JP2010286548A - Multi-core fiber and optical connector including the same - Google Patents

Abstract

Provided is a multi-core fiber or the like having a structure for easily realizing good optical coupling between connection objects when applied to a part of an optical waveguide in an optical communication system.
A multi-core fiber includes a plurality of cores, a clad 120 that integrally covers the plurality of cores 110 while maintaining a predetermined arrangement state, and a positioning structure 150. Specifically, each of the plurality of cores 110 functions as an optical waveguide extending along a predetermined axis AX and optically independent from each other. The clad 120 integrally covers the plurality of cores 110 and holds the arrangement state of the plurality of cores 110 in a cross section orthogonal to the predetermined axis AX. The positioning structure 150 restricts the rotation around the predetermined axis AX, which is the rotation with respect to the connection target of the core array defined on the cross section.
[Selection] Figure 1

Description

  The present invention relates to a multi-core fiber having a plurality of cores, each of which individually functions as an optical waveguide, as a part of an optical fiber network, and in particular, to easily improve the connection accuracy between the multi-core fiber and various optical network resources. It relates to a structure that can be realized.

  Conventionally, in order to provide an FTTH (Fiber To The Home) service that enables optical communication between one transmitting station and a plurality of subscribers, for example, as shown in FIG. 9, a multi-stage optical splitter is interposed. Thus, a so-called PON (Passive Optical Network) system is realized in which each subscriber shares one optical fiber.

  That is, the PON system shown in FIG. 9 is between the terminal station 1 (transmitting station), which is the final relay station of an existing communication system such as the Internet, and between the terminal station 1 and the subscriber home 2 (subscriber). And an installed optical fiber network. This optical fiber network includes a closure (including an optical splitter 30) provided as a branch point, an optical communication line 12 from the terminal station 1 to the closure, and an optical communication line 31 from the closure to each subscriber home 2. Has been.

  The terminal station 1 includes a station-side terminal device 10 (OLT: Optical Line Terminal) and an optical splitter 11 that branches a multiplexed signal from the OLT 10. On the other hand, the subscriber's home 2 is provided with a subscriber-side terminal device 20 (ONU: Optical Network Unit). In addition, the closure as a branching point of the optical fiber network laid between the terminal station 1 and the subscriber's home 2 includes at least an optical splitter 30 for further branching the multiplexed signal that has arrived, and service contents A wavelength selection filter or the like for limiting the frequency is arranged.

  As described above, in the PON system shown in FIG. 9, the optical splitter 11 is provided in the terminal station 1 and the optical splitter 30 is also provided in the closure arranged on the optical fiber network. One station-side terminal device 10 can provide FTTH service to a plurality of subscribers.

  However, in a PON system in which a plurality of subscribers share a single optical fiber through multistage optical splitters as described above, future transmission capacity such as congestion control (Congestion Control) and securing of a receiving dynamic range, etc. It is true that there is a technical challenge against this increase. As a means for solving this technical problem (congestion control, securing a dynamic range, etc.), a transition to an SS (Single Star) system can be considered. When migrating to the SS system, the number of fiber cores on the inner side of the station increases with respect to the PON system. Therefore, it is essential to make the diameter and the ultra-high density of the optical cable inside the station. A multi-core fiber is suitable as the optical fiber for ultra-fine diameter and ultra-high density.

  For example, as a multi-core fiber, the optical fiber disclosed in Patent Document 1 has seven or more cores arranged two-dimensionally in its cross section. Patent Document 2 discloses an optical fiber in which a plurality of cores are aligned in a straight line, and it is described that connection with an optical waveguide / semiconductor optical integrated device is facilitated.

JP 05-341147 A JP-A-10-104443

  The inventors have found the following problems as a result of examining the above-described conventional technology.

  That is, the multicore fiber described in Patent Document 1 is difficult to connect to an optical device or the like at the transmission end or the reception end. As described in Patent Document 2, an optical device such as an optical waveguide or a semiconductor optical integrated device that is normally manufactured has a plurality of optical transmission / reception elements (light emitting area or light receiving area) arranged in one dimension. In general, such an optical device is optically coupled to a multi-core fiber in which a plurality of cores are two-dimensionally arranged in the cross section (hereinafter, this arrangement state is referred to as a two-dimensional core array). It was difficult.

