JP2000019434A - Optical selector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inexpensive optical selector of a simple constitution which is capable of switching an optical transmission line as it is in a light state without transducing an optical signal into an electrical signal. SOLUTION: This selector is constituted so that the optical signal S emitted from one end of an input side optical fiber 1 is reflected at an optical reflection part 3 where a movable reflecting plate 3r is controlled with a control circuit 2 and that a reflected light S' is made to enter one end of either of plural output side optical fibers 4. Further. the central part on one end surface of each output side optical fiber 4 is arranged so as to be in contact with a sphericality with an optical signal reflecting point of the optical reflection part 3 as a center and a semiconductor galvanomirror is used in the optical reflection part 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an optical selector for selectively outputting an input optical signal from any one of a plurality of optical transmission lines, and more particularly to an optical selector that does not require photoelectric conversion. is there.

[0002]

2. Description of the Related Art For example, in various types of optical communication equipment for transmitting and receiving optical signals via optical transmission lines such as optical fibers, there are cases where optical signals are input / output to / from a plurality of optical fibers.
In such a device, an optical selector (optical switch) is used to output an input optical signal to one of the optical fibers.
Is used.

A conventional optical selector generally converts an optical signal sent from an input optical fiber into an electric signal using a light receiving element, and inputs the electric signal to a selection circuit or the like to switch an output destination. Then, the electric signal output from the selection circuit is converted into an optical signal using a light emitting element, and the optical signal is transmitted to the optical fiber on the output side.

[0004]

However, in the conventional optical selector, it is necessary to convert the input optical signal into an electric signal once and convert it into an optical signal again as described above.
A light-receiving element, a light-emitting element, and the like must be provided for each optical fiber on the input side and the output side, and the configuration is complicated. In particular, in the case of an optical selector used in an optical switch or an optical computer of a subscriber optical network, a large number of optical fibers are connected as an input / output optical transmission line, so that the configuration becomes more complicated. There is a problem that the optical selector becomes expensive.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has a simple configuration capable of switching an optical transmission line in a state of light without converting an optical signal into an electric signal, and is inexpensive. It is an object to provide a simple optical selector.

[0006]

Therefore, as one mode of the optical selector according to the present invention, there is provided an input-side optical transmission line from which an input optical signal is output from one end, and an output from the input-side optical transmission line. Light reflecting means including a movable reflecting surface for reflecting the reflected light signal, a plurality of output-side optical transmission paths through which the light signal reflected by the light reflecting means can be incident from one end, and reflection of the light reflecting means. Light reflection control for controlling the position of the reflection surface such that the optical signal reflected by the surface is incident from one end of one of the plurality of output side optical transmission lines selected from the plurality of output side optical transmission lines. And means.

According to this configuration, the optical signal input to the input side optical transmission line and emitted from one end is incident on the reflecting surface of the light reflecting means and is reflected. The light reflecting means adjusts the position (angle) of the reflecting surface so that the reflected light is incident from one end of one of the plurality of output-side optical transmission paths selected from the plurality of output-side optical transmission paths. Controlled by means. Thus, the optical signal reflected by the light reflecting means enters from one end of the selected output-side optical transmission line, propagates through the output-side optical transmission line, and is output. Therefore, the switching of the output optical transmission line is performed in the state of the optical signal.

In the above-mentioned optical selector, it is preferable that each of the output-side optical transmission lines is arranged such that a central portion of one end surface thereof is in contact with a spherical surface centered on a light signal reflection point of the light reflection means. . Accordingly, the optical signal reflected by the light reflecting means is incident on the one end surface of each output side optical transmission line substantially perpendicularly, so that the optical selector has a low loss.

Alternatively, there is provided an optical system for changing the propagation direction of the optical signal reflected by the light reflecting means to a fixed direction, and each of the output-side optical transmission lines has one end face passing through the optical system. The optical signal may be arranged so as to be substantially perpendicular to a certain propagation direction. In such a configuration, the propagation direction of the optical signal reflected by the light reflecting means is converted to a fixed direction by the optical system, and the light signal is incident on one end surface of each output-side optical transmission path substantially perpendicularly. As in the case of, an optical selector having a low loss is obtained.

