KR100278660B1 - Data driver for thin film transistor type liquid crystal display and operation method thereof - Google Patents

Abstract

Disclosed are a data driving device and a method of operating the same for a thin film transistor type liquid crystal display capable of minimizing errors in color signals due to different output characteristics for each driver stage by passing pixels of the same color adjacent to each other through the same driver stage. Each of the first, second and third high voltage outputs constituted by a combination of these devices determines one of the high voltages having a gray level of 2 ^X corresponding to the X bit first digital data and outputs the determined voltage. Each of the first, second and third low voltage outputs determines one of the low voltages having a gray level of 2 ^X corresponding to the second digital data of X bits, and outputs the determined voltage. In response to the polarity signal, the output of the first high voltage output unit or the output of the first low voltage output unit is output as a signal for controlling a red (R: red) pixel on the first dot or the second dot, and the second selector is the polarity. In response to the signal, the output of the second high voltage output unit or the output of the second low voltage output unit is output as a signal for controlling the green (G) pixel on the first dot or the second dot, and the third selector is a polarity signal. Third high voltage output in response to Characterized in that the output as a signal for controlling: (Blue B) pixels of the output or third output low voltage output of blue to the first dots or the second dots.

Description

Data driving device for thin film transistor type liquid crystal display and operating method thereof

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thin film transistor type liquid crystal display driving device, and more particularly, to an integrated data driving device for a thin film transistor type liquid crystal display and a method of operating the same.

In general, a thin film transistor (TFT) liquid crystal display (LCD) includes a gate driver and a data driver. The gate driver drives the gate lines of the liquid crystal panel, and the data driver drives the 'column lines' (or 'pixel lines') of the liquid crystal panel. Here, the data driver is composed of a plurality of integrated data driving devices, each driving a predetermined number of pixel lines in the liquid crystal panel. Such a conventional integrated data driving device is disclosed, for example, in US Pat. No. US5754156.

In the case of a dot inversion scheme, an output terminal of a conventional data driving apparatus includes two channels, that is, an R channel and a green pixel that output a signal for driving a red pixel. The G channel for outputting a signal for driving, the B channel for driving the G channel and the blue pixel (B) or the B channel and the R channel shared one driving circuit. In this case, when the entire screen is expressed in a single color, there may be a problem that the brightness of neighboring R, G and / or B pixels may be incorrect, or the screen may flicker. This means that when the entire screen is represented in a single color, there is an error between a signal for driving an R, G or B pixel in one dot and a signal for driving an R, G or B pixel in a neighboring dot adjacent to the dot. Because it exists.

An object of the present invention is to provide a thin film transistor type liquid crystal display capable of minimizing an error between signals for driving pixels (R, G, or B) of the same color adjacent to each other when the screen is expressed in a single color. To provide a data drive device for.

Another object of the present invention is to provide a method of operating a data driving device for the thin film transistor type liquid crystal display.

1 is a block diagram of a preferred embodiment of the present invention of a data driving apparatus for a TFT-LCD according to the present invention.

FIG. 2 is a flowchart for explaining a data driving method for a TFT-LCD according to the present invention performed in the apparatus shown in FIG.

In order to achieve the above object, a data driving device according to the present invention for driving corresponding pixel lines of a thin film transistor type liquid crystal display is characterized in that one of the high voltages each having a gray level of 2 ^X is X-bit first digital data. First, second and third high voltage output means for determining corresponding to and outputting the determined voltage, each of the low voltages having a gray level of 2 ^X corresponding to the second bit of X digital data. First, second and third low voltage output means for determining and outputting the determined voltage, and the output of the first high voltage output means or the output of the first low voltage output means in response to a polarity signal; Output as a signal for controlling a red (R: Red) pixel, or outputting the output of the first high voltage output means or the output of the first low voltage output means to the first dot in response to the polarity signal. First selecting means for outputting an R pixel to an adjacent second dot as a signal for controlling the R pixel; and outputting the output of the second high voltage output means or the output of the second low voltage output means in response to the polarity signal. Output as a signal for controlling a green pixel (G: Green) in one dot, or output the output of the second high voltage output means or the output of the second low voltage output means to the second dot in response to the polarity signal. Second outputting means for outputting a G pixel as a signal for controlling the pixel and an output of the third high voltage output means or an output of the third low voltage output means in response to the polarity signal blue (B: Blue) outputs as a signal for controlling a pixel or outputs the output of the third high voltage output means or the output of the third low voltage output means in response to the polarity signal to the second dot. A third selecting means for outputting a signal for controlling is preferably configured in combination.

