JPH06331837A - Optical device - Google Patents

Abstract

PURPOSE:To eliminate the need for a photocoupler and an optical branching filter to make a system small in size, light in weight, and low in cost, to prevent the degradation of a signal due to reflected light, to facilitate arraying and integration of the system, and to improve the productivity to reduce the cost of the system. CONSTITUTION:When the optical signal supplied from the other end face side of a first waveguide 2 is propagated in the first waveguide 2 to reach a half- transmission and half-reflection face 1, this optical signal is reflected by the face 1 and is converted to an electric signal by a photo-detector 5; and when the optical signal supplied from the other end face side of a second waveguide 4 is propagated in the second waveguide 4 to reach a half-transmission and half-reflection face 3 of the second waveguide 4, this optical signal is transmitted through this face 3 and the half-transmission and half-reflection face 1 and is supplied to the other end face side of the first waveguide 2.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical device used for optical fiber communication, and more particularly to an optical CAT.
V, an optical device used as an optical transmitter or an optical receiver used in the field of optical communication and the like.

SUMMARY OF THE INVENTION The present invention relates to an optical device capable of bidirectional optical fiber communication.
By opposing the first optical waveguide and the second optical waveguide, each of which has an oblique cut surface, between the light source and the photodetector, bidirectional communication is possible without using an optical coupler and the like. In addition to achieving downsizing and cost reduction of the system, it is possible to improve reliability and integration, and to prevent signal deterioration due to multiple reflected light, which would occur when an optical coupler is used.

[0003]

2. Description of the Related Art As an optical device capable of performing bidirectional optical fiber communication, the device shown in FIG. 11 is conventionally known.

The optical device shown in this figure has terminals respectively
An optical coupler (or an optical demultiplexer) 102 to which two optical fibers 101 are connected and which transmits an optical signal supplied via each of these optical fibers 101 to each of the other optical fibers 101.
And four optical connectors 10 provided at the other end of each optical fiber 101 connected to one end of the optical coupler 102 and optically connecting each optical fiber 101 to another optical fiber.
4, an optical fiber 103, one end of which is connected to one of the optical connectors 104, and the other end of the optical fiber 103, which generates an optical signal in response to an input drive signal. A light source 105 that causes an optical signal to enter the other end of the optical fiber 103, and one end of each of the optical connectors 104
One of the optical fiber 106 and the other end of the optical fiber 106.
And a photodetector 107 that receives an optical signal supplied via 6 and generates an electrical signal.

Then, when a drive signal is supplied from a transmission circuit (not shown), an optical signal is generated by the light source 105, and the optical signal is generated via each of the optical fibers 103, 101, the optical connector 104 and the optical coupler 102. When it is transmitted to a communication destination and an optical signal is supplied from the communication destination, it is guided to the photodetector 107 via each of the optical fibers 101 and 106, the optical connector 104 and the optical coupler 102 and converted into an electric signal. , To a receiving circuit (not shown).

[0006]

By the way, the conventional optical device used in such a bidirectional optical transmission system has the following problems.

That is, in the conventional optical device, the optical coupler 102, the optical demultiplexer, and the like are required, and many other independent optical components are required. Therefore, the system is downsized, reduced in cost, and integrated. However, there is a problem in that the cost cannot be increased.

Further, there is a possibility that unwanted interference or interference may occur due to the interaction of coherent light between the optical components, resulting in deterioration of system characteristics.

For example, the reflected lights from the four optical connectors 104 added to the optical coupler 102 interfere with each other through the optical coupler 102, which distorts the signal.

Therefore, in order to eliminate such inconvenience, in the conventional optical device, each end face of the optical connector 104 is all polished obliquely so that signal distortion due to multiple reflection does not occur.

However, in such a method, each end face of each optical connector 104 has to be polished by the number of optical connectors 104, so that there is a problem that the polishing cost is too high.

In view of the above circumstances, the present invention makes it possible to reduce the size, weight and cost of the system by eliminating the need for an optical coupler, an optical demultiplexer and the like, and to prevent signal deterioration due to reflected light. It is an object of the present invention to provide an optical device capable of facilitating arraying and integration of a system while preventing it, and further improving productivity to achieve cost reduction of the system.

