit 1210, an output port unit 1211, a main lens 1214, a reflective diffraction grating 1215, a beam splitter 1225, a shutter 1227a, 1227b, micromirror arrays 1213 and 1231, and a parallelizing lens 1216 are provided. The wavelength selection switch 1200 also includes a shutter control device 1233 that controls the shutters 1227a and 1227b and a mirror control device 1235 that controls the micromirror arrays 1213 and 1231.

  The input port unit 1210 has one port, and the output port unit 1211 has a plurality of ports 1211a and 1211b.

  The beam splitter 1225 divides one optical path extending from the input port unit 1210 into two optical paths P1 and P2 extending toward the micromirror arrays 1213 and 1231, and combines the optical paths P1 and P2 into the output port unit 1211. An optical path splitting and synthesizing element that forms one optical path extending in the direction is configured.

  The shutters 1227 a and 1227 b and the shutter control device 1233 constitute an optical path switching mechanism that can switch an optical path that optically couples the input port unit 1210 and the output port unit 1211. The shutters 1227a and 1227b are made of transmissive liquid crystal, for example. The shutter control device 1233 performs control so that one of the shutters 1227a and 1227b is selectively opened or transmitted, and the other shutter is closed or blocked. As a result, the input port unit 1210 and the output port unit 1211 are optically coupled through one optical path, that is, one of the optical paths P1 and P2.

  The micromirror array 1213 includes a plurality of micromirror devices 1213a, 1213b, and 1213c arranged one-dimensionally. The micromirror array 1231 includes a plurality of micromirror devices 1231a, 1231b, and 1231c arranged one-dimensionally. I have. As each of the micromirror devices 1213a, 1213b, 1213c, 1231a, 1231b, and 1231c, the micromirror device 1002a typically shown in FIG. 2 in the description of the first embodiment can be applied. The mirror control device 1235 controls the rotation angles of the micromirror devices 1213a, 1213b, 1213c, 1231a, 1231b, and 1231c.

  The micromirror array 1213 is disposed on the optical path P1, and the micromirror array 1231 is disposed on the optical path P2. The port of the input port unit 1210 is coupled to the ports 1211a and 1211b of the output port unit 1211 via the micromirror array 1213 on the optical path P1 or the micromirror array 1231 on the optical path P2. The ports 1211a and 1211b of the output port unit 1211 to which the ports of the input port unit 1210 are coupled can be switched by changing the rotation angles of the micromirror devices 1213a, 1213b, 1213c, 1231a, 1231b, and 1231c. That is, the micromirror arrays 1213 and 1231 and the mirror control device 1235 constitute a port switching mechanism that can switch the ports 1211a and 1211b of the output port unit 1211 to which the port of the input port unit 1210 is coupled.

  The reflective diffraction grating 1215 is a spectroscopic element that disperses incident light at different angles depending on the wavelength, and is on the optical path from the input port unit 1210 to the beam splitter 1225 and on the optical path from the beam splitter 1225 to the output port unit 1211. Is arranged.

[Action]
The input port unit 1210 emits a wavelength multiplexed signal 1221 obtained by multiplexing a plurality of optical signals having different wavelengths toward the main lens 1214. The wavelength multiplexed signal 1221 passes through the main lens 1214, is reflected by the reflective diffraction grating 1215, and is demultiplexed into a plurality of optical signals 1222a, 1222b, and 1222c having different wavelengths. The demultiplexed optical signals 1222a, 1222b, and 1222c pass through the main lens 1214 again and are split into optical signals that travel along the two optical paths P1 and P2 by the beam splitter 1225. For example, the shutter control device 1233 opens the shutter 1227a and closes the shutter 1227b. As a result, the path of the optical signal is set to the optical path P1. The optical signal travels along only the optical path P1, and is reflected and deflected by the micromirror devices 1213a, 1213b, and 1213c of the micromirror array 1213.