In order to achieve the above another object, the operation method according to the present invention of the data driving device for driving the corresponding pixel lines of the thin film transistor type liquid crystal display, one of the high voltage having a gray scale of 2 ^X X digital first bit Determining corresponding to the data, determining one of the low voltages having a gray level of 2 ^X corresponding to the second digital data of X bits, and determining whether the polarity of the column to which the pixel to be driven belongs is negative or positive. And if the polarity is positive, determine the determined high voltage as a signal for controlling the corresponding pixel in the first dot, and control the corresponding pixel in the second dot adjacent to the first dot. Determining as a signal to control and for controlling the corresponding pixel at the first dot when the determined low voltage is negative. Determining a call, it comprises a high voltage determined by the step of determining a signal for controlling the corresponding pixel to the second dot, the pixels that are preferably red, green or blue pixel.

Alternatively, the data driving method for a TFT-LCD according to the present invention, the operation method according to the invention of the data driving device for driving the pixel lines of the liquid crystal display thin film transistor-type, of the high voltage having a gray level of 2 ^X Determining one corresponding to the first digital data of X bits, and determining one of the low voltages having a gray level of 2 ^X corresponding to the second digital data of X bits, and a column adjacent to the pixel to be driven. determining whether the polarity of the column and the row is negative or positive; if the polarity is negative, determining the determined high voltage as a signal for controlling the corresponding pixel in the first dot, and determining the determined low voltage Is determined as a signal for controlling a corresponding pixel in a second dot adjacent to the first dot, and when the polarity is positive, the determined low voltage Determining as a signal for controlling a corresponding pixel in one dot, and determining the determined high voltage as a signal for controlling a corresponding pixel in the second dot, wherein the corresponding pixel is red, green, or blue. It is preferably a pixel.

Hereinafter, the configuration and operation of a data driving apparatus for a thin film transistor type liquid crystal display (TFT-LCD) according to the present invention will be described with reference to the accompanying drawings.

1 is a block diagram of a preferred embodiment of a data driving apparatus for a TFT-LCD according to the present invention, which includes a shift register 10, first and second latches 12 and 14, first, Second, third, ..., and second Selectors 20, 22, 24, ... and 26, first, second, third, ..., and High voltage outputs 30, 34, 38, ... and 42, first, second, third, ..., and Low voltage outputs 32, 36, 40, ... and 44, +1, first +2, first +3,... And K-th selectors 100, 102, 104,... And 106.

Each of the high and low voltage outputs shown in FIG. 1 consists of a digital / analog converter and a buffer. That is, the first high voltage output unit 30 is composed of a first digital to analog converter (DAC) 60 and a first buffer 62, and the second high voltage output unit 34 is The third high voltage output unit 38 includes a third DAC 68 and a third buffer 70, and the third high voltage output unit 38 includes a fifth DAC 76 and a fifth buffer 78. The high voltage output unit 42 is composed of a K-1 DAC 84 and a K-1 buffer 86. Similarly, the first low voltage output unit 32 is composed of a second DAC 64 and a second buffer 66, and the second low voltage output unit 36 is composed of a fourth DAC 72 and a fourth buffer ( 74, the third low voltage output unit 40 is composed of a sixth DAC 80 and a sixth buffer 82, and The low voltage output section 44 is composed of a K-th DAC 88 and a K-th buffer 90.

The shift register 10 shown in FIG. 1 starts the shifting operation in response to the first clock signal CK1 and the carry input Ci input from the previous data driving device. At this time, the shift register 10 shifts to the right or left in response to the left / right control signal SHL. At this time, the shift register 10 sequentially outputs one bit from the shifted result to the first latch 12 as a shifting clock signal. After the shifting ends, the shift register 10 outputs a carry output Co as a carry input of the next data driving device.

Meanwhile, the first latch 12 inputs X bits of digital data through the input terminal IN in response to the shifting clock signal output from the shift register 10. Here, the first latch 12 latches as many X bits of digital data as K (where K represents the total number of column lines that the data driving apparatus shown in FIG. 1 can drive). Therefore, the first clock signal CK1 After the period, K digital data, each of which is X bits, are latched in the first latch 12.

