KR101584998B1 - Driving circuit for liquid crystal display device and method for driving the same - Google Patents

Abstract

The present invention relates to a driving apparatus for a liquid crystal display device and a driving method thereof, which can reduce power consumption for driving a liquid crystal panel while preventing an image quality failure due to a difference in charged amount of a video signal in a liquid crystal panel in which the number of data lines is halved A liquid crystal panel having a pixel matrix of a structure in which the number of data lines is halved; A data driver for charging a video signal to each data line of the liquid crystal panel and charging the video signal by reducing the amount of charging during a strong charging period by a charging amount of a video signal distorted during a charging period; And supplies data to the data driver in such a way that the data driver supplies the image data to the data driver in such a manner that the charged amount of the image signal is reduced in the strong charging period by the charged amount of the video signal, And a timing controller for controlling the data driver.

A dot inversion driving method, a polarity control signal, a selection enable signal,

Description

TECHNICAL FIELD [0001] The present invention relates to a driving apparatus for a liquid crystal display device and a driving method thereof. BACKGROUND OF THE INVENTION [0002]

The present invention relates to a liquid crystal display device and, more particularly, to a liquid crystal display device capable of reducing a consumption power for driving a liquid crystal panel while preventing an image quality failure due to a difference in the charged amount of a video signal in a liquid crystal panel, To a driving apparatus and a driving method thereof.

A liquid crystal display device displays an image using electrical and optical characteristics of a liquid crystal. Liquid crystals have different anisotropic properties depending on the molecular long axis direction and short axis direction of refractive index and dielectric constant, and can easily control the molecular arrangement and optical properties. A liquid crystal display device using the same displays an image by changing the alignment direction of liquid crystal molecules according to the electric field size and adjusting the light transmittance transmitted through the polarizing plate.

A liquid crystal display includes a liquid crystal panel in which a plurality of pixels are arranged in a matrix form, a gate driver for driving gate lines of the liquid crystal panel, and a data driver for driving data lines of the liquid crystal panel.

Each pixel of the liquid crystal panel implements a desired color by a combination of red, green, and blue sub-pixels that adjust the light transmittance according to a data signal. Each sub-pixel includes a thin film transistor connected to the gate line and the data line, and a liquid crystal capacitor connected to the thin film transistor. The liquid crystal capacitor charges the difference voltage between the data signal supplied to the pixel electrode through the thin film transistor and the common voltage supplied to the common electrode, and drives the liquid crystal according to the charged voltage to adjust the light transmittance.

The gate driver includes a plurality of gate integrated circuits (ICs) sequentially driving gate lines of the liquid crystal panel.

The data driver includes a plurality of data ICs for converting a digital data signal into an analog video signal and supplying the analog video signal to the data lines of the liquid crystal panel each time each of the gate lines is driven.

The data IC includes a complicated circuit configuration such as a digital-to-analog converter (DAC) and the like, so that the manufacturing cost is high, and the number of data lines of the liquid crystal panel is larger than the gate line, so more data ICs than the gate ICs are required. Accordingly, a method of reducing the number of data ICs while maintaining the resolution of the liquid crystal panel in order to reduce the manufacturing cost of the liquid crystal display device has been considered.

For example, in order to reduce the number of data ICs, a liquid crystal panel in which the number of data lines is halved by using a structure in which each of the odd-numbered and even-numbered subpixels located on both sides of one data line is sequentially driven by the one data line It was proposed.

However, when a version method with dots such as 2 dots or 4 dots is applied to a liquid crystal panel in which the number of data lines is halved, the sub pixels having a polarity that is the same as the polarity of the previous horizontal period, Pixels to be charged may be divided into horizontal lines or vertical lines. In this case, there is a problem in that data charging amount difference with respect to the same gradation is generated between the strongly charged pixel line and the approximately charged pixel line, and image quality defects such as horizontal line or vertical line unevenness and flicker occur.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems and it is an object of the present invention to provide a liquid crystal display device capable of reducing a consumed power for driving a liquid crystal panel while preventing a picture quality defect due to a difference in charged- An object of the present invention is to provide a driving apparatus for a device and a driving method thereof.

