A head-mounted display (HMD) divides an image into a high resolution (HR) inset portion at a first resolution, a peripheral portion, and a transitional portion. The peripheral portion is downsampled to a second resolution that is less than the first resolution. The transitional portion is blended such that there is a smooth change in resolution that corresponds to a change in resolution between a fovea region and a non-fovea region of a retina. An inset region is generated using the HR inset portion and the blended transitional portion, and a background region is generated using the downsampled peripheral portion. The inset region is provided to a HR inset display, and the background region is provided to a peripheral display. An optics block combines the displayed inset region with the displayed background region to generate composite content.

A system for user activity and data aggregation and visualization, comprising a data aggregation server that receives data via a network, a prioritization server that ranks data, and a visualization engine that generates a visualization of ranked data using a planetary model, and a method for visualizing data using a planetary model.

A wireless device supporting Wi-Fi Direct service includes: a display; a communication unit; and a controller configured to cause: transmitting resolution information including a plurality of resolutions that are supported by the wireless device to a second wireless device; receiving an entire image including a first image and a second image from the second wireless device if a resolution of the first image is not one of the plurality of resolutions; displaying the first image by removing the second image from the received entire image when the entire image is received; and receiving the first image from the second wireless device without the second image if the resolution of the first image is included in the resolution information, the second image being an image that is added to the first image such that a resolution of the received entire image corresponds to one of the plurality of resolutions.

An image resolution processing method includes: obtaining motion information of a display apparatus; determining a motion direction and rate information of the display apparatus according to the motion information; determining, according to the motion direction, a target object that is at least one of a horizontal resolution and a vertical resolution; determining a target value according to the rate information and a standard resolution of the display apparatus; and generating a to-be-displayed image, a value of the target object in an image resolution of the to-be-displayed image being equal to the target value.

A system for creating a panorama image in real time across a bandwidth-limited network by communicating low-resolution images and selected high-resolution image portions, and registering (stitching) the low-resolution images based on shared objects in the high-resolution image portions.

A system and method for interpolating between pixels of an image for providing zoom and pan features. A piecewise cubic spline is used to find the values of each of four provisional interpolation points in each of four rows of an image and, similarly, a piecewise cubic spline is used to interpolate between the provisional interpolation points to find the value of a point in the output image. Boundary conditions used to constrain the coefficients of the piecewise cubic spline provide enhanced quality in the output image.

Techniques are described for generating and rendering video content based on area of interest (also referred to as foveated rendering) to allow 360 video or virtual reality to be rendered with relatively high pixel resolution even on hardware not specifically designed to render at such high pixel resolution. Processing circuitry may be configured to keep the pixel resolution within a first portion of an image of one view at the relatively high pixel resolution, but reduce the pixel resolution through the remaining portions of the image of the view based on an eccentricity map and/or user eye placement. A device may receive the images of these views and process the images to generate viewable content (e.g., perform stereoscopic rendering or interpolation between views). Processing circuitry may also make use of future frames within a video stream and base predictions on those future frames.

Transitions between monitor configurations may be streamlined by minimizing the tearing down and recreating of render targets and primary frame buffers associated with the monitors. In at least one example, the techniques described herein include identifying at least one render target in a first monitor configuration that is also in a second monitor configuration. In response to identifying the at least one render target in the first monitor configuration that is also in the second monitor configuration, the techniques herein describe maintaining the at least one render target during a transition between the first monitor configuration to second monitor configuration.

System, method, and computer product embodiments for efficiently casting interactively-controlled visual content displayed on a first display screen to a second display screen. In an embodiment, the computing device sends the visual content displayed on the first display screen to a multimedia device for displaying on the second display screen. Upon receipt of an instruction that visually manipulates how the visual content is displayed on the first display screen, the computing device generates a command representative of the received instruction. The command may specify a positional relationship between the center of the first display screen and the visual content displayed on the first display screen. Then, the computing devices sends the command to the multimedia device that causes the second display screen to display the visual content according to the positional relationship.

The method includes the steps of: a) acquiring a display resolution of an external monitor; b) acquiring screen pictures of application pages of a smartphone; c) determining a quantity of screen divisions of the external monitor according to information acquired in step b); d) resizing the screen pictures acquired in step b) to match one of the screen divisions according to the display resolution; e) combining the screen pictures resized in step d) into an integrated screen picture with multiple screen divisions; and f) displaying the integrated screen picture on the external monitor.