A computer system receives an initial multilayered ceramic package design. The computer system maintains a first selection of mesh line segments of the mesh line segments at a first width and adjusts a second selection of mesh line segments of the plurality of mesh line segments to a second width. The computer system controls fabrication of the multilayered ceramic package based on the modified multilayered ceramic package design.

An electronic device includes a printed circuit board. The printed circuit board includes a plurality of different signaling planes and a plurality of different reference planes. A single ended via interconnects the plurality of different signaling planes. A return via interconnects the plurality of different reference planes. The electronic device includes a shared void that includes the single ended via and the return via.

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 (PCB) may include a plurality of horizontally disposed signal layers. The PCB may include a first vertically disposed differential via electrically connected to a first horizontally disposed signal layer, of the plurality of horizontally disposed signal layers, and a second horizontally disposed signal layer of the plurality of horizontally disposed signal layers. The PCB may include a second vertically disposed differential via electrically connected to the first signal horizontally disposed layer and the second horizontally disposed signal layer. The PCB may include a first set of clearances encompassing the first vertically disposed differential via and the second vertically disposed differential via, a second set of clearances encompassing the first vertically disposed stub, and a third set of clearances encompassing the second vertically disposed stub.

A method of fabricating a multilayer circuit board is provided which includes forming a layer of a the multilayer circuit board with an internal clearance region having a modified voltage-to-ground clearance of conductive material adjacent to an aperture of the multilayer circuit board. The modified voltage-to-ground clearance of conductive material is based on a configuration of a connector pin to be press-fit connected within the aperture of the multilayer circuit board, and the internal clearance region is enlarged in a direction of greatest normal force outward from the aperture with insertion of the connector pin into the aperture.

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 signal transmitting apparatus includes a first line that is provided in one of plural layers of a board and transmits a signal by superimposing the signal on an electric power line that supplies electric power; a coupling section in which the electric power line is coupled to the first line and the first line is branched; plural second lines that branch off in the coupling section and are provided in another layer different from the one layer; and a conductive layer that is provided between the one layer and the other layer. The conductive layer has an opening that encompasses the coupling section in plan view, and the coupling section has a coupling line that has a larger width than the first line and plural through-holes that connect the coupling line and the plural second lines through the opening of the conductive layer.

The various structures forming communication paths on a printed circuit board can create several undesired effects, especially when high frequency signals are considered. Non-functional pads created during the manufacturing process have the potential to create an undesired effect, but when the overall collection of non-functional pads are carefully configured, an optimized communication path can be formed. More specifically, by selectively removing some collection of the non-functional pads, the high frequency characteristics of the communication paths can be optimized.

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.

The various structures forming communication paths on a printed circuit board can create several undesired effects, especially when high frequency signals are considered. Non-functional pads created during the manufacturing process have the potential to create an undesired effect, but when the overall collection of non-functional pads are carefully configured, an optimized communication path can be formed. More specifically, by selectively removing some collection of the non-functional pads, the high frequency characteristics of the communication paths can be optimized.