According to an aspect of the present invention, there is provided a driving apparatus for a liquid crystal display, including: a liquid crystal panel having a pixel matrix having a structure in which the number of data lines is halved; A data driver for charging a video signal to each data line of the liquid crystal panel and charging the video signal by reducing the amount of charging during a strong charging period by a charging amount of a video signal distorted during a charging period; And supplies data to the data driver in such a manner that the data driver supplies the image data to the data driver in such a manner that the charged amount of the image signal is reduced in the strong charging period by the charged amount of the video signal distorted in the weak charging period, And a timing controller for controlling the data driver.

The data driver includes: a shift register for outputting a sampling signal in response to a source start pulse and a source shift clock from the timing controller; a sampling register for sequentially sampling the image data according to the sampling signal, A latch unit for simultaneously outputting data of a line in response to a polarity control signal and a selection enable signal from the timing controller, and outputting a voltage level of the gamma voltages as a whole, A gamma voltage generating unit for converting one line of data from the latch unit into analog video signals by using gamma voltages supplied with varying voltage levels in the approximate charging period and the strong charging period unit, Analog converter, and the digital-analog converter Characterized in that one amplifies the video signal from the conversion unit having an output buffer to be supplied to each data line of the liquid crystal panel.

Wherein the gamma voltage generator comprises a voltage divider circuit for generating positive and negative gamma voltages using a plurality of reference gamma voltages and first and second driving voltage sources in a voltage division mode between a plurality of resistors connected in series, And the first driving voltage may be supplied to one end of the voltage divider circuit as it is, or the first driving voltage may be supplied to one end of the voltage divider circuit in accordance with the selection enable signal, A first switching unit which is provided between the other end of the voltage dividing circuit and the second driving voltage source and supplies the second driving voltage to the other end of the voltage dividing circuit in accordance with the selection enable signal, Or the second driving voltage is lowered by the amount of charge that the image signal is distorted and becomes smaller in the approximate charging period, Article characterized in that it includes second switching unit for.

Wherein the first switching unit supplies the first driving voltage directly to the voltage divider circuit in response to the selection enable signal or the first driving voltage that is reduced by the charging amount distorted by the at least one first step- Wherein the second switching unit supplies the second driving voltage directly to the voltage dividing circuit in response to the selection enable signal or the second switching unit supplies the second driving voltage to the voltage dividing circuit by the at least one second step- And a switching element for supplying a second driving voltage that is lowered by a charged amount that is distorted when the battery is charged, to the voltage divider circuit.

Wherein the timing controller generates a first logic state select enable signal so that the first and second switching units can supply the first and second driving voltages as they are to the voltage dividing circuit in the approximate charging period, And the first and second switching units supply the first and second driving voltages to the voltage dividing circuit so that the first and second driving voltages can be supplied to the voltage dividing circuit by a charging amount of the video signal distorted by the phantom, 2 logic select enable signal and supplies the select enable signal to the first and second switching units, respectively.

According to another aspect of the present invention, there is provided a method of driving a liquid crystal display device including a liquid crystal panel, a data driver, a gate driver, and a timing controller having a pixel matrix of a half number of data lines A method of driving a liquid crystal display device, comprising: charging a video signal to data lines of the liquid crystal panel; Charging the video signal by reducing the charged amount during a strong charging period by a charging amount that is distorted in a period during which the video signal is approximately charged using the data driver; And controlling the data driver to generate a data control signal so as to reduce the charged amount in the strong charging period by a charged amount of the image signal distorted in the weak charging period.

Wherein the step of charging and reducing the charged amount in the strong charging period by a charging amount of the video signal distorted in the weak charging period includes the steps of outputting a sampling signal in response to the source start pulse and the source shift clock from the timing controller, Sequentially sampling the image data according to the sampling signal and simultaneously outputting one line of sampled data according to a source output enable signal, and outputting the sampled data in response to a polarity control signal and a selection enable signal in the data control signal Generating and outputting a voltage level of the gamma voltages as a whole by varying the voltage level of the gamma voltages in units of the approximate charging period and the strong charging period, Converts the data of the line into the analog video signal, And the step of amplifying the video signal characterized by including the step of supplying to the respective data lines of the liquid crystal panel.

The step of generating the variable voltage level of the gamma voltages as a whole may include generating a gamma voltage having a positive polarity and a negative polarity by using a plurality of reference gamma voltages and first and second driving voltage sources in a divided mode among a plurality of resistors connected in series, Wherein the first driving voltage is supplied to one end of the voltage dividing circuit having the divided voltage mode as it is, or the first driving voltage is supplied to one end of the voltage dividing circuit having the divided voltage mode in accordance with the selection enable signal, And supplying the second driving voltage to the other end of the voltage divider circuit as it is or supplying the second driving voltage to the other terminal of the voltage divider circuit as the charged voltage And a step of supplying the pressurized water.

