WO2015100828A1 - 栅极驱动电路以及驱动方法 - Google Patents

栅极驱动电路以及驱动方法 Download PDF

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Publication number
WO2015100828A1
WO2015100828A1 PCT/CN2014/071390 CN2014071390W WO2015100828A1 WO 2015100828 A1 WO2015100828 A1 WO 2015100828A1 CN 2014071390 W CN2014071390 W CN 2014071390W WO 2015100828 A1 WO2015100828 A1 WO 2015100828A1
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Prior art keywords
reset
voltage
reset voltage
signal
gate
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PCT/CN2014/071390
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English (en)
French (fr)
Inventor
徐向阳
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深圳市华星光电技术有限公司
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Application filed by 深圳市华星光电技术有限公司 filed Critical 深圳市华星光电技术有限公司
Priority to KR1020167016566A priority Critical patent/KR101906943B1/ko
Priority to JP2016542182A priority patent/JP6231692B2/ja
Priority to GB1610389.7A priority patent/GB2536160B/en
Priority to US14/241,804 priority patent/US10032424B2/en
Priority to EA201691315A priority patent/EA032171B1/ru
Publication of WO2015100828A1 publication Critical patent/WO2015100828A1/zh

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Classifications

    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G3/00Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes
    • G09G3/20Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters
    • G09G3/34Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source
    • G09G3/36Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source using liquid crystals
    • G09G3/3611Control of matrices with row and column drivers
    • G09G3/3674Details of drivers for scan electrodes
    • G09G3/3677Details of drivers for scan electrodes suitable for active matrices only
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2300/00Aspects of the constitution of display devices
    • G09G2300/04Structural and physical details of display devices
    • G09G2300/0404Matrix technologies
    • G09G2300/0408Integration of the drivers onto the display substrate
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2310/00Command of the display device
    • G09G2310/02Addressing, scanning or driving the display screen or processing steps related thereto
    • G09G2310/0264Details of driving circuits
    • G09G2310/0286Details of a shift registers arranged for use in a driving circuit
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2310/00Command of the display device
    • G09G2310/06Details of flat display driving waveforms
    • G09G2310/061Details of flat display driving waveforms for resetting or blanking
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2320/00Control of display operating conditions
    • G09G2320/02Improving the quality of display appearance
    • G09G2320/0219Reducing feedthrough effects in active matrix panels, i.e. voltage changes on the scan electrode influencing the pixel voltage due to capacitive coupling

Definitions

  • the present invention relates to the field of liquid crystal display technologies, and in particular, to a drain driving circuit and a driving method.
  • LCDs liquid crystal displays
  • the Gate Driver on Airay (GO A) technology is a technique in which gate drivers (Gate Driver ICs) are directly fabricated on an array substrate instead of an external silicon wafer.
  • the application of this technology can directly make the gate drive circuit in the periphery of the panel, which reduces the production process and reduces the product cost.
  • the high integration of the TFT-LCD panel is improved, and the panel is made thinner.
  • a feed through voltage in which the display electrode (also referred to as a pixel electrode) is changed by capacitive coupling occurs.
  • the most influential is the gate drive voltage variation, which is the feedthrough voltage generated via the parasitic capacitance Cgd. Therefore, the effect of the feedthrough voltage can be reduced by the method of compensating the common voltage, but since the liquid crystal capacitor Clc is not a fixed parameter, it is difficult to achieve the purpose of improving the image quality by adjusting the common voltage.
  • FIG. 1 is a schematic diagram of a conventional two-stage driving 4T ⁇ C GOA circuit, in which TFT1 is a driving transistor, and is mainly used for controlling a gate line high potential output.
  • TFT2 and TFT3 are reset transistors, and their main function is to pull the gate line potential low while releasing the charge of the holding capacitor Cb, so that the TFT1 is turned off.
  • TFT4 is an input (or pre-charge) transistor. The main trick is to pre-charge the holding capacitor Cb and smash TFT1. The main function of the capacitor Cb is to store the charge and maintain the gate potential of the TFT1.
  • the input signal is the gate line output signal gate[Nl] of the previous row.
  • the output signal of the TFT1 is the current line » line output signal gate[N], and the reset signal is T line. » Line output signal gate[N+l].
  • the input of TFT1 is the clock signal Vck.
  • the specific drive timing is shown in Figure 2.
  • the second-order driving is performed by performing the following operations by using the GOA circuit as the GOA unit. That is, the output of the previous GOA unit is the trigger signal of the GOA unit, and the output of the next GOA unit is used as the reset signal of the GOA unit.
  • the clock signal uses two (Vcik_A, Vclk__B) for the GOA unit and the even line of the odd line. GOA unit.
  • the wire output potential Vss determines the height or amplitude of the output pulse on the grid line.
  • One of the technical problems to be solved by the present invention is to provide a gate driving circuit capable of effectively reducing the influence of the feedthrough voltage on the display quality of image quality.
  • a driving method of the pole driving circuit is also provided.
  • an N-th stage GOA circuit of the multi-stage GOA circuit includes: an energy storage unit; a charging unit, and an electrical connection Between an N-1th gate line and the energy storage unit, precharging the energy storage unit according to the N-1th gate line signal to obtain a voltage; a driving unit, electrically connecting a first clock output line and an Nth pole line, wherein the signal of the Nth pole line is pulled up to a pull-up voltage according to the voltage and a clock signal; a first reset unit, Connected between the energy storage unit and a first reset voltage or a third reset voltage, which is based on the signal of the (N+1)th gate line and the first reset voltage or the third reset voltage The signal of the pole line is reset to the first reset voltage or the third reset voltage; a second reset unit is electrically connected between an Nth gate line and a second reset voltage according to the N+3th gate a signal of the polar
  • the gate line connected to the Nth-level G0A circuit is negative polarity
  • the first reset unit is based on the signal of the N+th pole line And a first reset voltage to reset the signal of the Nth gate line to a first reset voltage, the first reset voltage and the second reset voltage having a negative voltage difference.
