Abstract: Object: To provide an FPC integrated capacitance switch and a method of manufacturing the same, which allow an FPC portion to have high electrical reliability when used in a bent manner and to have wiring lines to be densely arranged.

Abstract: A pressure detection device includes a pressure sensitive sensor and a pressure calculating unit. The pressure sensitive sensor includes an upper base substrate, a lower base substrate, and a pressure sensitive layer formed on a surface of one of the base substrates. The pressure sensitive layer includes a pair of pressure sensitive portions located symmetrically with respect to a plane center. A first elastic body and a second elastic body are disposed at a position to which a pressing force is applied. A first electrode and a second electrode are disposed with the pressure sensitive layer. The pressure calculating unit is configured to cause the pressure sensitive sensor to detect a pressure change for each of the pair of pressure sensitive portions and to add a sign-reversed pressure change in a pressure sensitive portion to a pressure change in the other pressure sensitive portion to amplify an output.

Abstract: A pressure sensor is disclosed. The pressure sensor includes a common electrode, a plurality of individual electrodes, a plurality of thin-film transistors and a common pressure-sensitive layer. The common electrode is formed as a layer. The plurality of individual electrodes are arranged in a matrix opposing the common electrode. The plurality of thin-film transistors are respectively located corresponding to the individual electrodes on sides of the individual electrodes opposite to the common electrode, where one or two or more adjacent thin-film transistors are connected to one individual electrode. The common pressure-sensitive layer is disposed on a surface of the common electrode on a side facing the plurality of individual electrodes. The plurality of individual electrodes include a first electrode, and a second electrode that is thicker than the first electrode and therefore creates a smaller gap from the common pressure-sensitive layer than the first electrode.

Abstract: A display panel is attached to an appliance that includes first and second light sources, in which one of the first and second light sources is capable of being turned off when the other is turned on. The display panel basically includes a molded body, a front-side decorative layer, and a sheet-like member. The display panel is capable of individually illuminating a plurality of graphics, which is simultaneously molded and decorated, with light passing through a molded resin. In particular, a first graphic is illuminated in a first window by turning on the first light source, while a first back-side light-shielding region and a second front-side light-shielding region prevent a second graphic from being illuminated. The second graphic is illuminated in a second window by turning on the second light source, while a second back-side light-shielding region and a first front-side light-shielding region prevent the first graphic from being illuminated.

Abstract: A pressure sensor is disclosed. The pressure sensor includes a common electrode, sensitized electrodes, mountain-shaped pressure-sensitive layers, and thin-film transistors. The common electrode is formed as a layer. The sensitized electrodes are arranged in a matrix opposing the common electrode. The mountain-shaped pressure-sensitive layers are respectively formed over the sensitized electrodes on a side close to the common electrode. The thin-film transistors are disposed to correspond to the sensitized electrodes on sides of the sensitized electrodes opposite to the common electrode.

Abstract: A method for acquiring data from a resistive film touch panel includes: A step in which, in a first drive mode in which a first drive circuit sequentially drives a first drive electrode group of the plurality of drive electrodes, a first detection circuit detects a first detection electrode group of the plurality of detection electrodes, and a second detection circuit detects a second detection electrode group of the plurality of detection electrodes. A step in which, in a second drive mode in which a second drive circuit sequentially drives a second drive electrode group of the plurality of drive electrodes, the first detection circuit detects the first detection electrode group, and the second detection circuit detects the second detection electrode group.

Abstract: First to third electrode layers (1) are laminated. A dielectric (22) disposed between the second and third electrode layers can be elastically deformed by pressing force from the first electrode layer-side to reduce distance between the second and third electrode layers. The first electrode layer is composed of first electrodes (Rxc) along a first direction (X). The second electrode layer is composed of second electrodes (Txcf) along a second direction (Y) intersecting the first direction. The third electrode layer is composed of third electrodes (Rxf) along a third direction (X) intersecting the second direction. During position-detection, the second electrodes (Txcf) function as transmission-side position-detection electrodes and the first electrodes function as reception-side position detection electrodes to constitute a mutual-capacitance touch panel unit (31).