Wherein the step of supplying the first driving voltage by stepping down and supplying the first driving voltage by a charging amount that is reduced by the amount of distortion of the video signal during the approximate charging period includes supplying the first driving voltage to the first driving voltage source by using at least one first step- Wherein the step of supplying the second driving voltage to the voltage dividing circuit by reducing the driving voltage by a charging amount distorted during the approximate charging and supplying the second driving voltage by reducing the charging amount by the amount of charging the video signal is reduced in the approximate charging period, And the second driving voltage is supplied to the voltage dividing circuit by reducing the second driving voltage by a charging amount that is distorted during the approximate charging using at least one second step-down resistor and a switching element connected in series to the driving voltage source.

Wherein the step of generating the data control signal so as to reduce the charged amount in the strong charging period by the charged amount of the video signal distorted in the weak charging period comprises the step of changing the first and second driving voltages And generating and outputting a first logic state selection enable signal to be supplied to the voltage dividing circuit; and during the strong charging period, the first and second driving voltages are lowered by a charged amount of the image signal distorted by the phantom, And generating and outputting a selection enable signal of a second logic state so as to be supplied to the voltage divider circuit.

According to an embodiment of the present invention, there is provided a driving apparatus for a liquid crystal display device and a method of driving the same, which minimize the difference in the charged amount of a video signal in a liquid crystal panel in which the number of data lines is halved, have.

The present invention also provides a method for reducing the power consumption by reducing the amount of charge of the video signal to be charged in each sub-pixel and the charge amount of the video signal to be charged to a minimum, The difference in the charged amount of the video signal can be minimized.

Hereinafter, a driving apparatus and a driving method of a liquid crystal display according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram illustrating a liquid crystal display device according to an embodiment of the present invention.

The liquid crystal display device shown in Fig. 1 includes a liquid crystal panel 2 having a pixel matrix of a structure in which the number of data lines DL1 to DLm is halved; A data driver 4 for charging a video signal to each of the data lines DL1 to DLm of the liquid crystal panel 2 and for reducing the amount of charged video signal during a strong charging period by a charging amount of a video signal distorted in a charging period, ; A gate driver 6 for driving the gate lines GL1 to GLn of the liquid crystal panel 2; And supplies the image data RGB from the outside to the data driver 4 and the data driver 4 charges the video signal by reducing the amount of the charged image signal in the strong charging period by a charged amount of the video signal distorted in the approximate charging period And a timing controller 8 for controlling the data driver 4 by generating a data control signal DCS.

The pixel matrix of the liquid crystal panel 2 shown in FIG. 1 includes a plurality of gate lines GL1 to GLn and data lines DL1 to DLm and odd gate lines GL1, GL3, GL5, ... G, B) arranged between the even-numbered gate lines GL1-GLn-1 and the even-numbered gate lines GL2, GL4, GL6, ..., GLn, (TFT) connected to the gate lines GL1 to GLn and the data lines DL1 to DLm, respectively.

The plurality of sub-pixels R, G and B are divided into red, green and blue sub-pixels R, G and B, respectively. The plurality of sub-pixels R, G and B are arrayed such that the order of the red, green and blue sub-pixels R, G and B is repeated along the horizontal direction of the pixel matrix, that is, And the sub-pixels of the same color are repeated in the vertical direction.

Each of the data lines DL1 to DLm is commonly connected to sub-pixels in odd columns and sub-pixels in even columns located on both sides. In other words, each of the data lines DL1 to DLm is connected to each of the sub-pixels in the odd-numbered column located on the left side adjacent to the data line through the thin film transistor TFT, and is connected to the even- Pixel are connected to each of the sub-pixels of the column through the thin film transistor (TFT). Sub-pixels in an odd-numbered column connected to one data line and sub-pixels in an even-numbered column are sequentially connected to different gate lines through corresponding thin film transistors (TFT). In other words, each of the sub-pixels R, G, and B constituting one horizontal line is disposed between a pair of gate lines, that is, an odd-numbered gate line and an even-numbered gate line, Or the like. At this time, a pair of sub-pixels connected to the same data line in the horizontal line, that is, sub-pixels in an odd-numbered column and sub-pixels in an even-numbered column are sequentially connected to different gate lines among the pair of gate lines. Accordingly, the number of the gate lines GL1 to GLn is doubled, but the number of the data lines DL1 to DLm is halved.

