Apparatus and methods for enhanced 3D visualization includes receiving a plurality of images of an image scene from a plurality of image sensors. Depth information at locations of the image scene is received from a plurality of depth sensors. The depth information is combined with the plurality of images of the image scene using a machine learning model. A 3D representation of the image scene is generated based on the combined depth and image information.

A method for method for classification of virtual reality (VR) content for use in head mounted displays (HMDs). The method includes accessing a model that identifies a plurality of learned patterns associated with the generation of corresponding baseline VR content that is likely to cause discomfort. The method includes executing a first application to generate first VR content. The method includes extracting data associated with simulated user interactions with the first VR content, the extracted data generated during execution of the first application. The method includes comparing the extracted data to the model to identify one or more patterns in the extracted data matching at least one of the learned patterns from the model such that the one or more patterns are likely to cause discomfort.

A method for displaying a three dimensional (“3D”) image includes rendering a frame of 3D image data. The method also includes analyzing the frame of 3D image data to generate depth data. The method further includes using the depth data to segment the 3D image data into i) at least one near frame of two dimensional (“2D”) image data corresponding to a near depth, and ii) at least one far frame of 2D image data corresponding to a far depth that is farther than the near depth from a point of view. Moreover, the method includes displaying the near and far frames at the near and far depths respectively. The near and far frames are displayed simultaneously.

A three-dimensional display apparatus includes a display surface, an optical element, and a controller. The display surface includes a plurality of subpixels arranged in a grid pattern along a first direction corresponding to a direction in which user's eyes are aligned and a second direction orthogonal to the first direction. The optical element defines a beam direction of light emitted by the display surface for each of a plurality of strip-shaped regions that extends in a direction on the display surface at a predetermined angle other than 0 degrees with respect to the second direction. The controller is configured to cause the display surface to display an image. The controller is configured to acquire brightness information and, based on the brightness information, reduce the luminance of at least a subset of binocular subpixels that have a portion included in a first visible region on the display surface for emitting light to a first eye position of a user and the remaining portion included in a second visible region on the display surface for emitting light to a second eye position of the user.

A stereoscopic video playback device is provided that processes original stereoscopic image pairs taken using parallel-axis cameras and provided for viewing under original viewing conditions by scaling and cropping to provide new viewing condition stereoscopic video on a single screen.

An approach for projecting light may be implemented using a acousto-optical depth switch that uses surface acoustic waves produced along a substrate to guide image light to different areas. The surface acoustic waves may be generated on a substrate using a transducer. Surface acoustic waves of different frequencies can guide image light onto different optical elements at different physical positions. The optical elements may be configured to show objects in an image at different distances from a viewer.

Provided is an image display device including a display element configured to modulate light to form an image; a light transfer unit configured to transmit the image formed by the display element to eyes of an observer, the light transfer unit comprising a focusing member; and a driver configured to drive the display element to change a position of the display element, the driver including: a first actuator comprising a deformable wire; a housing that fixes a first end and a second end of the deformable wire; and an operating structure through which the deformable wire is routed, wherein the operating structure is configured move the display element in a first direction in conjunction with a length variation of the deformable wire, and the operating structure includes an elastic structure configured to prevent tilt with respect to an axis in the first direction.

A parallax correction method and device, and a storage medium. The method comprises: collecting two original images comprising a target object by means of a binocular camera; determining a first paralax of the target object in imaging areas of the two original images; adjusting the positions of the imaging areas in the two original images according to the first parallax and a preset parallax; and determining a target image on the basis of the imaging areas after position adjustment.

Provided are stereoscopic eyeglasses capable of reducing visual fatigue in binocular stereoscopic display by a simple configuration. In stereoscopic eyeglasses, in order to expand a tolerance of match between vergence and accommodation enabling comfortable stereovision in eyeglasses-using stereoscopic display, wide-focus lenses ranging in focal length are incorporated so as to overlap optical filters in light transmission directions, and accordingly, visual fatigue to be caused by vergence-accommodation conflict during stereoscopic image observation is reduced.

A travel-environment display apparatus includes a generating unit that repeatedly generates a travel-environment image of a vehicle, and a display device that updates display in accordance with the travel-environment images. The generating unit generates an image including a vehicle object corresponding to the vehicle as viewed from a rear viewpoint and a linear road-surface object extending distantly from the vehicle object to correspond to a road, lane, or lane boundary line along which the vehicle is traveling. The generating unit also moves the vehicle object between two lanes expressed by the linear road-surface object between the travel-environment images, and changes an orientation of the linear road-surface object such that a far area thereof from the viewpoint significantly moves toward an opposite side from a lane-changing direction of the vehicle, as compared with a near area, and then moves back, when the vehicle performs a lane change between the two lanes.