JPH08313744A - Optical circuit parts - Google Patents

Abstract

(57) [Abstract] [Purpose] An independent optical waveguide with a simple structure of an optical waveguide circuit,
When the optical fiber of the optical fiber array component corresponding to this optical waveguide is aligned and connected, the optical waveguide group having a predetermined function of the optical waveguide circuit and the optical fiber of the optical fiber array component corresponding to this optical waveguide group The purpose is to be able to align and connect the optical axes at the same time. [Structure] An optical fiber array component 1 in which a plurality of optical fibers are arranged and an input / output end of an optical waveguide circuit 9 having a predetermined function, which is composed of at least three optical waveguide groups.
In the optical circuit component in which 3 and 17 are aligned and connected, the optical waveguide circuit 9 includes an optical waveguide 11 group having a predetermined function, and an independent optical waveguide 10 not involved in the function. Independent optical waveguide 10 and optical fiber 1 of the optical fiber array components 13 and 17 corresponding to this optical waveguide 10.
An optical circuit component in which the optical waveguide circuit 9 and the optical fiber array component 13, 17 are connected by aligning 4 and 18 with each other.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical circuit component used in fields such as optical communication and optical information processing. This optical circuit component is an independent optical waveguide having a simple structure of an optical waveguide circuit, and an optical fiber of an optical fiber array component corresponding to this optical waveguide is aligned and connected,
Since the optical axes of the optical waveguide group having a predetermined function of the optical waveguide circuit and the optical fibers of the optical fiber array component corresponding to this optical waveguide group can be aligned and connected at the same time, the optical waveguide circuit and the optical fiber array component can be connected. It is a highly accurate and simple connection.

[0002]

2. Description of the Related Art Various optical components have been developed in the fields of optical communication and optical information processing. One of these optical components is an optical waveguide circuit formed from an optical waveguide. This optical waveguide circuit is characterized in that it can form a highly integrated and highly functional optical circuit. It is effective to use an optical fiber to efficiently input and output light to and from the optical waveguide circuit. For that purpose, a highly accurate and simple optical fiber connection technique is used. Need to be connected.

FIG. 6 is a block diagram of a conventional optical waveguide circuit.
Reference numeral 1 is an optical waveguide circuit, 2 is an optical waveguide constituting the optical waveguide circuit 1, 3 and 6 are optical fiber array components connected to the optical waveguide circuit 1, and 4 and 7 are optical fibers constituting the optical fiber array component. Reference numerals 5 and 8 are optical fiber fixing components that constitute the optical fiber array component. θ is the centering axis. The optical fiber is connected only to the optical waveguide related to the function of the optical waveguide circuit (here, 1 × 8 multiplexing / demultiplexing function). The alignment between the optical fiber and the optical waveguide is
It is performed using light that has been acted on (demultiplexed) in the optical waveguide circuit.

[0004]

However, in the above-mentioned prior art, when the optical demultiplexing / multiplexing function of the optical waveguide circuit is increased,
The demultiplexed light intensity becomes small due to the principle loss due to demultiplexing. For example, in the case of a 1 × 64 multiplexer / demultiplexer, the principle loss due to demultiplexing is 18 dB. When performing alignment using such low-intensity light, there is a problem that the alignment accuracy deteriorates because the S / N ratio deteriorates when detecting light. Further, the alignment between the optical waveguide circuit and the optical fiber array component is x, y, z.
Direction and θ direction. When connecting one optical waveguide and an optical fiber, alignment in the x, y, and z directions is performed by detecting the optical output from the optical waveguide. However, the surface alignment in the θ direction cannot be performed using the optical output, and the surfaces are aligned while actually seeing the connection surface, which is a problem that it takes time. further,
If the optical waveguide circuit has functions such as optical path switching or optical wavelength selection, it is necessary to switch optical paths or select wavelengths during alignment, which complicates the alignment device or alignment method. Occurs. An object of the present invention is to solve the deterioration and complication of the alignment accuracy that occurs when the optical waveguide circuit and the optical fiber are connected together with the increase in the number of cores or the higher functionality of the optical waveguide circuit. Another object is to provide an optical circuit component in which an optical waveguide circuit and an optical fiber are connected.

