MULTICORE/MULTIMODE FIBER COUPLING DEVICE

Abstract

A device for coupling a multicore/multimode fiber that can transmit a large quantity of information. This multicore/multimode fiber coupling device has a first fiber group (11), a first light converging system (13), a first mode converter (15), a second fiber group (21), a second light converging system (23), and light converging system (33) for multicore fibers. By means of the first mode converter (15), light from the first fiber group (11) is subjected to mode conversion en masse. A space coupling system (33) for multicore fibers transmits light derived from the second fiber group (21) and light derived from the first fiber group (11) subjected to mode conversion to the multicore fibers (31).

Claims

1. A multi-core multi-mode fiber coupling device comprising: a first group (11) of fibers; a first light converging system (13) which converges a group of outgoing light beams from the first group (11) of fibers; a first mode converter (15) which converts a mode of the group of outgoing light beams from the first group (11) of fibers, which has been converged by the first light converging system (13), into a first mode; a second group (21) of fibers; a second light converging system (23) which converges a group of outgoing light beams from the second group (21) of fibers, and a spatial coupling system (33) for multi-core fiber which guides a group of outgoing light beams from the first mode converter (15) and a group of outgoing light beams from the second light converging system (23) into a multi-core fiber (31).

2. The multi-core multi-mode fiber coupling device according to claim 1, wherein the first mode converter (15) is a phase plate provided at a position in which a group of outgoing light beams from the first group (11) of fibers is allowed to coincide with each other by the first light converging system (13).

3. The multi-core multi-mode fiber coupling device according to claim 1, wherein the device further comprises: a third group (41) of fibers; a third light converging system (43) which converges a group of outgoing light beams from the third group (41) of fibers; and a third mode converter (45) which converts a mode into a second mode of the group of outgoing light beams from the third group (41) of fibers, which has been converged by means of the third light converging system (43), wherein the spatial coupling system (33) for multi-core fiber guides a group of outgoing light beams from the first mode converter (15), a group of outgoing light beams from the second light converging system (23), and a group of outgoing light beams from the third mode converter (45) into the multi-core fiber (31).

4. A multi-core multi-mode fiber coupling method comprising: a step in which a group of outgoing light beams is emitted from a first group (11) of fibers; a step in which the group of outgoing light beams from the first group (11) of fibers is converged by a first light converging system (13); a step in which the group of outgoing light beams from the first group (11) of fibers, which has been converged by means of the first light converging system (13), is subjected to mode conversion into a first mode by the first mode converter (15); a step in which a group of outgoing light beams is emitted from a second group (21) of fibers; a step in which the group of outgoing light beams from the second group (21) of fibers is converged by a second light converging system (23); and a step in which a group of outgoing light beams from the first mode converter (15) and a group of outgoing light beams from the second light converging system (23) are guided into a multi-core fiber (31) by a spatial coupling system (33) for multi-core fiber.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0019] FIG. 1 is a block diagram illustrating an example of the basic configuration of a multi-core multi-mode fiber coupling device.

[0020] FIG. 2 is a view for explaining an example of a mode converter.

[0021] FIG. 3 is a block diagram illustrating a preferred example of the multi-core multi-mode fiber coupling device.

DESCRIPTION OF EMBODIMENTS

[0022] Preferred embodiments for carrying out the present invention will now be described with reference to the attached drawings. It is to be noted that the present invention is not limited to embodiments described below, but may include an embodiment or embodiments which has or have been modified or changed as occasion demands within the scope that the person skilled in the art knows from the embodiments described below.

[0023] The present invention relates to a multi-core multi-mode fiber coupling device. The multi-core multi-mode fiber coupling device is configured to couple light beams from a plurality of light sources with a multi-core multi-mode fiber. Namely, such a device refers to a device adapted to guide light beams caused to be in a multi-mode including a plurality of higher order mode into respective cores of a multi-core fiber having a plurality of cores in a single optical fiber. There is no need for all cores included in the multi-core fiber to be used for optical information communication, but, e.g., any one of the central core and/or peripheral cores may be used for detection, and any feedback may be employed in advance as occasion demands.

[0024] FIG. 1 is a block diagram illustrating an example of the basic configuration of a multi-core multi-mode fiber coupling device of the present invention. As illustrated in FIG. 1, this device comprises first fiber group 11, first light converging system 13, first mode converter 15, second fiber group 21, second light converging system 23, and multi-core fiber spatial coupling system 33.

[0025] The first fiber group 11 refers to a group of two optical fibers or more which are provided at positions spatially away from each other. An example of the optical fibers constituting the first fiber group is a single mode fiber.

[0026] The first light converging system 13 is an optical system for converging a group of outgoing light beams from the first fiber group 11. An example of the first light converging system 13 is a prism or a mirror for guiding a plurality of outgoing light beams from the first fiber group 11 into the first mode converter 15 (e.g., phase plate). When the first light converging system 13 is a mirror, an optical path is adjusted so that light beams from a plurality of optical fibers existing spatially away from each other arrive at a predetermined position of a wavelength plate. In this way, a plurality of light beams from the first fiber group 11 are guided to a predetermined position of the first mode converter 15 by means of the first light converging system 13. However, in the case of an arrangement which can conduct a guide to a predetermined position of the first mode converter 15 without relying on the first light converging system 13, it is not necessarily required to use the first light converging system 13.