  • the first reset unit when the gate line connected to the Nth-level G0A circuit is positive, is a signal of the N+i gate line and a third reset voltage to reset the signal of the Nth pole line to a third reset voltage, the third reset voltage and the second reset voltage having a positive voltage difference.
  • the second reset unit is a transistor having a gate, a first source/drain, and a a second source/drain, the gate is electrically connected to the N+3th gate line, and the first source/drain and the second source/drain are electrically connected to the Nth gate Polar line and second Reset voltage.
  • the first reset unit includes a first transistor and a second transistor, each having a gate and a first a source/drain and a second source Z drain, wherein the drains of the first transistor and the second transistor are electrically connected in common and connected to the N+1th gate line - the first a first source/drain of the transistor is electrically connected to a first end of the energy storage unit, and a first source/drain of the second transistor is electrically connected to a second end of the energy storage unit; The second source/drain of the first transistor and the second transistor are electrically connected in common and are electrically connected to the first reset voltage or the reset voltage.
  • the charging unit is a transistor having a gate, a first source/drain, and a second a source/drain, the gate of the charging unit and the first source/drain are electrically connected to the N-1th gate line, and the second source/drain is electrically connected to the first of the energy storage unit end.
  • the driving unit is a transistor having a gate, a first source/drain, and a second a source/drain, a first source/drain of the driving unit is electrically connected to the clock output line, a gate thereof is electrically connected to the first end of the energy storage unit, and a second source Z is electrically connected to the drain N gate lines and a second end of the energy storage unit.
  • a driving method using any of the above gate driving circuits comprising: charging unit receiving the N-1th pole line signal to precharge the energy storage unit Obtaining a voltage; the driving unit receives a clock pulse signal, and pulls up the signal of the Nth pole line to a pull-up voltage according to the voltage and the clock pulse signal: the first reset unit receives the (N+1)th a signal of the gate line and a first reset voltage or a first: reset voltage, and the Nth gate line according to the signal of the (N+1)th gate line and the first reset voltage or the third reset voltage The signal is reset to the first reset voltage or the third reset voltage; the second reset unit receives the signal of the N+3th gate line and the second reset voltage, and according to the signal of the N+3th gate line and the second The voltage is reset to reset the Nth gate line to a second reset voltage.
  • the first reset unit when the gate line connected to the Nth-stage G0A circuit is negative polarity, the first reset unit receives the first reset voltage, and according to a signal of the Nthth gate line and a first reset voltage to reset a signal of the Nth gate line to a first reset voltage, wherein the first reset voltage and the second reset voltage have a negative power Pressure difference.
  • the first reset unit receives the first polarity when the pole line connected to the Nth stage G0A circuit is positive.
  • the third reset voltage and the second reset voltage have a positive voltage difference.
  • One or more implementations of the present invention may have the following advantages over the prior art;
  • the present invention proposes a fourth-order driving GOA circuit which uses two reset signals to pull the gate output signal to the reset signal Vssl and the reset signal Vss2 for the negative pole line, for the positive pole
  • the line pulls the gate output signal to the reset signal Vss3 and the reset signal Vss2, thereby implementing the fourth-order driving of the pixel unit.
  • the driving circuit can effectively solve the influence of the feedthrough voltage which cannot be solved by the second-order driving circuit on the pixel electrode, thereby improving the image quality effect.
  • Figure i is a schematic diagram of a second-order driven GOA circuit in the prior art
  • FIG. 3 is a schematic diagram of a fourth-order driven GOA circuit according to an embodiment of the present invention -
  • FIG. 4 is a sequence diagram of a fourth-order driven GOA circuit output according to the present invention
  • FIG. 5 is a schematic diagram of voltage waveforms of a gate drive driven by a fourth order
  • FIG. 6 is a schematic diagram showing voltage waveforms of a fourth-order driven positive polarity display electrode
  • Fig. 7 is a view showing a voltage waveform of a fourth-order driven negative polarity display electrode. detailed description
  • the driving circuit of this embodiment is a dry fourth-order driving circuit. It can compensate the feedthrough voltage without changing the common voltage.
  • the fourth-order driving circuit of this embodiment utilizes a storage capacitor ( The feedthrough voltage is used to compensate for the feedthrough voltage generated via the parasitic capacitance Cgd.
  • FIG. 3 is a schematic diagram of a fourth-order driven GOA circuit in accordance with an embodiment of the present invention.
  • the method includes: an energy storage unit Cb, a charging unit 31 electrically connected between a Ni gate line and an energy storage unit Cb, and the energy storage unit Cb according to the first gate line signal Precharge is performed to obtain a voltage.
  • a driving unit 32 is electrically connected to a clock output line and an Nth gate line, and pulls up the signal of the first gate line to a pull-up voltage according to the voltage and a clock pulse signal.
  • a first reset unit 33 is electrically connected between the energy storage unit Cb and a first reset voltage Vssl or a second reset voltage Vss3 according to the signal of the (N+1)th gate line and the first reset voltage Vssl or The reset voltage Vss3 resets the signal of the Nth gate line to the first reset voltage Vss1 or the second reset voltage Vss3.
  • a second reset unit 34 electrically connected between the Nth cabinet line and a second reset voltage Vss2, which is based on the signal of the N+3 gate lines and the second reset voltage Vss2 The gate line is reset to the second reset voltage Vss2.
  • the first reset unit 33 sets the Nth gate according to the signal of the Nth] gate line and the first reset voltage Vssl.
  • the signal of the polar line is reset to the - - reset voltage Vssl, and the first reset voltage Vss1 and the second reset voltage Vss1 have a negative voltage difference (V eW as shown in FIG. 5 described later).
  • the first reset unit 33 transmits the signal of the Nth pole line according to the signal of the Nth 1st gate line and the third reset voltage Vss3.
