The present invention relates to a display panel, having a display area and a fan-out area, and a GOA circuit. The GOA circuit includes a plurality of stage pre-charge modules, arranged for connecting output terminals of two adjacent gates in the GOA circuit in the fan-out area to two corresponding adjacent gate line outputs in the display area respectively. Each of the stage pre-charge modules includes a first thin film transistor, a second thin film transistor, a third thin film transistor, a fourth thin film transistor, a fifth thin film transistor and a sixth thin film transistor.

The present application discloses a drive circuit, a display module driving method and a display module. The drive circuit includes: a timing control chip, configured to output a state signal; a control circuit, configured to receive the state signal and output a ready signal; and a gate drive circuit, configured to control, according to the ready signal, whether a display screen displays a picture or not.

The disclosed systems and methods relate in general to the field of user input to a touch sensitive device, and in particular to user input systems and methods which can reduce the latency between a most recent input event and the displaying of a rendered frame reflecting such input. In an embodiment, a method for decreasing latency between an input touch event and the display of a frame reflecting the input touch event in a touch sensitive device includes estimating the time of a next frame refresh, receiving from the operating system touch data reflective of an input touch event, determining the application associated with the input touch event, estimating the time it will take the application to process and render the received touch data, determining a time at which delivery of the touch data to the application will permit the application to process and render the touch data prior to the time of the next frame refresh, based at least in part on the estimated time it will take the application to process and render the touch data, and the estimated time of the next frame refresh, and providing the touch data to the application just prior to the determined time.

To provide an active matrix display device in which power consumption of a signal line driver circuit can be suppressed, so that power consumption of the entire memory can be suppressed. A plurality of memory circuits which can write data of a video signal input to a pixel in one line period and can hold the data are provided in a signal line driver circuit of a display device. Then, the data held in each memory circuit is input to a pixel of a corresponding line as a video signal. By providing two or more memory circuits in a driver circuit, pieces of data of video signals corresponding to two or more line periods can be concurrently held in the memory circuits.

An object is to improve the drive capability of a semiconductor device. The semiconductor device includes a first transistor and a second transistor. A first terminal of the first transistor is electrically connected to a first wiring. A second terminal of the first transistor is electrically connected to a second wiring. A gate of the second transistor is electrically connected to a third wiring. A first terminal of the second transistor is electrically connected to the third wiring. A second terminal of the second transistor is electrically connected to a gate of the first transistor. A channel region is formed using an oxide semiconductor layer in each of the first transistor and the second transistor. The off-state current of each of the first transistor and the second transistor per channel width of 1 μm is 1 aA or less.

A micro-LED driver applies a low baseline power (i.e., a baseline voltage or current) to pre-charge a micro-LED in a nominally-off (i.e., non-light-emitting) state in addition to applying an operating driving power to drive the micro-LED in a light-emitting state. By pre-charging the micro-LED prior to applying the operating driving power, the micro-LED driver significantly decreases the time between application of the operating driving power and onset of emission of light from the micro-LED. In some embodiments, the micro-LED driver applies an operating driving power having multiple phases of current density to reduce the time between application of the operating driving power and onset of emission of light from the micro-LED.

A liquid crystal display device and a driving method thereof are disclosed. The method for driving the liquid crystal display device comprises the following steps: converting three primary color gray-scale data of a frame image to be displayed into multiple color gray-scale data; and presenting a first color field and a second color field of the frame image in sequence, wherein when each color field is presented, different sub pixels are driven according to a color of the backlight of the color field, the multiple color gray-scale data of the frame image, and pre-stored gray-scale data. According to the method, the color shift phenomena of the traditional liquid crystal display device can be eliminated.

A method comprises monitoring a drawing time of a first frame of image, obtaining a current state of a system on chip (SOC) when the drawing time exceeds a first drawing duration, where the current state comprises a current temperature of the SOC and/or a current load of the SOC, determining whether the current state exceeds a first preset threshold, when the current state does not exceed the first preset threshold, increasing an operating frequency of the SOC in a time range, and restoring the operating frequency after the increasing of the operating frequency ends, obtaining actual drawing duration of the first frame of the image when drawing of the first frame of the image is completed, and monitoring a drawing time of a second frame of the image when the actual drawing duration does not exceed second drawing.

The application discloses a method for determining overdrive voltage, which includes the following operations: determining a gray scale value of a pixel to be displayed of a current display picture and a picture type of the current display picture; determining a target refresh rate according to the picture type; and determining a target overdrive voltage of the pixel to be displayed according to the target refresh rate and the gray scale value of the pixel to be displayed, where the target refresh rate and the target overdrive voltage are positively correlated. The application also discloses a display panel and a computer readable storage medium. The display panel of the present application reasonably determines the overdrive voltage.

A display device includes a display array and a driving circuit. The display array includes at least one scan line. The driving circuit drives the display array and includes a timing controller and a gate driver. The timing controller controls a refresh rate of the display array at a first frequency or a second frequency, where the first frequency is higher substantially than the second frequency. The gate driver switches between supplying an enable voltage signal and a disable voltage signal to the scan line. Under the first or frequency, a corresponding first or second voltage difference exists between the enable voltage signal and the disable voltage signal. The first voltage difference is substantially greater than the second voltage difference, and the enable voltage signal has a same enable period.