[0005]

In order to solve the above problems, the present invention provides an optical circuit component for connecting to an optical fiber array component, which is composed of at least three optical waveguides. At least one of the optical waveguides has a predetermined function, and at least two of the optical waveguides are independent optical waveguides that do not participate in the function.

[0006] Further, an optical fiber which is composed of at least three optical waveguide groups and has an input / output terminal of an optical waveguide circuit having a predetermined function and an optical fiber array component in which a plurality of optical fibers are arranged in an aligned manner are connected. In the circuit component, the optical waveguide circuit has, in addition to an optical waveguide group having a predetermined function, an independent optical waveguide not involved in the function, and the independent optical waveguide and an optical fiber corresponding to this optical waveguide. An optical circuit component characterized in that the optical waveguide circuit and the optical fiber array component are connected by aligning an optical fiber of the array component.

Further, as a predetermined function of the optical waveguide circuit, there is provided an optical circuit component characterized by having a function of demultiplexing / multiplexing an optical output, a function of selecting a wavelength, or a function of switching an optical path. .

As the optical fiber array component,
An optical fiber connected corresponding to an optical waveguide group having a predetermined function of the optical waveguide circuit and an optical fiber connected corresponding to an independent optical waveguide of the optical waveguide circuit are aligned and fixed to a V-groove component. An optical circuit component characterized by the above.

Further, the optical circuit component is characterized in that it has two optical waveguides as the independent optical waveguides, and the distance between the two optical waveguides is always constant.

Further, as the optical circuit component, an independent optical waveguide of an optical waveguide circuit and an optical fiber of an optical fiber array component corresponding to the optical waveguide are aligned to connect the optical waveguide circuit and the optical fiber array component. After that, a part including the independent optical waveguide and the optical fiber is cut and removed to provide an optical circuit component.

As the optical circuit component, after aligning an independent optical waveguide of an optical waveguide circuit and an optical fiber of an optical fiber array component corresponding to the optical waveguide, an optical fiber array component having the optical fiber is prepared. , Is translated to the input / output end of the optical waveguide group having a predetermined function of the optical waveguide circuit,
An optical circuit component is characterized in that the optical waveguide group and the optical fiber of the optical fiber array component are connected.

[0012]

According to the present invention, an independent optical waveguide having a simple structure of an optical waveguide circuit and an optical fiber of an optical fiber array component corresponding to the optical waveguide are aligned and connected to each other, so that a predetermined optical waveguide circuit can be obtained. Since the optical axes of the optical waveguide group having functions and the optical fibers of the optical fiber array component corresponding to this optical waveguide group can be aligned and connected at the same time, the optical waveguide circuit and the optical fiber array component can be connected with high accuracy and easily. The optical circuit component can be provided. Further, since the independent optical waveguide having the simple structure of the optical waveguide circuit can be arranged without depending on the optical waveguide group having a predetermined function of the optical waveguide circuit, it is possible to freely design. further,
It is possible to use the plane-matched light output in the direction of rotation about the optical axis. Therefore, it is possible to provide the optical circuit component in which the optical fiber of the optical fiber array component is connected to the optical waveguide circuit with high accuracy and easily, which is the object of the present invention.

