KR100483383B1 - Liquid crystal display device having stair waveform data driving voltage and its driving method - Google Patents

Abstract

Stepped waveform data driving voltages having a voltage level of two or more and whose staircase waveform voltage at the final point of time become a voltage level to be charged to the actual pixel electrode are applied to each pixel electrode on the liquid crystal panel. In the case of the two-step data driving voltage consisting of two step waveforms, the step waveform voltage at the front end is set higher than the step waveform voltage at the rear end, thereby reducing the time for charging the voltage at the rear end to the pixel electrode.

Description

Liquid crystal display having a step driving waveform data driving voltage and its driving method

The present invention relates to a liquid crystal display device, and more particularly, to a driving circuit of a thin film transistor-liquid crystal display (TFT-LCD).

A liquid crystal display device, which is a kind of flat panel display device, utilizes the characteristics of a liquid crystal whose light transmittance changes according to a voltage, and is widely used because it can be driven at a low voltage and power consumption is small.

A gate pulse that controls the application of a data signal having image information to each pixel electrode of the liquid crystal panel is applied to a gate electrode of a TFT connected to the pixel electrode through a gate line on the liquid crystal panel. To turn the TFT on or off. When the gate signal is applied, the TFT is turned on, and at this time, the data signal voltage applied to the pixel electrode is charged. Even after the application of the gate signal is terminated and the TFT is turned off, the data signal voltage charged in the pixel electrode is maintained. However, the parasitic capacitance between the gate electrode and the drain electrode of the TFT causes distortion of the data signal applied to the pixel electrode. The distorted voltage is called the kick-back voltage and is denoted by Vk. In order to reduce the influence of the kickback voltage, in a normal driving circuit, when the data signal is applied to the pixel electrode, the voltage of the data signal and the kickback voltage are applied to the pixel electrode.

Recently, as the liquid crystal display is applied to a system requiring a high resolution such as a workstation, the width of the gate signal is reduced. As the width of the gate signal decreases, the time for charging the data signal to the pixel electrode is reduced, so that a voltage lower than the data signal voltage applied to the pixel electrode may be charged to the pixel electrode. As such, if the data signal is not properly charged in the pixel electrode, image quality defects such as flicker may occur.

In order to improve the deterioration of the charging characteristic of the pixel according to the decrease in the gate signal width, there is a method of charging the pixel electrode for a short time by improving the mobility of the TFT controlled by the gate signal. In the driving circuit, there is a method of separately applying a data signal by dividing the liquid crystal panel into an upper side and a lower side. However, when the data signal is applied to the upper and lower layers of the panel separately, the width of the gate driving signal is doubled to increase the time for charging the data signal to the pixel electrode, but the data driving element must be located at both the upper and lower sides. There is a disadvantage that the number increases the manufacturing cost.

SUMMARY OF THE INVENTION The present invention has been made to solve this problem, and an object of the present invention is to improve the charging characteristics of the pixel electrode without increasing the burden on the driving device, thereby reducing kickback voltage and reducing image quality defects such as flicker.

In order to achieve this problem, in the present invention, a data driving voltage having a stepped wave shape is applied to each pixel electrode on the liquid crystal panel. The stepped waveform data driving voltage may have a voltage level of two or more, and the stepped waveform voltage of the final time point becomes a voltage level to be actually charged to the pixel electrode.

In the case of a two-step data driving voltage consisting of two stepped waveforms, the stepped waveform voltage at the front end causes the pixel electrode to be charged to the voltage at the rear end in a short time. That is, the voltage at the front end serves to reduce the time for charging the data driving voltage to the pixel electrode. In addition, the data driving voltage is applied as a step waveform only when it is higher than the voltage of the common electrode, and when it is lower than the voltage of the common electrode, it is applied as a single waveform. This is because the charging time of the pixel electrode is reduced by the shear voltage of the stepped waveform data driving voltage only when the data driving voltage is higher than the voltage of the common electrode.

Hereinafter, preferred embodiments of the present invention will be described. However, the following examples are only preferred embodiments of the present invention and the present invention is not limited to the following examples.

