A system includes an enclosure having an air inlet end and an air outlet end, air movers positioned near the air outlet end, a first data connector positioned near the air outlet end between the air movers, a heat-generating electrical component positioned immediately between the data connector and the air inlet end, a first heat sink positioned immediately between at least one of the air movers and the air inlet end, and a first conductive pipe thermally coupled between the heat-generating electrical component and the first heat sink.

A security device in an electronic device which protects against unauthorized disassembly includes light sources, a plurality of photosensitive elements, a detection unit, a storage unit, a processor, and light guiding devices. Light conducting channels are provided between the light sources and the induction elements. Barrier objects that block light are installed at certain first light guiding channels of the light guiding channels, and are removed from the first light conducting channels when the electronic device is disassembled, so that induction signals output by the photosensitive elements are changed from the model or original digitally-recorded signals.

Fabric may include one or more conductive strands. An insertion tool may insert an electrical component into the fabric during formation of the fabric. The electrical component may include an electrical device mounted to a substrate and encapsulated by a protective structure. An interconnect structure such as a metal via or printed circuit layers may pass through an opening in the protective structure and may be used to couple a conductive strand to a contact pad on the substrate. The protective structure may be transparent or may include an opening so that light can be detected by or emitted from an optical device on the substrate. The protective structure may be formed using a molding tool that provides the protective structure with grooves or may be molded around a hollow conductive structure to create grooves. An electrical component mounted to the fabric may be embedded within printed circuit layers.

An opto-electric hybrid board that achieves sufficiently lower noise for signal transmission, is less prone to cause warpage during the mounting of various elements, and has high-speed communication properties, an opto-electric hybrid board α including: an electric circuit board 1; an optical waveguide 2 formed in a stacked manner on a first surface 1a of the electric circuit board 1; and a reinforcement plate 3 for reinforcing the electric circuit board 1, wherein a surface of the optical waveguide 2 on the opposite side from a surface thereof contacting the first surface 1a of the electric circuit board 1 is covered with the reinforcement plate 3.

In an electronic device, at least a portion of a camera cover member is disposed inside a housing. The camera cover member includes a through-hole in fluid communication with the outside of the housing, and is formed to support a camera module disposed inside the housing. A microphone module is disposed inside the housing so as to be adjacent to the camera module, and includes a first circuit board disposed on the camera cover member and a microphone disposed on the first circuit board. A second circuit board is disposed to face the camera cover member with the microphone module therebetween, and includes a contact structure in contact with the first circuit board. The contact structure is configured to electrically connect the first circuit board to the second circuit board and can be disposed between the first circuit board and the second circuit board to surround the microphone.

An electronic device comprises an electro-optical circuit package including at least photonic integrated circuit (PIC) having at least one light source and a package substrate; a printed circuit (PCB) including at least one optical connector to receive light from the at least one light source; and multiple liquid metal electrical contacts disposed between the package substrate and the PCB.

Provided are an optical sensor device using surface acoustic waves and an optical sensor device package. The optical sensor device includes: a substrate including a first light sensing area and a temperature sensing area and including a piezo electric material; a first input electrode and a first output electrode which are disposed in the first light sensing area and are apart from each other with a first delay gap therebetween; a first sensing film overlapping the first delay gap and configured to cover at least some portions of the first input electrode and the first output electrode; and a second input electrode and a second output electrode which are disposed in the temperature sensing area and are apart from each other with a second delay gap therebetween. The second delay gap is exposed to air.

In embodiments, an electronic device comprises a housing including a printed circuit board (PCB) in an inner space thereof; and a camera module assembly disposed in the inner space and including: a module housing; a first camera module having a first camera housing, the first camera module disposed in at least a part of the module housing and including a first flexible PCB (FPCB) drawn out of the module housing and connected to the PCB; and a second camera module having a second camera housing separate from the first camera housing, the second camera module disposed in the module housing to be adjacent to the first camera module and including a second FPCB drawn out of the module housing and electrically connected to the PCB, wherein the first and second FPCBs are overlapped at least in part with each other, when the module housing is viewed from above, and drawn to face a same direction.

For optical communications between semiconductor ICs, optical transceiver assembly subsystems may be integrated with a processor. The optical transceiver assembly subsystems may be monolithically integrated with processor ICs or they may be provided in separate optical transceiver ICs coupled to or attached to the processor ICs.

An electronic device includes a supporting board, an electrical board and electronic units. The supporting board includes a circuit layer. The electrical board has a board body, through holes through the board body, an electrical layer on the board body, and primary conductive elements respectively in the through holes. The board body has opposite first and second surfaces. The through holes communicate with the first surface and the second surface. The primary conductive elements electrically connect the electrical layer to the circuit layer. The electronic units are arranged on the first surface. Each electronic unit partially overlaps with one corresponding through hole in a projection direction of the electrical board. Each electronic unit has an electronic component and a secondary conductive element electrically connecting the electronic component to the electrical layer. The secondary conductive elements and the primary conductive elements are arranged in dislocation in the projection direction.