In another aspect of the optical selector according to the present invention, there are provided a plurality of input-side optical transmission paths from which an input optical signal is emitted from one end, and a plurality of light paths emitted from each of the input-side optical transmission paths. A first light reflecting means including a plurality of movable reflecting surfaces for respectively reflecting signals, a plurality of output-side optical transmission paths capable of receiving each optical signal reflected by the first light reflecting means from one end, Each of the optical signals reflected by each of the reflection surfaces of the first light reflection means outputs one of the plurality of output-side optical transmission paths corresponding to the respective one of the input-side optical transmission paths. First light reflection control means for controlling the position of each of the reflection surfaces so as to be incident from one end of the side light transmission path.

According to this configuration, each optical signal input to each of the plurality of input-side optical transmission lines and emitted from one end is:
The light is incident on and reflected by each of the reflection surfaces of the first light reflection means. Each of these reflecting surfaces is positioned so that the reflected light is incident on one end of one output-side optical transmission line selected corresponding to the input-side optical transmission line from which the incident optical signal is sent. (Angle) is controlled by the first light reflection control means. Thus, each optical signal reflected by the first light reflecting means enters from one end of the selected output side optical transmission line, propagates through the output side optical transmission line, and is output. Therefore, the switching of the input / output optical transmission line is performed in the state of the optical signal.

The above-mentioned optical selector includes a plurality of movable reflecting surfaces corresponding to the respective output-side optical transmission lines, and each of the reflecting surfaces is reflected by each of the reflecting surfaces of the first light reflecting means. Second light reflecting means for respectively reflecting the optical signals, and the respective optical signals reflected by the respective reflecting surfaces of the second light reflecting means are substantially perpendicularly incident on one end face of the corresponding output side optical transmission line. And a second light reflection control means for controlling the position of each reflection surface.

In this configuration, each optical signal reflected by each reflection surface of the first light reflection means is applied to each reflection surface of the second light reflection means corresponding to the output side optical transmission path to which each of the light signals is output. After being reflected by the optical transmission line, the light is incident from one end of the corresponding output side optical transmission line. Each position of each reflection surface of the second light reflection means is controlled by the second light reflection control means, so that the optical signal is incident on the one end face of each output side optical transmission line substantially perpendicularly. And the optical selector has a low loss.

Alternatively, a plurality of lens portions corresponding to the respective output-side optical transmission lines are provided, and in each of the lens portions, an optical signal reflected by each reflecting surface of the first light reflecting means is output to a corresponding output side. One end surface of the optical transmission path may be provided with a lens array for condensing light. Accordingly, the optical signal reflected by each reflection surface of the first light reflection means passes through each lens portion of the lens array, and is condensed on one end surface of the corresponding output-side optical transmission path. In this case, the optical selector has a low loss as in the above case.

Further, as a specific configuration of the optical selector of each of the above-described embodiments, it is preferable that each of the reflecting surfaces is a reflecting mirror of a semiconductor galvanometer mirror manufactured by using a semiconductor manufacturing technique. By making each reflecting surface of the light reflecting means a reflecting mirror of a semiconductor galvanometer mirror, the size of the optical selector can be reduced.

[0016]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an external view illustrating a main part configuration of the optical selector according to the first embodiment. In FIG.
The present optical selector is configured, for example, such that an optical signal S emitted from one end of one input side optical fiber 1 which is an input side optical transmission line is
The reflected light S ′ is reflected by a light reflecting section 3 as a light reflecting means that is driven and controlled by a control circuit 2 as a light reflection controlling means, and the reflected light S ′ is transmitted to a plurality of output side optical fibers 4 as an output side optical transmission line. In this configuration, the light is incident on one of the ends.

The input optical fiber 1 and the output optical fiber 4 are general optical fibers used in various optical communication systems. Here, the optical signal S is emitted from the input side optical fiber 1 without passing through an optical system such as a lens,
Also, it is assumed that the reflected light S ′ is incident on each output side optical fiber 4. Note that an optical system may be provided at one end of each optical fiber so as to condense optical signals that enter and exit. Further, the optical transmission line of the present invention is not limited to an optical fiber, but may be, for example, an optical waveguide.

The arrangement of the input side optical fiber 1, the light reflecting section 3 and each output side optical fiber 4 is, for example, as shown in the side sectional view of FIG. The central portion of the end face is provided so as to be in contact with a spherical surface centered on the light signal reflection point of the light reflection portion 3. With such an arrangement, the reflected light S ′ from the light reflecting section 3 is incident on the end face of the output side optical fiber 4 substantially perpendicularly. Here, each end face of the input side optical fiber 1 and the output side optical fiber 4 is located on the same spherical surface, but each end face of the input side optical fiber 1 is It may be arranged on a different spherical surface from the located spherical surface.