The data driver 4 receives a data control signal DCS from the timing controller 8, for example, a source start pulse SSP, a source shift clock SSC, a source output enable SOE (Source Output Enable) signal from the timing controller 8 to an analog voltage, that is, a video signal. Specifically, the data driver 4 latches the image data (Data) input according to the SSC, and then, in response to the SOE signal, applies a scan pulse to each of the gate lines GL1 to GLn, To each of the data lines DL1 to DLm.

At this time, the data driver 4 outputs the positive polarity (+) or negative polarity (-) having a predetermined level in accordance with the gray level value of the image data (Data) arranged in response to the polarity control signal from the timing controller Selects a gamma voltage, and supplies the selected gamma voltage to each of the data lines DL1 to DLm as a video signal. In addition, the data driver 4 supplies the video signal in the next strong charging period by a charging amount that is distorted by the video signal being charged to a substantially equal level with the period during which the video signal is supplied, that is, The amount of charge of the signal is reduced and charged. As described above, the configuration of the data driver 4 for reducing the charging amount of the video signal during the strong charging period of the video signal by the charging amount of the video signal distorted in the approximate charging period of the video signal and the driving method thereof will be described later Will be described in more detail with reference to FIG.

The gate driver 6 receives the gate control signal GCS from the timing controller 8. In response to the supplied gate control signal GCS, for example, a gate start pulse (GSP), a gate shift clock (GSC) and a gate output enable (GOE) signal Sequentially generates scan pulses, and sequentially supplies the scan pulses to the gate lines GL1 to GLn. In other words, the gate driver 6 shifts the GSP from the timing controller 8 according to the GSC to sequentially supply a scan pulse, for example, a gate-on voltage to the gate lines GL1 to GLn. Then, the gate-off voltage is supplied during the period when the gate-on voltage is not supplied to the gate lines GL1 to GLn. Here, the gate driver 6 controls the pulse width of the scan pulse in accordance with the GOE signal.

The timing controller 8 sequentially arranges image data (Data) input from the outside in accordance with driving of the liquid crystal panel 2 and sequentially supplies the image data to the data driver 4. The timing controller 8 generates a gate control signal GCS using external synchronization signals DCLK, DE, Hsync, and Vsync and supplies the gate control signal GCS to the gate driver 6. Then, by using the above-mentioned synchronization signals (DCLK, DE, Hsync, Vsync), the data driver 4 supplies the video signal to the next strong charging periods as much as the charging amount of the video signal, Generates a data control signal (DCS) including a selection enable signal so that the charge amount can be reduced and charged, and supplies it to the data driver (4).

2 is a view showing a pixel matrix structure of the liquid crystal panel shown in Fig.

Referring to FIG. 2, each of the sub-pixels R, G, and B of the pixel matrix in which the number of the data lines DL1 to DLm is halved is inverted in units of sub-pixels vertically adjacent in the vertical direction, It is possible to charge the video signal in the form of a version with two dots in which the polarity is inverted in units of two sub-pixels in the direction of the sub-pixel. The arrows in FIG. 2 indicate the filling order of the video signals in 2 × 2 sub pixels neighboring up, down, left and right. More specifically, since a pair of sub-pixels connected to the same data line are sequentially driven by different gate lines (odd or even gate lines), a video signal supplied to each of the data lines DL1 to DLm is 2 The polarity of the video signal is inverted in 2H units, and hence the polarity inversion period of 4H is maintained.

As the data polarity is inverted in 2H units in each of the data lines DL1 to DLm, a pair of sub-pixels sequentially connected and connected to the same data line has a charge characteristic of charging of a polarity opposite to the previous horizontal period Sub-pixel, and a strong-charging sub-pixel that charges data having the same polarity as the previous horizontal period. In other words, a pair of sub-pixels connected to the same data line and sequentially driven has a relatively long charging time (i.e., rising or falling time) of the video signal as the data of the polarity opposite to the previous horizontal period is charged. A charged sub-pixel having a smaller charge amount of the gradation-contrast video signal and a charged-up sub-pixel having a data charging time shorter than that of the approximately charged sub-pixel and having a larger data charging amount for the same gradation . In this case, a sub-pixel in which the video signal is strongly charged due to the same polarity as the previous horizontal period, and a sub-pixel in which the video signal is about to be charged due to a polarity opposite to the previous horizontal period are divided into horizontal lines or vertical lines .

