The first capacitor is opposed to and electrically connected to the first back electrode. The second capacitor is opposed to and electrically connected to the second back electrode. Each of the first circuit and the second circuit has a main region that overlaps with a corresponding one of the first capacitor and the second capacitor. At least one circuit of the first circuit and the second circuit has an extension region extending from the main region toward another circuit of the first circuit and the second circuit. At least one of one of the pair of first wires and the second wire is bonded to the extension region.

A circuit board according to an embodiment includes an insulating layer; and a lead pattern portion disposed on the insulating layer, wherein the lead pattern portion includes: a first portion disposed on the insulating layer; and a second portion extending from one end of the first portion; wherein the first portion is disposed overlapping the insulating layer in a vertical direction, wherein the second portion is disposed in an outer region of the insulating layer and does not overlap the insulating layer; and wherein the lead pattern portion has a centerline average roughness in a range of 0.05 .Math.m to 0.5 .Math.m or a 10-point average roughness in a range of 1.0 .Math.m to 5.0 .Math.m.

Provided are a printed circuit board configured to achieve reduction in impedance of a differential transmission line extending in a stacking direction, and an optical module. The printed circuit board includes a stacking-direction differential transmission line extending in the stacking direction, including: a differential signal via pair including a first signal via and a second signal via; and a plurality of conductor plate pairs each including a first conductor plate expanding outward from the first signal via, and a second conductor plate expanding outward from the second signal via. With respect to a perpendicular bisector of a center-of-gravity line segment connecting centers of gravity of the first and second signal vias, in each of the plurality of conductor plate pairs, centers of gravity of contours of the first and second conductor plates are located on inner sides of the centers of gravity.

An electronic device includes a camera module comprising a circuit board, a lens, a first IC chip, and at least one metal column. The lens is mounted on the circuit board. The first IC chip and the metal column are arranged on a surface of the circuit board away from the lens. An attachment includes a body and a second IC chip. The first IC chip and the second IC chip can communicate with each other. The circuit board includes a first surface closed to the attachment. The metal column is arranged on the first surface, and the body includes a second surface close to the camera module. The body further includes at least a connecting channel. The metal column is located in the connecting channel to realize the electrical connection between the camera module and the attachment.

A printed circuit board (PCB) includes a substrate including a first insulating layer and first wiring patterns disposed on the first insulating layer, an optical sensing chip including a vertical cavity surface emitting laser (VCSEL) and a photodiode, disposed on the first insulating layer to be in contact with at least one of the first wiring patterns, a transimpedance amplifier (TIA) chip disposed to be spaced apart from the optical sensing chip on the first insulating layer and disposed to be in contact with at least one first wiring pattern, different from the first wiring pattern connected to the optical sensing chip, among the first wiring patterns, and a dielectric layer stacked on the substrate and having a hole exposing the VCSEL and the photodiode of the optical sensing chip. The optical sensing chip and the transimpedance amplifier chip are connected through a wiring pattern disposed on the dielectric layer.

An electronic device includes a substrate, a polarizer, a flexible printed circuit board, a first transparent glue layer, a first colloid, and a second colloid. The substrate includes a first side and a second side. The first side is opposite to the second side. The polarizer is disposed on the first side of the substrate. The flexible printed circuit board is connected to the first side of the substrate with a conductive glue. A gap is formed between flexible circuit board and polarizer. The first transparent glue layer is disposed on the second side of substrate. The first colloid is configured to bond at least two of substrate, polarizer, or flexible printed circuit board. The second colloid is configured to bond at least two of the substrate, the flexible printed circuit board, or the first transparent glue layer. The first colloid is not in contact with the second colloid.

A camera module comprising: a housing; a lens assembly that is fixed to the housing and comprises at least one lens; a circuit board that is arranged inside the housing and comprises a first circuit board and a second circuit board, on which image sensors arranged to face the lens are mounted, respectively; and a first shield can arranged inside the housing so as to support edges of the first and second circuit boards.

The present disclosure is directed to a board mounted active component assembly that includes a printed circuit board to which a connector is mounted and electrically connected. In one aspect, the connector includes a housing defining an adapter port for receiving an optical plug. The connector also includes a fiber optic transceiver module secured within the housing such that the transceiver module is optically aligned with an optical plug received in the adapter port. The fiber optic transceiver module includes a transmitter optical sub-assembly (TOSA) and a receiver optical sub-assembly (ROSA) with leads connected to a circuit on the printed circuit board.

A pluggable optical module may include a substrate. The pluggable optical module may include a compressible sliding thermal interface disposed on the substrate to contact a riding heatsink. The compressible sliding thermal interface material may be compressed to fill interstices between a first surface of the substrate and a second surface of the riding heatsink. The compressible sliding thermal interface may protrude from the first surface of the substrate such that insertion of the pluggable optical module into a cage compresses the compressible sliding thermal interface to achieve a threshold thermal boundary resistance.

An opto-electric hybrid board includes: an electric circuit board including an insulation layer haying front arid back surfaces, arid electrical interconnect lines formed on the front surface of the insulation layer; and an optical waveguide having a substantially rectangular shape as seen in plan view and provided on the back surface of the insulation layer of the electric circuit board, with a metal layer therebetween. The optical waveguide has at least one end portion disposed in overlapping relation with the metal layer. The at least one end portion of the optical waveguide has corner portions. Each of the corner portions is radiused to have an arcuate shape or has a polygonal shape produced by arranging a plurality of obtuse-angled portions in a substantially arcuate configuration.