An electronic device includes an active area and multiple shift registers. The active area comprises multiple pixel circuits. Each of the multiple shift registers is configured to output a first control signal, a second control signal, and a third control signal to a part of pixel circuits of the multiple pixel circuits. A duty ratio of the third control signal is greater than a duty ratio of the second control signal, and the duty ratio of the second control signal is greater than a duty ratio of the first control signal. A part of the multiple shift registers and other part of the multiple shift registers are substantially symmetrically disposed at two sides of the active area, respectively.

A shift register includes a latch clock generation circuit and a clock latch circuit. The latch clock generation circuit generates a latch clock signal and an inverted latch clock signal based on a first internal clock signal, a first inverted internal clock signal, a second internal clock signal, and a second inverted internal clock signal. The clock latch circuit latches a control signal in synchronization with one signal selected from the first internal clock signal, the first inverted internal clock signal, the second internal clock signal, and the second inverted internal clock signal. The clock latch circuit also latches the latched control signal in synchronization with the latch clock signal or the inverted latch clock signal to generate and output a shift control signal.

A gate driving circuit comprises a plurality of shift registers coupled in serial. An nth shift register includes a driving circuit, a pull-up circuit and a first auxiliary voltage regulator circuit. The driving circuit is electrically coupled to an output node and a first node. The driving circuit is configured to receive a clock signal and output a gate signal according to the clock signal. The pull-up circuit is electrically coupled to the driving circuit. The first auxiliary voltage regulator circuit is electrically coupled to the pull-up circuit and a second node. The first auxiliary voltage regulator circuit is configured to receive a control signal and the second node corresponding to a second voltage.

The present disclosure provides a shift register. The shift register includes: a first node control module configured to control level at a first node based on a first clock signal and a second clock signal; a second node control module configured to control level at a second node based on level at the first node, the first clock signal, the second clock signal, a first low level signal and a high level signal; an output control module configured to control an output terminal to output high or low level based on level at the first node, level at the second node, the high level signal and a second low level signal; and a carry control module configured to control a carry terminal to output high or low level based on level at the second node, level at the output terminal, the high level signal and the second low level signal.

A shift register, a driving circuit and a display device are provided. The shift register comprises an output circuit, a node control circuit, and a first node charging circuit. The output circuit provides a signal at a first clock signal terminal or a signal at a first reference voltage terminal to a gate signal output terminal under a control of a signal at a first node or a control of a signal at a second node. The node control circuit controls levels of the signal at the first node and at the second node to be opposite. The first node charging circuit includes a first control terminal, and provides a signal at a first fixed voltage terminal to the first node under a control of a signal at the first control terminal during a charging period of the first node in a non-scanning period.

A shift register unit, a method of driving a shift register unit, a gate driving circuit and a display device are provided. The shift register unit includes an input circuit, a first pull-up node reset circuit and an output circuit. The input circuit is configured to control an level of a pull-up node to a first level in response to an input signal of an input terminal, and thereafter control a level of a first node to a second level under control of a level of a pull-down node. The first node is in a current path for controlling the level of the pull-up node. The first pull-up node reset circuit is configured to reset the pull-up node in response to a first reset signal. The output circuit is configured to output a clock signal to an output terminal under control of the level of the pull-up node.

A shift register circuit includes an input terminal, a reset terminal, a first scan voltage terminal, a second scan voltage terminal, a first reference voltage terminal, a second reference voltage terminal, a clock terminal, an output terminal, an input circuit, a first control circuit, a second control circuit, and an output circuit. The first control circuit is configured to supply a second reference voltage applied at the second reference voltage terminal to a first node and bring the second reference voltage terminal into conduction with the output terminal in response to a second node being at an active potential. The second control circuit is configured to supply a first reference voltage applied at the first reference voltage terminal to the first node and bring the first reference voltage terminal into conduction with the output terminal in response to a third node being at an active potential.

The present disclosure provides a gate driving circuit, a driving method, and a display device. The gate driving circuit includes cascaded multistage gate driving units and a reset adjustment unit. Each stage of the gate driving units includes a pull-up module, a first output module, a second output module, and a reset module. The reset adjustment unit is used for, under the control of a first and a second control signal, inputting the reset signal of the reset terminal of a former stage gate driving unit to the reset module of a latter stage gate driving unit, and inputting the reset signal of the reset terminal of the latter stage gate driving unit to the reset module of the former stage gate driving unit.

A shift register circuit including: a first switching unit, a second switching unit, a third switching unit, a fourth switching unit, a fifth switching unit, a sixth switching unit, a seventh switching unit, and an eighth switching unit.

The present disclosure provides a shift register. The shift register includes: a first node control module for controlling level at the first node; a second node control module for controlling level at a second node; and an output control module for controlling the output terminal to output high or low level. The first node control module includes an input unit configured to write the input signal into the third node and a protection unit configured to control a level at a fourth node based on a level at the third node and control writing of the level at the fourth node into the first node based on the second clock signal. The technical solution of the present disclosure can prevent the transistor for providing the third node with inputting signal from being broken down.