The light reflecting section 3 is a movable mirror which is disposed at a predetermined angle with respect to the optical axis of the optical signal S, and in which the reflecting plate 3r rotates based on a signal from the control circuit 2. The angle of the reflecting plate 3r arranged on the optical axis and the displacement angle for rotating the reflecting plate 3r are set according to the arrangement of the output side optical fiber 4 on which the reflected light S 'is incident. As the light reflecting portion 3, for example, it is preferable to use a semiconductor galvanomirror manufactured using a semiconductor manufacturing technique. This semiconductor galvanometer mirror is disclosed by the present applicant in Japanese Patent Application Laid-Open Nos.
This has been previously proposed in Japanese Patent Application Publication No. 218857 and the like, and is described in detail in each of the above publications.

FIG. 3 is an exploded perspective view of an example of a semiconductor galvanomirror suitable as the light reflecting portion 3 of the present embodiment.
In FIG. 3, a semiconductor galvanomirror 200 has a silicon substrate 201 on which an outer movable plate 204A is provided with a torsion bar 2.
The inner movable plate 204B is pivotably supported by the torsion bar 205B whose axis is orthogonal to the torsion bar 205A inside the outer movable plate 204A. It is pivoted. The outer movable plate 204A is formed in a frame shape, and a pair of outer electrode terminals 209A and 209A formed on the upper surface of the silicon substrate 201 is formed on the upper surface thereof.
A planar coil 206A (shown schematically as a single line in the figure) electrically connected through one portion of the coil 05A is provided so as to be covered with an insulating layer. Also, the inner movable plate 204B
Is formed in a flat plate shape, and a silicon substrate 20
1 pair of inner electrode terminals 209B, 209B
To the outer movable plate 204 from one side of the torsion bar 205B.
A planar coil 206B (schematically indicated by a single line in the figure) which passes through the portion A and is electrically connected to the torsion bar 205A via the other side is provided so as to be covered with an insulating layer. Inner movable plate 204B surrounded by planar coil 206B
A total reflection mirror (reflection mirror) 208 is formed at the center of the. The total reflection mirror 208 corresponds to the reflection plate 3r of the light reflection unit 3.

Upper and lower glass substrates 202 and 203 made of, for example, borosilicate glass are anodically bonded to the upper and lower surfaces of the silicon substrate 201, respectively. The upper glass substrate 202 has a square opening 202A at the center of the flat plate portion.
And the upper portion of the movable plate is open. The lower glass substrate 203 has a square groove 203 in the center of the flat plate.
A. Thereby, the upper and lower glass substrates 20
2, 203 and the silicon substrate 201 have a three-layer structure to secure a swinging space for both movable plates 204A, 204B.

The upper and lower glass substrates 202 and 203 each have eight permanent magnets 21 in pairs.
0A to 213A and 210B to 213B are arranged as shown. The permanent magnets 210A and 211A of the upper glass substrate 202 facing each other are
Generates a magnetic field for driving the outer movable plate with the permanent magnets 210B and 211B. The permanent magnets 212A and 213A of the upper glass substrate 202 facing each other generate a magnetic field for driving the inner movable plate with the permanent magnets 212B and 213B of the lower glass substrate 203.

Next, the operating principle of the semiconductor galvanometer mirror 200 will be briefly described. For example, the electrode terminal 209
A and 209A have one of them as a positive pole and the other as a negative pole, and a current flows through the plane coil 206A. On both sides of the outer movable plate 204A, a magnetic field is formed by the permanent magnets 210A and 210B and the permanent magnets 211A and 211B in a direction crossing the plane coil 206A along the plane of the outer movable plate 204A. When a current flows through the planar coil 206A in the magnetic field, the current is applied to both ends of the outer movable plate 204A in accordance with the current density and the magnetic flux density of the planar coil 206A in a direction according to the left-hand rule of Fleming of current, magnetic flux density, and force. The force acts, and the outer movable plate 204A rotates. When the outer movable plate 204A rotates, the torsion bar 205A is twisted, and the outer movable plate 204A is turned to a position where the spring reaction force of the torsion bar 205A generated thereby and the electromagnetic force acting on the outer movable plate 204A are balanced. Move.

