A display device for virtual reality. A first display panel comprises a first pixel row having a first end and a second end that is closer to the second display panel than the first end. The first pixel row has a first arrangement of unit pixels that alternate between a first unit pixel type and a second unit pixel type. A second display panel comprises a second pixel row aligned with the first pixel row and having a third end and a fourth end that is further from the first display panel than the third end. A first unit pixel at the first end of the first pixel row is the first unit pixel type, and a second unit pixel at the third end of the second pixel row is the second unit pixel type.

An electrically controlled spectacle includes a spectacle frame and optoelectronic lenses housed in the frame. The lenses include a left lens and a right lens, each of the optoelectrical lenses having a plurality of states, wherein the state of the left lens is independent of the state of the right lens. The electrically controlled spectacle also includes a control unit housed in the frame, the control unit being adapted to control the state of each of the lenses independently.

Provided is an imaging apparatus including an imaging section that generates, from a single scene, captured image data including reference image data, first parallax image data having a first parallax in one direction relative to a subject of the reference image data, and second parallax image data having a second parallax in another direction that is opposite the one direction; an adjustment condition acquiring section that acquires an adjustment condition relating to parallax amount adjustment; and an image processing device that processes the reference image data, the first parallax image data, and the second parallax image data, based on the adjustment condition, to generate third parallax image data having a third parallax that is in the one direction and different from the first parallax and fourth parallax image data having a fourth parallax that is in the other direction and different from the second parallax.

A method for applying power in a plurality of pulses to the projection source to control the projection source to emit coherent light during an exposure interval comprising at least two sub-intervals, the applied power causing the projection source to have different temperatures during first and second sub-intervals of the at least two sub-intervals; and emitting light from the projection source, wherein the projection source emits light having different wavelengths during the first and second sub-intervals in accordance with the different temperatures of the projection source.

A range is determined for a disparity search for images from an image sensor array. In one example, a method includes receiving a reference image and a second image of a scene from multiple cameras of a camera array, detecting feature points of the reference image, matching points of the detected features to points of the second image, determining a maximum disparity between the reference image and the second image, and determining disparities between the reference image and the second image by comparing points of the reference image to points of the second image wherein the points of the second image are limited to points within the maximum disparity.

A processing apparatus includes a luminance information obtainer that obtains luminance information for each color in each of a plurality of images, each of which is imaged respectively when a light source arranged at mutually different positions sequentially irradiates an object with light, and a color setter that sets a color to use in obtaining surface normal information for each region of an image on the basis of the luminance information.

A mobile terminal which is capable of capturing an image focused on according to a distance from an object, includes a camera configured to sense an object using a plurality of lenses, a display unit configured to display an image received through the camera, and a controller that is configured to recognize capturing distances between the plurality of lenses and the object using sensing information on the object, generate a focal zone, defined by focal distances corresponding to some of the recognized capturing distances, and control a display unit to output an image focusing on at least one object included in the focal zone.

An autostereoscopic display system (240) arranged to display an autostereoscopic image, the display system comprising a display panel (400, 500) comprising multiple sub-pixels. The multiple sub-areas of a sub-pixel comprising a high-intensity sub-area, wherein the high-intensity sub-area is arranged to provide light of a higher intensity than the other sub-areas in the multiple sub-areas of the sub-pixel for at least one image value received in the sub-pixel. The high-intensity sub-area may be arranged in the sub-pixel to reduce banding, inter alia, by splitting the multiple sub-areas along a direction parallel to the direction of the columns.

A three dimensional system including additional 2 dimensional to three dimensional conversion.

In accordance with disclosed embodiments, there are provided systems, methods, and apparatuses for implementing maximum likelihood image binarization in a coded light range camera. For instance, a depth camera is described having therein a projector to project a collection of planes, each at a different angle of projection, onto a scene via a plurality of coded pattern images, each of the coded pattern images having encoded therein via a plurality of stripes, the angle of projection for the plane of projection within which the respective coded pattern image is projected; a detector to capture the plurality of coded pattern images from the scene; a processing component to output a bit value for each pixel in the captured plurality of coded pattern images based on the pixel captured and based further on a patch of neighboring pixels surrounding the pixel; a decoder to decode each of the plurality of coded pattern images based on the bit values output by the processing component to determine the angle of projection for the corresponding plane of projection; and a triangulator to determine a position of an object in the scene based on an intersection of the determined angle of projection for the corresponding plane of projection with a geometric ray originating from the detector that detected the plurality of the coded pattern images. Other related embodiments are disclosed.