KR20110033422A - Liquid crystal display and method of driving the same - Google Patents

Abstract

PURPOSE: A liquid crystal display and a method of driving the same are provided to reduce power consumption by reducing heat from a timing controller. CONSTITUTION: In a liquid crystal display and a method of driving the same, a frame memory(112) stores pixel data of a current frame. The frame memory outputs the pixel data of a previous frame. A lookup table(114) compares the pixel data of the previous frame with the pixel data of the current frame. The look up table stores modulation data. A comparator(120) decides whether the pixel data of the current frame is the highest or lowest gradation data. A data selection unit(116) outputs one of modulation data and pixel data.

Description

Liquid crystal display and its driving method {LIQUID CRYSTAL DISPLAY AND METHOD OF DRIVING THE SAME}

The present invention relates to a liquid crystal display and a driving method thereof capable of reducing heat generation and power consumption.

The liquid crystal display displays an image by using the electrical and optical characteristics of the liquid crystal. The liquid crystal display is an active matrix type in which thin film transistors, which are switching elements, are formed in each sub-pixel, and thus are suitable for displaying moving images. However, due to the inherent viscosity and elasticity of liquid crystals, motion blur may occur due to the afterimage of a previous frame during video playback due to a slow response speed and hold type driving characteristics. There is a problem. For example, when the data voltage applied to the liquid crystal in the nth frame is variable, the luminance does not change immediately to the target gray scale, but gradually changes from the gray scale of the previous frame to the target gray scale due to the slow response speed of the liquid crystal, thereby affecting the next frame. Afterimages are caused.

In order to solve this problem, an overdriving method of improving a liquid crystal response speed in proportion to the applied voltage by applying an overshoot voltage higher than a target value at the instant of data change is used. The overdriving method stores the data of the previous frame in the frame memory, compares the data of the previous frame with the data of the current frame, and converts the data into modulated data stored in the look-up table according to the comparison result.

As such, there is a case where the modulation data stored in the lookup table of the conventional overdriving method and the data of the current frame are the same. In this case, although the look-up table must be accessed even though the data of the current frame is output without over-driving, a heat generation phenomenon occurs in the timing controller in which the look-up table is mounted and power consumption is increased.

In order to solve the above problems, the present invention is to provide a liquid crystal display and a driving method thereof that can reduce the heat generation phenomenon and power consumption.

In order to achieve the above technical problem, a liquid crystal display according to the present invention includes a frame memory for storing pixel data of a current frame and outputting pixel data of a previous frame; A lookup table for comparing the pixel data of the previous frame and the pixel data of the current frame and storing preset modulation data according to the comparison result; A comparator for determining whether the pixel data of the current frame is the highest gray level data or the lowest gray level data; And a data selector configured to select and output any one of the modulated data of the lookup table and pixel data of the current frame according to the comparison information of the comparator.

The comparator supplies a high logic enable signal to the data selector if the pixel data of the current frame is not the highest gray level data or the lowest gray level data, and if the pixel data of the current frame is the highest gray level data or the lowest gray level data, A logic enable signal is supplied to the data selector.

The comparator supplies a high logic enable signal to the data selector if the pixel data of the current frame is not the highest gray level data or the lowest gray level data, and if the pixel data of the current frame is the highest gray level data or the lowest gray level data, A first comparator for supplying a logic enable signal to the data selector; If the pixel data of the current frame and the pixel data of the previous frame are different, the enable signal of the high logic is supplied to the data selector, and if the pixel data of the current frame and the pixel data of the previous frame are the same, the row And a second comparator for supplying a logic enable signal to the data selector.

The data selector outputs the modulated data of the lookup table in response to the enable signal of the high logic, and selects and outputs pixel data of the current frame in response to the enable signal of the low logic. .

In order to achieve the above technical problem, a driving method of a liquid crystal display according to the present invention includes comparing pixel data of a previous frame and pixel data of a current frame and storing preset modulation data in a lookup table according to the comparison result; ; Storing pixel data of the current frame in a frame memory; Determining whether the pixel data of the current frame is the highest gray level data or the lowest gray level data; And selecting one of the modulated data of the lookup table and the pixel data of the current frame by the data selector according to the determination result.

The liquid crystal display and the driving method thereof according to the present invention output the pixel data of the current frame without accessing the lookup table when the pixel data of the current frame is the highest gray level data or the lowest gray level data. In addition, the liquid crystal display and the driving method thereof according to the present invention output the pixel data of the current frame without accessing the lookup table when the pixel data of the current frame and the pixel data of the previous frame are the same. Accordingly, the liquid crystal display according to the present invention can reduce heat generation of the timing controller in which the look-up table is embedded, thereby preventing component damage and reducing power consumption.

