Embodiments disclosed herein provide systems, methods and computer readable media for generating remote views in a virtual mobile device platform. A virtual mobile device platform may be coupled to a physical mobile device over a network and generate frames of data for generating views on the physical device. These frames can be generated using an efficient display encoding pipeline on the virtual mobile device platform. Such efficiencies may include, for example, the synchronization of various processes or operations, the governing of various processing rates, the elimination of duplicative or redundant processing, the application of different encoding schemes, the efficient detection of duplicative or redundant data or the combination of certain operations.

Disclosed are a transmitting method, a receiving method, a transmitting device and a receiving device for high-definition video data. The transmitting method comprises the follows. High-definition video data with different color space formats is obtained by a transmitting device via an input interface. processing, by the transmitting device, the high-definition video data into a data packet; transmitting, by the transmitting device, the data packet to a first communication module with the transmission rate not less than a first threshold. The first communication module is configured to transmit the data packet. By the adoption of the disclosure, the transmitting device can transmit the high-definition video data to a receiving device through the first communication module and based on a network cable or an optical fiber, so that lossless high-definition video transmission with ultra-low latency can be realized.

The present disclosure provides an image display method, an image processing method and related devices. The image display method includes: receiving and storing an original image from a processing terminal, the original image being an image rendered by the processing terminal; acquiring a first image from the original image; displaying the first image between a first time point and a second time point; acquiring a second image from the original image; and displaying the second image between the second time point and a third time point.

Disclosed are an electronic device and a method for controlling the electronic device. Specifically, the electronic device according to the present disclosure receives a first image signal and a second image signal which are separated from an original image signal through a first channel and a second channel having different frequency bandwidths, and which have different data rates. When the first image signal and the second image signal are received, the electronic device determines whether an error exists in the second image signal, obtains a first output image signal and a second output image signal on the basis of the first image signal and the second image signal according to a result of the determination, and outputs the obtained first output image signal or second output image signal.

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.

This disclosure describes efficient communication of surface texture data between system on a chip (SOC) integrated circuits. An example system includes a first integrated circuit and a second integrated circuit communicatively coupled to the first integrated circuit by a video communication interface. The first integrated generates a superframe in a video frame of the video communication interface for transmission to the second integrated circuit. The superframe includes multiple subframe payloads that carry surface texture data to be updated in the frame and corresponding subframe headers that include parameters of the subframe payloads. The second integrated circuit includes a direct access memory (DMA) controller. The DMA upon receipt of the superframe, writes the surface texture data within each of the subframe payloads directly to an allocated location in memory based on the parameters included in the corresponding one of the subframe headers.

An apparatus comprising a display in which a plurality of pixels are arranged in an array, and a generator configured to, in a first frame, generate first data corresponding to a first region of the display to display a first image in the first region of the display and, in a second frame, generate second data corresponding to a second region of the display, which includes the first region and is larger than the first region, to display a second image in the second region of the display is provided. A region of the second region is defined as a third region, a resolution of the first image and a resolution of at least the third region in the second image are different from each other.

A gaze point acquisition section 470 in a compression coding section 422 of a server 400 acquires position information associated with a gaze point of a user in a moving image that is generated by an image forming section 420 and is displayed on a client. An attention degree estimation section 472 estimates an attention degree on the basis of a position of the gaze point, for each of unit regions produced by dividing a frame plane. A compression coding processing section 474 compression-codes the moving image at a compression rate varied in the frame plane according to a distribution of the attention degrees. A communication section 426 transmits compression-coded data to an image processing apparatus 200.

The present disclosure relates to methods and apparatus for display processing. For example, disclosed techniques facilitate regional processing of images for under-display device displays. Aspects of the present disclosure can identify a subsection of a set of frame layers, the identified subsection corresponding to a lower pixel density region, relative to at least one other region, of a display. Aspects of the present disclosure can also blend first pixel data for each frame layer corresponding to the identified subsection to generate second pixel data. Further, aspects of the present disclosure can populate a buffer layer based on the second pixel data. Additionally, aspects of the present disclosure can blend pixel data from the set of frame layers and the buffer layers to generate a blended image. Aspects of the present disclosure can also transmit the blended image for presentment via the display.

A mechanism is described for facilitating consolidated compression/de-compression of graphics data streams of varying types at computing devices. A method of embodiments, as described herein, includes generating a common sector cache relating to a graphics processor. The method may further include performing a consolidated compression of multiple types of graphics data streams associated with the graphics processor using the common sector cache.