KR20070076198A - Liquid crystal display and driving method thereof - Google Patents

Abstract

An LCD(Liquid Crystal Display) device and a driving method thereof are provided to reduce power consumption of the LCD device by preventing a source voltage from being supplied to a first gamma generator in an 8-color mode. A liquid crystal display device includes a power source(20), a first gamma voltage generator(30), and a second gamma voltage generator(40). The power source generates various power signals and supplies the power signals to the LCD. The first gamma voltage generator generates a full-color gamma voltage by using the power signal from the power source, in a full-color mode. The second gamma voltage generator outputs one of the power signals from the power source according to polarity of the data in an 8-color mode.

Description

Liquid crystal display and its driving method {LIQUID CRYSTAL DISPLAY AND DRIVING METHOD THEREOF}

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

2A and 2B are diagrams illustrating gamma voltages of the white gray and the black gray respectively output to the second gamma voltage generator illustrated in FIG. 1.

<Brief Description of Drawings>

10: timing controller 20: power supply

30: first gamma voltage generator 40: second gamma voltage generator

50: data driving circuit 60: gate driving circuit

70: liquid crystal panel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device, and more particularly, to a liquid crystal display device and a driving method thereof in which an afterimage of the liquid crystal display device is prevented.

In general, a liquid crystal display (LCD) is composed of a plurality of liquid crystal cells arranged in a matrix form and switching elements for applying an image signal to the liquid crystal cells so as to transmit the amount of light supplied from the backlight unit. Adjust to display the image.

Conventional liquid crystal display devices include a video card for converting analog data into digital image data, a data driver circuit for supplying image data to data lines of the liquid crystal panel, and a gamma voltage generator for supplying gamma voltage to the data driver circuit. And a gate driver circuit for sequentially driving the gate lines of the liquid crystal panel, a timing controller for controlling the data driver circuit and the gate driver circuit, a voltage for driving the gate driver circuit, the data driver circuit, the timing controller, and the like. A power supply unit to generate is provided.

The video card converts an analog input video signal into a digital image data signal suitable for a liquid crystal panel and supplies it to a timing controller.

The timing controller supplies red, green, and blue digital image data and control signals from the video card to the gamma voltage generator and the data driving circuit. A control signal for driving the gate driving circuit is generated and supplied to the gate driving circuit.

The gate driving circuit sequentially generates scan pulses in response to a control signal input from the timing controller and sequentially supplies the gate pulses to the gate lines.

The data driving circuit receives an image data signal and a control signal input from a timing controller and a gamma voltage input from a gamma voltage generator, converts the digital image data signal into an analog image signal, and supplies the digital image data signal to a data line.

The gamma voltage generator individually generates a plurality of analog voltages from a gamma array in which a plurality of resistors are connected in series. For example, when 0 V is applied to one end of the gamma array and 5 V is applied to the other end, voltages of 0 V and 5 V are divided by a plurality of resistors from the gamma array of the gamma generator, and thus, a plurality of gammas having different voltage levels. Voltages are output.

The image displayed on the liquid crystal display device is a full-color mode in which 64 luminance is selected for red, green, and blue, and an 8-color mode in which two luminance is selected for red, green, and blue, respectively. It is divided into cases. However, the conventional liquid crystal display device has a problem in that power consumption is large as the gamma voltage generators are driven without distinguishing between displaying an image in a full-color mode and displaying an image in an 8-color mode. In order to solve this problem, when displaying an image in 8-color mode, the highest and lowest voltages are used to display white and black in the 8-color mode. However, in this case, since the high and low voltage levels of the white and black are the same, the difference between the kickback voltages of the white and the black may not be expressed, and thus, an afterimage or an afterimage occurs in the LCD.

Accordingly, it is an object of the present invention to provide a liquid crystal display device and a driving method thereof which reduce power consumption in the 8-color mode and compensate for voltage differences between white and black to prevent afterimages.

In order to achieve the above object, the present invention provides a power supply unit for generating and supplying a plurality of power signals, and generating a first gamma voltage using the power signal supplied from the power supply unit in full-color mode to generate a full color gamma voltage. And a second gamma voltage generator for outputting any one of the power signals according to the polarity of data among the power signals from the power supply unit in the 8-color mode.

