Multicore fiber, optical device, and multicore fiber assembly

1 - 15 . (canceled) 16 . A multi-core fiber having a first end surface and a second end surface, comprising: a cladding; and cores inside the cladding, wherein the cores extend in a first extending direction at the first end surface and extend in a second extending direction at the second end surface, the first end surface is inclined in an inclination direction that is not orthogonal to the first extending direction, the second end surface is inclined in an inclination direction that is not orthogonal to the second extending direction, and in a state of contact, where the first end surface is in contact with the second end surface such that an angle made by the first extending direction and the second extending direction is minimized, each of the cores at the first end surface at least partially overlaps one of the cores at the second end surface. 17 . The multi-core fiber according to claim 16 , wherein an inclination angle of the first end surface is equivalent to an inclination angle of the second end surface. 18 . The multi-core fiber according to claim 16 , wherein the cores at the first end surface and the cores at the second end surface are identifiable by core numbers, and in the contact state, the cores that at least partially overlap each other have the same core number. 19 . The multi-core fiber according to claim 16 , wherein the cores at the first end surface and the cores at the second end surface are identifiable by core numbers, and in the contact state, the cores that at least partially overlap each other have the same core number. 20 . The multi-core fiber according to claim 16 , wherein the cores at the first end surface and the cores at the second end surface are each arranged linearly symmetrically with respect to a virtual axis orthogonal to the inclination direction of the first end surface and the inclination direction of the second end surface. 21 . The multi-core fiber according to claim 20 , wherein the virtual axis does not cross any of the cores at the first end surface or at the second end surface. 22 . The multi-core fiber according to claim 20 , further comprising: a marker extending between the first end surface and the second end surface in the cladding, wherein at both the first end surface and the second end surface, a center of the marker is disposed between the virtual axis and a straight line passing through a center of one of the cores that is farthest from and parallel to the virtual axis. 23 . An optical device comprising: the multi-core fiber according to claim 16 ; and a single-core connector disposed at one end of the multi-core fiber. 24 . An optical device comprising: a multi-core fiber bundle constituted by multi core fibers, each of which is the multi-core fiber according to claim 16 ; and a multi-core connector disposed to one end of the multi-core fiber bundle or an integrated single-core connector group disposed to the one end, wherein each of the multi core fibers has a connector-side end surface of the first end surface and the second end surface disposed on a side of the multi-core connector or the integrated single-core connector group, and the multi-core fiber bundle is fixed to the multi-core connector or the integrated single-core connector group such that all of the connector-side end surfaces are inclined in an aligned direction. 25 . The optical device according to claim 24 , wherein each of the multi-core fibers is configured such that the cores at the connector-side end surface are identifiable by core numbers, and the multi-core fibers include two or more multi-core fibers in which the cores that at least partially overlap each other have the same core number as a result of subjecting the connector-side end surfaces of the multi-core fibers to translation and inversion. 26 . The optical device according to claim 25 , wherein the inversion is carried out with respect to a virtual axis parallel to or orthogonal to the aligned direction. 27 . The optical device according to claim 24 , wherein each of the multi-core fibers is configured such that the cores at the connector-side end surface are identifiable by core numbers, and the multi-core fibers include two or more multi-core fibers in which the cores that at least partially overlap each other have the same core number as a result of subjecting the connector-side end surfaces of the multi-core fibers to translation and rotation. 28 . The optical device according to claim 25 , wherein each of the multi-core fibers includes a marker extending between the first end surface and the second end surface inside the cladding, the multi-core fibers are constituted by: a first multi-core fiber group, wherein the connector-side end surfaces of two or more multi-core fibers of the first multi-core fiber group are aligned along a virtual axis orthogonal to the aligned direction and arranged on one side of the virtual axis; and a second multi-core fiber group, wherein the connector-side end surfaces of two or more multi-core fibers of the second multi-core fiber group are aligned along the virtual axis and arranged on the other side of the virtual axis, and at each of the connector-side end surfaces of the multi-core fibers, a distance from the marker to the virtual axis is shorter than distance from each of the cores to the virtual axis. 29 . An optical device comprising: a Fan-In/Fan-Out device including: an optical path conversion section; and the multi-core fiber recited in claim 23 or a multi-core fiber connected to the multi-core fiber recited in claim 23 . 30 . A multi-core fiber assembly comprising: a first multi-core fiber having a first end surface, including: a first cladding; and first cores inside the first cladding, wherein the first cores extend in a first extending direction at the first end surface, and the first end surface is inclined in an inclination direction that is not orthogonal to the first extending direction; and a second multi-core fiber having a second end surface, including: a second cladding; and second cores inside the second cladding, wherein the second cores extend in a second extending direction at the second end surface, and the second end surface is inclined in an inclination direction that is not orthogonal to the second extending direction, wherein when the first end surface contacts the second end surface such that an angle made by the first extending direction and the second extending direction is minimized, each of the first cores in the first end surface at least partially overlaps one of the second cores in the second end surface. 31 . A multi-core fiber having a first end surface and a second end surface, comprising: a cladding; and cores inside the cladding, wherein the cores extend in a first extending direction at the first end surface and extend in a second extending direction at the second end surface, the first end surface is inclined in an inclination direction that is not orthogonal to the first extending direction, the second end surface is inclined in an inclination direction that is not orthogonal to the second extending direction, and in a state of contact, where the first end surface is in contact with the second end surface such that an angle made by the first extending direction and the second extending direction is within a predetermined range, each of the cores at the first end surface at least partially overlaps one of the cores at the second end surface.