An electronic device is provided. The electronic device includes a housing, a display that is visually exposed through one surface of the housing and that includes a display panel including a pixel array and a layer group including a plurality of layers stacked on the display panel, a printed circuit board disposed in the housing, a piezo unit attached to a rear surface of the display panel, and a flexible printed circuit board (FPCB) that is connected to the piezo unit and that extends to the printed circuit board, the flexible printed circuit board including a coil that surrounds at least part of the piezo unit.

A head-mounted display device is provided, including an at least partially see-through display, an electrical device, and a flexible printed circuit board (FPC) arranged on a surface of a see-through portion of the display. The FPC may include a plurality of electrical traces electrically coupled to the electrical device. Each electrical trace may be separated from at least one other electrical trace by one or more respective see-through gaps. The FPC may further include a transparent material arranged between the electrical traces in each see-through gap.

A folded light engine comprising an array of LEDs mounted on a strip substrate, wherein the strip substrate comprises a central portion provided with a first set of through-holes, a first peripheral portion provided with an electrically conducting track connecting a first group of LEDs and a second set of through holes, and a second peripheral portion provided with an electrically conducting track connecting a second group of LEDs. The first peripheral portion is folded over the central portion, so that the LEDs thereon coincide with through-holes in the central portion, and the second peripheral portion is folded over the first peripheral portion, so that each LEDs thereon coincide with a combined through-hole formed by through-holes in the central portion and in the first peripheral portion. An elongated light engine can be cost efficiently manufactured in a relatively simple processes, including single-sided circuit patterning and LED mounting.

A carrier assembly may include a first carrier sub-assembly, said first carrier sub-assembly having an elongated shape and comprising at least one electrically conductive layer structure and at least one electrically insulating layer structure, said at least one electrically conductive layer structure extending up to a first area provided on one of two extremities of the elongated shape, wherein a first plurality of conductive nanowires is provided on said first area, and a second carrier sub-assembly, said second carrier sub-assembly comprising at least one electrically conductive layer structure and at least one electrically insulating layer structure, said at least one electrically conductive layer structure comprising a second area, wherein a second plurality of conductive nanowires is provided on that second area.

An endoscopy system including an insertion tube segment, a handle segment, at least one heat source, a heat pipe and a heat-conductive material is provided. The insertion tube segment has first and second end portions opposite to each other and is inserted in the handle segment. An inside of the insertion tube segment and an inside of the handle segment commonly have a connecting space. The at least one heat source is disposed in the first end portion. The heat pipe is disposed in the connecting space and at least extends from a portion of the connecting space of the insertion tube segment to a portion of the connecting space of the handle segment. The heat-conductive material is disposed between the at least one heat source and the first end portion, and the heat-conductive material is thermally coupled to the at least one heat source and the heat pipe, respectively.

A driving system (7) includes an actuator (71A) that performs at least one among translations in three directions orthogonal to one another and rotations about axes in the three directions, and a flexible wiring body (73A) that connects a semiconductor element (6) moving along with the actuator (71A) and a frame (72) positioned outer than the semiconductor element (6). The flexible wiring body (73A) is provided with a main part (731A) mounted with the semiconductor element (6) and electrically connected to the semiconductor element (6), and a plurality of arm parts (732A) extending from the main part (731A) toward the frame (72) and bent three-dimensionally.

The present disclosure relates to branched proximal connectors for high density neural interfaces and methods of microfabricating the branched proximal connectors. Particularly, aspects of the present disclosure are directed to a branched connector that includes a main body having a base portion of a supporting structure and a plurality of conductive traces formed on the base portion, and a plurality of plugs extending from the main body. Each plug of the plurality of plugs include an end portion of the supporting structure comprised of the one or more layers of dielectric material, and a subset of conductive traces from the plurality of conductive traces. Each trace from the subset of conductive traces terminates at a bond pad exposed on a surface of the end portion of the supporting structure.

A camera module includes a housing, a lens, an assembly, a terminal, and an electronic component. The housing includes a front surface part, a rear surface part on the opposite side to that, and a side surface part connecting the front surface part and the rear surface part. The lens is exposed from the front surface part. The assembly includes an image sensor and is located on the rear surface part side relative to the lens. The terminal is located at the rear surface part for connection with an outside part. A flexible board includes a part extending from the assembly toward the terminal. The electronic component is mounted on the flexible board.

A flexible printed circuit board includes: a trunk portion; and a pair of branch portions as two portions branched from the trunk portion and arranged on a battery including multiple arrayed cells, in which for at least one branch portion of the pair of branch portions, bending is performed using a pair of parallel bending lines extending apart from the other branch portion as extending apart from the trunk portion, and the at least one branch portion is bent such that a direction of bending at one bending line of the pair of parallel bending lines and a direction of bending at the other bending line are directions opposite to each other.

An electronic device includes a frame, a housing including a first temple connected to one side of the frame and a second temple connected to an opposite side of the frame, a first printed circuit board (PCB) located in the first temple, a first flexible printed circuit board (FPCB) electrically connected to the first PCB, and a second FPCB electrically connected to the first PCB. The first FPCB includes a first overlapping portion that is extracted from the first PCB in a first direction and overlaps the second FPCB. The first FPCB further includes a first branch that extends from the first overlapping portion and does not overlap the second FPCB. The second FPCB includes a second overlapping portion that is extracted from the first PCB in the first direction and overlaps the first FPCB. The second FPCB further includes a second branch that extends from the second overlapping portion and does not overlap the first FPCB.