Here, when the second gamma voltage generator is driven, the power signal supplied to the first gamma voltage generator is cut off, and the first gamma voltage generator is turned off.

The second gamma voltage generator generates white gamma voltages using the first and second power signals supplied from the power supply unit, and uses the third and fourth power signals supplied from the power supply unit to generate black gray levels. Generate gamma voltage.

In this case, the first power signal has a higher voltage level than the third power signal, and the second power signal is a voltage having a lower voltage level than the fourth power signal.

The first power signal is a gamma reference voltage supplied to the first gamma voltage generator, the second power signal is a low common voltage supplied to the liquid crystal panel, and the third power signal is supplied to the data driving circuit. The intermediate driving signal is supplied, and the fourth power signal is the gate driving voltage.

The timing controller may further include a timing controller including a register storing address data for distinguishing between the full-color mode and the 8-color mode, wherein the register is output from the second gamma voltage generator in the 8-color mode. The positive and negative data values of the white gray level and the positive and negative data values of the black gray level are stored so as to correspond to the first to fourth power signals.

In order to achieve the above object, the driving method of the liquid crystal display according to the present invention includes generating a plurality of power signals in a power supply unit, and generating a first gamma voltage in the full-color mode using any one of the power signals. Generating a gamma voltage having a full-color gradation in a negative part, and selecting and outputting one power signal according to a polarity of data among the plurality of power signals in a second gamma voltage generator in an 8-color mode; It includes.

In this case, a power signal supplied to the first gamma voltage generator is cut off in the 8-color mode to turn off the first gamma voltage generator.

The second gamma voltage generator generates a gamma voltage of white gray using the first and second power signals supplied from the power supply unit, and generates a black gray using the third and fourth power signals supplied from the power supply unit. Generating a gamma voltage of.

The second gamma voltage generator may output a second gamma by outputting a positive and negative data value of a white gray level and a positive and negative data value of a black gray level corresponding to the first to fourth power signals stored in a register. The method may further include driving the voltage generator.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram illustrating a liquid crystal display according to an exemplary embodiment of the present invention, and FIGS. 2A and 2B are diagrams illustrating white and black gray levels output to a second gamma voltage generator shown in FIG. 1. It is a figure which shows gamma voltage, respectively.

1 to 2B, the liquid crystal display according to the present invention uses a power supply unit 20 for generating and supplying a plurality of power signals and a full color using the power signal supplied from the power supply unit in full-color mode. A first gamma voltage generator 30 generating a gamma voltage, and a second gamma selecting and outputting one of the power signals according to the polarity of data among the power signals from the power supply unit 20 in the 8-color mode. The voltage generator 40 is provided.

Specifically, the power supply unit 20 includes a plurality of power signals, for example, a data power signal AVDD supplied to the data driving circuit 50 and an intermediate driving signal VCI supplied to the data driving circuit 50. Gate on voltage / gate off voltage (Von / Voff) and gate power signal (VSS) supplied to the gate driving circuit 60, and common voltage (high common voltage / low common common) applied to the common electrode of the liquid crystal panel 70 The voltage Vcomh / Vcoml and the gamma reference voltage GVDD supplied to the first gamma voltage generator 30 are generated and supplied to each.

The first and gamma voltage generators 30 have a gamma array circuit consisting of a plurality of series connected resistors and a line branched between each resistor. In addition, a gamma reference voltage (GVDD) supplied from the power supply unit 20 is supplied to one end of the gamma array circuit, and the other end supplies a ground voltage to selectively output the divided voltages through a branched line to provide full-color. Generate gamma voltage. That is, in the full-color mode, the gamma reference voltage GVDD is supplied to the gamma array circuit included in the first and gamma voltage generators 30 to generate a gamma voltage indicating full-color gray scale. The full-color gamma voltage generated by the first and gamma voltage generators 30 is supplied to the data driving circuit 50.