At this time, the displacement angle of the outer movable plate 204A is
It is proportional to the current flowing through the planar coil 206A. Therefore,
By controlling the current flowing through the planar coil 206A,
The displacement angle of the outer movable plate 204A, that is, the total reflection mirror 208 can be controlled. If the relationship between the amount of current flowing through the planar coil and the displacement angle of the movable plate is determined in advance, the total reflection mirror 208 can be set at a desired displacement angle position by controlling the amount of current.

The inner movable plate 204B is
By rotating around the torsion bar 205B as an axis according to the same operating principle as that of A, the displacement angle can be controlled by controlling the amount of current flowing through the planar coil 206B. By controlling the rotation of the outer and inner movable plates 204A and 204B in this manner, the position of the total reflection mirror 208, that is, the position of the reflection plate 3r of the light reflection unit 3 can be variably controlled.

A detection coil (not shown) for detecting the displacement of the outer movable plates 204A and 204B based on the mutual inductance with the planar coils 206A and 206B is provided on the lower glass substrate 203, and each torsion bar 205
A and 205B are preferably provided symmetrically. In this case, when controlling the displacement angle of the mirror 208, a displacement angle detection current having a frequency higher than the drive current frequency is supplied to the plane coil 206A so as to be superimposed on the drive current. Then, based on this detection current, an induced voltage is generated in each detection coil by mutual inductance between the planar coil 206A and the detection coil provided on the lower glass substrate 203. When the outer movable plate 204A is in the horizontal position, the distance between the induced coils generated in the detection coils is equal to the distance between each detection coil and the corresponding planar coil 206A, and the difference is zero. When the outer movable plate 204A rotates around the torsion bar 205A due to the electromagnetic force, one of the detection coils approaches and the mutual inductance increases, and the induced voltage increases. The voltage drops. Therefore, the induced voltage generated in both the detection coils changes according to the displacement angle of the movable plate, and by detecting this induced voltage, the movable plate, that is,
The displacement angle of the total reflection mirror 208 can be detected. Then, for example, a bridge circuit or the like is used to feed back the induced voltage difference generated between the two detection coils to the drive system of the outer movable plate 204A via the differential amplifier to control the drive current. It is possible to control the displacement angle of 208 more precisely.

Next, the operation of the optical selector configured as described above will be described. When the present optical selector is activated, based on a command for selecting from which output optical fiber 4 the optical signal input to the input optical fiber 1 is output.
A control signal is sent from the control circuit 2 to the light reflecting unit 3 to drive the light reflecting unit 3. As a result, the reflection plate 3r of the light reflection unit 3 is held at a predetermined position corresponding to the output side optical fiber 4 for outputting an optical signal.

When an optical signal is input to the optical selector in such a state, the optical signal S emitted from one end of the input side optical fiber 1 enters the reflecting plate 3r of the light reflecting section 3 at a constant angle. Is reflected. The reflected light S ′ travels straight toward one end of the selected output side optical fiber 4, enters the end face at an almost perpendicular angle, propagates through the output side optical fiber 4, and is output.

When a command for switching the output side optical fiber 4 for outputting an optical signal is sent to the control circuit 2, a control signal for moving the reflecting plate 3r of the light reflecting section 3 is sent to the control circuit 2.
Is sent to the light reflection unit 3 and the reflection plate 3r is held at a position corresponding to the output side optical fiber 4 after the switching. As a result, the reflected light S ′ emitted from the input side optical fiber 1 and reflected by the light reflecting portion 3 is substantially perpendicularly incident on one end of the output side optical fiber 4 which is different from the one before, and inside the output side optical fiber 4. And is output.

As described above, according to the first embodiment, the signal light S emitted from one input-side optical fiber 1 is reflected by the light reflector 3 in which the position of the reflector 3r is variably controlled. ,
By making the light incident on any one of the plurality of output-side optical fibers 4, the optical signal is once converted into an electric signal and then converted into an optical signal again, unlike a conventional optical selector.
The output can be switched directly in the state of the optical signal, and an inexpensive optical selector can be realized with a simple configuration. In addition, since the respective end faces of the output side optical fiber 4 are arranged on the same spherical surface, the reflected light S ′ from the light reflecting portion 3 is incident on the end face of the output side optical fiber 4 almost perpendicularly. , A low-loss optical selector. Further, if a semiconductor galvanomirror is used for the light reflecting portion 3, the size of the optical selector can be reduced.

