An optical element device includes an opto-electric hybrid board sequentially including an optical waveguide having a mirror, and an electric circuit board having a terminal in a thickness direction, and an optical element optically connected to the mirror and electrically connected to the terminal. The opto-electric hybrid board includes a mounting region including the mirror and the terminal when projected in the thickness direction and mounted with the optical element. Furthermore, the opto-electric hybrid board includes an alignment mark for aligning the optical element with respect to the mirror. The alignment mark is made of a material for forming the optical waveguide, and disposed at both outer sides of the mounting region in a width direction.

An optical receptacle includes: an optical receptacle body; two supporters which are connected to a respective end of the optical receptacle body, wherein each supporter is connected to one end of the optical receptacle body at a central portion of the respective supporter, and the two supporters face each other with a space therebetween; and four adhesive reservoirs which are disposed at respective four corners of the optical receptacle in plan view, wherein each of the adhesive reservoirs is a through hole or a recess, and the through hole or the recess is surrounded circumferentially by the supporter. The optical receptacle body and the two supporters together have a plane symmetrical shape with respect to a plane parallel to an optical axis of the light emitted from each of the second optical surfaces. The four adhesive reservoirs are disposed plane symmetrically with respect to the plane.

The present disclosure generally relates to printed circuit boards or printed circuit board assemblies for fiber optic communications. In one example, an optoelectronic assembly may include a printed circuit board including a laser-roughened area, at least one optoelectronic component coupled to a surface of the printed circuit board, and an optical component attached to the printed circuit board. The coupling area may be defined by the optical component contacting the printed circuit board, and the laser-roughened area may be positioned entirely within the coupling area defined by the optical component contacting the printed circuit board.

Techniques and mechanisms for facilitating horizontal communication with a photonic integrated circuit (PIC) chip, and a lens structure which is optically coupled thereto. In an embodiment, a PIC chip comprises integrated circuitry, photonic waveguides, and integrated edge-oriented couplers (IECs) which are coupled to the integrated circuitry via the photonic waveguides. The PIC chip forms respective first divergent lens surfaces of the IECs, which are each at a respective terminus of a corresponding one of the photonic waveguides. A lens structure, which is adjacent to the IECs, comprises a second divergent lens surface having an orientation which is substantially orthogonal to the respective orientations of the first divergent lens surfaces. In another embodiment, an edge of the PIC chip forms one or more recess structures, and the lens structure comprises one or more tenon portions which each extends into a respective recess structure of the one or more recess structures.

An optical package comprising an optical die that is electrically coupled to a package substrate, and an optical interconnect adjacent the optical die. The optical interconnect comprises a first polarizing filter adjacent to a first lens, a second polarizing filter adjacent to a second lens; and a film comprising a magnetic material between the first polarizing filter and the second polarizing filter. The second polarizing filter is rotated with respect to the first polarizing filter and the magnetic material is to rotate a polarization vector of light incoming to the optical interconnect. An optical fiber interface port is immediately adjacent to the first lens. The second lens is immediately adjacent to an optical interface of the optical die.

The present disclosure discloses an optical module including a circuit board and a light-emitting assembly. In the light-emitting assembly, a wavelength tuning mechanism is formed of a semiconductor optical amplification chip, a silicon optical chip and a semiconductor refrigerator. The semiconductor optical amplification chip may provide a plurality of wavelengths, and a wavelength selection is carried out by an optical filter in the silicon optical chip; a temperature adjustment for the optical filter is achieved by the semiconductor refrigerator, so as to further adjust a performance of the filter for wavelength selection. The above device is provided in a housing to facilitate packaging of the devices.

Disclosed is a micro-optical interconnect component including an optical platform including, arranged onto a substrate, at least one optical alignment structure fixing an optical component and/or arranged as alignment structure to adapt another interconnect component. The optical platform includes a light deflecting element, having a total volume of less than 1 mm3, and made of a material having a refractive index higher than 1. The light deflecting element includes a face, facing the optical alignment structure, and has a curved reflecting surface so that an incident light beam onto the first face is deflected by an angle between 60° and 120°, the incident light beam may be provided from the outside or the inside of the substrate. Also disclosed are optical devices including at least one optical interconnect component and to optical systems including at least one optical device, as well as a batch fabrication process of the optical interconnect component

An optoelectronic device. The device comprising: a silicon-on-insulator, SOI, wafer, the SOI wafer including a cavity and an input waveguide, the input waveguide being optically coupled into the cavity; and a mirror, located within the cavity and bonded to a bed thereof, the mirror including a reflector configured to reflect light received from the input waveguide in the SOI wafer.

An apparatus arranged for deflecting an optical component for alignment purposes of the optical component with a further optical component, wherein the apparatus comprises a plurality of adjacently placed elongate carriers, extending mutually parallel to each other in a longitudinal direction, wherein two adjacently placed elongate carriers have a spacing between them for receiving a first optical component such that the received optical component rests against two adjacently placed elongate carriers, wherein the two elongate carriers have slopes such that the spacing between the two adjacently placed elongate carriers is smaller at a bottom side compared to the spacing at a top side of the carriers, wherein the carriers comprise piezoelectric material configured to deflect the carriers in a direction perpendicular to the longitudinal direction by actuating the piezoelectric material.

An optical receptacle includes an optical receptacle main body and a cylindrical fixing member. The optical receptacle main body includes a first optical surface, a second optical surface, and an annular groove disposed to surround a first central axis of the first optical surface or disposed to surround a second central axis of the second optical surface. The fixing member is configured with a material with a smaller linear expansion coefficient than that of the optical receptacle main body, and is fit to the groove so as to be in contact with at least a part of an inner surface of the groove.