Abstract: A display may include an array of pixels that receive control signals from a chain of gate drivers. Each gate driver may include a logic sub-circuit and an output buffer sub-circuit. The output buffer sub-circuit may include depletion mode semiconducting oxide transistors with high mobility. The logic sub-circuit may include semiconducting oxide transistors, some of which can be depletion mode transistors and some of which can be enhancement mode transistors with lower mobility. The logic sub-circuit may include at least a carry circuit, a voltage setting circuit, an inverting circuit, a discharge circuit.

Abstract: Embodiments of the present disclosure provide a shift register unit and a method foe driving the same, a gate driving circuit, and a display device. The shift register unit includes: a control circuit coupled to an input signal terminal, a clock signal terminal, and an output control terminal, and configured to provide an output control signal to the output control terminal based on a signal from the input signal terminal and a signal from the clock signal terminal; and an output circuit coupled to the output control terminal, an output signal terminal, and a threshold voltage control terminal, and configured to provide an output signal to the output signal terminal under control of a potential at the output control terminal, and adjust a threshold voltage of at least one of a plurality of transistors in the output circuit under control of a signal from the threshold voltage control terminal.

Abstract: The present disclosure relates to a shift register circuit and a drive method thereof, a gate drive circuit, and a display panel. The shift register circuit comprises a second reset circuit, and a reset operation is performed for a first node and a signal output terminal by the second reset circuit during an off stage of the display panel.

Abstract: The present disclosure provides a gate driver-on-array (GOA) unit and a method of driving the same, a GOA circuit, and a display apparatus. The GOA unit includes a pulling-up circuit, a pulling-down circuit and an output holding circuit. The pulling-up circuit is configured to output a gate scanning signal from the output terminal, under the control of a trigger signal, a first control signal and a second control signal. The output holding circuit is configured to hold the gate scanning signal output from the output terminal, under the control of the trigger signal, the first control signal and the second control signal. The pulling-down circuit is configured to reset the gate scanning signal and hold the gate scanning signal in a reset state for a set time period, under the control of the trigger signal, the first control signal and the second control signal.

Abstract: The present disclosure provides a gate driving circuit, a shift register, and a driving control method thereof. The shift register includes: a gate signal generation circuit configured to generate a first gate signal for gating transistors, wherein the gating transistors comprise a first gating transistor and a second gating transistor coupled in series; a gate signal output control circuit configured to receive a first level signal, and output a first gate signal from the gate signal generation circuit to the first gating transistor and the second gating transistor under control of the first level signal; and a control circuit configured to receive a second level signal, a first control signal, and a second control signal, and output the first control signal to the first gating transistor and output the second control signal to the second gating transistor under control of the second level signal.

Abstract: The present disclosure provides an emission driving circuit, which includes: a first node control module configured to provide an input signal or a high level signal to a first node based on a first clock signal and a second clock signal, to control a level at the first node; a second node control module configured to control a level at a second node based on the level at the first node, the first clock signal, the second clock signal, a first low level signal and the high level signal; and 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. A low level of the first low level signal is different from a low level of the second low level signal.

Abstract: Disclosed is a GOA drive circuit, including a plurality of GOA drive units. Each trigger unit in first K GOA drive units includes a first thin film transistor, which has a gate connected to a trigger clock corresponding to the trigger unit. The trigger clock is configured to turn off the trigger unit when a scan clock of an output unit corresponding to the trigger unit is at a high level.

Abstract: The gate driving circuit includes a shift register including a plurality of stages. An n-th stage among the plurality of stages includes: a pull-up switching element outputting a first clock to an output node in accordance with a voltage in a Q node, a pull-down switching element outputting a gate low voltage VGL to the output node in accordance with a voltage in a QB node, and a logic unit inverting and outputting a voltage in the Q node and a voltage in the QB node.