The second latch 14 receives the first, second, third, ..., and K-bit digital data latched in the first latch 12 in response to the second clock signal CK2 by 2X bits. My Output to selectors 20, 22, 24, ... and 26, respectively. Here, the second clock signal CK2 is a signal simultaneously applied to a plurality of data driving devices existing in the data driver (not shown).

First, second, third, ... and first M (1≤M≤) which is one of the selectors 20, 22, 24, ... and 26 The selector divides 2X bits of digital data output from the second latch 14 into first and second digital data, each of which is X bits, in response to a polarity signal POL, and separates the first and second digital data. Output the data to the Mth high and low voltage outputs, respectively. Here, the polarity signal POL is a signal for determining the polarity of the signals Y ₁ to Y _K to be described later.

However, unlike the one shown in Fig. 1, the first to the first The selectors 20, 22, 24,... And 26 may be provided between the first latch 12 and the second latch 14. In this case, the first to the first The M-th selector, which is one of the selectors, separates 2X bits of digital data input from the first latch 12 into first and second digital data, each of which is X bits, in response to the polarity signal POL. The first and second digital data to the M-th high and low voltage outputs through the second latch 14.

On the other hand, the first to the first of the data driving apparatus for TFT-LCD according to the present invention N (1≤N≤), which is one of the high voltage outputs 30, 34, 38, ..., and 42 The high voltage output unit determines one of the high voltages having a gray scale of 2 ^X corresponding to the first digital data of X bits, and removes the determined voltage. Output to + N selector. To this end, the Nth high voltage output unit includes a DAC that determines one of 2 ^X kinds of high voltages corresponding to the first digital data of X bits, and a buffer that increases and outputs the driving capability of the high voltage determined in the DAC. Can be.

Similarly, first to first N (1≤N≤), which is one of the low voltage outputs 32, 36, 40, ..., and 44 The low voltage output determines one of the low voltages having a gray scale of 2 ^X corresponding to the second digital data of X bits and removes the determined voltage. Output to + N selector. To this end, the Nth low voltage output unit includes a DAC that determines one of 2 ^X kinds of low voltages corresponding to the second digital data of X bits, and a buffer that increases and outputs the driving capability of the low voltage determined by the DAC. Can be.

For example, when the level of the voltage driving the pixels of the liquid crystal panel varies from '0' to '10' volts, the high voltage output unit 30, 34, 38, ... or 42 is '6' Select one of the voltages from 'volts to' 10 'volts in response to the first digital data of X bits, and output the selected voltage to the corresponding selector (100, 102, 104, ... or 106) The low voltage outputs 32, 36, 40, ... or 44 select one of the voltages from '0' to '5' in response to the second digital data of X bits, Is output to the corresponding selection unit (100, 102, 104, ... or 106).

Meanwhile, The +1 selector 100 red (R: Red) the output of the first high voltage output unit 30 or the output of the first low voltage output unit 32 to the first dot in response to the polarity signal POL. Output as a signal Y ₁ for controlling the pixel, or output the output of the first high voltage output unit 30 or the output of the first low voltage output unit 32 to the first dot in response to the polarity signal POL. and it outputs a signal (Y ₄₎ for controlling the R-pixel in the second neighboring dots. Similarly, my The +2 selector 102 draws the output of the second high voltage output unit 34 or the output of the second low voltage output unit 36 on the first dot in response to the polarity signal POL (G: Green). Output as a signal Y ₂ for controlling the pixel, or output the output of the second high voltage output section 34 or the output of the second low voltage output section 36 to the second dot in response to the polarity signal POL. The signal is output as a signal Y ₅ for controlling the G pixel. My The +3 selector 104 blues the output of the third high voltage output unit 38 or the output of the third low voltage output unit 40 to the first dot in response to the polarity signal POL. Output as a signal Y ₃ for controlling the pixel or output the output of the third high voltage output unit 38 or the output of the third low voltage output unit 40 to the second dot in response to the polarity signal POL. B, and outputs a signal (Y ₆₎ for controlling the pixels. The above-described high voltage output unit may be designed to have good output characteristics for high voltages, and the low voltage output unit may be designed to have good output characteristics for low voltages.

