Disclosed are an array substrate and a display device which belong to the technical field of displays, and solve the technical problem that, in the existing in-cell technology, the manufacturing process of array substrates is too complex. The array substrate comprises a plurality of pixel units each having a thin film transistor, a plurality of common electrodes, and a plurality of address lines. The address lines each are formed by connecting a first metal wire and a second metal wire, the first metal wire being located at a same layer as a gate of the thin film transistor, and the second metal wire being located at a same layer as a source and a drain of the thin film transistor.

An organic light-emitting diode (OLED) display and method of driving the same are disclosed. In one aspect, the OLED display includes a display panel including a plurality of pixels and a data driver configured to apply a data signal to the display panel in one of two-dimensional (2D) and stereoscopic display modes. The display also includes a controller configured to convert an image signal to 2D image data for the pixels at each of N×k sub-fields in the 2D display mode and convert the image signal to stereoscopic image data for the pixels at each of N sub-fields in the stereoscopic display mode, where N and k are integers greater than 1. The display further includes a frame memory configured to store the 2D image data in the 2D display mode and the stereoscopic image data in the stereoscopic display mode.

A 3D laser projection systems and methods are disclosed herein. A laser projection system includes a left projector head and a right projector head, wherein a first video projected onto a movie screen by the left projector head has a first polarization and a second video projected onto the movie screen by the right projector head has a second polarization different from the first polarization. The laser projection system can include a laser light generator located a first defined distance away from the left projector head and a second defined distance from the right projector head and coupled to the left projector head and the right projector head with fiber optic cables that transmit light from the laser light generator to the left projector head and the right projector head. The laser light generator includes a laser diode configured to output light and to transmit it to the fiber optic cables.

A method for the autostereoscopic representation of images on a display screen includes the steps of selecting a view mode from a plurality of pre-defined view modes; creating a channel mask that defines a number N of channels per segment of the optical plate, wherein N is larger than or equal to the number of views in the selected view mode; providing a texture for each of the N channels; correlating each screen pixel with at least one texture by reference to the channel mask; applying an allocation algorithm for allocating the total of the image information to be displayed at a time to at least two textures such that each texture includes the information for one view

A user interface and an earth-moving machine are described. The user interface includes displaying means and a control unit (CU). The displaying means includes a transparent display unit for displaying virtual earth-moving images. The images are displayed at a virtual image distance from the displaying unit.

A system for display three dimensional content on a display.

Stereoscopic system including a portal component, first sensor and first cable, second sensor and second cable, first display and second display. The portal component includes an axis, a first channel and second channel extending along the axis. The first sensor is secured within the first channel at a first angle with respect to the axis and directed inwardly toward a location. The first cable extends from the first sensor. The second sensor is secured within the second channel at a second angle with respect to the axis and directed inwardly toward the location. The first angle and second angle converge at the location to define a depth of perception. The second cable extends from the second sensor. The first display structure is disposed in proximity to a left aperture of an eyeframe, and the second display structure is disposed in proximity to a right aperture of the eyeframe.

A system comprising a video display device, an audio output device and a computing device. The computing device may comprise one or more processors configured to (i) determine orientation angles of a spherical video based on an input, (ii) extract a viewport from the spherical video based on the orientation angles, (iii) output the viewport to the video display device, (iv) render a sound field based on the orientation angles and the audio output device and (v) output the sound field to the audio output device. Sound sources that comprise the sound field are adjusted to align with the viewport. The sound sources outside of the viewport are attenuated.

The present invention is directed to a laser light source.

To reduce burden of a viewer at the time of performing stereoscopic display by a stereoscopic display device and to show a stereoscopic image in a natural and comfortable manner. A disparity estimating unit 210 estimates disparity from the left and right images of an input image to generate a disparity map. A disparity analyzing unit 230 analyzes the disparity map to generate a disparity control parameter for performing suitable disparity control. A disparity control unit 240 controls the content of processing at an image conversion unit 250 in accordance with the disparity control parameter. The image conversion unit 250 performs image conversion on the input image based on the control by the disparity control unit 240 to output an output image. The image conversion unit 250 performs image conversion of two steps. The image conversion unit 250 performs shift processing for shifting the relative positions of the left and right images of the input image in the horizontal direction as first step image conversion, for example. The image conversion unit 250 performs scaling processing for performing enlargement/reduction of the entire screen with each center of the left and right images as a reference, as second step image conversion, for example.