Abstract: A display panel, including a device substrate, an opposite substrate, a sealant, and a display medium, is provided. A pixel array of the device substrate is located in a display region, and a periphery circuit of the device substrate is located in a non-display region, wherein the periphery circuit includes at least one driving device, a planarization layer, and at least one wire. The planarization layer covers the driving device. The wire is located on the planarization layer, and the wire is electrically connected with the driving device and disposed to overlap the driving device. The opposite substrate is located opposite to the device substrate, and the sealant is located in the non-display region therebetween and covers the wire. The display medium is located between the device substrate, the opposite substrate, and the sealant. A manufacturing method of a display panel is also provided.

Abstract: A method to make dyed functional film comprising the steps of providing a soluble polymer material; adding an appropriate solvent to the polymer material to make a soluble polymer solution; providing a soluble dye; adding an appropriate solvent to the dye to make a soluble dye solution; adding the dye solution to the polymer or PVA solution, and introducing the dyed polymer or PVA solution to a solution casting device; removing a thin dyed functional film from the casting device; and letting the dyed functional film dry and solidified.

Abstract: A method to manufacture infrared lens comprising the steps of: providing a portion of polyurethane (PU) material; mixing a portion of OH compound into said PU material to form a portion of OH PU material; providing a portion of solvent and mixing said OH PU material to said solvent to form a portion of PU solution; providing a portion of IR dye and mixing said IR dye to said PU solution to form a portion of IR PU solution; providing a portion of catalyst and mixing said catalyst to a portion of NCO compound to form a portion of NCO catalyst; mixing said NCO catalyst to said IR PU solution to form a portion of IR PU liquid solution; applying said IR PU liquid solution to a lens layer; allowing said PU liquid solution to solidify to form a IR functional lens layer.

Abstract: A pixel structure includes a gate electrode, a gate dielectric layer, a silicon channel layer, a silicon source ohmic contact layer, a silicon drain ohmic contact layer, a source auxiliary ohmic contact layer, a drain auxiliary ohmic contact layer, a transparent conductive portion, a transparent pixel electrode, a source electrode, and a drain electrode. The silicon channel layer is disposed on the gate dielectric layer and above the gate electrode. The silicon source ohmic contact layer, the source auxiliary ohmic contact layer, the transparent conductive portion, and the source electrode are disposed on the silicon channel layer in sequence. The silicon drain ohmic contact layer and the drain auxiliary ohmic contact layer are disposed on the silicon channel layer in sequence. At least a portion of the transparent pixel electrode is disposed between the drain electrode and the drain auxiliary ohmic contact layer.

Abstract: A 3-d stereoscopic viewing lens which the retarder film is made of a PVA film. A 3-D stereoscopic viewing lens having a linear polarized film, one or more lens substrate layers, and an epoxy layer. A process of making retarder film including mounting a PVA film to an assembly line; wetting, cleaning, and washing the PVA film through said assembly line; softening, expanding and stretching the PVA film's x-axis through said assembly line; adding gap filling agent to the PVA film; stretching the PVA film's y-axis through a width frame holder and as a result transforming the PVA film into a retarder film.

Abstract: The present invention discloses an improved method of LED reflector manufacturing process where the method includes providing a substrate, wherein said substrate comprises a reflector unit, and a Light Emitting Diode; providing a shield member with ferromagnetic property; placing said shield member over the desired area of over the substrate; providing a magnet where said shield member is attracted to; placing said magnet immediately below the substrate wherein said magnet is capable of immobilizing the shield member over the substrate; performing a vacuum deposition coating; and removing the magnet and the shield member.

Abstract: A display panel, including a device substrate, an opposite substrate, a sealant, and a display medium, is provided. A pixel array of the device substrate is located in a display region, and a periphery circuit of the device substrate is located in a non-display region, wherein the periphery circuit includes at least one driving device, a planarization layer, and at least one wire. The planarization layer covers the driving device. The wire is located on the planarization layer, and the wire is electrically connected with the driving device and disposed to overlap the driving device. The opposite substrate is located opposite to the device substrate, and the sealant is located in the non-display region therebetween and covers the wire. The display medium is located between the device substrate, the opposite substrate, and the sealant. A manufacturing method of a display panel is also provided.

Abstract: A process of creating a retarder using thin-stretched polymer film to perfectly conform to a curved mold and achieving nearly-crystallized lamination thanks to minimized thickness of said retarder using PVA film; thus, achieving greatly-enhanced optical clarity, contrast, and 3-D effect during stereoscopic image viewing and greatly-reduced user discomfort. A 3-D stereoscopic viewing lens having a retarder film using a PVA film filled with a gap filling agent to create a refringent effect, a polarized film and a base material.