Abstract: A shift register is proposed, comprising: a first control module connected to an ON voltage access terminal and a first node, for controlling whether to output an ON voltage and a first control signal to the first node; a second control module connected to the ON voltage access terminal, a second node and an output terminal, for controlling whether to output the ON voltage and a voltage of the output terminal to the second node; an output module connected to the first node, the second node, the output terminal, an OFF voltage access terminal, and the ON voltage access terminal, for inputting the ON or OFF voltage to the output terminal according to voltages of the first and second nodes; and an input module connected to an input terminal, for controlling whether to input a signal of the input terminal to the first and second control modules.

Abstract: A shift register is provided that outputs a gate driving pulse even if a start pulse provided to a first stage is not synchronized with a clock pulse. The shift register has multiple stages that sequentially output gate driving pulses. At least one stage includes a first switching device turned-on by a first clock signal and applying the start pulse to a first node. A second switching device is turned-on by the first clock signal and applies a first supply voltage to a second node. A third switching device is turned-on by the start pulse applied to the first node and outputs a second clock signal. A fourth switching device is turned-on by the first supply voltage and outputs a second supply voltage. A fifth switching device is turned-on by the start pulse and applies the start pulse to the first node.

Abstract: A shift register includes unit circuits connected in a cascade, and each of the unit circuits includes a logic circuit, a first output unit, and a second output unit. The first output unit is a buffer amplifier for outputting a driving signal and includes: a first transistor for outputting a first voltage; and a second transistor for outputting a second voltage lower than the first voltage. The second output unit is a buffer amplifier for outputting a signal to a next unit circuit in the cascade and includes: a third transistor for outputting a third voltage; and a fourth transistor for outputting a fourth voltage lower than the third voltage. The second voltage is set at a potential higher than the fourth voltage.

Abstract: A display device including various portions, circuits and other arrangements for outputting various pulses and triggers, for controlling forward shift and backward shift operations.

Abstract: Various structures and methods are disclosed related to configurable scrambling circuitry. Embodiments can be configured to support one of a plurality of protocols. Some embodiments relate to a configurable multilane scrambler that can be adapted either to combine scrambling circuits across a plurality of lanes or to provide independent lane-based scramblers. Some embodiments are configurable to select a scrambler type. Some embodiments are configurable to adapt to one of a plurality of protocol-specific scrambling polynomials. Some embodiments relate to selecting between least significant bit (“LSB”) and most significant bit (“MSB”) ordering of data. In some embodiments, scrambler circuits in each lane are adapted to handle data that is more than one bit wide.

Abstract: A plurality of cascaded unit register circuits which comprises a bidirectional shift register include main stages and dummy stages at the top before the main stages and dummy stages at the bottom after the main stages. A k-th stage outputs a pulse Pk in synchronization with a clock signal with a reference point N1 being at H level. The main stages include terminals NSF and NSB for setting N1 to H to which Pk?1 and Pk+1 are input, respectively, and terminals NRB and NRF for setting N1 to L level to which Pk?2 and Pk+2 are input, respectively. The order of generation of clock signals is reversed according to the direction of a shift, and whether a start trigger signal is applied to a top stage or a bottom stage is switched. Top dummy stages do not have NRB. Bottom dummy stages do not have NRF.

Abstract: A bidirectional shift register outputs pulses from a plurality of cascaded unit register circuits in a shift order which is one of a forward direction and a reverse direction. A ?th stage of unit register circuit (38) has two set terminals connected to respective outputs of (??1)th and (?+1)th stages and two reset terminals connected to respective outputs of (?+2)th and (??2)th stages. The unit register circuit (38) sets, when a pulse is input to any one of the set terminals, a reference point N1 to an H level, and, when a pulse is input to any one of the reset terminals, N1 to an L level. The order of phase change of clock signals is reversed according to the direction of a shift, and whether a start trigger signal is applied to a top stage or a bottom stage is switched.

Abstract: A shift register has a first latch and a second latch and a first output circuit and a second output circuit. The first latch and the second latch are series-connected. The latches are implemented to take over a signal state applied to their data inputs in a transparent state and to maintain the taken-over signal state in a non-transparent operating state. Clock inputs of the latches are switched such that the second latch is in the transparent operating state when the first latch is in the non-transparent operating state and vice versa. The first output circuit is implemented to provide a predetermined level independent of the signal state existing in the first latch at a first shift register output of the shift register in the transparent operating state and to provide a level depending on the signal state stored in the first latch in the non-transparent operating state of the first latch.

