Abstract: A TFT array substrate is disclosed. The TFT array substrate includes a TFT area, which includes a TFT first electrode layer, a TFT second electrode layer, a TFT insulation layer, and a TFT etching stop layer. The TFT array substrate also includes also includes a storage capacitor, which includes a capacitor first electrode layer, a capacitor second electrode layer, a capacitor insulation layer, and a capacitor etching stop layer. The TFT first electrode layer and the capacitor first electrode layer are formed in a shared first electrode layer, the TFT second electrode layer and the capacitor second electrode layer are formed in a shared second electrode layer, the TFT insulation layer and the capacitor insulation layer are formed in a shared insulation layer, and the TFT etching stop layer and the capacitor etching stop layer are formed in a shared etching stop layer.

Abstract: A TFT array substrate having compensated gate signal delays is disclosed. The TFT array substrate includes a plurality of gate lines, a plurality of data lines insulatedly intersecting with the plurality of the gate lines, and a plurality of TFT switches, each of which is connected with one of the gate lines and one of the data lines. The TFT array substrate also includes a plurality of driving units, where the driving units are located at both ends of the gate lines, and each of the driving units is connected with at least one gate line to drive the TFT switches connected to the at least one gate line.

Abstract: Embodiments of the present invention disclose a TFT array substrate, a display panel and a display device. Gap directions of gaps formed between visual test pads in a visual test area on the TFT array substrate are staggered with the alignment direction of an alignment film on the same plane with at least one staggered angle, and the staggered angle is more than 5 degrees, so that the problem of Rubbing Mura is solved.

Abstract: An Organic Light-Emitting Diode (OLED) display device and a corresponding flexible printed circuit (FPC) are disclosed. The display device includes a first substrate and a second substrate arranged in opposition. In addition, frit is arranged on an inner side of the first substrate, and the display device also includes at least one bonding mark, where the bonding mark includes the frit, and at least one sub-bonding mark arranged on a surface of the first substrate. The at least one sub-bonding mark includes a first portion and a second portion arranged apart from each other, and the first portion and the second portion are arranged at an edge of the frit. The FPC includes at least one auxiliary bonding mark aligning the FPC to the OLED display device, where the at least one auxiliary bonding mark is aligned with the at least one sub-bonding mark of the OLED display device.

Abstract: A method of preparing an OGS touch screen is disclosed. The method includes forming a first film layer on a provided substrate, where the first film layer includes at least one hollow region and a protection film surrounding each hollow region. The method also includes tempering each hollow region by tempering the substrate, and removing the protection film on the substrate.

Abstract: A method of manufacturing an Organic Light Emitting Diode (OLED) pixel is disclosed. The method includes forming an anode and forming a pixel definition layer. The pixel definition layer includes a first sub-pixel area, a second sub-pixel area, a third sub-pixel area corresponding to the third sub-pixel, and a pixel spacing area. The first sub-pixel, the second sub-pixel and the third sub-pixel are separated from each other by the pixel spacing area. The method also includes coating a long-chain fatty acid ester layers on the pixel spacing area, the second sub-pixel area, and the third sub-pixel area, coating light emitting layers on the sub-pixel areas and on the long-chain fatty acid ester layers, and ashing the substrate and removing the long-chain fatty acid ester layers to form light emitting patterns. The method also includes forming a cathode.

Abstract: A method of manufacturing a touch panel is disclosed. The method includes providing a plurality of substrates, each having a size, providing a carrier including a plurality of grooves each having a size corresponding with the size of the substrates. The method also includes placing the plurality of substrates into the grooves, simultaneously forming a touch structure layer on each of the substrates, and separating substrates from the carrier.

Abstract: An OLED package structure includes: a substrate, on which an organic light-emitting element is provided, and a cover plate having an annular groove surrounding the organic light-emitting element thereon. A packaging adhesive, partly inside the groove and partly outside the groove, adheres the cover plate to the substrate to seal the organic light-emitting element. In the OLED package structure according to the present invention, the thickness of the spacer can be smaller, so as to eliminate color mixture during an evaporation process and to prevent a Newton ring phenomenon in the OLED package structure.

