JPH06324221A - Optical fiber array - Google Patents

Abstract

PURPOSE:To provide the optical fiber array which has the high accuracy of the relative positions between respective optical fiber units, is free from optical axis mis-alignment and permits easy assembly and is free in design. CONSTITUTION:Plural pieces of the optical fiber units 110 formed by fixing optical fibers 101 into cylindrical capillaries 102 are aligned into the spaces segmented by aligning plates 105 by using their outside dimensional sizes. Circular cylindrical or spherical spacers 103 which maintain the specified distances between the optical fiber units are inserted between the respective optical fiber units and are adhered by adhesives 104 to decrease the positional displacement by rolling of the optical fiber units, by which the high-accuracy alignment is automatically realized. The structure of the capillaries constituting the optical fiber units may be made into a structure capable of integrating collimator lenses and the optical fibers.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber array, and more particularly to an optical fiber array used in an optical fiber parallel transmission device or a parallel optical signal processing device.

[0002]

2. Description of the Related Art For example, regarding a two-dimensional optical fiber array, reference, Kunio Koyabu, Fumikazu Ohira, Tsuyoshi Yamamoto, Shinji Matsuo, "Prototype of high-density two-dimensional fiber array", 199.
3rd IEICE Spring Conference, c-307, p4-3
The example described in No. 43 is well known. FIG. 5 shows a configuration example of the optical fiber array of the reference document. The optical fiber unit 410 forming the optical fiber array is composed of 401 optical fibers and 402 cylindrical capillaries, and these are arranged in a two-dimensional square lattice to form a two-dimensional optical fiber array. Reference numeral 404 is an adhesive that adheres and fixes the optical fiber unit. An alignment plate 405 aligns the optical fiber units. In the optical fiber array of FIG. 5, alignment is performed with high precision using the outer diameter dimension of the capillary 402 and the outer dimension of the alignment plate 405 that have been processed with high precision as references. Cylindrical capillaries can be processed with higher precision than, for example, prisms (square prisms, triangular prisms, etc.),
It is convenient when constructing an optical fiber array, but because it is cylindrical, it rolls easily, and even if the external dimension accuracy is good,
As shown in FIG. 5, the slight displacement d of the alignment plate affects the array pitch dimension and the like, and the alignment plate is often displaced from the intended square lattice. Therefore, it has been difficult to easily construct a high-precision and large-scale optical fiber array.

In addition to the above examples, although the optical fiber array is an example of a one-dimensional array, a method of using a substrate having a V groove or a U groove as a method for fixing the position of the optical fiber is disclosed in, for example, Japanese Patent Laid-Open No. No. 4-130406, Yasuhisa Tanizawa,
"Waveguide type optical device" (Published May 1, 1992)
And JP-A-4-216509, Hideki Isono, Yasuhiro Omori,
It is well known in the examples described in Kazue Hattori, "Method for connecting waveguide type optical device and optical fiber" (published on August 6, 1992). However, if an optical fiber alignment plate having V-grooves or the like is used, the substrate size is limited, and it is difficult to construct an especially large-scale optical fiber array.

Similarly, an example of a one-dimensional array,
Regarding a method of installing a collimator lens in an optical fiber array, see, for example, Japanese Patent Laid-Open No. 4-324406, Takeo Iwama, Masayoshi Kamohara, “Method of coupling optical fiber array and lens array” (published on November 13, 1992). The examples described are well known. This example is a method of aligning the lens and the fiber array by using a cross alignment mark on the fiber array. As described above, when the collimator lens is installed in the optical fiber, there is a problem that it is difficult to reduce the cost because the alignment process is required and the complicated process is required.

[0005]

When a plurality of optical fibers or optical fiber units with collimator lenses are arranged in an array, relative positional accuracy and optical axis angle deviation between the optical fiber units pose problems. Further, particularly when constructing a large-scale optical fiber array using a large number of optical fiber units, ease of assembly and design flexibility also become problems.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a high relative positional accuracy between the optical fiber units and not to shift the optical axis.
An object is to provide an optical fiber array that is easy to assemble and is freely designed.

