Provided is a 360-degree image data processing method performed by a 360-degree video reception apparatus. The method includes receiving 360-degree image data, obtaining information on an encoded picture and metadata from the 360-degree image data, decoding a picture based on the information on the encoded picture, rendering the decoded picture and an overlay based on the metadata, in which the metadata includes overlay related metadata, the overlay is rendered based on the overlay related metadata, the overlay related metadata includes information on an alpha plane of the overlay, and the information on the alpha plane of the overlay is included in a image item or a video track.

The present disclosure relates to an eyewear and a control method thereof. The eyewear includes an optic, a camera device and a frame; wherein the optic and the camera device are respectively located on the frame; and the optic is a transparent display screen. The control method of the eyewear includes: detecting a light intensity of ambient light; obtaining a current light intensity of transmitted light generated after the ambient light passes through the optic, based on the light intensity of the ambient light and current light transmittance of the eyewear; adjusting the light transmittance of the optic; starting the camera device to acquire an environment image; performing enhancement processing on the environment image to obtain an enhanced environment image; and controlling the optic to display according to the enhanced environment image.

The present disclosure relates to an eyewear and a control method thereof. The eyewear includes an optic, a camera device and a frame; wherein the optic and the camera device are respectively located on the frame; and the optic is a transparent display screen. The control method of the eyewear includes: detecting a light intensity of ambient light; obtaining a current light intensity of transmitted light generated after the ambient light passes through the optic, based on the light intensity of the ambient light and current light transmittance of the eyewear; adjusting the light transmittance of the optic; starting the camera device to acquire an environment image; performing enhancement processing on the environment image to obtain an enhanced environment image; and controlling the optic to display according to the enhanced environment image.

A method includes receiving, through a network by a computing system associated with an artificial-reality device, video data of a user of a second computing system comprising a first and second image of the user. The first and second images may be captured concurrently by a first camera and a second camera of the second computing system, respectively. The computing system generates a planar proxy for displaying the user and determines a pose for the planar proxy within a three-dimensional virtual environment. The computing system renders a left image for a left-eye display and a right image for a right-eye display of the artificial-reality device based on the planar proxy having the determined pose and the first image, and the planar proxy having the determined pose and the second image, respectively. The computing system displays the rendered left image and right image using the left-eye display and right-eye display, respectively.

A method, including recording a first and a second camera image; the first camera image and the second camera image having an overlap region. The method includes: assigning pixels of the first camera image and pixels of the second camera image to predefined points of a three-dimensional lattice structure, the predefined points being situated in a region of the three-dimensional lattice structure, which represents the overlap region; ascertaining a color information item difference for each predefined point as a function of the assigned color information items; ascertaining a quality value as a function of the ascertained color information item difference at the specific, predefined point; determining a global color transformation matrix as a function of the color information item differences, weighted as a function of the corresponding quality value; and adapting the second camera image as a function of the determined color transformation matrix.

Systems and methods for reducing a number of focal planes used to display a three-dimensional object are disclosed herein. In an embodiment, data defining a three-dimensional image according to a first plurality of focal planes are received. Pixel luminance values from the first plurality of focal planes are mapped to a second plurality of focal planes comprising fewer focal planes than the first plurality of focal planes. Data is stored identifying initial focal distances of the mapped pixel luminance values in the first plurality of focal planes. The second plurality of focal planes are then displayed on a near eye device which uses the data identifying initial focal distances of the mapped pixel luminance values to adjust a wavelength of light produced by the second plurality of images to cause the pixels to appear at their original focal distances.

Systems and methods for reducing a number of focal planes used to display a three-dimensional object are disclosed herein. In an embodiment, data defining a three-dimensional image according to a first plurality of focal planes are received. Pixel luminance values from the first plurality of focal planes are mapped to a second plurality of focal planes comprising fewer focal planes than the first plurality of focal planes. Data is stored identifying initial focal distances of the mapped pixel luminance values in the first plurality of focal planes. The second plurality of focal planes are then displayed on a near eye device which uses the data identifying initial focal distances of the mapped pixel luminance values to adjust a wavelength of light produced by the second plurality of images to cause the pixels to appear at their original focal distances.

The disclosure relates to a display control device, a display control method, and a recording medium capable of performing more reliable stereoscopic viewing. Whether or not a condition for generating erroneous fusion on a presented image is satisfied on the basis of the display mode of a plurality of display objects arranged side by side in one direction on the presented image at the time of displaying the presented image presented in three-dimensional space. The presented image is expressed by an image for a right eye and an image for a left eye for stereoscopic viewing by using fusion in which the image for a right eye and the image for a left eye are superimposed and recognized as one image. Then, control of applying a predetermined effect to display of the presented image is performed on the basis of the determination result. The present technology can be applied to, for example, a stereoscopic display system using a head-mounted display.

The disclosure relates to a display control device, a display control method, and a recording medium capable of performing more reliable stereoscopic viewing. Whether or not a condition for generating erroneous fusion on a presented image is satisfied on the basis of the display mode of a plurality of display objects arranged side by side in one direction on the presented image at the time of displaying the presented image presented in three-dimensional space. The presented image is expressed by an image for a right eye and an image for a left eye for stereoscopic viewing by using fusion in which the image for a right eye and the image for a left eye are superimposed and recognized as one image. Then, control of applying a predetermined effect to display of the presented image is performed on the basis of the determination result. The present technology can be applied to, for example, a stereoscopic display system using a head-mounted display.

A method of controlling parameters for image sensors includes; receiving a first image and a second image, calculating first feature values related to the first image and second feature values related to the second image; generating comparison results by comparing the first feature values of fixed regions and first variable regions of the first image with the second feature values of fixed regions and first variable regions of the second image, and controlling at least one parameter on the basis of the comparison results.