JP5263342B2 - Optical wiring parts - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a means that makes downsizing possible for optical wiring components and that connects an optical waveguide structure to a multifiber optical connector efficiently with reduced space. <P>SOLUTION: The optical wiring component includes an optical waveguide structure having a plurality of cores, a clad and an optical path conversion section which, in the cores, bends the optical path of the cores toward optical fiber holes, and also includes a multifiber optical connector having optical fiber holes of a plurality of steps, while the optical wiring component is an optically connectable component. The optical waveguide structure has a zigzag-structured end with a patterning performed, by arranging the optical path conversion section from one end to the other end in the short side direction of the optical fiber so as to be placed opposite to the optical fiber holes, and by repeating the procedure successively for the optical fiber holes of the adjacent steps, in the structure of the optical wiring component. <P>COPYRIGHT: (C)2008,JPO&amp;INPIT

Description

  The present invention relates to an optical wiring component.

  In optical communication, an optical waveguide is usually used in combination with an optical fiber. The optical waveguide is coupled to a multi-core optical fiber. In general, as a method of coupling the optical waveguide and the optical fiber, the optical fiber connector substrate and the optical waveguide substrate are fixed, and the optical fiber and the optical fiber are coupled. A method of aligning and fixing with the waveguide has been performed. Specific examples thereof include an optical waveguide component including an optical waveguide body capable of coupling multiple optical waveguides and multiple optical connectors via fitting pins (see, for example, Patent Document 1). Furthermore, in the coupling using multiple optical waveguides, it is necessary to assemble optical connectors in multiple stages, and it is necessary to use more parts.

JP 7-35952 A

  The present invention provides a means for enabling an optical wiring component to be miniaturized and for connecting an optical waveguide structure to a multi-core optical connector in a space-saving and efficient manner.

The present invention is achieved by the optical wiring components of the following items (1) to (10).
(1) An optical connection component having a plurality of rows of optical path connection portions arranged at a predetermined pitch, wherein the optical path connection portions are arranged in a matrix in which the row direction and the column direction are orthogonal to each other. Connecting parts,
An optical waveguide structure comprising: a plurality of core portions provided in the same plane; a clad portion; and an optical path conversion portion provided in the core portion for bending an optical path of the core portion toward the optical path connection portion. Body,
An optical wiring component comprising:
The optical waveguide structure is branched at a branch portion provided in the middle thereof, and the end portion on the non-branched side of the optical waveguide structure has a longitudinal direction of the core portion with respect to the arrangement direction of the optical path connecting portion. It is connected with respect to the optical connection component so as to be inclined, and the optical path conversion unit provided in each of the adjacent core units among the plurality of core units is different from the optical path connection units in different stages. An optical wiring component, wherein the optical wiring components are configured so as to be opposed to each other and displaced from each other in the longitudinal direction of the core portion.
(2) The optical wiring component according to (1), wherein the plurality of core portions are configured to be bent in a plan view at the end portion.
(3) The optical path conversion unit has an inclined surface formed by providing a space in the core unit, or an inclined surface formed at an end of the core unit. The optical wiring component according to item (2).
(4) The optical connection component having the plurality of stages of optical path connecting portions includes any one of the first to third aspects including a multi-core optical connector having a plurality of stages of optical fiber holes. Optical wiring components as described in the paragraph.
(5) The optical wiring component according to (4), wherein the optical wiring component further includes an optical fiber inserted into the optical fiber hole.
(6) The optical wiring component further includes an optical element provided with a plurality of stages of light receiving / emitting portions provided on the side opposite to the optical waveguide structure of the multi-fiber optical connector,
The optical wiring component according to item (4), wherein the core portion and the light receiving / emitting portion are optically connected through the optical fiber hole.
(7) The optical connection component having the plurality of stages of optical path connection units includes any one of items (1) to (3) including an optical element including a plurality of stages of light receiving / emitting units. Optical wiring components as described in 1.
(8) The optical wiring component according to (7), wherein the optical connection component is configured such that the optical path of the core unit is directly optically connected to the light receiving / emitting unit from the optical path conversion unit. .
(9) The optical waveguide structure has an alignment hole, and the optical connection component has a fixing guide that fits into the alignment hole. The optical wiring component according to any one of items 1).
(10) The optical wiring component according to any one of (1) to (9), wherein the optical waveguide structure has a conductor circuit.