  • the G0A circuit is substantially a 5T4C circuit including: a transistor TFT1 (as a driving unit 32), transistors TFT2 and TFT3 (to jointly constitute a first reset unit 33), a transistor TFT4 (as a charging unit 31), and a transistor TFT5. (as the second reset unit 34) these five transistors are turned off and a holding capacitor Cb (as an energy storage unit). Also, the parasitic capacitance Cgd between the gate and the drain of the TFT1 is schematically plotted.
  • the input signal of the circuit includes a clock signal (positive or negative polarity clock signal) Vck, an output of the N-1th gate line Output[N-1], and an output of the ⁇ gate line Output [+i],
  • the output of the N+3th gate line is 0utput[N+3] > the first reset signal Vss] or the reset signal Vss3, and the second reset signal Vss2.
  • the driving transistor TFT1 has a gate, a first source/drain and a second source/drain.
  • the first source/drain is electrically connected to the clock output line Vck, and the drain is electrically connected to the capacitor Cb.
  • the first end of the second source/drain electrically connects the Nth gate line and the second end of the capacitor Cb. Mainly used to control the high potential output of the cabinet line.
  • TFT2, TFT3, and TFT5 are reset transistors, which are mainly used to pull the gate line potential low while holding the capacitor The Cb charge is released, and the TFT1 is turned off.
  • the gates of the TFT2 and the TFT3 are electrically connected to each other and connected to the N+1th gate line.
  • the first source/drain of the TFT2 is electrically connected to the first end of the capacitor Cb
  • the first source/drain of the TFT3 is The second end of the capacitor Cb is electrically connected
  • the second source/drain of the TFT 2 and the TFT 3 are electrically connected in common and electrically connected to the first reset voltage Vssi or the third reset voltage Vss3.
  • the TFT2 Since the fourth-order driving of the pixel voltage is realized by the difference of the gate potentials of the positive and negative rows, the TFT2 resets the gate line input to the Vssl potential for the negative line output, and the TFT2 resets the gate line input to the Vss3 for the positive line output. Potential.
  • TFT5 resets the gate output to the Vss2 potential, which is driven by the output signal gate[N+3].
  • the TFT 5 has a drain, a first source/drain and a second source/drain.
  • the gate is electrically connected to the N+3 gate lines, the first source/drain and the second The source/drain are electrically connected to the Nth gate line and the second reset voltage Vss2, respectively.
  • the TFT 4 is an input (or precharge) transistor whose main function is to precharge the holding capacitor Cb and turn on the TFT1.
  • the utility model has a gate, a first source/drain and a second source/drain. The cabinet and the first source/drain are electrically connected to the N-1th gate line, and the second source/drain Connect the first end of the capacitor Cb.
  • a clock sequence with the same cycle and opposite polarity (Clk A, Clk B) is used. They are used in the corresponding GOA circuits on the odd-numbered gate lines and the corresponding GOA circuits on the even-numbered gate lines.
  • the GOA circuit on the gate line Gatel (negative polarity) corresponding to the odd-numbered row lines is reversed, indicating how to implement the fourth-order driving.
  • the TFT 4 receives the driving voltage of the previous gate line, precharges the holding capacitor Cb, and turns on the TFT 1.
  • the TFT1 output pole line high potential Vgh.
  • the TFT2 and the TFT3 receive the driving voltage of the next gate line, pull down the potential of the polar line, and release the charge of the holding capacitor Cb, so that the TFTi is turned off.
  • FIG. 5 is a waveform diagram of the fourth-order drive gate drive voltage.
  • the waveform diagram of the fourth-order drive that among the four-step driving cabinet driving voltage waveforms, there are four kinds of voltages of positive and negative polarities: the snoring voltage Vgh and the voltage difference Vg
  • the voltage Vss2 is turned off, the voltage Vss3 is higher than the turn-off voltage Vss2 (the voltage difference V e W is present ), and the voltage Vss1 is lower than the turn-off voltage Vss2 (the voltage difference V e is present).
  • the gate drive trace voltage responsible for positive and negative polarity is not the same, as shown in Figure 6, it is positive polarity display.
  • the voltage waveform of the electrode wherein, 61 represents the N-th ⁇ gate driving voltage, 62 represents the common voltage, and 64 represents the ⁇ th gate driving voltage.
  • In the figure, I can see that after the display electrode voltage 63 is charged by the source drive, it will undergo three more voltage changes (as indicated by the dotted circle in the figure). The first is the feedthrough voltage 63 via the parasitic capacitance Cgd when the current drain driving switch is off, and the second is the feed through the storage capacitor Cs when the previous (N-1) gate drive trace voltage is pulled back. The voltage 632 is the most important voltage that pushes the display electrode voltage 63 up to the positive voltage range. Finally, ⁇ is the feedthrough voltage 633 generated by the ffl parasitic capacitance Cgd when the current Nth gate drive trace voltage is pulled down. This voltage is due to the relationship of the parasitic capacitance Cgd, and the magnitude of the change is not large, so The impact is also relatively small.
  • Fig. 7 it is a voltage waveform diagram of a negative polarity display electrode.
  • 71 represents the N-1th pole drive voltage
  • 72 represents the common voltage
  • 74 represents the Nth gate drive voltage.
  • the feedthrough voltage 731 generated by the parasitic capacitance Cgd when the current Nth gate drive trace voltage is turned off is affected, and the display electrode voltage 73 is pulled down due to the voltage off relationship.
  • the feed-through voltage 732 of the storage capacitor Cs when the previous (N-1) gate drive trace is pulled down is important because it is the main component that adjusts the voltage to the negative voltage and must be able to Adjust the overall voltage to the required level.
  • the current N gate drive trace voltage is pulled back through the feedthrough voltage 733 of the parasitic capacitance Cgd. Since the magnitude of the pullback voltage is relatively small, the overall effect is relatively small.
