A display driver integrated circuit includes a first slave module and a second slave module. The first slave module is initially set as a primary module to receive a mode conversion command, and is disabled based on the mode conversion command. The second slave module is initially set as a secondary module that does not receive the mode conversion command, and is set as the primary module instead of the first slave module when the first slave module is disabled. The first and second slave modules control processing or transfer of data through a channel included in or coupled to a display according to a predetermined protocol.

The present invention discloses an image blending system built-in a display, comprising a video input module, a video routing unit, a regional image processing unit, a terminal image blending unit and a display terminal unit.

In a method for determining a position of at least one display screen within an array of coupled display screens an emitted signal from an adjacent display screen is detected. The detecting is performed by a sensor coupled with a side of a plurality of sides of a display screen. A positional code number is determined based on the detecting. The positional code number includes a bit number corresponding to a detection of the signal emitted from the adjacent display screen.

A computing device comprises an electronic paper display, a processor and a memory. The memory is arranged to store platform software and application software for at least one application that is not adapted to work with an electronic paper display. The platform software comprises a UI conversion module comprising device-executable instructions, which when executed by the processor, cause the processor to: access a UI element tree for the application; generate a modified UI element tree for the application by removing and/or re-styling at least one UI element; and render data from the application using the modified UI element tree for display on the electronic paper display.

A display assembly includes a display device, a first clamping plate and a second clamping plate. The display apparatus has at least one display area, and the first clamping plate and the second clamping plate are disposed on two opposite sides of the display device in a thickness direction thereof. At least one of the first clamping plate and the second clamping plate is located on at least one light-emitting side of the display device, and in a clamping plate located on a light-emitting side of the display device, at least a partial region of a portion covering an active area of the display device is in a transparent state. Edges of the first clamping plate and the second clamping plate have at least one adapter portion, and adapter portions are configured to fix the display assembly to an object in an external environment through at least one adapter.

A motion picture camera arrangement comprises a motion picture camera and a display device, wherein the motion picture camera has an image sensor for taking images at a variable frame rate and wherein the display device displays the taken images at a settable display rate. A method of operating the motion picture camera arrangement comprises the steps of: selecting a frame rate; determining a setting value for the display rate of the display device, wherein the setting value corresponds, in dependence on the selected frame rate, either to the selected frame rate or to a product or quotient of the selected frame rate and a whole-number multiplier or divisor; operating the image sensor at the selected frame rate; and operating the display device using the determined setting value for the display rate.

A multi-input display device may, responsive to a user-selection, divide a display region into different regions corresponding to display data received at different input graphics ports. Display metadata for each display region may be individually transmitted to each respective source of the display data.

An image processing device includes a memory that stores a program and a processor that executes the program stored in the memory to perform a process. The process includes obtaining input image data that is generated by combining, in a horizontal direction, an effective display area of first image data and an effective display area obtained by expanding an effective display area of second image data in the vertical direction, the vertical size of the second image data being smaller than the vertical size of the first image data; and generating second output image data corresponding to the second image data by reducing the vertical size of second intermediate image data among first intermediate image data and the second intermediate image data, which are obtained by dividing the input image data in the horizontal direction, based on the vertical size of the effective display area of the second image data.

A display control method includes: in response to a display area of a display device being divided into multiple display sub-areas, controlling outputs from the multiple display sub-areas at corresponding refresh rates. The refresh rates of different display sub-areas can be the same or different.

Disclosed are a display panel, a method of controlling the display panel. The display panel includes multiple pixel groups arranged in an array, wherein each pixel group comprises a first sub-pixel and a second sub-pixel which are adjacently arranged; a plurality of gate lines, wherein the first sub-pixel and the second sub-pixel in a same row of the array are connected to one gate line; a plurality of first data lines, wherein the first sub-pixels in a same column of the array are connected to one first data line; a plurality of second data lines. The second sub-pixels in a same column of the array are connected to one second data line of the plurality of second data lines; the first and the second data lines are spacedly arranged, and a driving component to which the gate lines, the first data lines and the second data lines are connected.