An optical subassembly includes a planar dielectric waveguide structure that is deposited at temperatures below 400 C. The waveguide provides low film stress and low optical signal loss. Optical and electrical devices mounted onto the subassembly are aligned to planar optical waveguides using alignment marks and stops. Optical signals are delivered to the submount assembly via optical fibers. The dielectric stack structure used to fabricate the waveguide provides cavity walls that produce a cavity, within which optical, optoelectronic, and electronic devices can be mounted. The dielectric stack is deposited on an interconnect layer on a substrate, and the intermetal dielectric can contain thermally conductive dielectric layers to provide pathways for heat dissipation from heat generating optoelectronic devices such as lasers.

This present disclosure seals the light propagation path in an optical interconnection element from external contaminants. The optical interconnection element includes a reflective surface, which can also be sealed from external contaminants Additional novel concepts include all enclosed sealed regions of the optical interconnection element being fluidly connected and making the final seal of the optical interconnection element with a thin plate, which can bend reducing the pressure differential between the ambient environment and the sealed internal volume of the optical interconnection element.

An IC device includes a heat spreader, an electronic component over the heat spreader, an optical component over the electronic component, a multilayer structure over the optical component, and a redistribution structure over the multilayer structure. The multilayer structure includes a waveguide optically coupled to the optical component. The redistribution structure is electrically coupled to the electronic component by vias through the optical component and the multilayer structure.

Provided is an opto-electric transmission composite module capable of efficiently dissipating heat of an opto-electric conversion portion,An which includes an opto-electric hybrid board configured to be optically and electrically connected to an opto-electric conversion portion and including an optical waveguide and an electric circuit board in order toward one side in a thickness direction; a printed wiring board electrically connected to the electric circuit board; a heat dissipating layer; and a casing made of metal, the casing accommodating the opto-electric hybrid board, the printed wiring board, and the heat dissipating member, the casing including a first wall are provided. The first wall, the heat dissipating layer, a portion of the printed wiring board, and the opto-electric hybrid board are disposed in order toward one side in the thickness direction. The heat dissipating layer is in contact with the first wall and the printed wiring board.

A silicon photonics optical transceiver device includes a silicon photonics optical module and a heat conducting housing that accommodates the silicon photonic optical module therein. The heat conducting housing has an inner surface formed with a first heat dissipation portion that wraps around and is in contact with transmitter optical sub-assemblies of the silicon photonics optical module to realize thermal conduction, and a second heat dissipation portion that is in contact with a digital signal processor of the silicon photonics optical module to realize thermal conduction.

An optical subassembly includes a planar dielectric waveguide structure that is deposited at temperatures below 400° C. The waveguide provides low film stress and low optical signal loss. Optical and electrical devices mounted onto the subassembly are aligned to planar optical waveguides using alignment marks and stops. Optical signals are delivered to the submount assembly via optical fibers. The dielectric stack structure used to fabricate the waveguide provides cavity walls that produce a cavity, within which optical, optoelectronic, and electronic devices can be mounted. The dielectric stack is deposited on an interconnect layer on a substrate, and the intermetal dielectric can contain thermally conductive dielectric layers to provide pathways for heat dissipation from heat generating optoelectronic devices such as lasers.

An integrated optical device includes: a mounting base; an optical semiconductor device which is provided on a surface of the mounting base; a substrate; and an optical waveguide which is provided on a surface of the substrate, wherein an incident surface of the optical waveguide is disposed to face an emission surface of the optical semiconductor device, wherein light emitted from the optical semiconductor device is able to be incident to the optical waveguide, wherein the optical semiconductor device is connected to the mounting base through a metal layer, wherein the mounting base is connected to the substrate through the other metal layer, and wherein a mounting base bottom surface on the side opposite to a surface of the mounting base and a substrate bottom surface on the side opposite to a surface of the substrate are provided on the substantially same plane.

An optical module is provided in the present disclosure. According to an embodiment, the optical module may comprise a housing, two or more circuit board layers, and a light emitting chip. The two or more circuit board layers may be disposed in the housing and electrically connected to each other; and the light emitting chip may be electrically connected to at least one of the circuit board layers.

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.

In one example embodiment, an optoelectronic assembly includes a multilayer ceramic substrate that includes multiple ceramic layers and a via disposed through at least one of the ceramic layers. The via may be formed from a conductive material that is configured to communicate a signal through the via. The multilayer ceramic substrate may be configured to dissipate heat emitted by an electronic component coupled to the multilayer ceramic substrate.