[0007]

The optical fiber array of the present invention is a fiber array in which a plurality of optical fiber units having optical fibers fixed in the capillaries are arranged in a square lattice, and spacers are provided between the capillaries. Is characterized by.

The optical fiber array with a collimator lens of the present invention is a fiber array in which a plurality of optical fiber units each having an optical fiber fixed in a capillary are arranged in a square lattice, and the collimator lens and the optical fiber are provided in the capillary. And a spacer is provided between the capillaries.

[0009]

According to the present invention, for example, when a plurality of optical fiber units having optical fibers fixed in a cylindrical capillary are aligned by using their outer diameters, a circle for keeping the distance between the optical fiber units constant. A columnar or spherical spacer is inserted between the optical fiber units to reduce the positional displacement due to the rolling of the optical fiber units and realize automatic and highly accurate alignment.

Further, the structure of the capillaries forming the above-mentioned optical fiber unit is made into a structure capable of integrating the collimator lens and the optical fiber to reduce the variation of the optical coupling characteristics due to the positional displacement between the collimator lens and the optical fiber unit. It is configured so that the light from can be emitted or entered with high efficiency.

An optical fiber unit is composed of an optical fiber and a cylindrical capillary. The array pitch of the optical fiber array is a constant value, and this value matches the outer dimensions of the capillaries. Since the accuracy of the arrangement pitch of the optical fiber array is determined by the outer diameter of the capillaries, a material (for example, ceramics) that can be processed with high accuracy and is not easily deformed is used for the capillaries. The spacer has, for example, a cylindrical shape, and in the case of a square lattice optical fiber array,
The outer diameter is (√2-1) times the array pitch, which fills the gap between the optical fiber units. If the dimensional accuracy of the capillaries and spacers that make up the optical fiber unit is good, a high-precision optical fiber array should be able to be constructed without depending on the shape, but in reality, the dimensional accuracy depends on the shape. To do. Therefore, a cylindrical shape or a cylindrical shape that can be processed with high technical precision as compared with a prism (a square pillar or a triangular pillar) or the like was used. Further, the spacer is made in the same shape (for example, ceramics) as the above-mentioned capillaries, and its length is the same as that of the capillaries because of easy alignment. By arranging the spacers processed in this way between the optical fiber units, displacement due to rolling of the optical fiber units is eliminated, and a high-precision and large-scale optical fiber array can be easily constructed as compared with the conventional configuration. be able to. The optical fiber unit is adhesively fixed with an adhesive.
In this case, the alignment plate is used to perform alignment without deviation. As with the optical fiber unit, the dimensional accuracy of the alignment plate also determines the accuracy of the optical fiber array, so a material that can be processed with high accuracy and is difficult to deform (for example, a ceramic plate) is used.

Even if a spherical spacer having a diameter (√2-1) times the arrangement pitch is used as the spacer, the position of the optical fiber unit can be fixed by the same action. The spherical spacer can also be processed with higher accuracy than a prism or the like.

A collimator lens may be attached to the above-mentioned optical fiber unit. In this case, two types of capillaries may be used, one for the collimator lens and the other for the optical fiber, or a capillary for both the collimator lens and the optical fiber may be used. The capillary for both the collimator lens and the optical fiber has two inner diameters for fixing the optical fiber and for fixing the collimator lens. Further, the collimator lens can be composed of an optical fiber and a Selfox lens. When the capillaries for fixing the optical fiber and the capillaries for fixing the SELFOX lens are separately used, for example, those having the same outer diameter dimension and the same central axis as those made of ceramics can be used.

When manufacturing an optical fiber unit with a collimator lens, the positional deviation between the collimator lens and the optical fiber and the optical axis deviation become problems. The positional deviation and the optical axis deviation are mainly determined by the dimensional accuracy in manufacturing the optical fiber unit. The dimensional accuracy is determined by the capillaries, the core diameter and outer dimensions of the optical fiber, and the outer dimensions of a standard SELFOC lens used as a collimator lens. The processing accuracy Δd of the components of these optical fiber units can actually be realized at about ± 1 μm. Therefore, the positional deviation accuracy of the above-mentioned optical fiber unit alone is about Δd to ± 1 μm, and when N optical fiber units are arrayed, an optical fiber array with accuracy of about ± N × Δd to ± N μm is obtained. , Can be easily configured without requiring special alignment.