  • the voltage that rises upward will be larger for the voltage range of the positive polarity, and the voltage that is raised upward is
  • the upper gate drive trace voltage is pulled up by the feedthrough voltage of the storage capacitor Cs. Because the required voltage is relatively large, the voltage of the previous gate drive trace will be relatively large when it is pulled back.
  • the formation of the negative display voltage range is also accomplished by utilizing the voltage change of the previous gate drive trace. Unlike the positive display electrode voltage, it requires a pull-down feedthrough voltage to form a negative display electrode voltage range. The pull-down voltage it requires is relatively small compared to the positive pull-up voltage.
  • the present invention proposes a 5T1C fourth-order driving GOA circuit, which uses two reset signals to respectively pull the cabinet output signal to the reset signal Vssl and the reset signal Vss2 for the odd-numbered lines, and the even-numbered lines are respectively
  • the gate output signal is pulled down to the reset signal Vss3 and the reset signal Vss2 to implement the fourth-order driving of the pixel unit.
  • the driving circuit can effectively solve the influence of the feedthrough voltage which cannot be solved by the second-order driving circuit on the pixel electrode, thereby improving the image quality effect.

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Computer Hardware Design (AREA)
  • General Physics & Mathematics (AREA)
  • Theoretical Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Crystallography & Structural Chemistry (AREA)
  • Control Of Indicators Other Than Cathode Ray Tubes (AREA)
  • Multimedia (AREA)
  • Liquid Crystal (AREA)
  • Shift Register Type Memory (AREA)
  • Liquid Crystal Display Device Control (AREA)

Abstract

公开了一种栅极驱动电路以及驱动方法。该电路包括多级GOA电路,该多级GOA电路的第N级GOA电路包括:充电单元(31),其根据第N-1条栅极线信号对储能单元(Cb)进行预充电以得到一电压;驱动单元(32),其根据电压及时钟脉冲信号上拉第N条栅极线的信号至上拉电压;第一复位单元(33),其根据第N+1条栅极线的信号以及第一复位电压或第三复位电压而将第N条栅极线的信号复位至第一复位电压或第三复位电压;第二复位单元(34),其根据第N+3条栅极线的信号以及第二复位电压而将第N条栅极线复位至第二复位电压。该电路通过两个复位单元实现像素单元四阶驱动,能够有效地解决馈通电压对像素电极的影响,提高影像品质效果。

Description

櫥极驱动电路以及驱动方法 技术领域 本发明涉及液晶显示技术领域, 尤其涉及一种樋极驱动电路以及驱动方法。
背景技术 近年来, 随着薄型化的显示趋势, 液晶显示器 (Liquid Crystal Display, LCD) 已广 泛使用在各种电子产品的应用中, 例如手机、 笔记本计算机以及彩色电视机等。