[0013]

Embodiments of the present invention will be described in detail below with reference to the drawings. [Embodiment 1] FIG. 1 is a perspective view showing the structure of a first embodiment of an optical circuit component according to the present invention. In this figure, 9 is an optical waveguide circuit having a Y-branch type 1 × 64 demultiplexing / multiplexing function, 10 is an independent optical waveguide included in the optical waveguide circuit 9, and 11 is a demultiplexer / multiplexer included in the optical waveguide circuit 9. Optical waveguide to compose, 12
Is a glass plate for increasing the adhesion area with an optical fiber array component described later, and 13 is three single-core optical fibers 14
, 15 is a V-groove component that serves as a guide for aligning the single-core optical fiber 14, and 16 is 1
A holding cover for fixing the core optical fiber 14 to the groove of the V-groove component 15, 17 is an optical fiber array component having two 1-core optical fibers 18 and 8 8-core ribbon fibers 19, and 20 is the aforementioned V-groove component that serves as a guide for aligning the one-core optical fiber 18 and the eight-core ribbon fiber 19, 2
Reference numeral 1 denotes a holding lid for fixing the 1-core optical fiber 18 and the 8-core ribbon fiber 19 to the V-groove component 20.

The optical waveguide circuit 9 is a set of Y branch type 1 × 6.
The optical waveguide 11 and the two independent optical waveguides 10 constituting the quadruple-multiplexer are used. In producing the optical circuit component of the present invention, the optical waveguide circuit 9 was formed on the silicon substrate by the flame deposition method. The cross sections of the optical waveguides 10 and 11 are 6
It was a rectangle of × 6 μm. Glass plates 12 and 12 were adhered to the input and output ends of the optical waveguide 9 by using an ultraviolet curable adhesive. Further, the input and output ends were obliquely polished by 8 degrees in order to control the reflected light returning from the end faces. In the optical fiber array parts 13 and 17, the one-core optical fiber 14 or the eight-core ribbon fiber 19 is arranged in the V-groove parts 15 and 20, and fixed with the restraining lids 16 and 21, and then an ultraviolet curable adhesive is used. It was fixed and prepared.

The optical waveguide circuit 9 and the optical fiber array components 13 and 17 were aligned using the independent optical waveguide 10 and then fixed using an ultraviolet curing adhesive. The single-core optical fiber 14 used for alignment was cut and removed in the vicinity of the V-groove component 15 after being fixed. A laser beam with an optical output of −2.5 dBm was used for alignment. The optical output from the independent optical waveguide 10 at the time of alignment was −3.5 dBm, which was a sufficient light intensity for stable and simple alignment.

In the prior art, the optical output from the demultiplexed optical waveguide is −27.5 dBm, and since it is a low output, it is very difficult to distinguish between the guided light and the clad light, and it is troublesome to perform alignment. It was hanging. In addition, it is necessary to perform the surface alignment of the optical waveguide and the optical fiber array component in the θ direction while observing the connection end face.

By using the present invention, it becomes possible to perform the alignment stably and easily. In addition, the surface alignment in the θ direction can be performed at the same time when the alignment is performed, and the connection can be efficiently performed. The connection between the demultiplexed optical waveguide and the single-core optical fiber was performed accurately with an excess loss due to axial misalignment of 0.5 dB or less as an average of all ports. Therefore, it became clear that the present invention can connect the optical waveguide circuit and the optical fiber array component with high accuracy and easily.

[Second Embodiment] FIG. 2 is a perspective view showing the structure of a second embodiment of the optical circuit component according to the present invention. In this figure, 22 is an arrayed waveguide diffraction grating type optical waveguide circuit having a wavelength selection function, 23 is an independent optical waveguide, 24 is an optical waveguide forming an arrayed waveguide diffraction grating, and 25 is an optical fiber array component. A glass plate for increasing the bonding cross-sectional area, 26 and 31 are two single-core optical fibers 27 and one 8
An optical fiber array component having a core ribbon fiber 28,
29 is a 1-fiber optical fiber 27 and 8-fiber ribbon fiber 2
A V-groove component serving as a guide for aligning 8 is a holding lid for fixing the 1-core optical fiber 27 and the 8-fiber ribbon fiber 28 to the groove of the V-groove component 29.

