The preset disclosure provides a driving circuit, a driving method, and a display panel including the driving circuit. The driving circuit includes a plurality of gate driver on array (GOA) unit circuits. Odd stages of the GOA unit circuits are cascaded with each other and even stages of the GOA unit circuits are cascaded with each other. Signal lines disposed and corresponding to the odd stages of the GOA unit circuits provide odd stage scan control signals, odd stage scan start signals, and odd stage high frequency clock signals. Signal lines disposed and corresponding to the even stages of the GOA unit circuits provide even stage scan control signals, even stage scan start signals, and even stage high frequency clock signals. A common line disposed and corresponding to all of the GOA unit circuits provides a first low frequency clock signal and a second low frequency clock signal.

Disclosed are an image display method, a device, a smart TV, and a readable storage medium. The image display method includes: acquiring an original image signal of a current frame image; extracting evenly spaced rows of data from the original image signal of the current frame image to form a pre-processed image signal; acquiring each row of data in the pre-processed image signal, scanning the each row of data, synchronously acquiring at least two rows of scan images corresponding to the each row of data to form a display image of the current frame image; and acquiring a frame frequency of the original image signal and a vertical synchronization signal of the display image, controlling a period of a backlight pulse signal according to the frame frequency, controlling a duty cycle of the backlight pulse signal according to a period of the vertical synchronization signal, and displaying the display image.

A rotating display, for creating a three-dimensional image, that includes a display panel configured to rotate about an axis and comprising a plurality of groups of light emitting elements, with each element being individually controllable and configured to display a plurality of pixels of the image, a processor to receive pixel data for the display panel and divide the data into a plurality of pixel data lines, each line comprising pixel data for only one of the groups of light emitting elements, a buffer to receive one or more of the data lines, for each group of light emitting elements, and a demultiplexer configured to receive a pixel data line and provide pixel data to each light emitting element according to a refresh rate of the display panel. The display panel is configured to rotate about the axis at a rate commensurate with the refresh rate of the display panel.

Circuits for programming a circuit with decreased programming time are provided. Such circuits include a storage device such as a capacitor for storing display information and for ensuring a driving device such as a driving transistor drives a light emitting device according to the display information. The present disclosure provides driving schemes for decreasing flickering perceived while displaying video content by introducing idle phases in between in emission phases to increase the effective refresh rate of a display. Driving schemes are also disclosed for reducing the effects of cross-talk by ensuring that programming information is refreshed in a display array that utilizes a driver connected to multiple data lines via a multiplexer.

A display device includes a plurality of pixels. The pixels are configured to be operated in a plurality of frame periods. Each of the frame periods includes at least two first emission periods corresponding to a first scan signal and at least two second emission periods corresponding to a second scan signal. Each of the pixels includes a light emitting diode and a driving circuit coupled to the light emitting diode. In a same frame period, a first pixel of the plurality of pixels is emitted in the at least two first emission periods and a second pixel of the plurality of pixels is emitted in the at least two second emission periods.

A gate driver circuit and a display device including the same have a voltage difference between output lines of the gate driver circuit that is reduced. To this end, a first gate driver is disposed on one side of a display panel, while a second gate driver is disposed on side of the display panel opposite the one side. An odd-numbered output line of the first gate driver is connected to an even-numbered output line of the second gate driver, while an even-numbered output line of the first gate driver is connected to an odd-numbered output line of the second gate driver. Therefore, the voltage difference between the output lines of the gate driver circuit is minimized or reduced.

A processor obtains an input image containing both bright and dark regions. The processor obtains a threshold between a first pixel value and a second pixel value of the display. Upon detecting a region of the input image having an original pixel value above the threshold, the processor can create a data structure including a location of the region in the input image and an original pixel value of the region. The data structure occupies less memory than the input image. The display presents the input image including the region of the image having the original pixel value above the threshold. The processor sends the data structure to a camera, which records the presented image. The processor performing postprocessing obtains the data structure and the recorded image and increases dynamic range of the recorded image by modifying the recorded image based on the data structure.

A processor obtains an input image containing both bright and dark regions. The processor obtains a threshold between a first pixel value and a second pixel value of the display. Upon detecting a region of the input image having an original pixel value above the threshold, the processor can create a data structure including a location of the region in the input image and an original pixel value of the region. The data structure occupies less memory than the input image. The display presents the input image including the region of the image having the original pixel value above the threshold. The processor sends the data structure to a camera, which records the presented image. The processor performing postprocessing obtains the data structure and the recorded image and increases dynamic range of the recorded image by modifying the recorded image based on the data structure.

An image dividing circuit includes an input interface circuit that receives input image data configured by a total number of horizontal pixels HT, an image data dividing circuit that divides the input image data into first to n-th output image data, and an output interface circuit that includes output circuits for first to n-th channels that output the first to n-th output image data. The parameter n is an integer greater than or equal to 3, and the parameter HT is not an integer multiple of the parameter n. An output circuit for an i-th channel outputs i-th output image data in which at least one of the total number of horizontal pixels and the total number of vertical lines in the i-th channel has been variably adjusted. The parameter i is an integer greater than or equal to 1 but smaller than or equal to n.

A processor performing postprocessing obtains an input image containing both bright and dark regions. The processor obtains a threshold between a first pixel value of the virtual production display and a second pixel value of the virtual production display. The processor modifies the region according to predetermined steps producing a pattern unlikely to occur within the input image, where the pattern corresponds to a difference between the original pixel value and the threshold. The processor can replace the region of the input image with the pattern to obtain a modified image. The virtual production display can present the modified image. A processor performing postprocessing detects the pattern within the modified image displayed on the virtual production display. The processor calculates the original pixel value of the region by reversing the predetermined steps. The processor replaces the pattern in the modified image with the original pixel value.