1 illustrates a driving circuit for a liquid crystal display according to an exemplary embodiment of the present invention. As shown in FIG. 1, a driving circuit for a liquid crystal display according to the present invention receives an image signal and a synchronization signal from an external source and generates a plurality of timing signals and a data signal applied to each pixel electrode on the liquid crystal panel 10. The controller 20 receives power from an external system, generates a plurality of analog voltages, receives a timing signal and a data signal from the timing controller 20, and receives an analog voltage from the power supply 30. Receives an analog voltage from a timing signal and a power supply 30 from a data driving device 40 and a timing controller 20 that apply data driving voltages having two or more stepped waveforms to respective pixel electrodes on the liquid crystal panel 10. The gate driving device 50 generates a gate driving voltage to control the application of the data driving signal to each pixel electrode. do.

2 illustrates a relationship between a data driving voltage and a gate driving voltage generated in a conventional driving circuit, and FIG. 3 illustrates a relationship between a data driving voltage Vd and a gate driving voltage Vg according to an exemplary embodiment of the present invention. It was. The voltage of the common electrode opposite to the pixel electrode is represented by Vcom.

2 and 3, the conventional data driving voltage has a single level, but the data driving voltage according to the present invention has a stepped wave shape. Such a step waveform may have two or more voltage levels, and the level of the step voltage of the last point in time becomes a voltage level to be applied to the actual pixel electrode. 3 illustrates a data driving voltage having two voltage levels Vdh and Vdl. In the step waveform data driving voltage having two voltage levels, the voltage Vdl of the rear stage is a voltage to be actually charged to the pixel electrode. The voltage Vdh at the front side causes the pixel electrode to be charged to the voltage at the rear end within a short time. That is, the voltage at the front end serves to reduce the time for which the data driving voltage is charged to the pixel electrode. In the stepped waveform data driving voltage, the voltage at the rear end should have a width of at least 5 kHz so that the voltage charged in the pixel electrode is equal to the actual data signal voltage.

In addition, the step waveform data driving voltage is applied as a step waveform only when the data driving voltage to be actually applied is higher than the voltage of the common electrode, and is applied as a single waveform when it is lower than the voltage of the common electrode. This is because the kickback voltage acts in the direction of bringing down the potential of the pixel electrode regardless of the polarity of the data driving voltage with respect to the common electrode voltage. Therefore, the charging time of the pixel electrode is reduced only when the data driving voltage is higher than the voltage of the common electrode. Because there is.

FIG. 4 is a waveform diagram illustrating characteristics of a pixel voltage Vp charged in a pixel electrode over time when a data driving voltage having a waveform as shown in FIG. 2 is applied to a workstation-class liquid crystal panel. Fig. 3 shows waveform diagrams of pixel voltages when the data driving voltage having the waveform shown in Fig. 3 is applied. At this time, the gate driving voltage and the data driving voltage were both 15 kW.

As shown in FIGS. 4 and 5, the time when the data driving voltage is completely charged in the pixel electrode and the pixel voltage has the same level as the data driving voltage is shorter than that of the single waveform. Also, the kickback voltage is 0.8V for a single waveform, but decreases to 0.6V for a stepped waveform, and the maximum deviation of the kickback voltage on the liquid crystal panel is 0.5V for a single waveform, but to 0.14 for a stepped waveform. This reduction in variation reduces flicker on the screen.

Next, a driving method of the liquid crystal display according to the exemplary embodiment of the present invention will be described. First, an image signal input from the outside is processed to generate a data signal and a timing signal having image information, and a gray voltage and a gate voltage to be applied to the liquid crystal panel. The data driving voltage of the staircase waveform is made from the data signal, the gray voltage and the timing signal, and the gate driving signal of the square wave is made from the timing signal and the gate voltage. The data driving signal is applied to the source electrode of the thin film transistor connected to each pixel electrode on the liquid crystal panel 10, and the gate driving signal is applied to the gate electrode of the thin film transistor so that the data driving voltage is charged to the pixel electrode so as to be imaged on the liquid crystal panel. Should be displayed.