The optical waveguide circuit 22 is an optical waveguide 24 which constitutes a set of arrayed waveguide diffraction gratings having a wavelength selection function.
And two independent optical waveguides 23. In producing the optical circuit component of the present invention, the optical waveguide circuit 22 was formed on the silicon substrate by the flame deposition method. The cross sections of both the optical waveguides 23 and 24 are rectangular with a size of 6 × 6 μm. A glass plate 25 was attached to the input and output ends of the optical waveguide circuit 22 using an ultraviolet curing adhesive. Further, the optical waveguide circuit 22
The input and output ends were obliquely polished by 8 degrees in order to suppress light reflected back from the end faces. The optical fiber array component 26,
31 was produced by arranging the 1-core optical fiber 27 and the 8-core ribbon fiber 28 in the V-groove component 29, fixing them with the restraining lid 30, and then fixing them with an ultraviolet curing adhesive. The optical waveguide circuit 22 and the optical fiber array components 26 and 31 were aligned using the independent optical waveguide 23, and then fixed using an ultraviolet curable adhesive. In the connection with the single-core optical fiber 27, the excess loss due to the axial misalignment is 0.
It was performed with accuracy of 5 dB or less. Optical output for alignment
Laser light having a wavelength of 2.5 dBm and a wavelength of 1.55 μm was used. The optical output during alignment was -3.5 dBm, which was a sufficient light intensity for alignment.

In the prior art, since the optical waveguide that contributes to the wavelength selection is used for the alignment, it is inefficient because it is necessary to use the highly coherent wavelength tunable light source to perform the alignment while selecting the wavelength. . Therefore, the present invention enables the connection of optical fibers independent of the function of the optical waveguide circuit,
It became clear that it is possible to connect the optical waveguide circuit and the optical fiber array component with high accuracy and easily. Although this embodiment relates to an optical circuit component having a wavelength selection function, an optical circuit component having an optical path switching function can also be aligned without switching the optical path, so that the same effect can be obtained.

[Third Embodiment] FIG. 3 is a perspective view showing the structure of a third embodiment of the optical circuit component according to the present invention. In this figure, 32 is an optical waveguide circuit having a Y-branch type 1 × 8 optical demultiplexing / multiplexing function, 33 is an independent optical waveguide, 34 is an optical waveguide constituting a demultiplexer, and 35 is an optical fiber array component described later. A glass plate for increasing the adhesion cross-sectional area of the fiber, 36 is an optical fiber array component having three single-core optical fibers 37, 3
Reference numeral 8 denotes a V-groove component that serves as a guide for aligning the one-core optical fibers 37, and 39 denotes the one-core optical fiber 37 and the V-groove component 3
A holding lid for fixing to the groove of 8, an optical fiber array component 40 having two one-core optical fibers 41 and one 8-core ribbon fiber 42, and 43 being two one-core optical fibers 41
And a V-groove component that serves as a guide for aligning one 8-fiber ribbon fiber 42, and 44 fixes two 1-fiber optical fibers 41 and one 8-fiber ribbon fiber 42 to the groove of the V-groove component 43. It is a restraining lid for.

The optical waveguide circuit 32 comprises a set of Y branch type 1
The optical waveguide 34 and the two independent optical waveguides 33 constituting the × 8 multiplexer / demultiplexer are used. In producing the optical circuit component of the present invention, the optical waveguide circuit 32 was formed on the silicon substrate by the flame deposition method. The cross sections of the both optical waveguides 33 and 34 are rectangular 6 × 6 μm. A glass plate 35 is formed on the input and output ends of the optical waveguide circuit 32 by using an ultraviolet curable adhesive.
Glued. Further, the input and output ends were obliquely polished by 8 degrees in order to suppress reflected light from the end faces. The optical fiber array components 36, 40 are composed of single-core optical fibers 37, 4
The 1- or 8-fiber ribbon fiber 42 is connected to the V-groove parts 38, 43.
Was prepared by fixing it with a UV curable adhesive, and then fixing it with the pressing lids 39 and 44.