  In addition, since the multi-core fiber described in Patent Document 2 is intended for optical connection with a one-dimensionally arranged optical transmission / reception element, the cores are arranged one-dimensionally. In this case, since it is difficult to significantly increase the number of cores per multi-core fiber, it cannot be used as an optical transmission line.

  On the other hand, in FTTH, the number of fiber cores increases as the number of subscribers increases, so it is also true that the fiber storage space in the station is being pressed, and a multi-core fiber having a one-dimensional core arrangement and a multi-core having a two-dimensional core arrangement. It can be easily imagined that the demand for using any of the fibers will increase. However, considering the connection between the multicore fiber and other network resources, it is necessary to correct the rotation of the core arrangement around the longitudinal direction of the multicore fiber, unlike the connection of the single core fiber. Is easily expected to become extremely complicated. That is, in such connection work, fine adjustment of the core arrangement on the multi-core fiber side is usually performed while measuring the power of monitor light passing through the connection point for each core functioning as an individual optical waveguide. Fine adjustment of the core arrangement itself is performed by rotating the multi-core fiber around its longitudinal direction, but it is difficult to visually confirm the core arrangement. Therefore, an increase in the complexity of the connection work when connecting to a multi-core fiber having a plurality of cores and other network resources is easily expected.

  The present invention has been made to solve the above-described problems, and is a multi-core fiber that can be applied as a part of an optical waveguide in an optical communication system, and is the same when applied to a part of the optical waveguide. To provide a multicore fiber having a structure for easily realizing good optical coupling between various network resources (connection objects), such as another multicore fiber having a core arrangement, and an optical connector including the same It is an object.

  In order to solve the above-described problems, a multi-core fiber according to the present invention includes a plurality of cores, a clad that integrally covers the plurality of cores, and a rotation of the core arrangement around the longitudinal direction of the multi-core fiber. A positioning structure for limiting Specifically, each of the plurality of cores functions as an optical waveguide that extends along a predetermined axis (matches the longitudinal direction of the multi-core fiber) and is optically independent from each other. The clad integrally covers the plurality of cores and holds the plurality of cores in a one-dimensional or two-dimensional array in the cross section of the multi-core fiber perpendicular to a predetermined axis. The positioning structure restricts rotation about a predetermined axis, which is rotation with respect to the connection target of the core array defined on the cross section.

  As described above, by providing the positioning structure in the multi-core fiber itself, the rotation state of the core array with respect to the connection target can be visually confirmed, and the efficiency of the connection work can be greatly improved.

  In the multi-core fiber according to the present invention, the positioning structure preferably includes an outer peripheral shape of the multi-core fiber shaped in an astigmatism in its cross section in order to facilitate connection work between the multi-core fibers. Thus, when performing core positioning on the basis of the outer peripheral shape, highly accurate core positioning can be easily realized. More specifically, the positioning structure may include an outer peripheral shape of the multicore fiber in which at least a part is configured by a straight line in the cross section of the multicore fiber. In addition, the positioning structure may include an outer peripheral shape of the multicore fiber configured by a concave shape in which at least a part protrudes toward the center of the cross section in the cross section of the multicore fiber. Further, the positioning structure may include an outer peripheral shape of the multi-core fiber that is configured by a convex shape that protrudes in a direction from the center of the cross section toward the outer periphery of the cross-section in the cross section of the multi-core fiber. In any positioning structure, when connecting between multi-core fibers, an auxiliary structure having a shape that engages with the positioning structure of the multi-core fiber is formed in a jig or the like in advance, so that the circumferential direction of the multi-core fiber is determined. Can be easily realized.

  In the multicore fiber according to the present invention, the positioning structure may be a guide hole extending along a predetermined axis from the end face of the multicore fiber. In particular, the guide hole is preferably shaped so that the cross-sectional shape on the end face is asymmetric with respect to the point. In the connection work between the multi-core fibers, a guide pin having a cross-sectional shape matching the guide hole is prepared, and both ends of the guide pin are inserted into the guide holes of the multi-core fibers to be connected as described above. Connection work between multi-core fibers whose cores are positioned with high accuracy can be realized without preparing a jig.

  An optical connector according to the present invention includes a multi-core fiber (multi-core fiber according to the present invention) having the above-described structure, and a ferrule attached to a tip portion including an end face of the multi-core fiber. In particular, the ferrule has a through-hole that accommodates the tip portion of the multi-core fiber, and an auxiliary structure for limiting the rotation of the multi-core fiber around the predetermined axis relative to the ferrule in cooperation with the positioning structure described above. Is provided in the through hole. This is because the multi-core fiber is accurately positioned in a connector shape.

