A method for minimizing latency of moving objects in an augmented reality (AR) display device is described. In one aspect, the method includes determining an initial pose of a visual tracking device, identifying an initial location of an object in an image that is generated by an optical sensor of the visual tracking device, the image corresponding to the initial pose of the visual tracking device. rendering virtual content based on the initial pose and the initial location of the object, retrieving an updated pose of the visual tracking device, tracking an updated location of the object in an updated image that corresponds to the updated pose, and applying a time warp transformation to the rendered virtual content based on the updated pose and the updated location of the object to generate transformed virtual content.

A video game system includes a video server system (VSS) having a first network address. The VSS pairs a game controller having a second network address with a display system having a third network address. The VSS receives controller data packets directed to the first network address from the game controller over a first communication channel. The controller data packets include the second network address and information for updating a game state of a video game. The VSS decodes the controller data packets and directs generation of an updated game state of the video game using information within the controller data packets. The VSS generates a video stream of the video game using the updated game state. The VSS transmits the video stream to the display system at the third network address over a second communication channel. The first and second communication channels differ by at least one network segment.

In an example, an apparatus comprises a plurality of execution units, and a first general register file (GRF) communicatively couple to the plurality of execution units, wherein the first GRF is shared by the plurality of execution units. Other embodiments are also disclosed and claimed.

A mechanism is described for facilitating using of a shared local memory for register spilling/filling relating to graphics processors at computing devices. A method of embodiments, as described herein, includes reserving one or more spaces of a shared local memory (SLM) to perform one or more of spilling and filling relating to registers associated with a graphics processor of a computing device.

Display device including: an array of pixels comprising several pixel blocks; a video card comprising an input configured to receive a digital signal to be displayed by the array of pixels, and an output coupled to the blocks via at least one main data bus;

and wherein: the array of pixels comprises control circuits each associated with one of the blocks, coupled to the main data bus and including a main memory circuit; the video card includes a compression circuit configured to compress, before sending them to the output, the digital data to be displayed by the blocks; each control circuit includes a decompression circuit for decompressing the part of the digital data received by the control circuit before storing them in the main memory circuit.

An image forming apparatus which is capable of appropriately producing displays using installed expansion application modules without using a window manager module. The image forming apparatus produces a display in accordance with a display instruction for at least one of the installed expansion application modules. When display instructions for the expansion application modules overlap each other, priorities for display are assigned based on starting conditions related to the expansion application modules.

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.

A graphics processing unit (GPU) includes a timing reference one or more processors configured to generate and provide, based on the timing reference, frames to a display system that supports variable refresh rates. The frames include a vertical blanking region having a first duration. The display system transmits information indicating an operation to be performed by the display system during the vertical blanking region of one or more subsequent frames. The one or more processors are configured to increase the first duration to a second duration in response to receiving the information indicating an operation to be performed by the display system during the vertical blanking region of at least one subsequent frame. In some cases, the first duration of the vertical blanking region is a minimum duration that corresponds to a maximum refresh rate supported by the display system.

An e-paper display device including an e-paper display panel, a graphics library and a display controller is provided. The display controller is coupled to the e-paper display panel. The display controller is configured to receive a line segment input signal and call the graphics library, and then drive, using a set of signal waveforms, the e-paper display panel to display a line segment. The set of signal waveforms is generated according to the line segment input signal and the graphics library. The line segment includes at least one gray level. In addition, a method for driving an e-paper display device is also provided.

Systems and methods for displaying super saturated color. Image data for display on a display or viewing device with a potential white luminance in a standard system with a maximum luminance is processed such that colors near the white point are reduced to a limited luminance. As the chroma of the displayed color is increased, a luminance attenuation is decreased. The scaling of the reduction is operable to be a linear function, a non-linear function, or any other function.