KR20020046601A - Method of Driving Liquid Crystal Panel in 2-Dot Inversion and Apparatus thereof - Google Patents

Abstract

PURPOSE: A method and an apparatus for driving an LCD panel by using a 2-dot inversion method are provided to enhance image quality by using the 2-dot inversion method to drive the LCD panel. CONSTITUTION: A gate drive IC(12) is used for driving a multitude of gate lines(GL1 to GLn) on an LCD panel(10). A source drive IC(14) is used for driving a multitude of source lines(SL1 to SLm). The source lines(SL1 to SLm) cross each other. The LCD panel(10) has pixels arranged on each region which is divided by the gate lines(GL1 to GLn) and the source lines(SL1 to SLm). The pixels(PE) have a liquid crystal cell(CLC) for controlling the amount of transmitting light in response to a data signal and a TFT(Thin Film Transistor) for connecting selectively a source line(SL) with the liquid crystal cell(CLC) in response to a gate signal on a gate line(GL).

Description

A method of driving a 2-dot inversion liquid crystal panel and a device therefor {Method of Driving Liquid Crystal Panel in 2-Dot Inversion and Apparatus}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technique for driving a liquid crystal panel in a liquid crystal display device, and more particularly, to a liquid crystal panel driving method and apparatus for driving a liquid crystal panel in a 2-dot inversion system.

A typical liquid crystal display device displays an image corresponding to a video signal by adjusting the light transmittance of liquid crystal cells on a liquid crystal panel. In such a liquid crystal display, a line inversion system, a column inversion system, a dot inversion system, and a 2-dot inversion method are used to drive liquid crystal cells on a liquid crystal panel. And four driving methods of the Group Inversion System. In the two-dot inversion type liquid crystal panel driving method, the polarities of the data signals supplied to the liquid crystal panel are as shown in Figs. 1A and 1B. In other words, the data lines are inverted for each data line and frame. In other words, in the two-dot inversion type liquid crystal panel driving method, the polarities of the data signals supplied to the liquid crystal panel are inverted every data line and two gate lines on the liquid crystal panel and every frame. In the 2-dot inversion type liquid crystal panel driving method, a polarity control signal supplied to a data driver integrated circuit chip (hereinafter, referred to as a "D-IC chip") is shown in FIGS. 2A and 2B. As shown in FIG. 2, the inversion occurs every two horizontal synchronization periods. In addition, the polarity control signal is inverted for each frame.

In fact, when 31 gray level data and 0 gray level data are displayed alternately in both the horizontal and vertical directions (sub dot pattern), the polarity of the data signal supplied to each pixel on the liquid crystal panel is shown in FIGS. 3A and 3B. As shown in FIG. 6, the frame is inverted for each frame. In addition, the polarities of the 31 gray level data and the 0 gray level data alternated with each other in both the vertical and horizontal directions have polarities opposite to each other in the horizontal direction. In other words, 31 gray level data always have the same polarity in the horizontal direction. On the other hand, the 31 gray level data and the 0 gray level data have polarities that are repeatedly inverted in two horizontal synchronization periods in the vertical direction.

As described above, the liquid crystal panel driving method of the 2-dot inversion method in which the polarity of the data signal is inverted every two horizontal synchronizing periods is as compared to the liquid crystal panel driving method of the dot inversion method in which the polarity of the data signals is inverted every horizontal synchronizing period. The polarity interval of the data signal is doubled. In other words, the two-dot inversion type liquid crystal panel driving method causes visual amplification to occur as the frame progresses compared to the dot inversion type liquid crystal panel driving method. Therefore, in the image displayed by the liquid crystal panel driving method of the two-dot inversion method, when the same data signal is repeated to have the same polarity, wave noise due to the movement of the human eye appears. As a result, the image quality of the image displayed by the two-dot inversion liquid crystal panel driving method is degraded.

Accordingly, an object of the present invention is to provide a method and apparatus for driving a liquid crystal panel of a two-inversion method suitable for improving the image quality of an image.

1A and 1B are diagrams showing polar patterns of data signals supplied to liquid crystal cells of a liquid crystal panel by a conventional two-dot inversion liquid crystal panel driving method.

2A and 2B show waveforms of a polarity control signal supplied to a source driving IC chip of a liquid crystal panel by a conventional two-dot inversion liquid crystal panel driving method.

