This application relates to the field of electronic technologies, and in particular, to an electronic device. A camera assembly may be supported, and a charging path or a high-current path may be shortened, so that an impedance can be reduced, efficiency can be improved, and power consumption can be prevented from being increased. An electronic device is provided, including a circuit board and a camera assembly, where the circuit board has a mounting hole extending through the circuit board in a thickness direction, and the mounting hole includes a first end and a second end oppositely arranged along the thickness direction of the circuit board; and the camera assembly includes a first part arranged in the mounting hole and a second part extending out from the first end of the mounting hole, and the first part includes a camera substrate assembly; and a support member, arranged on the circuit board and at the mounting hole, where the first part is arranged on the support member, the support member includes at least one conductive sheet, the at least one conductive sheet is further coupled to a metal wiring of the circuit board, and the at least one conductive sheet is insulated from the camera substrate assembly.

Technologies for a flexible three-dimensional power plane in a chassis are disclosed. In one embodiment, a flexible ribbon cable is laid along a circuit board tray. The flexible ribbon cable is secured to the tray using power bosses. The power bosses connect to one or more conductors on the ribbon cable. When the circuit board is mounted on the circuit board tray, the power bosses extend through holes in the circuit board and mate with power clips on the surface of the circuit board tray. The ribbon cable, power bosses, and power clips can distribute power to various locations on the circuit board, without requiring large traces that take up space on the circuit board.

A layout structure of flexible circuit board includes a flexible substrate and leads formed on a surface of the flexible substrate. Each of the leads has a bump connection end and a curved part. The bump connection end of each of the leads is located on a chip disposition area of the surface and electrically connected to a chip. The curved part has a first connection point and a second connection point, and the length of the curved part is longer than a straight-line distance between the first and second connection points.

Various configurations of a grounding element or conductive element for a printed circuit board (PCB), as well as a process for manufacturing, are disclosed. For example, a PCB can include a solder grounding element connecting a copper track to a metal substrate, where the solder grounding element is applied via ultrasonic soldering during a manufacturing process. In another example, a PCB can include a spring pin grounding element connecting a copper track to a metal substrate. In yet another example, a PCB can include an auto splice grounding element connecting a copper track to a metal substrate. In yet another example, a PCB can include a press fit pin grounding element connecting a copper track to a metal substrate. In yet another example, a PCB can include a clip pin grounding element connecting a copper track to a metal substrate.

A component carrier and a method for manufacturing a component carrier are described. The component carrier has a carrier body with a plurality of electrically conductive layer structures and/or electrically insulating layer structures. At least a part of the component carrier is formed as a three-dimensionally printed structure.

Printed circuit boards (PCBs) may include a heat sink configured to draw heat from a surface-mounted component through the PCB toward a side of the PCB opposite a side having the surface-mounted component. The heat sinks may be single piece components that extend at least partially through the PCB. In some embodiments, the PCB may include connectors that interface between the PCB and a heat sink, or possibly other components.

The invention which relates to an EMC filter for the suppression of interference signals addresses the problem of specifying a solution with which reworking expenditures of an inverter board are reduced and, additionally, installation space restriction as well as reduction of development and production costs are attained. This problem is resolved thereby that in an EMC filter module at least one core of a choke with a winding is disposed on a first mounting board, that at least one of the capacitors is disposed on the first mounting board, that the first mounting board comprises at least two contact means and that the first mounting board of the EMC filter module is disposed with its contact means on a main board of an inverter and is electrically connected thereto.

A mounting clip can be placed and secured over the exterior surfaces of a package of an integrated optical assembly. The mounting clip includes a top panel, end clips that curl and extend down from end edges of the top panel, an interference tab that extends up from the top panel, and cap clips that curl and extend up from the top panel. The mounting clip is dimensioned such that bends in the end clips press and secure against exterior side surfaces of the package of the integrated assembly. Thus, the mounting clip can be secured to the package of the integrated assembly using an interference or friction fit. A cap on a fiber optic cable that extends from the package can be curled around and secured between the interference tab and cap clips of the mounting clip to secure it during surface mounting.

The present disclosure relates to phase shifters, antennas, and base stations. One example phase shifter includes a cavity, a built-in printed circuit board (PCB), and a stress relief portion. The stress relief portion is connected to the PCB, and the stress relief portion is configured to reduce a stress generated due to different coefficients of thermal expansion (CTE) of the cavity and the PCB.

Methods for mounting a power amplifier (PA) assembly having an extended heat slug (11) are disclosed. According to one aspect, a method includes manufacturing a left side PCB (22a) and a right side PCB (22b). The method further includes sliding the left side PCB and the right side PCB inward (30) to encompass the PA assembly so that one of the left and right side PCB is in a position to contact a drain of the PA (13) and so that the other of the left and right side PCB is in a position to contact a gate of the PA (14).