Abstract: A method of controlling a successive-comparing-register analog-to-digital convertor (SAR ADC) is provided. Based upon the method, the SAR ADC receives a conversion clock that controls a conversion rate of the SAR ADC.

Abstract: A shift register unit, shift register and display apparatus, for addressing the issue that the leakage current of the depletion TFT affects the shift register.

Abstract: A gated-clock shift register including a series of clocked flip-flops with preceding outputs connected to subsequent inputs as a horizontal digital shift register. Each flip-flop (or other state holding device) includes a clock buffer between the respective flip-flop's clock, and the global clock. Each clock buffer propagates the clock signal when it determines the associated flip-flop will have a state change during that clock cycle (e.g., via an XOR of the flip-flops input and output signals). In the absence of a state change, that buffer does not propagate the clock signal, essentially only clocking the relevant flip-flops. Further, the clock buffer may be implemented with only NMOS devices (or alternatively, only PMOS devices), which offers power savings over an otherwise required CMOS implementation.

Abstract: A gate driver, comprises a plurality of shift registers configured to output signals sequentially such that an Nth shift register is reset by an output signal of an (N+2)th shift register, wherein last, second last and third last shift registers are reset by a last output signal of the last shift register.

Abstract: An image sensing apparatus includes a pixel array including an optical black region and effective pixel region, and a scanning unit which scans the pixel array. The scanning unit includes a first shift register which scans the optical black region by a shift operation, and a second shift register which scans the effective pixel region by a shift operation. The second shift register starts the shift operation during a first period when the first shift register scans the optical black region, and scans a readout region serving as a partial region of the effective pixel region during a second period following the first period.

Abstract: A display device includes a plurality of scan lines and a scan driver. The scan driver includes a plurality of stages for transmitting a scan signal having a first voltage to the plurality of scan lines, and each of the stages includes a sequential switching unit, a sequential output unit, a concurrent switching unit, and a concurrent output unit. The concurrent output unit includes a first transistor for transmitting a second control signal to the output terminal according to a first control signal during a concurrent driving period before the scan signal is converted from a first level to a second level according to the second control signal, and a gate voltage of the first transistor is controlled by a voltage that is different from the first voltage according to the first control signal.

Abstract: A shift register circuit includes plural shift register stages for providing plural gate signals. Each shift register stage includes a driving unit, an input unit, a driving adjustment unit and a pull-down unit. The driving unit is utilized for outputting a gate signal according to a system clock and a driving control voltage. The input unit is put in use for outputting the driving control voltage according to an input control signal and a first input signal. The driving adjustment unit is employed for adjusting the driving control voltage according to a second input signal and a third input signal. The pull-down unit is used for pulling down the gate signal and the driving control voltage according to a fourth input signal.

Abstract: Disclosed are a shift register, and a gate driving circuit including a plurality of shift registers connected in sequence to respectively supply scan signals to a plurality of gate lines of a display device. Each shift register includes: an input unit which outputs a directional input signal having a gate high or low voltage based on an output signal from a previous or subsequent shift register to a first node; an inverter unit which is connected to the first node, generates an inverting signal to a signal at the first node, and outputs the inverting signal to a second node; and an output unit which includes a pull-up unit connected to the first node and activating an output clock signal based on the signal at the first node, and a pull-down unit activating and outputting a pull-down output signal based on a signal at the second node.

Abstract: Each shift register includes a first element controlled by a first potential node to supply a first driving voltage to an output terminal, a second element controlled by a second potential node to supply a second driving voltage lower than the first driving voltage to the output terminal, and a third element for controlling the first potential node and the second potential node so as to have opposite potential levels. Voltages are applied to the third element so that a state of A>B and A>C and a state of A<B and A<C, or a state of A>B and A<C and a state of A<B and A>C, or a state of A<B and A>C and a state of A>B and A<C are switched alternately (A: a gate terminal of the third element, B: a voltage applied to a first terminal thereof, C: a voltage applied to a second terminal thereof).