Therefore, the driving apparatus for a liquid crystal display according to an embodiment of the present invention can compensate for the amount of charge distorted by the charge due to the polarity of the polarity of the previous horizontal period, The charging amount of the video signal is reduced and charged. In this case, unlike the case of further increasing the voltage level of the video signal to be charged in the weak charge period, the voltage level of the video signal can be further lowered during the strong charge period, Power can be reduced.

3 is a block diagram specifically showing the data driver shown in FIG.

The data driver 4 shown in Fig. 3 includes a shift register 21 for outputting a sampling signal (SAM) in response to SSP and SSC from the timing controller 8, A latch unit 22 for sequentially sampling the data (Data) and outputting one line of data (RData) sampled according to the SOE signal, a polarity control signal POL from the timing controller 8, A gamma voltage generating unit 24 for varying the voltage level of the gamma voltages GV in units of the charging and discharging periods in response to the energization period En, A digital-to-analog converter (ADC) for converting one line of data (RData) from the latch unit 22 into an analog video signal (AData) using the supplied gamma voltages (GV) A converter (DAC) And an output buffer 25 for amplifying the analog video signal AData from the DAC 23 and supplying the analog video signal AData to the data lines DL1 to DLm.

The shift register 21 generates the sampling signal SAM by using the SSC and the SSP from the timing controller 8. [ Specifically, the shift register 21 generates the sampling signal SAM by shifting the source start pulse SSP according to the SSC, and sequentially supplies the sampling signal SAM to the latch unit 22. [

The latch unit 22 sequentially samples the image data Data supplied from the timing controller 8 through the data bus line in accordance with the sampling signal SAM from the shift register 21. The sampled data is stored in units of one horizontal line, and the latched image data (RData) for one horizontal line is simultaneously output to the DAC 25 in response to the SOE signal.

The gamma voltage generator 24 receives the first and second driving voltages VDD and VSS and a plurality of reference gamma voltages RGV from a power supply unit and a reference gamma voltage generator. Here, the first driving voltage VDD may be a positive DC driving voltage, and the second driving voltage VSS may be a negative DC driving voltage. The gamma voltage generator 24 generates the positive (+) and negative (-) gamma voltages (VDD and VSS) in a divided mode between a plurality of resistors serially connected between the first and second driving voltages And supplies a plurality of positive (+) and negative (-) gamma voltages GV to the DAC 23, as shown in FIG. At this time, the gamma voltage generator 24 generates the gamma voltages GV in the approximately charge period and the strong charge period in response to the polarity control signal POL and the select enable signal En from the timing controller 8 The entire level is varied and output. Here, the voltage level of the gamma voltages GV that are globally variable is varied by the amount of charge that the image signal is distorted and becomes smaller in the approximate charge period.

The DAC 23 is supplied with a plurality of positive (+) or negative (-) gamma voltages supplied with varying voltage levels according to the polarity control signal POL from the timing controller 8 and the selection enable signal En Converts the video data RData into the positive polarity positive or negative polarity analog video signal AData by using the voltage GV and outputs the converted video signal AData of one line to the output buffer 25). Here, the polarity control signal POL can be inverted in at least one horizontal line unit. Specifically, when a plurality of positive (+) gamma voltages GV are supplied from the gamma voltage generator 24 by the polarity control signal POL, the DAC 23 outputs the image data (+) Gamma voltage (GV) corresponding to the reference voltage (RData) to convert it into an analog video signal (AData) and output it. If a plurality of negative (-) gamma voltages GV are supplied from the gamma voltage generator 24, a negative (-) gamma voltage GV corresponding to the image data RData is selected, Signal (AData) and outputs it.

The output buffer 25 outputs the video signal AData using the first driving voltage VDD in order to prevent the video signal AData from the DAC 23 from being distorted according to the RC time constant of the data lines DL1 to DLm. (AData) and supplies the amplified video signal (AData) to the data lines (DL1 to DLm).

4 is a circuit diagram showing the gamma voltage generator shown in FIG.

