The disclosure describes a method, apparatus and system for reducing crosstalk of auto-stereoscopic displays using higher resolution panels. In such panels, a fraction of a total number of views is generated by sending a same signal on a number of adjacent views. A signal processing correcting function is applied to the fractioned views to reduce crosstalk.

A 3D display device and the driving method for the 3D display device are provided. The 3D display device includes a liquid crystal display panel for monochrome display, and an electroluminescence display panel for color display disposed under the liquid crystal display panel; the electroluminescence display panel includes a plurality of regions arranged in a matrix, the plurality of regions form columns of bright regions and columns of dark regions, which are arranged alternately the liquid crystal display panel includes a plurality of first sub-pixels arranged in a matrix; each bright region of the electroluminescence display panel corresponds to at least two first sub-pixels adjacent in row direction of the liquid crystal display panel.

The present disclosure relates to a display apparatus and a three-dimensional display method thereof. A via hole at least passing through a base substrate is formed in an array substrate of a liquid crystal display panel, and a signal line on a upper surface of the array substrate can be connected with a driving chip bonded onto an electroluminescent display substrate, through to the via hole on a lower surface of the array substrate and through a conductive material in an optical clear adhesive. A signal line on the electroluminescent display substrate also can be connected with a driving chip bonded onto an upper surface of the array substrate, through the conductive material in the optical clear adhesive on a lower surface of the array substrate and through the via hole.

Unidirectional grating-based backlighting includes a light guide and a diffraction grating at a surface of the light guide. The light guide is to guide a light beam and the diffraction grating is configured to couple out a portion of the guided light beam using diffractive coupling and to direct the coupled-out portion away from the light guide as a primary light beam at a principal angular direction. The diffraction grating is to further produce a secondary light beam directed into the light guide at an opposite one of the principal angular direction. The unidirectional grating-based backlighting further includes an angularly selective reflective layer within the light guide adjacent to the light guide surface that is configured to reflectively redirect the diffractively produced, secondary light beam out of the light guide in the direction of the primary light beam.

Examples are disclosed that relate to depth-aware late-stage reprojection. One example provides a computing system configured to receive and store image data, receive a depth map for the image data, processing the depth map to obtain a blurred depth map, and based upon motion data, determine a translation to be made to the image data. Further, for each pixel, the computing system is configured to translate an original ray extending from an original virtual camera location to an original frame buffer location to a reprojected ray extending from a translated camera location to a reprojected frame buffer location, determine a location at which the reprojected ray intersects the blurred depth map, and sample a color of a pixel for display based upon a color corresponding to the location at which the reprojected ray intersects the blurred depth map.

A viewing angle controlling light source device and a display apparatus are provided. The viewing angle controlling light source device includes a base substrate; a light emitting array arranged on the base substrate, wherein the light emitting array includes a plurality of light emitting units; at least one liquid crystal lens array arranged on the light emitting array, wherein the liquid crystal lens array includes a plurality of liquid crystal lens units corresponding to the light emitting units one by one, each liquid crystal lens unit includes a first electrode and a second electrode, and a liquid crystal layer arranged between the first electrode and the second electrode a light emergent direction of light emitted by the light emitting unit after the light transmitting through the liquid crystal lens unit by regulating a voltage difference between the first electrode and the second electrode.

The present invention relates to a multi-view three-dimensional (3D) display apparatus including a display panel in which pixels (or subpixels) outputting an image are arranged and a parallax barrier disposed on a front surface of the display panel and including a plurality of apertures, wherein the apertures of the parallax barrier are set according to a Fresnel number.

An object is to manage a plurality of users by displaying a video on a plurality of head mounted displays. A plurality of head mounted display systems are connected to a server, the server including a first communication control unit transmitting image data to the connected head mounted display systems and a generation unit generating new image data according to information relating to visual lines of users transmitted from the head mounted display systems in accordance with the image data and outputting the generated new image data to the first communication control unit, and each of the head mounted display systems including: a display unit displaying the image data supplied from the server; a detection unit detecting a visual line of a user viewing the image data displayed on the display unit; and a second communication control unit transmitting information relating to the visual line detected by the detection unit to the server.

A viewing technology method, system, and non-transitory computer readable medium including a display device associated with a user and at least two drones having an image capturing device, include a drone control circuit configured to control a flight path of the at least two drones such that the drones are separated by the inter-drone distance, a vergence angle determining circuit configured to determine a vergence angle of the pupils of the user relative to the image displayed on the display device, and a image control circuit configured to control a display of the image on the display device according to the vergence angle to cause the image to create a just-noticeable-difference in the image.

In various embodiments, methods and systems for reprojecting images based on a velocity depth late stage reprojection process are provided. A reprojection engine supports reprojecting images based on an optimized late stage reprojection process that is performed based on both depth data and velocity data. Image data and corresponding depth and velocity data of the image data is received. A determination of an adjustment to be made to the image is made. The determination is made based on motion data, the depth data and the velocity data. The motion data corresponds to a device associated with displaying the image data. The velocity data supports determining calculated correction distances for portions of the image data. The image data is adjusted based on the determined adjustment. Adjusting the image data is based on integrating depth-data-based translation and velocity-data-based motion correction, into a single pass implementation, to adjust the image data.