Abstract: An analog-to-digital converter (ADC) circuit comprising two time-interleaved successive approximation register (SAR) ADCs. Each of the two time-interleaved SAR ADCs comprises a first stage SAR sub-ADC, a residue amplifier, a second stage SAR sub-ADC and a digital error correction logic. The residue amplifier is shared between the time-interleaved paths, has a reduced gain and operates in sub-threshold to achieve power effective design.

Abstract: An image display system includes a gate driving circuit. The gate driving circuit includes several stages of gate drivers each for generating a gate driving signal to drive a row of pixels. Each stage of the gate driver receives a clock signal and a first reset signal. A first stage of the gate driver receives a vertical start pulse as an input signal of the first stage. The remaining stages of the gate drivers respectively receive the gate driving signal generated by a previous stage of the gate driver as the input signal of the remaining stages. Each stage of the gate drivers further receives the gate driving signal generated by a next stage of the gate driver as a second reset signal, and generates the corresponding gate driving signal according to the clock signal, the first reset signal, and the corresponding input signal and second reset signal.

Abstract: To provide a pulse signal output circuit capable of operating stably and a shift register including the pulse signal output circuit. A pulse signal output circuit includes a plurality of transistors each including an oxide semiconductor. In accordance with operations of the pulse signal output circuit, the threshold voltage of the transistor including an oxide semiconductor is changed. A shift register including the pulse signal output circuit is formed. A pulse signal output circuit capable of operating stably and a shift register including the pulse signal output circuit can be provided.

Abstract: Embodiments of the disclosed technical solution provides a shift register unit circuit which operates based on two clock signals and comprises input terminals, a pre-charging circuit, a first level pulling-down circuit, a second level pulling-down circuit and a scan signal output terminal. Embodiments of the disclosed technical solution also provides a shift register having at least two shift register unit circuits connected in cascade, and further provides a liquid crystal display array substrate and a liquid crystal display. Embodiments of the disclosed technical solution settles problems that a threshold voltage of the pulling-down TFT would drift under a direct current bias voltage and a output is unstable due to a clock hopping, increases a reliability of the circuit and reduces power consumption.

Abstract: Discussed herein is a shift register which is capable of stabilizing an output thereof. The shift register includes a plurality of stages for sequentially outputting scan pulses in such a manner that high durations of the scan pulses partially overlap with each other. Each of the stages includes a node controller for controlling a charging duration of a set node, and an output unit for outputting a corresponding one of the scan pulses through an output terminal for the charging duration of the set node.

Abstract: A shift register is provided in which leakage of charges from a voltage at a set node is prevented to stabilize an output from a stage. The shift register includes stages for sequentially outputting scan pulses. An nth one of the stages includes a node controller for controlling voltages at nodes, and an output unit for outputting any one of a corresponding one of the scan pulses and a first discharging voltage according to the voltages at the nodes. The nodes include set and reset nodes. The node controller of the nth stage includes a first switching device controlled by a voltage supplied to the reset node for supplying a second discharging voltage to the set node, and an inverter circuit controlled by a voltage supplied to the set node for supplying any one of a charging voltage and a third discharging voltage to the reset node.

Abstract: A shift register is disclosed. In one aspect, the shift register has a plurality of stages dependently coupled to an input line of a start pulse and is driven by first, second and third clock signals respectively input to first, second and third input lines. The shift register includes first and second voltage stabilizer circuits to prevent leakage currents.

Abstract: An exemplary shift register is adapted for receiving a preceding-stage output signal to generate a preceding-stage supply signal and outputting an input signal as an extreme value of a current-stage output signal according to the preceding-stage supply signal. The shift register includes an active controller, a voltage boosting circuit and an output circuit. The active controller receives the preceding-stage output signal and thereby produces an active control signal. The voltage boosting circuit receives a first operating voltage, the preceding-stage supply signal and the active control signal, and uses a capacitive coupling effect to change the voltage value of the preceding-stage supply signal and thereby generates an output control signal. The output circuit is electrically coupled to the voltage boosting circuit, the active controller and the input signal and determines the time of outputting the input signal as the extreme value according to the output control signal.