[0027] The first mode converter 15 is an optical device for converting the mode of a group of outgoing light beams from the first fiber group 11, which have been converged by means of the first light converging system 13, into the first mode. An example of the first mode converter 15 is a phase plate. It is preferable that the first mode converter 15 is a phase plate arranged in a position where the group of outgoing light beams from the first fiber group 11 coincide with each other by means of the first light converging system 13. In the first mode converter 15, light beams included in the group of outgoing light beams from the first fiber group 11 may be simultaneously subjected to mode conversion, thereby making it possible to easily attain the multi-core multi-mode fiber coupling.

[0028] The mode converter is known as disclosed in, e.g. the Japanese Patent Application Laid Open No. 2009-047784 publication, and the Japanese Patent Application Laid Open No. 2010-122688 publication. The mode converter can convert light beams of the base mode into light beams of any higher order mode. An output from the first fiber has ordinarily basic (base) mode (TEM.sub.00). Light beams of the basic mode are subjected to mode conversion as occasion demands at the first mode converter 15. An example of the mode after it has undergone mode conversion is a first order mode (TEM.sub.01 or TEM.sub.10). Any mode (e.g., TEM.sub.11 or TEM.sub.02) except for the above may be used. On the other hand, it is preferable that a group of outgoing light beams from the first mode converter 15, which arrives at a multi-core multi-mode fiber, are different in the mode from any other group of light beams.

[0029] For example, when three kinds of groups of light beams are input into the multi-core multi-mode fiber, it is preferable to employ three modes of the base mode (the case where, e.g. an output from the single mode fiber is not subjected to mode conversion), TEM.sub.01 and TEM.sub.10. Such modes are introduced into the multi-core multi-mode fiber, and any mode may be employed if it can be separated by using known means in a multi-core multi-mode fiber of the receiving side.

[0030] A preferred example of the multi-core multi-mode fiber coupling device is an example in which light beams are converged on a predetermined position of the first mode converter 15 by means of the first light converging system 13. FIG. 2 is a view for explaining an example of the mode converter. As illustrated in FIG. 2, this phase plate 16 indicates that there is a transparent medium having a specific refractive index in an adjacent intensity distribution in a spatial light in correspondence with the propagation mode within an optical fiber arranged, in order to allow a difference between phases of intensities adjacent in the spatial light in correspondence with the propagation mode within the optical fiber to be (180) to provide a physical optical path difference corresponding to a phase difference at that wavelength. In this drawing, since light beams 19, which are arranged so that they are uniformly irradiated onto respective thin and thick parts 17 and 18, have optical path lengths different from each other, mode conversion will be performed. The configuration of the mode converter is not limited to the configuration described above. However, with this method, the traveling direction of light beams in the base mode from the single mode fiber is adjusted by means of the optical system, thus making it possible to easily and simultaneously perform mode conversion of these plural light beams in the base mode.

[0031] Ordinarily, the multi-core fiber has a plurality of cores in positions symmetrical with respect to the central core. Moreover, the phase plate is such that the boundary between the thin part 17 and the thick part 18 linearly exists. In the present invention, light beams from the fiber, which have been once converged at this boundary, are guided into respective cores of the multi-core.

[0032] The second light converging system 23 is an optical system for converging a group of outgoing light beams from the second fiber group 21. In this example, such a second mode converter adapted to perform mode conversion of the mode of the group of outgoing light beams from the second fiber group 21, which have been converged by the second light converging system 23, is not indispensable. This is because it is sufficient that any light signal in the base mode is included in the multi-core multi-mode fiber. On the other hand, the mode of a group of outgoing light beams from the second fiber group 21, which have been converged by means of the second light converging system 23, may be subjected to mode change or conversion by means of the second mode converter.

[0033] The multi-core fiber spatial coupling system 33 is an optical system for guiding a group of outgoing light beams from the first mode converter 15 and a group of outgoing light beams from the second light converging system 23 into the multi-core fiber 31. The multi-core fiber spatial coupling system 33 guides respective plural light beams, which are included in the group of rays of outgoing light beams from the first mode converter 15 and the group of outgoing light beams from the second light converging system 23, into a corresponding one or ones of a plurality of cores of the multi-core multi-mode fiber. An example of such an optical system is an optical system in the multi-core fiber coupling device disclosed in the Japanese Patent Application Laid Open No. 2013-182222 publication.

