An electronic device. The electronic device includes a first processor configured to generate a first display signal, and a second processor configured to generate a second display signal and output to a display area. The second processor includes a forwarding module, the first processor is connected to the forwarding module, and the first display signal generated by the first processor is output to the display area through the forwarding module.

A control method includes obtaining a first task content and, in response to detecting that a first display area outputs a second task content, mapping the first task content to a second display area for output. The first display area and the second display area are different display areas in a same display screen, or the first display area and the second display area are on different display screens and each include at least a partial display area of one of the different display screens.

A data processing method applied to a first electronic device. The method includes determining first data and second data corresponding to a first display unit and a second display unit respectively based on an obtained to-be-displayed data; adjusting the first data and the second data to obtain target first data and target second data respectively based on an adjustment parameter, the adjustment parameter being determined based on display parameters of the first display unit and the second display unit, the display parameters being related to pixels per unit area of the first display unit and the second display unit; and outputting the target first data to the first display unit and outputting the target second data to the second display unit for the first display unit and the second display unit to display the same size when displaying the same object.

Disclosed are techniques for automatically aligning a wrist-mounted display device to a primary display device to facilitate simultaneous use of both display devices. Historical usage information corresponding to a user using both devices is leveraged to determine usage patterns for the devices together. Subsequently, when the primary display device is used by the user, the usage patterns are used to determine when the wrist-mounted display device can be used together with the primary display device. Position information from each device is used to determine a position for the wrist-mounted display device to automatically relocate to for aligning the wrist-mounted display device and the primary display device to have similar viewing directions. The wrist-mounted display device is automatically aligned to the position, and a usage of the aligned wrist-mounted display device is initiated based on the historical usage patterns.

A method for processing data for display on a screen involves encoding, using a first colour space, a first portion of image data intended to be displayed on a first area of the screen and encoding, using a second colour space, a second portion of image data intended to be displayed on a second area of the screen. The encoded first and second portions of the image data are compressed, and transmitted over a link for display on the screen. By using different colour spaces to encode image data that is displayed in different parts of a screen, differences in a users vision and/or aberrations caused by display equipment may be accounted for and so provide an improved user experience. Using different colour spaces for different screen areas may also reduce the amount of data that needs to be transmitted, for example by encoding image data more effectively and/or allowing more efficient compression of data.

A content display device includes a line-of-sight direction detection unit, a gazing point identification unit, a gazing content identification unit, and a display control unit. The line-of-sight direction detection unit is configured to detect a line-of-sight direction of a person located in a vicinity of a display region in which a plurality of contents are simultaneously displayed. The gazing point identification unit is configured to, based on the line-of-sight direction, identify a gazing point in the display region of the person. The gazing content identification unit is configured to, based on a distribution of the gazing point detected in a predetermined period, identify a gazing content at which the person is gazing. The display control unit configured to determine a display mode of each of the plurality of contents, based on a result of identifying the gazing content, and display each of the plurality of contents in the display mode determined.

A calibration method for splicing displays including initializing a plurality of displays, obtaining the gamuts of the displays, setting a display with the smallest gamut among the displays as the reference display, adjusting the color temperature, brightness and six-axis hue and saturation of the reference display respectively to a reference color temperature, a reference brightness and reference RGB coordinates, and adjusting the displays according to the reference color temperature, the reference brightness and the reference RGB coordinates.

An electronic device comprises: a communication unit; a camera; and a processor that controls, via the communication unit, a display wall comprising a plurality of display modules. The processor configured to control the display wall so that the plurality of display modules sequentially display a preset image; obtain a plurality of images by controlling the camera to capture the plurality of images of the display wall while each display module among the plurality of display modules displays the preset image; and identifies a location and a shape of each display module among the plurality of display modules of the display wall, based on the plurality of images.

A display device includes a display panel including pixels connected to data lines and scan lines, a data driving circuit which drives the data lines, a scan driving circuit which drives the scan lines, and a driving controller divides the display panel into first and second display regions, controls the data driving circuit and the scan driving circuit to drive the first display region at a first driving frequency and to drive the second display region at a second driving frequency lower than the first driving frequency, and sets third driving frequencies respectively corresponding to horizontal lines in a boundary region, which is defined by a portion of the second display region adjacent to the first display region, during a multi-frequency mode. Each of the third driving frequencies has a frequency level between the first driving frequency and the second driving frequency.

A video stream is encoded using spread spectrum video transport and sent as an analog signal to a display of a VR visor where a decoder integrated with a source driver decodes the analog signal and drives the display. The analog signal is sent wirelessly to the display where it is received, converted to wired format, decoded and displayed. A wireless SSVT analog signal is received at the headset processor and forwarded to the VR visor for reception, conversion, decoding and display. A wireless SSVT analog signal is received at the processor, converted to wired format, sent wirelessly to the display where it is received at a receiver, converted to wired format, decoded and displayed. A video stream is stored in persistent storage on the headset processor using SSVT encoding. The decoder integrated with a source driver of a display is implemented directly on the glass of the display panel.