Abstract: Embodiments of the disclosure relate to a pixel structure for naked-eye stereoscopic display, which comprises: a main display region; and at least one crosstalk region. The main display region and the crosstalk region are configured such that brightness of the main display region and brightness of the crosstalk region are controlled separately. Embodiments of the disclosure also relate to an array substrate for use with an inclined optical grating, and a method for controlling the pixel structure of the array substrate.

Abstract: Embodiments of the present invention relates to the technical field of augmented reality. A virtual reality display method is disclosed, comprising: acquiring a real scene picture; retrieving from the real scene picture a target image having the same shape and color with a sample image, and extracting the space coordinates of the target image; and shielding off or highlighting the target image according to the space coordinates. From the perspective of subtraction and on the basis of a real scene, the virtual reality display method and system according to the embodiment of the present invention achieve the effect of shielding off or weakening interference information of the real scene and highlighting the real subject of interest by means of shielding off or highlighting.

Abstract: A grating, a manufacturing method thereof and a display device are disclosed. The grating comprises: a substrate including a plurality of first view field regions (A1) and a plurality of second view field regions (A2) which are alternately distributed; a plurality of ridge structures formed on the substrate in each first view field region (A1) and each second view field region (A2); and a patterned light shield layer being formed on the ridge structures and including a plurality of light-blocking regions and a plurality of light-transmitting regions, wherein in each first view field region (A1), each light-transmitting region is formed on a sloping surface of a first side of each ridge structure; in each second view field region (A2), each light-transmitting region is formed on a sloping surface of a second side of each ridge structure; and the first side and the second side are two opposite sides.

Abstract: The embodiments of the present invention disclose a remote conference system and a method of performing the remote conference.

Abstract: A display device and driving method thereof are disclosed. The display device includes a display screen, including a plurality of sub-pixels arranged in the form of a matrix, colors of the sub-pixels in the same column including all colors necessary for display by the display screen; a grating disposed on top of the display screen, including light-transmissive regions and light-shading regions that are arranged alternately, the light-transmissive regions being in parallel to each column of the sub-pixels; a rolling structure, located between the display screen and the grating; and a push mechanism, for pushing the grating and/or the display screen, so that relative position of the grating and the display screen is switchable between a first state and a second state, and switchover between a dual viewing field display effect and an anti-spy display effect is achieved for the display device.

Abstract: A dual view-field display and a fabricating method and a driving method thereof are provided. The dual view-field display includes a color filter substrate and an array substrate which are oppositely disposed. A slit grating is disposed on a side of the color filter substrate or the array substrate, and the color filter substrate includes a plurality of pixel units and a first black matrix surrounding each pixel unit. The slit grating includes light-shielding regions and light-transmitting regions, which are arranged at intervals in a matrix. The dual view-field display further comprises a light blocking portion configured for preventing light rays from leaking out of an upper-edge region and/or a lower-edge region of the light-transmitting region, which solves a problem that a viewing angle of a user of the dual view-field display is limited.

Abstract: Embodiments of the present invention disclose a dual-view field display panel comprising: a first substrate and a second substrate disposed opposite to the first substrate; and a dual-view grating disposed on a side of the first substrate away from the second substrate, which has a plurality of elongated transparent areas spaced from each other; wherein each of the plurality of elongated transparent areas corresponds to a plurality of rows of pixels and is substantially parallel therewith, and the number of rows of the plurality of rows of pixels corresponding to each of the plurality of elongated transparent areas is selected based on the thickness of the first substrate, so that light from the plurality of rows of pixels is able to be viewed in the left-view field or in the right-view field through a corresponding transparent area.

Abstract: A double-vision-device alignment device and a double-vision-device alignment method are provided. The double-vision-device alignment device is configured to accurately align a display pan& with a double-vision device, and comprising; a first chromaticity detecting unit, configured to detect a color in a first viewing region; a second chromaticity detecting unit, configured to detect a color in a second viewing region, wherein the first viewing region and the second viewing region are formed by light splitting of the double-vision device, and the first viewing region and the second viewing region correspond to different display regions of the display panel, respectively. It is judged whether an alignment is accurate by detection of a chromaticity detecting unit, which can prevent an alignment result from being affected by human factors, improve accuracy and efficiency, and reduce labor intensity, and the device can be operated by non-professionals.

Abstract: A liquid crystal lens, a fabrication method thereof and a display device are provided, the liquid crystal lens comprises: a first substrate (1); a second substrate (2), opposed to the first substrate (1); a liquid crystal layer (3), interposed between the first substrate (1) and the second substrate (2); a first transparent electrode layer (5), located on a side of the first substrate (1) close to the liquid crystal layer (3); a planarization layer (6), located on a side of the first transparent electrode layer (5) close to the liquid crystal layer (3); a first alignment layer (4), located on a side of the planarization layer (6) close to the liquid crystal layer (3); a second transparent electrode layer (7), disposed on a side of the second substrate (2) close to the liquid crystal layer; a second alignment layer (8), disposed on a side of the second transparent electrode layer (7) close to the liquid crystal layer (3).