[0013]

In order to achieve the above object, an optical device according to the present invention is a semi-transmissive / semi-transmissive device in which one end face is inclined with respect to the optical axis and a part of a propagating optical signal is reflected. A first waveguide having a reflective surface and a semi-transmissive / semi-reflective surface on the end surface opposite to the semi-transmissive / semi-reflective surface, with the end surface being inclined at an angle corresponding to the semi-transmissive / semi-reflective surface. The second waveguide having the optical waveguide and the other end face side of the first waveguide, and the optical signal reflected by the semi-transmissive / semi-reflective surface of the first waveguide are received and converted into an electrical signal. And a photodetector that operates.

[0014]

In the above structure, when an optical signal is supplied from the other end face side of the first waveguide and this propagates through the first waveguide and reaches the semi-transmissive / semi-reflective surface, the semi-transmissive / semi-reflective surface is transmitted. The light is reflected by the reflecting surface and converted into an electric signal by the photodetector, and an optical signal is supplied from the other end face side of the second waveguide, which propagates through the second waveguide and is semi-transmissive of the second waveguide. When reaching the semi-reflective surface, the semi-transmissive / semi-reflective surface and the semi-transmissive / semi-reflective surface of the first waveguide are transmitted, propagated through the first waveguide, and the other end face side of the first waveguide Is supplied to.

[0015]

1 is a block diagram showing a first embodiment of an optical device according to the present invention.

In the optical device shown in this figure, one end face is cut obliquely with respect to the optical axis, and a semi-transmissive / semi-reflective surface 1 for reflecting a part of a propagating optical signal and transmitting the rest is formed. The first optical waveguide 2 and one end surface are cut obliquely with respect to the optical axis to form a semi-transmissive / semi-reflective surface 3 that reflects a part of the propagating optical signal and transmits the rest. Arranged so that the semi-transmissive / semi-reflective surface 3 faces the semi-transmissive / semi-reflective surface 1 of the first optical waveguide 2 and the optical axis thereof is linear with the optical axis of the first optical waveguide 2. The second optical waveguide 4 and the semi-transmissive / semi-reflective surface 1 of the first optical waveguide 2 are arranged on the path of an optical signal emitted from the first optical waveguide 2 to the outside. And a photodetector 5 that receives a signal and generates an electrical signal.

An optical signal is supplied from the other end face of the first optical waveguide 2, and when the optical signal propagates in the first optical waveguide 2 and reaches the semi-transmissive / semi-reflective surface 1, The part is reflected by the semi-transmissive / semi-reflective surface 1 and emitted to the outside of the first optical waveguide 2, and is received by the photodetector 5 and converted into an electric signal.

An optical signal is supplied from the other end face of the second optical waveguide 4, and when this optical signal propagates in the second optical waveguide 4 and reaches the semi-transmissive / semi-reflective surface 3, the A part of the light passes through the semi-transmissive / semi-reflective surface 3 and enters the semi-transmissive / semi-reflective surface 1 of the first optical waveguide 2, and propagates in the first optical waveguide 2 so that the first optical waveguide 2 It is transmitted to the other end face side.

In this case, one end surface of each of the first optical waveguide 2 and the second optical waveguide 4 is obliquely cut to form the semi-transmissive / semi-reflective surfaces 1 and 3, and these semi-transmissive / semi-reflective surfaces are formed. 1,
3 has a function equivalent to that of an optical coupler, and by making each of the semi-transmissive / semi-reflective surfaces 1 and 3 oblique, multiple reflection is prevented, thereby eliminating signal distortion due to interference of reflected light. There is.

Further, the structure is such that only the photodetector 5 is arranged on the path of the optical signal reflected by the semi-transmissive / semi-reflective surface 1 of the first optical waveguide 2 and emitted to the outside of the first optical waveguide 2. This facilitates the optical coupling between the first optical waveguide 2 and the photodetector 5.

As described above, in this embodiment, one end surface of the first optical waveguide 2 and one end surface of the second optical waveguide 4 are obliquely cut to form the semi-transmissive / semi-reflective surfaces 1 and 3. However, since the photodetector 5 is arranged on the path of the optical signal reflected by the semi-transmissive / semi-reflective surface 1 of the first optical waveguide 2, an optical coupler and an optical demultiplexer are not required. The system can be made smaller, lighter, and cheaper, while preventing signal deterioration due to reflected light, facilitating system integration and integration, and further improving productivity to improve system productivity. Cost reduction can be achieved.

FIG. 2 is a block diagram showing a second embodiment of the optical device according to the present invention. In this figure, the same parts as those in FIG. 1 are designated by the same reference numerals.

The optical device shown in this figure is different from the device shown in FIG. 1 in that a light source 6 for generating an optical signal according to an input drive signal is added, and the optical signal obtained by this light source 6 is converted into a first optical signal. 2 That is, the light is incident on the other end face of the optical waveguide 4.

