A semiconductor device, while being small, makes it possible to achieve low inductance responding to high speed switching. The semiconductor device includes a plurality of conductive pattern members, on each of which is mounted one or a plurality of power semiconductor chips, and a printed circuit board wherein a chip rod-form conductive connection member connected to the power semiconductor chip and a pattern rod-form conductive connection member connected to the conductive pattern member are disposed on the surface opposing the conductive pattern member. The conductive pattern member is formed of a narrow portion and a wide portion, the narrow portion of at least one conductive pattern member and the printed circuit board are connected by the pattern rod-form conductive connection member, and a current path is formed between the conductive pattern member and the power semiconductor chip connected via the chip rod-form conductive connection member to the printed circuit board.

The disclosure relates to a touch panel. The touch panel includes a substrate having a surface, a metal nanowire film, at least one electrode, and a conductive trace. The metal nanowire film includes a metal nanowire film. The metal nanowire film includes a number of first metal nanowire bundles parallel with and spaced from each other. Each of the number of first metal nanowire bundles includes a number of first metal nanowires parallel with each other. The first distance between adjacent two of the number of first metal nanowires is less than the second distance between adjacent two of the number of first metal nanowire bundles.

A support structure located at a bottom of a ball grid array (BGA) is provided. The support structure includes a printed circuit board (PCB) having first positioning pin holes, an interface plate having second positioning pin holes which correspond to the first positioning pin holes arranged on the PCB, a support film arranged on the PCB and having support portions, and positioning components penetrating the first positioning pin holes and the second positioning pin holes corresponding to the first positioning pin holes to assemble the support film on the PCB and the interface plate.

The disclosure relates to a touch panel. The touch panel includes a substrate having a surface, a transparent conductive layer, at least one electrode, and a conductive trace. The transparent conductive layer includes a metal nanowire film. The metal nanowire film includes a number of first metal nanowire bundles parallel with and spaced from each other. Each of the number of first metal nanowire bundles includes a number of first metal nanowires parallel with each other. The first distance between adjacent two of the number of first metal nanowires is less than the second distance between adjacent two of the number of first metal nanowire bundles.

In a circuit module of the present disclosure, one or more solder balls have an ellipsoidal shape, are located in an inter-board region between an upper circuit board and a lower circuit board, and electrically connect the upper circuit board and the lower circuit board. The size of the second solder ball is larger than the size of the first solder ball. A first sealing resin is provided in the inter-board region so as to be in contact with a first lower main surface and a second upper main surface and to cover surfaces of the one or more second solder balls.

Techniques, elements, and assemblies for high current board-level conductive pathways on printed circuit boards are provided. In one example, a method includes providing a circuit board having footprint elements that define a route between endpoints. The method includes applying solder paste onto the footprint elements, and placing modular conductive blocks along the route onto the solder paste associated with the footprint elements. The method also includes forming, by at least a solder reflow operation, an assembly comprising the circuit board and the modular conductive blocks that establishes a conductive pathway along the route with series coupling of the modular conductive blocks to each other.

Provided is a conductive pattern having at least one unit conductive pattern forming one touch pixel according to an aspect of the present invention. The at least one unit conductive pattern includes a plurality of nanostructures each having opposite ends. A ratio of nanostructures, both opposite ends of which are in contact with edges of the at least one unit conductive pattern to all nanostructures included in the at least one unit conductive pattern is 70% or more.

A fuse according to an embodiment disclosed herein includes a printed circuit board (PCB); a conductive pattern disposed on the PCB; a film disposed at lateral sides of the conductive pattern or on a partial region of the conductive pattern to leave an open region; and a coating disposed on the conductive pattern and the film.

A transparent conductive film comprises a transparent substrate and a metal wiring portion formed thereon. A thin metal wire contained in an electrode portion in the metal wiring portion has a surface shape satisfying the condition of Ra.sup.2/Sm>0.01 m and has a metal volume content of 35% or more. Ra represents an arithmetic average roughness in micrometers and is equal to or smaller than the thickness of a metal wiring located in a position where the surface roughness is measured. Sm represents an average distance between convex portions and is 0.01 m or more.

A transparent conductive film comprises a transparent substrate and a metal wiring portion formed thereon. A thin metal wire contained in an electrode portion in the metal wiring portion has a surface shape satisfying the condition of Ra.sup.2/Sm>0.01 m and has a metal volume content of 35% or more. Ra represents an arithmetic average roughness in micrometers and is equal to or smaller than the thickness of a metal wiring located in a position where the surface roughness is measured. Sm represents an average distance between convex portions and is 0.01 m or more.