Next, a second embodiment of the present invention will be described. FIG. 4 is a side cross-sectional view illustrating a main configuration of the optical selector according to the second embodiment. However, the same parts as those in the configuration of the first embodiment are denoted by the same reference numerals. FIG.
In the optical selector according to the second embodiment, the end faces of the plurality of output-side optical fibers 4 are arranged on one plane, and the reflected light S ′ from the light reflecting portion 3 is incident on each end face substantially perpendicularly. In order to make the reflected light S ′ emitted in each direction parallel, a lens 5 (optical system) is provided. The configuration of the second embodiment is the same as the configuration of the first embodiment except that the end faces of the output side optical fiber 4 are arranged on one plane and the lens 5 is provided.

The lens 5 is arranged between the light reflecting portion 3 and each end face of the output side optical fiber 4 such that the focal point coincides with the light signal reflecting point of the light reflecting portion 3. The light reflected by the light reflection unit 3 at a predetermined reflection angle becomes parallel light that travels in a certain direction by passing through the lens 5. In the optical selector having such a configuration, as in the case of the first embodiment,
The light reflecting section 3 is driven in response to a control signal from the control circuit 2, and the reflecting plate 3r is held at a predetermined position corresponding to the output side optical fiber 4 for outputting an optical signal. The optical signal S emitted from one end of the input side optical fiber 1 is reflected by the reflector 3 r, and the reflected light S ′ is sent to the lens 5. Lens 5
The reflected light S ′ that has passed through the optical fiber 4 becomes parallel light that travels in a certain direction, enters the selected end face of the output-side optical fiber 4 substantially perpendicularly, propagates through the output-side optical fiber 4, and is output. You.

As described above, according to the second embodiment, when it is necessary to arrange the respective end faces of the plurality of output side optical fibers 4 on one plane, the lens 5 which makes the reflected light S 'parallel light is used.
Is provided, the same effect as that of the first embodiment can be obtained. Next, a third embodiment of the present invention will be described. In the third embodiment, an optical selector that selectively outputs an optical signal input to each of a plurality of input optical fibers from any one of a plurality of output optical fibers is described. explain.

FIG. 5 is an external view showing the main configuration of an optical selector according to the third embodiment. In FIG. 5, the present optical selector includes an input-side optical fiber bundle 6 in which a plurality of input-side optical fibers are bundled, and a second optical fiber bundle that reflects an optical signal emitted from one end of each optical fiber of the input-side optical fiber bundle 6. A first light reflection array 7 as a first light reflection unit, a second light reflection array 8 as a second light reflection unit that reflects light reflected from the first light reflection array 7 again, Light reflection array 7,
The control circuit 9 includes a control circuit 9 for controlling the driving of the optical fiber 8 and an output-side optical fiber bundle 10 in which a plurality of output-side optical fibers into which the reflected light from the second light reflection array 8 is incident at one end.
Here, the control circuit 9 functions as first and second light reflection control means.

The input side optical fiber bundle 6, for example, 16 optical fibers 6a to 6p are bundled, and each optical fiber 6a to 6p is bundled.
One end face of 6p is arranged in the same plane. In addition, the output side optical fiber bundle 10 also includes, for example, 16 optical fibers 1.
0A to 10P are bundled, and each optical fiber 10A to 10P
Are arranged in the same plane. Here, the number of optical fibers on the input side and the output side is the same, but in the present invention, the number of optical fibers on the input side and the output side may be different, and each number can be arbitrarily selected.

The first light reflecting array 7 includes light reflecting portions 7a corresponding to the respective optical fibers 6a to 6p of the input side optical fiber bundle 6.
７7p are arranged in one plane. The second light reflecting array 8 includes light reflecting portions 8A to 8P corresponding to the optical fibers 10A to 10P of the output side optical fiber bundle 10, respectively.
Are arranged in one plane. Each of the light reflecting portions 7a to 7p, 8A to 8P of the first and second light reflecting arrays 7, 8
The light reflecting portions 3 used in the first and second embodiments, respectively.
It is preferable to use the same one as described above, and particularly to use a semiconductor galvanomirror. When a semiconductor galvanomirror is used, a semiconductor galvanomirror in which 16 semiconductor galvanomirrors are integrated on the same substrate is used.