  The deflected optical signal passes through the shutter 1227a, the beam splitter 1225, the collimating lens 1216 and the main lens 1214, is reflected by the reflective diffraction grating 1215, passes through the main lens 1214 again, and then is output from the output port unit 1211. The light enters the ports 1211a and 1211b of the port portion 1211.

  In the example of FIG. 6, the optical signals 1223a, 1223b, and 1223c reflected by the micromirror devices 1213a, 1213b, and 1213c are incident on the port 1211a of the output port unit 1211.

  The rotation angles of the micromirror devices 1213a, 1213b, and 1213c in the operating state change with time, similarly to the micromirror devices 1002a and 1002b of the first embodiment. The rotation angle change amount has an allowable range corresponding to the allowable range of optical power.

(Control example)
For example, the shutter control device 1233 and the mirror control device 1235 perform the same control as the control described in relation to FIG. 4 in the first embodiment.

  For example, in a state where an optical signal from the input port unit 1210 is coupled to the output port unit 1211 via the micromirror array 1213 on the optical path P1, the rotation angles of the micromirror devices 1213a, 1213b, and 1213c in the operating state Immediately before the amount of change exceeds the allowable range, the shutter control device 1233 closes the shutter 1227a, opens the shutter 1227b, switches the optical signal path to the optical path P2, and at the same time, the mirror control device 1235 Then, the micromirror array 1231 is operated to set the micromirror devices 1231a, 1231b, and 1231c to desired rotation angles. As a result, the optical signal from the input port unit 1210 is coupled to the output port unit 1211 via the micromirror array 1231 on the optical path P2.

  Further, after switching the optical path, the mirror control device 1235 returns the micromirror array 1213 to the non-operating state, returns the supply voltage to the micromirror devices 1213a, 1213b, and 1213c to 0 V, and releases the accumulated electric charge. Thereafter, the mirror controller 1235 keeps the micromirror array 1213 in a non-operating state until it is next operated.

  Thereafter, similarly, the shutter control device 1233 switches the optical paths P1 and P2, and the mirror control device 1235 switches between the operating state and the non-operating state of the micromirror arrays 1213 and 1231.

(Another control example)
Further, the shutter control device 1233 and the mirror control device 1235 may perform the same control as the control described in relation to FIG. 5 in the second embodiment.

  For example, in a state where the optical signal from the input port unit 1210 is coupled to the output port unit 1211 via the micromirror array 1213 on the optical path P1, the optical signal path is changed from the optical path P1 to the optical path P2. In addition, the mirror control device 1235 operates the micromirror array 1231 to set the micromirror devices 1231a, 1231b, and 1231c to desired rotation angles.

  After that, before the rotational angle change amount of the micromirror devices 1213a, 1213b, and 1213c in the operating state exceeds the allowable range, the shutter control device 1233 closes the shutter 1227a and opens the shutter 1227b, The signal path is switched from the optical path P1 to the optical path P2. As a result, the optical signal from the input port unit 1210 is coupled to the output port unit 1211 via the micromirror array 1231 on the optical path P2.

  Further, after switching the optical path, the mirror control device 1235 returns the micromirror array 1231 to the non-operating state, returns the supply voltage to the micromirror devices 1231a, 1231b, and 1231c to 0 V, and releases the accumulated charges. Thereafter, the mirror controller 1235 keeps the micromirror array 1231 in a non-operating state until the next operation.

  Thereafter, similarly, the shutter control device 1233 switches the optical paths P1 and P2, and the mirror control device 1235 switches between the operating state and the non-operating state of the micromirror arrays 1213 and 1231.

〔effect〕
An optical switch is provided in which fluctuations in the output power of an optical signal due to the occurrence of rotational angle drift are reduced. The optical switch of the present embodiment can reduce fluctuations in the output power of the optical signal even with a micromirror that shows any rotation angle change, for example, a rotation angle change that does not reach a steady state within a certain time. it can.

