Abstract: In an intersecting region of a bundle of wirings in a column direction and a bundle of wirings in a row direction, a column wiring block region arranged with detection column wirings and first floating wirings and a row wiring block region arranged with detection row wirings and second floating wirings are disposed in a staggered manner. The bundle of wirings in the column direction includes a first compensation region arranged with the detection column wirings which connect between the detection column wirings in the column wiring block regions adjacent to each other in a diagonal direction. The bundle of wirings in the row direction includes a second compensation region arranged with the detection row wirings which electrically connect between the detection row wirings in the row wiring block regions adjacent to each other in a diagonal direction.

Abstract: A touch screen according to the present invention includes a plurality of row direction wires and a plurality of column direction wires provided to intersect with each other through an insulating film in planar view. The plurality of row direction wires includes a mesh-like wire having a plurality of first row direction wires extending in the longitudinal direction and a plurality of second row direction wires extending in the lateral direction. The plurality of column direction wires includes a mesh-like wire having a plurality of first column direction wires extending in the longitudinal direction and a plurality of second column direction wires extending in the lateral direction, and each of the first row direction wires and each of the first column direction wires are provided at an interval of p/3 or more.

Abstract: A lower electrode and an upper electrode have crossing portions where first element wiring of a mesh of the lower electrode and second element wiring of a mesh of the upper electrode cross each other in three dimensions. The lower electrode includes row-direction wiring and a floating electrode that are insulated from each other by disconnected portions provided to the first element wiring other than the crossing portions. The upper electrode includes column-direction wiring and a floating electrode that are insulated from each other by disconnected portions provided to the second element wiring other than the crossing portions.

Abstract: A touch screen according to the present invention includes: a substrate; and a plurality of row direction wirings and a plurality of column direction wirings which are disposed on the substrate to intersect through an insulating film in a stereoscopic view, and at an intersection portion of each of the row direction wirings and each of the column direction wirings, wiring width of at least one of the row direction wiring and the column direction wiring is wider than a portion other than the intersection portion in a plan view.

Abstract: A touch screen according to the present invention includes: a transparent substrate; a plurality of row-direction wirings and a plurality of column-direction wirings provided on the transparent substrate, the row-direction wirings and the column-direction wirings intersecting via an inter-layer insulating film with each other in a stereoscopic view; a plurality of lead-out wirings each provided to be electrically extended from each of first ends of the said row-direction wirings and the column-direction wirings; and a shield wiring provided to surround in a planar view the row-direction wirings, the column-direction wirings, and the lead-out wirings, wherein the row-direction wirings, the column-direction wirings, and the shield wiring have comb-teeth parts which are formed to have comb-teeth shapes such that distances from the shield wiring to the row-direction wirings and the column-direction wirings are small at predetermined parts.

Abstract: Detection column wires and detection row wires are formed by fine wires made of a light-reflective conductive material. The detection column wires are divided into a plurality of column-direction wire bundles each including a predetermined number of detection column wires electrically connected to one another. The detection row wires are divided into a plurality of row-direction wire bundles each including a predetermined number of detection row wires electrically connected to one another. Reflected light distribution patterns are further provided. The reflected light distribution patterns each include a curved portion that is curved when viewed from a direction perpendicular to a surface of a touch screen, are arranged so that normals to the curved portion are directed towards all directions, and are dispersed so that regions, of curved portions, in which normals are perpendicular to a longitudinal direction of pixels are not aligned with each other in the longitudinal direction of the pixels.

Abstract: A touch screen according to the present invention includes a transparent substrate, a first detection electrode formed on the transparent substrate, a second detection electrode disposed to sterically cross the first detection electrode via an interlayer insulating film, and a polarizing plate bonded to cover the second detection electrode. Each of the first detection electrode and the second detection electrode includes, as a repetition unit, thin wire electrodes that incline in different directions and cross each other. The thin wire electrodes are formed of a combination of a plurality of conductive thin wires extending in a direction inclined 10 degrees or less from a transmission axis direction or an absorption axis direction of the polarizing plate.

Abstract: In an intersecting region of a bundle of wirings in a column direction and a bundle of wirings in a row direction, a column wiring block region arranged with detection column wirings and first floating wirings and a row wiring block region arranged with detection row wirings and second floating wirings are disposed in a staggered manner. The bundle of wirings in the column direction includes a first compensation region arranged with the detection column wirings which connect between the detection column wirings in the column wiring block regions adjacent to each other in a diagonal direction. The bundle of wirings in the row direction includes a second compensation region arranged with the detection row wirings which electrically connect between the detection row wirings in the row wiring block regions adjacent to each other in a diagonal direction.

