An optical receptacle includes an optical component assembly, a tubular sleeve, and a tubular shell. The optical component assembly includes a light guide member, a tubular member, which retains the light guide member in the through hole, and projections, which extends outward of an outer peripheral surface of the tubular member at one end. The sleeve is fitted to the outer periphery of the light guide member at a rear end portion. The inside diameter of a front portion of the sleeve differs from that of the rear end portion. The shell covers the outer peripheral surface of the sleeve and includes a groove in a rear end portion. The groove extends in an axial direction and turns and extends in a circumferential direction. The groove is engaged with the projections of the tubular member to secure the shell. The shell and the sleeve are attachable and detachable.

An optical waveguide termination comprising a light-receiving inlet for receiving light to be terminated, a curved section extending from the inlet and having a continuously decreasing radius of curvature, and a light-terminating tip at an end of the curved section. The curved section may define a spiral waveguide, for example a logarithmic spiral, having a waveguide width that continuously decreases from the inlet to the tip.

One example includes an optical coupler. The optical coupler includes a waveguide formed in a first layer of a layered structure that is to propagate an optical signal. The waveguide includes an end portion. The optical coupler also includes a turning mirror that includes a bulk structure and a reflective material deposited on an angular face of the bulk structure to form a surface of the turning mirror. The bulk structure can have a greater cross-sectional size than a cross-sectional size of the waveguide, such that the angular face extends above the first layer of the layered structure and extends into a second layer of the layered structure below the first layer. The surface of the turning mirror can be arranged to reflect the optical signal that is provided from the end portion of the waveguide.

The objective of the present invention is to provide an optical modulator adapted for use with various modulating units and various modulation regions, and with which variability in optical losses is limited as far as possible. An optical modulator in which an optical waveguide and a control electrode for controlling an optical wave propagating through the optical waveguide are provided in a substrate, characterized in that: the optical waveguide is provided with a first branching portion which causes one input light beam to branch into two light beams; each of a first and a second modulating portion connected to two branched waveguides which branch at the first branching portion is provided with a structure in which one or more Mach-Zehnder type optical waveguides are combined; the control electrode comprises signal electrodes which apply modulated signals to the first and second modulating portions; input portions of all the signal electrodes are disposed on either the left or the right of the substrate relative to the direction in which the optical wave propagates; and in relation to output portions of the signal electrodes, the output portions of the signal electrodes led out from each modulating portion are disposed on the side on which the first or second modulating portions are disposed, relative to the direction in which the optical wave propagates.

The present disclosure provides a pitch reducing optical fiber array or a multicore fiber including at least one chiral fiber grating incorporated therein that is operable to couple the modes in different fiber cores within a spectral range determined in some instances by the helical pitch of the corresponding chiral fiber grating.

Periscope assemblies are provided which have a light path that travels in a first plane along the first waveguide, a second plane along the second waveguide that is parallel to the first plane, and along a third plane along the third waveguide that intersects the first plane and the second plane. In some examples the periscope assembly includes first and second carriers comprising respective first and second waveguides and defining respective first and second cavities in which a third carrier comprising a third waveguide is disposed and optionally includes an optical component. In some examples, the cavities are defined in one or more carriers on a mating surface, on a side opposite to the mating surface, or on a side perpendicular to a mating surface.

Periscope assemblies are provided which have a light path that travels in a first plane along the first waveguide, a second plane along the second waveguide that is parallel to the first plane, and along a third plane along the third waveguide that intersects the first plane and the second plane. In some examples the periscope assembly includes first and second carriers comprising respective first and second waveguides and defining respective first and second cavities in which a third carrier comprising a third waveguide is disposed and optionally includes an optical component. In some examples, the cavities are defined in one or more carriers on a mating surface, on a side opposite to the mating surface, or on a side perpendicular to a mating surface.

The invention relates to a lamp unit (1) for a headlight, in particular a motor vehicle headlight, the lamp unit (1) comprising multiple light sources (2), a light guide unit (3), and a downstream projector lens (4), the light guide unit (3) having multiple light guides (30), each light guide (30) having one light decoupling surface (30a) and one light coupling surface (30b), and each light source (2) coupling light exactly into a light guide (30) assigned to it through a light coupling surface (30b). The invention provides that the light sources (2) and the light coupling surfaces (30b) of the light guides (30) have light conducting rods (10) arranged between them, which are joined into at least one light conducting rod bundle (100), each light source (2) coupling light essentially exclusively into the light conducting rod coupling areas (10a) of the light conducting rods (10) assigned to the respective light source (2), the light of an assigned light source (2) that exits from the light conducting rod decoupling areas (10b) being coupled essentially exclusively into the light coupling surface (30b) of the light guide (30) assigned to the respective light source (2).

The utility model relates to the technical field of optical fiber cutting device, and particularly relates to a kind of multi-function cutting fixture which is used to fix the optical fiber in cutting process. The utility model of multi-function cutting fixture for the optical fiber cutting device includes the clamp body and the clamp cover. One side of the said clamp body is pivoted to the said clamp cover, and the other side of the said clamp body is clamping connected to the said clamp cover. The said clamp body is equipped at least with No.1 fiber placing groove, No.2 fiber placing groove and No.3 fiber placing groove. The said clamp cover is equipped with the elastomer that contacts with the said No.1 fiber placing groove, and No.1 contact structure that contacts with the said No.2 fiber placing groove. The said No.1 contact structure is equipped with a convex body that contacts with the said No.3 fiber placing groove. Compared with the prior art, the utility model of multi-function cutting fixture can hold a variety of types of optical fiber. When holding different types of optical fiber, we do not need to change the fixture. The work efficiency is improved greatly.

The utility model relates to the technical field of optical fiber cutting device, and particularly relates to a kind of multi-function cutting fixture which is used to fix the optical fiber in cutting process. The utility model of multi-function cutting fixture for the optical fiber cutting device includes the clamp body and the clamp cover. One side of the said clamp body is pivoted to the said clamp cover, and the other side of the said clamp body is clamping connected to the said clamp cover. The said clamp body is equipped at least with No.1 fiber placing groove, No.2 fiber placing groove and No.3 fiber placing groove. The said clamp cover is equipped with the elastomer that contacts with the said No.1 fiber placing groove, and No.1 contact structure that contacts with the said No.2 fiber placing groove. The said No.1 contact structure is equipped with a convex body that contacts with the said No.3 fiber placing groove. Compared with the prior art, the utility model of multi-function cutting fixture can hold a variety of types of optical fiber. When holding different types of optical fiber, we do not need to change the fixture. The work efficiency is improved greatly.