[Modification]
In this embodiment, the shutter is a transmissive liquid crystal element. However, the shutter is not limited to liquid crystal as long as it can control light transmission and blocking.
In this embodiment, three mirrors (three micromirror devices) are shown in the micromirror array, but the present invention is not limited to this, and 50 mirrors, 100 mirrors, or more may be used.

  In the present embodiment, the configuration of the 1-input N-output type optical switch has been described. However, it is also possible to configure an N-input 1-output type optical switch by using the input port unit and the output port unit opposite to each other. It is.

[Fourth embodiment]
〔Constitution〕
The present embodiment is a wavelength selective switch in which the configuration of the optical path switching mechanism is different from that of the third embodiment. Specifically, as shown in FIG. 7, the wavelength selective switch 2000 of the present embodiment includes, as an optical path switching mechanism, a deflection mirror having a mirror surface whose direction can be changed, such as a commercially available galvano mirror 2001, and a galvano A galvano mirror control device 2003 for controlling the mirror 2001 is provided. That is, in the wavelength selective switch 2000 of this embodiment, the beam splitter 1225, the shutters 1227a and 1227b, and the shutter control device 1233 of the wavelength selective switch 1200 in FIG. 6 are basically replaced with the galvano mirror 2001 and the galvano mirror control device 2003. It is the composition which was made.

  The optical path switching mechanism of FIG. 6 is configured to switch between the two optical paths P1 and P2, but the optical path switching mechanism of the present embodiment is configured to switch between the three optical paths P1, P2, and P3. For this reason, the wavelength selective switch 2000 of this embodiment includes a micromirror array 1241 in addition to the micromirror arrays 1213 and 1231. The micromirror array 1241 includes a plurality of micromirror devices 1241a, 1241b, and 1241c arranged one-dimensionally. As each of the micromirror devices 1241a, 1241b, and 1241c, the micromirror device 1002a typically shown in FIG. 2 in the description of the first embodiment can be applied.

  The galvano mirror control device 2003 controls the galvano mirror 2001 so that the mirror surface of the galvano mirror 2001 is repeatedly directed to the micromirror arrays 1213, 1231, and 1241 in order. As a result, the optical signal path is repeatedly switched in turn to the optical paths P1, P2, and P3.

  Other configurations are the same as those of the third embodiment.

[Action]
Similarly to the third embodiment, the wavelength multiplexed signal 1221 obtained by multiplexing a plurality of optical signals having different wavelengths is reflected by the reflective diffraction grating 1215 after passing through the main lens 1214, and thus has a plurality of lights having different wavelengths. The signals 1222a, 1222b, and 1222c are demultiplexed. The demultiplexed optical signals 1222a, 1222b, 1222c pass through the main lens 1214 again and enter the galvanometer mirror 2001. The optical signals 1222a, 1222b, and 1222c incident on the galvanometer mirror 2001 are reflected by the galvanometer mirror 2001 along, for example, the optical path P1, and enter the micromirror array 1213. The optical signals 1223a, 1223b, and 1223c reflected by the micromirror array 1213 are reflected again by the galvanometer mirror 2001. Thereafter, similarly to the third embodiment, the optical signals 1223a, 1223b, and 1223c pass through the collimating lens 1216 and the main lens 1214, are reflected by the reflective diffraction grating 1215, pass through the main lens 1214 again, and then output. The light enters the ports 1211a and 1211b of the output port unit 1211 of the port unit 1211.

  The rotation angle of the micromirror array 1213 in the operating state changes with time, similarly to the micromirror devices 1002a and 1002b of the first embodiment. This rotational angle change amount has an allowable range corresponding to the allowable range of optical power.

(Control example)
The galvano mirror control device 2003 and the mirror control device 1235 perform, for example, the same control as the control described in relation to FIG. 4 in the first embodiment.

