Abstract: An OLED display device includes a substrate, an active element array, at least one OLED, a light absorption layer or an optical scattering layer, and an encapsulation plate. The active element array and the OLED are disposed over an upper surface of the substrate. The OLED includes a first electrode, a second electrode, and an organic light-emitting layer. The first electrode is disposed on a side adjacent to the active element array, and the second electrode is opposite to the first electrode. Both the first and second electrodes have a high transmittance and a low reflection in a wavelength range of visible light. The organic light-emitting layer is interposed between the first and second electrodes. The light absorption layer or optical scattering layer is disposed between the OLED and the substrate. The encapsulation plate is disposed over the second electrode.

Abstract: An OLED touch display device includes an OLED display and a laminated package component. The laminated package component covers the OLED display and includes a quarter-wave plate, a liquid crystal polarizer and a touch sensor unit. The touch sensor unit is a single-layer electrode structure.

Abstract: Present invention discloses a touch panel and a manufacturing method thereof, the touch panel comprises: a substrate; a silver nano-wire electrode layer provided on the substrate comprising a connecting area and a non-connecting area; a first protective layer provided on silver nano-wire electrode layer having a first hole corresponding to connecting area; a second protective layer provided on first protective layer having a second hole corresponding to position of first hole; and a connecting wire provided on second protective layer connected to silver nano-wire electrode layer in connecting area through second hole and first hole. With the touch panel, the problem that etching solution can't seep when a single protective layer is too thick and the problem that a silver nano-wire layer is easily oxidized and the adhesion of the silver nano-wire layer is poor when a single protective layer is too thin can be avoided.

Abstract: A liquid crystal display device and a viewing angle switching method are provided. The liquid crystal display device includes a display panel, a backlight source, and a light adjustment liquid crystal film disposed between the display panel and the backlight source. The light adjustment liquid crystal film includes an upper substrate, a lower substrate disposed opposite to the upper substrate, and a liquid crystal layer located between the upper substrate and the lower substrate. The upper substrate is provided with an upper electrode on a side thereof facing the lower substrate. The lower substrate is provided with a lower electrode on a side thereof facing the upper substrate. The light adjustment liquid crystal film is configured to change a backlight exit angle of the light emitted by the backlight after passing through the display panel by applying a voltage between the upper electrode and the lower electrode.

Abstract: The present disclosure provides a touch-panel display device. The touch-panel device comprises a transparent substrate including a first surface and a second surface on opposite sides of the transparent substrate, respectively, a display module at the first surface side of the transparent substrate, and a first sensing electrode layer, disposed between the transparent substrate and the display module, including a first nanostructure layer having first regions and second regions, the first regions being electrically isolated from each other by the second regions, and a haze difference between the first regions and the second regions is not greater than 0.1%.

Abstract: An OLED display device includes a substrate, an active element array, at least one OLED, a light absorption layer or an optical scattering layer, and an encapsulation plate. The active element array and the OLED are disposed over an upper surface of the substrate. The OLED includes a first electrode, a second electrode, and an organic light-emitting layer. The first electrode is disposed on a side adjacent to the active element array, and the second electrode is opposite to the first electrode. Both the first and second electrodes have a high transmittance and a low reflection in a wavelength range of visible light. The organic light-emitting layer is interposed between the first and second electrodes. The light absorption layer or optical scattering layer is disposed between the OLED and the substrate. The encapsulation plate is disposed over the second electrode.

Abstract: The present disclosure provides a method of forming a nanoscale conductive film. The method comprises providing a nanoscale base film, forming a first patterned insulating layer on the nanoscale base film, and etching the nanoscale base film in a current generation system, using the first patterned insulating layer as a mask. The nanoscale base film includes a substrate, a first overcoat on one side of the substrate, and a first nano material layer laminated between the substrate and the first overcoat. The first patterned insulating layer is formed on the first overcoat, exposing portions of the first overcoat. In the first nano material layer, first regions are masked by the first insulating layer and second regions are not masked by the first insulating layer. The first regions and the second regions are electrically isolated from each other after etching the nanoscale base film in the current generation system.

Abstract: A touch display is disclosed including a display module, a polarizer disposed on the display module, and a plurality of touch electrodes at least partly coated on the polarizer, wherein the touch electrodes are formed by nano-silver. Since the touch electrodes formed by nano-silver is employed in the display, a multifunctional touch display is provided. A method for making the touch display is also disclosed.

Abstract: An OLED touch display device includes an OLED display and a laminated package component covering the OLED display and including a quarter-wave plate, a liquid crystal polarizer, a first touch sensor layer and a second touch sensor layer. The first touch sensor layer and the second touch sensor layer are configured to cooperatively detect touch events.

Abstract: The present invention provides a touch panel, including a lower substrate, an organic light-emitting component, disposed on the lower substrate, a nano silver sensing layer, disposed on the organic light emitting component, and an upper substrate, disposed on the nano silver sensing layer.