The optical fiber array components 36 and 40 are
It was manufactured using the one-core optical fiber cut in Example 2.
The optical waveguide circuit 32 and the optical fiber array components 36 and 40
Was aligned using an independent optical waveguide 33 and then fixed using an ultraviolet curable adhesive. In connection with a single-core optical fiber, the excess loss due to axial misalignment was 0.
It was performed with accuracy of 5 dB or less. Optical output for alignment
Laser light having a wavelength of 2.5 dBm and a wavelength of 1.55 μm was used. The light output during alignment was −3.5 dBm, which was a sufficient light intensity for alignment. The optical fiber array component 40 used in this example is of the same type as the optical fiber array component used in Example 2, and the same type of optical fiber is obtained by unifying the input / output positions of the independent optical waveguides 33. It became clear that array components could be used. Further, it has been clarified that the optical waveguide circuit and the optical fiber array component in the optical circuit component having different functions can be connected by the same procedure.

In the prior art, an optical circuit component having a predetermined function needs a centering method corresponding to each function, so that the method of connecting the optical waveguide circuit and the optical fiber array component is complicated and inefficient. Met. Therefore, it becomes clear that the present invention is an optical fiber connection that can be uniformly applied to optical waveguide circuits having different functions, and it is possible to connect the optical waveguide circuit and the optical fiber array component with high precision and easily. It was

[Fourth Embodiment] FIG. 4 is a perspective view showing the structure of a fourth embodiment of the optical circuit component according to the present invention. In this figure, 45 is an optical waveguide circuit having a wavelength selection function, 46 is an independent optical waveguide, 47 is an optical waveguide constituting a wavelength selection filter, 48 is a 3 dB directional coupler, 49 is a wavelength selective reflector, and 50 is Glass plate, 51 is four 1-core optical fibers 52
, 53 is a V-groove part that serves as a guide for aligning the single-core optical fiber 52, and 54 is 1
A holding lid for fixing the optical fiber 52 to the groove of the V-groove component 53, and aa 'is a cutting line.

The optical waveguide circuit 45 is composed of an optical waveguide 47 which constitutes a set of wavelength selection filters and two independent optical waveguides 46. The wavelength selection filter includes a 3 dB directional coupler 48 and a wavelength selection reflector 49.
The operation of the wavelength selection filter will be briefly described. The wavelength selective reflector 49 is assumed to reflect light of a specific wavelength λ1. When light of wavelength λ 1 is input from one port of the wavelength selective filter, the light is reflected by the wavelength selective reflector 49 via the 3 dB directional coupler 48, and again passes through the 3 dB directional coupler 48, Output from the other port. Light other than the wavelength λ 1 is emitted from the opposite end face without being reflected by the wavelength selective reflector 49.

In producing the optical circuit component of the present invention,
The optical waveguide circuit 45 was formed on the silicon substrate by the flame deposition method. The cross sections of both the optical waveguides 46 and 47 are 6 ×
It was a rectangle of 6 μm. A glass plate 50 was adhered to the input end of the optical waveguide circuit 45 by using an ultraviolet curable adhesive. Further, the input and output ends of the optical waveguide circuit 45 were obliquely polished by 8 degrees in order to control the reflected light returning from the end face. The optical fiber array component 51 was produced by disposing four single-core optical fibers 52 in the V-groove component 53, fixing them with the pressing lid 54, and then fixing them with an ultraviolet curing adhesive. The optical waveguide circuit 45 and the optical fiber array component 51 were aligned using an independent optical waveguide 46 and then fixed using an ultraviolet curable adhesive. Finally, the independent optical waveguide 46 was removed by cutting along the cutting line aa '.