Abstract: A gas sensor, disposed projecting from a wiring member serving as a mounting target and including a first wire and a second wire, the gas sensor detecting a gas that produces water in a case that the gas is combusted by being supplied with a voltage from the first wire and the second wire and measuring a resistance value using the first wire and the second wire, the gas sensor including a resistor holding a catalyst that facilitates combustion of the gas, a first electrode terminal connected between one end of the resistor and the first wire, and a second electrode terminal connected between another end of the resistor and the second wire, and the first electrode terminal and the second electrode terminal are fixed to each other and form a water vapor diffusion cavity.

Abstract: [Object] To provide a method for producing an electrical wiring member having a layered structure of copper wiring and a blackening layer and to provide the electrical wiring member through a search for a material for the blackening layer, the material being etched at a rate close to that for the copper wiring under conditions where etching controllability is ensured. [Solution] A method for producing an electrical wiring member according to the present invention includes a step of forming, on at least one main surface of a substrate, a layered film 6 of a Cu layer 3 and CuNO-based blackening layers (2a and 2b); a step of forming a resist layer 4a in a predetermined region on the layered film 6; and a step of removing a partial region of the layered film 6 by bringing the layered film 6 into contact with an etchant.

Abstract: A capacitive touch panel including: a single transparent substrate; a first electrode pattern formed on a first surface of the transparent substrate; a first dummy electrode pattern including a plurality of first dummy electrodes and formed on a region where the first electrode pattern is not formed; a second electrode pattern formed on a second surface of the transparent substrate; and a second dummy electrode pattern including a plurality of second dummy electrodes and formed on a region where the second electrode pattern is not formed, the first/second dummy electrodes are electrically insulated from the first/second electrode pattern by slits respectively, the slits of the second/first dummy electrodes include outermost first/third gaps and second/fourth gaps disposed inward of the first/third gaps respectively, and the third/second gaps and the fourth/first gaps are patterned to overlap each other in a plurality of dotted regions in a plan view.

Abstract: A molding with an integrated electrode pattern, including a resin molded body having a first surface and a second surface opposing each other; a first film that is formed on the first surface and that includes an electrode pattern and a first lead-out wire electrically connected to the electrode pattern, the first film not being covered by the resin molded body; and a second film that stands on the first surface, and that includes a second lead-out wire electrically connected to the first lead-out wire, the second film having a rectangular shape, and the resin molded body includes a pair of support wall portions formed integrally with the first surface so as to stand on the first surface and clamp both ends of a base part of the second film.

Abstract: A method for acquiring data from a resistive film touch panel includes: A step in which, in a first drive mode in which a first drive circuit sequentially drives a first drive electrode group of the plurality of drive electrodes, a first detection circuit detects a first detection electrode group of the plurality of detection electrodes, and a second detection circuit detects a second detection electrode group of the plurality of detection electrodes. A step in which, in a second drive mode in which a second drive circuit sequentially drives a second drive electrode group of the plurality of drive electrodes, the first detection circuit detects the first detection electrode group, and the second detection circuit detects the second detection electrode group.

Abstract: A capacitive touch panel including: a single transparent substrate; a first electrode pattern formed on a first surface of the transparent substrate; a first dummy electrode pattern including a plurality of first dummy electrodes and formed on a region where the first electrode pattern is not formed; a second electrode pattern formed on a second surface of the transparent substrate; and a second dummy electrode pattern including a plurality of second dummy electrodes and formed on a region where the second electrode pattern is not formed, the first/second dummy electrodes are electrically insulated from the first/second electrode pattern by slits respectively, the slits of the second/first dummy electrodes include outermost first/third gaps and second/fourth gaps disposed inward of the first/third gaps respectively, and the third/second gaps and the fourth/first gaps are patterned to overlap each other in a plurality of dotted regions in a plan view.

Abstract: Object: To provide a gas sensor having a small size and that can suppress gas detection problems caused by frost using only a small amount of power. Solution: A first electrode terminal (12) includes at least one first connection part (121) connected to a first wire and a first arm part (123) extending from the first connection part (121) to one end (11a) of a resistor (11). A second electrode terminal (13) includes at least one second connection part (131) connected to a second wire and a second arm part (133) extending from the second connection part (131) to the other end (11b) of the resistor (11). The first electrode terminal (12) and the second electrode terminal (13) are fixed to each other and form a water vapor diffusion cavity (S2) extending from the resistor (11) to a wiring member or the vicinity of the wiring member, with at least part of the first arm part (123) and at least part of the second arm part (133) coated with insulation.