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

1 is a block diagram illustrating a liquid crystal display according to a first embodiment of the present invention.

The liquid crystal display shown in FIG. 1 includes a liquid crystal panel 102 for displaying an image, a gate driver 108 and a data driver 106 for driving the liquid crystal panel 102, a gate driver 108 and a data driver ( A timing controller 104 for controlling 106 and an over-driving circuit (ODC) 110 for modulating the input pixel data for over-driving.

The liquid crystal panel 102 includes a liquid crystal cell Clc matrix and a thin film transistor TFT connected to the gate line GL and the data line DL to drive each of the liquid crystal cells Clc. The thin film transistor TFT of the liquid crystal panel 102 is turned on by the gate-on voltage from the gate line GL, so that the data signal of the data line DL is supplied to the liquid crystal cell Clc, thereby providing a liquid crystal cell Clc. ) Is applied as much as the difference between the common voltage (Vcom) and the data signal, and is turned off by the gate-off voltage to maintain the voltage applied to the liquid crystal cell (Clc). The liquid crystal cell Clc drives the liquid crystal according to the applied voltage to adjust the light transmittance so that the liquid crystal panel 102 displays an image.

The gate driver 108 sequentially supplies the gate-on voltage to the gate line GL in response to the control signal from the timing controller 104, and supplies the gate-off voltage in other periods.

The data driver 106 converts the digital data signal into an analog voltage using the control signal and the gamma voltage from the timing controller 104, and supplies the changed analog voltage to the data line DL.

The timing controller 104 generates a plurality of control signals using a plurality of synchronization signals input through a system (not shown) and supplies the control signals to the gate driver 108 and the data driver 106. The timing controller 104 aligns the pixel data signal input from the overdriving circuit 110 and supplies the pixel data signal to the data driver 106.

The overdriving circuit 110 compares the pixel data of the current frame Fn input from the outside with the pixel data of the previous frame Fn-1 and modulates the data according to the comparison result.

Specifically, the overdriving circuit 110 modulates the pixel data of the current frame Fn when the pixel data of the current frame Fn is not the highest or lowest gray level data, and the pixel data of the current frame Fn is the highest. In the case of gray level or lowest gray level data, the pixel data of the current frame Fn is output without modulating the pixel data of the current frame Fn.

To this end, the overdriving circuit 110 includes a frame memory 112, a lookup table 114, a comparator 120, and a data selector 116 as shown in FIG. 2.

The frame memory 112 stores pixel data input from the outside in frame units and supplies the stored frame data to the data selector 116.

The comparator 120 determines whether the pixel data of the current frame Fn is the highest gray level data or the lowest gray level data. Specifically, the comparator 120 supplies the enable signal LE of the low logic to the data selector 116 when the pixel data of the current frame Fn is the highest gray level data or the lowest gray level data, and the current frame Fn. If the pixel data of? Is not the highest gray level data or the lowest gray level data, a high logic enable signal HE is supplied to the data selector 116.

The lookup table 114 compares the pixel data of the previous frame Fn-1 with the pixel data of the current frame Fn and stores modulation data shown in Table 1 corresponding to the comparison result.

The modulated data stored in the lookup table 114 is supplied to the data selector 116 in response to the high logic enable signal HE. This lookup table 114 is stored in a memory such as SDRAM.

The data selector 116 compares the pixel data of the current frame Fn with the pixel data of the previous frame Fn-1 in response to the high logic enable signal HE from the comparator 120 to determine a lookup table ( The modulation data (MData) stored in 114 is output. In addition, the data selector 116 outputs pixel data Data of the current frame Fn in response to the enable signal LE of the row logic from the comparator 120.

As described above, when the pixel data of the current frame Fn is the highest gray level data or the lowest gray level data, the modulation data stored in the lookup table 114 is the same data as the pixel data of the current frame Fn as shown in Table 1, and thus, a separate over Driving is unnecessary. Accordingly, the data selector 116 accesses the lookup table 114 when the high logic enable signal HE from the comparator 120 is input, whereas the low logic enable signal from the comparator 120 is accessed. When LE is input, the pixel data of the current frame Fn is output without accessing the lookup table 114. Accordingly, the liquid crystal display according to the present invention can reduce heat generation of the timing controller 104 in which the lookup table 114 is embedded, thereby preventing component damage and reducing power consumption.

3 is a flowchart illustrating a driving method of a liquid crystal display according to a first exemplary embodiment of the present invention.