  The ferrule according to the present invention is inserted into an alignment sleeve or the like in order to connect the multi-core fiber to which the ferrule is attached to another network resource. Therefore, on the outer peripheral surface of the ferrule, a positioning structure for restricting the rotation of the ferrule around the predetermined axis (the same positioning structure provided in the multicore fiber) is formed.

  According to the present invention, by providing a positioning structure that restricts rotation in the outer circumferential direction of a multicore fiber having a plurality of cores, connection between the multicore fiber and other network resources, for example, a multicore fiber having the same core arrangement It is possible to easily improve the accuracy of the core positioning in the connection work between them.

It is a perspective view which shows the structure of one Embodiment of the multi-core fiber which concerns on this invention. It is a figure for demonstrating the connection operation | work of the multi-core fiber and optical connector which concern on this invention. It is a figure for demonstrating the manufacturing process of the jig | tool (guide member) fixation process of the multi-core fiber which concerns on this invention, and an optical connector. It is a figure for demonstrating the connection operation | work of the multi-core fibers which concern on this invention. It is a figure for demonstrating the various positioning structure applied to the multi-core fiber which concerns on this invention. It is a figure for demonstrating the cross-section of the jig | tool (guide member) to which the multi-core fiber which concerns on this invention is fixed. It is a perspective view for demonstrating the structure of the ferrule attached to the front-end | tip part of the multi-core fiber which concerns on this invention. It is a figure for demonstrating the connection operation | work of the multi-core fibers which concern on this invention. It is a figure which shows the structure of the conventional optical communication system (PON system).

  Hereinafter, embodiments of the multicore fiber and the optical connector according to the present invention will be described in detail with reference to FIGS. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted. In addition, as the multicore fiber applicable to the present invention, a multicore fiber having either a one-dimensional core array or a two-dimensional core array can be applied, but in the following description, a two-dimensional core array having a more complicated connection operation is used. Reference will be made only to the multi-core fiber that it has. However, a multi-core fiber having a one-dimensional core array also has the same effect as a multi-core fiber having a two-dimensional core array.

  FIG. 1 is a perspective view showing the structure of an embodiment of a multi-core fiber according to the present invention. In FIG. 1, the multi-core fiber 500 includes a plurality of cores 110, a clad 120 that integrally covers the plurality of cores 110 while maintaining a two-dimensional array state (may be a one-dimensional core array), a clad The resin coating 130 provided in the outer periphery of 120 and the positioning structure 150 are provided. Each of the cores 110 extends along a predetermined axis AX that coincides with the longitudinal direction of the multi-core fiber 500 and functions as an optical waveguide that is optically independent from each other. The clad 120 integrally covers the plurality of cores 110 and holds the two-dimensional core arrangement of the multicore fiber 500 configured by the plurality of cores 110 in a cross section of the multicore fiber 500 orthogonal to the predetermined axis AX. . The positioning structure 150 limits the rotation about the predetermined axis AX, which is rotation with respect to the connection target of the two-dimensional core array defined on the cross section. In the connection work, the resin coating 130 at the tip portion including the end face of the multi-core fiber 500 is removed.

  Next, FIG. 2 shows various connection forms between the multi-core fiber 100 having a general structure (which may have either a one-dimensional core array or a two-dimensional core array) and other network resources. Show. As a matter of course, the multi-core fiber 500 according to the present embodiment also assumes various connection forms as shown in FIG.

  For example, FIG. 2A shows an example in which multicore fibers are directly connected as a connection form between multicore fibers. That is, in the state where the end face of one multi-core fiber 100a and the end face of the other multi-core fiber 100b are abutted at the connection point A, the positioning work (alignment work) between the cores in each of the multi-core fibers 100a and 100b is performed. After this alignment operation, the multi-core fibers 100a and 100b are fusion-bonded at the connection point A.

  FIG. 2B shows an example of non-contact connection between multi-core fibers as a connection form between multi-core fibers. That is, in order to constitute an optical connector, one multi-core fiber 100a has a ferrule 300a attached to a tip portion including its end face (fixed with an adhesive, hereinafter referred to as adhesive fixing). In addition, in order to form an optical connector also on the other multi-core fiber 100b, the ferrule 300b is bonded and fixed to the tip portion including the end face. The ferrules 300 a and 300 b of the optical connector configured as described above are inserted into the alignment sleeve 200. Note that the positioning of the cores in each of the multi-core fibers 100a and 100b is performed, for example, in a state where the ferrules 300a and 300b are inserted into the alignment sleeve 200, and the ferrules 300a and 300b are fixed to the alignment sleeve 200 after the positioning is completed. Is done.

