An optical connecting device includes: a holder part having first and second holder members and a resin body therebetween; and multiple optical fibers each having first and second resin-uncoated fiber portions and the first and second resin-coated fiber portions. The first resin-uncoated fiber portion is disposed between first portions of the first and second holder members so as to extend in a direction of a first axis and be arranged along a first reference plane. The second resin-uncoated fiber portion and the first resin-coated fiber portion extend between second portions of the first and second holder members. One of the first and second holder members has a through-hole, extending along a second axis intersecting the first axis in the second portions thereof, receiving the resin body. The first and second holder members have first and second inner faces, separated away from the first reference plane, in the second portions, respectively.

The invention relates to an optical fiber mounted photonic integrated circuit device, wherein the tolerance for positioning in terms of the coupling between the single mode optical fibers and the optical waveguides provided on the photonic integrated circuit device is increased. An optical waveguide core group is provided in such a manner where a plurality of optical waveguide cores having a portion that is tapered in the direction of the width within a plane are aligned parallel to each other at intervals that allow for mutual directional coupling and that are narrower than the width of the core of the single mode optical fiber, and the inclined connection end surface of the single mode optical fiber and the upper surface of an end portion of the optical waveguide cores face each other for coupling.

A recessed portion in a semiconductor substrate and a method of forming the same are provided. The method comprises: forming a mask on the semiconductor substrate; forming a protection layer on a top surface of the mask and on at least one sidewall of the mask, and on at least one surface of the semiconductor substrate exposed by the mask; performing a first etching process to remove the protection layer on the top surface of the mask and on a bottom surface of the semiconductor substrate exposed by the mask; and performing a second etching process to remove the remaining protection layer and to etch the semiconductor substrate to form the recessed portion. In this way, a recessed portion with relatively smooth and vertical sidewalls can be realized.

An optical connector includes: an optical fiber; a ferrule provided at an end of the optical fiber, through which a core wire of the optical fiber is inserted; a housing 9 configured to accommodate the ferrule; a fiber end face provided in the core wire of the optical fiber, located inside the ferrule from an end face of the ferrule in a state where the core wire is inserted through the ferrule; and a fixing means provided between an outer periphery of the core wire and an inner periphery of the ferrule, the fixing means configured to fix the core wire of the optical fiber to the ferrule and to fix a position of the fiber end face.

A robot includes: a first arm that has a first light guide path, a second arm that has a second light guide path, a joint portion that has a rotation axis and connects the first arm and the second arm to each other so as to be rotatable about the rotation axis and a light rotary joint that is provided between the first light guide path and the second light guide path inside the joint portion and that optically connects the first light guide path and the second light guide path to each other. In addition, the light rotary joint has a first light guide portion which is fixed to the first light guide path and has a tubular shape about the rotation axis and an end portion of the second light guide path on the light rotary joint side faces the first light guide portion.

An optical module package has a first case, a second case and a fiber unit. The first case has a case bottom-part formed along the length direction of the fiber unit, a bottom convex-part formed on the case bottom-part so as to project toward inside direction of the first case and an elastic support part made of elastic member and covering the bottom convex-part. The optical waveguide device is supported by the elastic support part and the optical fiber is arranged at the distant position from the elastic support part.

Light is directed from a light source at a coupling surface of a slider into a delivery waveguide of the slider. The delivery waveguide couples a first portion of the light into a near-field transducer at a media-facing surface. A second portion of the light is coupled into a splitter waveguide. The second portion of light is detected to perform an active alignment of the light source on the slider.

A cable marking clip for securing to a connector of a cable such that axial movement of the cable marking clip relative to the connector is prevented includes an outer portion; and an inner portion attached to the outer portion at an end. The outer portion is configured to engage a connector having strain relief grooves and the inner portion is configured to be received radially between the connector and a cable so as to prevent axial movement of the cable marking clip relative to connectors with and without strain relief grooves.

A robot includes: a first arm that has a first light guide path, a second arm that has a second light guide path, a joint portion that has a rotation axis and connects the first arm and the second arm to each other so as to be rotatable about the rotation axis and a light rotary joint that is provided between the first light guide path and the second light guide path inside the joint portion and that optically connects the first light guide path and the second light guide path to each other. In addition, the light rotary joint has a first light guide portion which is fixed to the first light guide path and has a tubular shape about the rotation axis and an end portion of the second light guide path on the light rotary joint side faces the first light guide portion.

An optical connector includes: an optical fiber arranged along an optical axis; a light guide member having a first end face and a second end face and configured to guide a laser beam from the first end face to the second end face, the laser beam emitted along the optical axis from a light source entering the first end face, and the second end face being joined to an incident end face of the optical fiber; and a window member arranged between the light source and the light guide member and configured to guide, to the first end face of the light guide member, the laser beam emitted from the light source. The window member has a first transmission face and a second transmission face, the laser beam emitted from the light source entering the first transmission face, and the second transmission face being configured to emit the laser beam.