First, pixel data of a previous frame Fn-1 and pixel data of a current frame Fn stored in the frame memory 112 are input to the data selector 116 (step S11). The pixel data of the current frame Fn is input to the comparator 120 to determine whether the pixel data of the current frame Fn is the highest gray level data MSG or the lowest gray level data LSG (step S12).

If the pixel data of the current frame Fn is not the highest gray level data MSG or the lowest gray level data LSG, the comparator 120 generates an enable signal HE having a high logic to generate the data selector 116. Supply to step (S13). The data selector 116 modulates the pixel data of the current frame Fn into modulation data MData stored in the lookup table in response to the high logic enable signal HE, and the modulation data MData is a data driver. It is supplied to 106 (step S14).

If the pixel data of the current frame Fn is the highest gray level data MSG or the lowest gray level data LSG, the comparator 120 generates an enable signal LE having a low logic to the data selector 116. Supply (step S15). The data selector 116 supplies the pixel data Data of the current frame Fn to the data driver 106 in response to the enable signal LE of the row logic (step S16).

4 is a block diagram illustrating an overdriving circuit of a liquid crystal display according to a second exemplary embodiment of the present invention.

The overdriving circuit shown in FIG. 4 includes a frame memory 112, a lookup table 114, a comparator 120, and a data selector 116.

The frame memory 112 stores pixel data input from the outside in frame units and supplies the stored frame data to the data selector 116.

The comparator 120 is composed of first and second comparators 122 and 124.

The first comparator 122 determines whether the pixel data of the current frame Fn is the highest gray level data or the lowest gray level data. Specifically, the first comparator 122 supplies the enable signal LE of the low logic to the data selector 116 when the pixel data of the current frame Fn is the highest gray level data or the lowest gray level data. If the pixel data of Fn) is not the highest gray level data or the lowest gray level data, the enable signal HE of high logic is supplied to the data selector 116.

The second comparator 124 determines whether the pixel data of the previous frame Fn-1 and the pixel data of the current frame Fn are the same. In detail, the second comparator 122 supplies the low logic enable signal LE to the data selector 116 when the pixel data of the current frame Fn and the pixel data of the previous frame Fn-1 are the same. If the pixel data of the current frame Fn and the pixel data of the previous frame Fn-1 are not the same, the enable signal HE having a high logic is supplied to the data selector 116.

The lookup table 114 compares the pixel data of the previous frame Fn-1 with the pixel data of the current frame Fn and stores modulation data shown in Table 2 corresponding to the comparison result.

The modulated data stored in the lookup table 114 is supplied to the data selector 116 in response to the high logic enable signal HE. This lookup table 114 is stored in a memory such as SDRAM.

The data selector 116 responds to the high logic enable signal HE from the first and second comparators 122 and 124, respectively, and the pixel data of the current frame Fn and the pixel data of the previous frame Fn-1. Compared to the modulation data (MData) stored in the lookup table 114 is output. In addition, the data selector 116 outputs the pixel data Data of the current frame Fn in response to the enable logic LE of the low logic from the first and second comparators 122 and 124, respectively.

As described above, when the pixel data of the current frame Fn is the highest gray level (for example, 1023 gray level) data or the lowest gray level (0 gray level) data, the pixel data of the current frame Fn and the previous frame Fn-1. If the pixel data of the same is the same, the modulation data stored in the lookup table 114 is the same as the pixel data of the current frame (Fn) as shown in Table 2, and no separate overdriving is necessary.

Accordingly, the data selector 116 accesses the lookup table 114 when the high logic enable signal HE from the comparator 120 is input, whereas the low logic enable signal from the comparator 120 is accessed. When LE is input, the pixel data of the current frame Fn is output without accessing the lookup table 114. Accordingly, the liquid crystal display according to the present invention can reduce heat generation of the timing controller 104 in which the lookup table 114 is embedded, thereby preventing component damage and reducing power consumption.

5 is a flowchart illustrating a driving method of a liquid crystal display according to a second exemplary embodiment of the present invention.

First, pixel data of the previous frame Fn-1 and pixel data of the current frame Fn stored in the frame memory are input to the data selector 116 (step S11). The pixel data of the current frame Fn is input to the first comparator 122 to determine whether the pixel data of the current frame Fn is the highest gray level data MSG or the lowest gray level data LSG (step S22). . In addition, the pixel data of the current frame Fn and the pixel data of the previous frame Fn-1 are input to the second comparator 124 so that the pixel data of the current frame Fn and the pixel data of the previous frame Fn-1 are input. (S22).