  FIG. 2C shows an example of non-contact connection between the multicore fiber and the branch device as a connection form between the multicore fiber and the optical branch device. That is, the ferrule 300 is bonded and fixed to the tip portion including the end face of the multi-core fiber 100 to form an optical connector. On the other hand, in the optical branching device 220, incident end surfaces for individually capturing light beams from the respective two-dimensionally arranged cores are formed on the light receiving surface, and the light beams captured from each incident end correspond to the corresponding branch paths 230. Is output. The optical branching device 220 is housed in a sleeve 210 held by a ferrule 300 attached to the tip portion of the multi-core fiber 100. After the ferrule 300 of the optical connector configured as described above is inserted into the sleeve 210, the plurality of cores arranged two-dimensionally in the multi-core fiber 100 and the plurality of light beams formed on the light receiving surface of the optical branching device 210. Positioning with the incident end face is performed.

  In any of the above connection forms (FIGS. 2 (a) to 2 (c)), it is necessary to position the multi-core fiber with respect to the connection target, and the optical power of the monitor light passing through the connection site is required. While measuring, the position of the ferrule 300 bonded and fixed to the multi-core fiber 100 or its tip is adjusted.

  In any of the above connection configurations, the multi-core fiber 500 according to the present invention can greatly simplify the connection work when connecting to other network resources.

  That is, in the connection between the multi-core fibers, the multi-core fiber 500 is installed in advance on the guide member 400 as shown in FIG. At this time, the prepared guide member 400 is provided with a guide groove 510 in which the multi-core fiber 500 is installed. Normally, a general optical fiber (including a multi-core fiber) installed in the guide groove 510 cannot restrict rotation in the outer peripheral direction around the predetermined axis AX. Therefore, even if a multi-core fiber having a two-dimensional core array is installed, the rotation of the two-dimensional core array cannot be restricted. In addition, the positional relationship of the two-dimensional core array with respect to the connection target cannot be confirmed.

  On the other hand, the multi-core fiber 500 according to the present embodiment is provided with the positioning structure 150 on the surface of the clad 120 as shown in FIG. Therefore, by providing a guide 520 having a cross-sectional shape that can be engaged with the positioning structure 150 in the guide groove 510 in which the multi-core fiber 500 is installed, the outer periphery of the multi-core fiber 500 about the predetermined axis AX is provided. It becomes possible to limit the rotation of the direction (the direction indicated by the arrow S in FIG. 3A).

  Specifically, when connecting multi-core fibers, as shown in FIG. 4, a guide member for holding each multi-core fiber to be connected is prepared. For example, in the example of FIG. 4A, the tip portions of the multi-core fibers 500a and 500b are placed in the guide grooves 510 of one guide member 400 shown in FIG. 3A, and the positioning structures 150 and the guides 520 are placed. Install to engage. As described above, since the multi-core fibers 500a and 500b are installed in the guide groove 510 of the guide member 400 and the positioning in the outer circumferential direction is completed at the same time, the core positioning at the connection point A can be realized with high accuracy. As shown in FIG. 4B, the multi-core fibers 500a and 500b may be separately held by the guide members 400a and 400b. In this case, the end face of the multi-core fiber 500a and the end face of the multi-core fiber 500b can be brought together by bringing the guide member 400a and the guide member 400b closer. At this time, highly accurate core positioning between the multi-core fibers 500a and 500b is achieved in a state where the end faces are abutted. That is, it is possible to perform fusion splicing at the connection point A only by butting the multi-core fibers 500a and 500b without performing alignment work between the two-dimensionally arranged cores.

