A display system circuitry capable of saving power consumption includes a display panel and a driver circuitry. In particular, the display panel includes a plurality of source electrodes with a plurality of data lines and a plurality of gate electrodes further includes a gate driver which is directly incorporated into a thin film transistor array to form Gate on Array (GOA) electrode, a source electrode transmitting a plurality of data driving signals, a gate electrode transmitting gate driving signals, a VCOM electrode transmitting voltage driving signals, a display electrode transmitting displaying driving signals. The driver circuitry includes a display driver IC which includes a source driver operably configured to drive the source electrode and gate control to control gate driver output, and a touch driver IC configured to generate the touch scan signal from a touch sensor.

A gate driver on array (GOA) device and a display panel are provided. The GOA device includes multi-level cascaded GOA units. Each level of the GOA units comprises a first sub GOA unit and a second sub GOA unit. The first sub GOA unit is configured to output a first scan driving signal. The second sub GOA unit is configured to output a second scan driving signal. The first sub GOA unit and the second sub GOA unit share at least a portion of signal wirings, so that a width of the GOA device is narrowed while a circuit layout of the display panel is simplified.

An image display apparatus includes a display screen on which pixel circuits are disposed in a matrix, each of which includes an EL element, a transistor connected to a first gate signal line, a transistor connected to a second gate signal line, and a driving transistor. A second gate signal line driving unit and a first gate signal line driving unit of a first gate driving circuit apply a control voltage to the first gate signal line and the second gate signal line, respectively. The second gate signal line driving unit of a second gate driving circuit applies a control voltage to the first gate signal line. An ON voltage, a first OFF voltage, and a second OFF voltage are sequentially applied to the first gate signal line. The ON voltage and the first OFF voltage are sequentially applied to the second gate signal line.

An image display apparatus includes a display panel that displays an image and a switching panel operated in a two-dimensional mode or three-dimensional mode such that the image is perceived as a two-dimensional mode or three-dimensional image on the display panel. The switching panel includes a plurality of unit devices. Each of the unit devices includes a first zone disposed at one side of a center axis of the unit device and a second zone disposed at the other side of the center axis. Each of the first zone and the second zone includes a plurality of electrodes, respectively. The plurality of electrodes do not overlap the center axis.

The present invention provides a GOA circuit of LTPS semiconductor TFT, employed for forward-backward bidirectional scan transmission, comprising a plurality of GOA units which are cascade connected, and N is set to be a positive integer and an Nth GOA unit utilizes a plurality of N-type transistors and a plurality of P-type transistors and comprises a transmission part (100), a transmission control part (200), an information storage part (300), a data erase part (400), an output control part (500) and an output buffer part (600). The transmission gate is employed to perform the former-latter level transferring signal, and the NOR gate logic unit and the NAND gate logic unit are employed to convert the signals, and the sequence inverter and the inverter are employed to save and transmit the signals to solve the issues that the stability of the circuit is poor, and the power consumption is larger as concerning the LTPS with single type TFT elements, and the problem of TFT leakage of the single type GOA circuit to optimize the performance of the circuit. The ultra narrow frame or frameless designs can be realized.

The present disclosure provides a shift register, its driving method, a gate driver circuit and a display device. The shift register includes an input module, a resetting module, a touch switching module, a node control module, a first output module and a second output module. In the shift register, through the cooperation of the above six modules, it is able to provide a touch stage between any two adjacent time periods of a display stage, it enables a driving signal output end of the shift register to output a DC signal at the touch stage, and enable the gate driver circuit to achieve a display function after the touch stage is ended.

A gate driver on array (GOA) circuit and a display device are provided. The GOA circuit is formed on an array substrate, and has a plurality of GOA units. Each of the GOA units has a drive module, a pull-down module, a pull-down output module, and a pull-up output module, which has a forward and reverse scanning function and avoids providing a forward and reverse scanning control unit and receiving a signal of the forward and reverse scanning control unit by connecting a circuit input of a pull-down output module and a drive module.

Some embodiments of the present disclosure provide a shift register unit, a gate driver, a driving method thereof and a display device. The shift register unit includes: an output circuit, configured to receive a clock signal and output the clock signal to an output signal terminal under control of a voltage of a pull-up control node; a pull-down control circuit, configured to receive a control voltage signal and control the voltage of the pull-up control node and a voltage of the output signal terminal according to the control voltage signal; and an output control circuit, configured to receive a first voltage signal and the control voltage signal, and control the voltage of the output signal terminal in response to the first voltage signal and the control voltage signal.

A display device includes a display panel, a timing controller, and a data driver. The display panel includes a central region and a peripheral region. The timing controller converts image data to converted data so that a maximum luminance of the peripheral region is less than a maximum luminance of the central region. The data driver generates a data signal based on the converted data and to provide the data signal to the display panel.

A GOA driving circuit, a TFT display panel and a display device are disclosed. The GOA driving circuit includes: an input module configured for outputting first control signals in accordance with the received display scanning signals and the touch scanning signals; an output module configured for outputting the first output control signals in accordance with the first control signals and the first clock signals; a pull-down module configured for outputting pull-down signals in accordance with the first control signals, the second control signals and the low level signals; and a pull-down maintaining module configure for outputting the second output control signals in accordance with the pull-down signals, the high level signals, and the first clock signals. The DC source is adopted to charge/discharge Qn to keep Qn at a reasonable level, and the transfer capability is enhanced. In addition, the forward scanning and the backward scanning may be implemented.