A printed circuit board includes a plurality of layers including attachment layers and routing layers; and via patterns formed in the plurality of layers, each of the via patterns including first and second signal vias forming a differential signal pair, the first and second signal vias extending through at least the attachment layers; ground vias extending through at least the attachment layers, the ground vias including ground conductors; and shadow vias located adjacent to each of the first and second signal vias, wherein the shadow vias are free of conductive material in the attachment layers. The printed circuit board may further include slot vias extending through the attachment layers and located between via patterns.

Provided is a structure including at least: a first conductor plane; a second conductor plane disposed so as to face the first conductor plane; a first transmission line that is formed in a layer different from the first conductor plane and the second conductor plane and is disposed so as to face the second conductor plane, one end of the first transmission line being an open end; a conductor via that connects another end of the first transmission line with the first conductor plane; a slit that is formed on the second conductor plane and stretches to both sides of the first transmission line from a starting point where the slit overlaps the first transmission line in a plan view. Thus, a structure that enables formation of a compact EBG structure is provided.

A printed wiring board is provided with a wiring layer, a first ground layer, a second ground layer, a grounding through-hole, a signal through-hole, a first clearance, and a second clearance. The wiring layer has a signal line. The first ground layer has a first ground plane. The second ground layer is positioned between the wiring layer and the first ground layer and has a second ground plane. The grounding through-hole passes through the wiring layer, the first ground layer, and the second ground layer and is connected to the second ground plane. The signal through-hole passes through the wiring layer, the first ground layer, and the second ground layer and is connected to the signal line. The first clearance is formed in the first ground layer, is positioned in the vicinity of the signal through-hole and the grounding through-hole, and separates the first ground plane from the signal through-hole and the grounding through-hole. The second clearance is formed in the second ground layer, is positioned in the vicinity of the signal through-hole, and separates the second ground plane from the signal through-hole.

A printed circuit board includes a plurality of layers including attachment layers and routing layers; and via patterns formed in the plurality of layers, each of the via patterns including first and second signal vias forming a differential signal pair, the first and second signal vias extending through at least the attachment layers; ground vias extending through at least the attachment layers, the ground vias including ground conductors; and shadow vias located adjacent to each of the first and second signal vias, wherein the shadow vias are free of conductive material in the attachment layers. The printed circuit board may further include slot vias extending through the attachment layers and located between via patterns.

A printed circuit board includes a plurality of layers including attachment layers and routing layers; and via patterns formed in the plurality of layers, each of the via patterns comprising: dual diameter first and second signal vias forming a differential signal pair, the first and second signal vias being configured to accept contact tails of signal conductors of a connector; dual diameter ground shadow vias adjacent to each of the first and second signal vias, wherein the dual diameter shadow ground vias have a reversed diameter configuration with respect to the dual diameter first and second signal vias; and ground vias configured to accept contact tails of ground conductors of the connector.

A circuitized substrate which includes a conductive paste for providing electrical connections. The paste, in one embodiment, includes a metallic component including nano-particles and may include additional elements such as solder or other metal micro-particles, as well as a conducting polymer and organic. The particles of the paste composition sinter and, depending on what additional elements are added, melt as a result of lamination to thereby form effective contiguous circuit paths through the paste. A method of making such a substrate is also provided, as is an electrical assembly utilizing the substrate and including an electronic component such as a semiconductor chip coupled thereto.

A circuit board comprises a plurality of layers, first and second reference conductive vias extending in a vertical direction through at least a portion of the plurality of layers, first and second signal conductive vias extending in the vertical direction between and spaced apart in a horizontal direction from the first and second reference conductive vias through at least a portion of the plurality of layers, and a dielectric region extending in the vertical direction between the first and second signal conductive vias. An air via extends in the vertical direction through the dielectric region between the first and second signal conductive vias. An anti-pad extends in the horizontal direction between the first and second reference conductive vias and surrounding in the horizontal direction the first and second signal conductive vias, the air via, and the dielectric region.

A stack structure of a high frequency printed circuit, mainly includes a transmission conductor pin group in a form of single row, where each signal pair and each transmission pair of the transmission conductor pin group respectively have a through hole portion thereon, and the inner layer of the circuit board has a trace portion in electric connection with the through hole portion, allowing each four terminals to be formed into one group. Utilizing the clever arrangement of the through hole portions and trace portions separates each terminal properly, thereby increasing the property of transmitted signals, and, at the same time, reducing noise interferences such as EMI and RFI.

Provided is a multilayer printed circuit board comprising a plurality of wire layers and mounted with a switching power supply, wherein at least three broad patterns, which are formed on at least three wire layers, and a via for connecting the at least three broad patterns are provided to a power supply path connecting a connector, which is to be connected to an external power supply, and the switching power supply, a first capacitor is connected to the connector-side broad pattern, a second capacitor is connected to the switching power supply-side broad pattern, and a -type filter is configured with parasitic inductance, which is generated by the at least three broad patterns and the via, the first capacitor, and the second capacitor.

A circuit may include a signal path, a first layer including the signal path, and a second layer including the signal path. The circuit may additionally include a path via having a signal-path via location and configured to connect the signal path at the first layer with the signal path at the second layer. The circuit may also include a ground plane associated with the first layer. The ground plane may have a ground-plane location that corresponds to the signal-path via location. The ground plane may also include an asymmetrical cutout portion that extends away from the ground-plane location on a first side of the ground plane that is opposite a second side of the ground plane that corresponds with a side of the first layer where the path via interfaces with the signal path at the first layer.