In this case, similarly to the optical device shown in FIG. 1, one end face of each of the first optical waveguide 2 and the second optical waveguide 4 is obliquely cut to form the semi-transmissive / semi-reflective faces 1 and 3. , These semi-transmissive / semi-reflective surfaces 1 and 3 have the same function as the optical coupler,
By making 3 slanted, multiple reflections are prevented, and thereby signal distortion due to interference of reflected light is eliminated.

Further, a photodetector 5 is arranged on the path of an optical signal reflected by the semi-transmissive / semi-reflective surface 1 of the first optical waveguide 2 and emitted outside the first optical waveguide 2, The light source 6 is simply arranged on the other end face side of the optical waveguide 4, so that the optical coupling among the first optical waveguide 2, the second optical waveguide 4, the photodetector 5, and the light source 6 is achieved. Makes it easy.

Even in this case, similarly to the above-described embodiment, the optical coupler, the optical demultiplexer, etc. are not required, so that the system can be made compact, lightweight, and inexpensive, and at the same time, due to the reflected light. It is possible to facilitate the arraying and integration of the system while preventing the deterioration of the signal that is generated, and further improve the productivity to achieve the system cost reduction.

FIG. 3 is a block diagram showing a third embodiment of the optical device according to the present invention.

In the optical device shown in this figure, one end face is cut obliquely with respect to the optical axis, and a semi-transmissive / semi-reflective surface 11 for reflecting a part of a propagating optical signal and transmitting the rest is formed. The first optical fiber 12 and one end surface thereof are cut obliquely with respect to the optical axis to form a semi-transmissive / semi-reflective surface 13 that reflects a part of the propagating optical signal and transmits the rest. So that the semi-transmissive / semi-reflective surface 13 faces the semi-transmissive / semi-reflective surface 11 of the first optical fiber 12,
Also, the second optical fiber 14 is arranged so that its optical axis is linear with the optical axis of the first optical fiber 12, and is reflected by the semi-transmissive / semi-reflective surface 11 of the first optical fiber 12, A first photodiode 15 arranged on the path of an optical signal emitted from the first optical fiber 12 to the outside and receiving the optical signal to generate an electric signal, and the semi-transmission / transmission of the second optical fiber 14. A second photodiode 16 arranged on a path of an optical signal reflected by the semi-reflecting surface 13 and emitted from the second optical fiber 14 to the outside, and receiving the optical signal to generate an electric signal. There is.

An optical signal is supplied from the other end face side of the first optical fiber 12, and when this optical signal propagates in the first optical fiber 12 and reaches the semi-transmissive / semi-reflective surface 11,
A part of it is reflected by the semi-transmissive / semi-reflective surface 11,
The light signal emitted from the optical fiber 12 is received by the first photodiode 15 and converted into an electric signal, while the optical signal transmitted through the semi-transmissive / semi-reflective surface 11 is semi-transmissive / semi-transmissive of the second optical fiber 14. While entering the reflecting surface 13,
This second optical fiber 1 propagates in the second optical fiber 14
4 is transmitted to the other end face side.

An optical signal is supplied from the other end face side of the second optical fiber 14, and this optical signal is supplied to the second optical fiber 1.
When it reaches the semi-transmissive / semi-reflective surface 13 after propagating inside 4, the part of the light is reflected by the semi-transmissive / semi-reflective surface 13 and emitted to the outside of the second optical fiber 14, and the second photodiode 1
While being received by 6 and converted into an electric signal, the optical signal transmitted through the semi-transmissive / semi-reflective surface 13 is incident on the semi-transmissive / semi-reflective surface 11 of the first optical fiber 12, and the first optical fiber 12 Propagating in the first optical fiber 12
Is transmitted to the other end face side of the.

In this case, similarly to each of the above-mentioned embodiments, one end face of each of the first optical fiber 12 and the second optical fiber 14 is obliquely cut to form the semi-transmissive / semi-reflective faces 11, 13. These semi-transmissive / semi-reflective surfaces 11 and 13 have a function equivalent to that of an optical coupler, and by making each semi-transmissive / semi-reflective surface 11 and 13 oblique, multiple reflection is prevented and reflection is thereby performed. Signal distortion caused by light interference is eliminated.

