Graphene ink compositions comprising nitrocellulose and related methods of use comprising either thermal or photonic annealing.

A display device includes a display panel, and an electrostatic capacitive type touch panel which is formed in an overlapping manner with the display panel. A plurality of X electrodes and a plurality of Y electrodes intersecting with the X electrodes. A first signal line supplies signals to the X electrodes, a second signal line supplies signals to the Y electrodes, and the first signal line and the second signal line are formed on a flexible printed circuit board. A dummy electrode is formed adjacent to an electrode portion of each X electrode and electrode portion of each Y electrode, the dummy electrode does not overlap the X electrode and the Y electrode, and the dummy electrode does not electrically connect with the first and second signal lines.

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 display device includes a display panel, a printed circuit board attached to the display panel and including a ground potential supply terminal, a circuit, and a wiring pattern electrically coupling the ground potential supply terminal and the circuit, and a housing that contacts a coupling place provided to the wiring pattern and is attached to the printed circuit board through the coupling place. The wiring pattern includes a terminal wiring pattern electrically coupled with the ground potential supply terminal, a circuit wiring pattern branched from a branch part at a predetermined position on the terminal wiring pattern and electrically coupled with the circuit, and a housing wiring pattern branched from the branch part of the terminal wiring pattern and electrically coupled with the coupling place, and the circuit wiring pattern and the housing wiring pattern are uncoupled with each other at any place other than the branch part.

A wiring board includes a signal line, a shield member whose main surface extends along the signal line, and a branch line that is electrically connected to the shield member, that includes a leading end that is opened, and that extends in a direction parallel with the main surface of the shield member.

A method may include receiving a first and a second complementary signal to provide differential signaling. The method may further include providing a first conductor trace to transport the first complementary signal; providing a second conductor trace to transport the second complementary signal, the second conductor trace immediately adjacent to the first conductor trace; providing a third conductor trace to transport the first complementary signal, the third conductor trace immediately adjacent to the second conductor trace; and providing a fourth conductor trace to transport the second complementary signal, the fourth conductor trace immediately adjacent to the third conductor trace.

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 disclosure relates to a power supply module. The power supply module may include a flexible substrate and a plurality of battery cells distributed in an array on one side of the flexible substrate. Adjacent battery cells of the plurality of battery cells on each line in a first direction may be connected in series by a flexible connector to form a plurality of lines of battery cells, and the plurality of lines of battery cells may be connected in parallel through a first electrode.

The invention relates to an element in the shape of a sensor, an active electronic component, a switch, a circuit, or an electric conducting path for integration into a surrounding medium. The element is penetrable by the surrounding medium and has a porous, non-conductive substrate and at least one circuit trace made of conductive material present on the substrate. The openings of the substrate are open in an area of the circuit trace. The use and manufacture of the element are also provided.

A printed circuit board includes a printed wiring board, and a first element and a second element mounted on the printed wiring board. The printed wiring board includes a plurality of first signal lines and a plurality of second signal lines. The plurality of first signal lines each include a first main line, a first branch line, and a second branch line. The plurality of second signal lines each include a second main line, a third branch line, and a fourth branch line. The first branch line includes a first conductor pattern disposed in a first conductor layer. The second branch line includes a second conductor pattern disposed in the first conductor layer. The third branch line includes a third conductor pattern disposed in a second conductor layer. The fourth branch line includes a fourth conductor pattern disposed in the second conductor layer.