[0034] An example of the multi-core fiber spatial coupling system 33 is configured to comprise, as illustrated in FIG. 1, a first relay lens to which a group of outgoing light beams from the first mode converter 15 are incident, and a beam splitter which guides light beams from the first relay lens and a group of outgoing light beams from the second light converging system 23 into the multi-core multi-mode fiber. An output from the beam splitter is propagated into the multi-mode fiber via a multi-mode fiber coupling lens, and respective ones of the group of light beams will be thus propagated into objective cores. The relay lens refers to a lens or a lens system for transmitting an image which has been formed at an optical system located forward towards further backward. Mismatch in size between a predetermined higher order mode in which multi light beams have been converted by the phase plate and the homogeneous mode in the fiber is optimized by means of the relay lens so that the maximum coupling efficiency can be provided.

[0035] As described above, light beams included in the group of outgoing light beams from the first fiber group 11 are simultaneously subjected to mode conversion at the first mode converter 15, thereby making it possible to easily attain multi-core multi-mode fiber coupling.

[0036] The light beams which have been emitted from the multi-core multi-mode fiber 31 are separated by a multi-core fiber coupling lens (multi-core fiber separation lens) 61 so that they are transmitted into a plurality of fibers 65 by means of an optical system 63.

[0037] The present invention also provides a multi-core multi-mode fiber coupling method using the above-described multi-core multi-mode fiber coupling device. This method comprises steps described below.

[0038] A group of outgoing light beams are emitted from the first fiber group 11. The group of outgoing light beams from the first fiber group 11 are converged by means of the first light converging system 13. The group of outgoing light beams from the first fiber group 11, which have been converged by means of the first light converging system 13, are subjected to mode conversion into the first mode by means of the first mode converter 15.

[0039] A group of outgoing light beams are emitted from the second fiber group 21. The group of outgoing light beams from the second fiber group 21 are converged by means of the second light converging system 23. The group of outgoing light beams from the first mode converter 15 and the group of outgoing light beams from the second light converging system 23 are guided into the multi-core fiber 31 by means of the multi-core fiber spatial coupling system 33.

[0040] FIG. 3 is a block diagram illustrating a preferred example of the multi-core multi-mode coupling device. The example illustrated in FIG. 3 further comprises, in addition to the components of the previously mentioned multi-core multi-mode coupling device, a third group of fibers 41 which will be hereinafter simply referred to as a third fiber group 41, a third light converging system 43 and a third mode converter 45. By using the same principle as described above, it is possible to guide a group of light beams having a larger number of modes into the multi-core multi-mode fiber. The third light converging system 43 is an optical system for converging a group of outgoing light beams from the third fiber group 41. The third mode converter 45 is an optical device for converting the mode into a second mode of a group of outgoing light beams from the third fiber group 41, which have been converged by means of the third light converging system 43. The third fiber group 41, the third light converging system 43 and the third mode converter 45 have configurations similar to those of the first fiber group 11, the first light converging system 13 and the first mode converter 15, respectively.

[0041] In the case of this example, the multi-core fiber spatial coupling system 33 guides a group of outgoing light beams from the first mode converter 15, a group of outgoing light beams from the second light converging system 23, and a group of outgoing light beams from the third mode converter 45 into the multi-core fiber 31.

[0042] The present invention also provides a multi-core multi-mode fiber coupling method using the above-described multi-core multi-mode fiber coupling device. This method comprises steps described below.

[0043] A group of outgoing light beams are emitted from the first fiber group 11. The group of outgoing light beams from the first fiber group 11 are converged by means of the first light converging system 13. The group of outgoing light beams from the first fiber group 11, which have been converged by means of the first light converging system 13, are subjected to mode conversion into the first mode by means of the first mode converter 15.

[0044] A group of outgoing light beams are emitted from the second fiber group 21. The group of outgoing light beams from the second fiber group 21 are converged by means of the second light converging system 23.

[0045] A group of outgoing light beams are emitted from the third fiber group 41. The group of outgoing light beams from the third fiber group 41 are converged by means of the third light converging system 43. The group of outgoing light beams from the third fiber group 41, which have been converged by means of the third light converging system 43, are subjected to mode conversion into the second mode (the third mode when light beams of the second fiber group have been subjected to mode conversion into the second mode) by means of the third mode converter 45. The group of outgoing light beams from the first mode converter 15, the group of outgoing light beams from the second light converging system 23 and the group of outgoing light beams from the third mode converter 45 are guided into the multi-core fiber 31 by means of the multi-core fiber spatial coupling system 33.

INDUSTRIAL APPLICABILITY

[0046] The present invention can be utilized in the field of the optical fiber communication using spatial division multiplexing and multi-core multi-mode fiber.

DESCRIPTION OF REFERENCE NUMERALS

[0047] 11 . . . First fiber group

[0048] 13 . . . First light converging system

[0049] 15 . . . First mode converter

[0050] 21 . . . Second fiber group

[0051] 23 . . . Second light converging system

[0052] 31 . . . Multi-core fiber

[0053] 33 . . . Multi-core fiber spatial coupling system

[0054] 41 . . . Third fiber group

[0055] 43 . . . Third light converging system

[0056] 45 . . . Third mode converter

[0057] 61 . . . Multi-core fiber coupling lens

[0058] 63 . . . Optical system

[0059] 65 . . . Fiber