Content data of a display target is acquired in accordance with a user's operations and is used to determine a configuration of a display image. Of the regions to be rendered using fonts in the display image, the region in which a character is to be displaced by a very small amount is determined. The characters targeted for displacement are rendered while being displaced over time in accordance with predetermined displacement rules. The characters not targeted for displacement are rendered in a reference position. With all characters rendered, the display image is completed and output. The processes of S12 to S24 are repeated until display is terminated.

A display apparatus is provided. The A display apparatus includes a plurality of subpixels, the plurality of subpixels comprising a plurality of first subpixels, a plurality of second subpixels, and a plurality of third subpixels. The plurality of third subpixels are arranged in an array of I columns and J rows. The display apparatus includes a plurality of repeating units. A respective repeating unit of the plurality of repeating units includes one of the plurality of first subpixels, one of the plurality of second subpixels, and two of the plurality third subpixels. The two of the plurality third subpixels in the respective repeating unit are arranged along a first direction or a second direction, the one of the plurality of first subpixels and the one of the plurality of second subpixels in the respective repeating unit are arranged along the second direction or the first direction.

A display device capable of performing proper display without image signal conversion is provided. In the case of high-resolution display, individual data is supplied to each pixel through a first signal line and a first transistor included in each pixel. In the case of low-resolution display, the same data is supplied to a plurality of pixels through a second signal line and a second transistor electrically connected to the plurality of pixels. When the number of image signals to be displayed is more than one and the image signals support different resolutions, display can be performed without up conversion or down conversion by switching an image signal supply path as described above.

A display driver includes image processing circuitry and driver circuitry. The image processing circuitry is configured to process image data for a plurality of pixel circuits of a display panel. The image processing circuitry includes a demura table comprising one or more base compensation values associated with each of the plurality of pixel circuits, and a lookup table (LUT) comprising one or more compensation coefficients associated with each of a plurality of frame rates. Processing the image data for the pixel circuits comprises a mura compensation for at least one pixel circuit of the plurality of pixel circuits using the one or more base compensation values and the one or more compensation coefficients. The drive circuitry is configured to update the plurality of pixel circuits based on the processed image data.

A display device and display method thereof are provided. The display device includes an image capture unit, a grayscale value capture unit, a grayscale value difference calculating unit, a grayscale difference threshold setting unit, and a pixel pattern output unit. In the display method of the present disclosure, weighted weight calculations managing different line types are correspondingly added, therefore, the color aliasing may be effectively avoided, and image features may be restored to the utmost.

Embodiments of the present disclosure provide a pixel arrangement structure, a display panel, and a display device. The pixel arrangement structure includes at least one repeating pixel group, wherein each of the at least one repeating pixel group includes a first pixel unit, a second pixel unit, a third pixel unit, and a fourth pixel unit. Two sub-pixels of the first pixel unit are adjacent to two sub-pixels of the second pixel unit, and two sub-pixels of the third pixel unit are adjacent to two sub-pixels of the fourth pixel unit, thereby achieving pixel multiplexing.

A data conversion method, a display method, a data conversion device and a display device. The data conversion method includes: performing data reorganization on original pixel data corresponding to at least one row of pixels in a display panel to obtain reorganized pixel data. In any data channel, the performing data reorganization on original pixel data corresponding to at least one row of pixels in a display panel to obtain reorganized pixel data includes: a first reorganized part in the n-th reorganized pixel data set consists of a first original part in the (n-1)-th original pixel data set, and a second reorganized part in the n-th reorganized pixel data set consists of a second original part in the n-th original pixel data set, wherein n is an integer satisfying 1<n≤N, and N is an integer greater than 1.

Systems and methods to compensate for color fringe visual artifacts due at least in part to subpixel locations on an electronic display are provided. An electronic device may include subpixel layout compensation circuitry (SLCC) and an electronic display. The SLCC may receive first image data and an indication of spatial positions of subpixels that make up pixels of an electronic display. The SLCC may generate second image data based at least in part on the first image data and the indication of the spatial positions of the subpixels. The second image data may reduce or eliminate a color fringe artifact that would otherwise occur without compensation.

A liquid crystal on silicon panel including a plurality of driving circuits is provided. Each of the driving circuits includes a first driving route and a second driving route. The first driving route and the second driving route are configured to drive corresponding subpixel electrodes and respectively determine display content of a first wobulation image and a second wobulation image. In addition, a projection apparatus including the liquid crystal on silicon panel is also provided.

A method includes rendering, by at least one processor, a first sub-frame of an image, where the first sub-frame includes a first subset of pixels of the image. The method includes displaying the first sub-frame on a display. The method also includes rendering, by the at least one processor, a second sub-frame of the image, where the second sub-frame includes a second subset of pixels of the image, and where the second sub-frame is shifted a half-pixel diagonally from the first sub-frame. The method also includes displaying the second sub-frame on the display after displaying the first sub-frame, where the display is optically shifted a half-pixel diagonally to display the second sub-frame.