Embodiments of the present disclosure provide a shift register circuitry and a driving method thereof, a gate driving circuitry, and a display device. The shift register circuitry includes an input circuit and a plurality of output circuits coupled to the input circuit. The input circuit is coupled to an input signal terminal, and is configured to, under the control of the voltage at the input signal terminal, cause the plurality of output circuits to operate. Each of the plurality of output circuits is coupled to a respective clock signal terminal and a respective output signal terminal, and is configured to operate to couple the clock signal terminal to the output signal terminal so as to output a driving signal at the output signal terminal.

A shift register circuit includes a set circuit, a first reset circuit, a first control circuit, and an output circuit. The output circuit is configured to change an active potential at the first node further away from an inactive potential in response to a first clock signal transferred to a signal output terminal being active, and the first control circuit is further configured to, responsive to the first clock signal transferred to the signal output terminal being active, restrict a change in the active potential at the first node based on a second reference voltage from a second reference voltage, the second reference voltage having a magnitude between an active input pulse and the inactive potential.

Provided is a technique of causing less display irregularities to occur when the scanning of the gate lines is resumed in a display device in which the scanning of gate lines is performed intermittently.

A display device includes a display panel, and a driving circuitry that includes a plurality of drive circuits for scanning gate lines. The driving circuitry alternately switches a scanning period in which the gate lines are scanned, and a non-scanning period in which the scanning of the gate lines is suspended, during one vertical scanning period, according to a control signal. Each driving circuit 301n includes a first switching element N that applies a selection voltage to the gate line; an internal line netA; a second switching element A that charges the internal line netA to a first potential; and a third switching element B that includes a drain electrode connected to the internal line netA, and a source electrode having a second potential that is lower than the first potential. a drive circuit corresponding one of the gate lines that is selected at start of the scanning period includes a charging circuit 301b(n) which recharges the internal line netA of this drive circuit to a potential equal to or higher than the first potential, before the start of this scanning period.

A shift register unit, a driving method thereof, a gate driver circuit and a display device are provided. The shift register unit includes a first pull-up node control unit, a second pull-up node control unit configured to enable a pull-up node to be at a first level at a pull-down maintenance stage under the control of a first clock signal, a first pull-down node control unit configured to enable a pull-down node to be at a second level at the pull-down maintenance stage under the control of the first clock signal, a second pull-down node control unit, a gate driving signal output unit configured to output a gate driving signal under the control of the pull-up and pull-down nodes, and a carry signal output unit configured to enable a carry signal output end to output a carry signal under the control of the pull-up and pull-down nodes.

A shift register unit and a driving method thereof, a gate driving circuit, and an array substrate are provided, and the shift register unit includes: an input sub-circuit connected between a signal input terminal and a pull-up node, an output sub-circuit connected between the pull-up node and a signal output terminal; a reset sub-circuit connected between a reset terminal, the pull-up node and the signal output terminal; and a clock signal selection sub-circuit having input terminals connected to a first clock signal terminal and a second clock signal terminal, and a first output terminal connected to the output sub-circuit, and for selecting to provide either a first clock signal or a second clock signal to the output sub-circuit according to voltage levels at the first control terminal and the second control terminal.

An organic light emitting display comprises pixels connected to gate lines, and a gate driving circuit to supply a gate signal to at least one gate line, and having stages connected to each other in a cascading way. A n.sup.th (n is a positive integer) stage of the gate driving circuit includes a Q1 node charging unit to charge a Q1 node to a turn-on voltage using first and second clock signals in reverse-phase, and a pull-up transistor to apply the turn-on voltage to an output terminal in response to a Q1 node voltage. The Q1 node charging unit includes a first charging unit to charge the Q1 node voltage to the turn-on voltage using the second clock signal; and a second charging unit to charge a Q2 node, coupled to the Q1 node, using the first clock signal in a section where the Q1 node has the turn-on voltage.

Disclosed is a shift register unit, a gate driving circuit and a driving method, as well as a display apparatus. The shift register unit has a working cycle including an input phase, an output phase, a reset phase and a maintaining phase. In the reset phase, a clock signal is transmitted to an output terminal to pull a voltage of the output terminal down to a reference voltage, and the pulled-down voltage of the output terminal is subsequently changed from the reference voltage to a gate-off voltage. In the maintaining phase, the voltage of the output terminal is maintained at the gate-off voltage. The reference voltage is smaller than the gate-off voltage.

There are provided a shift register unit and a driving method thereof. The shift register unit includes: an input circuit, whose first terminal receives an input signal of the shift register unit, and second terminal is connected to a pull-up node, the input circuit being configured to output the input signal to the pull-up node; an output circuit, whose first terminal is connected to a clock signal terminal, second terminal is connected to the pull-up node, third terminal is connected to an output terminal of the shift register unit, the output circuit being configured to output a signal of the clock signal terminal to the output terminal under the control of the pull-up node; a pull-up node control circuit, and the pull-up node control circuit being configured to discharge the pull-up node through third power supply voltage terminal under the control of a first power supply voltage terminal.

The embodiments of the present disclosure provide a shift register, a method for driving the same, and a gate driving circuit. A pull-down sub-circuit of the shift register is under the control of a third clock signal terminal and a fourth clock signal terminal, wherein signals of the third clock signal terminal and the fourth clock signal terminal are mutually inverted signals, and signal periods of the third clock signal terminal and the fourth clock signal terminal are a half of a signal period of a first clock signal terminal or a second clock signal terminal.

The present application provides a reset circuit for a shift register circuit, a shift register circuit, a gate driving circuit, a display apparatus, and a driving method. The reset circuit comprises a first adjustment control circuit having an input terminal configured to receive a ground line signal, and a control terminal configured to receive a first control signal; a second adjustment control circuit having an input terminal configured to receive an adjustment signal via an adjustment signal input terminal, a control terminal configured to receive a second control signal, and an output terminal configured to be coupled to an output terminal of the first adjustment control circuit; and a storage circuit having a first terminal connected to the output terminals of the second adjustment control circuit and the first adjustment control circuit, and a second terminal connected between a reset signal input terminal and a transistor.