KR100486232B1 - Row electrode line driving device of liquid crystal display device and driving method thereof - Google Patents

Abstract

Disclosed are a horizontal electrode line driving device of a liquid crystal display and a method thereof. The horizontal electrode line driving device includes a shift register section, a counter, a decoder section, and a driving section. The shift register unit includes a plurality of shift registers connected in series to shift the frame data signal in synchronization with a clock signal. The counter has a clock input terminal connected to an output terminal of the final shift register, a reset terminal connected to an inverted frame data signal terminal, and outputs a predetermined N bit selection signal by counting an output signal of the final shift register. The decoder unit includes decoder groups having decoders which are simultaneously driven as many as N powers of two connected to each of the shift registers, the decoder groups being interlaced with each other, The decoder groups are sequentially decoded in response to a selection signal. The driving unit selectively outputs a high voltage signal, a common voltage signal, and a low voltage signal of a predetermined level in response to an output signal of the decoder unit. In the horizontal electrode line driving apparatus, the voltage difference between adjacent horizontal electrode lines is reduced, so that the force of the liquid crystal molecules positioned between the horizontal electrode lines in the vertical direction with respect to the horizontal electrode lines is reduced, thereby reducing the image quality inhibiting factor.

Description

Low electrode line driving device of liquid crystal display device and driving method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a horizontal electrode line driving device and a method thereof of a liquid crystal display device, and more particularly, to a horizontal electrode line driving device applied to a MLS (Multiple Line Selection) method of driving a high speed response STN liquid crystal display device. And a horizontal electrode line driving method implemented in the driving apparatus.

The method of driving a high-speed response STN liquid crystal display device is largely divided into an MLS method and a multiple line addressing (MLA) method. For the MLS method, US Patent No. 5,262,881 and STN panel disclosed for driving a matrix type liquid crystal display device are described. Is discussed in detail in the SID 94 DIGEST (pp. 61 ~ 64) disclosed for the method of driving the liquid crystal display using the MLS method.

FIG. 1 is a view illustrating a horizontal electrode line driving method of a liquid crystal display device driven by a conventional MLS method. Referring to FIG. 1, in the conventional horizontal electrode line driving method using the MLS method, the upper horizontal electrode lines COM1, COM2, COM3, and COM4 are simultaneously driven and the lower horizontal electrode lines COM5, COM6, COM7, and COM8 are simultaneously driven. . On the other hand, the difference between the RMS (Root-Mean-Square) values of the voltages applied to the horizontal electrode lines (COM1, COM2, ..., COM8) and the vertical electrode lines (SEG1, SEG2, ..., SEG18) is the threshold voltage (Threshold). As the voltage is higher or lower than the value of Vth, the inversion of the liquid crystal molecules is determined, and thus the on or off of each pixel is determined. At this time, a high voltage (± 15 V) is applied to the horizontal electrode line and a lower voltage (± 3 V) is applied to the vertical electrode line. In this manner, as the pixels are turned on or off, a screen as shown is displayed.

However, according to the conventional MLS display method, the liquid crystal molecules positioned between the horizontal electrode lines are aligned vertically with respect to the horizontal electrode lines as the voltage difference between the adjacent horizontal electrode lines is applied as high as about 30 volts. There is a disadvantage that can be inhibited.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide a horizontal electrode line driving apparatus capable of reducing a quality deterioration factor by reducing a voltage difference between adjacent horizontal electrode lines.

Another object of the present invention is to provide a horizontal electrode line driving method implemented in the horizontal electrode line driving apparatus.

In order to achieve the above object, the horizontal electrode line driving apparatus of the liquid crystal display according to the present invention includes a shift register unit, a counter, a decoder unit, and a driving unit. The shift register unit includes a plurality of shift registers connected in series to shift the frame data signal in synchronization with a clock signal. The counter has a clock input terminal connected to an output terminal of the final shift register, a reset terminal connected to an inverted frame data signal terminal, and outputs a predetermined N bit selection signal by counting an output signal of the final shift register. The decoder unit includes decoder groups having decoders which are simultaneously driven as many as N powers of two connected to each of the shift registers, the decoder groups being interlaced with each other, The decoder groups are sequentially decoded in response to a selection signal. The driving unit selectively outputs a high voltage signal, a common voltage signal, and a low voltage signal of a predetermined level in response to an output signal of the decoder unit.