Abstract: [Object] To provide a method for manufacturing a touch sensor capable of concurrently forming routed circuit patterns on both surfaces of a base film and capable of aligning the routed circuit patterns on the top and bottom surfaces with each other with high accuracy. [Solution] A method for manufacturing a touch sensor includes forming electrode patterns on both surfaces of a base film through concurrent light exposure on both surfaces and development using photosensitive electrically conductive films each including a support film, an electrically conductive layer disposed on the support film and containing an electrically conductive fiber, and a second photosensitive resin layer disposed on the electrically conductive layer. Routed circuit patterns obtained by patterning the light-shielding metal layers are formed in advance on both surfaces of the base film.

Abstract: A touch sensor with a circularly polarizing plate includes an electrostatic capacitance type touch sensor. A circularly polarizing plate is arranged on a visible side of the electrostatic capacitance type touch sensor. The sensor includes a transparent substrate and a plurality of first electrodes individually formed in a strip shape on the transparent substrate. The sensor additionally includes a plurality of second electrodes formed on a surface of the transparent substrate opposite to a surface on which the first electrodes are formed. The second electrodes have a strip shape in a manner of intersecting with the first electrodes. The first electrodes are made of a metal mesh. The second electrodes are made of a plurality of conductive nanowires, existing in a connecting state respectively so as to be conductively connected, and a binder resin holding the plurality of conductive nanowires on the second transparent substrate.

Abstract: A transfer sheet includes, on a base sheet, at least a release layer containing particles and having a surface roughness Ra of 0.15 to 1.0 ?m, a protective layer containing an ionizing radiation-curable urethane resin and having a Martens hardness of 2.0 to 40.0 N/mm2, and the adhesive layer containing an acrylic resin, that are laminated in this order. A decorative sheet is formed by transferring the transfer sheet on a support sheet. A decorative article is a resin molded article decorated by using the transfer sheet or the decorative sheet.

Abstract: A multipoint-measurement strain sensor which is free of a conduction failure originated from slippage at the time of lamination and which can reduce the material cost, and a method for producing the multipoint-measurement strain sensor are provided. A multipoint-measurement strain sensor 31 of the present invention includes a substrate film 34, a plurality of strain-sensing parts 33 formed on a first main surface 34a of the substrate film 34, routing circuits 37, 38 formed, in correspondence with the respective strain-sensing parts 33, on a second main surface 34b of the substrate film 34, and having outer connection terminals 37b, 38b near an outer edge of the substrate film 34, and a conductive paste 41, 42 to fill via holes 39, 40 such that each of the strain-sensing parts 33 is connected to the corresponding routing circuit 37, 38.

Abstract: A transfer sheet includes, on a base sheet, at least a release layer containing particles and having a surface roughness Ra of 0.15 to 1.0 ?m, a protective layer containing an ionizing radiation-curable urethane resin and having a Martens hardness of 2.0 to 40.0 N/mm2, and the adhesive layer containing an acrylic resin, that are laminated in this order. A decorative sheet is formed by transferring the transfer sheet on a support sheet. A decorative article is a resin molded article decorated by using the transfer sheet or the decorative sheet.

Abstract: In a touch panel, a plurality of first transparent electrodes are formed on a first substrate film, and extend in one direction. A plurality of first wires are formed on the first substrate film, and are connected to the plurality of first transparent electrodes. A plurality of second transparent electrodes are formed to intersect the plurality of first transparent electrodes. A plurality of second lead wires are connected to the plurality of second transparent electrodes. First and second shield layers are formed on the first base-material film, and overlap the plurality of second lead wires in a planar view. The first and second shield layers each have a length range set to not include lengths of ? of each of a plurality of frequencies within a specific range/n (n=2, 4, 6, . . . ), to not induce resonance phenomena with respect to the plurality of frequencies.