An object of the present invention is to obtain calibration data more easily in a VR (Virtual Reality) device. a user wearing a pair of VR goggles visually recognizes overlapped marker images displayed in the 360-degree VR space, and a stationary state is detected when the images for right and left eyes are overlapped, and when the stationary state satisfies a predetermined condition set in advance, one of the plurality of marker images displayed on the display in this state, which is at the center, is set as a marker image for calibration setting, calibration data of the interpupillary distance based on the marker image for calibration setting having been set is acquired, and the acquired calibration data is set as calibration data used for subsequent reproduction of images.

An object of the present invention is to obtain calibration data more easily in a VR (Virtual Reality) device. a user wearing a pair of VR goggles visually recognizes overlapped marker images displayed in the 360-degree VR space, and a stationary state is detected when the images for right and left eyes are overlapped, and when the stationary state satisfies a predetermined condition set in advance, one of the plurality of marker images displayed on the display in this state, which is at the center, is set as a marker image for calibration setting, calibration data of the interpupillary distance based on the marker image for calibration setting having been set is acquired, and the acquired calibration data is set as calibration data used for subsequent reproduction of images.

A wallpaper system presents a first wallpaper image of a wallpaper video to a user and receives, via a user input device, one or both of: (i) a spatial user input selection, and (ii) a time user input selection from the user to apply to the wallpaper video. In response to detecting one or both of: (i) the spatial user input selection, and (ii) the time user input selection, the wallpaper system determines one or both of: (i) a respective spatial movement parameter within a wallpaper video associated with the spatial user input selection, and (ii) a respective time coordinate within the wallpaper video associated with the time user input selection. Wallpaper system presents, via the image display, a second wallpaper image associated with one or both of: (i) the respective spatial movement parameter, and (ii) the respective time coordinate.

A wallpaper system presents a first wallpaper image of a wallpaper video to a user and receives, via a user input device, one or both of: (i) a spatial user input selection, and (ii) a time user input selection from the user to apply to the wallpaper video. In response to detecting one or both of: (i) the spatial user input selection, and (ii) the time user input selection, the wallpaper system determines one or both of: (i) a respective spatial movement parameter within a wallpaper video associated with the spatial user input selection, and (ii) a respective time coordinate within the wallpaper video associated with the time user input selection. Wallpaper system presents, via the image display, a second wallpaper image associated with one or both of: (i) the respective spatial movement parameter, and (ii) the respective time coordinate.

A video processing method includes receiving at least one virtual reality (VR) content, obtaining at least one picture from the at least one VR content, encoding the at least one picture to generate a part of a coded bitstream, and encapsulating, by a file encapsulation circuit, the part of the coded bitstream into at least one ISO Base Media File Format (ISOBMFF) file. The at least one ISOBMFF file includes a first track parameterized with a first set of translational coordinates, wherein the first set of translational coordinates identifies an origin of a first omnidirectional media content.

A video processing method includes receiving at least one virtual reality (VR) content, obtaining at least one picture from the at least one VR content, encoding the at least one picture to generate a part of a coded bitstream, and encapsulating, by a file encapsulation circuit, the part of the coded bitstream into at least one ISO Base Media File Format (ISOBMFF) file. The at least one ISOBMFF file includes a first track parameterized with a first set of translational coordinates, wherein the first set of translational coordinates identifies an origin of a first omnidirectional media content.

A display device includes a display device body. The display device body includes a first lens barrel and a second lens barrel. A first lens is disposed at a first end of the first lens barrel, and a second lens is disposed at a first end of the second lens barrel. A first distance sensor and a second distance sensor are further disposed on the display device body. The second distance sensor is configured to measure a distance between a right eyeball and the second lens. Two distance sensors are disposed on the display device body.

A display device includes a display device body. The display device body includes a first lens barrel and a second lens barrel. A first lens is disposed at a first end of the first lens barrel, and a second lens is disposed at a first end of the second lens barrel. A first distance sensor and a second distance sensor are further disposed on the display device body. The second distance sensor is configured to measure a distance between a right eyeball and the second lens. Two distance sensors are disposed on the display device body.

Systems and methods are disclosed that dynamically and laterally shift each virtual object displayed by an augmented reality headset by a respective distance as the respective virtual object is displayed to change virtual depth from a first virtual depth to a second virtual depth. The respective distance may be determined based on a lateral distance between a first convergence vector of a user's eye with the respective virtual object at the first virtual depth and a second convergence vector of the user's eye with the respective virtual object at the second virtual depth along the display, and may be based on an interpupillary distance. In this manner, display of the virtual object may be adjusted such that the gazes of the user's eyes may converge where the virtual object appears to be.

Configurations are disclosed for presenting virtual reality and augmented reality experiences to users. The system may comprise an image capturing device to capture one or more images, the one or more images corresponding to a field of the view of a user of a head-mounted augmented reality device, and a processor communicatively coupled to the image capturing device to extract a set of map points from the set of images, to identify a set of sparse points and a set of dense points from the extracted set of map points, and to perform a normalization on the set of map points.