An electronic device, comprising: a first functional board, a second functional board, and a connector main body, wherein the connector main body is a PCB, wherein a plurality of via holes are formed in the PCB, wherein soldering pads are arranged in the via holes, and wherein the soldering pads are used for communicating the first functional board and second functional board, wherein the PCB is provided with a space for accommodating elements on the first and second functional boards, wherein the soldering pads on both sides of the connector are respectively connected with the soldering pad of the first functional board and the soldering pad of the second functional board.

A system includes a first printed circuit board (PCB), a temperature sensor, a switching circuit provided on the first PCB, and a controller. The temperature sensor is configured to measure temperature of at least an area of the first PCB. The controller is configured to trigger the switching circuit to turn off power to the first PCB, based at least in part on the temperature sensor detecting a temperature above a temperature threshold. The system is able to disrupt power much faster than conventional methods of power protection which may have a blind spot to certain areas of the first PCB, since these methods rely on power disruption when a maximum power is sensed.

A multilayer substrate includes a base body including a first main surface, a first external electrode provided on the first main surface and made of metal foil, a first interlayer connection conductor, and a second interlayer connection conductor having higher conductivity than the first interlayer connection conductor. The base body includes insulating base material layers that are stacked on one another. The first interlayer connection conductor is provided at least in an insulating base material layer on which the first external electrode is provided, and is connected to the first external electrode. The second interlayer connection conductor is disposed inside the base body, and is connected to the first external electrode through the first interlayer connection conductor.

A connecting structure includes an insulation base, first pads, and second pads. The insulation base includes a first surface, a second surface, and a lateral surface connecting therebetween. First grooves are defined on the first surface, second grooves are defined on the second surface, third grooves are defined on the lateral surface. Each third groove connects one first groove and one second groove. The first pads are deposited in the first grooves. The second pads are deposited in the second grooves. Wiring portions are deposited in the third grooves, each wiring portion connects one first pad and one second pad. A conductive ink layer is coated on the first and the second pads. A protective ink layer is coated on the wiring portions and the insulating base except for the first and the second pads. The first and the second grooves are stepped grooves.

An object is to obtain a power conversion device that can suppress the generation of noise due to coupling and achieve the size reduction of a substrate. In a power conversion device, a main circuit wire for connecting main circuit components to form a main circuit includes a first main circuit wire and a second main circuit wire wired so as to be separated from each other on a substrate. A control wire is wired between the first main circuit wire and the second main circuit wire so as to be insulated therefrom, and the first main circuit wire and the second main circuit wire are connected to each other via the main circuit component placed so as to be separated from the control wire in the thickness direction of the substrate.

Aspects of the disclosure provide a printed circuit board (PCB) system that includes an integrated circuit (IC) package, a first PCB and a PCB module. The IC package has a package substrate and an IC chip that is coupled to a top surface of the package substrate. The first PCB is configured to electrically couple with first contact structures that are disposed on a bottom surface of the package substrate. The PCB module includes a second PCB and one or more electronic components electrically coupled to the second PCB. The PCB module is configured to electrically couple with second contact structures that are disposed on the top surface of the package substrate.

A printed circuit board (PCB) assembly with a first PCB connected to a second PCB with a flexible interconnect and a vapor chamber for positioning between the first PCB and the second PCB. The flexible interconnect allows the PCB assembly to be in an open configuration or a closed configuration. In the closed configuration, the vapor chamber is between the two PCBs. The flexible interconnect supplies a portion of the electric power from the first PCB to the second PCB and a power connector supplies a second portion of the electric power. Grounding springs allow localized grounding of the PCB assembly. The flexible interconnect, the power connector and the grounding springs provide structural support for the second PCB. The vapor chamber may be longer than the PCBs to draw heat away from components and the flexible interconnect may be used as an airflow guide for improving airflow over components.

An antenna array may include a plurality of printed circuit boards (PCBs) oriented in a stacked arrangement, parallel to and spaced apart from one another. Each of the PCBs may include a linear array of antenna elements, which cooperate with the linear arrays of antenna elements on other PCBs to form a two-dimensional array of antenna elements. The PCBs may be supported at one end by a common backplate in a cantilevered manner, with the linear arrays of antenna elements located near the free end of the PCBs. The PCBs may include a thicker portion and a thinner portion, and the thinner portion may include a heat sink or other thermal dissipation structure.

According to one embodiment, a vibration detecting device includes a housing, a vibration sensor, a circuit board, a flexible wiring member, and an elastic member. The vibration sensor is accommodated in the housing. The circuit board is accommodated in the housing, and is provided with a first electric component configured to process a detection signal of the vibration sensor. The wiring member electrically connects the vibration sensor and the circuit board to each other. The elastic member contains a polymer material, and is accommodated in the housing as being in contact with the housing and the circuit board, and being detachable from the housing. The circuit board is held by the housing through the elastic member.

Disclosed is an antenna module including a first printed circuit board (PCB) including a first surface facing a first direction and a second surface facing a second direction opposite the first direction, a second PCB including a third surface facing the first direction spaced from the first PCB and a fourth surface facing the second direction spaced from the first surface, a radio frequency integrated circuit (RFIC) disposed on the first surface, and a connection member comprising a conductive material connecting the first surface to the fourth surface. The at least one first conductive pattern is connected to the RFIC. The at least one third conductive pattern is connected to the RFIC via the connection member. The at least one first conductive pattern and the at least one third conductive pattern at least partially overlap with each other at least partly, when viewed from above the second surface.