A filter circuit includes: a first element that is a first capacitor or a first inductor connected in series between input and output terminals; a second element that is connected in parallel to the first element between the input and output terminals, is a second inductor when the first element is the first capacitor, and is a second capacitor when the first element is the first inductor; a third element that is connected in parallel to the first element and in series with the second element between the input and output terminals, is a third inductor when the first element is the first capacitor, and is a third capacitor when the first element is the first inductor; and an acoustic wave resonator having a first end coupled to a first node between the second element and the third element and a second end coupled to a ground terminal.

A photovoltaic device including: a first amorphous semiconductor layer (3) and a second amorphous semiconductor layer (4) both on a back face of a semiconductor substrate (1); electrodes (5, 6); and a wiring board (8). The electrodes (5, 6) are disposed on the first amorphous semiconductor layer (3) and the second amorphous semiconductor layer (4) respectively. The wiring board (8) has wires (82) connected to the electrodes (5) by a conductive adhesive layer (7). The wiring board (8) has wires (83) connected to the electrodes (5) by the conductive adhesive layer (7). The electrodes (5) include conductive layers (51, 52). The electrodes (6) include conductive layers (61, 62). The conductive layers (51, 61) are composed primarily of silver. The conductive layers (52, 62) cover the conductive layers (51, 52) respectively. Each conductive layer (52, 62) is composed of a metal more likely to be oxidized than silver.

The present disclosure relates to branched proximal connectors for high density neural interfaces and methods of microfabricating the branched proximal connectors. Particularly, aspects of the present disclosure are directed to a branched connector that includes a main body having a base portion of a supporting structure and a plurality of conductive traces formed on the base portion, and a plurality of plugs extending from the main body. Each plug of the plurality of plugs include an end portion of the supporting structure comprised of the one or more layers of dielectric material, and a subset of conductive traces from the plurality of conductive traces. Each trace from the subset of conductive traces terminates at a bond pad exposed on a surface of the end portion of the supporting structure.

An electronic device according to one embodiment includes a wiring substrate, the wiring substrate having a first wiring connected to a first external terminal and a second wiring connected to a second external terminal and extending along the first wiring. Additionally, the above electronic device has a semiconductor device mounted on the above wiring substrate and electrically connected to each of the first and second wirings. Further, the above electronic device has a capacitor mounted on the above wiring substrate and electrically connected to the semiconductor device via each of the above first and second wirings. Furthermore, a distance between the above semiconductor device and capacitor is shorter than a distance between each of the above first and second external terminals and the above capacitor.

A package comprises a body, and an electrically conductive pattern supported by said body. An interface portion is configured to receive a module to a removable attachment with the package. The electrically conductive pattern comprises, at least partly within said interface portion, a wireless coupling pattern that constitutes one half of a wireless coupling arrangement.

A power converter in which a plurality of semiconductor switches are connected to a drive circuit configured to control states of the semiconductor switches, the power converter including: a plurality of semiconductor switches having the same reference potential; a drive circuit configured to control states of the plurality of semiconductor switches; and a multilayer substrate in which a wiring that connects the drive circuit and the plurality of semiconductor switches and includes a reference potential wiring and a control signal wiring is disposed, wherein, in the multilayer substrate, the reference potential wiring and the control signal wiring are disposed in different layers at positions overlapping in a substrate lamination direction, and within the wiring, in a common wiring portion from the drive circuit to a branch point of the wiring and a branch wiring portion from the branch point to each of the semiconductor switches, an impedance of the common wiring portion is set to be lower than an impedance of the branch wiring portion and wiring impedances of the branch wiring portions are matched to each other.

A PCBA for use in a high-energy broadband electric field includes a low-voltage power supply and alternating conductive and dielectric layers. An outermost one of the conductive layers includes a dielectric surface switch having closely-spaced switch contacts. The first switch contact is connected to the positive terminal and the second switch contact connected to the negative terminal. Vias connect the conductive layers to the terminals through the respective first and second switch contacts to form power and ground planes. A metamaterial layer of nickel is doped with up to 20 percent phosphorus or chromium by weight, has a uniform thickness of less than 5 m, is sandwiched between interfacing surfaces of a pair of the conductive and dielectric layers, and evenly coats one of the interfacing surfaces. A sonobuoy system includes the PCBA, e.g., an Electronic Function Select board, a cylindrical housing, and an acoustic array.

An electronic component includes: a plurality of multilayer capacitors stacked in multiple rows and columns and each having external electrodes on both ends thereof in a first direction; and a board including a body and a connection portion. The connection portion includes: a plurality of positive electrode land patterns; a plurality of negative electrode land patterns; positive and negative electrode terminal patterns formed on a lower surface of the body to be spaced apart from each other in the first direction; a positive electrode connection portion connecting the plurality of positive electrode land patterns to the positive electrode terminal pattern; and a negative electrode connection portion connecting the plurality of negative electrode land patterns to the negative electrode terminal pattern.

Disclosed is an inter-board connection structure including a signal line conductor (22) provided in an outer layer of a printed circuit board (100), a signal line conductor (24) extending in a direction from the signal line conductor (22) to a signal pad (21), and forming a capacitive component between itself and a signal pad (21), and a signal line conductor (23) branching and extending from a connecting portion between the signal line conductor (22) and the signal line conductor (24), and electrically connected to the signal pad (21).

A circuit board includes: a substrate; a first power feed line disposed so as to be close to a plurality of radiating elements provided on a surface of the substrate and to extend in a first direction; a first connection conductor extending in a second direction orthogonal to the first direction, one end of the first connection conductor being connected to the first power feed line substantially at its central portion in the first direction; and a second power feed line that has a first line part extending in a third direction orthogonal to the second direction, the first line part joining to another end of the first connection conductor, and also has a second line part branching from the first line part, the second line part joining to the other end from a third direction side.