阵列基板栅极驱动 (Gate Driver on Airay, GO A) 技术是直接将櫥极驱动电路 (Gate Driver ICs) 制作在阵列基板上, 来代替由外接硅晶片制作的一种技术。 该技术的应用可 直接将栅极驱动电路做在面板周 ί簡, 从而减少了制作程序, 并且降低了产品成本。 此 外, 还提高了 TFT-LCD面板的高集成度, 使面板更薄型化。 在对面板进行驱动时, 会产生由电容耦合引起显示电极(也称像素电极)变动的馈通 (feed through) 电压。 影响最大的是栅极驱动电压变化, 即经由寄生电容 Cgd所产生的 馈通电压。 因此通过对公共电压补偿的方法可以减小馈通电压的影响, 但由于液晶电容 Clc并非是一个固定的参数, 因此通过调整公共电压以便改进影像品质目的不易实现。
传统的二阶驱动 GOA电路本质为一 4T1C (四个 TFT幵关、 一个电容) 电路。 如图 1所示为传统的两阶驱动 4T】C的 GOA电路原理图, 其中, TFT1为驱动晶体管, 主要用 于控制栅线高电位输出。 TFT2和 TFT3为复位晶体管, 主要作用是将栅线电位拉低, 同 时释放保持电容 Cb的电荷, 使 TFT1处于关闭状态。 TFT4是输入(或预充电)晶体管, 主要诈 是给保持电容 Cb预充, 将 TFT1 打幵。 电容 Cb 主要作用是存储电荷, 保持 TFT1栅极电位, 其输入信号为上一行的栅线输出信号 gate[N-l], TFT1输出信号为当前 行 »线输出信号 gate[N], 复位信号为 T一行 »线输出信号 gate[N+l]。 TFT1输入端为时 钟信号 Vck。 具体驱动时序如图 2所示。 通过将上述 GOA电路作为 GOA单元进行以下动作来完成二阶驱动。 即前一 GOA单 元的输出诈为本 GOA单元的触发信号, 下一 GOA单元的输出作为本 GOA单元的复位信 号。 时钟信号采用两个 (Vcik_A, Vclk__B) , 分别用于奇数行的 GOA单元和偶数行的 GOA单元。 櫥线输出电位 Vss决定栅线上输出脉冲的高度或者说是幅度。
然而上述电路没有解决馈通电压带来的影像效果的影响。 因此, 如何解决上述问 题, 提供一种驱动方案以有效减少馈通电压对影像品质的显示效果影响, 乃业界所致力 的课题之一。 发明内容 本发明所要解决的技术问题之一是需要提供一种栅极驱动电路, 其能够有效减少馈 通电压对影像品质的显示效果的影响。 另外, 还提供了一种極极驱动电路的驱动方法。
1 )为了解决上述技术问题, 本发明提供了一种栅极驱动电路, 包括多级 GOA电路, 该多级 GOA电路的一第 N级 GOA电路包括; 一储能单元; 一充电单元, 电连接于一第 N-1条栅极线和所述储能单元之间, 其根据第 N- 1条栅极线信号对所述储能单元进行预充 电以得到一电压; 一驱动单元, 电连接于一 ^钟输出线及一第 N条極极线, 其根据所述 电压及一时钟脉冲信号上拉所述第 N条極极线的信号至一上拉电压; 一第一复位单元, 电连接于所述储能单元和一第一复位电压或第三复位电压之间, 其根据第 N+1条栅极线 的信号以及第一复位电压或第三复位电压而将所述第 N条極极线的信号复位至第一复位 电压或第三复位电压; 一第二复位单元, 电连接于一第 N条栅极线和一第二复位电压之 间, 其根据第 N+3条栅极线的信号以及第二复位电压而将所述第 N条栅极线复位至第二 复位电压。
2) 在本发明的第 ) 项的一个优选实施方式中, 在所述第 N级 G0A电路所连接的 栅极线为负极性 ', 所述第一复位单元根据第 N+ 条極极线的信号以及第一复位电压而 将所述第 N条栅极线的信号复位至第一复位电压, 所述第一复位电压与所述第二复位电 压具有一负电压差。
3 )在本发明的第 1 )项或第 2)项中的一个优选实施方式中, 在所述第 N级 G0A电 路所连接的栅极线为正极性时, 所述第一复位单元根据第 N+i条栅极线的信号以及第三 复位电压而将所述第 N条極极线的信号复位至第三复位电压, 所述第三复位电压与所述 第二复位电压具有一正电压差。
4)在本发明的第 1 )项至第 3 )项中的任一个优选实施方式中, 所述第二复位单元为 一晶体管, 其具有一栅极、 一第一源极 /漏极和一第二源极 /漏极, 该栅极电连接所述第 N+3条栅极线, 该第一源极 /漏极和该第二源极 /漏极分别电连接所述第 N条栅极线和第二 复位电压。
5 )在本发明的第 1 )项至第 4)项中的任一个优选实施方式中, 所述第一复位单元包 括一第一晶体管和一第二晶体管, 分别具有一栅极、 一第一源极 /漏极和一第二源极 Z漏 极, 所述第一晶体管和所述第二晶体管的樋极共同电连接并与所述第 N+1 条櫥极线连 接- 所述第一晶体管的第一源极 /漏极与所述储能单元的第一端电连接, 所述第二晶体管 的第一源极 /漏极与所述储能单元的第二端电连接; 所述第一晶体管和第二晶体管的第二 源极 /漏极共同电连接并与所述第一复位电压或第 复位电压电连接。
6)在本发明的第 1 )项至第 5 )项中的任一个优选实施方式中, 所述充电単元为一晶 体管, 其具有一栅极、 一第一源极 /漏极和一第二源极 /漏极, 所述充电单元的栅极和第 一源 /漏极电连接所述第 N- 1条櫥极线, 其第二源 /漏接电连接所述储能单元的第一端。
7)在本发明的第 1 )项至第 6)项中的任一个优选实施方式中, 所述驱动単元为一晶 体管, 其具有一栅极、 一第一源极 /漏极和一第二源极 /漏极, 所述驱动单元的第一源极 / 漏极电连接所述时钟输出线, 其栅极电连接储能单元的第一端, 其第二源极 Z漏极电连接 第 N条栅极线和所述储能单元的第二端。
8 ) 根据本发明的另一方面, 还提供了一种使用如上任一种栅极驱动电路的驱动方 法, 包括; 充电单元接收第 N-1 条極极线信号对储能单元进行预充电以得到一电压; 驱 动单元接收一时钟脉冲信号, 并根据所述电压及该时钟脉冲信号上拉所述第 N条極极线 的信号至一上拉电压: 第一复位单元接收第 N+1条栅极线的信号以及第一复位电压或第 — Ξ:复位电压, 并根据第 N+1 条栅极线的信号以及第一复位电压或第三复位电压而将所述 第 N条栅极线的信号复位至第一复位电压或第三复位电压; 第二复位单元接收第 N+3条 栅极线的信号以及第二复位电压, 并根据第 N+3条栅极线的信号以及第二复位电压而将 所述第 N条栅极线复位至第二复位电压。
