A printed circuit board includes a plurality of layers including conductive layers separated by dielectric layers, the conductive layers including a signal layer; and via patterns formed in the plurality of layers, each of the via patterns comprising first and second signal vias extending from a first surface of the printed circuit board to the signal layer, the signal layer including first and second signal traces connected to the first and second signal vias, respectively, the signal layer further including a ground conductor located between the signal traces and adjacent signal-carrying elements.

A pre-charge unit for charging a DC link capacitor includes a printed circuit board including at least one conductive layer; a pre-charge switch on the printed circuit board; and a pre-charge resistor electrically connected in series with the pre-charge switch, wherein the pre-charge resistor is formed by a conductive trace in the at least one conductive layer of the printed circuit board.

The present invention discloses a driving circuit for a display panel and a display device. The driving circuit includes a driving circuit board configured to carry a driving circuit, and first pads located on the driving circuit. The first pads are connected through a detachable connector.

A printed circuit board including a set of five layers encompassing a breakout area is described. The set includes a first ground layer, a first signal layer having a first conductive layer within the breakout area, a second ground layer having conductive material, a second signal layer having a second conductive layer within the breakout area, and a third ground layer. The second ground layer having a void forming a differential pair being two parallel traces, and being separated into a first portion positioned within the breakout area and a second portion outside of the breakout area. The differential pair having a first width and a first spacing within the breakout area and a second width and second spacing outside of the breakout area, with the second width greater than the first width. The first and second conductive layers forming a first ground plane and a second ground plane.

A novel and useful a single layer RFIC/MMIC structure including a package and related redistribution layer (RDL) based low loss grounded coplanar transmission line. The structure includes a package molded around an RF circuit die with a single redistribution layer (RDL) fabricated on the surface thereof mounted on an RF printed circuit board (PCB) via a plurality of solder balls. Coplanar transmission lines are fabricated on the RDL to conduct RF output signals from the die to PCB signal solder balls. The signal trace transition to the solder balls are funnel shaped to minimize insertion loss and maximize RF isolation between channels. A conductive ground shield is fabricated on the single RDL and operative to shield the plurality of coplanar transmission lines. The ground shield is electrically connected to a ground plane on the PCB via a plurality of ground solder balls arranged to surround the plurality of coplanar RF transmission lines and signal solder balls, and are operative to couple the ground shield to the ground plane on the PCB and provide an electrical return path for the plurality of coplanar transmission lines. Ground vias on the printed circuit board can be either located under the ground solder balls or between them.

An electrical connector includes a substrate that includes a plurality of ground traces at first and second surfaces of the substrate, and a ground coupling assembly that couples pairs of ground traces at each of the first and second surfaces, and further couples the ground traces at the first surface to the ground traces at the second surface.

A display panel and a bezel substrate thereof are disclosed. The bezel substrate includes a bending section and a plurality of wirings. Each of the wirings includes a first line section and a second line section, the first line section and the second line section are disposed on the bending section, a width of the first line section to each of the wirings is greater than a width of the second line section of the wirings, and the first line sections of the adjacent wirings are staggered with respect to each other.

The present disclosure provides a panel, a manufacturing method for the same, and a terminal. The panel includes: a base substrate; at least one differential signal line group on the base substrate, each including two signal lines; and at least one ground wire group on the base substrate and on the same side of the base substrate as the at least one differential signal line group. The at least one ground wire group is in one-to-one correspondence with the at least one differential signal line group, each ground wire group includes two ground wires, and orthographic projections of the two ground wires in each ground wire group on the base substrate are on two sides of an orthographic projection of a corresponding differential signal line group on the base substrate, respectively.

The present invention provides a light emitting diode(s), LED, light strip arranged for providing improved color consistency over its length. The LED light strip comprises LED strings positioned along the length of the LED light strip and powered in parallel, for emitting, for example, red, green, blue and white light. The resistance of the supply and return traces, in combination with variations in the current drawn by or the forward voltage of the various LED and resistors used in the LED strings of different color, causes a voltage drop along these traces leading to inconsistent color rendering. By adjusting the resistivity of the traces, such as through providing return paths having different resistances for LED strings of different color, the consistency of the color rendering can be improved.

In this circuit board 30, first signal wiring portions 351 and second ground wiring portions 353 of a first wiring layer 34 are adjacent to each other in a pitch direction. Further, second signal wiring portions 381 and first ground wiring portions 383 of a second wiring layer 37 are adjacent to each other in the pitch direction. In the pitch direction, outer edges 405 of line portions 345 of two first signal wiring portions 351 are located more inward than both edges 435 of a line portion 375 of the first ground wiring portions 383. Outer edges 415 of line portions 375 of two second wiring portions 381 are located more inward than both edges 425 of the line portion 345 of the second ground wiring portion 353. This achieves good signal transmission characteristics without providing a ground layer separate from a signal layer.