As described above, in the liquid crystal display according to the present invention, the data driving voltage becomes a stepped waveform, thereby reducing the time for charging the voltage to the pixel electrode. Therefore, the flicker defect and the like can be eliminated without increasing the data driving element, thereby improving the display quality of the liquid crystal panel.

Although this invention has been described with reference to the most practical and preferred embodiments, the invention is not limited to the embodiments disclosed above, but also includes various modifications and equivalents which fall within the scope of the following claims.

1 is a block diagram illustrating a driving circuit for a liquid crystal display according to an exemplary embodiment of the present invention.

2 is a waveform diagram showing a relationship between a data driving voltage and a gate driving voltage of a conventional driving circuit for a liquid crystal display device;

3 is a waveform diagram illustrating a relationship between a data driving voltage and a gate driving voltage of a driving circuit for a liquid crystal display according to an exemplary embodiment of the present invention;

FIG. 4 is a waveform diagram illustrating a relationship with a pixel voltage when a data driving voltage having a waveform as shown in FIG. 2 is applied to the pixel electrode.

FIG. 5 is a waveform diagram illustrating a relationship with a pixel voltage when a data driving voltage having a waveform as shown in FIG. 3 is applied to the pixel electrode.

Claims (12)

Processing the image signal input from the outside to generate a data signal and a timing signal having the image information; Creating a gray voltage and a gate voltage to be applied to the liquid crystal panel; Generating a data driving voltage having a stepped waveform using the data signal, the gray voltage, and the timing signal; Generating a gate driving signal of a square wave using the timing signal and a gate voltage; Applying the data driving voltage to a source electrode of a thin film transistor connected to each pixel; Applying the gate driving signal to a gate electrode of the thin film transistor so that the data driving voltage is charged to the pixel electrode; Driving method of liquid crystal display device. In claim 1, The data driving voltage becomes a stepped waveform only when it is higher than the common electrode voltage opposite to the pixel electrode. Driving method of liquid crystal display device. In claim 1, The voltage level of the stepped waveform at the last time point among the plurality of stepped waveforms forming the data driving voltage is a voltage level that the pixel should display. Driving method of liquid crystal display device. In claim 3, The plurality of step waveforms forming the data driving voltage are made into a two-step waveform having two voltage levels. Driving method of liquid crystal display device. In claim 4, The data driving voltage of the two-step waveform is To make the preceding step waveform voltage level higher than the later step waveform voltage level. Driving method of liquid crystal display device. In claim 5, The data driving voltage of the two-step waveform is To make the width of the staircase waveform at the rear end more than 5 ㎲ Driving method of liquid crystal display device. Liquid crystal panel to display an image, A timing controller which receives an image signal and a synchronization signal from an external source and generates a plurality of timing signals and a data signal applied to each pixel electrode on the liquid crystal panel; Power supply for generating a plurality of analog voltages by receiving power from the outside, A gate driving element which receives a timing signal from the timing controller and an analog voltage from the power supply and controls the data signal to be applied to each pixel electrode; And a data driving device configured to receive a timing signal and a data signal from the timing controller, and to receive an analog voltage from the power supply and to apply a data driving voltage having two or more stepped waveforms to each of the pixel electrodes. Liquid crystal display. In claim 7, The data driving voltage becomes a stepped waveform only when it is higher than the common electrode voltage opposite to the pixel electrode. Liquid crystal display. In claim 7, Among the plurality of step waveforms forming the data driving voltage, the voltage level of the step waveform at the last time becomes the voltage level that the pixel should display. Liquid crystal display. In claim 9, The plurality of step waveforms forming the data driving voltage are two-step waveforms having two voltage levels. Liquid crystal display. In claim 10, The two-stage waveform data driving voltage is The stepped waveform voltage level at the front end is higher than the stepped waveform voltage level at the rear end. Liquid crystal display. In claim 11, The two step waveform data driving voltages are The width of the staircase waveform at the rear end is 5 ㎲ or more Liquid crystal display.

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