The gamma voltage generator 24 of the present invention shown in FIG. 4 generates a plurality of reference gamma voltages RGV1 to RGVn in a divided mode between a plurality of resistors R256 to R256 ' A voltage divider circuit for generating positive (+) and negative (-) gamma voltages (GV) using the driving voltage sources (VDD and VSS), a voltage divider circuit And supplies the first driving voltage VDD to one end of the voltage divider circuit as it is or the first driving voltage VDD as a negative voltage according to the selection enable signal En from the timing controller 8 And a second driving voltage source (VSS) which is provided between the other end of the voltage divider circuit and the second driving voltage source (VSS) to supply the divided voltage (Vss) according to the selection enable signal (En) The second driving voltage VSS may be directly supplied to the other end of the circuit or the second driving voltage V (SS) and supplies the second switching unit 34 with the voltage.

The gamma voltage generator 24 configured as described above receives the first positive driving voltage VDD, the second negative driving voltage VSS, and the plurality of reference gamma voltages RGV1 through RGVn, The reference gamma voltages RGV1 to RGVn are divided by the voltage divider circuit to generate a plurality of gamma voltages GV. Specifically, the voltage divider circuit is configured to have positive and negative gamma voltages (positive and negative voltages) at a voltage-dividing node between a plurality of resistors (R1 to R256 ') serially connected between the first switching unit 34 and the second switching unit 36 (GV).

The first switching unit 34 supplies the first driving voltage VDD directly to the voltage dividing circuit or at least one first voltage step-down resistor RD in response to the selection enable signal En from the timing controller 8 And a switching element for supplying a first driving voltage that is lowered by a charge amount distorted by the charge to the voltage divider circuit. The second switching unit 36 also supplies the second driving voltage VSS directly to the voltage dividing circuit in response to the selection enable signal En or supplies the second driving voltage VSS to the voltage divider circuit through at least one second voltage- And a switching element for supplying a second driving voltage that is lowered by a charge amount distorted at the time of charging to the voltage dividing circuit.

By the first and second switching units 34 and 36 of the present invention constructed and operated as described above, the voltage divider circuit can supply the gamma voltages ( GV).

FIG. 5 is a driving waveform diagram of an example of driving the pixel matrix shown in FIG. 1 and FIG. 2 and the first and second switching units shown in FIG.

Referring to FIG. 5, the data driver 4 of the present invention includes a data driver 4 for inverting a video signal so that polarities thereof are inverted in accordance with a polarity control signal POL supplied to be inverted in two horizontal periods from the timing controller 8, To the lines DL1 to DLm. In other words, in the data driver 4, the polarity of each sub-pixel (R, G, B) constituting the pixel matrix is inverted in units of sub-pixels vertically adjacent to each other, and in the horizontal direction, So that the video signals are supplied to the data lines DL1 to DLm in the form of a version with two dots as much as possible.

2 and 5, the video signal is charged in a period during which the video signal is supplied with the polarity opposite to the polarity of the video signal supplied in the previous horizontal period, and the polarity of the video signal supplied during the previous horizontal period The video signal can be strongly charged during a period in which the video signal is supplied with the same polarity. The timing controller 8 of the present invention controls the timing controller 8 so that the first and second switching units 34 and 36 can supply the first and second driving voltages VDD and VSS to the voltage- And generates a logic selection enable signal En and supplies it to the switches of the first and second switching units 34 and 36, respectively. Therefore, the voltage dividing circuit of the gamma voltage generating section 24 divides the first and second driving voltages VDD and VSS to generate the positive and negative gamma voltages GV. In each sub-pixel, The video signal of the exhibition is distorted.

However, the timing controller 8 controls the first and second switching units 34 and 36 to supply the first and second driving voltages VDD and VSS by the charging amount aV of the video signal distorted during the strong charging period A second logic state selection enable signal En is generated so as to be supplied to the voltage dividing circuit while being supplied to the switches of the first and second switching units 34 and 36, respectively. Accordingly, the voltage dividing circuit of the gamma voltage generating unit 24 divides the first and second driving voltages that have been stepped down by the charged amount (aV) of the distorted video signal, Thereby generating and outputting the inverted positive polarity and negative polarity gamma voltages. Thus, in each of the sub pixels, a video signal whose voltage is lowered by the charged amount (aV) of the video signal distortion-distorted is supplied during the strong charging period. That is, in the display of the coercive force, a video signal which is reduced by the charged amount (aV) of the image signal distorted by the vampire is supplied to each sub pixel, so that the difference between the charged amount of the vampire display and the charged amount of the coercive display can be minimized.