For alignment, the optical output at wavelength λ1 is -2.5 dB.
m laser light was used. The laser light is made incident on the light input ends P1 and P2 of the independent optical waveguide 46, and the light output end P
Alignment was performed using the outputs from 1'and P2 '. The light output during alignment was -3.5 dBm, which was a sufficient light intensity for stable and simple alignment. In the prior art, when performing alignment using light of wavelength λ1, since the input and output ends of the light are the same end, alignment is performed only after the surface alignment in the θ direction. Was impossible. Therefore, it was necessary to perform alignment using light other than the wavelength λ1.

By using the present invention, alignment using light of wavelength λ1 is possible. The connection between the optical waveguide 47 forming the wavelength selection filter and the single-core optical fiber 52 was performed accurately with the excess loss due to the axis deviation being 0.5 dB or less as an average of all ports. Therefore, according to the present invention, it has become clear that the optical waveguide circuit 45 and the optical fiber array component 51 can be connected with high precision and easily. Although this embodiment relates to an optical waveguide circuit which constitutes a wavelength selection filter, the present invention is also effective for an optical waveguide circuit having another function in which the input and output ends of light are the same. In addition, this example is for reducing the size of the optical waveguide circuit manufactured. Although the independent optical waveguide portion was cut and removed, the same effect can be obtained without removing it.

[Fifth Embodiment] FIG. 5 is a perspective view showing the structure of a fifth embodiment of the optical circuit component according to the present invention. In this figure, 55 is an optical waveguide circuit having a wavelength selection function, 56 is an independent optical waveguide, 57 is an optical waveguide constituting a wavelength selection filter, 58 is a 3 dB directional coupler, 59 is a wavelength selective reflector, and 60 is a wavelength selective reflector. Glass plate, 61 is two single-core optical fibers 62
, 63 is a V-groove component that serves as a guide for aligning the two 1-core optical fibers 62, and 64 is a V-groove component 6 that includes the 2 1-core optical fibers 62.
Suppression lid for fixing in the groove of 3, xI, yI, zI, θ
I is the centering axis when the optical fiber array component 61 is arranged at the position I, and xII, yII, zII, θII are the centering axes when the optical fiber array component 61 is arranged at the position II.

The optical waveguide circuit 55 is composed of an optical waveguide 57 which constitutes a set of wavelength selection filters and two independent optical waveguides 56. The wavelength selection filter comprises a 3 dB directional coupler 58 and a wavelength selection reflector 59.
The operation of the wavelength selection filter will be briefly described. The wavelength selective reflector 59 reflects light of a specific wavelength λ1. When light of wavelength λ1 is inputted from one port (light input end P3) of the optical waveguide 57 constituting the wavelength selection filter, this light is reflected by the wavelength selection reflector 59 via the 3 dB directional coupler 58. , Passes through the 3 dB directional coupler 58 again, and outputs from the other port (optical input end P4). Light other than the wavelength λ1 is emitted from the opposite end face without being reflected by the wavelength selective reflector 59.

In producing the optical circuit component of the present invention,
The optical waveguide circuit 55 was formed on the silicon substrate by the flame deposition method. The cross sections of both the optical waveguides 56 and 57 are 6 × 6 μ.
It was a rectangle of m. A glass plate 60 was adhered to the input end of the optical waveguide circuit 55 using an ultraviolet curable adhesive. Further, the input and output ends were obliquely polished by 8 degrees in order to suppress reflected light from the end faces. The optical fiber array component 6
No. 1 was produced by arranging two single-core optical fibers 62 in the V-groove component 63, fixing them with the restraining lid 64, and then fixing them with an ultraviolet curing adhesive. The optical waveguide circuit 55 and the optical fiber array component 61 are aligned with each other and then fixed using an ultraviolet curable adhesive. Optical output at wavelength λ1 for alignment −
A laser beam of 2.5 dBm was used.

