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.

In a multilayer wiring board having through holes used in an electronic device, wiring is efficiently performed at high density while preventing crosstalk of differential signals. A wiring board includes: a plurality of pads arranged linearly at a predetermined pitch; a plurality of through holes arranged in parallel along an arrangement direction of the pads; and a wiring pattern connecting the pad to the through hole. Between the through holes connected to the pads which are connected to the ground via the wiring patterns, two through holes through which each of a pair of differential signals constituting a differential signal pair passes are provided such that a direction of a straight line connecting the two through holes is inclined to the arrangement direction of the pads.

A system of circuit card components each include through-holes for soldering having recessed copper layers for thermal insulation. Thermal insulation prevents heat conduction away from flowing solder, allowing the solder to flow freely through the through-hole. Even high-temperature, lead-free solders may maintain the necessary temperature to flow. Different circuit layers include specialized features based on distance from a top or bottom surface. Vias surrounding the through-hole maintain the necessary cross-sectional area for electrical connectivity.

A printed circuit board includes a differential signal via pairs to route differential signal between layers of the printed circuit board. A first differential signal via pair is oriented in a first orientation and a second differential signal via pair is oriented perpendicular to the first orientation. The second differential signal via pair is located such that a midpoint of a first line segment drawn between centers of first and second vias of the second differential signal pair intersects a first ray drawn from a center of a first via of the first differential signal via pair through a center of a second via of the first differential signal via pair. Further, the second differential signal via pair is located such that the midpoint of the first line segment is at a characteristic via-to-via pitch distance for the printed circuit board from the center of the second via of the first differential signal via pair.

A resin multilayer substrate includes a plurality of insulating resin base material layers and a plurality of conductor patterns provided on the plurality of insulating resin base material layers. The plurality of conductor patterns include a plurality of signal lines provided at positions not overlapping each other as viewed from a laminating direction of the insulating resin base material layers, and a ground conductor overlapping the plurality of the signal lines as viewed from the laminating direction. Openings are provided in the ground conductor and, as viewed from the laminating direction, an aperture ratio is higher in an inner zone that is sandwiched between two signal lines than in an outer zone of the two signal lines.

A printed circuit board includes a circuit board body and a solder pad row disposed on a back of the circuit board body. The solder pad row includes a solder thief pad and a plurality of circular pin solder pads. An outline of an edge, on the solder thief pad proximate to the pin solder pads is an arc that is concave toward the solder thief pad.

The present invention provides an inductor device comprising one or more interconnected columns of conductive material embedded in a supporting structure, wherein the one or more columns comprise an input terminal and an output terminal; and wherein each column is surrounded by a first magnetic layer.

A grid array capacitor can be used to physically and electrically couple an integrated circuit (IC) package to a printed circuit board (PCB). The grid array capacitor includes an inner conductor and an inner dielectric coaxially surrounding the inner conductor. A secondary conductor can be located to surround, in a coaxial orientation, the inner dielectric. Both the inner conductor and the secondary conductor can be electrically connected to the IC package and to the PCB. In certain applications, the structure of the inner conductor, inner dielectric, and secondary conductor can provide capacitance used to decouple electronic circuits.

A laminated structure includes an interconnect structure including first and second product areas and a first interconnect layer, and a first insulating layer formed on the interconnect structure. The first product area includes an opening penetrating the first insulating layer, and the second product area includes an annular groove penetrating the first insulating layer. The laminated structure further includes an electronic component mounted inside the opening in the first product area with an annular gap formed between the electronic component and a wall surface defining the opening, an insulating member located inside the groove in the second product area, a second insulating layer that fills the annular gap and the groove, and covers the first insulating layer, the electronic component, and the insulating member, and a second interconnect layer formed on the second insulating layer, and electrically connected to the first interconnect layer.