Provided is optical module as a photoelectric conversion module that includes a photoelectric hybrid board, a light-receiving/emitting element, a driving element, and a heat dissipating sheet. The light-receiving/emitting element and the driving element are mounted on one surface in a thickness direction of the photoelectric hybrid board. The heat dissipating sheet is in contact with the light-receiving/emitting element and the driving element from a side opposite to the photoelectric hybrid board. The driving element has a greater height above the photoelectric hybrid board than the light-receiving/emitting element.

A laser device has a plurality of laser diodes; a plurality of optical elements installed corresponding to the plurality of the laser diodes; a plurality of units formed by fixing the laser diodes and the optical elements per each laser diode and installed corresponding to the plurality of the laser diodes; a converging element that converges laser beams emitted from the plurality of the laser diodes to a fiber; a housing element houses the plurality of the units and the converging element; and a thermal transfer plate performs heat dissipation of the plurality of the units. The heat resistance reducing element having a heat resistance value that is smaller than a predetermined value is installed between the thermal transfer plate and each unit or the processing for reducing the heat resistance is performed.

A phase shifter includes a substrate layer, a cladding layer, and a waveguide. The phase shifter includes a waveguide and a heating element. The phase shifter includes a thermally conductive structure disposed on the cladding layer to disperse heat from the waveguide. The thermally conductive structure may include a metal strip disposed longitudinally along the beam, may include thermally conductive pads, and/or may include thermally conductive vias coupled between the cladding layer and the substrate layer. The phase shifter may be incorporated into light detection and ranging (LIDAR) devices, telecommunications devices, and/or computing devices.

An optical module includes: a first board having an optical component bonded thereto with an adhesive; a connection structure part rising from the first board and made of a material having lower thermal conductivity than thermal conductivity of a material of the first board; and a second board joined to the connection structure part.

An optical transceiver includes a housing, a heat source accommodated in the housing, and a heat spreader. The heat spreader includes a heat transfer portion accommodated in the housing and a heat dissipation portion exposed to outside. The heat spreader is in thermal contact with the heat source, and the heat dissipation portion of the heat spreader is in proximity of an optical port of the housing.

A connector has a case, a circuit board, and a thermal diffusing unit. The case has an inner surface. The circuit board is mounted in the case and has a heating source. The thermal diffusing unit abuts the inner surface of the case and the heating source of the circuit board. An area of the thermal diffusing unit abutting the inner surface is bigger than an area of the thermal diffusing unit abutting the heating source. A heat transfer coefficient of the thermal diffusing unit is bigger than a heat transfer coefficient of the case. With the structure above, the thermal diffusing unit is allowed to transmit heat from a small area to a big area, thereby improving the heat dissipation efficiency of the connector.

A multilayer PCB structure includes a core layer, a first layer on a first surface of the core layer, a second layer on a second surface of the core layer, and a thermally conductive material in the core layer. The first surface and the second surface of the core layer are opposite to each other, and a window is formed on the second layer by removing part of the second layer. The window of the second layer exposes part of the core layer below the thermally conductive material.

Electronic-photonic packages and related fabrication methods are described. A package may include a plurality of photonic integrated circuits (PICs), where each PIC comprises a photonic accelerator configured to perform matrix multiplication in the optical domain. The package may further include an application specific integrated circuit (ASIC) configured to control at least one of the photonic accelerators. The package further includes an interposer. The plurality of PICs are coupled to a first side of the interposer and the ASIC is coupled to a second side of the interposer opposite the first side. A first thermally conductive member in thermal contact with at least one of the PICs. The first thermally conductive member may include a heat spreader. A second thermally conductive member in thermal contact with the ASIC. The second thermally conductive member may include a lid. The first thermally conductive member faces the first side of the interposer, and the second thermally conductive member faces the second side of the interposer. In some embodiments, the interposer sits in part on a substrate and in part on the PICs.

This application provides a heat dissipation structure for an optical module and a communications device, and relates to the field of optical communications technologies. The heat dissipation structure for the optical module includes: a panel with a jack; a PCB board, disposed on one side of the panel, where the PCB board is configured to install the optical module; and a heat conduction module, configured to conduct, to the panel, heat emitted from the optical module, where one end of the heat conduction module is in contact with the optical module, and the other end of the heat conduction module is in contact with the panel. In the heat dissipation structure for the optical module and the communications device, the panel is mainly used to dissipate heat from the optical module.

An optical package includes a substrate made of a first material having an upper surface and a lower surface. The substrate further includes at least one cavity opening onto an upper surface of the substrate. Electrical connection vias extend through the substrate. An electronic integrated circuit chip is mounted on the upper surface of the substrate in a position so as to cover the at least one cavity. The electronic integrated circuit chip includes an integrated optical sensor. Each cavity is filled with a second material having a thermal conductivity greater than the thermal conductivity of the first material. The electrical connection vias are arranged on either side of each cavity and between two cavities.