A printed circuit board includes a layered substrate having a plurality of layers having an electrical connector footprint configured to receive an electrical connector. The printed circuit board includes pair anti-pads passing through the layered substrate around pairs of signal vias. The printed circuit board includes ground vias passing through the layered substrate. The ground vias are configured to receive ground pins of the electrical connector. The ground vias are located outside of the pair anti-pads. The printed circuit board includes SI vias passing through the layered substrate. The SI vias form an SI fence surrounding the corresponding pair anti-pad.

An electric motor includes a rotor assembly and a stator assembly. The stator assembly includes a plurality of teeth, a plurality of coils supported about the plurality of teeth, and a conductive terminal electrically connected to at least one coil of the plurality of coils. The conductive terminal includes a lead portion. The electric motor also includes a printed circuit board coupled to the stator assembly and electrically connected to the lead portion. The electric motor further includes a solder cup supported on the lead portion between the printed circuit board and the stator assembly. The solder cup includes a wide end facing toward the printed circuit board, and a narrow end opposite the wide end.

Embodiments described herein relate to a method for modifying transmission line characteristics. The method may include: making a first determination of a null frequency of an input signal to a transmission line; performing an analysis to make a second determination of a wavelength of the input signal using, at least in part, the null frequency; making a third determination, based on the analysis, of a half wavelength of the input signal; calculating, based on the half wavelength, a total stub length; and adding a trace to a stub associated with a via, wherein the stub and the trace are a length that is at least a portion of the half wavelength of the input signal.

An electronic device may include a connector having a connector body and conductive pins extending outwardly from the connector body, and a circuit board having a dielectric layer, and spaced apart female contacts extending therein. Each female contact may include a conductive tubular via, a core within the conductive tubular via, and a conductive cup having a lower end abutting and joined to the conductive tubular via and an upper end defining a recess receiving a corresponding conductive pin of the connector. The conductive cup may have an outer diameter greater than an outer diameter of the conductive tubular via.

Multiple designs for a multi-layer circuit may be simulated to determine impedance profiles of each design, allowing a circuit designer to select a design based on the impedance profiles. One feature that can be modified is the structure surrounding the barrels of a differential VIA on layers that are not connected to the differential VIA. Specifically, one antipad can be used that surrounds both barrels or two antipads can be used, with one antipad for each barrel. Additionally, the size of the antipad or antipads can be modified. These modifications affect the impedance of the differential VIA. Additionally, a conductive region may be placed that connects to the VIA barrel even though the circuit on the layer does not connect to the VIA. This unused pad, surrounded by a non-conductive region, also affects the impedance of the differential VIA.

A surge protective device (SPD) circuit system for providing overvoltage protection to an electrical power circuit includes a PCB assembly, an SPD module, and an SPD monitoring system. The PCB assembly selectively mountable on the PCB includes a PCB and a remote signal (RS) PCB contact on the PCB. The SPD module includes an overvoltage clamping element and an RS spring contact including an RS contact portion. When the SPD module is mounted on the PCB and the electrical power circuit is connected to the PCB: the PCB electrically connects the SPD module to the circuit and the overvoltage clamping element provides overvoltage protection to the circuit; the RS contact portion engages the RS PCB contact; the RS spring contact is elastically deflected and persistently loads the RS contact portion against the RS PCB contact; and the RS spring contact is electrically connected to the SPD monitoring system via the RS PCB contact.

An electronic assembly is provided, including a wiring board, a control element, and a pair of first internal electrical connectors. The wiring board includes a mounting surface, a first patterned conductive layer, a plurality of second patterned conductive layers, a plurality of near conductive holes, a plurality of far conductive holes, and a first conductive path. The first patterned conductive layer is located between the mounting surface and the second patterned conductive layers. The control element is mounted on the mounting surface of the wiring board. The pair of first internal electrical connectors are mounted on the mounting surface of the wiring board, and are adapted for mounting a pair of memory modules. The first conductive path extends from the control element at least through the corresponding second patterned conductive layer and the first patterned conductive layer to the pair of first internal electrical connectors.

A printed circuit board includes an insulating layer and a circuit layer disposed on the insulating layer. The circuit layer includes a first circuit pattern and a second circuit pattern. Each of the first and second circuit patterns has a first side surface, a second side surface opposing the first side surface, and a top surface connected to ends of the first and second side surfaces, when viewed in a cross section direction. The first side surface of the first circuit pattern and the first side surface of the second circuit pattern face each other. A height of the first side surface of the first circuit pattern is greater than a height of the second side surface of the first circuit pattern, and a height of the first side surface of the second circuit pattern is greater than a height of the second side surface of the second circuit pattern.

Provided is a method of measuring eccentricity of a blind via hole formed in a printed circuit board including an inner-layer board and an outer-layer board that are bonded by thermocompression bonding. The method includes acquiring, by a microscope camera, an image by photographing a marker which is formed on a surface of the outer-layer board and a blind via hole which is exposed upward through a marker hole formed in a center of the marker with a microscope camera, and measuring, by computing equipment connected to the microscope camera, eccentricity indicating a separation distance and a separation direction from central coordinates of the marker hole to central coordinates of the blind via hole using a distance between an end point of the marker hole and an end point of the blind via hole which are included in the image.

An electronic device includes: a multilayered base substrate including a plurality of substrate bases stacked on each other; a first conductive via and a second conductive via penetrating the substrate bases and spaced from each other; a conductive line electrically connecting the first conductive via and the second conductive via to each other and disposed on at least one of the substrate bases of the plurality of substrate bases; and an open stub including a first end and a second end, wherein the first end is connected to a connector of the conductive line, and the second end is opened.