9) 在本发明的第 8 ) 项的一个优选实施方式中, 在所述第 N级 G0A电路所连接的 栅极线为负极性时, 所述第一复位单元接收第一复位电压, 并根据第 N+1条檝极线的信 号以及第一复位电压而将所述第 N 条栅极线的信号复位至第一复位电压, 所述第一复位 电压与所述第二复位电压具有一负电压差。
10) 在本发明的第 8 ) 项或第 9) 项中的一个优选实施方式中, 在所述第 N级 G0A 电路所连接的極极线为正极性时, 所述第一复位单元接收第三复位电压, 并根据第 N+1 条 »极线的信号以及第三复位电压而将所述第 N条栅极线的信号复位至第三复位电压, 所述第:三复位电压与所述第二复位电压具有一正电压差。 与现有技术相比, 本发明的一个或多个实施 ^可以具有如下优点;
本发明提出了一种四阶驱动 GOA电路, 该电路通过两个复位信号, 对于负极性的極 极线, 将栅极输出信号拉低至复位信号 Vssl和复位信号 Vss2, 对于正极性的極极线, 将 栅极输出信号拉低至复位信号 Vss3 和复位信号 Vss2, 进而实现像素单元四阶驱动。 并 Ά, 该驱动电路能够有效地解决二阶驱动电路无法解决的馈通电压对像素电极的影响, 进而提高影像品质效果。
本发明的其它特征和优点将在随后的说明书中阐述, 并且, 部分地.从说明书中变得 显而易见, 或者通过实施本发明而了解。 本发明的目的和其他优点可通过在说明 ^、 权 利要求 ^以及^图中所特别指出的结构来实现和获得。 附图说明
^图用来提供对本发明的进一步理解, 并旦构成说明书的一部分, 与本发明的实施 例共同用于解释本发明, 并不构成对本发明的限制。 在跗图中:
图 i 是现有技术中二阶驱动的 GOA电路示意图;
图 2 是现有技术中二阶驱动 GOA电路输出的时序图;
图 3是根据本发明一实施例的四阶驱动的 GOA电路示意图- 图 4是根据本发明的四阶驱动的 GOA电路输出的^序图;
图 5是四阶驱动的栅极驱动的电压波形示意图;
图 6是四阶驱动的正极性显示电极的电压波形示意图;
图 7是四阶驱动的负极性显示电极的电压波形示意图。 具体实施方式
为使本发明的目的、 技术方案和优点更加清楚, 以下结合跗图对本发明作进一歩地 i羊细说明。
需要说明的是, 本实施例的驱动电路属干四阶驱动电路。 其可以在不变动公共电压 的情形下, 将馈通电压给补偿回来。 本实施例的四阶驱动电路是利用经由存储电容 ( 的 馈通电压, 来补偿经由寄生电容 Cgd所产生的馈通电压。
图 3是根据本发明一实施例的四阶驱动的 GOA电路示意图。 为方便描述, 仅绘制了 多级 GOA电路的一第 N级 GOA电路。 如图 3所示, 包括: 一储能单元 Cb, 一充电单元 31 , 电连接于一第 N-i条栅极线和储能单元 Cb之间, 其根据第 条栅极线信号对储能 单元 Cb进行预充电以得到一电压。 一驱动单元 32 , 电连接于一时钟输出线及一第 N条 栅极线, 其根据电压及一时钟脉 信号上拉第 Ν 条栅极线的信号至一上拉电压。 一第一 复位单元 33 , 电连接于储能单元 Cb和一第一复位电压 Vssl或第 Ξ:复位电压 Vss3之间 , 其根据第 N+1条栅极线的信号以及第一复位电压 Vssl或第 复位电压 Vss3而将第 N条 栅极线的信号复位至第一复位电压 Vssl或第≡复位电压 Vss3。 一第二复位单元 34, 电连 接干一第 N条櫥极线和一第二复位电压 Vss2之间 , 其根据第 N+3条栅极线的信号以及第 二复位电压 Vss2而将第 N条栅极线复位至第二复位电压 Vss2。
需要说明的是, 在第 N级 G0A电路所连接的栅极线为负极性时, 第一复位单元 33 根据第 N十】条櫥极线的信号以及第一复位电压 Vssl而将第 N条栅极线的信号复位至第 - - 复位电压 Vssl, 该第一复位电压 Vssl与第二复位电压 Vssl具有一负电压差(如后述图 5 所示 VeW) 。 而在第 N级 GOA电路所连接的栅极线为正极性时, 第一复位单元 33根据 第 N十 1条栅极线的信号以及第三复位电压 Vss3而将第 N条極极线的信号复位至第三复位 电压 Vss3, 该第三复位电压 Vss3与第二复位电压 Vss2具有一正电压差 (如后述图 5所 不 ei+)) 。 如图 3所示, 该 G0A电路实质为一 5T4C电路包括: 晶体管 TFT1 (作为驱动单元 32 ) 、 晶体管 TFT2和 TFT3 (共同构成第一复位单元 33 ) 、 晶体管 TFT4 (作为充电单 元 31 )和晶体管 TFT5 (作为第二复位单元 34 )这五个晶体管幵关以及一保持电容 Cb (作 为储能单元) 。 并旦, 还示意性地绘制出了 TFT1栅极和漏极之间的寄生电容 Cgd。
该电路的输入信号包括时钟信号(正极性或负极性时钟信号) Vck、 第 N-1行栅线的 输出 Output[N- 1]、 第 Ν·Η 行栅线的输出 Output[ +i ]、 第 N+3 行栅线的输出 0utput[N+3] > 第一复位信号 Vss】或第 复位信号 Vss3 , 以及第二复位信号 Vss2。
其中, 驱动晶体管 TFT1具有一栅极、 一第一源极 /漏极和一第二源极 /漏极, 其第一 源极 /漏极电连接时钟输出线 Vck, 其樋极电连接电容 Cb的第一端, 其第二源极 /漏极电 连接第 N条栅极线和电容 Cb的第二端。 主要用于控制櫥线高电位输出。
TFT2 、 TFT3和 TFT5为复位晶体管, 主要用于将栅线电位拉低, 同时将保持电容 Cb电荷释放, 使 TFT1处于关闭状态。