The second and gamma voltage generators 40 selectively output the power signals supplied from the power supply unit 20 according to the polarity of the data. At this time, the power supply unit 20 is supplied with the first to fourth power signals. The first power signal is a gamma reference voltage GVDD supplied to the first and gamma voltage generators 30, the second power signal is a low common voltage Vcoml supplied to the liquid crystal panel, and the third power signal is data. The intermediate driving signal VCI is supplied to the driving circuit 50, and the fourth power supply signal is the gate power signal VSS supplied to the gate driving circuit 60. As shown in FIG. 2A, the first power signal and the second power signal are alternately output as white gamma voltages, and as shown in FIG. 2B, the third power signal and the fourth power signal are alternately altered to black gamma voltages. Is output. Here, the first power signal is greater than the voltage level of the third power signal and the second power signal is smaller than the voltage level of the fourth power signal. Accordingly, when the gray level from white to black or black to white is changed, the charged voltage is rapidly discharged due to the kickback voltage so that afterimages do not appear in the display area. That is, the effective time between the black gamma voltage and the common voltage is reduced, and the discharge time is reduced when the screen is changed to white so that the afterimage does not appear on the screen.

On the other hand, the liquid crystal display according to the present invention further includes a timing controller 10 having a register for storing information about each mode to distinguish between the full-color mode and the 8-color mode.

Specifically, the timing controller 10 receives R, G, and B image data signals, a vertical synchronization signal as a frame discrimination signal, a horizontal synchronization signal as a horizontal discrimination signal, and a main clock signal applied from an external graphic controller. A control signal for driving the gate driving circuit 60 and the data driving circuit 50 is output. Then, the image data signals are output to the first and second gamma voltage generators 30 and 40. The timing controller 10 stores the positive and negative data values for the white gray level and the positive and negative data values for the black gray level in the 8-color mode at the first address of the register to generate the second and gamma voltage generators. The power signals supplied to the 40 may be set. That is, the positive and negative data for the white grayscale are stored in correspondence with the data for the first and second power signals, and the positive and negative data for the black grayscale are data for the third and fourth power signals. And then save it. And outputs power signals corresponding to data values stored in a register of the timing controller to the second and gamma voltage generators 40 in the eight-color mode, and the first and the second gamma voltage generators 40, respectively. The gamma voltage of the white gray level is alternately outputted by alternating the power signals, and the gamma voltage of the black gray level is outputted by alternating the third and fourth power signals. At this time, a signal distinguishing the full-color mode and the 8-color mode may be inserted into the first address stored in the register. This is a full-color mode when the value '1' or '0' is entered in the first bit of the first address and '1' is stored in the first bit, for example. 8 when '0' is stored. Can indicate color mode. On the contrary, if '1' is stored, it may represent an 8-color mode and if '0' is stored, it may represent a full-color mode.

The liquid crystal display device including the first and second gamma voltage generators 30 and 40 and the timing controller 10 supplies a driving voltage to the liquid crystal panel 70 displaying an image and the liquid crystal panel 70. And a gate driving circuit 60 and a data driving circuit 50.

Specifically, the gate driving circuit 60 controls the gate on voltage Von through a gate on voltage and gate off voltage Von / Voff signal applied from the power supply unit 20 and a control signal applied from the timing controller 10. The scan signal is sequentially supplied to the gate line formed on the liquid crystal panel 70. In addition, the gate driving circuit 60 supplies the gate-off voltage Voff to the gate line in a period other than the period in which the gate-on voltage Von is supplied.

The data driver circuit 50 is output from the gate driver circuit 60 through a gamma voltage selectively applied by the first and second gamma voltage generators 30 and 40 and a control signal input from the timing controller 10. The analog image data signal is output to a data line formed in the liquid crystal panel 70 for one period according to the gate-on voltage Von. At this time, in the full-color mode, the full-color image data signal is supplied to the data line of the liquid crystal panel 70 using the gamma voltages supplied from the first and gamma voltage generators 30, and 8-color. In the mode, the 8-color analog image data signal is supplied to the data line of the liquid crystal panel 70 by using the gamma voltage input from the second and gamma voltage generator 40.

As such, in the 8-color mode of the liquid crystal display, the second gamma voltage generator includes a second gamma voltage generator to generate gamma voltages of white and black grays and supplies them to the data driving circuit using a plurality of power signals supplied from the power supply. Since the first gamma voltage generator does not need to be driven, power consumption is reduced and white and black gamma voltages are appropriately supplied to prevent afterimages caused by kickback voltages.