Further, the first optical fiber 12 is reflected by the semi-transmissive / semi-reflective surface 11 of the first optical fiber 12.
The first photodiode 15 is arranged on the path of the optical signal emitted to the outside of the optical fiber, and is reflected by the semi-transmissive / semi-reflective surface 13 of the second optical fiber 14 to be emitted to the outside of the second optical fiber 14. The second photodiode 16 is simply arranged on the path of the optical signal to be transmitted, whereby the first optical fiber 12 and the second optical fiber 14 are
First photodiode 15 and second photodiode 1
It facilitates the optical coupling between 6 and.

As described above, in this embodiment, one end surface of the first optical fiber 12 and one end surface of the second optical fiber 14 are obliquely cut to form the semi-transmissive / semi-reflective surface 11,
13 is formed, the first photodiode 15 is arranged on the path of the optical signal reflected by the semi-transmissive / semi-reflective surface 11 of the first optical fiber 12, and the second optical fiber 14
Since the second photodiode 16 is arranged on the path of the optical signal reflected by the semi-transmissive / semi-reflective surface 13, the system is downsized and lightened without the need for an optical coupler or an optical demultiplexer. It is possible to reduce the cost and prevent the deterioration of the signal due to the reflected light while facilitating the arraying and integration of the system, and further improving the productivity to achieve the cost reduction of the system. it can.

FIG. 4 is a block diagram showing a fourth embodiment of the optical device according to the present invention.

In the optical device shown in this figure, one end face is obliquely cut with respect to the optical axis, and the cut face is coated with a dielectric film or a metal film to form a wavelength filter 20. The first optical fiber 22 having a semi-transmissive / semi-reflective surface 21 that reflects the propagating optical signal of wavelength λ2 and transmits the optical signal of wavelength λ1 by the filter 20.
And, one end face is cut obliquely with respect to the optical axis, and the semi-transmission / semi-reflection that allows all the light to pass through without being reflected by the propagating optical signal by the AR coat 23 provided on the cut face. The surface 24 is formed, the semi-transmissive / semi-reflective surface 24 faces the semi-transmissive / semi-reflective surface 21 of the first optical fiber 22, and the optical axis is the first optical fiber 22.
The second optical fiber 25 arranged so as to be linear with the optical axis of the optical fiber 22 and the semi-transmissive / semi-reflective surface 21 of the first optical fiber 22 reflect the first optical fiber 22. It is provided on the path of an optical signal emitted to the outside, and has a photodiode 26 that receives the optical signal and generates an electrical signal.

Then, an optical signal of wavelength λ2 is supplied from the other end face side of the first optical fiber 22, and this optical signal is the first optical signal.
When the light propagates through the optical fiber 22 and reaches the semi-transmissive / semi-reflective surface 21, it is reflected by the semi-transmissive / semi-reflective surface 21 to be the first
The light is emitted outside the optical fiber 22 and is received by the photodiode 26 and converted into an electric signal.

An optical signal of wavelength λ1 is supplied from the other end face side of the second optical fiber 25, and this optical signal propagates in the second optical fiber 25 and reaches the semi-transmissive / semi-reflective surface 24. Then, all the light is transmitted through the semi-transmissive / semi-reflective surface 2
4 and the semi-transmissive / semi-reflective surface 2 of the first optical fiber 22.
The light enters the first optical fiber 22, propagates in the first optical fiber 22, and is transmitted to the other end face side of the first optical fiber 22.

In this case, the first optical fiber 22 and the second optical fiber 22
Each one end face of the optical fiber 25 is cut obliquely, and the semi-transmissive / semi-reflective faces 21 and 24 having the AR coat 23 and the wavelength filter 20 are formed. While having a function equivalent to that of an optical demultiplexer, by making each semi-transmissive / semi-reflective surface 21 and 24 oblique, multiple reflection is prevented, and thereby signal distortion caused by interference of reflected light is eliminated. There is.

Further, the first optical fiber 22 is reflected by the semi-transmissive / semi-reflective surface 21 of the first optical fiber 22.
On the path of the optical signal emitted to the outside of the photodiode 2
The structure is such that only 6 are arranged, and by this, these first
The optical coupling between the optical fiber 22 and the photodiode 26 is facilitated.

As described above, in this embodiment, one end face of the first optical fiber 22 and one end face of the second optical fiber 25 are obliquely cut to form the semi-transmissive / semi-reflective surface 21,
Since 24 is formed and the photodiode 26 is arranged on the path of the optical signal reflected by the semi-transmissive / semi-reflective surface 21 of the first optical fiber 22, an optical coupler and an optical demultiplexer are not required. The system can be made smaller, lighter, and cheaper, while preventing signal deterioration due to reflected light, facilitating system arraying and integration, and further improving productivity. It is possible to achieve low cost.

