A plug connector is attachable with an optical fiber cable and is connectable with a receptacle connector. The receptacle connector comprises a receptacle shell. The plug connector comprises a front holder, a cable holding portion, a rear holder and a coupling member. The front holder is made of metal. The front holder is mated with the receptacle shell when the plug connector is connected with the receptacle connector. The cable holding portion is made of metal. The cable holding portion is configured to hold the optical fiber cable. The rear holder guards the cable holding portion. The rear holder comprises, at least in part, a thermal insulating portion made of non-metal material. The coupling member couples the front holder and the rear holder with each other. Each of the coupling member and the front holder is in contact with the rear holder only on the thermal insulating portion.

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 opto-electric hybrid board includes an optical waveguide, and an electric circuit board disposed on a one-side surface in the thickness direction of the optical waveguide. The electric circuit board includes a first terminal on which an optical element portion is mounted and a second terminal on which a driver element portion is mounted. The electric circuit board includes a metal supporting layer that overlaps the first terminal and the second terminal when the electric circuit board is projected in the thickness direction. The metal supporting layer has an opening portion that is located between the first terminal and the second terminal when the metal supporting layer is projected in the thickness direction.

An optical transceiver according to an embodiment includes: a housing having inner sides defining an inner space inside the housing; an optical module including a package, a semiconductor device, and a sleeve, the package being configured to house the semiconductor device, the semiconductor device generating a Joule heat, the sleeve being attached to an outside of the package, the sleeve being fixed to the housing with keeping the package away from the inner sides; a heat-conducting material filled between the package and one of the inner sides, the heat-conducting material including an oily component; and a sheet member being placed between the heat-conducting material and the package, the sheet member covering the heat-conducting material to prevent the oily component from reaching the optical module. The Joule heat is conducted from the package to the housing through the sheet member and the heat-conducting material.

A semiconductor photonic package can include a laser module and a photonic integrated circuit (PIC), each having a different operating temperature. The two modules are placed on a common substrate allowing accurate optical alignment. In addition, a thermal barrier is integrated into the substrate between the laser module and the PIC to provide thermal stability, especially to the laser module. The substrate can include a housing with good electrical conductivity or an optical substrate and housing. The thermal barrier is integrated into the optical substrate, the housing, or both. The thermal barrier in the optical substrate can be a cutout that does not divide the optical substrate into two separate pieces.

An electrical component assembly includes a substrate and first and second electrical components attached to the substrate and operably connected with each other via the substrate. In use the first electrical component generates a first amount of heat and the second component generates a second amount of heat. The first component is thermally connected with a heat sink along a first heat path and the second component is connected with the heat sink along a second, different, heat path, such that the thermal conductivity between the first and second components is lower than the thermal conductivity of the first heat path and of the second heat path.

An optical module includes a housing, a heat sink apparatus arranged in and thermally connected to the housing, and a printed circuit board partially arranged on the heat sink apparatus. The optical module further includes an optoelectronic chip arranged on the heat sink apparatus. The printed circuit board has a first surface, a second surface opposite to the first surface, and an opening that extends from the first surface to the second surface. The heat sink apparatus is connected to the second surface. The opening is located near a center of the printed circuit board. The optoelectronic chip is arranged in the opening.

A device may include a first substrate. The device may include an optical source. The optical source may generate light when a voltage or current is applied to the optical source. The optical source may be being provided on a first region of the first substrate. The device may include a second substrate. A second region of the second substrate may form a cavity with the first region of the first substrate. The optical source may extend into the cavity. The device may include an optical interconnect. The optical interconnect may be provided on or in the second substrate and outside the cavity. The optical interconnect may be configured to receive the light from the optical source.

The present disclosure is generally directed to techniques for thermal management within optical subassembly modules that include thermally coupling heat-generating components, such as laser assemblies, to a temperature control device, such as a thermoelectric cooler, without the necessity of disposing the heat-generating components within a hermetically-sealed housing. Accordingly, this arrangement provides a thermal communication path that extends from the heat-generating components, through the temperature control device, and ultimately to a heatsink component, such as a sidewall of a transceiver housing, without the thermal communication path extending through a hermetically-sealed housing/cavity.

An optical module includes a housing, a heat sink apparatus arranged in and thermally connected to the housing, and a printed circuit board partially arranged on the heat sink apparatus. The optical module further includes a first optoelectronic chip and a second optoelectronic chip that are both arranged on the heat sink apparatus. The first optoelectronic chip and second optoelectronic chip are both electrically connected to the printed circuit board. The printed circuit board has a first surface, a second surface opposite to the first surface, and an opening that extends from the first surface to the second surface. The second optoelectronic chip is arranged at the opening. The second optoelectronic chip is arranged separately from the first optoelectronic chip.