It is a top view for demonstrating the example of the optical wiring component of this invention. In this invention, it is the top view to which the connection part of an optical waveguide structure and a multi-core optical connector was expanded. In an example of the optical wiring component of this invention, it is a top view for demonstrating the connection with an 8-fiber optical connector. It is a schematic diagram explaining the manufacture example of the optical waveguide structure in this invention. It is a schematic diagram for demonstrating the optical path changing part in this invention. It is a perspective view for demonstrating an example of the optical wiring component of this invention. It is a perspective view for demonstrating an example of the optical wiring component of this invention. It is a perspective view for demonstrating an example of the optical wiring component of this invention. It is a perspective view for demonstrating an example of the optical wiring component of this invention. In this invention, it is the top view to which the connection part of the optical waveguide structure which provided the hole for alignment, and a multi-core optical connector was expanded.

The present invention includes a plurality of core parts, a clad part, and an optical waveguide structure having an optical path conversion part that bends the optical path of the core part toward the optical path connection part in the core part,
An optical connecting component having a multi-stage optical path connecting portion;
An optical wiring component comprising
The optical waveguide structure is arranged so that the optical path changing portion is arranged so as to face the optical path connecting portion, from one end to the other end in the short direction of the optical waveguide, and on the adjacent optical path connecting portion. On the other hand, this is an optical wiring component having a staggered structure end portion that is patterned by repeating this in order. According to the present invention, it is possible to reduce the size of the optical wiring component, and to provide means for efficiently connecting the optical waveguide structure to the multi-fiber optical connector in a space-saving manner. Hereinafter, although this invention is demonstrated, this invention is not limited to these at all.

  Examples of the optical connecting component having the optical path connecting portion of the plurality of stages include those having an optical path connecting function between optical components, and those having a function of introducing / deriving light into / from the optical path of the optical waveguide. As an example, a multi-fiber optical connector having a plurality of stages of optical fiber holes and an optical element having a plurality of stages of light receiving / emitting portions can be cited.

  The multi-fiber optical connector having a plurality of stages of optical fiber holes has an optical fiber hole as the optical path connecting portion. For example, as an array of optical fiber holes, 16 cores (8 cores × 2 rows (stages)) ), 24 cores (12 cores x 2 rows (stages)), 32 cores (8 cores x 4 rows (stages)), 60 cores (12 cores x 5 rows (stages)), 80 cores (16 cores x 5 rows (stages)) Step)). At this time, 125 μm can be used as the diameter of the hole, and 250 μm, 500 μm, or the like is used as the pitch interval between the holes. Moreover, as a cross-sectional area of such a multi-fiber optical connector, for example, 2.5 mm × 4.4 to 8.4 mm is used although it depends on the arrangement of the optical fiber holes.

  As the optical element having the plurality of stages of light receiving / emitting parts, the light receiving part and the light emitting part serve as an optical path connecting part, and the optical element in which the light receiving / emitting parts are formed in a plurality of stages, and these are arranged in one stage Even if the optical elements are arranged, they can be used as a plurality of stages by arranging two or more optical elements arranged in one stage.

The optical wiring component of the present invention will be described in detail below with reference to the drawings.
FIG. 1 is a plan view for explaining an example of the optical wiring component of the present invention, and FIG. 2 is an enlarged plan view of a connection portion between the optical waveguide structure and the multi-core optical connector. The wire core in FIG. 2, that is, the optical fiber hole is a two-stage example.

