A display control system includes a plurality of display devices and a display controller (display device). The display controller generates a graphics command for each frame, and attaches, to the graphics command, time stamp corresponding to an order of generation of the graphics command. Each of the plurality of display devices: acquires the graphics command; performs, in parallel, first processing of acquiring only the time stamp attached to the graphics command in the order of generation and second processing of performing rendering processing based on the graphics command in the order of generation and acquiring the time stamp attached to the graphics command based on which the rendering processing is performed; and when a difference between the time stamp acquired in the first processing and the time stamp acquired in the second processing exceeds a predetermined threshold value, performs reduction processing for reducing a load on the rendering processing.

An electronic device includes a first interface configured to obtain a first media data of a first source device; a second interface configured to obtain a second media data of a second source device; a processing device configured to generate a third media data; and an output device configured to output media data. The media data may be the first media data, the second media data, or the third media data. The third media data affects the first media data or the second media data if the third media data and the first media data are simultaneously outputted, or the third media data and the second media data are simultaneously outputted. The processing device is configured to process the first media data and the second media data to obtain a processing result, the processing result being used to generate presentation data indicating correspondences between interfaces and the media data.

A content receiver may establish a communication connection with an entertainment system component. Utilizing the communication connection, the content receiver may control the entertainment system component in order to synchronize user interfaces the content receiver is operable to provide with user interfaces the entertainment system component is operable to provide. Hence, the user interfaces provided by the various entertainment system components may more closely resemble user interfaces of the content receiver, reducing user confusion. The content receiver may synchronize such user interfaces by altering software of the entertainment system component. In altering the software, the content receiver may replace or modify the software to change one or more aspects of one or more entertainment system user interfaces to that of one or more aspects of a content receiver user interface. The aspects may include visual properties, audio properties, and so on.

Methods and apparatus for displaying layers on a display of a computing device are disclosed. The method includes creating layers from graphical data and assigning a priority to each of the layers. The layers are displayed on the display of the computing device, and in a current draw cycle, any layers assigned an urgent priority are updated. In addition, updates are applied to layers near a touch area of the display and updates to other layers ae deferred until a predefined event occurs.

A method (100) for monitoring the displaying of a plurality of video contents (VD1, . . . , VDM) on a display (1) is described, the video contents (VD1,, VDM) each comprising a stream of digital images (I1, . . . , IK), each digital image comprising a respective pixel matrix. The method does not require the integration of markers inside the video contents and the monitoring is performed by means of an optical sensor (2) having a sensitive area facing the display (1) so as to detect over time the chromatic variations of the video contents displayed.

Methods and apparatus for link training and low power operation. A multi-lane high speed bus is optimized for transferring audio/visual (A/V) data at slower rates. In one embodiment, the high speed bus is configured to use a packet format structure that allows for more fluid data delivery times, thereby allowing the high speed bus to deliver A/V data at times selected to reduce power consumption. In another embodiment, the high speed bus is configured to cache link initialization data for subsequent link re-initialization before entering a low power state. Thereafter, when the link exits the low power state, the high speed bus can skip certain portions of link initialization. Still a third embodiment of the present disclosure is directed to exemplary modifications to existing high speed bus link training and low power operation, consistent with the aforementioned principles. Variants of a Universal Serial Bus implementation are provided for illustration.

A monitor display system includes a computing device that is coupled to a collection of dissimilar monitors and a display manager that is coupled to the computing device. The display manager has an image generator that generates an image for the collection of dissimilar monitors and also has a pixel density normalizer that is coupled to the image generator and provides an alignment of the image across the collection of dissimilar monitors. A method of managing a display image is also included.

Systems are presented including: a first electronic device operative to receive a first input, the first electronic device including: a first data communication unit operative to connect the first electronic device to a second electronic device; and a first processing unit operative to process the first input to generate information representing at least a portion of a first intended display, and operative to establish at least one communication channel between the first and second electronic devices using the first data communication unit operative and to call at least one application programming interface to forward the information representing the at least the portion of the first intended display to the second electronic device for display, and further operative to receive and process a representation of a second input from the second electronic device.

The disclosure provides a method for optimizing remote display at a client device in communication with a remote desktop. The method generally includes receiving one or more frames for display at the client device, determining that a frame rate of the received one or more frames is less than an expected frame rate and/or a resolution of the received one or more frames is less than an expected resolution, determining that at least one of a local central processing unit (CPU) usage at the client device is less than a CPU usage threshold or a local graphics processing unit (GPU) usage at the client device is less than a GPU usage threshold, applying one or more enhancement techniques to the received one or more frames to produce one or more optimized frames while continuously monitoring the local CPU usage and/or the local GPU usage at the client device, and rendering the one or more optimized frames for display at the client device.

A driving circuit and an operating method thereof are disclosed. The driving circuit is disposed in a display apparatus and coupled to an OLED display panel. The driving circuit includes a buffer module, a regenerating module, a data processing module and a driving module. The buffer module receives and temporarily stores a first image data. The regenerating module generates a second image data different from the first image data according to the first image data. The data processing module performs a data processing process on the second image data to generate an output image data. The driving module is coupled between the data processing module and the OLED display panel and used to output an output the output image data to the OLED display panel.