FIG. 5 is a block diagram showing a fifth embodiment of the optical device according to the present invention.

In the optical device shown in this figure, one end face is cut obliquely with respect to the optical axis, and a semi-transmissive / semi-reflective surface 31 for reflecting a part of a propagating optical signal and transmitting the rest is formed. The first optical fiber 32 and one end face thereof are cut obliquely with respect to the optical axis, and the AR coat 33 provided on the cut face allows all the light to pass through without reflecting the propagating optical signal. A second optical fiber 35 on which a semi-transmissive / semi-reflective surface 34 is formed, and a V-shaped groove 36 is formed on the upper portion, and the V-shaped groove 36 forms a semi-transmissive / semi-reflective surface 31 of the first optical fiber 32. The second optical fiber 35
The semi-transmissive / semi-reflective surface 34 of the
A fiber holder 3 for holding the first optical fiber 32 and the second optical fiber 35 so that the optical axis of the optical fiber 32 and the optical axis of the second optical fiber 35 are linear.
7 and the optical signal which is reflected by the semi-transmissive / semi-reflective surface 31 of the first optical fiber 32 and is emitted from the first optical fiber 32 to the outside, and receives the optical signal. And a photodiode 38 that generates an electric signal.

Then, an optical signal is supplied from the other end surface side of the first optical fiber 32, and when this optical signal propagates in the first optical fiber 32 and reaches the semi-transmissive / semi-reflective surface 31,
The light is reflected by the semi-transmissive / semi-reflective surface 31, emitted from the first optical fiber 32, and the photodiode 38
The light is received by and converted into an electric signal.

An optical signal is supplied from the other end face side of the second optical fiber 35, and this optical signal is supplied to the second optical fiber 3
When the light propagates through 5 and reaches the semi-transmissive / semi-reflective surface 34, all the light is transmitted through the semi-transmissive / semi-reflective surface 34 to the semi-transmissive / semi-reflective surface 31 of the first optical fiber 32. While being incident, it propagates through the first optical fiber 32 and is transmitted to the other end face side of the first optical fiber 32.

In this case, the first optical fiber 32 and the second optical fiber 32
Each one end surface of the optical fiber 35 is cut obliquely, and a semi-transmissive / semi-reflective surface 34 having an AR coat 33 is provided.
A semi-transmissive / semi-reflective surface 31 having no AR coat 33 is formed, and these semi-transmissive / semi-reflective surfaces 31 and 34 have a function equivalent to that of an optical coupler.
By making the semi-reflective surfaces 31 and 34 oblique, multiple reflection is prevented, and thereby signal distortion caused by interference of reflected light is eliminated.

Furthermore, the first optical fiber 32 is reflected by the semi-transmissive / semi-reflective surface 31 of the first optical fiber 32.
On the path of the optical signal emitted to the outside of the photodiode 3
The structure is such that only 8 are arranged, and this
The optical coupling between the optical fiber 32 and the photodiode 38 is facilitated.

As described above, in this embodiment, one end face of the first optical fiber 32 and one end face of the second optical fiber 35 are obliquely cut to form the semi-transmissive / semi-reflective surface 31,
Since the photo diode 38 is formed on the path of the optical signal reflected by the semi-transmissive / semi-reflective surface 31 of the first optical fiber 32, an optical coupler and an optical demultiplexer are unnecessary. The system can be made smaller, lighter, and cheaper, while preventing signal deterioration due to reflected light, facilitating system arraying and integration, and further improving productivity. It is possible to achieve low cost.

FIG. 6 is a block diagram showing a sixth embodiment of the optical device according to the present invention. In this figure, the same parts as those in FIG. 5 are designated by the same reference numerals.

The optical device shown in this figure is different from the device shown in FIG. 5 in that a light source 39 for generating an optical signal according to the input drive signal is added, and the optical signal obtained by this light source 39 is added to the first optical signal. 2 That is, the light is incident on the other end face of the optical waveguide 35.

In this case, the light source 39 is a laser diode 40 which generates an optical signal in accordance with the input drive signal,
And a lens 41 which collects the optical signal emitted from the laser diode 40 and makes it enter the other end face of the second optical waveguide 35. When a drive signal is input, the lens 41 responds to the drive signal. To generate an optical signal,
This optical signal is collected and made incident on the other end surface of the second optical waveguide 35.

Even in this case, as in the above-described respective embodiments, it is possible to reduce the size, weight and cost of the system by eliminating the need for an optical coupler, an optical demultiplexer, etc. It is possible to reduce the system cost while facilitating the arraying and integration of the system while improving the signal deterioration due to the system and further improving the productivity.

