In an embodiment, with a capacitor mounting structure 200, series-connected first multilayer capacitor 211 and second multilayer capacitor 212 are placed in such a way that signals flow through them in the opposite directions, respectively. In addition, the series-connected first multilayer capacitor 211 and second multilayer capacitor 212 are placed in such a way that their respective internal electrode layers 211c, 212c face each other. The capacitor mounting structure can prevent the overall ESL value from increasing even when multilayer capacitors are connected in series.

A wiring substrate includes an insulating base that has a plate surface; a first circuit that is provided on the plate surface; a first terminal that is provided on the plate surface, and to which a mounting member is attached; a second terminal that is provided on the plate surface; a first wiring that connects the first circuit and the first terminal to each other; and a second wiring that connects the first terminal and the second terminal to each other, is electrically connected to the first wiring in the first terminal, and has a parallel section in which the second wiring is disposed close to and parallel to the first wiring without being electrically connected to the first wiring outside the first terminal.

A method and apparatus to electronically sense air flow and close a switch when air flow is adequate to operate an electric heater, HVACR system, or other apparatus. The apparatus is more reliable than electro-mechanical devices often used for this purpose.

A multilayer board includes a layered body including insulating base material layers that are laminated, and first and second signal lines, a first ground conductor including a first opening, a second ground conductor, a third ground conductor, and an interlayer connecting conductor. The first signal line overlaps the first opening when seen in a layering direction. The second signal line is provided on a layer different from a layer including the first signal line and includes a portion extending side by side with the first signal line when seen in the Z-axis direction. The first, second, and third ground conductors are connected by the interlayer connecting conductor. The third ground conductor is disposed on a layer including the first signal line or a layer positioned between the first signal line and the second signal line.

A printed wiring board (1) includes: a base substrate (3); a plurality of pads (15a, 17a) for electrical connection that are disposed at one surface side of the base substrate (3) and at a connection end portion (13) to be connected with another electronic component (50); wirings (9, 11) that are connected with the pads (15a, 17a); and engageable parts (28, 29) that are formed at side edge parts of the connection end portion (13) and are to be engaged with engagement parts (58) of the other electronic component (50) in the direction of disconnection. The flexible printed wiring board (1) further includes reinforcement layers (31, 32) that are disposed at the other surface side of the base substrate (3) and at a frontward side with respect to the engageable parts (28, 29) when viewed in the direction of connection with the other electronic component, and that are formed integrally with the wirings (9).

A substrate that enables increasing an allowable current value of a current path in a thickness direction of the substrate and narrowing spaces between multiple current paths, and the like are provided. To solve this subject, a substrate includes a sheet-shaped first base material (1) having a penetrating hole (1B) in the thickness direction and includes a second base material (2) fitted into the penetrating hole (1B). The second base material (2) includes multiple metal bodies (2B). The metal bodies (2B) penetrate in the thickness direction of the first base material (1) in a state of having an end exposed at each of a first surface and a second surface of the second base material (2) that face each other in the thickness direction.

A printed wiring board includes an insulation layer, conductive pads formed on the insulation layer and positioned to connect an electronic component, and a conductive wiring pattern including first and second conductive patterns and formed on the insulation layer such that the conductive wiring pattern is extending between the conductive pads. The first pattern includes first wiring lines, the second pattern includes second wiring lines, the first and second conductive patterns are formed such that the first wiring lines and the second wiring lines are alternately arrayed on the insulation layer, each of the first wiring lines includes a first metal layer formed on an interface with the insulation layer, each of the second wiring lines includes a second metal layer formed on an interface with the insulation layer, and the first metal layer includes a metal material which is different from a metal material forming the second metal layer.

A component carrier includes a stack having at least one electrically insulating layer structure and a plurality of electrically conductive layer structures, and a component embedded in the stack and having an array of pads on a main surface of the component. A first electrically conductive connection structure of the electrically conductive layer structures electrically connects a first pad of the pads up to a first wiring plane, and a second electrically conductive connection structure of the electrically conductive layer structures electrically connects a second pad of the pads up to a second wiring plane being different from the first wiring plane.

A transmission line component includes an insulation substrate, signal line conductors, and a common-mode choke coil. The insulation substrate is made of a flexible material, and has a shape extending in a first direction. The signal line conductors are on or in the insulation substrate, and extend mainly in the first direction. The common-mode choke coil includes linear conductors on or in the insulation substrate, and is connected to the signal line conductors. The insulation substrate includes a first signal line portion in which the signal line conductors are provided, and a coil portion in which the common-mode choke coil is provided in the first direction. The insulation substrate includes a bent portion in the first signal line portion.

Provided are a nano-scale LED assembly and a method for manufacturing the same. First, a nano-scale LED device that is independently manufactured may be aligned and connected to two electrodes different from each other to solve a limitation in which a nano-scale LED device having a nano unit is coupled to two electrodes different from each other in a stand-up state. Also, since the LED device and the electrodes are disposed on the same plane, light extraction efficiency of the LED device may be improved. Furthermore, the number of nano-scale LED devices may be adjusted. Second, since the nano-scale LED device does not stand up to be three-dimensionally coupled to upper and lower electrodes, but lies to be coupled to two electrodes different from each other on the same plane, the light extraction efficiency may be very improved. Also, since a separate layer is formed on a surface of the LED device to prevent the LED device and the electrode from being electrically short-circuited, defects of the LED electrode assembly may be minimized. Also, in preparation for the occurrence of the very rare defects of the LED device, the plurality of LED devices may be connected to the electrode to maintain the original function of the nano-scale LED electrode assembly.