The deviation of the optical axis angle can be reduced by increasing the length of the capillary in a range where the elastic deformation amount of the capillary is smaller than the dimensional accuracy. For example,
Regarding the capillaries having the dimensional accuracy of ± 1 μm,
If the length L is 10.0 mm or more, the optical axis angle deviation is about ± Δd / L = ± 0.1 mrad, and sufficient angular accuracy can be secured for integrating a normal optical fiber and a collimator lens. . Actually, it is possible to easily manufacture a capillary having a length of about 10 and a few mm and the deformation of which is less than the processing accuracy. If N optical fiber units having an angle accuracy of ± Δd / L = ± 0.1 mrad are arrayed, an optical fiber array having an angle accuracy of ± NΔd / L = ± 0.1 × Nmrad is obtained. , Can be easily realized without requiring special alignment.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments with reference to the drawings, but it goes without saying that the present invention is not limited to these embodiments.

(Embodiment 1) FIG. 1 shows a first embodiment of the present invention. (A) is a horizontal sectional view and (B) is a vertical sectional view.
An optical fiber 101 and a capillary 102 constitute an optical fiber unit 110. In this embodiment, the arrangement pitch of the optical fiber array is a, and this value matches the outer dimension d ₁ of the capillary 102. Since the accuracy of the array pitch of the optical fiber array is determined by the outer diameter of the capillaries 102, a material (for example, ceramics) that can be processed with high accuracy and is difficult to deform is used for the capillaries 102. Reference numeral 103 denotes a columnar spacer, and in the case of the square lattice optical fiber array shown in FIG. 1, its outer diameter d ₂ fills the gap between the optical fiber units 106 as shown in FIG. 1 (A). (√2-1) a. The spacer 103 is made of the same material (for example, ceramics) as the capillary 102, and its length is the same as that of the capillary 102 for ease of alignment. By arranging the spacer 103 processed in this way between the optical fiber units 110, displacement due to rolling of the optical fiber units 110 is eliminated, and a high-precision and large-scale optical fiber array can be easily realized as compared with the conventional configuration. Could be configured to. Moreover, 104 is an adhesive agent for adhering and fixing the optical fiber unit 110, and 105 is an alignment plate. As with the optical fiber unit, the dimensional accuracy of the alignment plate 105 also determines the accuracy of the optical fiber array, so a material that can be processed with high accuracy and is difficult to deform (for example, a ceramic plate) was used.

Although FIG. 1 shows an embodiment of a 4 × 4 two-dimensional optical fiber array, it can be easily inferred that a general N × M (N and M are natural numbers) optical fiber array can also be constructed.

(Embodiment 2) FIG. 2 shows a second embodiment of the present invention. (A) is a horizontal sectional view and (B) is a vertical sectional view.
In this embodiment, as the spacer 113, a spherical spacer 113 having a diameter d ₃ = (√2-1) a is used instead of the cylindrical spacer of the first embodiment. Even if the spherical spacer 113 is used, the optical fiber unit 11 can be operated in the same manner as in the first embodiment.
The position of 0 can be fixed.

Although FIG. 2 shows an embodiment of a 4 × 4 two-dimensional optical fiber array, it can be easily inferred that a general N × M (N and M are natural numbers) optical fiber array can be constructed.

