A charge release circuit, a display substrate, a display device and a charge release method thereof are provided. The charge release circuit including: a controller, a charge release sub-circuit and a first conductor, wherein the charge release sub-circuit is respectively connected with the controller, the first conductor and a second conductor in an active area of an array substrate, and the charge release sub-circuit is configured to conduct the first conductor and the second conductor under a control of the controller, so as to allow charges on the second conductor to move to the first conductor. The charge release circuit can solve the problem that the display panel in the black-screen state displays bright spots so as to reduce the number of bright spots on the display panel in the black-screen state.

The present disclosure provides an array substrate and a display device. The array substrate includes a plurality of pixel units arranged in a matrix form. When one row of pixel units is charged through a second scanning line, a next row of pixel units is pre-charged through a first scanning line, so as to improve the charging efficiency of the pixel units.

A precharge voltage terminal as a connection unit that is for connection with an external precharge voltage output unit that outputs a precharge voltage, a voltage switching circuit that is connected to a data line drive circuit and the precharge voltage terminal in an input stage, is connected to data lines in an output stage, and switches a connection target of the data lines between the data line drive circuit and the precharge voltage terminal, and a control circuit that controls the voltage switching circuit such that the connection target of the data lines is switched to the precharge voltage terminal and the precharge is supplied to the data lines in a fly-back period before a tone display period in which a voltage of an image signal is supplied to pixels via the data lines are provided.

Systems, methods, and device are provided to provide inversion techniques for dynamic variable refresh rate electronic displays. One embodiment of the present disclosure describes An electronic display including a display panel that display images with varying refresh rates and a timing controller that receives image data from an image source, determines a counter value, and instructs a driver in the electronic display to apply a voltage to the display panel to write an image on the display panel, in which a negative voltage is applied when the counter value is positive and a positive voltage is applied when the counter value is less than or equal to zero. Additionally, the timing controller update the counter value based at least in part on duration the image is displayed on the display panel, wherein the counter value increases when the voltage is positive and decreases when the voltage is negative.

The invention provides a structure of AMOLED driver circuit with external compensation, disposing mutually independent detection scan driver module (2) and gate scan driver module (3), disposing data selector (MUX) for each column of pixel unit circuits (1); during frame normal display, the gate scan driver module (3) outputting normal scan driver signals (G(1)-G(n)) through all data selectors (MUX) to the gates of switch TFTs (T1) in each column of pixel unit circuits (1); during frame V-blanking, the detection scan driver module (2) making one of data selectors (MUX) to respectively output corresponding detection scan driver signals to the gates of switch TFT (T1) and detection TFT (T3) of corresponding column of pixel unit circuits (1) to perform detection and compensation on TFT or OLED stage-by-stage during AMOLED panel display duration without affecting display quality.

A display device is operated by using several iterations of a scan phase followed by a global drive phase. In the scan phase, the state of each pixel in the display device is set to either “enabled” or “disabled”, during which time a global drive generator is inactive. Then, in the global drive phase, a global drive signal is sent to the display device. Only the subset of enabled pixels is affected by the global drive signal, which causes the enabled pixels to perform a transition to a desired display state. The sequence of the scan phase followed by the global drive phase is then repeated up to the number of unique transitions required to update the display device.

A gate driving circuit and a display apparatus including the same are disclosed, in which a plurality of gate lines may be driven through one stage circuit. The gate driving circuit includes first to mth stage circuits outputting a plurality of scan signals by dividing the scan signals into a first signal group and a second signal group. The first to mth stage circuits are grouped into k number of stage groups having two adjacent stage circuits, stage circuits of jth stage group (j is a natural number of 1 to k−1) output the scan signals of the first signal group to be earlier than the scan signals of the second signal group, and stage circuits of (j+1)th stage group output the scan signals of the second signal group to be earlier than the scan signals of the first signal group.

A display apparatus includes pixels arranged in a two-dimensional matrix pattern, each of which including a light-emitting unit and a drive circuit that drives the unit and includes a comparator circuit that compares a control pulse with potential based on signal voltage and outputs predetermined voltage based on the result, a transistor driving the unit in response to the predetermined voltage, and a current source that supplies current to the unit during driving of the transistor, includes a current-source transistor, a capacity unit connected to a gate electrode of the current-source transistor, a differential amplifier that detects a differential between voltage based on reference constant current and reference voltage, and a transistor controlling the voltage based on reference constant current depending on current flowing through the current-source transistor, and controls gate potential of the current-source transistor on the basis of output of the amplifier in synchronization with a scanning signal.

A display device including: a scan driver that transmits scan signals to scan lines; a data driver that data signals to data lines; and a display portion that includes pixels, respectively connected to the corresponding scan lines and corresponding data lines, and displays an image by the pixels that simultaneously emit light according to the corresponding data signals, wherein each of pixels includes: an organic light emitting diode; a first transistor that includes a gate connected to a first node, and is connected between first power and an anode of the organic light emitting diode; a second transistor that includes a gate connected to a corresponding scan line and transmits the corresponding data signal to the first node; and a first capacitor that is connected to the first node, and stores a data voltage according to the data signal.

A variety of methods for driving electro-optic displays so as to reduce visible artifacts are described. Such methods include (a) applying a first drive scheme to a non-zero minor proportion of the pixels of the display and a second drive scheme to the remaining pixels, the pixels using the first drive scheme being changed at each transition; (b) using two different drive schemes on different groups of pixels so that pixels in differing groups undergoing the same transition will not experience the same waveform; (c) applying either a balanced pulse pair or a top-off pulse to a pixel undergoing a white-to-white transition and lying adjacent a pixel undergoing a visible transition; (d) driving extra pixels where the boundary between a driven and undriven area would otherwise fall along a straight line; and (e) driving a display with both DC balanced and DC imbalanced drive schemes, maintaining an impulse bank value for the DC imbalance and modifying transitions to reduce the impulse bank value.