Disclosed is an electronic device for determining the angular position of a shaft of a motor vehicle, the device including a printed circuit board and a magnetic guide including at least two fastening tabs for fastening to the printed circuit board, the printed circuit board including a base substrate and at least two fastening areas for fastening the magnetic guide, each designed to receive a fastening tab of the magnetic guide, the fastening tab defining a fastening orifice. Each fastening area is defined on the base substrate of the printed circuit board and includes a pad fastened to the base substrate. Each fastening tab is joined to the pad of the corresponding fastening area by way of an adhesive that is applied in its fastening orifice.

A supporting-terminal-equipped capacitor chip includes a capacitor chip, and first and second supporting terminals that are electrically conductive and hold the capacitor chip therebetween. A portion of the capacitor chip other than a first connection portion and the first supporting terminal are separated from each other. A portion of the capacitor chip other than a second connection portion and the second supporting terminal are separated from each other. The first connection portion is located on the first main surface adjacent to a first end surface. The second connection portion is located on the first main surface adjacent to a second end surface.

An electronic component includes: a capacitor body; a pair of external electrodes disposed on opposite end surfaces of the capacitor body, respectively; and a pair of metal frames respectively including a pair of connected portions connected to the pair of external electrodes, respectively, and a pair of mounted portions bent at and extending from one ends of the pair of connected portions, respectively, wherein corners of end portions of the pair of mounted portions facing each other have a curved surface.

An example method for attaching a ball grid array chip to a circuit board includes providing an adapter for attaching a chip with a plurality of solder balls to a circuit board, the adapter having an adapter substrate made from a material having substantially the same coefficient of thermal expansion as the substrate used in the chip and having at least one electrical contact site on a mounting surface of the adapter substrate for engaging a solder ball on the ball grid array chip and a plurality of lead wires extending from each side of the adapter substrate. At least one of the lead wires is electrically connected to at least one electrical contact site on the adapter substrate.

An electrical connector used for connecting an chip module to a printed circuit board includes an insulating housing, a number of terminals and a cover. The insulating housing includes a body portion. The terminals are insert molded in the body portion. The body portion includes an upper face and a lower face. Each of the terminals includes a first soldering portion extending upwardly beyond the upper face and a second soldering portion extending downwardly beyond the lower face. The cover covers the insulating housing. The electrical connector has a simple structure and a simple manufacturing process.

A packaged electronic device includes a package structure with opposite first and second sides spaced apart from one another along a first direction, and opposite third and fourth sides spaced apart from one another along a second direction, as well as first and second leads. The first lead includes a first portion that extends outward from the third side of the package structure and extends downward toward a plane of the first side and away from a plane of the second side. The second lead includes a first portion that extends outward from the third side of the package structure, and the second lead extends upward toward the plane of the second side and away from the plane of the first side to allow connection to another circuit or component, such as a second packaged electronic device, a passive circuit component, a printed circuit board, etc.

An electrical contact, a 3D LED and a method of manufacturing 3D LEDs are described. The electrical contact includes a printed circuit board (PCB) bridge and a PCB connector. The PCB bridge comprises at least one electrical contact. The at least one electrical contact is configured for electrical coupling with at least one interposer of a string of LEDs. The PCB connector is electrically coupled to the PCB bridge. The PCB connector comprises an electrical contact configured for electrical coupling with at least one external electrical wire.

A power tube connection structure includes a substrate, a printed circuit board, and a power tube, where a through groove allowing the power tube to pass through is cut into the printed circuit board, a mounting groove is cut into the upper surface of the substrate at a location corresponding to the through groove, one end of the power tube extends through the through groove, and is welded onto a bottom face of the mounting groove, the end of the power tube that extends into the mounting groove abuts onto a side wall of the mounting groove close to an output end of the power amplifier, and a solder flux escape channel is made into the side wall of the mounting groove close to the output end of the power amplifier.

A capacitor comprises a first winding member, where the first winding member comprises a first dielectric layer and a first conductive layer. A second winding member comprises a second dielectric layer and second conductive layer. The first winding member is interleaved, partially or entirely, with the second winding layer. A dielectric package is adapted to at least radially contain or border the first winding member and the second winding member. A first metallic member has a generally planar, radially extending surface for electrically and mechanically contacting an upper portion the first conductive layer. A second metallic member has a generally planar, radially extending surface for electrically and mechanically contacting a lower portion of the second conductive layer.

A semiconductor device includes a semiconductor element, a die pad, an encapsulating member, and a plurality of leads. The die pad has a front surface on which the semiconductor element is mounted. The encapsulating member covers and seals the semiconductor element. The plurality of leads each have a first end connected to the semiconductor element in an inside of the encapsulating member and a second end led out from a side surface of the encapsulating member. A lower surface of a package including the semiconductor element, the die pad, and the encapsulating member is located on a back surface side of the die pad and has a convexly curved shape.