  The present invention relates to an optical wiring component including a multi-row optical waveguide and a multi-core optical connector, and includes an optical waveguide structure 102 having a plurality of core portions and a cladding portion, and a plurality of stages. A multi-core optical connector 101 having an optical fiber hole, and an optical wiring component that is optically connectable, wherein the optical waveguide structure has an optical path of the core portion connected to the core portion, and the optical fiber. Staggered so as to have an optical path changing portion bent toward the hole, and the optical path changing portion in the core portion 105 being disposed so as to face the optical fiber hole (first stage 104a, second stage 104b). This is an optical wiring component having a structural end 103.

  In the present invention, the staggered structure refers to the light at adjacent steps so that the optical path changing portions in the plurality of core portions are shifted so as to be aligned with the optical fiber holes from one end in the short direction of the optical waveguide to the other end. The fiber hole is repeatedly patterned in order, such as the first stage, the second stage, the first stage, and the second stage. When the optical fiber hole has three stages, the optical path extends from one end of the optical waveguide to the other end, as in the first, second, third, first, second, and third stages. Patterning is performed so that the conversion unit is displaced so as to fit the optical fiber hole. In the drawing, the lengths of the core end portions are alternated, but the lengths may be the same depending on how the optical path conversion unit is provided.

Hereinafter, the optical waveguide structure used in the present invention will be described.
The optical waveguide structure in the present invention includes an optical waveguide layer having a core part and a cladding part, and the optical waveguide layer includes, for example, a core part and a cladding part having a refractive index lower than that of the core part. A core layer provided in contact with at least one surface of the core layer, and a cladding layer having a refractive index lower than that of the core portion, or a cladding portion having a refractive index lower than that of the core portion. For example, a three-layer embedded waveguide embedded in the substrate.
A conductor circuit may be formed in the optical waveguide structure.

In the present invention, the optical waveguide layer in the optical waveguide structure 102 is an optical path changing portion (not shown, but formed at the positions of the optical fiber holes 104a and 104b) in the core portion 105. A staggered structure that is repeatedly patterned in order with respect to the adjacent optical fiber holes from one end to the other end in the short direction of the optical waveguide so as to be opposed to the fiber holes 104a and 104b. The core portion is curved toward the end portion (having a curved portion 107) so that the patterning is disposed so as to face the optical fiber hole (FIG. 2). It is preferable in design that it is made as described above. The curved portion may be a bent portion and may be deformed to such an extent that no optical loss occurs.
In the optical waveguide structure, by providing an alignment hole facing the fixing guide (FIG. 10), the alignment hole and the fixing guide are fitted to each other, so that the optical path conversion unit and the optical fiber of the optical waveguide structure are fitted. It becomes possible to fit the holes passively with high accuracy.

A production example of the optical waveguide structure will be described.
As shown in FIG. 4C, the core layer 11 has a core portion 13 having a refractive index higher than that of the cladding portion 14. The optical waveguide layer 10 includes a core layer 11 that forms the core portion 13 and clad portions that are formed by clad layers 12 a and 12 b provided on both surfaces of the core layer 11. As a result, light can be transmitted through the core. The size of the cross section of the core part is, for example, 35 to 100 μm × 35 to 100 μm, and the distance from the adjacent core part is, for example, 20 to 500 μm.

  Such an optical waveguide layer 10 is formed by, for example, applying a varnish containing a material constituting the cladding layer on the base material 15 to form the cladding layer 12b, and then configuring the core layer on the cladding layer. A varnish containing a material to be coated is applied to form the core layer 11, and then a varnish containing a material constituting the cladding layer is applied to the core layer to form another cladding layer 12b. The body 18 is formed (FIG. 4A). At this time, the thickness of the formed three layers is usually preferably about 70 to 150 μm, for example.