Abstract: Each stage (Xi) of a shift register includes a first output transistor (M5), a first capacitor (C1), an input gate (M1), a first switching element (M2), a second switching element (M3), a third switching element (M4), and a fourth switching element (M6).

Abstract: A shift register includes a shift circuit configured to shift an input signal in synchronization with a shift dock to output an output signal of the shift register, and a clock control circuit configured to enable the shift clock in response to the input signal and disable the shift clock in response to the output signal of the shift register.

Abstract: An exemplary shift register includes a plurality of transistors. The transistors are subjected to the control of a start pulse signal, a first clock signal and a second clock signal to generate a gate driving signal. The first clock signal and the second clock signal are phase-inverted with respect to each other. A logic low level of the first clock signal and another logic low level of the second clock signal are different from each other. Moreover, the transistors are negative threshold voltage transistors. A potential at the gate of the each of the transistors is lower than another potential at the source/drain of the transistor at the situation of the transistor being switched-off state.

Abstract: A shift register includes a plurality of serially-coupled shift register units each including a first node, a second node, an input circuit, a pull-up circuit and a pull-down circuit. The shift register unit receives an input voltage at an input end, and provides an output voltage at an output end. The input circuit controls the signal transmission path between a first clock signal and the first node according to the input voltage. The pull-up circuit controls the signal transmission path between a second clock signal and the output end according to the voltage level of the first node. The voltage level of the first node or the output end is maintained according to the voltage level of the second node. The voltage level of the second node is maintained according to the first clock signal, the second clock signal and the voltage level of the first node.

Abstract: A pulse signal output circuit capable of operating stably and a shift register including the pulse signal output circuit are provided. A clock signal is supplied to one of transistors connected to a first output terminal. A power supply potential is applied to one of transistors connected to a second output terminal. Thus, power consumed by discharge and charge of the transistor included in the second output terminal can be reduced. Further, since a potential is supplied from a power source to the second output terminal, sufficient charge capability can be obtained.

Abstract: An object of the present invention is to provide a pulse signal output circuit capable of operating stably and a shift register including the pulse signal output circuit. In an embodiment of the pulse signal output circuit, a transistor has a source terminal or a drain terminal connected to a gate electrode of another transistor having a source terminal or a drain terminal forming an output terminal of the pulse signal output circuit, the channel length of the transistor being longer than the channel length of the other transistor. Thereby, the amount of a leakage current modifying the gate potential of the other transistor can be reduced, and a malfunction of the pulse signal output circuit can be prevented.

Abstract: An object is to provide a pulse signal output circuit capable of operating stably and a shift register including the pulse signal output circuit. A pulse signal output circuit according to one embodiment of the disclosed invention includes first to tenth transistors. The ratio W/L of the channel width W to the channel length L of the first transistor and W/L of the third transistor are each larger than W/L of the sixth transistor. W/L of the fifth transistor is larger than W/L of the sixth transistor. W/L of the fifth transistor is equal to W/L of the seventh transistor. W/L of the third transistor is larger than W/L of the fourth transistor. With such a structure, a pulse signal output circuit capable of operating stably and a shift register including the pulse signal output circuit can be provided.

Abstract: An asynchronous logic family of circuits which communicate on delay-insensitive flow-controlled channels with 4-phase handshakes and 1 of N encoding, compute output data directly from input data using domino logic, and use the state-holding ability of the domino logic to implement pipelining without additional latches.

Abstract: A shift register includes a shift circuit configured to shift an input signal in synchronization with a shift dock to output an output signal of the shift register, and a clock control circuit configured to enable the shift clock in response to the input signal and disable the shift clock in response to the output signal of the shift register.