In the aligning procedure, first, the optical fiber array component 61 is positioned at the position I, the laser light is made incident on the independent optical waveguides 56 from the light input ends P1 and P2, and the light output end P is generated.
Using the outputs from 1'and P2 ', four centering axes xI, yI, z
Alignment I was performed for I and θI. The centering I is intended for the surface alignment of the optical waveguide circuit 55 and the optical fiber array component 61 in the θI direction. Next, the optical fiber array component 61 is moved in parallel to the position II, the laser light is made incident on the optical waveguide 57 constituting the wavelength selection filter from the light input ends P3 and P4, and three alignments except the θII direction are performed. Axis xII, yI
Alignment II of I and zII was performed. Here, since the optical waveguide circuit 55 and the optical fiber array component 61 are aligned in the θI direction during the alignment I, it is not necessary to perform the alignment in the θII direction.

In the prior art, when performing alignment using the light of wavelength λ1, it was necessary to arrange the optical fiber array component at the position II and perform the surface alignment in the θII direction. At this time, it is difficult to align the positions where the light is incident from the light input ends P3 and P4 to the optical waveguide forming the wavelength selection filter independently, so that it is difficult to perform the surface alignment in the θII direction. Therefore, it was necessary to perform alignment using light other than the wavelength λ1.

By using the present invention, alignment using light of wavelength λ1 is possible. The connection between the optical waveguide 57 constituting the wavelength selection filter and the single-core optical fiber 62 was performed accurately with the excess loss due to the axis misalignment being 0.5 dB or less as an average of all ports. Therefore, it becomes clear that the present invention can connect the optical waveguide circuit 55 and the optical fiber array component 61 with high accuracy and easily. Although this embodiment relates to the connection between the optical waveguide circuit 55 having the wavelength selection filter and the optical fiber array component 61, the optical waveguide circuit having another function in which the input and output ends of the light are the same end. On the other hand, the present invention is effective.

[0036]

As described above, in the optical circuit component of the present invention, the input / output end of the optical waveguide circuit having at least three optical waveguide groups and having a predetermined function and the plurality of optical fibers are provided. In an optical circuit component that aligns and connects the arranged optical fiber array components, the optical waveguide circuit has an independent optical waveguide that does not participate in the function, in addition to the optical waveguide group having a predetermined function, Since the independent optical waveguide and the optical fiber of the optical fiber array component corresponding to the optical waveguide are aligned to form an optical circuit component in which the optical waveguide circuit and the optical fiber array component are connected to each other, the optical waveguide circuit is simplified. An optical waveguide group having a predetermined function of an optical waveguide circuit by aligning and connecting an independent optical waveguide having a different structure and an optical fiber of an optical fiber array component corresponding to this optical waveguide. To provide an optical circuit component in which an optical waveguide circuit and an optical fiber array component are connected with high accuracy and easily, because the optical axis of the optical fiber array component corresponding to this optical waveguide group and the optical axis can be simultaneously connected. You can Further, since the independent optical waveguide having the simple structure of the optical waveguide circuit can be arranged without depending on the optical waveguide group having a predetermined function of the optical waveguide circuit, it is possible to freely design. Further, it is possible to use the plane-matched light output in the rotation direction about the optical axis.

[Brief description of drawings]

FIG. 1 is a perspective view of a first embodiment of the present invention.

FIG. 2 is a perspective view of a second embodiment of the present invention.

FIG. 3 is a perspective view of a third embodiment of the present invention.

FIG. 4 is a perspective view of a fourth embodiment of the present invention.

FIG. 5 is a perspective view of a fifth embodiment of the present invention.

FIG. 6 is a configuration diagram of a conventional optical circuit component.