In addition, it is preferable to further include a voltage conversion means for inputting the frame data signal and the clock signal to the front end of the shift register unit to compare with a predetermined reference voltage and to convert to a voltage level required for the operation of the device.

In addition, the counter is a binary counter that outputs a 2-bit selection signal by performing 2-bit counting, and the decoder groups may be driven simultaneously by four decoders connected to an output terminal of each shift register.

The voltage converting means inputs the frame signal and the clock signal to compare the signals with a predetermined reference voltage, inputs an output of the voltage comparator, and shifts to a voltage level required to operate subsequent circuits. It is preferable to include a level shifter.

In addition, the high voltage signal, the common voltage signal, and the low voltage signal of the driving unit may be 15 volts, 0 volts, and -15 volts, respectively.

In order to achieve the above object, the horizontal electrode line driving method of the liquid crystal display device according to the present invention is a horizontal electrode line driving method of a liquid crystal display device using a multiple line selection method of simultaneously driving a plurality of horizontal electrode lines. A first step of shifting and outputting a frame data signal in accordance with the following steps; a second step of counting the frame data signal from the first step and outputting a predetermined N bit selection signal; Interlacing decoder groups each having a number of decoders simultaneously driven corresponding to N powers of 2 connected to each other and sequentially decoding the decoder groups in response to the selection signal of the second step. Step 3 and optionally predetermined according to the decoding result from the third step In that it comprises a fourth step of outputting a high voltage signal, a common voltage signal, and a low voltage signal level it is characterized.

The second step is a step of outputting a 2-bit selection signal by performing two-bit counting, and the third step is a step in which four decoders are connected and driven simultaneously to an output terminal of each shift register. Do.

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

2 is a view showing the structure of a horizontal electrode line driving apparatus according to an embodiment of the present invention. 2, the horizontal electrode line driving apparatus according to the present invention includes a voltage comparator 20, a level shifter 22, a shift register unit 24, a binary counter 26, a decoder unit 28, and a driver 29. ). The voltage comparator 20 has an input terminal connected to the first frame signal FRM terminal and the first clock signal CLK terminal, and the level shifter 22 has an input terminal connected to the output terminal of the voltage comparator 2. In the shift register section 24, the input terminal is front-end as the clock input terminal is connected to the second clock signal CLK_OUT terminal, for example, the input terminal of the shift register SR2 is connected to the output terminal of the shift register SR1. It consists of 60 shift registers SR1, SR2, ..., SR59, SR60 connected to the output register of the shift register. In the binary counter 26, the clock input terminal is connected to the output terminal of the 60th shift register SR60, and the inverted frame signal FRMB terminal is connected to the reset terminal. The decoder unit 28 includes first decoders DEC0 connected to the output terminals of the shift registers SR1, SR5, ..., SR53, SR57, and input terminals of the shift registers SR2, SR6, ..., SR54. The second decoders DEC1 connected to the output terminal of SR58, the third decoders DEC2 connected to the output terminal of the shift registers SR3, SR7, .. SR55, SR59, and each input terminal Fourth decoders DEC3 are connected to the output terminals of the shift registers SR4, SR8, .. SR56, SR60, and the control inputs of the respective decoders DEC0, DEC1, DEC2, and DEC3 are binary counters 26. Is connected to the select signals F0 and F1. In addition, the driving unit 29 has an input terminal connected to an output terminal of the decoder unit 28, and the driving voltage input terminal is a high voltage signal V _H , a common voltage signal V _C , and a low voltage signal V _L. Is connected to.