FIG. 7 is a block diagram showing a seventh embodiment of the optical device according to the present invention.

The optical device shown in this figure is made of Ti (titanium).
And the like are subjected to diffusion treatment to form an optical waveguide 43 on the upper surface, and the optical waveguide 43 is divided into two by an oblique cut groove 42 formed on the upper surface, and a semi-transmissive / semi-reflective surface 44 is formed on one end surface of each of the optical waveguides 43. , 45 formed with the first optical waveguide 4
6 and LiNbO ₃ crystal substrate 4 having second optical waveguide 47
8 and an optical fiber 49 arranged on the other end face side of the first optical waveguide 46 formed on the LiNbO ₃ crystal substrate 48 and optically connected to the first optical waveguide 46.
And a laser diode 50 and a lens 51,
An optical signal is generated according to the input drive signal to generate the Li signal.
The light source 52 which is incident on the other end surface of the second optical waveguide 47 formed on the NbO ₃ crystal substrate 48 and the semi-transmissive / semi-reflective surface 44 of the first optical waveguide 46 reflect the first light to the first end. The photodiode 53 is arranged on the path of the optical signal emitted from the optical waveguide 46 to the outside and receives the optical signal to generate an electric signal.

Then, an optical signal is supplied from the other end face side of the first optical waveguide 46, and this optical signal is supplied to the first optical waveguide 46.
When the light propagates inside and reaches the semi-transmissive / semi-reflective surface 44, a part of the light is reflected by the semi-transmissive / semi-reflective surface 44 and emitted to the outside of the first optical waveguide 46. The light is received and converted into an electric signal.

An optical signal is generated by the light source 52, is incident on the other end face of the second optical waveguide 47, and is propagated in the second optical waveguide 47 to cause the semi-transmission / transmission.
When it reaches the semi-reflective surface 45, a part of it passes through the semi-transmissive / semi-reflective surface 45 and enters the semi-transmissive / semi-reflective surface 44 of the first optical waveguide 46, and After propagating and being transmitted to the other end face side of the first optical waveguide 46, it propagates in the optical fiber 49 and is transmitted to a distant place.

In this case, one end surface of each of the first optical waveguide 46 and the second optical waveguide 47 is obliquely cut to make semi-transmission.
By forming the semi-reflective surfaces 44 and 45, and having each of these semi-transmissive / semi-reflective surfaces 44 and 45 have a function equivalent to that of an optical coupler, the semi-reflective / semi-reflective surfaces 44 and 45 are inclined. By preventing multiple reflections, signal distortion caused by interference of reflected light is eliminated.

Further, the photodiode 53 is arranged on the path of the optical signal reflected by the semi-transmissive / semi-reflective surface 44 of the first optical waveguide 46 and emitted to the outside of the first optical waveguide 46. The optical fiber 49 is arranged on the other end face side of the optical waveguide 46, and the light source 52 is further arranged on the other end face side of the second optical waveguide 47, whereby the first optical waveguide 46 and the second optical waveguide 46 are formed. Optical waveguide 47
The optical coupling between the photodiode 53, the optical fiber 49 and the light source 52 is facilitated.

As described above, in this embodiment, the optical waveguide 43 is divided into two by the oblique cut groove 42 and the first optical waveguide 46 having the semi-transmissive / semi-reflective surface 44 and the semi-transmissive / semi-reflective surface 45 are provided. The second optical waveguide 47 is formed, the photodiode 53 is arranged on the path of the optical signal reflected by the semi-transmissive / semi-reflective surface 44 of the first optical waveguide 46, and the other end surface of the second optical waveguide 47 is arranged. Since the light source 52 is arranged on the side, the size, weight and cost of the system can be reduced by eliminating the need for an optical coupler or an optical demultiplexer, and the deterioration of the signal due to the reflected light can be prevented. While preventing, it is possible to facilitate the arraying and integration of the system, further improve the productivity, and achieve the cost reduction of the system.

FIG. 8 is a block diagram showing an eighth embodiment of the optical device according to the present invention.

