A storage system comprising storage including a plurality of storage banks and a storage controller to control writing of received pixel data to the storage banks in a distribution pattern. The distribution pattern includes pattern sections, each of which corresponds to pixels from a row of input pixels, and pattern blocks, each of which corresponds to pixels from a plurality of adjacent rows and columns of the input pixels. Pixel data in a pattern section and a pattern block are each written to different ones of the storage banks. The pattern section includes a first section part, which overlaps the pattern block and a second section part, which does not overlap the pattern block. Pixel data of the first section part is written to a first set of storage banks and pixel data of the second section part is written to a second, different, set of storage banks.

The present technology relates to a display system, a display device, a display method, and a mobile apparatus capable of improving convenience for an occupant of the mobile apparatus.

The display system includes a first display that extends in a left-right direction in front of a first seat of a mobile apparatus, in which a left end portion of the first display faces diagonally backward right as viewed from the first seat, a center portion of the first display faces backward as viewed from the first seat, and a right end portion of the first display faces diagonally backward left as viewed from the first seat. The present technology can be applied to, for example, an in-vehicle display system.

Methods and apparatus for dynamically reducing bandwidth usage by embedded displays are disclosed. An example method includes receiving a request to display a frame associated with a pixel depth on a display of a computing device, determining whether the frame includes a background layer, and when the frame includes the background layer, adjusting the pixel depth of the background layer.

A method, device and non-transitory computer-readable storage medium for controlling a frame rate of a mobile terminal are disclosed. The method includes obtaining a rendering frame rate of a target object In a current running scene, the target object including a target application or a target layer, setting a composition frame rate in the current running scene according to the rendering frame rate of the target object, composing rendered images in the current running scene at the composition frame rate, and displaying a composed image.

ClearType resolution recovery resampling of source content is performed as the source content is transformed from a source presentation format to a destination presentation format by at least distinguishing between pixels of a bitmap corresponding to the source content that are ClearType pixels and pixels of the same bitmap that are non-ClearType pixels. Identification of ClearType pixels is performed by identifying Alpha values of pixels that are less than 1, by identifying high frequency color fringing of pixels and/or by explicit declarations in the bitmap. The bitmap is resampled by applying transforms, such as convolution filters, in selective and discriminating ways, such that, for example, the ClearType pixels of the bitmap are resampled/transformed on a subpixel granularity and the non-ClearType pixels of the same bitmap are transformed on a pixel granularity.

The present disclosure relates to a driving method of graphene display device and the graphene display devices. The method includes obtaining target point coordinates of a pixel within a color gamut system by RGB grayscale values to be inputted by the pixels, obtaining chromaticity coordinate (CIE) or a brightness of a first dynamic sub-pixel and a second dynamic sub-pixel of the pixel according to a location relationship of three color gamut blocks divided by a RGB color gamut within the target point coordinate and a gamut coordinate system, determining a driving voltage of the pixel in accordance with the CIE or the brightness of the first dynamic sub-pixel and the second dynamic sub-pixel, and outputting the driving voltage to the pixel. The graphene display device may for quickly, effectively, and more convenient realize high color fidelity so as to enhance the performance of LCDs.

A three-dimensional (3-D) look up table (LUT) can be accessed using an address decoder to identify a plurality of vertices in the 3-D LUT based on a number (m) of most significant bits (MSBs) of three coordinate values representative of a first color and a non-zero integer (p). The three coordinate values are determined by a source gamut. One or more memories store component values representative of a plurality of second colors determined by a destination gamut. The component values are stored at memory locations associated with the plurality of vertices. An interpolator maps the input color to an output color in the destination gamut based on the component values.

ClearType resolution recovery resampling of source content is performed as the source content is transformed from a source presentation format to a destination presentation format by at least distinguishing between pixels of a bitmap corresponding to the source content that are ClearType pixels and pixels of the same bitmap that are non-ClearType pixels. Identification of ClearType pixels is performed by identifying Alpha values of pixels that are less than 1, by identifying high frequency color fringing of pixels and/or by explicit declarations in the bitmap. The bitmap is resampled by applying transforms, such as convolution filters, in selective and discriminating ways, such that, for example, the ClearType pixels of the bitmap are resampled/transformed on a subpixel granularity and the non-ClearType pixels of the same bitmap are transformed on a pixel granularity.

Disclosed are a display panel and an electronic device. The display panel includes sub-pixels arranged in an array, wherein each pixel row of the sub-pixels comprises 3n sub-pixels, with every six adjacent sub-pixels of the pixel row forming a pixel group, n2, and the six adjacent sub-pixels of the pixel group are arranged in sequential order in a first direction parallel to the row direction. The display panel further includes a controller, where in a first display mode the controller controls each of the sub-pixels to be charged to emit light; and in a second display mode the controller controls at most two sub-pixels of each of the pixel groups in at least one of the pixel rows to not emit light, and controls at most two sub-pixels of the pixel group which have same order in two adjacent frames of pictures to not emit light.

In an embodiment, a user equipment (UE) coupled to a display screen enters into a reduced blue light (RBL) mode. The UE determines, while operating in accordance with the RBL mode, a degree of blue light reduction in at least a portion of a display frame to be output on the display screen using at least one RBL rule from a set of RBL rules that is based upon one or more of (i) application-specific information of an application that is contributing image data to the portion of the display frame, and (ii) content-specific information that characterizes the image data in the portion of the display frame. The UE selectively reduces the blue light in the at least a portion of the display frame based on the determining. The UE sends the display frame with the selectively reduced blue light portion to the display screen for output.