Abstract: Disclosed is a method for driving a display device. The display device comprises scanning lines, data lines, pixels, a first source driving circuit, and a second source driving circuit. The scanning lines are sequentially located in a first region, an intermediate region, and a second region. Each data line is divided into two electrically disconnected lines. The method comprises: turning on one scanning line in the first region and one scanning line in the second region simultaneously; the first and second source driving circuits providing data for each pixel electrically connected to the turn-on scanning lines in the first and second regions; turning on one scanning line in the intermediate region; and providing data by the first or second source driving circuits according to a position in which each data line is divided into the two electrically disconnected lines.

Abstract: The present invention provides a 3D display apparatus, a 3D display system and a driving method thereof. The 3D display system comprises 3D display glasses and the 3D display apparatus. The 3D display apparatus comprises a liquid crystal display panel and a backlight module. In the driving method, when driving the liquid crystal display panel, the backlight module is turned on at least two times within a frame time. The present invention can improve a crosstalk problem and a flickering problem of the 3D display apparatus.

Abstract: A liquid crystal display device includes a first voltage source providing a first voltage; a second voltage source providing a second voltage greater than the first voltage; and a switching unit arranged at a connection between a gate terminal of a first TFT and a scan line. The switching unit has a control terminal electrically connected to the scan line, an input terminal electrically connected to the first voltage source, and an output terminal electrically connected to the second voltage source and a common electrode of a storage capacitor of a pixel unit. When the switching unit receives a scan signal, the first voltage source supplies the first voltage to the common electrode of the storage capacitor of the pixel unit. When no scan signal is received, the second voltage source supplies the second voltage to the common electrode of the storage capacitor of the pixel unit.

Abstract: Embodiments of the present invention disclose a stereoscopic display system and a driving method thereof The stereoscopic display system includes a display unit, shutter glasses, and a backlight unit. The display unit displays a left-eye image and a right-eye image in a time division manner. The shutter glasses include a left-eye lens and a right-eye lens. The shutter glasses and the display unit alternately open and close the left-eye lens and the right-eye lens in synchronization with each other. The backlight unit supplies planar light to the display unit. Within a time period of activation of the shutter glasses, the shutter glasses show a transmittance in a first time interval smaller than a transmittance in a second time interval. The backlight unit includes first light source sections and second light source sections. The first light source sections have display brightness that is less than display brightness of the second light source sections.

Abstract: A flat panel display includes a display panel and a control circuit. The display panel has a display area and a peripheral area. Besides, the display panel includes a pixel array, signal lines, first rescue lines, second rescue lines, and an adjustable load. The pixel array is located in the display area, and the signal lines extend from the display area to the peripheral area and electrically connect the pixel array. The first rescue lines, the second rescue lines, and the adjustable load are disposed in the peripheral area. Each of the second rescue lines crosses an end of one of the signal lines, and the adjustable load is electrically connected with the first rescue lines. The control circuit includes a driving unit and a rescue unit. The driving unit is electrically connected with the signal lines, and the rescue unit is electrically connected with the first rescue lines.

Abstract: An active device array substrate including a substrate, scan lines, control lines, data lines, pixel structures, main transmission lines and sub transmission lines is provided. The substrate has an active area and a peripheral area. The scan lines and the control lines are disposed within the active area. The control lines are parallel to the scan lines and each control line is located between two of the scan lines. The main transmission lines located within the peripheral area are connected with the scan lines. The sub transmission lines located within the peripheral area are connected with the control lines. Each sub transmission line is located between two of the main transmission lines. Each main transmission line at least includes an impedance adjusting unit, and the impedance difference between each main transmission line and one of the adjacent sub transmission lines is larger than 3?.

Abstract: A flat panel display includes a display panel and a control circuit. The display panel has a display area and a peripheral area. Besides, the display panel includes a pixel array, signal lines, first rescue lines, second rescue lines, and an adjustable load. The pixel array is located in the display area, and the signal lines extend from the display area to the peripheral area and electrically connect the pixel array. The first rescue lines, the second rescue lines, and the adjustable load are disposed in the peripheral area. Each of the second rescue lines crosses an end of one of the signal lines, and the adjustable load is electrically connected with the first rescue lines. The control circuit includes a driving unit and a rescue unit. The driving unit is electrically connected with the signal lines, and the rescue unit is electrically connected with the first rescue lines.

Abstract: An LCD device having test architecture includes a plurality of data lines, a plurality of gate lines, a plurality of common lines, and a plurality of rows of pixel units. The odd and even common lines are utilized for furnishing a first common voltage and a second common voltage, respectively. The odd and even rows of pixel units are coupled to corresponding odd and even common lines, respectively. Furthermore, disclosed is a test method for detecting defects of the LCD device. The test method includes enabling all the gate lines and furnishing a first test voltage to a corresponding data line during a first interval, disabling even gate lines and furnishing a second test voltage to the corresponding data line during a second interval, and switching the second common voltage from a first common test voltage to a second common test voltage during a third interval.