TFT2和 TFT3的栅极共同电连接并与第 N+1条櫥极线连接, TFT2的第一源极 /漏极 与电容 Cb的第一端电连接, TFT3的第一源极 /漏极与电容 Cb的第二端电连接, TFT2和 TFT3的第二源极 /漏极共同电连接并与第一复位电压 Vssi或第:三复位电压 Vss3电连接。 由于像素电压四阶驱动藉由正负极行栅极电位的不同变化而实现, 因此对于负极行输 出, TFT2将栅线输入复位到 Vssl电位, 对于正极行输出, TFT2将栅线输入复位到 Vss3 电位。
其中, TFT5将栅极输出复位到 Vss2电位, 其由输出信号 gate[N+3]迸行驱动。 TFT5 具有一樋极、 一第一源极 /漏极和一第二源极 /漏极, 该栅极电连接第 N+3 条栅极线, 该 第一源极 /漏极和该第二源极 /漏极分别电连接第 N条栅极线和第二复位电压 Vss2。
TFT4是输入(或预充电)晶体管, 主要作用是给保持电容 Cb预充, 将 TFT1打开。 其具有一栅极、 一第一源极 /漏极和一第二源极 /漏极, 櫥极和第一源 /漏极电连接第 N-1 条櫥极线, 其第二源 /漏接电连接电容 Cb的第一端。
具体的驱动 '序如图 4所示。 采用两个周期相同、 极性相反的时钟序列(Clk A, Clk B)。 它们分别被用在奇数行栅线上对应的 GOA电路以及偶数行栅线上对应的 GOA电路
以对应奇数行栅线 Gatel (负极性) 上的 GOA电路为倒, 说明如何实现四阶驱动。 首先, TFT4接收到上一栅线的驱动电压, 对保持电容 Cb进行预充, 将 TFT1打开。
TFT1输出極线高电位 Vgh。 TFT2和 TFT3接收下一栅线的驱动电压, 将極线电位拉 低, 同^将保持电容 Cb电荷释放, 使 TFTi处于关闭状态。
由于为奇行输出, TFT2 将栅线输入复位 (拉低) 到 Vssi 电位。 最后, TFT5 被第 N+3条栅线驱动, 以将栅极输出复位到 Vss2电位, 完成如图 4所示的 Gatei的驱动。 为了进一步了解本发明, 下面具体对时序波形进行说明。 图 5 为四阶驱动栅极驱动 电压的波形图。 从这个四阶驱动的波形图中可以看出, 在这个四阶驱动的櫥极驱动电压 波形之中, 正负两种极性的电压总共有 4 种: 打幵电压 Vgh、 压差为 Vg 的关闭电压 Vss2、 比关闭电压 Vss2高(存在压差 Ve W )的电压 Vss3以及比关闭电压 Vss2更低(存 在压差 Ve « ) 的电压 Vssl。 负责正极性与负极性的栅极驱动走线电压是不一样的, 如图 6 所示, 为正极性显示 电极的电压波形图。 其中, 61表示第 N- ί条樋极驱动电压, 62表示公共电压, 64表示 第 Ν条栅极驱动电压。
^图中我 —可以看出, 显示电极电压 63通过源极驱动充好电后, 会再经过三次的电 压变化(如图中虚线圈所示)。 首先是当前第 Ν条檝极驱动走线关闭时经由寄生电容 Cgd 的馈通电压 63】, 其次是由前一条 (第 N- 1 ) 栅极驱动走线电压拉回时经由存储电容 Cs 的馈通电压 632, 该电压是将显示电极电压 63推升到正极性电压范围的最重要的电压。 而最后, 剣是当前第 N条栅极驱动走线电压下拉时经 ffl寄生电容 Cgd所产生的馈通电压 633 , 这个电压由于是经由寄生电容 Cgd的关系, 而且变化的幅度也不大, 所以影响也比 较小。
如图 7所示, 其为负极性显示电极的电压波形图。 其中 71表示第 N-1条極极驱动电 压, 72表示公共电压, 74表示第 N条栅极驱动电压。
^图 7中可以看出, 显示电极电压 73通过源极驱动充好电后, 会再经过三次的电压 变化。 首先是当前第 N条栅极驱动走线电压关闭时经由寄生电容 Cgd所产生的馈通电压 731影响, 由于电压关闭的关系剣会把显示电极电压 73往下拉。 其次是上一条 (第 N- 1 ) 栅极驱动走线下拉时经过存储电容 Cs的馈通电压 732, 这个电压的影响很重要, 因为它 是将电压调整成负极性电压的主要成分, 必须能够将整体的电压调整到所需要的准位。 最后是当前第 N条栅极驱动走线电压拉回时经由寄生电容 Cgd的馈通电压 733的影响, 由于拉回电压的幅度比较小, 所以整体的影响也比较少。
因为受到经过寄生电容 Cgd的馈通电压影响, 若是要将正负极性的电压范围分幵的 话, 对于正极性的电压范围, 往上提升的电压会比较大, 而其往上提升的电压是 ώ上一 条栅极驱动走线电压往上拉经由存储电容 Cs的馈通电压来形成。 因为其所需的电压比较 大, 所以上一条栅极驱动走线在的拉回时电压也会比较大。 而对于负极性的显示电压范 围的形成, 也是利用上一条栅极驱动走线的电压变化来完成。 跟正极性的显示电极电压 不一样的是, 它需要的是下拉的馈通电压, 以便形成负的显示电极电压范 。 它所需要的 下拉电压跟正极性的上拉电压比较起来会比较小。 通过对栅极驱动走线的电压进行上述 的四阶驱动, 能够减少馈通电压像素电极的影响。
综上所述, 本发明提出了一种 5T1C的四阶驱动 GOA电路, 该电路通过两个复位信 号, 对奇数行分别将櫥极输出信号拉低至复位信号 Vssl和复位信号 Vss2 , 偶数行分别将 栅极输出信号拉低至复位信号 Vss3 和复位信号 Vss2 , 进而实现像素单元四阶驱动。 并 旦, 该驱动电路能够有效地解决二阶驱动电路无法解决的馈通电压对像素电极的影响, 进而提高影像品质效果。 以上所述, 仅为本发明较佳的具体实施方式, 但本发明的保护范 I并不局限于此, 任何熟悉该技术的人员在本发明所揭露的技术范围内, 可轻易想到的变化或替换, 都应 涵盖在本发明的保护范围之内。 因此, 本发明的保护范围应该以权利要求的保护范围为

Claims

权利要求书
1、 一种栅极驱动电路, 包括多级 G0A电路, 该多级 G0A电路的一第 N级 G0A电 路包括:
