The method for manufacturing a display device includes forming a light emitting element and a terminal on a substrate, forming a sealing film including a first inorganic insulating film and a second inorganic insulating film to cover the light emitting element and the terminal, forming a resist having a taper shape in which a thickness of an end portion on the sealing film becomes thinner as it goes to the terminal side by using a gray-tone mask, forming a taper shape in which thicknesses in end portions of the first inorganic insulating film and the second inorganic insulating film becomes thinner as it goes to the terminal side by etching, forming a touch electrode above the sealing film and forming wiring connected to the terminal via the end portions together with connecting to the touch electrode for detecting a touched position.

A method for making an electroluminescent marking on an exterior wall of an aircraft, including a step of superpositioning of layers designed or configured to produce the electroluminescent marking on a first face of a flexible backing distinct from the aircraft to obtain a marking tape and a step of affixing the marking tape to the exterior wall of the aircraft. The disclosure herein also concerns a marking tape for the implementing of the method, a marking device obtained from the method, and an aircraft comprising the marking device.

A method for making an electroluminescent marking on an exterior wall of an aircraft, including a step of superpositioning of layers designed or configured to produce the electroluminescent marking on a first face of a flexible backing distinct from the aircraft to obtain a marking tape and a step of affixing the marking tape to the exterior wall of the aircraft. The disclosure herein also concerns a marking tape for the implementing of the method, a marking device obtained from the method, and an aircraft comprising the marking device.

A method is described for driving light emission of a light emitting device that includes first and second electrode layers, and first and second groups of light emitting diodes between the first and second electrode layers. A first electrode voltage is provided to the first and second electrode layers to conduct the first group of light emitting diodes, and then a second electrode voltage is provided to the first and second electrode layers to conduct the second group of light emitting diodes.

A method is described for driving light emission of a light emitting device that includes first and second electrode layers, and first and second groups of light emitting diodes between the first and second electrode layers. A first electrode voltage is provided to the first and second electrode layers to conduct the first group of light emitting diodes, and then a second electrode voltage is provided to the first and second electrode layers to conduct the second group of light emitting diodes.

A wiring line is provided on a TFT layer, in which the wiring line is formed in the same layer and formed of the same material as those of a reflection electrode. The reflection electrode includes a plurality of metallic conductive layers made up of a low resistance metallic material, an oxide-based lower transparent conductive layer provided on a lower surface side of a lowermost metallic conductive layer constituting a lowermost layer, an oxide-based upper transparent conductive layer having light reflectivity and provided on an upper surface side of an uppermost metallic conductive layer constituting an uppermost layer, and an oxide-based intermediate transparent conductive layer provided between the plurality of metallic conductive layers.

A display device includes a thin film transistor layer including a first interlayer insulation film, a first wiring layer, a second interlayer insulation film, a second wiring layer, a third interlayer insulation film, a third wiring layer, a first planarization film, a fourth wiring layer, and a second planarization film; and a first damming wall in a frame area separated from the first and second planarization film in a display area by a first slit. There is provided a fourth interlayer insulation film between the third and fourth wiring layer. The fourth interlayer insulation film covers an edge of either one or both of a first frame line and a second frame line as the third wiring layer in a region where the first frame line is located opposite the second frame line in a plan view, the edge facing the display area and being exposed in the first slit.

A first electronic component (10) includes a terminal (142) and a substrate (100). The substrate (100) includes the terminal (142). At least a portion of a second electronic component (20) overlaps the terminal (142) of the first electronic component (10). A resin film (300) electrically connects the terminal (142) of the first electronic component (10) and the second electronic component (20). The resin film (300) includes a first portion (310) and a second portion (320). The first portion (310) of the resin film (300) overlaps the terminal (142) and the second electronic component (20) when viewed from a predetermined direction (D). The second portion (320) of the resin film (300) does not overlap the substrate (100) or the terminal (142), and overlaps the second electronic component (20) when viewed from the predetermined direction (D).

A first electronic component (10) includes a terminal (142) and a substrate (100). The substrate (100) includes the terminal (142). At least a portion of a second electronic component (20) overlaps the terminal (142) of the first electronic component (10). A resin film (300) electrically connects the terminal (142) of the first electronic component (10) and the second electronic component (20). The resin film (300) includes a first portion (310) and a second portion (320). The first portion (310) of the resin film (300) overlaps the terminal (142) and the second electronic component (20) when viewed from a predetermined direction (D). The second portion (320) of the resin film (300) does not overlap the substrate (100) or the terminal (142), and overlaps the second electronic component (20) when viewed from the predetermined direction (D).

A system and method for producing a conformal electroluminescent coating on an object wherein an electrically conductive base backplane film layer is applied upon a substrate. One or more intermediate layers, such as dielectric, or phosphor film layers, is/are applied upon the conductive backplane film layer. An electrode film layer is applied upon the one or more intermediate layers using a substantially transparent, electrically conductive material. The electroluminescent phosphor is excitable by an electrical field established across the phosphor film layer such that the device emits electroluminescent light upon application of an electrical charge between the conductive backplane film layer and the electrode film layer.