  Further, the active energy ray 16 is irradiated to the intermediate formed by the core layer 11 and the clad layers 12a and 12b provided on both surfaces of the core layer 11 (FIG. 4B), and the core portion 13 is irradiated. Then, the base material 15 is peeled off to obtain the optical waveguide layer 10 (FIG. 4C). According to this method, the portions other than the core portion 13 of the core layer 11 described later and the cladding layers 12a and 12b all constitute the cladding portion.

  In the core portion formation, the plurality of core portions of the optical waveguide formed in multiple stripes are arranged at one end in the short direction of the optical waveguide such that the core end portion is disposed at a position facing the optical fiber hole. At the other end, the pattern 17 having the patterned staggered structure end formed on the adjacent optical fiber holes in order is laminated on the intermediate body 18 and irradiated with active energy rays. It ’s fine.

  At this time, by using a metal plate such as copper and copper alloy as the base material, an optical waveguide layer with a metal plate is prepared, and the metal plate is etched to form a conductor circuit, thereby forming a conductor circuit on the clad layer. A conductor layer can be formed on the substrate.

  In the above description, the core part is formed by forming three layers of the core layer and the clad layer. However, one layer each may be formed, and two layers of the clad layer 12b and the core layer 11 are used as intermediates. After forming the core part, the clad layer 12a may be formed.

(Core layer)
Examples of the material constituting the core layer 11 include resin materials such as cyclic olefin resins such as acrylic resins, epoxy resins, polyimide resins, benzocyclobutene resins, and norbornene resins. Among these, norbornene resins (particularly, addition polymers of norbornene resins) are preferable. Thereby, it is excellent in transparency, a softness | flexibility, insulation, and heat resistance. Furthermore, the hygroscopicity can be lowered as compared with the case where other resins are used.

Moreover, as a constituent material of the core layer 11, a material whose refractive index changes by irradiation with active energy rays or further heating is preferable. Preferable examples of such a material include a resin composition containing a cyclic olefin resin such as a benzocyclobutene resin and a norbornene resin as a main material. Those containing (addition polymer) (as the main material) are particularly preferred.
Examples of the active energy rays used for the exposure include active energy rays such as visible light, ultraviolet light, infrared light, and laser light, electron beams, and X-rays. The electron beam can be irradiated with an irradiation amount of, for example, about 50 to 2000 KGy.

(Clad layer)
The material constituting the clad layers 12 a and 12 b is not particularly limited as long as the refractive index is lower than that of the material constituting the core layer 11. Specific examples include resin materials such as cyclic olefin resins such as acrylic resins, epoxy resins, polyimide resins, and norbornene resins. Among these, norbornene resins (in particular, addition polymers of norbornene resins) are preferable. Thereby, it is excellent in transparency, insulation, flexibility, and heat resistance. Furthermore, the hygroscopicity can be lowered as compared with the case where other resins are used.

  For example, in the case of an addition polymer of norbornene resin, the refractive index can be adjusted depending on the type of the side chain. Specifically, the refractive index can be adjusted as appropriate by providing an alkyl group, an aralkyl group, a halogenated alkyl group, a silyloxy group, or the like in the side chain of a norbornene resin (especially an addition polymer is preferred). Thereby, a difference in refractive index from the material constituting the core portion can be generated.

  In particular, the material constituting the core layer 11 is preferably an addition polymer of norbornene resin, and the material constituting the cladding layers 12a and 12b is preferably an addition polymer of norbornene resin. Thereby, especially heat resistance and toughness can be improved.

As the norbornene-based resin (addition polymer thereof) constituting the clad layers 12a and 12b, specifically, those having a linear aliphatic group in the side chain are preferable. Thereby, a softness | flexibility and folding resistance can be improved. Examples of the linear aliphatic group include propyl group, butyl group, pentyl group, hexyl group, heptyl group, octyl group, nonyl group, and decyl group.
The clad layers 12a and 12b may be made of the same constituent material or different constituent materials.