一储能单元- 一充电单元, 电连接于一第 N-i条櫥极线和所述储能单元之间, 其根据第 N- 1条檝 极线信号对所述储能单元迸行预充电以得到一电压;
一驱动单元, 电连接于一^钟输出线及一第 N条極极线, 其根据所述电压及一时钟 脉冲信号上拉所述第 N条栅极线的信号至一上拉电压;
一第一复位单元, 电连接于所述储能单元和一第一复位电压或第:三复位电压之间,其 根据第 N+】条栅极线的信号以及第一复位电压或第:三复位电压而将所述第 N条栅极线的 信号复位至第一复位电压或第三复位电压;
一第二复位单元, 电连接干一第 N条極极线和一第二复位电压之间, 其根据第 N+3 条櫥极线的信号以及第二复位电压而将所述第 N条栅极线复位至第二复位电压。
2、 根据权利要求 1所述的栅极驱动电路, 其中, 在所述第 N级 G0A电路所连接的 栅极线为负极性 , 所述第一复位单元根据第 N÷l条栅极线的信号以及第一复位电压而 将所述第 N条栅极线的信号复位至第一复位电压, 所述第一复位电压与所述第二复位电 压具有一负电压差。
3、 根据权利要求 1所述的栅极驱动电路, 其中, 在所述第 N级 G0A电路所连接的 栅极线为正极性^, 所述第一复位单元根据第 N+1条檝极线的信号以及第三复位电压而 将所述第 N条栅极线的信号复位至第三复位电压, 所述第三复位电压与所述第二复位电 压具有一正电压差。
4、 根据权利要求〗所述的栅极驱动电路, 其中,
所述第二复位单元为一晶体管,其具有一栅极、一第一源极 /漏极和一第二源极 /漏极, 该櫥极电连接所述第 N+3条栅极线,该第一源极 /漏极和该第二源极 /漏极分别电连接所述 第 N条栅极线和第二复位电压。
5、 根据权利要求 2所述的極极驱动电路, 其中,
所述第二复位单元为一晶体管,其具有一栅极、一第一源极 /漏极和一第二源极 /漏极, 该櫥极电连接所述第 N+3条栅极线,该第一源极 /漏极和该第二源极 /漏极分别电连接所述 第 N条栅极线和第二复位电压。
6、 根据权利要求 3所述的極极驱动电路, 其中,
所述第二复位单元为一晶体管,其具有一栅极、一第一源极 /漏极和一第二源极 /漏极, 该栅极电连接所述第^ 3条櫥极线,该第一源极 /漏极和该第二源极 /漏极分别电连接所述 第 N条栅极线和第二复位电压。
7、 根据权利要求 4所述的樋极驱动电路, 其中,
所述第一复位单元包括一第一晶体管和一第二晶体管,分别具有一栅极、 一第一源极 /漏极和一第二源极 /漏极,
所述第一晶体管和所述第二晶体管的栅极共同电连接并与所述第 N- l 条櫥极线连 接;
所述第一晶体管的第一源极 /漏极与所述储能单元的第一端电连接, 所述第二晶体管 的第一源极 /漏极与所述储能单元的第二端电连接;
所述第一晶体管和第二晶体管的第二源极 /漏极共同电连接并与所述第一复位电压或 第三复位电压电连接。
8、 根据权利要求 7所述的極极驱动电路, 其中, 所述充电単元为一晶体管, 其具有 一櫥极、 一第一源极 /漏极和一第二源极 /漏极,
所述充电单元的櫥极和第一源 /漏极电连接所述第 N-1条栅极线, 其第二源 /漏接电连 接所述储能单元的第一端。
9、 根据权利要求 8所述的樋极驱动电路, 其中, 所述驱动单元为一晶体管, 其具有 一櫥极、 一第一源极 /漏极和一第二源极 /漏极,
所述驱动单元的第一源极 /漏极电连接所述时钟输出线, 其栅极电连接储能单元的第 一端, 其第二源极/漏极电连接第 N条栅极线和所述储能单元的第二端。
10、 一种使用栅极驱动电路的驱动方法, 所述櫥极驱动电路包括多级 G0A电路, 该 多级 G0A电路的一第 N级 G0A电路包括:
一储能单元;
一充电单元, 电连接于一第 N-1条栅极线和所述储能单元之间, 其根据第 : 条極 极线信号对所述储能单元进行预充电以得到一电压;
一驱动单元, 电连接于一 ^钟输出线及一第 N条栅极线, 其根据所述电压及一时钟 脉冲信号上拉所述第 N条栅极线的信号至一上拉电压;
一第一复位单元, 电连接于所述储能単元和一第一复位电压或第三复位电压之间,其 根据第 N÷i条櫥极线的信号以及第一复位电压或第三复位电压而将所述第 N条栅极线的 信号复位至第一复位电压或第:三复位电压;
一第二复位单元, 电连接于一第 N条樋极线和一第二复位电压之间, 其根据第 N+3 条栅极线的信号以及第二复位电压而将所述第 N条栅极线复位至第二复位电压, 所述驱动方法包括:
充电单元接收第 N- 1条櫥极线信号对储能单元进行预充电以得到一电压; 驱动单元接收一时钟脉冲信号, 并根据所述电压及该时钟脉冲信号上拉所述第 N 条 栅极线的信号至一上拉电压;
第一复位单元接收第 N- l 条栅极线的信号以及第一复位电压或第 _三复位电压, 并根 据第 N- 条栅极线的信号以及第一复位电压或第 复位电压而将所述第 Ν条極极线的信 号复位至第一复位电压或第≡复位电压;
第二复位单元接收第 Ν÷3条栅极线的信号以及第二复位电压, 并根据第 Ν+3条栅极 线的信号以及第二复位电压而将所述第 Ν条栅极线复位至第二复位电压。
11、 根据权利要求 i0所述的驱动方法, 其中, 在所述第 N级 GOA电路所连接的極 极线为负极性时,
所述第一复位单元接收第一复位电压, 并根据第 N+1 条栅极线的信号以及第一复位 电压而将所述第 N条檝极线的信号复位至第一复位电压, 所述第一复位电压与所述第二 复位电压具有一负电压差。
12、 根据权利要求 10所述的驱动方法, 其中, 在所述第 N级 GOA电路所连接的栅 极线为正极性时,
所述第一复位单元接收第三复位电压, 并根据第 N+1条栅极线的信号以及第:三复位 电压而将所述第 N条樋极线的信号复位至第三复位电压, 所述第 复位电压与所述第二 复位电压具有 ·正电压差。
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