Abstract: A shift register includes a plurality of stages, each of the stages generate an output signal, in sequence. Each of the shift register includes a present stage and a first capacitor. The present stage outputs an output signal based on one of a scan start signal and a carry signal of the previous stage. The first capacitor reduces a ripple component of the carry signal of the present stage which activates the next stage. Therefore, a carry signal having a reduced ripple component is supplied to the next stage, so that a transient current is intercepted at a transistor receiving the carry signal, which is arranged in the next stage, thus ensuring reliability of the shift register.

Abstract: A shift register includes cascade-connected stages, each of which includes a data latch and an output stage. In at least one embodiment, the latch has a single data input which, in use, receives a date signal from a preceding or succeeding stage. The output stage includes a first switch, which passes a clock signal to the stage output when the output stage is activated by the latch. The output stage also comprises a second switch, which passes the lower supply voltage to the stage output when the output stage is inactive.

Abstract: A shift register including shift register units controlled by first and second clock signals for generating an output signal. For each unit, in an active period, the first driving device drives the first switch device to activate the output signal, and the second driving device provides a voltage signal according to the first clock signal to drive the first switch device to de-activate the output signal. When the first switch device de-activates the output signal, the second switch device provides the voltage signal to serve as the output signal according to the second clock signal. In the active period, the voltage signal has a low level, and the first and second clock signals are set as alternating-current signals and are opposite to each other. In a blanking period, the voltage signal has a high level, and each of the first and second clock signals is set as a direct-current signal.

Abstract: A single-channel thin-film transistor buffer includes a first output stage including first and second thin-film transistors connected in series, a seventh thin-film transistor having one main electrode connected to a control electrode of the first thin-film transistor (first control line), the other main electrode connected to a power source of the second thin-film transistor, and a control electrode connected to a second control line, an eighth thin-film transistor having one main electrode connected to a control electrode of the second thin-film transistor (second control line), the other main electrode connected to the power source of the second thin-film transistor, and a control electrode connected to the first control line, and an eleventh thin-film transistor having a control electrode connected to an output terminal of a second output stage connected in parallel with the first output stage and one main electrode connected to the first control line.

Abstract: A shift register circuit includes a plurality of bit register units, coupled in series, for transferring an input signal among the plurality of bit register units to sequentially output the input signal to a plurality of data output terminals according to a control signal and a clock signal, wherein the number of the plurality of data output terminals is greater than that of the plurality of bit register units, and a control unit for generating the control signal to control transference of the input signal.

Abstract: A shift register including shift register units substantially cascaded is disclosed. Each shift register unit is controlled by first and second clock signals opposite to each other for generating an output signal. Each shift register unit includes first and second switch devices and first and second devices. The first switch device provides the output signal through an output node. The first driving device drives the first switch device according to a first input signal to activate the output signal. The second driving device provides a first voltage signal, according to the first clock signal, to drive the first switch device and de-activate the output signal. When the first switch device de-activates the output signal, the second switch device provides the second voltage signal to the output node according to the second clock signal. A level of the first voltage signal is lower than a level of the second voltage signal.

Abstract: A gate drive circuit includes a shift register having stages connected to each other in series. An (m)-th stage (‘m’ is a natural number) includes an output part, a discharging part, a first holding part and a second holding part. The output part outputs the first clock signal as a gate signal in response to a first clock signal provided from an external device and discharges the gate signal in response to a second input signal. The output part includes a first transistor having a first channel length. The discharging part discharges a signal of the first node to the second voltage level. The first holding part maintains a signal of the first node at a level of the gate signal, and is discharged to the second voltage level. The first holding part includes a second transistor having a second channel length that is longer than the first channel length. The second holding part maintains a signal of the first node at a level of the second voltage level.

Abstract: As multiphase clocks to be supplied to a first gate driver that drives odd-numbered scanning lines in a liquid crystal display region and a second gate driver that drives even-numbered scanning lines, clocks, which are effective within an effective period of the image signal just before an image signal starts to be supplied to display elements for each scanning line of the liquid crystal display region, is generated and the first and second gate drivers drive switching elements in the effective period of the clock.