If the pixel data of the current frame Fn is not the highest gray level data MSG or the lowest gray level data LSG, and the pixel data of the current frame Fn and the pixel data of the previous frame Fn-1 are not the same. The comparator 120 generates a high logic enable signal HE and supplies it to the data selector 116 (step S23). The data selector 116 modulates the pixel data of the current frame into modulation data MData stored in the lookup table in response to the high logic enable signal HE, and the modulation data MData is converted into the data driver 106. It is supplied to (step S24).

If the pixel data of the current frame Fn is the highest grayscale data MSG or the lowest grayscale data LSG, and the pixel data of the current frame Fn and the pixel data of the previous frame Fn-1 are the same, the comparator 120 generates a low logic enable signal LE and supplies it to the data selector 116 (step S25). The data selector 116 supplies the pixel data Data of the current frame Fn to the data driver 106 in response to the enable signal LE of the low logic (step S26).

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. Will be clear to those who have knowledge of.

1 is a block diagram illustrating a liquid crystal display according to the present invention.

FIG. 2 is a block diagram illustrating a first embodiment of the overdriving circuit shown in FIG. 1.

3 is a flowchart for describing a method of driving the overdriving circuit illustrated in FIG. 2.

FIG. 4 is a block diagram for describing a second embodiment of the overdriving circuit shown in FIG. 1.

5 is a flowchart for describing a method of driving the overdriving circuit illustrated in FIG. 4.

<Description of Symbols for Main Parts of Drawings>

102 liquid crystal panel 104 timing control unit

106: data driver 108: gate driver

110: overdriving circuit 112: frame memory

114: lookup table 116: data selection unit

120,122,124: comparator

Claims (9)

A frame memory for storing pixel data of a current frame and outputting pixel data of a previous frame; A lookup table for comparing the pixel data of the previous frame and the pixel data of the current frame and storing preset modulation data according to the comparison result; A comparator for determining whether the pixel data of the current frame is the highest gray level data or the lowest gray level data; And a data selector configured to select and output any one of the modulated data of the lookup table and pixel data of the current frame according to the comparison information of the comparator. The method of claim 1, The comparator supplies a high logic enable signal to the data selector if the pixel data of the current frame is not the highest gray level data or the lowest gray level data, and if the pixel data of the current frame is the highest gray level data or the lowest gray level data, And a logic enable signal is supplied to said data selector. The method of claim 1, The comparator If the pixel data of the current frame is not the highest gray level data or the lowest gray level data, a high logic enable signal is supplied to the data selector, and if the pixel data of the current frame is the highest gray level data or the lowest gray level data, A first comparator for supplying an enable signal to the data selector; If the pixel data of the current frame and the pixel data of the previous frame are different, the enable signal of the high logic is supplied to the data selector, and if the pixel data of the current frame and the pixel data of the previous frame are the same, the row And a second comparator for supplying a logic enable signal to the data selector. The method according to claim 2 or 3, The data selector outputs the modulated data of the lookup table in response to the enable signal of the high logic, and selects and outputs pixel data of the current frame in response to the enable signal of the low logic. Driving device for liquid crystal display device. Comparing pixel data of a previous frame with pixel data of a current frame and storing preset modulation data in a look-up table according to the comparison result; Storing pixel data of the current frame in a frame memory; Determining whether the pixel data of the current frame is the highest gray level data or the lowest gray level data; And selecting one of the modulated data of the lookup table and the pixel data of the current frame by the data selector according to a result of the determination. The method of claim 5, Determining whether the pixel data of the current frame is the highest gray level data or the lowest gray level data Supplying an enable signal of a high logic to the data selector if the pixel data of the current frame is not the highest gray level data or the lowest gray level data; And supplying an enable signal of a low logic to the data selection unit if the pixel data of the current frame is the highest gray level data or the lowest gray level data. The method of claim 6, And determining whether the pixel data of the current frame and the pixel data of the previous frame are the same. The method of claim 7, wherein Determining whether the pixel data of the current frame and the pixel data of the previous frame are the same Supplying the high logic enable signal to the data selector if the pixel data of the current frame and the pixel data of the previous frame are different; And supplying the enable signal of the row logic to the data selector if the pixel data of the current frame and the pixel data of the previous frame are the same. The method of claim 6 or 8, According to the determination result, selecting and outputting any one of the modulation data of the lookup table and the pixel data of the current frame in the data selection unit Outputting the modulated data of the lookup table in response to the enable signal of the high logic, and selecting and outputting pixel data of the current frame in response to the enable signal of the low logic Driving method of liquid crystal display device.

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