(Embodiment 3) FIGS. 3A and 3B show an optical fiber unit 11 according to the first and second embodiments of the present invention.
An example of the optical fiber unit when the collimator lens is attached to 0 is shown. FIG. 3A shows an example in which two types of capillaries for collimator lens 220 and capillaries for optical fiber 221 are used, and FIG. 3B shows a configuration example in which a collimator lens and a capillary 230 for both optical fibers are used. 220 is also fixed in position by a spacer, but the outer diameter of 220 and the spacer for 220 may be the same as or different from the outer diameter of 221 and the spacer for 221. The collimator lens / capillary 230 for shared optical fiber has two inner diameters for fixing the optical fiber and for fixing the collimator lens. Reference numeral 201 is an optical fiber, 202 is a core portion of the optical fiber, and 210 is a collimator lens composed of a SELFOC lens. 221 is a capillary for fixing an optical fiber, 220 is a capillary for fixing a SELFOC lens, both of which are ceramics having the same outer diameter dimension and central axis. The capillaries are provided with tapers 231 and 222 to facilitate the introduction of optical fibers and collimator lenses.

By arranging the optical fiber units shown in FIG. 3 as in the first and second embodiments shown in FIGS. 1 and 2, a square lattice optical fiber array can be realized.

(Embodiment 4) FIG. 4 shows a fourth embodiment of the present invention. In this embodiment, the cross section of the capillary 302 for fixing the optical fiber 301 has one side d ₄ = (√2-1) a.
And the spacer 303 has a square shape with one side (√2-1) a. An optical fiber array having a square lattice with a pitch a can be constructed by the capillaries and spacers having this shape. 305 is an alignment plate,
304 is an adhesive agent for fixing the respective optical fiber units. No adhesive is needed between the capillary and the spacer.

There are innumerable combinations of cross-sectional shapes of the capillaries and the spacers constituting the two-dimensional optical fiber array other than the above-mentioned embodiments, which itself contributes greatly to the degree of freedom in designing the optical fiber array. There is.

[0025]

As described above, according to the present invention, when assembling the optical fiber array, the optical fibers are automatically aligned and assembled with the dimensional accuracy of the capillaries and the spacers, so that arraying is easy. Further, as compared with the method using the V-groove substrate which has been used conventionally, there is no limitation on the array size of the optical fiber, and there is an advantage that a large-scale optical fiber array can be constructed. Further, the array pitch of the optical fibers can be arbitrarily designed only by changing the outer diameter sizes of the capillaries and the spacers.

[Brief description of drawings]

1A and 1B are schematic cross-sectional views showing an optical fiber array according to a first embodiment of the present invention, where FIG. 1A is a cross-sectional view and FIG.
Is a vertical sectional view.

2A and 2B are schematic cross-sectional views showing an optical fiber array according to a second embodiment of the present invention, where FIG. 2A is a cross-sectional view and FIG.
Is a vertical sectional view.

FIG. 3 is a schematic cross-sectional view showing a configuration example of an optical fiber unit with a collimator lens according to a third embodiment of the present invention. (A) is a configuration example using a shared capillary,
(B) shows a configuration example using a separate capillary.

FIG. 4 is a schematic cross-sectional view showing a fourth embodiment of the present invention in which a capillary has a regular octagonal cross-sectional shape.

FIG. 5 is a schematic cross-sectional view showing a conventional optical fiber array.

[Explanation of symbols]

 101 Optical Fiber 102 Capillary 103 Spacer (Cylindrical) 104 Adhesive 105 Alignment Plate 110 Optical Fiber Unit 113 Spacer (Spherical) 201 Optical Fiber 202 Optical Fiber Core 210 Collimator Lens 220 Capillary for Collimator Lens 221 Capillary for Optical Fiber 222, 231 Taper 230 Capillary for Optical Fiber and Collimator Lens 300 Optical Fiber Core 301 Optical Fiber 302 Capillary 303 Spacer 304 Adhesive 305 Alignment Plate 310 Optical Fiber Unit 401 Optical Fiber 402 Micro Ferrule 410 Optical Fiber Unit 404 Adhesive 405 Alignment Plate

Claims (2)

[Claims] 1. A fiber array in which a plurality of optical fiber units each having an optical fiber fixed in a capillary are arranged in a square lattice shape, and a spacer is provided between the capillaries. 2. A fiber array in which a plurality of optical fiber units having optical fibers fixed in a capillary are arranged in a square lattice shape, a collimator lens and optical fibers are fixed in the capillary, and a spacer is provided between the capillaries. An optical fiber array with a collimator lens.