The operation of the horizontal electrode line driving device configured as described above will be described below. The voltage comparator 20 compares the signals with a predetermined reference voltage when the first frame signal FRM and the first clock signal CLK are input, and the level shifter 22 inputs the output of the voltage comparator 20. As a result, the second frame signal FRM_OUT and the second clock signal CLK_OUT are output by converting to a voltage level required to operate subsequent circuits, for example, ± 15 volts. That is, the input signal is converted to -15 volts when inputted to O volts and +15 volts when inputted to 5 volts to output the second frame signal FRM_OUT and the second clock signal CLK_OUT. The shift register unit 24 shifts and outputs the second frame signal FRM_OUT in synchronization with the second clock signal CLK_OUT. The binary counter 26 performs counting in response to the output signal of the 60th shift register SR60. The binary counter 26 outputs two bits of selection signals F0 and F1 as a result of the counting. The binary counter 26 is reset when the inverted frame signal FRMB is "low". The decoder unit 28 decodes and outputs the output signal of the shift register unit 24 in response to the selection signals F0 and F1 of the binary counter 26. In the case of the decoding combined by the 2-bit selection signals F0 and F1, the number is two squares, so four types of decoding selections are possible. That is, when the selection signal is N bits, the number becomes N powers of two in the case of combinable decoding. The driver 29 selectively outputs the high voltage signal V _H , the common voltage signal V _C , and the low voltage signal V _L in response to the output of the decoder 28 to drive the horizontal electrode line. The horizontal electrode driving signals COM1, COM2, ..., COM240 are generated. The horizontal electrode driving signals COM1, COM2, ..., COM240 are supplied to the horizontal electrode lines of the liquid crystal display (not shown).

As a result, the first frame signal FRM input to the voltage comparator 20 is shifted along each of the shift registers SR1, SR2, ..., SR59, SR60 in synchronization with the first clock signal CLK, and is a binary counter. 26 performs a binary counting operation in response to the output signal of the final shift register SR60. The selection signals F0 and F1 output from the binary counter 26 are input to the control input terminals of the decoders DEC0, DEC1, DEC2, and DEC3, so that the first decoders DEC0, the second decoders DEC1, The third decoders DEC2 and the fourth decoders DEC3 sequentially perform the decoding operation. The drivers DRVs connected to the output terminals of the decoders DEC0, DEC1, DEC2, and DEC3, which have performed the decoding operation in the driver 29, selectively respond to the output of the respective decoders with a high voltage signal V _H or a low voltage. The signal V _L is output, and the drivers DRVs connected to the output terminals of the remaining decoders output the common voltage signal V _C.

3 is a view illustrating a horizontal electrode line driving method implemented in the above-described horizontal electrode line driving apparatus. Referring to FIG. 3, a part of the liquid crystal display device driven by the horizontal electrode line driving apparatus according to the present invention has 18 vertical electrode driving signals SEG1, SEG2,... 16 horizontal electrode driving signals COM1, COM2, ..., COM15, and COM16 are connected to the horizontal electrodes.

2 and 3, the drivers DRVs connected to the decoders that perform the decoding operation output the high voltage signal V _H or the low voltage signal V _L and do not perform the decoding operation. The drivers DRV connected to the output the common voltage signal V _C. For example, when the first decoder DEC0 performs the decoding operation, the corresponding driver DRV is simultaneously driven so that the horizontal electrode driving signals COM1, COM5, COM9, and COM13 are connected to the high voltage signal V _H or the low voltage. The signal V _L is output, and the remaining horizontal electrode driving signals COM2, COM3, COM4, COM6,..., COM15, and COM16 stages output the common voltage signal V _C. Meanwhile, as the difference between the RMS values of the voltages applied to the horizontal electrode lines COM1, COM2, ..., COM15, COM16 and the vertical electrode lines SEG1, SEG2, ..., SEG18 is higher or lower than the threshold voltage value. The inversion of the liquid crystal molecules is determined and thereby the on or off of each pixel is determined. In this case, as the first decoder DEC0, the second decoder DEC1, the third decoder DEC2, and the fourth decoder DEC3 sequentially perform decoding operations, one screen as shown in FIG. Is displayed.

The horizontal electrode line driving apparatus and the driving method thereof according to the present invention as described above, when the horizontal electrode driving signal decoded by the decoder is a high voltage signal (V _H ) or a low voltage signal (V _L ), the remaining horizontal electrode driving signal Since the common voltage signal V _C becomes, for example, assuming that the horizontal electrode lines are driven at a ± 15 volt level, the voltage difference between adjacent horizontal electrode lines does not become 30 volts, and is lowered to about 15 volts.