  In addition to the method described above, the optical waveguide layer 10 can be obtained by a known method such as a method in which a core portion is provided in a previously formed recess and the periphery thereof is covered with a clad material (cladding portion).

(Optical path conversion unit)
The optical waveguide layer 10 in the optical waveguide structure is provided with an optical path conversion part that bends the optical path of the core part toward the optical fiber guide hole of the multi-fiber optical connector. The optical path changing portion may be provided at any location of the core portion in the vicinity of the optical connection portion with the multi-fiber optical connector, but can be provided at each of the end portions of the plurality of core portions. When provided at the end of the core part, the length of each core part is adjusted as shown in FIG.

A method for forming an example of the optical path conversion unit will be described.
As shown in FIG. 5A, the optical path conversion unit 109 has an inclined surface formed by providing a space having a triangular cross section from one surface side of the optical waveguide layer 10 as described above. In some cases, there may be an inclined surface at the end of the core part in FIG.
The inclined surface is inclined (approximately 45 degrees with respect to the light transmission direction of the core portion) with respect to the light transmission direction of the core portion provided in the core layer 11. Thereby, for example, as shown by an arrow A in FIG. 5, the light transmitted through the core portion provided in the core layer 11 is totally reflected, and the light transmission direction can be changed to a substantially right angle.

  Briefly describing the method for forming such an optical path changing portion, a laser is irradiated to a portion where a reflection portion of the optical waveguide layer 10 composed of a core portion and a clad portion joined to the outer periphery of the core portion is formed. Then, by changing the laser irradiation region relative to the optical waveguide layer 10, the laser irradiation time to the portion of the optical waveguide layer forming the optical path changing portion is partially changed, and the laser optical waveguide layer The optical path conversion part can be formed by removing the constituent material of the optical waveguide layer while adjusting the degree of reach in the depth direction. Thus, since the reflection part can be formed by laser irradiation, it is easy to form the optical path conversion part in an arbitrary pattern at an arbitrary position. Therefore, the pattern of the optical wiring can be easily formed.

Examples of the laser include an excimer laser such as ArF and KrF, a YAG laser, and a CO ₂ laser.

  Although the irradiation energy of a laser is not specifically limited, 1-10 mJ is preferable and 5-7 mJ is especially preferable. Within the above range, the constituent material of the optical waveguide layer 10 can be removed in a short time. Although the frequency at the time of laser irradiation is not specifically limited, 50-300 Hz is preferable and 200-250 Hz is especially preferable. When the frequency is within the above range, the smoothness of the inclined surface is particularly excellent.

  The size of the optical waveguide layer 10 irradiated with laser is not particularly limited because it depends on the size of the optical path changing portion to be formed, but is preferably 80 to 200 μm × 80 to 200 μm, particularly 100 to 150 μm × 100. It is preferable that it is -150 micrometers. Thereby, a fine optical path conversion part can be formed.

In the present invention, the multi-fiber optical connector is of a multi-dimensional arrangement in which a plurality of optical fiber holes are formed, and examples of the arrangement of the optical fiber holes are as described above.
The core part in the optical structure is designed according to the arrangement of the optical fiber holes in these multi-fiber optical connectors.

  The optical waveguide structure 102 obtained above is disposed so as to face the optical path changing portion of the core portion 105 and the optical fiber holes 104a and 104b of the multi-fiber optical connector, and is aligned with the fixing guide 106 of the connector. The connector cover can be fixed to obtain an optical wiring component.

  In the optical waveguide structure, examples of the method for providing the alignment hole facing the fixing guide include an ablation method using an excimer laser and a precision drilling method using an NC drill. The size of the alignment hole is, for example, 500 to 700 μm in diameter, and the error is preferably about ± 0.5 to 0.8 μm.

