A 3D display device is provided, comprising: a multi-viewpoint 3D display screen, comprising a plurality of composite pixels, wherein each composite pixel in the plurality of composite pixels comprises a plurality of composite subpixels, and each composite subpixel in the plurality of composite subpixels comprises a plurality of subpixels corresponding to a plurality of viewpoints; an eye positioning apparatus, configured to acquire spatial positions of eyes of a user; and a 3D processing apparatus, configured to determine the viewpoints by the spatial positions of the eyes of the user, and render the subpixels, corresponding to the viewpoints, in the plurality of composite subpixels based on received 3D signals. According to the above 3D display device, the flexibility of 3D display can be improved. A 3D display method, a 3D display terminal, a computer-readable storage medium and a computer program product are also provided.

A method for implementing 3D image display and a 3D display device are provided. The method comprises: detecting a posture change of a 3D display device, which comprises a multi-viewpoint 3D display screen comprising multiple composite pixels and a lenticular grating covering the multiple composite pixels, each composite pixel comprises multiple composite subpixels, each composite subpixel comprises multiple subpixels, and the lenticular grating is obliquely arranged to cover multiple subpixels along a first direction of the 3D display device to define multiple first posture viewpoints and cover at least two composite pixels along a second direction of the 3D display device to define at least two second posture viewpoints; and when a posture of the 3D display device changes, adjusting a display orientation of a 3D image, so that the 3D image is kept in an initial display orientation before a posture change of the 3D display device.

A method for implementing 3D image display and a 3D display device are provided. The method comprises: detecting a posture change of a 3D display device, which comprises a multi-viewpoint 3D display screen comprising multiple composite pixels and a lenticular grating covering the multiple composite pixels, each composite pixel comprises multiple composite subpixels, each composite subpixel comprises multiple subpixels, and the lenticular grating is obliquely arranged to cover multiple subpixels along a first direction of the 3D display device to define multiple first posture viewpoints and cover at least two composite pixels along a second direction of the 3D display device to define at least two second posture viewpoints; and when a posture of the 3D display device changes, adjusting a display orientation of a 3D image, so that the 3D image is kept in an initial display orientation before a posture change of the 3D display device.

An apparatus and method for displaying an image are disclosed. The apparatus includes independently-controllable microLED unit cells including sets of microLEDs each emitting light and at least one lens to control an emission angle and emission profile of the light emitted by the microLED unit cells. A display controller controls an intensity distribution of the microLED unit cells in accordance with a video data signal such that a first portion of the emitted light is emitted at a first emission angle with a first emission profile and a second portion of the emitted light is emitted at a second emission angle with a second emission profile. The first and second light portions form three-dimensional stereoscopic images.

An apparatus and method for displaying an image are disclosed. The apparatus includes independently-controllable microLED unit cells including sets of microLEDs each emitting light and at least one lens to control an emission angle and emission profile of the light emitted by the microLED unit cells. A display controller controls an intensity distribution of the microLED unit cells in accordance with a video data signal such that a first portion of the emitted light is emitted at a first emission angle with a first emission profile and a second portion of the emitted light is emitted at a second emission angle with a second emission profile. The first and second light portions form three-dimensional stereoscopic images.

Described are various embodiments of a digital display device comprising a light filed display operatively coupled thereto, and vision correction system and method user same. In one embodiment, a system and method are provided for implementing a viewer-specific image perception adjustment within a defined view zone (e.g. field of view zone).

Described are various embodiments of a digital display device comprising a light filed display operatively coupled thereto, and vision correction system and method user same. In one embodiment, a system and method are provided for implementing a viewer-specific image perception adjustment within a defined view zone (e.g. field of view zone).

An image display apparatus including one or more virtual-image screens, a display section, and a display control unit. The one or more virtual-image screens are arranged to cover at least a part of a periphery of a predetermined axis, display a virtual image of a projected image by using the predetermined axis as a basis, and are transparent. The display section has one or more display surfaces that display a plurality of viewpoint images in mutually different directions and project the plurality of displayed viewpoint images onto the one or more virtual-image screens, respectively, the plurality of viewpoint images being images of a display target as viewed from mutually different directions. The display control unit displays, a virtual image of the display target that is visible from a second direction extending toward the predetermined axis from the observation point.

An image display apparatus including one or more virtual-image screens, a display section, and a display control unit. The one or more virtual-image screens are arranged to cover at least a part of a periphery of a predetermined axis, display a virtual image of a projected image by using the predetermined axis as a basis, and are transparent. The display section has one or more display surfaces that display a plurality of viewpoint images in mutually different directions and project the plurality of displayed viewpoint images onto the one or more virtual-image screens, respectively, the plurality of viewpoint images being images of a display target as viewed from mutually different directions. The display control unit displays, a virtual image of the display target that is visible from a second direction extending toward the predetermined axis from the observation point.

A cluster according to an embodiment of the disclosure includes a display and a spatial image panel. The display is installed in the vehicle to output predetermined information as a 2D image. The spatial image panel is configured to output a 3D image in a predetermined space in front. The spatial image panel includes a first lens array, a second lens array, and a refractive medium. The first lens array is disposed adjacent to the display and includes a plurality of first lenses arranged on the same plane. The second lens array is disposed in parallel with the first array so that the first lenses and second lenses overlap each other. The refractive medium is disposed between the first lens array and the second lens array.