Abstract: A liquid crystal panel, a display device and a scanning method thereof is disclosed. The liquid crystal panel includes a CF substrate, a TFT substrate and a liquid crystal layer sandwiched between the CF substrate and the TFT substrate; the CF substrate includes a transparent substrate and an integrated capacitive-electromagnetic composite touch layer located at the inner side of the transparent substrate to identify touch signals; wherein, the integrated capacitive-electromagnetic composite touch layer includes a capacitive touch structure and an electromagnetic touch structure electrically insulated from each other. According to the embodiments of the present invention, the integrated capacitive-electromagnetic composite touch layer is integrated to the inner of the CF substrate, so that the liquid crystal display including the liquid crystal panel of the embodiments of the present invention has capacitive and electromagnetic touch functions and is relatively thin.

Abstract: An embedded capacitive touch display panel is disclosed. The display panel includes a first transparent substrate, and a grid-shaped metal conductive layer formed on the first transparent substrate. The grid-shaped metal conductive layer includes first metal electrodes extending in a first direction, and second metal electrodes extending in a direction intersecting the first direction. Each of the second metal electrodes is divided into multiple sections by openings, through which the first metal electrodes extend. In addition, the first and second metal electrodes are separated from each other by gaps. The display panel also includes a color filter layer, including a plurality of red, green, and blue color resist units, and a green color resist bar. The gaps include a first gap part, parallel to the green color resist bar, where the first gap part is not overlapped by the green color resist bar.

Abstract: According to one embodiment of the present invention, a timing controller for a display, includes a first unit, a second unit and a third unit. The first unit is configured to generate an image signal from a first input signal. The second unit is configured to generate a multitude of timing signals and a control signal from a multitude of second input signals, the control signal being generated after the multitude of timing signals are generated. The third unit is configured to generate a multitude of first signals from the multitude of timing signals after receipt of the control signal from the second unit. The image signal and the multitude of first signals are configured to drive the display when the timing controller is connected to the display.

Abstract: The present invention discloses a fringe field switching (FFS) liquid crystal display and a color filter substrate. The liquid crystal display includes an upper substrate, a lower substrate, and a liquid crystal layer sandwiched between the upper substrate and the lower substrate. The lower substrate includes a common electrode and a pixel electrode, and the pixel electrode includes at least one branch electrode and an end electrode for connecting the branch electrode; and an auxiliary electrode corresponding to the end electrode is arranged on the upper substrate. In the presence of the auxiliary electrode, unwanted electric fields between the end electrode and the common electrode are effectively attenuated, and arrangement of liquid crystal molecules at the boundary of a pixel element where the end electrode is located is stabilized, so that disclination lines are improved, pictures are displayed uniformly with high quality.

Abstract: A display panel and a display device are provided. The display panel includes a substrate, multiple data line groups which are arranged on the substrate sequentially and adjacently, and multiple gate line groups which are arranged on the substrate sequentially and adjacently. The display panel further includes multiple pixel electrode array units which are arranged in an array on the substrate. The pixel electrodes in the pixel electrode array unit are electrically connected with the data lines and the gate lines via switch elements. Data driving signals received by any two adjacent pixel electrodes in a same column have opposite polarities. The pixel electrode array unit includes a first pixel electrode, a second pixel electrode, a third pixel electrode, and a fourth pixel electrode. Data driving signals received by any two adjacent pixel electrodes of a same type in the same row have opposite polarities.

