A quantum mechanical circuit includes a substrate; a first electrical conductor and a second electrical conductor provided on the substrate and spaced apart to provide a gap therebetween; and a third electrical conductor to electrically connect the first electrical conductor and the second electrical conductor. The third electrical conductor is a poor thermal conductor.

A circuit board device includes a multilayer structure, a main ground area and a circuit module. The multilayer structure includes a plurality of plates. The main ground area is arranged in the multilayer structure. The circuit module includes a differential signal circuit and a surrounding circuit module. The differential signal circuit is located in the multilayer structure, and includes a positive signal pad and a negative signal pad. The positive signal pad is located on a configuration surface of one of the plates. The negative signal pad is located on the disposition surface, and is separated from the positive signal pad. The surrounding circuit module is located on the disposition surface, and electrically connected to the main ground area. The surrounding circuit module surrounds the positive signal pad and the negative signal pad in an enclosing way, and is physically separated from the differential signal circuit.

According to one embodiment, a semiconductor memory system includes a substrate, a plurality of elements and an adhesive portion. The substrate has a multilayer structure in which wiring patterns are formed, and has a substantially rectangle shape in a planar view. The elements are provided and arranged along the long-side direction of a surface layer side of the substrate. The adhesive portion is filled in a gap between the elements and in a gap between the elements and the substrate, where surfaces of the elements are exposed.

A printed circuit board includes: a first layer including a first ground including a first opening, wherein a first ground wire is within the first opening; a second layer disposed in a direction from the first layer and including a second ground including a second opening, wherein the second opening at least partially overlaps with the first opening and wherein a second ground wire is within the second opening; a third layer between the first layer and the second layer and including a third opening, wherein the third opening at least partially overlaps with the first opening and wherein a first via pad is within the third opening; and a fourth layer between the second layer and the third layer and including a fourth opening, wherein the fourth opening at least partially overlaps with the third opening and wherein a second via pad is within the fourth opening.

A wiring substrate which includes a base member having a first surface, a first differential signal line disposed on the first surface of the base member and a second differential signal line disposed adjacent to the first differential signal line on the first surface of the base member. A ground layer which faces the first and second differential signal lines, has a plurality of openings continuously arranged along a predetermined direction. In a planar view of the wiring substrate, where a length of each of the plurality of openings in a direction along the signal lines is a length L1, a length of the opening in a direction orthogonal to Li is a length L2, and a distance between the first and second differential signal lines is a length L3, L1 is equal to or greater than four times L2, and L2 is equal to or less than L3.

Systems for shielding bent signal lines provide ways to couple different antenna arrays for radio frequency (RF) integrated circuits (ICs) (RFICs) associated therewith where the antenna arrays are oriented in different directions. Because the antenna arrays are oriented in different directions, the antenna structures containing the antennas may be arranged in different planes, and signal lines extending therebetween may include a bend. To prevent electromagnetic interference (EMI) or electromagnetic crosstalk (EMC) from negatively impacting signals on the signal lines, the signal lines may be shielded. The shields may further include vias connecting the mesh ground planes and positioned exteriorly of the signal lines. The density of the vias may be varied to provide a desired rigidity in planes containing the antenna arrays while providing a desired flexibility at a desired bending location in the signal lines to help bending process accuracy.

The present invention relates to a radio frequency identification (personalized) device (RFID) without chip, in particular to a RFID tag (personalized) without chip, also referred to as chipless RFID tag.

Disclosed is an optical receiver. The optical receiver includes a circuit board, a base member, a photodetector mounted on the base member, a transimpedance amplifier, and a capacitor. The base member is disposed between a first grounding pattern and a second grounding pattern on a first side of the circuit board. The transimpedance amplifier is mounted on the first grounding pattern. The capacitor is mounted on the second grounding pattern. The first wiring pattern and the second wiring pattern are apart from both the first grounding pattern and the second grounding pattern in a plan view of the first side. The first grounding pattern is electrically connected to the second grounding pattern through a grounding pattern formed on the first side.

A display device includes a display panel, a data driver which transmits a data voltage to the display panel, a first flexible printed circuit board attached to the display panel and including an input side wiring electrically connected to the data driver, a first printed circuit board (PCB) electrically connected to the input side wiring to transmit a high-speed driving signal to the data driver, and a metal tape overlapping the input side wiring in a plan view and attached on the first flexible printed circuit board, where a part of the metal tape overlapping the input side wiring in the plan view defines an opening.

A printed circuit board includes a plurality of layers including attachment layers and routing layers; and columns of via patterns formed in the plurality of layers, wherein via patterns in adjacent columns are offset in a direction of the columns, each of the via patterns comprising: first and second signal vias forming a differential signal pair, the first and second signal vias extending through at least the attachment layers; and at least one conductive shadow via located between the first and second signal vias of the differential pair. In some embodiments, at least one conductive shadow via is electrically connected to a conductive surface film.