6 is a driving waveform diagram of the pixel matrix shown in Figs. 1 and 2 and another example of driving the first and second switching units shown in Fig.

Referring to FIG. 6, the data driver 4 of the present invention includes a timing controller 8 for inverting a polarity of a polarity of a polarity control signal POL supplied from the timing controller 8, To the lines DL1 to DLm. In other words, the data driver 4 applies a video signal to each data line in the form of a version having 4 dots so that each sub-pixel (R, G, B) constituting a pixel matrix is inverted in polarity in units of two sub- (DL1 to DLm).

2 and 6, the video signal is charged in a period during which the video signal is supplied with the polarity opposite to the polarity of the video signal supplied in the previous horizontal period, and the polarity of the video signal supplied during the previous horizontal period The video signal can be strongly charged during a period in which the video signal is supplied with the same polarity. The timing controller 8 of the present invention controls the timing controller 8 so that the first and second switching units 34 and 36 can supply the first and second driving voltages VDD and VSS to the voltage- And generates a logic selection enable signal En and supplies it to the switches of the first and second switching units 34 and 36, respectively. Therefore, the voltage dividing circuit of the gamma voltage generating section 24 divides the first and second driving voltages VDD and VSS to generate the positive and negative gamma voltages GV. In each sub-pixel, The video signal of the exhibition is distorted.

However, the timing controller 8 controls the first and second switching units 34 and 36 to supply the first and second driving voltages VDD and VSS by the charging amount aV of the video signal distorted during the strong charging period A second logic state selection enable signal En is generated so as to be supplied to the voltage dividing circuit while being supplied to the switches of the first and second switching units 34 and 36, respectively. Therefore, the voltage dividing circuit of the gamma voltage generating unit 24 divides the first and second driving voltages that have been stepped down by the charged amount (aV) of the distorted video signal, Thereby generating and outputting the inverted positive polarity and negative polarity gamma voltages. Thus, in each of the sub pixels, a video signal whose voltage is lowered by the charged amount (aV) of the video signal distortion-distorted is supplied during the strong charging period. That is, in the display of the coercive force, a video signal which is reduced by the charged amount (aV) of the image signal distorted by the vampire is supplied to each sub pixel, so that the difference between the charged amount of the vampire display and the charged amount of the coercive display can be minimized.

As described above, the present invention reduces power consumption by reducing the charge amount of the video signal to be charged in each sub-pixel and the charge amount of the video signal to be charged to a minimum, The difference in the charged amount of the video signal can be minimized.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

1 is a configuration diagram illustrating a liquid crystal display device according to an embodiment of the present invention;

2 is a view showing a pixel matrix structure of the liquid crystal panel shown in Fig.

3 is a configuration diagram specifically showing the data driver shown in Fig.

4 is a configuration circuit diagram showing the gamma voltage generator shown in FIG.

Fig. 5 is a driving waveform diagram of an example of driving the pixel matrix shown in Figs. 1 and 2 and the first and second switching units shown in Fig. 4; Fig.

Fig. 6 is a driving waveform diagram of the pixel matrix shown in Figs. 1 and 2 and another example of driving the first and second switching units shown in Fig. 4;

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

2: liquid crystal panel 4: data driver

6: Gate driver 8: Timing controller

21: shift register 22: latch portion

23: DAC 24: gamma voltage generator

25: output buffer 34: first switching unit

36: Second switching unit En: Select enable signal

TFT: Thin Film Transistor SOE: Source Output Enable

Claims (10)

