The disclosure provides an array substrate, a manufacturing method thereof, and a liquid crystal display (LCD) panel. The array substrate includes a substrate, a driving circuit layer, a pixel electrode layer, and an astigmatism layer, which are stacked. The pixel electrode layer includes a plurality of pixel electrodes which are independent from each other. The astigmatism layer includes a plurality of astigmatism components which are connected to each other and correspond to the pixel electrodes. An area of a light-emitting surface of the astigmatism components away from the pixel electrodes is greater than an area of an electrode surface of the pixel electrodes away from the substrate. The disclosure improves viewing angles.

A driving method of a display panel and a display device are provided. The driving method includes adopting drive data of relatively high voltage and drive data of relatively low voltage respectively for driving any two adjacent pixels; in each of the rows, with adjacent three pixels as a repeater, a polarity arrangement drive adopted by the pixels in a first column is different from a polarity arrangement drive adopted by the pixels in other two columns, the polarity arrangement drive above is one of a first polarity arrangement drive and a second polarity arrangement drive; in each of the columns, the polarity arrangement drive of every two of the pixels is identical; the first polarity arrangement drive and the second polarity arrangement drive are alternately changed with two of the pixels as a repeater. The display device uses such a driving method.

A display panel and a display device are provided, and the display panel includes a circuit layer and a pixel layer disposed over the circuit layer. The pixel layer includes a first region used to form a first sub-pixel and a second region used to form a second sub-pixel. The ability of light to pass through the liquid crystal molecules over the first and second subpixels sequentially decreases. The circuit layer includes a driving circuit disposed opposite to the first region, and a difference between image brightness above the first region and image brightness of above the second region is within a predetermined range.

A display panel and a display device are provided, and the display panel includes a circuit layer and a pixel layer disposed over the circuit layer. The pixel layer includes a first region used to form a first sub-pixel and a second region used to form a second sub-pixel. The ability of light to pass through the liquid crystal molecules over the first and second subpixels sequentially decreases. The circuit layer includes a driving circuit disposed opposite to the first region, and a difference between image brightness above the first region and image brightness of above the second region is within a predetermined range.

A pixel driving circuit and a display device are provided. The pixel driving circuit includes a plurality of sub-pixels, at least 3M scan wires, at least two data wires, and a driving circuit. At least three consecutive sub-pixels in a same column constitute one pixel, each two rows of pixels form one group, and each of the sub-pixels includes M domain areas. In each group of the pixels, ith domain areas of the sub-pixels with a same color are connected to a same scan wire of the at least 3M scan wires, each column of the sub-pixels is correspondingly connected to the at least two data wires, M≥2, 1≤i≤M, and M and i are integers. A charging rate of the each of the sub-pixels are improved through the pixel driving circuit.

The present application relates to the technical field of display and provides a display panel and an image control device and an image control method thereof; wherein, the image control device includes a high-voltage gamma module, a low-voltage gamma module and a first selection module.

A driving method of a display panel and a display device are provided. The driving method includes adopting drive data of relatively high voltage and drive data of relatively low voltage respectively for driving any two adjacent pixels; in each of the rows, with adjacent three pixels as a repeater, a polarity arrangement drive adopted by the pixels in a first column is different from a polarity arrangement drive adopted by the pixels in other two columns, the polarity arrangement drive above is one of a first polarity arrangement drive and a second polarity arrangement drive; in each of the columns, the polarity arrangement drive of every two of the pixels is identical; the first polarity arrangement drive and the second polarity arrangement drive are alternately changed with two of the pixels as a repeater. The display device uses such a driving method.

An information handling system peripheral display provides backlight to a liquid crystal display panel through a light guide plate with illumination from a light emitting diode package having plural evenly spaced light emitting diodes disposed in a spaced relationship along one side of the light guide plate. For insert molded coupling devices, a midframe structure integrates spacers at opposing ends of the bottom side of the light guide plate to maintain the spaced relationship without any additional intervening structures between the light emitting diode package and light guide plate along the bottom side between the opposing ends.

An information handling system peripheral display provides backlight to a liquid crystal display panel through a light guide plate with illumination from a light emitting diode package having plural evenly spaced light emitting diodes disposed in a spaced relationship along one side of the light guide plate. For insert molded coupling devices, a midframe structure integrates spacers at opposing ends of the bottom side of the light guide plate to maintain the spaced relationship without any additional intervening structures between the light emitting diode package and light guide plate along the bottom side between the opposing ends.

The present disclosure provides a sub-pixel unit and a method of controlling the same, a pixel unit, an array substrate, and a display device. In one embodiment, a sub-pixel unit includes: at least two subpixels. Each of the at least two subpixels includes: a first electrode; a second electrode; and a liquid crystal layer controlled by a voltage between the first electrode and the second electrode; at least one of the first electrode and the second electrode is a slit electrode. The two subpixels have different initial twist angles, and the initial twist angle is an included angle between a direction of a slit of the slit electrode and a direction where major axes of liquid crystal molecules are oriented when the liquid crystal layer is in an unpowered state, in the respective subpixel.