The control circuit 9 issues a command for selecting from which of the optical fibers 10A to 10P of the output optical fiber bundle 10 the optical signals input to the respective optical fibers 6a to 6p of the input optical fiber bundle 6 are to be output. , A control signal is sent to each of the light reflecting arrays 7 and 8. Specifically, the control signal sent to the first light reflection array 7 is emitted from each of the optical fibers 6a to 6p of the input-side optical fiber bundle 6, and is reflected by the corresponding light reflection units 7a to 7p. The signals are output from the selected optical fibers 10 </ b> A to 1 </ b> A of the output side optical fiber bundle 10.
To be sent to the light reflecting portions 8A to 8P corresponding to 0P,
These are signals for controlling the positions of the respective reflectors by driving the respective light reflectors 7a to 7p. Control signals sent to the second light reflection array 8 are reflected by the first light reflection array 7 and correspond to the corresponding light reflection portions 8A to 8P of the second light reflection array.
The optical signal reflected again by the optical fiber 10
These signals control the positions of the respective reflection plates by driving the respective light reflecting portions 8A to 8P so that the light reflecting portions 8A to 8P are incident substantially perpendicularly on one end surfaces of A to 10P.

Accordingly, for each of the optical fibers 6a to 6p of the input side optical fiber bundle 6, the optical fibers 10A to 10A of the output side optical fiber bundle 10 which is the output destination of the input optical signal.
When P is selected, the driving state of each of the light reflecting portions 7a to 7p and 8A to 8P of the first and second light reflecting arrays (the angle of each reflecting plate).
Is determined. Next, the operation of the optical selector configured as described above will be described.

Here, as an example, a case where an optical signal emitted from the optical fiber 6a of the input-side optical fiber bundle 6 is made to enter the optical fiber 10A of the output-side optical fiber bundle 10, as indicated by a broken line arrow in FIG. Think. When a command for determining such input / output conditions is sent to the control circuit 9, the control circuit 9 drives the light reflection array 7a corresponding to the optical fiber 6a to the light reflection array 7, and transmits the light corresponding to the optical fiber 10A. A signal for controlling the reflector at an angle at which the reflected light is incident on the light reflecting portion 8A of the reflecting array 8 is sent. On the other hand, the light reflecting array 8A
And a signal for controlling the reflector at an angle such that the reflected light is incident on the end face of the optical fiber 10A substantially perpendicularly is sent.

The optical signal input to the optical fiber 6a of the input side optical fiber bundle 6 and emitted from one end enters the light reflecting portion 7a of the light reflecting array 7 and is reflected therefrom. Sent to section 8A. Light reflection part 7a
Is reflected by the light reflecting portion 8A, is reflected again, and is sent toward one end of the optical fiber 10A. The reflected light from the light reflecting portion 8A enters at an angle substantially perpendicular to the end face of the optical fiber 10A, propagates through the optical fiber 10A, and is output.

The optical signal input to the optical fiber 6a of the input side optical fiber bundle 6 in this manner is applied to each of the light reflecting arrays 7,
8, an optical fiber 10A of the output side optical fiber bundle 10
Will be output from Note that the optical signal input to the other optical fiber of the input-side optical fiber bundle 6 is also output from any one of the output-side optical fiber bundles 10 in the same manner as described above. A control signal is sent from the control circuit 9 to each of the light reflection arrays 7 and 8. Further, when a command to switch the output destination of the input optical signal is sent to the control circuit 9, the angle of the reflector for the corresponding light reflecting portion of each of the light reflecting arrays 7, 8 is changed according to the command, The optical path in which the optical signal travels is switched.

As described above, according to the third embodiment,
The optical signals emitted from the respective optical fibers 6a to 6p on the input side optical fiber side 6 are converted into the respective light reflecting portions 7 of the light reflecting arrays 7 and 8.
a to 7p, 8A to 8P, and any one of the optical fibers 10A to 10B of the plurality of output side optical fiber bundles 10
Since it is possible to switch the output destinations of a plurality of input optical signals in the state of light, it is possible to realize an inexpensive optical selector with a simple configuration.
Further, by adjusting the incident angle of the optical signal to each optical fiber of the output side optical fiber bundle 10 by the light reflection array 8, a low-loss optical selector can be provided. Further, each of the light reflecting portions 7a to 7p, 8A of the light reflecting arrays 7, 8
If a semiconductor galvanomirror is used for ~ 8P,
An array of light reflecting portions can be easily realized, and the size of the optical selector can be reduced.