Abstract: A chip package includes a chip, an isolation layer on the bottom surface and the sidewall, a redistribution layer that is on the isolation layer and in electrical contact with a side surface of the conductive pad, and a passivation layer. The chip has a sensor, at least one conductive pad, a top surface, a bottom surface, and a sidewall. The sensor is located on the top surface. The conductive pad is located on an edge of the top surface. The redistribution layer at least partially protrudes from the conductive pad so as to be exposed. The passivation layer is located on the isolation layer and the redistribution layer, such that the redistribution layer not protruding from the conductive pad is between the passivation layer and the isolation layer, and the redistribution layer protruding from the conductive pad is located on the passivation layer.

Abstract: A chip package includes a chip, an insulating layer and a conductive layer. The chip includes a substrate, an epitaxy layer, a device region and a conductive pad. The epitaxy layer is disposed on the substrate, and the device region and the conductive pad are disposed on the epitaxy layer. The conductive pad is at a side of the device region and connected to the device region. The conductive pad protrudes out of a side surface of the epitaxy layer. The insulating layer is disposed below the substrate and extended to cover the side surface of the epitaxy layer. The conductive layer is disposed below the insulating layer and extended to contact the conductive pad. The conductive layer and the side surface of the epitaxy layer are separated by a first distance.

Abstract: Present invention discloses a touch panel and a manufacturing method thereof, the touch panel comprises: a substrate; a silver nano-wire electrode layer provided on the substrate comprising a connecting area and a non-connecting area; a first protective layer provided on silver nano-wire electrode layer having a first hole corresponding to connecting area; a second protective layer provided on first protective layer having a second hole corresponding to position of first hole; and a connecting wire provided on second protective layer connected to silver nano-wire electrode layer in connecting area through second hole and first hole. With the touch panel, the problem that etching solution can't seep when a single protective layer is too thick and the problem that a silver nano-wire layer is easily oxidized and the adhesion of the silver nano-wire layer is poor when a single protective layer is too thin can be avoided.

Abstract: A chip package includes a chip, an insulating layer, a flowing insulating material layer and conductive layer. The chip has a conductive pad, a side surface, a first surface and a second surface opposite to the first surface, which the side surface is between the first surface and the second surface, and the conductive is below the first surface and protruded from the side surface. The insulating layer covers the second surface and the side surface, and the flowing insulating material layer is disposed below the insulating layer, and the flowing insulating material layer has a trench exposing the conductive pad protruded form the side surface. The conductive layer is disposed below the flowing insulating material layer and extended into the trench to contact the conductive pad.

Abstract: Present invention discloses a touch panel and a manufacturing method thereof, the touch panel comprises: a substrate; a silver nano-wire electrode layer provided on the substrate comprising a connecting area and a non-connecting area; a first protective layer provided on silver nano-wire electrode layer having a first hole corresponding to connecting area; a second protective layer provided on first protective layer having a second hole corresponding to position of first hole; and a connecting wire provided on second protective layer connected to silver nano-wire electrode layer in connecting area through second hole and first hole. With the touch panel, the problem that etching solution can't seep when a single protective layer is too thick and the problem that a silver nano-wire layer is easily oxidized and the adhesion of the silver nano-wire layer is poor when a single protective layer is too thin can be avoided.

Abstract: An OLED touch display device includes an OLED display and a laminated package component. The laminated package component covers the OLED display and includes a quarter-wave plate, a liquid crystal polarizer and a touch sensor unit. The touch sensor unit is a single-layer electrode structure.

Abstract: A chip package is provided. The chip package includes a first chip including a carrier substrate and a device substrate thereon. A second chip is mounted on the device substrate. A portion of the device substrate extends outward from the edge of the second chip, so as to be exposed from the second chip. A conductive pad is between the device substrate and the second chip. A polymer protective layer conformally covers the second chip, the exposed portion of the device substrate, and the edge of the carrier substrate. A redistribution layer is disposed on the polymer protective layer and extends into a first opening that passes through the polymer protective layer and the second chip and exposes the conductive pad, so as to be electrically connected to the conductive pad.

Abstract: A chip package includes a chip, an insulating layer and a conductive layer. The chip includes a substrate, an epitaxy layer, a device region and a conductive pad. The epitaxy layer is disposed on the substrate, and the device region and the conductive pad are disposed on the epitaxy layer. The conductive pad is at a side of the device region and connected to the device region. The conductive pad protrudes out of a side surface of the epitaxy layer. The insulating layer is disposed below the substrate and extended to cover the side surface of the epitaxy layer. The conductive layer is disposed below the insulating layer and extended to contact the conductive pad. The conductive layer and the side surface of the epitaxy layer are separated by a first distance.

Abstract: An OLED touch display device includes an OLED display and a laminated package component. The laminated package component covers the OLED display and includes a quarter-wave plate, a liquid crystal polarizer and a touch sensor unit. The touch sensor unit is a single-layer electrode structure.

Abstract: An organic light-emitting diode (OLED) display and fabrication method thereof are provided. The OLED display includes an organic light-emitting layer comprising a plurality of primary color regions and a plurality of mixed color regions, wherein the primary color regions and the mixed color regions have the same light emitting direction. A color shift prevention layer is disposed above or under the organic light-emitting layer, the color shift prevention layer comprising a plurality of opaque patterns disposed on the light emitting direction of the corresponding mixed color regions. The color shift prevention layer incorporated in the OLED display is able to block the mixed light emitted from the mixed color regions of the organic light-emitting layer. Therefore, the color shift problem can be solved.