FIG. 6 is an example in which an optical path conversion unit 109 is provided at the end of the core part 105 of the optical waveguide layer of the optical waveguide structure 102. The optical path conversion unit 109 and the optical fiber hole 104 are aligned with each other. This is an assembled example.
As the assembly method, for example, the optical waveguide structure obtained above and a multi-fiber connector, the optical path conversion part of the optical waveguide structure is the optical path of the core part, and the optical fiber hole of the multi-fiber connector is used. The optical waveguide structure can be sandwiched and fixed so that the optical waveguide structure can be sandwiched and overlapped, and then a fixing cover (not shown) can be superimposed on the optical waveguide structure. As the fixing cover, a flat plate, a connector ferrule, or the like having an alignment hole or a guide pin at a position facing the alignment hole can be used.

The wiring component obtained as described above can have a structure in which the optical fiber 110 is inserted into the optical fiber hole 104 and the optical path of the optical waveguide and the optical fiber are optically connected (FIG. 6).
In the above example (FIG. 6), the example in which the optical path conversion unit 109 and the optical fiber 110 are optically connected by the optical fiber hole 104 is shown. However, the optical fiber 110 is further inserted using the optical fiber hole 104 as a guide, The optical path conversion unit 109 and the optical fiber 110 can be directly optically connected (FIG. 8). This makes it possible to efficiently join an optical fiber and a waveguide with little optical loss, and further reduce the space by the staggered structure.
In these assembling, by using an optical waveguide structure having an alignment hole 114 facing the fixing guide 106, positioning is facilitated by inserting a guide pin into the alignment hole 114 and the fixing guide 106. Further, also in the fixing cover (not shown), by providing the alignment hole 114 at a position facing the fixing guide, the alignment hole 114 of the fixing cover, Positioning is facilitated by inserting guide pins into the alignment holes 114 of the optical waveguide structure and the fixing guides 106 of the multi-fiber optical connector.

Further, the wiring component can be directly optically connected to an optical element such as a light emitting element and a light receiving element without using an optical fiber. For example, the optical fiber 110 is not inserted into the optical fiber hole 104, In the optical fiber hole 104, the optical element 111 is arranged on the opposite side to the side where the optical path changing unit 109 is provided (FIG. 7). At this time, the optical path of the optical waveguide is arranged to be transmitted to the light receiving / emitting unit 112 of the optical element through the optical fiber hole 104.
As a method of assembling this structure, a substrate in which the optical element 111 is arranged on a substrate such as an electric circuit substrate is prepared, and the optical waveguide structure 102 and the multi-fiber optical connector 101 are aligned in the same manner as described above. Further, the optical path in the optical fiber hole 104 of the multi-fiber optical connector 101 is aligned and overlapped so as to face the light receiving / emitting unit 112 of the optical element, and fixed to the upper part of the optical waveguide structure. The optical waveguide structure 102 and the multi-core optical connector 101 can be sandwiched and fixed by overlapping a cover (not shown).

Further, the optical wiring component may be such that the optical path of the core part is directly optically connected to the light receiving / emitting part of the optical element from the optical path converting part. As the optical elements formed in a plurality of stages, two optical elements 111 in which the light receiving / emitting portions 112 are arranged in a single stage are arranged on a substrate such as an electric circuit board (may be two or more). The light receiving / emitting unit 112 has a structure in which the optical path changing unit 109 of the optical waveguide structure 102 is arranged (FIG. 9).
As a method for assembling this structure, the optical waveguide structure obtained above, a substrate on which at least the light receiving / emitting section 112 is mounted on the substrate 115 such as an electric circuit substrate, and the fixing cover 116 are prepared. Next, the optical path conversion unit of the optical waveguide structure is aligned and overlapped so that the optical path of the core part is directed to the light receiving / emitting unit 112, and further the fixing cover 116 is overlapped, and the optical waveguide structure 102 can be clamped and fixed. At this time, if an alignment hole is provided in a predetermined position in the optical waveguide structure 102, the substrate 115, and the fixing cover 116, it is easy to align using a guide pin as described above. Become.