Next, a fourth embodiment of the present invention will be described. In the fourth embodiment, the microlens array is used in place of the light reflection array 8 in the third embodiment described above, so that the reflected light from the light reflection array 7 is applied to each end face of the output side optical fiber bundle 10. A case where the light is efficiently incident will be described. FIG. 6 is an external view illustrating a main configuration of an optical selector according to the fourth embodiment.

In FIG. 6, in the present optical selector, instead of the light reflection array 8 used in the third embodiment, a micro lens array 11 is provided near one end of each of the optical fibers 10A to 10P of the output side optical fiber bundle 10. The control circuit 9 is arranged to drive and control the light reflection array 7. The configuration other than the above is the same as the configuration of the third embodiment. The microlens array 11 includes 16 microlenses 11A to 11P (lens portions) corresponding to the optical fibers 10A to 10P of the output side optical fiber bundle 10, which are arranged in one plane. Each of the microlenses 11A to 11P has a function of condensing the reflected light from the light reflection array 7 on the end faces of the corresponding optical fibers 10A to 10P. That is, the microlens array 11 is arranged so that the light reflection array 7 forms an image on the end face of each optical fiber on the output side. As such a microlens array 11, for example, a known microlens array proposed in the field of an optical computer or the like can be used.

In the optical selector having the above-described configuration, for example, the optical signal emitted from the optical fiber 6a of the input-side optical fiber bundle 6 is converted into the optical fiber 10 of the output-side optical fiber bundle 10.
A, when the light is incident on the light reflection array 7 from the control circuit 9.
Then, the light reflecting portion 7a corresponding to the optical fiber 6a is driven,
Microlens array 11 corresponding to optical fiber 10A
A signal for controlling the reflection plate is sent at an angle at which the reflected light is sent toward the microlens 11A. The optical signal input to the optical fiber 6a of the input side optical fiber bundle 6 and emitted from one end is applied to the light reflecting portion 7a of the light reflecting array 7.
And is reflected and incident on the microlenses 11A of the microlens array 11. Micro lens 11A
Is incident on the end face of the optical fiber 10A in a condensed state, propagates through the optical fiber 10A, and is output. The same applies to the optical signals input to the other optical fibers of the input-side optical fiber bundle 6 as described above. When a command to switch the output destination of the input optical signal is sent to the control circuit 9, the state of the corresponding light reflecting portion of the light reflecting array 7 is controlled according to the command, and the optical path of the optical signal is switched. Can be

As described above, according to the fourth embodiment, the same effect as in the third embodiment can be obtained by providing the microlens array 11 near one end of the output-side optical fiber bundle 10. It is possible.

[0047]

As described above, according to the first aspect of the present invention,
The signal light emitted from the input-side optical transmission path, the position of the reflecting surface is reflected by a light reflecting means whose position is controlled,
By making the light incident on any one of the plurality of output-side optical transmission lines, it is possible to switch the optical transmission line in the state of the optical signal without performing photoelectric conversion. An inexpensive optical selector can be realized.

According to a second aspect of the present invention, the central portion of each end face of the output side optical transmission line is arranged so as to be in contact with the spherical surface centered on the optical signal reflection point of the optical reflection means, thereby achieving light reflection. Since the reflected light from the means is incident on the end face of the output-side optical transmission line substantially perpendicularly, a low-loss optical selector can be provided. Alternatively, an optical system for converting the propagation direction of the reflected light from the light reflecting means into a fixed direction is provided, and the optical system is substantially perpendicular to the propagation direction of the optical signal passing through the optical system. Even if the respective end faces of the output-side optical transmission line are arranged as described above, the same effect as the second aspect of the invention can be obtained.

According to a fourth aspect of the present invention, each signal light emitted from the plurality of input-side optical transmission lines is reflected by the first light reflecting means whose position of the corresponding reflecting surface is controlled. By making the light incident on any one of the plurality of output-side optical transmission lines, it becomes possible to perform switching of the output optical transmission lines for a plurality of input optical signals in the light state, which is simplified. With a simple configuration, an inexpensive optical selector can be realized.