  For example, in a state where an optical signal from the input port unit 1210 is coupled to the output port unit 1211 via the micromirror array 1213 on the optical path P1, the rotation angles of the micromirror devices 1213a, 1213b, and 1213c in the operating state Immediately before the amount of change exceeds the allowable range, the galvano mirror control device 2003 changes the direction of the mirror surface of the galvano mirror 2001 to switch the optical signal path to the optical path P2, and at the same time, the mirror control device 1235 The mirror array 1231 is operated to set the micromirror devices 1231a, 1231b, and 1231c to desired rotation angles. As a result, the optical signal from the input port unit 1210 is coupled to the output port unit 1211 via the micromirror array 1231 on the optical path P2.

  Further, after switching the optical path, the mirror control device 1235 returns the micromirror array 1213 to the non-operating state, returns the supply voltage to the micromirror devices 1213a, 1213b, and 1213c to 0 V, and releases the accumulated electric charge. Thereafter, the mirror controller 1235 keeps the micromirror array 1213 in a non-operating state until it is next operated.

  Thereafter, similarly, the galvanomirror control device 2003 sequentially switches the optical paths P1, P2, and P3, and the mirror control device 1235 switches between the operating state and the non-operating state of the micromirror arrays 1213, 1231, and 1241. To do.

(Another control example)
Further, the galvanomirror control device 2003 and the mirror control device 1235 may perform the same control as the control described in relation to FIG. 5 in the second embodiment.

  For example, in a state where the optical signal from the input port unit 1210 is coupled to the output port unit 1211 via the micromirror array 1213 on the optical path P1, the optical signal path is changed from the optical path P1 to the optical path P2. In addition, the mirror control device 1235 operates the micromirror array 1231 to set the micromirror devices 1231a, 1231b, and 1231c to desired rotation angles.

  After that, before the rotation angle change amount of the micromirror devices 1213a, 1213b, and 1213c in the operating state exceeds the allowable range, the galvano mirror control device 2003 changes the direction of the mirror surface of the galvano mirror 2001 to change the optical signal. The path is switched from the optical path P1 to the optical path P2. As a result, the optical signal from the input port unit 1210 is coupled to the output port unit 1211 via the micromirror array 1231 on the optical path P2.

  Further, after switching the optical path, the mirror control device 1235 returns the micromirror array 1231 to the non-operating state, returns the supply voltage to the micromirror devices 1231a, 1231b, and 1231c to 0 V, and releases the accumulated charges. Thereafter, the mirror controller 1235 keeps the micromirror array 1231 in a non-operating state until the next operation.

  Thereafter, similarly, the galvanomirror control device 2003 sequentially switches the optical paths P1, P2, and P3, and the mirror control device 1235 switches between the operating state and the non-operating state of the micromirror arrays 1213, 1231, and 1241. Do it.

〔effect〕
In addition to the effects of the third embodiment, the number of components can be reduced, and an inexpensive wavelength selective switch can be provided.

[Modification]
Here, an example in which the deflection mirror is configured by the galvanometer mirror 2001 has been shown. However, the deflection mirror is not limited to the galvanometer mirror, and the mirror surface can be deflected in a plurality of directions, whereby a plurality of optical paths can be switched. It can be replaced by any mirror, such as a MEMS mirror. Moreover, although the example of the optical path switching mechanism which switches three optical paths was shown, the optical path switching mechanism of this embodiment can be easily extended to the structure which switches four optical paths.

  The embodiments of the present invention have been described above with reference to the drawings. However, the present invention is not limited to these embodiments, and various modifications and changes can be made without departing from the scope of the present invention. Also good. The various modifications and changes described here include an implementation in which the above-described embodiments are appropriately combined.