  On the other hand, when configuring an optical connector, as shown in FIG. 3B, the ferrule 300 is bonded and fixed to the multicore fiber 500 with the tip portion of the multicore fiber 500 inserted into the through hole of the ferrule 300. Is done. At this time, a guide 530 having a cross-sectional shape corresponding to the positioning structure 150 provided in the multi-core fiber 500 according to the present embodiment is provided on the inner wall of the through hole of the ferrule 300, and the positioning structure 150 and the guide 530 are engaged. By inserting the tip portion of the multi-core fiber 500 into the through-hole of the ferrule 300 in the combined state, the rotation of the multi-core fiber 500 in the outer peripheral direction is limited with respect to the ferrule 300. Since the ferrule 300 itself is further fixed to the sleeve as shown in FIGS. 2 (b) and 2 (c), it is positioned on the outer peripheral surface of the ferrule 300 as shown in FIG. 3 (b). A structure 540 may be provided. In this case, a guide having a cross-sectional shape that matches the positioning structure 540 of the ferrule 300 needs to be provided on the inner wall of the sleeve into which the ferrule 300 is inserted. In the case of a sleeve having a structure in which the position is fixed simultaneously with the insertion of the ferrule, the positioning structure 540 on the ferrule 300 side is not necessary.

  Next, various positioning structures applicable to the multi-core fiber according to the present invention will be described with reference to FIGS. FIG. 5 is a diagram for explaining various positioning structures applied to the multi-core fiber according to the present invention. FIG. 6 is a view for explaining a cross-sectional structure of the guide member 400 to which the multi-core fiber 500 according to the present invention is fixed as shown in FIG. FIG. 7 is a perspective view for explaining the structure of the ferrule 300 attached to the tip portion of the multi-core fiber 500 according to the present invention. FIG. 8 is a diagram for explaining a connection operation between the multi-core fibers 500 having the positioning structure as shown in FIG.

  First, it is preferable that the positioning structure applicable to the multicore fiber according to the present embodiment includes an outer peripheral shape of the multicore fiber shaped asymmetrically in the cross section of the multicore fiber.

  Specifically, FIG. 5A shows a cross-sectional structure of a multi-core fiber 510 to which the positioning structure 151 according to the first modification is applied. In other words, the positioning structure 151 of the multi-core fiber 510 is defined by the outer peripheral shape of the multi-core fiber 510 at least partially configured by a straight line in the cross section. The guide member 410 on which the multi-core fiber 510 provided with such a positioning structure 151 is installed has a cross-sectional structure as shown in FIG. That is, in the guide groove 511 in which the multicore fiber 510 is installed, a flat portion (guide) 521 that matches the positioning structure 151 of the multicore fiber 510 is formed. When the multi-core fiber 510 is installed in the guide groove 511 of the guide member 410 having such a cross-sectional structure, simultaneously, the rotation of the multi-core fiber 510 in the outer peripheral direction is also limited, and as a result, a plurality of cores arranged in a two-dimensional array. The alignment work between each other can be omitted. Further, when an optical connector is configured using the multi-core fiber 510, a ferrule 310 as shown in FIG. 7A is applied. A flat portion (guide) 531 matching the positioning structure 151 is provided on the inner wall of the through-hole of the ferrule 310 (a tip portion including the end face of the multicore fiber 510 is inserted), and the tip portion of the multicore fiber 510 is provided. Is inserted into the ferrule 310, and the positioning of the multi-core fiber 510 with respect to the ferrule 310 is completed. A positioning structure 541 for contributing to positioning with the sleeve may be provided on the outer peripheral surface of the ferrule 310.

  FIG. 5B shows a cross-sectional structure of the multi-core fiber 520 to which the positioning structure 152 according to the second modification is applied. That is, the positioning structure 152 of the multi-core fiber 520 is defined by the outer peripheral shape of the multi-core fiber 520 configured by a concave shape (triangular cross-sectional shape) in which at least a part protrudes toward the center of the cross section in the cross section. . The guide member 420 on which the multi-core fiber 520 provided with such a positioning structure 152 is installed has a cross-sectional structure as shown in FIG. That is, the guide groove 512 in which the multicore fiber 520 is installed is formed with a guide 522 having a triangular cross-sectional shape that matches the positioning structure 152 of the multicore fiber 520. When the multi-core fiber 520 is installed in the guide groove 512 of the guide member 420 having such a cross-sectional structure, simultaneously, the rotation of the multi-core fiber 520 in the outer circumferential direction is also restricted, and as a result, a plurality of cores arranged two-dimensionally. The alignment work between each other can be omitted. Further, when an optical connector is configured using the multi-core fiber 520, a ferrule 320 as shown in FIG. 7B is applied. A guide 532 having a triangular cross-sectional shape matching the positioning structure 152 is provided on the inner wall of the through-hole of the ferrule 320 (a tip portion including the end face of the multi-core fiber 520 is inserted), and the tip of the multi-core fiber 520 is provided. At the same time that the portion is inserted into the ferrule 320, the positioning of the multi-core fiber 520 with respect to the ferrule 320 is completed. A positioning structure 542 for contributing to positioning with the sleeve may be provided on the outer peripheral surface of the ferrule 320.

