A high-speed transmission circuit design reduces or eliminates the presence of unwanted stub-effects and avoids uncontrolled line impedances that in existing circuits cause impedance mismatches that give rise to unwanted reflections and, ultimately, degrade signal integrity, e.g., in belly-to-belly configurations involving Quad Small Form-Factor Pluggable Double Density (QSFP DD) connectors. In various embodiments, by preventing overcrowding of signal lines, the circuit design further reduces crosstalk and increases signal integrity.

An electronic device according to various embodiments of the disclosure may include a printed circuit board constructed with a layered structure of a plurality of boards, and may include, among the plurality of boards, a circuit board constructed around a first region to which an acoustic component is disposed, and having at least one slit constructed to block a low-frequency band noise.

Provided is a printed circuit board including a first semiconductor device and a second semiconductor device mounted on a printed wiring board, the printed wiring board including a first and a second differential signal wirings each formed of a pair of signal transmission lines. The pair of signal transmission lines forming the first differential signal wiring are wired to have a relative arrangement in which one signal transmission line and another signal transmission line cross with each other at least once in the first differential signal wiring in a wiring direction thereof. The pair of signal transmission lines forming the second differential signal wiring are wired to have a relative arrangement in which one signal transmission line and another signal transmission line cross with each other at least once in the second differential signal wiring in a wiring direction thereof.

Embodiments of the present invention generally relate to communication connectors, and methods of manufacture thereof and their components. In some embodiments, the methods focus on reducing the net effect on electrical performance of communication connectors from variation in manufacturing, where the connectors include multiple stages of capacitive coupling.

An audio/video device may determine that a UI is displayed in a first AV signal, and may capture a frame of the UI in order to provide UI information to a UI generation component that generates a second UI. The AV device may then provide the second UI for display in place of the first UI. The AV device may act as a virtual controller device capable of controlling multiple devices and streaming content from multiple devices to multiple displays.

A printed circuit board (PCB) comprises two or more PCB layers comprising of a dielectric core and conductive cladding on adjoining surfaces; one or more DC lines embedded in one or more layers of the two or more PCB layers; one or more RF signal lines embedded in one or more layers of the two or more PCB layers; wherein the one or more DC lines crosses over/under at least one of the RF signal lines to form at least one crossover, wherein the at least one crossover is no thicker than the PCB layer in which it is situated. The printed circuit board of claim 1, further comprising two or more generally parallel DC lines which converge to form a stack of superposed parallel DC lines where the two or more DC lines cross over the one or more RF signal lines.

A semiconductor device comprises a semiconductor substrate, one or more circuits disposed on the semiconductor substrate, and a modification of any one of hardware, software or firmware of the electronic device that generates emission of electromagnetic energy from the semiconductor device with desired characteristic(s), without changing a designed interface functionality of the semiconductor device. Method are also provided for modifying the semiconductor device and identifying modified semiconductor device.

A switch circuit package module includes at least a semiconductor switch unit and at least a first capacitor unit. The semiconductor switch unit includes a first semiconductor switch element and a second semiconductor switch element. The first semiconductor switch element and the second semiconductor switch element include a plurality of sub micro-switch elements. The capacitor unit includes a plurality of capacitors configured to cooperate with the sub micro-switch elements. The capacitors are arranged in a symmetrical distribution surrounded the semiconductor switch unit, such that impedances of any two symmetrical commutation loops each of which mainly consists of one capacitor and two sub micro-switch elements from the first semiconductor switch element and second semiconductor switch element respectively are close to or the same with each other.

A signal transmission circuit packaging structure is disclosed. The signal transmission circuit packaging structure includes a body, a main circuit unit, power pins, input pins, output pins, control pins, and ground pins. The main circuit unit is arranged in the center of the body. The power pins supply power signal to the main circuit unit. The input pins and the output pins are arranged on a first and a second side of the body separately for electrically connecting to the main circuit unit. The control pins are arranged on the second side of the body and electrically connected to the main circuit unit. The ground pins are arranged at corners of the body to separate the input pins, the output pins, and the control pins.

A high speed communication jack including a housing including a port for accepting a plug, the port including a plurality of pins each connected to a corresponding signal line in the plug, a shielding case surrounding the housing, a circuit board in the housing having a substrate, a plurality of first vias extending through the substrate with each first via being configured to accommodate a pin on the housing, a plurality of second vias extending through the substrate with each second via being configured to accommodate a pin on the housing, a first set of traces on a top layer of the substrate that connects at least one first via with at least one corresponding second via; and a second set of traces on a side of the substrate opposite the top layer that connects at least one first via with at least one second via.