  Furthermore, in the wiring component of the present invention, the other end of the optical waveguide structure having the staggered structure portion may be connected to the multi-fiber optical connector by the same staggered structure portion. Moreover, as shown in FIG. 1, it can be set as the structure connected to the other multi-core optical connector by providing the branch part 108 in an optical waveguide structure. For example, when the staggered structure has 24 cores (12 cores × 2 stages), the light branches into three, and the light of 8 cores as shown in FIG. 3 (only the core part 105 is shown in the optical waveguide structure). Can be connected with a connector. In connection with the 8-fiber optical connector, an optical path conversion section is provided at the other end of the optical waveguide structure in the same manner as described above, and the optical path conversion section and the optical fiber hole of the 8-fiber optical connector are positioned. At the same time, the optical paths can be connected and assembled so as to be transmitted.

DESCRIPTION OF SYMBOLS 10 Optical waveguide layer 11 Core layer 12a, 12b Clad layer 13 Core part 14 Clad part 15 Base material 16 Active energy ray 17 Pattern 18 Intermediate body 101 Multi-fiber optical connector 102 Optical waveguide structure 103 Staggered structure edge part 104, 104a, 104b Optical fiber hole 105 Core portion 106 Fixing guide 107 Bending portion 108 Branching portion 109 Optical path changing portion 110 Optical fiber 111 Optical element 112 Light receiving / emitting portion 113 Multi-fiber optical connector 114 at the other end 114 Alignment hole 115 Substrate 116 Fixing cover

Claims (10)

An optical connection component having a plurality of rows of optical path connection portions arranged at a predetermined pitch, wherein the optical path connection portions are arranged in a matrix in which the row direction and the column direction are orthogonal to each other ; ,
An optical waveguide structure comprising: a plurality of core portions provided in the same plane; a clad portion; and an optical path conversion portion provided in the core portion for bending an optical path of the core portion toward the optical path connection portion. Body,
An optical wiring component comprising:
The optical waveguide structure is branched at a branch portion provided in the middle thereof, and the end portion on the non-branched side of the optical waveguide structure has a longitudinal direction of the core portion with respect to the arrangement direction of the optical path connecting portion. It is connected with respect to the optical connection component so as to be inclined, and the optical path conversion unit provided in each of the adjacent core units among the plurality of core units is different from the optical path connection units in different stages. An optical wiring component, wherein the optical wiring components are configured so as to be opposed to each other and displaced from each other in the longitudinal direction of the core portion.   2. The optical wiring component according to claim 1, wherein at the end portion, the plurality of core portions are configured to be bent in a plan view.   The optical wiring according to claim 1, wherein the optical path conversion unit has an inclined surface formed by providing a space in the core unit, or an inclined surface formed at an end of the core unit. parts.   4. The optical wiring component according to claim 1, wherein the optical connection component having a plurality of stages of optical path connection portions includes a multi-fiber optical connector having a plurality of stages of optical fiber holes.   The optical wiring component according to claim 4, wherein the optical wiring component further includes an optical fiber inserted into the optical fiber hole. The optical wiring component further includes an optical element including a plurality of stages of light receiving / emitting portions provided on the side opposite to the optical waveguide structure of the multi-fiber optical connector,
The optical wiring component according to claim 4, wherein the core portion and the light receiving / emitting portion are optically connected through the optical fiber hole.   4. The optical wiring component according to claim 1, wherein the optical connection component having the plurality of stages of optical path connection portions includes an optical element including a plurality of stages of light receiving / emitting portions.   The optical wiring component according to claim 7, wherein the optical connection component is configured such that an optical path of the core portion is directly optically connected to the light receiving / emitting unit from the optical path conversion unit.   The said optical waveguide structure has an alignment hole, and the said optical connection component has a fixing guide fitted to the said alignment hole. Optical wiring parts.   The optical wiring component according to claim 1, wherein the optical waveguide structure has a conductor circuit.

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