According to an exemplary embodiment of the present invention, a method of driving a liquid crystal display includes generating a plurality of power signals in a power supply unit, and gamma of a full-color gray level in a first gamma voltage generator in a full-color mode using any one of the power signals. Generating a voltage, and selecting and outputting one of the plurality of power signals according to the polarity of the data among the plurality of power signals in the second gamma voltage generator in 8-color mode. In the eight-color mode, the first gamma voltage is not driven by cutting off the power supplied to the first gamma voltage generator.

When a positive data signal is input to the second gamma voltage generator, a gamma reference voltage GVDD input from the power supply unit is output to generate a gamma voltage of white gray, and when a negative data signal is input, a low common Output the voltage Vcoml. The intermediate driving signal VCI of the data driving circuit input from the power supply unit is output to generate the gamma voltage of the black gray level, and when the negative data signal is input, the gate power signal VSS is output.

Here, in order to drive the first and second gamma voltage generators by dividing the full-color mode and the eight-color mode, respectively, the register of the timing controller distinguishes the full-color mode and the eight-color mode from the first bit of the first address. Stores bits and outputs data for each mode. In the 8-color mode, data of each power signal is matched and stored to output power signals having different voltage levels.

In the liquid crystal display and the driving method thereof according to the present invention, since the gamma voltage is supplied from the second gamma voltage generator to the data driver in 8-color mode, power consumption is not supplied to the first gamma voltage generator, thereby reducing power consumption. have.

In addition, in the 8-color mode, the display of the white gray level is alternately supplied with the gamma reference voltage GVDD and the low common voltage Vcoml, and the black gray level is displayed as the intermediate driving signal VCI and the gate power signal of the data driving circuit. VSS) is supplied alternately. As a result, afterimages of white and black grays can be prevented.

The present invention described above will be capable of various substitutions, modifications and changes by those skilled in the art to which the present invention pertains. Therefore, the present invention should not be limited to the above-described embodiments and the accompanying drawings, and the rights thereof should be determined by the claims.

Claims (11)

A power supply unit generating and supplying a plurality of power signals; A first gamma voltage generator configured to generate a full color gamma voltage using a power signal supplied from the power supply unit in a full color mode; And a second gamma voltage generator configured to output one of the power signals according to the polarity of the data among the power signals from the power supply unit in the 8-color mode. The method of claim 1, And when the second gamma voltage generator is driven, a power signal supplied to the first gamma voltage generator is cut off so that the first gamma voltage generator is turned off. The method of claim 1, The second gamma voltage generator generates a gamma voltage of white gray using the first and second power signals supplied from the power supply unit, and uses a gamma of black gray using the third and fourth power signals supplied from the power supply unit. And a voltage generating device. The method of claim 3, wherein And the first power signal has a higher voltage level than the third power signal, and the second power signal has a lower voltage level than the fourth power signal. The method of claim 3, wherein The first power signal is a gamma reference voltage supplied to the first gamma voltage generator, the second power signal is a low common voltage supplied to the liquid crystal panel, and the third power signal is supplied to the data driving circuit. And a fourth power signal is a gate power signal supplied to the gate driving circuit. The method of claim 3, wherein And a timing controller including a register storing address data for distinguishing between the full-color mode and the eight-color mode. The method of claim 6, In the 8-color mode, the timing controller is configured to correspond to the first to fourth power signals output from the second gamma voltage generator, and the positive and negative data values of the white gray and the positive and negative polarities of the black gray. And a data value is stored. Generating a plurality of power signals in the power supply unit; Generating a gamma voltage of a full color gray level by the first gamma voltage generator in the full-color mode using any one of the power signals; And selecting and outputting one of the plurality of power signals according to the polarity of the data from the plurality of power signals in the second gamma voltage generator in 8-color mode. The method of claim 8, And turning off the first gamma voltage generator by cutting off a power signal supplied to the first gamma voltage generator in the eight-color mode. The method of claim 8, The second gamma voltage generator generates a gamma voltage of white gray using the first and second power signals supplied from the power supply unit, and uses a gamma of black gray using the third and fourth power signals supplied from the power supply unit. A method of driving a liquid crystal display device further comprising generating a voltage. The method of claim 10, The second gamma voltage generator generates a second gamma voltage by outputting the positive and negative data values of the white gray level and the positive and negative data values of the black gray level corresponding to the first to fourth power signals stored in the register. The driving method of the liquid crystal display device further comprising the step of driving.

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