In the optical device shown in this figure, one end face is obliquely cut at an angle θ which is equal to or larger than the Brewster angle with respect to the direction orthogonal to the optical axis, and a part of the propagating optical signal is reflected, Semi-transmissive / semi-reflective surface 61 for transmitting the rest
And the first optical fiber 62 formed with is cut obliquely so that one end face has the same angle θ as the semi-transmissive / semi-reflective surface 61, reflects a part of the propagating optical signal, and transmits the rest. A semi-transmissive / semi-reflective surface 63 is formed, and the semi-transmissive / semi-reflective surface 63 is used for the first optical fiber 6.
A second optical fiber 64 arranged so as to face the semi-transmissive / semi-reflective surface 61 of the second optical fiber, and the optical axis thereof is linear with the optical axis of the first optical fiber 62; Reflected by the semi-transmissive / semi-reflective surface 61 of 62,
A photodiode 65 arranged on the path of an optical signal emitted from the first optical fiber 62 to the outside and receiving the optical signal to generate an electrical signal, and a polarization plane corresponding to each of the polarization planes according to the input drive signal. And a light source 66 for generating an optical signal which becomes a P wave in the inclination direction of the semi-transmissive / semi-reflective surfaces 61, 63 and making it enter the other end surface of the second optical fiber 64.

Then, an optical signal is supplied from the other end face side of the first optical fiber 62, and when this optical signal propagates in the first optical fiber 62 and reaches the semi-transmissive / semi-reflective surface 61,
A part of it is reflected by the semi-transmissive / semi-reflective surface 61 and
The light is emitted out of the optical fiber 62 and is received by the photodiode 65 and converted into an electric signal.

An optical signal is generated by the light source 66, is incident on the other end surface of the second optical fiber 64, propagates in the second optical fiber 64, and reaches the semi-transmissive / semi-reflective surface 63. Part of which is the semi-transmissive / semi-reflective surface 6
3 through which the semi-transmissive / semi-reflective surface 6 of the first optical fiber 62 passes.
The light enters the first optical fiber 62, propagates in the first optical fiber 62, and is transmitted to the other end face side of the first optical fiber 62.

In this case, as shown in FIG. 9, the plane wave reflectance of the optical signal incident on each of the semi-transmissive / semi-reflective surfaces 61 and 64 depends on the incident angle, and the angle at which the reflectance becomes zero for the P wave ( Brewster angle) exists. And in this example,
Utilizing the fact that the reflectance of the S wave rapidly increases above the Brewster angle, each semi-transmissive / semi-reflective surface 61, 63 has a circulator-like function.

As a result, P emitted from the light source 66
By making the optical signal of the wave incident on the other end surface of the second optical fiber 64, the optical signal is made incident on the first optical fiber 62 with almost no reflection at the semi-transmissive / semi-reflective surfaces 61, 63. Is transmitted to the other end face side of the first optical fiber 62, and from the other end face side of the first optical fiber 62 by the semi-transmissive / semi-reflective face 61 formed on one end face of the first optical fiber 62. The supplied optical signal from a distant place, that is, the optical signal which is generally a random polarization, is strongly reflected and made incident on the photodiode 65.

As described above, in this embodiment, one end face of the first optical fiber 62 and one end face of the second optical fiber 64 are obliquely cut at an angle θ which is equal to or greater than the Brewster angle, so that semi-transmission / Since the semi-reflective surfaces 61 and 63 are formed and the photodiode 65 is arranged on the path of the optical signal reflected by the semi-transmissive / semi-reflective surface 61 of the first optical fiber 62, the optical coupler and the optical demultiplexer are arranged. It is possible to reduce the size, weight and cost of the system by eliminating the need for a device, etc., while preventing deterioration of the signal due to reflected light, facilitating the arraying and integration of the system, and further improving the productivity. Can be improved and the system can be made inexpensive.

FIG. 10 is a block diagram showing the ninth embodiment of the optical device according to the present invention. In addition, in FIG.
The same parts as those of FIG.

The optical device shown in this figure is different from the device shown in FIG. 8 in that the other end face of the first optical fiber 62 receives an optical signal supplied from a distance and converts the polarization direction into an S wave. That is, the polarization controller 67 for switching is inserted.

As a result, when an optical signal is supplied from a distant place, the polarization controller 67 can control the polarization direction of this optical signal to make it an S wave, and this optical signal is sent to the first optical fiber 62. When it reaches the semi-transmissive / semi-reflective surface 61, it can be almost reflected and incident on the photodiode 65.

Even in this case, as in the above-described respective embodiments, it is possible to reduce the size, weight and cost of the system by eliminating the need for an optical coupler and an optical demultiplexer, and to reduce the reflected light. It is possible to reduce the system cost while facilitating the arraying and integration of the system while improving the signal deterioration due to the system and further improving the productivity.