  FIG. 5C shows a cross-sectional structure of the multi-core fiber 530 to which the positioning structure 153 according to the third modification is applied. That is, the positioning structure 153 of the multi-core fiber 530 is defined by the outer peripheral shape of the multi-core fiber 530 configured by a concave shape (square cross-sectional shape) in which at least a part protrudes toward the center of the cross section in the cross section. . The guide member 430 on which the multi-core fiber 530 having such a positioning structure 153 is installed has a cross-sectional structure as shown in FIG. That is, a guide groove 513 in which the multicore fiber 530 is installed is formed with a guide 523 having a square cross-sectional shape that matches the positioning structure 153 of the multicore fiber 530. When the multi-core fiber 530 is installed in the guide groove 513 of the guide member 430 having such a cross-sectional structure, rotation of the multi-core fiber 530 in the outer circumferential direction is also restricted at the same time. As a result, a plurality of cores arranged two-dimensionally with each other The alignment work between each other can be omitted. Further, when an optical connector is configured using the multi-core fiber 530, a ferrule 330 as shown in FIG. 7C is applied. On the inner wall of the through hole of the ferrule 330 (where the tip portion including the end face of the multi-core fiber 530 is inserted), a guide 533 having a quadrangular cross-sectional shape that matches the positioning structure 153 is provided, and the tip of the multi-core fiber 530 At the same time that the portion is inserted into the ferrule 330, the positioning of the multi-core fiber 530 with respect to the ferrule 330 is completed. A positioning structure 543 for contributing to positioning with the sleeve may be provided on the outer peripheral surface of the ferrule 330.

  FIG. 5D shows a cross-sectional structure of a multi-core fiber 540 to which the positioning structure 154 according to the fourth modification is applied. That is, the positioning structure 154 of the multi-core fiber 540 has an outer peripheral shape of the multi-core fiber 540 configured by a convex shape (triangular cross-sectional shape) in which at least a part of the positioning structure 154 protrudes from the center of the cross-section toward the outer peripheral direction. It is prescribed. The guide member 440 on which the multi-core fiber 540 including the positioning structure 154 is installed has a cross-sectional structure as shown in FIG. That is, a guide groove 514 in which the multi-core fiber 540 is installed is formed with a guide 524 having a triangular cross-sectional shape that matches the positioning structure 154 of the multi-core fiber 540. When the multi-core fiber 540 is installed in the guide groove 514 of the guide member 440 having such a cross-sectional structure, the rotation of the multi-core fiber 540 in the outer circumferential direction is restricted at the same time. As a result, a plurality of cores arranged two-dimensionally with each other The alignment work between each other can be omitted. Further, when an optical connector is configured using the multi-core fiber 540, a ferrule 340 as shown in FIG. 7D is applied. A guide 534 having a triangular cross-sectional shape matching the positioning structure 154 is provided on the inner wall of the through-hole of the ferrule 340 (a tip portion including the end face of the multi-core fiber 540 is inserted), and the tip of the multi-core fiber 540 is provided. At the same time that the portion is inserted into the ferrule 340, the positioning of the multi-core fiber 540 with respect to the ferrule 340 is completed. In addition, a positioning structure 544 for contributing to positioning with the sleeve may be provided on the outer peripheral surface of the ferrule 340.