In the above-described embodiment, a horizontal electrode line driving device for simultaneously driving four horizontal selection electrode lines at intervals of three lines between the electrode lines is described as an example. However, as will be appreciated by those skilled in the art, the present invention can be modified and appropriately implemented to simultaneously drive more or less horizontal selection electrode lines, and thus the scope of the present invention is not limited to the above-described embodiments. It should be understood that.

As described above, in the horizontal electrode line driving apparatus according to the present invention, since the voltage difference between adjacent horizontal electrode lines is reduced to about 15 volts, the liquid crystal molecules positioned between the horizontal electrode lines are less aligned in the vertical direction with respect to the horizontal electrode lines. Inhibitors can be reduced.

1 is a view for explaining a horizontal electrode line driving method of a liquid crystal display device driven by a conventional MLS method.

2 is a view showing the structure of a horizontal electrode line driving apparatus according to an embodiment of the present invention.

3 is a view illustrating a horizontal electrode line driving method implemented in a horizontal electrode line driving apparatus according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

20 ... voltage comparator, 22 ... level shifter,

24 ... shift register part, 26 ... binary counter,

28 decoder unit, 29 drive unit,

SR1, SR2, ..., SR60 ... shift register,

DEC0, DEC1, DEC2, DEC3 ... decoder, DRV ... driver,

FRM ... first frame signal, CLK ... first clock signal,

FRM_OUT ... second frame signal, CLK_OUT ... second clock signal,

V _H ... high voltage signal, V _C ... common voltage signal,

V _{L ...} low voltage signal,

COM1, COM2, ..., COM239, COM240 ... Strand electrode drive signal.

Claims (7)

In a horizontal electrode line driving apparatus of a liquid crystal display device using a multiple line selection method of simultaneously driving a plurality of horizontal electrode lines, A shift register unit comprising a plurality of shift registers connected in series to shift a frame data signal in synchronization with a clock signal; A counter connected to an output terminal of a final shift register, a reset terminal connected to an inverted frame data signal terminal, and a counter for counting an output signal of the final shift register and outputting a predetermined N bit selection signal; And decoder groups having decoders that are simultaneously driven as many as N powers of two connected to each of the shift registers, wherein the decoder groups are interlaced with each other and in response to the selection signal of the counter. A decoder to sequentially decode the decoder groups in response; And And a driving unit for selectively outputting a high voltage signal, a common voltage signal, and a low voltage signal of a predetermined level in response to an output signal of the decoder unit. 2. The apparatus of claim 1, further comprising voltage conversion means for inputting the frame data signal and the clock signal to a front end of the shift register part to compare the frame data signal with a predetermined reference voltage and convert the frame data signal to a voltage level required for operation of the apparatus. Horizontal electrode line driving device. The counter of claim 1, wherein the counter is a binary counter that outputs a 2-bit selection signal by performing 2-bit counting, and the decoder groups are simultaneously driven by four decoders connected to an output terminal of each shift register. Horizontal electrode line drive device. The method of claim 2, wherein the voltage conversion means, A voltage comparator for inputting the frame signal and a clock signal to compare the signals with a predetermined reference voltage; And And a level shifter for inputting an output of the voltage comparator and shifting the circuits to voltage levels required to operate subsequent circuits. The horizontal electrode line driving apparatus of claim 1, wherein the high voltage signal, the common voltage signal, and the low voltage signal are 15 volts, 0 volts, and −15 volts, respectively. A horizontal electrode line driving method of a liquid crystal display device using a multiple line selection method of simultaneously driving a plurality of horizontal electrode lines, A first step of shifting and outputting the frame data signal in synchronization with a clock signal; A second step of counting the frame data signal from the first step and outputting a predetermined N bit selection signal; The decoder groups each having a plurality of decoders that are simultaneously driven corresponding to the N-th power of 2 connected to each of the shift registers are interlaced with each other, and the decoder is in response to the selection signal of the second step. A third step of sequentially decoding the groups; And And a fourth step of selectively outputting a high voltage signal, a common voltage signal, and a low voltage signal of a predetermined level according to the decoding result from the third step. 7. The method of claim 6, wherein the second step is a step of outputting a two-bit selection signal by performing two-bit counting, and the third step is driven by four decoders connected to an output terminal of each shift register. A horizontal electrode line driving method, characterized in that the step.