In each of the above embodiments, the first
Optical waveguide 2, 46 (or first optical fiber 12, 2
2, 32, 62) and the second optical waveguides 4, 47
(Although the refractive indexes of the second optical fibers 14, 25, 35, 64) are the same, the respective refractive indexes may be different from each other.

In the seventh embodiment described above, L
The iNbO ₃ crystal substrate 48 is used to form the first optical waveguide 46 and the second optical waveguide 47.
The first optical waveguide and the second optical waveguide may be formed using an iTaO ₃ substrate, a glass substrate, or a semiconductor substrate.

[0072]

As described above, according to the present invention, it is possible to reduce the size, weight and cost of the system by eliminating the need for an optical coupler, an optical demultiplexer, etc. While preventing signal deterioration, system arraying and integration can be facilitated, and productivity can be improved to achieve system cost reduction.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing a first embodiment of an optical device according to the present invention.

FIG. 2 is a configuration diagram showing a second embodiment of the optical device according to the present invention.

FIG. 3 is a configuration diagram showing a third embodiment of the optical device according to the present invention.

FIG. 4 is a configuration diagram showing a fourth embodiment of the optical device according to the present invention.

FIG. 5 is a configuration diagram showing a fifth embodiment of the optical device according to the present invention.

FIG. 6 is a configuration diagram showing a sixth embodiment of the optical device according to the present invention.

FIG. 7 is a configuration diagram showing a seventh embodiment of the optical device according to the present invention.

FIG. 8 is a configuration diagram showing an eighth embodiment of the optical device according to the present invention.

FIG. 9 is a characteristic diagram showing an example of the relationship between the reflectance and the incident angle and polarization direction of an optical signal incident on a semi-transmissive / semi-reflective surface.

FIG. 10 is a configuration diagram showing a ninth embodiment of the optical device according to the present invention.

FIG. 11 is a configuration diagram showing an example of a conventionally known optical device.

[Explanation of symbols]

1, 3, 11, 13, 21, 24, 31, 34, 44,
45, 61, 63 semi-transmissive / semi-reflective surface 2, 46 first optical waveguide (first waveguide) 4, 47 second optical waveguide (second waveguide) 5 photodetector 6, 39, 52, 66 light source 15 1st photodiode (photodetector) 16 2nd photodiode (photodetector) 12, 22, 32, 62 1st optical fiber (1st waveguide) 14, 25, 35, 64 2nd optical fiber (2nd) Waveguide) 20 Wavelength filter 23, 33 AR coat 26, 38, 65 Photodiode (photodetector) 36 V-shaped groove 37 Fiber holder 40, 50 Laser diode 41, 51 Lens 42 Oblique cut groove 48 LiNbO ₃ crystal substrate 67 Polarization controller

Claims (7)

[Claims] 1. A first waveguide having a semi-transmissive / semi-reflective surface that has one end surface inclined with respect to the optical axis and reflects a part of a propagating optical signal; and the semi-transmissive / semi-reflective surface. A second waveguide having a semi-transmissive / semi-reflective surface formed on the end surface on the opposite side by inclining the end surface at an angle corresponding to the semi-transmissive / semi-reflective surface, and the other end surface side of the first waveguide. And a photodetector that receives an optical signal reflected by the semi-transmissive / semi-reflective surface of the first waveguide and converts the optical signal into an electric signal. 2. The optical device according to claim 1, further comprising a light source that generates an optical signal according to the input drive signal and makes the optical signal incident on the other end face of the second waveguide. 3. An oblique angle between the semi-transmissive / semi-reflective surface of the first waveguide and the semi-transmissive / semi-reflective surface of the second waveguide is set to be Brewster's angle or more, and each of the semi-transmissive / semi-reflective surfaces. The optical device according to claim 2, wherein the light source is incident on the other end surface of the second waveguide so that the polarization direction of the light source is a P wave with respect to the oblique direction of the semi-reflecting surface. 4. The optical device according to claim 1, wherein the refractive index of the first waveguide is different from the refractive index of the second waveguide. 5. A dielectric or metal coating on at least one of the semi-transmissive / semi-reflective surface of the first waveguide and the semi-transmissive / semi-reflective surface of the second waveguide. 2. The optical device according to 2, 3 or 4. 6. The method according to claim 1, wherein at least one of the first waveguide and the second waveguide is an optical fiber.
The optical device according to 2, 3, 4 or 5. 7. At least one of the first waveguide and the second waveguide is LiNbO ₃ , LiTaO ₃ ,
The optical device according to claim 1, which is a waveguide formed by using glass or a semiconductor as a substrate.