Further, according to the present invention, the angle of incidence of the optical signal on each end face of each output side optical transmission line is adjusted by the second light reflecting means, so that the optical loss of low loss is reduced. Can provide a selector. Alternatively, as in the invention according to claim 6, a lens array for condensing the reflected light from the first light reflecting means on one end surface of the output side optical transmission path may be provided. The same effect as that of the invention is obtained.

According to the seventh aspect of the present invention, in addition to the above-described effects, the size of the optical selector can be reduced by using each reflecting surface as a reflecting mirror of a semiconductor galvanometer mirror. Integration of the reflection surface can also be easily realized.

[Brief description of the drawings]

FIG. 1 is an external view showing a configuration of a main part of a first embodiment of the present invention.

FIG. 2 is a side sectional view showing an arrangement of each part of the first embodiment.

FIG. 3 is an exploded perspective view showing a configuration of a semiconductor galvanometer mirror used in the first embodiment.

FIG. 4 is a side sectional view showing a main part configuration of a second embodiment of the present invention.

FIG. 5 is an external view illustrating a configuration of a main part of a third embodiment of the present invention.

FIG. 6 is an external view showing a main part configuration of a fourth embodiment of the present invention.

[Description of Signs] 1, 6a to 6p: Input-side optical fiber 2, 9: Control circuit 3, 7a to 7p, 8A to 8P: Light reflecting portion 4, 10A to 10P: Output-side optical fiber 5: Lens 6: Input Side optical fiber bundle 7 First light reflection array 8 Second light reflection array 10 Output side optical fiber bundle 11 Microlens array 11A to 11P Microlens

Claims (7)

[Claims] 1. An input optical transmission line from which an input optical signal is emitted from one end, and a light reflecting means including a movable reflecting surface for reflecting an optical signal emitted from the input optical transmission line, A plurality of output-side optical transmission lines capable of receiving the optical signal reflected by the light reflecting means from one end, and an optical signal reflected by a reflecting surface of the light reflecting means, A light reflection control means for controlling the position of the reflection surface so as to be incident from one end of one of the selected output-side optical transmission lines. 2. The optical transmission line according to claim 1, wherein a central portion of one end face of each of the output side optical transmission lines is arranged so as to be in contact with a spherical surface centered on a light signal reflection point of the light reflection means. 2. The optical selector according to 1. 3. An optical system for converting a propagation direction of an optical signal reflected by the light reflecting means to a fixed direction, wherein each of the output-side optical transmission paths has one end face passing through the optical system. 2. The optical selector according to claim 1, wherein the optical selector is arranged so as to be substantially perpendicular to a certain propagation direction of the optical signal. 4. An optical transmission system comprising: a plurality of input-side optical transmission paths from which an input optical signal is emitted from one end; and a plurality of movable reflecting surfaces for respectively reflecting the optical signals emitted from each of the input-side optical transmission paths. A first light reflecting means, a plurality of output-side optical transmission paths through which the respective optical signals reflected by the first light reflecting means can be incident from one end, and a plurality of reflection surfaces of the first light reflecting means. Each of the reflected optical signals is incident from one end of one output-side optical transmission line selected corresponding to each of the input-side optical transmission lines of the plurality of output-side optical transmission lines, And a first light reflection control means for controlling the position of each of the reflecting surfaces. 5. A plurality of movable reflecting surfaces corresponding to the respective output-side optical transmission lines, and each of the reflecting surfaces reflects an optical signal reflected by each of the reflecting surfaces of the first light reflecting means. A second light reflecting means, and such that each optical signal reflected by each reflecting surface of the second light reflecting means is substantially perpendicularly incident on one end face of the corresponding output side optical transmission line. The optical selector according to claim 4, further comprising: a second light reflection control unit that controls a position of each of the reflection surfaces. 6. A plurality of lens sections corresponding to each of said output-side optical transmission lines, wherein each lens section outputs an optical signal reflected by each reflection surface of said first light reflecting means to a corresponding output side. 5. The optical selector according to claim 4, further comprising a lens array for focusing light on one end surface of the optical transmission path. 7. The optical selector according to claim 1, wherein each of the reflecting surfaces is a reflecting mirror of a semiconductor galvanometer mirror manufactured by using a semiconductor manufacturing technique.