[Explanation of symbols]

1 optical waveguide circuit 2 optical waveguide 3 optical fiber array component 4 optical fiber 5 optical fiber fixing component 6 optical fiber array component 7 optical fiber 8 optical fiber fixing component 9 optical waveguide circuit 10 independent optical waveguide 11 constructing a multiplexer Optical waveguide 12 Glass plate 13 Optical fiber array component 14 Optical fiber 15 V groove component 16 Suppression lid 17 Optical fiber array component 18 1-fiber optical fiber 19 8 Fiber ribbon fiber 20 V-slot component 21 Suppression lid 22 Optical waveguide circuit 23 Independent optical waveguide Waveguide 24 Optical waveguide constituting an arrayed waveguide diffraction grating 25 Glass plate 26 Optical fiber array component 27 Optical fiber 28 8-fiber ribbon fiber 29 V groove component 30 Suppression lid 31 Optical fiber array component 32 Optical waveguide circuit 33 Independent optical waveguide 34 Optical Waveguide 35 Glass Plate 36 Fiber array component 37 1-core optical fiber 38 V-groove component 39 Suppression lid 40 Optical fiber array component 41 1-core optical fiber 42 8-fiber ribbon fiber 43 V-slot component 44 Suppression lid 45 Optical waveguide circuit 46 Independent optical waveguide 47 Wavelength selection filter Optical waveguide 48 constituting 3 dB Directional coupler 49 Wavelength selective reflector 50 Glass plate 51 Optical fiber array component 52 1-core optical fiber 53 V groove component 54 Suppression lid 55 Optical waveguide circuit 56 Independent optical waveguide 57 Wavelength selection filter Constituting optical waveguide 58 3 dB directional coupler 59 Wavelength selective reflector 60 Glass plate 61 Optical fiber array component 62 1-core optical fiber 63 V groove component 64 Suppression lid xI, yI, zI, θI Optical fiber array component at position I Alignment axis when installed. Optical fiber array at xII, yII, zII, θII position II. Aligning axis when you have placed the parts

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hiroshi Nakagome 1-1-6 Uchisaiwaicho, Chiyoda-ku, Tokyo Nihon Telegraph and Telephone Corporation

Claims (7)

[Claims] 1. An optical circuit component for connecting with an optical fiber array component, comprising at least three optical waveguides, at least one of which has a predetermined function, The two optical circuit parts are independent optical waveguides that do not participate in the above function. 2. An optical system in which an input / output terminal of an optical waveguide circuit having at least three optical waveguide groups and having a predetermined function and an optical fiber array component in which a plurality of optical fibers are arranged are aligned and connected. In the circuit component, the optical waveguide circuit has, in addition to an optical waveguide group having a predetermined function, an independent optical waveguide not involved in the function, and the independent optical waveguide and an optical fiber corresponding to the optical waveguide. An optical circuit component, wherein the optical waveguide circuit and the optical fiber array component are connected by aligning an optical fiber of the array component. 3. An optical circuit component having a predetermined function of the optical waveguide circuit according to claim 2, which has a function of multiplexing / demultiplexing an optical output, a function of selecting a wavelength, or a function of switching an optical path. . 4. The optical fiber array component according to claim 2, wherein an optical fiber connected corresponding to an optical waveguide group having a predetermined function of an optical waveguide circuit and an independent optical waveguide of the optical waveguide circuit. An optical circuit component characterized in that a correspondingly connected optical fiber is aligned and fixed to a V-groove component. 5. The independent optical waveguide according to claim 2,
An optical circuit component having two optical waveguides, wherein the distance between the two optical waveguides is always constant. 6. The optical circuit component according to claim 2, wherein an independent optical waveguide of an optical waveguide circuit and an optical fiber of an optical fiber array component corresponding to this optical waveguide are aligned to form an optical waveguide circuit and an optical fiber array. An optical circuit component, characterized in that after the component is connected, a portion including the independent optical waveguide and the optical fiber is cut and removed. 7. The optical circuit component according to claim 2, wherein the optical fiber is provided after aligning an independent optical waveguide of an optical waveguide circuit and an optical fiber of an optical fiber array component corresponding to the optical waveguide. An optical fiber array component is translated to an input / output end of an optical waveguide group having a predetermined function of an optical waveguide circuit to connect the optical waveguide group and the optical fiber of the optical fiber array component. Optical circuit parts.