A novel method and interface are provided to generalize power delivery (PD) solutions and allow OEMs and suppliers to easily replace PD solutions using the same design and layout without having to re-spin the motherboard. This is achieved by defining a new interface and ball-out which support dual port PD solution that meet the system requirements. The embodiments employ an interposer to unify different PD solutions. The interposer is part of a unique Land Grid Array (LGA) soldered down solution with pre-defined interface employing a generic pinout to support PD solutions for dual type-C ports from different vendors. The interposer includes an LGA having a pattern of pads that is coupled to a LGA on a platform PCB with a matching pattern.

An electronic device in provided, including an antenna using a horn structure capable of using at least a portion of a metal member as a signal waveguide structure of the antenna. The device includes a housing, a display, a printed circuit board, and at least one wireless communication circuit, where a waveguide hole is provided to connect at least a portion of a through hole and an electronic component and is used as an operating channel of the electronic component together with the waveguide hole.

An optical sensor according to an embodiment of the present disclosure includes a light emitting substrate and a circuit board. The light emitting substrate includes a light emitting device. The circuit board is provided at a position opposing the light emitting device. The circuit board includes a light transmitting section and one or multiple light receiving devices. The light transmitting section transmits light of the light emitting device. The one or multiple light receiving devices receive light reflected by a reflective layer of the light of the light emitting device exiting through the light transmitting section. For example, the one or multiple light receiving devices are formed on a first major surface of the circuit board. For example, the light emitting substrate is disposed at a position opposing a second major surface, of the circuit board, on an opposite side to the first major surface, and is stacked on the circuit board with a first bump interposed therebetween.

An electronic device is provided. The electronic device includes a housing, a first printed circuit board disposed in the inner space of the housing, a second printed circuit board disposed so as to overlap at least a portion of the first printed circuit board, when the first printed circuit board is viewed from above, a first interposer disposed between the first printed circuit board and the second printed circuit board, and electrically connecting the first printed circuit board and the second printed circuit board, and at least one second interposer which is disposed between the first printed circuit board and the second printed circuit board so as to be spaced apart from the first interposer when the first printed circuit board is viewed from above, and which electrically connects the first printed circuit board and the second printed circuit board.

A video transcoding card includes a first transcoding assembly and a second transcoding assembly. The first transcoding assembly includes a first circuit board, first transcoding boards, and a first main electrical connector. The first transcoding boards and the first main electrical connector are disposed on the first circuit board and are electrically connected to the first circuit board. The second transcoding assembly includes a second circuit board, second transcoding boards and a second main electrical connector. The second transcoding boards and the second main electrical connector are disposed on the second circuit board and are electrically connected to the second circuit board. The first main electrical connector and the second main electrical connector are connected to each other, and the second transcoding boards are electrically connected to the first circuit board via the second circuit board, the second main electrical connector, and the first main electrical connector.

Various embodiments disclosed relate to LiDAR systems. The present disclosure includes a method and assemblies for connection photonics modules to LiDAR systems. In an example, a connection assembly can include a system board, a flex printed circuit board (PCB) connected to the system board through an interface, a photonics integrated circuit die mounted on a first side of the flex PCB and an electronic integrated circuit die mounted on a second side of the flex PCB, opposite the first side.

Provided is a MOSFET device for use with a printed circuit board (PCB) of a battery management system (BMS), the device including a semiconductor body; a metal conductor extending outwardly from a side of the semiconductor body; a plurality of power pins extending outwardly from at least one side of the semiconductor body, the power pins having tips bent downwardly; a gate pin extending outwardly from at least one side of the semiconductor body, wherein the tip of the gate pin is raised or elevated relative to the tips of the power pins so as to avoid electrical contact with the one of the spaced apart copper plates, and wherein the tip of the gate pin is connected to a circuit of the battery management system (BMS).

A memory module operation system for operating in high stress environments with strong vibration. The application and use of a retainer to reduce and dampen the effects of system vibration and the application of dynamic loads can retain a memory module in place in a memory socket. Further, the retainer can operate to reduce the effects of electromagnetic interference and can act as a heat transport system to reduce thermal stress on components.

A multilayer substrate includes a pair of first capacitor electrodes, a pair of second capacitor electrodes, and a dielectric substrate. Electrodes of the pair of first capacitor electrodes are disposed in dielectric substrate so as to face each other in a thickness direction of the dielectric substrate. Electrodes of the pair of second capacitor electrodes are disposed in the dielectric substrate so as to face each other in the thickness direction. A first element and a second element that are disposed in or on the dielectric substrate, and the pair of second capacitor electrodes, the pair of first capacitor electrodes, and a ground electrode that are disposed in the dielectric substrate are arranged in the stated order in the thickness direction. The pair of second capacitor electrodes at least partially overlaps the pair of first capacitor electrodes when viewed in plan in the thickness direction.

The disclosure provides a power supply module, including: a pin; a magnetic core including: a first and second magnetic plate arranged in parallel; a first upper wiring layer; a first middle wiring layer; a first lower wiring layer, wherein at least a part of the first upper wiring layer and the first middle wiring layer are connected to form a first winding surrounding the first magnetic plate, at least a part of the first lower wiring layer and the first middle wiring layer are connected to form a second winding surrounding the second magnetic plate. The magnetic core, the first and second winding form a magnetic element electrically connected to a switch. A magnetic loop surrounds a first axis, the first winding surrounds a second axis, the second winding surrounds a third axis, the first, second and third axis are parallel to a plane where the pin is located.