310 ... Mirror unit, 312 ... Fixed part, 314 ... Composite torsion bar, 316 ... Movable support part, 318 ... Composite torsion bar, 320 ... Movable part, 320a, 320b ... End, 322, 324 ... Rotating shaft, 326 ... Mirror surface, 328 ... Spacer, 340 ... Electrode substrate, 342, 342A, 342B, 342C, 342D ... Fixed electrode, 1000 ... Optical switch, 1001a ... Input port part, 1001b ... Output port part, 1002a, 1002b, 1012a, 1012b ... Micromirror device, 1003a, 1003b, 1013a, 1013b ... Micromirror array, 1005a, 1005b ... Beam splitter, 1007a, 1009a ... Shutter, 1011a, 1011b ... Fixed mirror, 1015 ... Shutter control device, 1017 ... Mi -Control device, 1200 ... wavelength selection switch, 1210 ... input port section, 1211 ... output port section, 1211a, 1211b ... port, 1213, 1231, 1241 ... micromirror array, 1213a, 1213b, 1213c, 1231a, 1231b, 1231c, 1241a, 1241b, 1241c ... micromirror device, 1214 ... main lens, 1215 ... reflective diffraction grating, 1216 ... collimating lens, 1221 ... wavelength multiplexed signal, 1222a, 1222b, 1222c, 1223a, 1223b, 1223c ... optical signal, 1225 ... Beam splitter, 1227a, 1227b ... Shutter, 1233 ... Shutter controller, 1235 ... Mirror controller, 2000 ... Wavelength selection switch, 2001 ... Galvano mirror, 2003 ... Gal Nomira controller, 3001,3003 ... hatched portions, P1, P2, P3 ... optical path, T1, T2, T3, T4, T5 ... time.

Claims (10)

An input port unit having at least one port to which an optical signal is input;
An output port unit having at least one port for outputting an optical signal;
An optical coupling optical system capable of optically coupling the input port unit and the output port unit via a plurality of optical paths;
An optical path switching mechanism capable of switching an optical path for optically coupling the input port section and the output port section;
Comprising a plurality of port switching mechanisms respectively provided for the plurality of optical paths;
At least one of the input port unit and the output port unit has a plurality of ports, and each port switching mechanism can switch the ports of the input port unit and the output port unit coupled to each other.   2. The light according to claim 1, wherein each port switching mechanism includes at least one micromirror array, and the optical switch includes a mirror control device that controls each micromirror array of the plurality of port switching mechanisms. switch.   The said mirror control apparatus operates the micro mirror array of the port switching mechanism on the optical path which optically couple | bonds the said input port part and the said output port part simultaneously with switching of the optical path by the said optical path switching mechanism. Light switch.   4. The optical switch according to claim 3, wherein the mirror control device maintains a micromirror array of a port switching mechanism on an optical path that is not optically coupled to the input port unit and the output port unit in a non-operating state.   The mirror control device operates a micromirror array of a port switching mechanism on an optical path that optically couples the input port unit and the output port unit next before switching the optical path by the optical path switching mechanism. 2. The optical switch according to 2.   The mirror control device returns the micromirror array of the port switching mechanism on the optical path that optically couples the input port unit and the output port unit to the non-operating state after the optical path switching by the optical path switching mechanism. The optical switch according to claim 5.   The optical switch according to claim 1, wherein the optical path switching mechanism includes a plurality of shutters respectively provided on the plurality of optical paths, and a shutter control device that controls the plurality of shutters. .   The optical coupling optical system and the optical path switching mechanism each include a deflection mirror having a mirror surface whose direction can be changed, and a deflection mirror control device that controls the deflection mirror. The optical switch described in one. The input port unit has a plurality of ports,
The output port section has a plurality of ports,
The optical coupling optical system forms an optical path dividing element that divides one optical path extending from the input port portion into the plurality of optical paths, and a single optical path extending toward the output port portion by combining the plurality of optical paths. An optical path combining element that
The optical switch according to claim 1, wherein each port switching mechanism has two micromirror arrays. The input port unit has one port;
The output port section has a plurality of ports,
The optical coupling optical system divides one optical path extending from the input port section into the plurality of optical paths and combines the plurality of optical paths to form one optical path extending toward the output port section. Having elements,
Each port switching mechanism has one micromirror array,
The optical switch further includes an optical spectroscopic element disposed on an optical path from the input port to the optical path splitting / combining element and on an optical path from the optical path splitting / combining element to the output port. An optical switch according to any one of the above.

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