A modified socket mechanism comprises a printed circuit board and a connector component located on a first face of the printed circuit board. The modified socket mechanism may comprise a first region of electrical contacts located on the first face. The first region of electrical contacts may be designed to interface with a processor module. The modified socket mechanism may also comprise a second region of electrical contacts located on a second face of the printed circuit board. The second region of electrical contacts may be designed to interface with a motherboard. The modified socket mechanism may also comprise a first electrical connection between the connector component and the first region of electrical contacts through the printed circuit board. Finally, the modified socket mechanism may also comprise a second electrical connection between the first region of electrical contacts and the second region of electrical contacts through the printed circuit board.

Semiconductor light emitting device includes: substrate including main and back surfaces, first and second side surfaces, and bottom and top surfaces, wherein main surface includes first to fourth sides; first main surface electrode on main surface and including first base portion contacting the sides of the main surface, and die pad connected to first base portion; second main surface electrode disposed on the main surface and including second base portion contacting first and third sides of the main surface, and wire pad connected to second base portion; semiconductor light emitting element including first electrode pad and mounted on die pad; wire connecting first electrode pad and wire pad; first insulating film covering portion between first base portion and die pad; second insulating film covering portion between second base portion and wire pad and having end portions contacting main surface; and light-transmitting sealing resin.

The present disclosure provides a testing fixture for holding a device under test (DUT). The testing fixture includes a base, a frame, a recessed portion, a plurality of sets of electrical contacts and a plurality of electrical lines. The frame extends upward along an outer perimeter of an upper surface of the base. The recessed portion is surrounded by the frame and the upper surface of the base, and the DUT is received in the recessed portion. The plurality of sets of electrical contacts are disposed on the recessed portion and arranged in a rotationally symmetrical manner, wherein a plurality of plated through holes of the DUT are in contact with one set of the electrical contacts after the DUT is assembled with the testing fixture.

An adapter board is described having a substrate having a width, a length and a depth and at least one electrical component placed one of within the substrate and on a surface of the substrate. The adapter board may also have a first pad positioned on the substrate, the first pad connected to the at least one electrical component through a first via. The adapter board may also have a second pad positioned on the substrate, the second pad connected to the at least one electrical component through a second via, wherein at least a portion of the adapter board is configured through an additive manufacturing process and wherein the substrate is configured to be installed within a downhole tool.

An electronic device and oscillator structure are provided. The electronic device includes a printed circuit board, an oscillator configured to oscillate at a frequency corresponding to an operation clock of the electronic device, and a connection member disposed between the oscillator and the printed circuit board such that the oscillator is spaced apart from a surface of the printed circuit board to electrically connect the oscillator to the printed circuit board. The connection member includes a first pad part electrically connected to a terminal of the oscillator, a second pad part electrically connected to a pad of the printed circuit board, and at least one conductive pattern electrically connecting the first pad part and the second pad part.

The invention relates to an electronic module (40) comprising at least one printed circuit board of a first type (referred to as printed circuit board A), which is equipped in an overlapping manner with at least one printed circuit board of a second type (referred to as printed circuit hoard B), printed circuit board B being equipped with at least one electronic component with specific requirements (19), mid the interconnected printed circuit boards A and B forming a stepped composite printed circuit board (100, 200, 300, 400, 300). The composite primed circuit board (100, 200, 300, 400, 500) is delimited at least in some regions by end regions (16) which are formed by sections of the at least one printed circuit board A, and the composite printed circuit board (100, 200, 300, 400, 500) is placed on a heat sink (20). A fastening side (15) of the at least one printed circuit board B rests flat on a contact face (21) of the heat sink (20), the contact face (21) of the heat sink (20) being dimensioned and positioned such that at least part of a extends laterally beyond the fastening side (15) of the at least one printed circuit board B in each case towards the end regions (10) formed. Supporting elements (23, 24, 23, 26) are formed on the contact face (21) of the treat sink for the mechanical support of the end regions (16). The invention also relates to a method for producing such an electronic module.

In a non-reciprocal circuit element, a permanent magnet is connected to one main surface of a magnetic plate, and a circuit board is connected to the other main surface of the magnetic plate, with a solder bump lying between the circuit board and the other main surface. The permanent magnet can control the transmission of electrical signal from each of a plurality of signal conductors of circuit board to a corresponding one of a plurality of input/output terminals of the magnetic plate. The non-reciprocal circuit element further includes an underfill material arranged between the magnetic plate and the circuit board. The magnetic plate has a through hole formed therein, the through hole extending from one main surface to the other main surface. The through hole has an empty space in which at least a part of a conductive film arranged in the through hole is exposed.

A display device includes a first panel including a pad side area at one side of the first panel, a first optically transparent adhesive member on one surface of the first panel, a printed circuit board including a first attachment portion attached to the one surface of the first panel at the pad side area, a window on the first optically transparent adhesive member, a second optically transparent adhesive member on the other surface of the first panel, and a second panel on the second optically transparent adhesive member opposite the first panel, wherein the pad side area has a connection area at which the printed circuit board is attached to the first panel, and at which an edge of the first optically transparent adhesive member extends beyond an edge of the second optically transparent adhesive member, and a non-connection area at which the printed circuit board is not attached.

A printed circuit board comprises a board main body, a sensor, an external connection pad, and a hollow-structured electrical conductor. The board main body has a top face and a bottom face opposite the top face. The sensor is mounted on one of the top face and the bottom face of the board main body. The external connection pad is provided on the top face or the bottom face of the board main body opposite the sensor. The hollow-structured electrical conductor extends through the board main body and electrically connects the sensor to the external connection pad.

A display device includes: a display panel including panel terminals; and a wiring substrate including first substrate terminals coupled to the panel terminals. The panel terminals include panel terminals arranged in a first region and panel terminals arranged in second regions sandwiching the first region. The first substrate terminals include first substrate terminals arranged in a third region and first substrate terminals arranged in fourth regions sandwiching the third region. A gap between panel terminals is substantially constant in the first and second regions. A first width of the panel terminals in the first region is different from a second width of the panel terminals in the second regions. A width of the first substrate terminals is substantially constant in the third and fourth regions. A first gap between first substrate terminals in the third region is different from a second gap between first substrate terminals in the fourth regions.