The disclosure provides a magnetic element and a power supply module. The magnetic element includes a first and second magnetic column, a first winding formed by sequentially connecting a first upper metal part, a first left metal part, a first middle metal part and a first right metal part, and a second winding formed by sequentially connecting a second middle metal part, a second left metal part, a first lower metal part and a second right metal part sequentially connected. The first left/middle/right metal parts and the second left/middle/right metal parts are formed on a first substrate having a first upper and lower groove in which the first and second magnetic columns are disposed respectively. The magnetic element and the power supply module in the application use circuit boards having symmetric groove structures, the process is simple, thereby facilitating panel production mode, easy for automation, and lowering cost.

A circuit module (100) includes: a substrate (10) including a plurality of inner conductors (2); a first electronic component arranged on one main surface (S1) of the substrate (10); a first resin layer (40) provided on the one main surface (S1) and configured to seal the first electronic component; a plurality of outer electrodes (B1) provided on another main surface (S2) of the substrate (10) and including a ground electrode; a conductor film (50) provided at least on an outer surface of the first resin layer (40) and a side surface (S3) of the substrate (10) and connected to the ground electrode with at least one of the plurality of inner conductors (2) interposed therebetween; and a resin film (60).

Disclosed are pressure sensors including a die and an application-specific integrated circuit (ASIC) mounted on a top surface of a substrate. The pressure sensor can define an inner volume and a bottom opening configured to abut the substrate. The die and ASIC are mounted on the top surface of the substrate within the inner volume. The substrate defines a first aperture therethrough and the die defines a second aperture therethrough in a direction along an axis perpendicular to the substrate, the first aperture and the second aperture being aligned. Metallic barrier(s) disposed on a bottom surface of the substrate, circumferentially about the first aperture, can be at least partially coated with solder mask to reduce or prevent flow of unwanted materials past the metallic barriers and through the first aperture. The substrate can include electrical connection pads on the bottom surface configured to be in communication with a daughter board.

A connector is mounted on an input-output board. The connector is interposed between the input-output board and a CPU board, and thereby a plurality of pads of the input-output board and a plurality of pads of the CPU board are respectively electrically connected. The connector includes a rectangular flat-plate housing having a first positioning hole and a second positioning hole, and at least one contact row held on the housing. The first positioning hole is formed at a first housing corner part of the housing. The second positioning hole is formed at a fourth housing corner part, which is at a diagonal position with respect to the first housing corner part, of the housing.

A modular user interface unit for an appliance is provided. The modular user interface unit includes an upper film layer comprising a conductive polymer and a plurality of electrodes. The modular user interface unit also includes a circuit board with a microcontroller thereon. The circuit board is electrically coupled to the upper film layer by a conductive polymer connector. The microcontroller is configured to receive raw capacitance data from the plurality of electrodes and to detect a touch based on the raw capacitance data.

Disclosed are a printed circuit board connector according to an embodiment and a module device including same. The printed circuit board connector comprises: a substrate; holes formed in the substrate at predetermined intervals and coated with a metal material on the inner circumferential surface thereof so as to form a metal layer; a first metal pad formed at one end of the holes and connected to the metal layer; and a second metal pad formed at the other end of the holes and connected to the metal layer.

Disclosed is a printed circuit board assembly comprising: a first printed circuit board; a second printed circuit board stacked with the first printed circuit board; and an interposer arranged between the first printed circuit board and the second printed circuit board, wherein the second printed circuit board includes a first part and a second part extending in a first direction from a part of the first part and wherein a length of the second part in a second direction perpendicular to the first direction is less than a length in the second direction of the first part, and wherein the direction of a first conductive pattern formed on the first part and the direction of a second conductive pattern formed on the second part are substantially perpendicular to each other.

A lens module includes a holder, at least one lens, a base, a sensor, an anisotropic conductive film, a flexible circuit board, and a filling member. The filling member is arranged at a side of the sensor and received in the holder. Along a direction of an optical axis of the lens module, a distance between the side of the sensor and the anisotropic conductive film is defined as a first value, a thickness of the filling member is defined as a second value, a ratio of the second value to the first value is in a range of 0.8 to 1. An electronic device having the lens module is also provided.

A twistable electronic device module including a twistable substrate, an electrode pattern layer, an insulating layer, a circuit layer, a plurality of circuit boards and a plurality of electronic devices is provided. The electrode pattern layer is disposed on the twistable substrate. The insulating layer is disposed on the electrode pattern layer. The edge of the insulating layer has an opening located at the edge of the twistable substrate and exposing a part of the electrode pattern layer. The circuit layer is disposed on the insulating layer and on the sidewall of the opening, and is connected with the electrode pattern layer. The plurality of circuit boards are disposed on the circuit layer, and each is electrically connected to the circuit layer. The plurality of electronic devices are disposed on the plurality of circuit boards, and each is electrically connected to a corresponding one of the plurality of circuit boards

An electronic component includes an electronic element and an interposer board. The electronic element includes a multilayer body and external electrodes at a pair of multilayer body end surfaces of the multilayer body and connected to internal electrode layers. The interposer board includes board end surfaces, board side surfaces orthogonal to the board end surfaces, and board main surfaces orthogonal to the board end surfaces and the board side surfaces. One of the pair of board main surfaces is located in a vicinity of the electronic element and joined with one of the multilayer body main surfaces in a vicinity of the interposer board. The interposer board is an alumina board. A solder layer is provided between the electronic element and the interposer board, joins the electronic element with the interposer board, and includes a solder unfilled region.