Abstract: A connection apparatus for electrically conductive pads includes a first substrate and a second substrate arranged in opposition, wherein a plurality of first electrically conductive pads are arranged on the inside of the first substrate, and a plurality of second electrically conductive pads are arranged on the inside of the second substrate. An electrically conductive glue is arranged between the first electrically conductive pads and the second electrically conductive pads, and the first electrically conductive pads each include a first body, the second electrically conductive pads each include a second body, and the first body and/or the second body includes a hollow portion or portions. The electrically conductive pads with a hollow portion(s) allowing light rays to illuminate and solidify the electrically conductive for bonding and interconnecting the upper and lower electrically conductive pads.

Abstract: A pixel structure includes a plurality of red sub-pixels, white sub-pixels, blue sub-pixels and green sub-pixels, which are arranged to form a plurality of first sub-pixel cells and second sub-pixel cells. The first and second sub-pixel cells may be arranged to form a plurality of pixel cells. The pixel cells may be arranged in the vertical direction repeatedly to form a plurality of pixel array cells. The pixel array cells may be arranged in the horizontal direction repeatedly to form a plurality of pixel arrays. The pixel structure further includes a supplement pixel array disposed in the pixel arrays according to a preset mode and configured to supplement polarity inversion in the pixel structure. The sub-pixels with a same color in a same row in a same signal frame may not have a same polarity, thereby reducing flicker and horizontal crosstalk of images and improving the image display quality.

Abstract: An electrostatic protection structure is disclosed. One inventive aspect is an electrostatic protection structure. The electrostatic protection structure includes a data line, adapted to transmit a pixel signal, where the data line includes an electrostatic diverting path. The electrostatic protection structure also includes a signal transmission path, where a first terminal of the signal transmission path is connected to a pixel unit, and a second terminal of the signal transmission path is connected to a signal output terminal, where the second terminal is configured to output a signal from the pixel unit. A first terminal of the electrostatic diverting path is connected to a constant potential, and a second terminal of the electrostatic diverting path is connected to the signal output terminal, and the impedance of the signal transmission path is greater than the impedance of the electrostatic diverting path.

Abstract: A touch-control display device is disclosed. The display device includes first, second, and third touch-control structures, a first plate, and a second plate opposing the first plate. The first and second touch-control structures form a capacitive touch-control structure, the third touch-control structure is an electromagnetic touch-control structure, and the first, second and third touch-control structures are respectively disposed on an inner side of the first plate, on an external side of the first plate, and on an inner or external side of the second plate. In addition, the first, second, and third touch-control structures are separated by one or more insulating layers.

Abstract: A liquid crystal cell is disclosed. The cell includes a first substrate, and a first overcoat layer. The first substrate includes first and second regions. The cell also includes a barrier layer on the first overcoat layer in the first region, a second substrate bonded with the first substrate, and a first spacer on the second substrate, where the first spacer is aligned with the first region. The cell also includes a second spacer on the second substrate facing the first substrate, where the second spacer aligns with the second region, and the length of the first spacer is greater than or equal to the length of the second spacer. The cell also includes a liquid crystal layer between the first and second substrates, where the area of a lower surface of the barrier layer is greater than the area of a lower surface of the first spacer.

Abstract: A color filter substrate is disclosed. The color filter substrate includes a first substrate, a first conductive film layer formed on the first substrate, and an RGB color blocking layer formed on the first conductive film layer, where a first via hole is disposed in the RGB color blocking layer. The color filter substrate also includes a first insulating layer formed on the RGB color blocking layer, where a second via hole is disposed in the first insulating layer, and a second conductive film layer formed on the first insulating layer, where the first conductive film layer is electrically connected to the second conductive film layer through the first via hole and the second via hole.

Abstract: A color filter substrate is disclosed. The color filter substrate includes a glass substrate, and an RGB color filter layer. The RGB color filter layer includes a plurality of optical filter columns, and each optical filter column includes a plurality of optical filter units in two colors. In addition, adjacent optical filter columns form an optical filter group, optical filter units of one of the colors in each optical filter group are arranged in a zigzag pattern, optical filter units arranged in the zigzag pattern are of different colors in adjacent optical filter groups, and the optical filter units are rectangular.