The disclosed computer-implemented method may include (1) receiving a first 2D frame depicting an evolving 3D scene and elements in the evolving 3D scene, (2) receiving a second 2D frame depicting the evolving 3D scene and the elements, (3) deriving 2D motion vectors from the first 2D frame and the second 2D frame that each include an estimated offset from coordinates of an element in the first 2D frame to coordinates of the element in the second 2D frame, (4) receiving depth information for the evolving 3D scene, (5) using the 2D motion vectors and the depth information to extrapolate a synthetic 2D frame, and (6) displaying the synthetic 2D frame to a user. Various other methods, systems, and computer-readable media are also disclosed.

A method for processing a video according to the present invention may comprise: generating a plurality of Most Probable Mode (MPM) candidates; determining whether there is an MPM candidate identical to an intra-prediction mode of a current block among the plurality of MPM candidates; obtaining the intra-prediction mode of the current block, based on a result of the determining; and performing an intra-prediction for the current block, based on the intra-prediction mode of the current block.

A method for displaying virtual content to a user, the method includes determining an accommodation of the user's eyes. The method also includes delivering, through a first waveguide of a stack of waveguides, light rays having a first wavefront curvature based at least in part on the determined accommodation, wherein the first wavefront curvature corresponds to a focal distance of the determined accommodation. The method further includes delivering, through a second waveguide of the stack of waveguides, light rays having a second wavefront curvature, the second wavefront curvature associated with a predetermined margin of the focal distance of the determined accommodation.

A location identification system analyzes information received corresponding to a device detected in a room of a patient. On detecting a location identification of the device, the system assigns the device to the location corresponding to the location identification. In embodiments, the system retrieves patient and care team information for the location. The location and patient and care team information may be communicated to a central video monitoring system.

Provided is a method for creating a virtual reality content, storing the virtual reality content in a transmission buffer, and after that, managing the transmission buffer. A server creates the virtual reality content based on user's motion information, stores the virtual reality content in the transmission buffer and is allowed to modify the virtual reality content stored in the transmission buffer based on subsequently received user's motion information, so that the most recent user's motion information can be appropriately reflected in the virtual reality content. It is possible to provide a more immersive virtual reality service.

A scanning camera for capturing images along two or more curved scan paths, the scanning camera comprising a camera assembly associated with each scan path, each camera assembly comprising an image sensor and a lens; a scanning mirror; and a drive coupled to the scanning mirror; wherein the drive is operative to rotate the scanning mirror about a spin axis according to a spin angle; the spin axis is tilted relative to each camera optical axis; the scanning mirror is tilted relative to the spin axis and each camera optical axis; the scanning mirror is positioned to reflect an imaging beam into each lens in turn; and each image sensor is operative to capture each image along a respective one of the scan paths by sampling the imaging beam at a corresponding spin angle.

Due to the factors such as lens distortion and camera misalignment, stereoscopic image pairs often contain vertical disparities. Introduced herein is a method and apparatus that determine and correct vertical disparities in stereoscopic image pairs using an optical flow map. Instead of discarding vertical motion vectors of the optical flow map, the introduced concept extracts and analyzes the vertical motion vectors from the optical flow map and vertically aligns the images using the vertical disparity determined from the vertical motion vectors. The introduced concept recognizes that although not apparent, vertical motion does exist in stereoscopic images and can be used to correct the vertical disparity in stereoscopic images.

A moving image encoding/decoding apparatus that performs encoding/decoding while predicting a multiview moving image including moving images of a plurality of different views includes: a corresponding region setting unit that sets a corresponding region on a depth map for an encoding/decoding target region; a region dividing unit that sets a prediction region that is one of regions obtained by dividing the encoding/decoding target region; a disparity vector generation unit that generates, for the prediction region, a disparity vector for a reference view using depth information for a region within the corresponding region that corresponds to the prediction region; a motion information generation unit that generates motion information in the prediction region from the reference view motion information based on the disparity vector for the reference view; and a prediction image generation unit that generates a prediction image for the prediction region using the motion information in the prediction region.

Systems and methods may provide for using one or more stereoscopic devices for gesture control and tracking in a head mounted display (HMD). Each of the one or more stereoscopic devices may include a pair of dynamic vision sensors (DVS) arranged to have complementary fields of view (FOV) to detect one or more of a leading and a trailing edge of an object moving in a range or area to be detected. The DVS sensors determine how the object is moving based on a change in light intensity of pixels without having to detect, transfer, or process all of the pixels. The system and method may thereby provide motion tracking and gesture control functions at very low latency and processing bandwidth.

An apparatus acquires update information indicating a predetermined frame update interval on a moving image at a virtual viewpoint reproduced by updating a virtual viewpoint image at the interval, the virtual viewpoint image being generated using multi-viewpoint images and viewpoint information; acquires frame information of the multi-viewpoint images for use in generating the moving image, the frame information including information of a plurality of frames corresponding to different imaging times; and generates the viewpoint information based on the update information and the frame information, such that the viewpoint information indicating a position of a virtual viewpoint and a direction from the virtual viewpoint updated at an interval longer than the predetermined frame update interval is generated as the viewpoint information for the moving image generated using a smaller number of frames of multi-viewpoint images than frames of virtual viewpoint images forming the moving image.