The present invention provides an over-drive value generating apparatus, which includes: a measuring module utilized to measure a plurality of brightness values shown by using a plurality of first-eye gray scales in every n scales and a plurality of second-eye gray scales in every n scales; an interpolation module utilized to linearly interpolate the brightness values into N×N brightness values which consist of N first-eye gray scales respectively corresponding to N second-eye gray scales; a calculating module utilized to calculate N×N crosstalk values of the N first-eye gray scales respectively switching to the N second-eye gray scales; and a determining module utilized to determine a first over-drive gray scale and a second over-drive gray scale. The present invention further provides a method for generating over-drive values.

An object of the present invention is to realize a liquid crystal display device of a field sequential system which is capable of preventing occurrence of color shift and flicker. One frame period is divided into a plurality of fields, the number of which is greater than the number of lighting patterns. Provided are a liquid crystal state value acquiring unit (131) configured to obtain a liquid crystal state value at an end time of a display field based on an input gradation value in the display field and a liquid crystal state value at an end time of a previous field (one field before the display field) (a gradation value corresponding to an aligned state of liquid crystal molecules), and an application gradation value acquiring unit (133) configured to obtain an application gradation value in the display field by correcting an input gradation value in the display field based on a liquid crystal state value at the end time of the previous field. The application gradation value acquiring unit (133) obtains an application gradation value such that display luminance in each field becomes display luminance corresponding to the input gradation value.

Interactive display system and method are provided, and the interactive display system includes a head-mounted display and an electronic device. The head-mounted display is configured to be worn by a user. The electronic device generates a previous frame and frame pixel depth information and transmits the previous frame and the frame pixel depth information to the head-mounted display so that the head-mounted display displays the previous frame. The head-mounted display generates current state information in response to a motion of the user and generates a current frame according to the current state information, the previous frame and the frame pixel depth information. The head-mounted display displays the current frame.

A pixel circuit is provided including a light-emitting element, a drive transistor that supplies a current to the light-emitting element, a light-emission control transistor that controls connection between a drain node of the drive transistor and an anode of the light-emitting element, and a first reset transistor that sets a potential of the anode of the light-emitting element to a predetermined potential. The pixel circuit further includes a second reset transistor that controls connection between a drain node of the drive transistor and a gate node of the drive transistor, a write transistor that controls writing of a signal voltage at the gate node of the drive transistor, and a capacitive element provided between a signal line to which the signal voltage is applied and a source node of the write transistor.

A liquid crystal display panel and a driving method thereof. The liquid crystal display panel comprises: a pixel unit module comprising a plurality of pixel units arranged in a matrix; a plurality of scanning lines, each of the scanning lines connected to at least two of the pixel units on a same row; a gate driving circuit connected to the plurality of scanning lines and providing gate signals for the scanning lines to control the pixel units, which the scanning lines are connected to, to be turned on; a plurality of data lines respectively connected to at least one pixel unit on different columns; a data driving circuit, which is connected to the plurality of data lines and provides data signals for the data lines to charge the turn-on pixel units which the data lines are connected to.

A display device and a power management chip are provided. The power management chip includes a rising-edge trigger, detecting rising edges of a pulse signal; a first counter, configured to calculate the number of the rising edges; a falling-edge trigger, detecting falling edges of the pulse signal; a second counter, configured to calculate the number of the falling edges of the pulse signal; an adder, configured to sum up the number of the rising edges and the number of the falling edges of the pulse signal; and a digital-to-analog converter, electrically connected to the adder, configured to convert to a target voltage based on the sum obtained by the adder. In such a way, the poweron time of the power management chip is reduced.

A driving method, a driving device and a liquid crystal display device are provided. The driving device of the LCD display device outputs the target grey value of the nth frame according to the original grey value of the nth frame, the original grey value of the (n−1)th frame and the look-up table. This improves the luminance of the sub-pixel of the nth frame, shortens the required charging time of the sub-pixel when the (n+1)th frame is being displayed. Thus, the sub-pixel of the (n+1)th frame could be efficiently charged and the luminance of the sub-pixel could be increased. In addition, since the luminance increase of the (n+1)th frame is more than that of the nth frame, the contrast of the LCD display could be improved.

A display control apparatus is configured to synchronize a transmission start timing to start a transmission of a video data to a display apparatus with a display operation start timing for the display apparatus to start a display operation in a display.

A display driving method includes: controlling a source driver to output a data signal, wherein the data signal comprises a plurality of first active pulse signals, the first active pulse signal in the Nth row is for driving a sub-pixel unit in the Nth row, and a timing difference between a starting point of the first active pulse signal in the Nth row and a starting point of a corresponding gate drive signal is smaller than a timing difference between a starting point of the first active pulse signal in the (N+M)th row and a starting point of a corresponding gate drive signal; and wherein the sub-pixel unit in the Nth row is closer to the source driver than the sub-pixel unit in the (N+M)th row, and N and M are positive integers greater than or equal to 1.

A driver, a display device, and an optical compensation method thereof are provided. The display panel includes sub-pixels arranged in an array. The method includes: receiving an initial gray level of each sub-pixel of a picture to be displayed; determining whether each sub-pixel satisfies a preset determination condition based on the initial gray level of each sub-pixel; if an absolute value of a difference between the initial gray levels of two sub-pixels electrically connected to a same data line and located in two adjacent rows is greater than a preset threshold, it is determined that a sub-pixel in a next row satisfies the preset determination condition; and, in response to determining that a sub-pixel satisfies the preset determination condition, acquiring a first compensation parameter of the sub-pixel, and compensating the initial gray level of the sub-pixel based on the acquired first compensation parameter.