By the above-described operation, the data driving apparatus according to the present invention shown in FIG. 1 generates signals (or channels) Y ₁ , Y ₂ , Y ₃ , Y ₄ , and Y pixel lines existing in the liquid crystal panel. ₅ , Y ₆ , ..., Y _K-3 , Y _K-2 , Y _K-1 and Y _K ).

Hereinafter, an operation method of a data driving apparatus for a TFT-LCD according to the present invention will be described with reference to the accompanying drawings.

FIG. 2 is a flowchart for explaining a data driving method for a TFT-LCD according to the present invention performed in the apparatus shown in FIG. 1, in which low and high voltages are determined in response to digital data (step 200). ), And determining the channel according to the polarity of the pixel to drive the determined voltages (steps 202 to 206).

Referring to FIG. 2, first, first, second, third, ..., and first of the data driving apparatus shown in FIG. Each of the high voltage outputs 30, 34, 38, ..., and 42 determines one of the high voltages having a gray level of 2 ^X in correspondence with the first digital data of X bits, and the first, second, Third, ..., and third Each of the low voltage outputs 32, 36, 40, ..., and 44 determines one of the low voltages having a gray level of 2 ^X corresponding to the X bit second digital data (step 200). After operation 200, when the apparatus illustrated in FIG. 1 is applied to the column inversion scheme, it is determined whether the polarity of the column to which the pixel to be driven belongs is negative or positive, and when applied to the dot inversion scheme, the column adjacent to the pixel for driving is applied. It is determined whether the polarity of the column and the row is negative or positive (step 202). That is, the data driving apparatus according to the present invention, which can be applied to both the column inversion method and the dot inversion method, determines whether the pixel polarity for driving is positive or negative. At this time, as previously assumed, assuming that the levels of the signals Y ₁ to Y _K for controlling the pixel vary from '0' to '10' volts, '0' to '5' The voltage between volts corresponds to negative polarity, and the voltage between '6' and '10' volts corresponds to positive polarity.

If the polarity of the pixel is positive, the high voltage determined at the high voltage output unit is determined as a signal for controlling the corresponding pixel at the first dot, that is, the R, G or B pixel, and the low voltage determined at the low voltage output unit. Is determined as a signal for controlling the corresponding pixel in the second dot adjacent to the first dot, that is, the R, G or B pixel (step 204). However, when the polarity of the pixel is negative, the low voltage determined at the low voltage output unit is determined as a signal for controlling the corresponding pixel at the first dot, that is, the R, G or B pixel, and the high voltage determined at the high voltage output unit. Is determined as a signal for controlling the corresponding pixel in the second dot, that is, the R, G or B pixel (step 206).

As a result, the conventional data driving apparatus, while the channels, i.e., Y1 and Y2, Y3 and Y4 or Y5 and Y6, share the same high and low voltage outputs, the data driving apparatus for the TFT-LCD according to the present invention described above. And in its operation method, it can be seen that the channels, that is, Y1 and Y4, Y2 and Y5 or Y3 and Y6 share the same voltage output.

As described above, the data driving apparatus for the thin film transistor type liquid crystal display and the operation method thereof according to the present invention have two colors, namely, when an error exists in one high or low voltage output. An error is generated in R and G, G and B or B and Gs, while an error is generated only in one color such as R, G or B, further improving the image quality in comparison with the conventional driving device. That is, the data driving apparatus according to the present invention improves image quality over the conventional apparatus which alternately displays errors in two colors because the errors are displayed by skipping one by one in the same color channel when an error exists in the shared voltage output unit. You can. Therefore, when the screen is displayed in a single color, there is an effect that can reduce the likelihood of a screen defect, that is, flicker or brightness defect by about 50% due to an output deviation that may occur due to a slight difference between channels.