  FIG. 5E shows a cross-sectional structure of a multi-core fiber 550 to which the positioning structure 155 according to the fifth modification is applied. That is, the positioning structure 155 of the multi-core fiber 550 has an outer peripheral shape of the multi-core fiber 550 that is configured by a convex (rectangular cross-sectional shape) shape in which at least a part protrudes from the center of the cross-section toward the outer peripheral direction. It is prescribed. The guide member 450 on which the multi-core fiber 550 having such a positioning structure 155 is installed has a cross-sectional structure as shown in FIG. That is, the guide groove 515 in which the multi-core fiber 550 is installed is formed with a guide 525 having a square cross-sectional shape that matches the positioning structure 155 of the multi-core fiber 550. When the multi-core fiber 550 is installed in the guide groove 515 of the guide member 450 having such a cross-sectional structure, rotation of the multi-core fiber 550 in the outer circumferential direction is also restricted at the same time. As a result, a plurality of cores arranged two-dimensionally with each other The alignment work between each other can be omitted. Further, when an optical connector is configured using the multi-core fiber 550, a ferrule 350 as shown in FIG. 7E is applied. On the inner wall of the through hole of the ferrule 350 (where the tip portion including the end face of the multi-core fiber 550 is inserted), a guide 535 having a square cross-sectional shape that matches the positioning structure 155 is provided, and the tip of the multi-core fiber 550 At the same time that the portion is inserted into the ferrule 350, the positioning of the multi-core fiber 550 with respect to the ferrule 350 is completed. In addition, a positioning structure 545 for contributing to positioning with the sleeve may be provided on the outer peripheral surface of the ferrule 350.

  Further, FIG. 5F shows a cross-sectional structure of a multi-core fiber 560 to which the positioning structure 156 according to the sixth modification is applied. That is, the positioning structure 156 of the multi-core fiber 560 is a guide hole extending along the predetermined axis AX from the end face of the multi-core fiber 560, and the cross-sectional shape on the end face is shaped to be astigmatic. The multi-core fibers 560 having such a positioning structure 156 are connected to each other through the guide pins 600 as shown in FIG. That is, the guide pin 600 has a cross-sectional shape that matches the positioning structure 156, and one end of the guide pin 600 is inserted into the positioning structure 156a formed on the end surface of one multi-core fiber 560a. The other end of the guide pin 600 is inserted into a positioning structure 156b formed on the end surface of the other multi-core fiber 560b. As described above, the multi-core fibers 560a and 560b abut each other on the end faces via the guide pins 600, so that the multi-core fibers 560a and 560b are also restricted from rotating in the outer circumferential direction. The alignment work between the plurality of cores thus made can be omitted.

  In addition, the positioning structure applied to the multi-core fiber according to the present invention is not limited to the shape as described above, and is not particularly limited as long as it can mechanically limit the rotation of the multi-core fiber in the outer circumferential direction. .

  The multi-core fiber according to the present invention can be applied to an optical transmission line of an optical communication system configured by various network resources.

  110 ... Core, 120 ... Cladding, 150 to 156 ... Positioning structure, 300, 300a, 300b, 310 to 350 ... Ferrule, 400, 400a, 400b, 410 to 450 ... Guide member, 500, 500a, 500b, 510 to 560, 560a, 560b ... multi-core fiber.

Claims (8)

A plurality of cores each extending along a predetermined axis and functioning as optical waveguides optically independent from each other;
A cladding that integrally covers the plurality of cores and that holds the arrangement state of the plurality of cores in a cross section orthogonal to the predetermined axis;
A multi-core fiber comprising: a positioning structure for limiting rotation of the core array defined on the cross-section, the rotation being about the predetermined axis with respect to a connection target. 2. The multi-core fiber according to claim 1, wherein the positioning structure includes an outer peripheral shape of the multi-core fiber shaped asymmetry in the cross section. The multi-core fiber according to claim 2, wherein the positioning structure includes an outer peripheral shape of the multi-core fiber at least part of which is configured by a straight line in the cross section. 3. The multi-core fiber according to claim 2, wherein the positioning structure includes an outer peripheral shape of the multi-core fiber configured by a concave shape in which at least a part protrudes toward the center of the cross-section in the cross-section. 3. The multi-core according to claim 2, wherein the positioning structure includes an outer peripheral shape of the multi-core fiber formed by a convex shape in which at least a part of the positioning structure protrudes from the center of the cross-section toward the outer peripheral direction. fiber. The positioning structure includes a hole that extends from the end face of the multi-core fiber along the predetermined axis and has a cross-sectional shape on the end face that is shaped asymmetrically. The multi-core fiber according to 1. The multi-core fiber according to any one of claims 1 to 5,
A ferrule attached to a tip portion including an end face of the multi-core fiber, the ferrule having a through-hole that houses the tip portion, and rotation of the multi-core fiber around the predetermined axis with respect to the ferrule, An optical connector comprising: a ferrule provided with an auxiliary structure in the through hole for cooperating and limiting. 8. The optical connector according to claim 7, wherein a positioning structure for limiting rotation of the ferrule about the predetermined axis with respect to a connection target is formed on an outer peripheral surface.

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