An electronic device is provided. The electronic device includes a communication circuit, and at least one processor operatively connected to the communication circuit, wherein the at least one processor is configured to establish, via the communication circuit, a communication connection with a display device, identify channel information about a first channel on which the communication connection is established, identify image information about an image displayed in the display device, and based on the channel information about the first channel and the image information, identify whether the electronic device is capable of transmitting a data frame each communication cycle which corresponds to a frame rate provided in the display device.

Embodiments of the subject matter described herein relate to a wireless programmable media processing system. In the media processing system, a processing unit in a computing device generates a frame to be displayed based on a graphics content for an application running on the computing device. The frame to be displayed is then divided into a plurality of block groups which are compressed. The plurality of compressed block groups are sent to a graphics display device over a wireless link. In this manner, both the generation and the compression of the frame to be displayed may be completed at the same processing unit in the computing device, which avoids data copying and simplifies processing operations. Thereby, the data processing speed and efficiency is improved significantly.

Provided are computer-implemented methods and systems for optimization of publication of an application to a web browser. An example method for optimization of publication of an application to a web browser may include capturing, by a server-side agent, a video frame of a virtual screen associated with the application. The method may further include comparing, by the server-side agent, the video frame to a previous video frame of the virtual screen to detect a change in the video frame. The method may continue with generating, by the server-side agent, an image of the change based on the detection. The method may further include sending, by the server-side agent, the image of the change to a client device. The virtual screen may be re-rendered on the client device based on the image of the change and the previous video frame.

A hub system control method, for controlling a hub which has a maximum bandwidth and is connected to a plurality of monitors, comprising: acquiring resolutions and refresh rates of each one of the monitors by the hub; computing used bandwidths of each one of the monitors according to the resolutions and the refresh rates; and controlling the hub to operate corresponding to at least one relation between the used bandwidths and the maximum bandwidth.

A video display includes a display panel with gate drivers and source drivers. Each of said the source drivers is arranged to receive a discrete-time continuous-amplitude signal representing a video stream over a transmission medium and to decode the signal using demodulation to produce a plurality of samples for output on outputs of the source drivers. At least one of the source drivers is arranged to extract a gate driver timing control signal from the signal and to output the gate driver control signal to the gate drivers in order to synchronize the gate drivers with outputs of the source drives, whereby the video stream is displayed on the display panel of the display unit.

An display driver and an operating method of the display driver are provided. The display driver includes a receiver comprising a bias current control circuit. The receiver receives image data. The bias current control circuit computes a data bit rate of the image data, and adjusting a bias current of the receiver according to the data bit rate. The operating method is adapted to the display driver.

Described are various embodiments of a light field vision-based testing device, system and method. One such device comprises an array of digital display pixels; a corresponding array of light field shaping elements (LFSEs); a hardware processor operable to adjust perception of a defined optotype within a range of visual acuity compensations; and an adjustable refractive optical system adjustable to selectively produce a complementary visual acuity compensation to extend each of a cylindrical compensation range and a spherical compensation range.

Methods and apparatus relating to an adaptive multibit bus for energy optimization are described. In an embodiment, a 1-bit interconnect of a processor is caused to select between a plurality of operational modes. The plurality of operational modes comprises a first mode and a second mode. The first mode causes transmission of a single bit over the 1-bit interconnect at a first frequency and the second mode causes transmission of a plurality of bits over the 1-bit interconnect at a second frequency based at least in part on a determination that an operating voltage of the 1-bit interconnect is at a high voltage level and that the second frequency is lower than the first frequency. Other embodiments are also disclosed and claimed.

An exemplary computer console can generate one or more video streams having image data relating to an image or a series of images, also referred to as video, to be presented by an electronic display device. The exemplary computer console can provide the one or more video streams to the electronic display device over one or more transport streams. The exemplary computer console can effectively throttle a video stream bitrate of the one or more video streams to be less than of the standard defined transport stream bitrate of the one or more transport streams to allow the transport of the one or more video streams over the one or more transport streams.

In a robot (3) in a remote location, an action scene of the robot (3) is determined based on a feature amount derived from its position and motion detection data and video data, and a video parameter or an imaging mode corresponding to the determined action scene is selected. Then, a process of adjusting the selected video parameter for the video data or a process of setting the selected imaging mode to the camera is performed, and the processed video data is transmitted to the information processing apparatus (2) on the user side via the network (4) and displayed on the HMD (1).