A liquid crystal panel having a plurality of sub-pixels constituting a pixel matrix having a structure in which the number of data lines is halved; A data driver for charging a video signal to each of the data lines of the liquid crystal panel and reducing the amount of charge in a strong charging period by a charged amount of the video signal distorted in the approximate charging period; And And supplies the video data to the data driver in such a manner that the data driver charges the video data by reducing the amount of the charged video data during the strong charging period by a charged amount of the video signal distorted during the approximate charging period, And a timing controller for controlling the data driver, The data driver includes: And a gamma voltage generator for varying the voltage level of the gamma voltages as a whole in response to the polarity control signal and the selection enable signal from the timing controller in units of the approximate charge period and the strong charge period,  The gamma- A voltage divider circuit for generating positive and negative gamma voltages using a plurality of reference gamma voltages and first and second driving voltage sources in a voltage division mode between a plurality of resistors connected in series, Wherein the first voltage is supplied to one end of the voltage dividing circuit in accordance with the selection enable signal, or the first driving voltage is provided between the one end of the voltage dividing circuit and the first driving voltage source, A first switching unit for down-regulating and supplying a charging amount which is distorted and reduced in a charging period, and Wherein the voltage divider circuit is provided between the other end of the voltage divider circuit and the second drive voltage source and supplies the second drive voltage to the other end of the voltage divider circuit as it is or according to the select enable signal, And a second switching unit for supplying the second switching unit with a reduced amount of charge that is distorted and reduced in the period. delete delete The method according to claim 1, Wherein the first switching unit comprises: The first drive voltage is directly supplied to the voltage dividing circuit in response to the selection enable signal or the first drive voltage that is reduced by the at least one first step- And a switching element for supplying the switching element, The second switching unit supplies the second driving voltage directly to the voltage dividing circuit in response to the selection enable signal or the second driving voltage that is reduced by the charging amount distorted by the at least one second step- And a switching element supplied to the voltage dividing circuit. The method according to claim 1, The timing controller includes: The first and second switching units generate a first logic state selection enable signal so that the first and second switching units can supply the first and second driving voltages to the voltage dividing circuit as they are, Respectively, Wherein the first and second switching units are configured to supply the first and second driving voltages to the voltage divider circuit by a charging amount of the video signal distorted by the phantom power during the strong charging period, And supplies the first and second switching units to the first and second switching units, respectively. A method of driving a liquid crystal display device having a liquid crystal panel, a data driver, a gate driver, and a timing controller having a pixel matrix of a structure in which the number of data lines is halved, Filling a data line of the liquid crystal panel with a video signal; Reducing the charged amount in a strong charging period during a strong charging period by a charging amount of a video signal in which the video signal is distorted in a weak charging period using the data driver; And And controlling the data driver to generate a data control signal so that the charged amount is charged and charged in the strong charging period by a charging amount of the video signal distorted in the weak charging period, The step of reducing the amount of charged charges in the strong charging period by a charged amount of the video signal distorted in the weak charging period, Generating and outputting a voltage level of the gamma voltages as a whole in response to the polarity control signal and the select enable signal of the data control signal in the approximate charge period and the strong charge period unit; Converting the data of one line into the analog video signal by using the gamma voltages supplied with the voltage level varying in units of the approximate charging period and the strong charging period, Wherein the step of varying the voltage level of the gamma voltages as a whole includes: Generating positive and negative gamma voltages using a plurality of reference gamma voltages and first and second driving voltage sources in a voltage division mode between a plurality of serially connected resistors, The first driving voltage is supplied to one end of the voltage dividing circuit having the voltage dividing mode in accordance with the selection enable signal, or the first driving voltage is lowered by a charging amount, And Supplying the second driving voltage as it is to the other end of the voltage divider circuit as the selection enable signal, or supplying the second driving voltage by reducing the amount of charge of the video signal by reducing the distortion of the video signal in the approximate charging period, A method of driving a display device. delete delete The method according to claim 6, Wherein the step of stepping down the first driving voltage by reducing the amount of charge of the video signal,  The first driving voltage is supplied to the voltage dividing circuit by stepping down the first driving voltage by at least one first step-down resistor and a switching element connected in series to the first driving voltage source, Wherein the step of supplying the second driving voltage by stepping down and supplying the second driving voltage by a charging amount which is reduced by the amount of distortion of the video signal during the approximate charging period includes supplying the second driving voltage to the second driving voltage source by using at least one second step- And the voltage of the driving voltage is lowered by the amount of charge that is distorted when the battery is charged, and then supplied to the voltage dividing circuit. The method according to claim 6, The step of generating the data control signal so as to reduce the charged amount in the strong charging period by the charged amount of the image signal distorted in the weak charging period, Generating and outputting a first logic state selection enable signal so that the first and second driving voltages can be supplied to the voltage dividing circuit as it is during the approximate charging period; And generating and outputting a second logic state selection enable signal so that the first and second driving voltages can be supplied to the voltage dividing circuit by the charging amount of the video signal distortion-distorted during the strong charging period A method of driving a liquid crystal display device.

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