Claims (7)

A data driving device for driving corresponding pixel lines of a thin film transistor type liquid crystal display (TFT-LCD), First, second, and third high voltage output means each of which determines one of the high voltages having a gray level of 2 ^X corresponding to the first digital data of X bits and outputs the determined voltage; First, second and third low voltage output means each of which determines one of the low voltages having a gray level of 2 ^X corresponding to the X digital second data and outputs the determined voltage; Outputting the output of the first high voltage output means or the output of the first low voltage output means as a signal for controlling a red (R: Red) pixel on a first dot in response to the polarity signal, or in response to the polarity signal; First selecting means for outputting the output of the first high voltage output means or the output of the first low voltage output means as a signal for controlling an R pixel to a second dot adjacent to the first dot; Outputting the output of the second high voltage output means or the output of the second low voltage output means as a signal for controlling a green pixel (G) on the first dot in response to the polarity signal, or the polarity signal Second selecting means for outputting the output of the second high voltage output means or the output of the second low voltage output means in response to the second dot as a signal for controlling a G pixel; And Outputting the output of the third high voltage output means or the output of the third low voltage output means as a signal for controlling a blue pixel on the first dot in response to the polarity signal, or the polarity signal In response to the third selecting means for outputting the output of the third high voltage output means or the output of the third low voltage output means to the second dot as a signal for controlling a B pixel. And a data driving device for a TFT-LCD. The method of claim 1, wherein the first, the second or the third high voltage output means A first digital to analog converter for determining one of the high voltages corresponding to the first digital data; And And a first buffer for increasing the driving capability of the voltage determined by the first digital to analog converter and outputting the first buffer. 3. The apparatus of claim 2, wherein the first, second or third low voltage output means A second digital to analog converter for determining one of the low voltages corresponding to the second digital data; And And a second buffer for increasing and outputting a driving capability of the voltage determined by the second digital to analog converter. The driving device for the TFT-LCD according to claim 1, wherein A shift register that shifts in response to the carry input and the first clock signal and outputs the shifted result as a shifting clock signal; A first latch configured to latch K (where K is the number of pixel lines) digital data input in response to the shifting clock signal; A second latch configured to output digital data latched in the first latch in response to a second clock signal; And Each of the digital data output from the second latch is separated into the first and second digital data in response to the polarity signal, and the separated first and second digital data are separated from the first and the second data. And fourth, fifth and sixth selection means for outputting to the second and third high and low voltage output means, respectively. The driving device for the TFT-LCD according to claim 1, wherein A shifting register for shifting in response to the carry input and the first clock signal and outputting the shifted result as a shifting clock signal; A first latch configured to latch K (where K is the number of pixel lines) digital data input in response to the shifting clock signal; Fourth, fifth, and sixth selection means, respectively, for separating the digital data output from the first latch into first and second digital data in response to the polarity signal; And Outputting the first, second and third high and low voltages in response to a second clock signal for the first and second digital data inputted and latched from the fourth, fifth and sixth selection means; And a second latch for outputting to the means, respectively. A method of operating a data driving device for driving corresponding pixel lines of a thin film transistor type liquid crystal display (TFT-LCD), Determining one of the high voltages having a gray level of 2 ^X corresponding to the first digital data of X bits, and determining the one of the low voltages having a gray level of 2 ^X corresponding to the second digital data of X bits. ; Determining whether the polarity of the column to which the pixel for driving belongs is negative or positive; When the polarity is positive, the determined high voltage is determined as a signal for controlling the corresponding pixel in the first dot, and the determined low voltage is used as a signal for controlling the corresponding pixel in the second dot adjacent to the first dot. Determining; And If the polarity is negative, determining the determined low voltage as a signal for controlling the corresponding pixel in the first dot and determining the determined high voltage as a signal for controlling the corresponding pixel in the second dot. and, And the corresponding pixel is a red, green or blue pixel. A method of operating a data driving device for driving corresponding pixel lines of a thin film transistor type liquid crystal display (TFT-LCD), Determining one of the high voltages having a gray level of 2 ^X corresponding to the first digital data of X bits, and determining the one of the low voltages having a gray level of 2 ^X corresponding to the second digital data of X bits. ; Determining whether the polarity of a column and a row adjacent to a pixel for driving is negative or positive; When the polarity is negative, the determined high voltage is determined as a signal for controlling the corresponding pixel in the first dot, and the determined low voltage is used as a signal for controlling the corresponding pixel in the second dot adjacent to the first dot. Determining; And If the polarity is positive, determining the determined low voltage as a signal for controlling the corresponding pixel in the first dot, and determining the determined high voltage as a signal for controlling the corresponding pixel in the second dot. and, And the corresponding pixel is a red, green or blue pixel.