Abstract: A photoelectric conversion device is provided in which a first photoelectric conversion module having a plurality of first photoelectric conversion elements formed on one surface of a first translucent insulated substrate and a second photoelectric conversion module having a plurality of photoelectric conversion elements formed on one surface of a second translucent insulated substrate are bonded together with the first photoelectric conversion elements and the second photoelectric conversion elements placed on an inner side. The photoelectric conversion device includes a plurality of photoelectric conversion element pairs formed by electrically connecting, in series, the first photoelectric conversion elements and the second photoelectric conversion elements arranged in positions opposed to each other. All the photoelectric conversion element pairs are electrically connected in series.

Abstract: A plasma CVD apparatus includes: a film forming chamber; a holding member that holds a substrate to be processed that is set in the film forming chamber; a shower head that is set in the film forming chamber to face the holding member, and supplies raw material gas and generates a plasma of the raw material gas; a radical generation chamber that is set at an opposite side of the shower head relative to the holding member and generates radicals of process gas; and an openable and closable shutter that is provided between the shower head and the radical generation chamber.

Abstract: A method for manufacturing a thin-film photoelectric conversion device includes forming a first electrode layer, a photoelectric conversion layer having three conductive semiconductor layers laminated thereon, and a second electrode layer sequentially laminated in this order on a translucent insulating substrate, such that adjacent thin-film photoelectric conversion cells are electrically connected in series, isolating a thin-film photoelectric conversion cell into a plurality of thin-film photoelectric conversion cells by forming isolation trenches that reach from the second electrode layer to the first electrode layer, removing a part of sidewalls at an external periphery of the thin-film photoelectric conversion cells positioned at an external peripheral edge of the thin-film photoelectric conversion device, along with the external periphery, and modifying into insulation layers by performing an oxidation process on all of the sidewalls of the isolation trenches of the photoelectric conversion layer and al

Abstract: A photoelectric conversion device is provided in which a first photoelectric conversion module having a plurality of first photoelectric conversion elements formed on one surface of a first translucent insulated substrate and a second photoelectric conversion module having a plurality of photoelectric conversion elements formed on one surface of a second translucent insulated substrate are bonded together with the first photoelectric conversion elements and the second photoelectric conversion elements placed on an inner side. The photoelectric conversion device includes a plurality of photoelectric conversion element pairs formed by electrically connecting, in series, the first photoelectric conversion elements and the second photoelectric conversion elements arranged in positions opposed to each other. All the photoelectric conversion element pairs are electrically connected in series.

Abstract: A thin film solar cell device of higher power generation efficiency, having a tandem structure in which a transparent electrode layer is inserted between a back surface electrode layer and a photoelectric conversion layer and between a plurality of stacked photoelectric conversion layers. A first electricity conducting path is obtained by forming a thin film made of a conductive material (with specific resistance<10?4 ?km) in a micropore penetrating an intermediate transparent electrode layer and a first insulating layer, for electrically connecting first and second photoelectric conversion layers to each other. A second electricity conducting path having the same structure also electrically connects the second photoelectric conversion layer and a back surface electrode layer to each other. The gross area of an electricity conducting path of the first and second electricity conducting paths is set in a range not less than 1×10?7 and not more than 4×10?6 relative to the area of the cell.

Abstract: A method for manufacturing a thin-film photoelectric conversion device includes forming a first electrode layer, a photoelectric conversion layer having three conductive semiconductor layers laminated thereon, and a second electrode layer sequentially laminated in this order on a translucent insulating substrate, such that adjacent thin-film photoelectric conversion cells are electrically connected in series, isolating a thin-film photoelectric conversion cell into a plurality of thin-film photoelectric conversion cells by forming isolation trenches that reach from the second electrode layer to the first electrode layer, removing a part of sidewalls at an external periphery of the thin-film photoelectric conversion cells positioned at an external peripheral edge of the thin-film photoelectric conversion device, along with the external periphery, and modifying into insulation layers by performing an oxidation process on all of the sidewalls of the isolation trenches of the photoelectric conversion layer and al

Abstract: A plasma CVD apparatus includes: a film forming chamber; a holding member that holds a substrate to be processed that is set in the film forming chamber; a shower head that is set in the film forming chamber to face the holding member, and supplies raw material gas and generates a plasma of the raw material gas; a radical generation chamber that is set at an opposite side of the shower head relative to the holding member and generates radicals of process gas; and an openable and closable shutter that is provided between the shower head and the radical generation chamber.