3A and 3B show polarity patterns in a liquid crystal panel when the liquid crystal panel is driven by alternately shifting the 31 and 0 gray level data signals in both the horizontal and vertical directions by the conventional 2-dot inversion liquid crystal panel driving method. Drawings showing.

4A to 4D are diagrams illustrating polar patterns of data signals supplied to liquid crystal cells of a liquid crystal panel by a two-dot inversion liquid crystal panel driving method according to an exemplary embodiment of the present invention.

FIG. 5 is a view schematically showing a two-dot inversion liquid crystal panel driving apparatus according to an embodiment of the present invention. FIG.

6A to 6D are diagrams showing waveforms of polarity control signals supplied to the source driving-IC chip of the two-dot inversion type liquid crystal panel driving apparatus of FIG.

7A to 7D illustrate liquid crystal panels in which the 31 and 0 gray level data signals are alternately driven in both the horizontal and vertical directions by a 2-dot inversion liquid crystal panel driving method according to an exemplary embodiment of the present invention. A diagram showing the polar pattern in the panel.

<Description of Symbols for Main Parts of Drawings>

10 liquid crystal panel 12 gate drive IC chip

14: Source Drive-IC Chip

In order to achieve the above object, the liquid crystal panel driving method of the 2-dot inversion method according to the present invention is: supplied to the odd-numbered pixels on the 4i-3, 4i-2, 4i-1 and 4i gate line of the liquid crystal panel The data signals are supplied with voltages of "+", "+", "-" and "-" and data signals supplied to the even-th pixels on the 4i-3, 4i-2, 4i-1 and 4i gate lines. Driving to have voltages of ","-"," + "and" + ", respectively; The data signals supplied to the odd pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel display voltages of "+", "-", "-", and "+" and 4i-. Driving the data signals supplied to the superior pixels on the 3, 4i-2, 4i-1 and 4i gate lines to have voltages of "-", "+", "+" and "-", respectively; The data signals supplied to the odd pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel display voltages of "-", "+", "+", and "-" and 4i-. Driving the data signals supplied to even-numbered pixels on the 3, 4i-2, 4i-1, and 4i gate lines to have voltages of "+", "-", "-", and "+", respectively; And data signals supplied to the odd-numbered pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel, and the voltages of "-", "-", "+" and "+" and 4i. Driving the data signals supplied to the even-numbered pixels on the -3, 4i-2, 4i-1, and 4i gate lines to have voltages of "+", "+", "-", and "-", respectively. It is characterized by including.

According to an aspect of the present invention, there is provided a liquid crystal panel driving apparatus comprising: a liquid crystal panel having liquid crystal pixel cells positioned at respective gate lines and gate lines crossing each other; Gate driving means for sequentially driving gate lines; Radix liquid crystals on gate lines 4i-3, 4i-2, 4i-1 and 4i of the liquid crystal panel in response to polarity control signals having phases of 0 °, -90 °, -270 ° and 180 ° as the frame proceeds. The source lines of the liquid crystal panel are arranged so that the pixel cells have different polar patterns and the even-numbered liquid crystal pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel have different polar patterns. And a source driving means for driving.

Other objects and advantages of the present invention in addition to the above objects will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 4 to 7.

4A to 4D schematically illustrate a liquid crystal panel driving method of a two-dot inversion method according to an exemplary embodiment of the present invention. 4A to 4D show polarities of data signals supplied to liquid crystal pixels on a liquid crystal panel in each of the first to fourth frames. 4A to 4D, data signals supplied to liquid crystal pixels have polarities that are inverted for each column line. In addition, the data signals supplied to the liquid crystal pixels have voltages of a polarity repeatedly inverted every two row lines from the first or second row lines. In other words, the data signals supplied to the liquid crystal pixels on the liquid crystal panel have a polarity change pattern repeated in four frame periods.

During the first frame period, as shown in FIG. 4A, the positive (+) and negative (-) data signals alternately appear from the left liquid crystal pixel to the right liquid crystal pixel. In addition, data signals supplied to the liquid crystal pixels on the first to last row lines of the liquid crystal panel are positive (+) to negative (-) and negative to (-) polarities every two row lines. It has a voltage of polarity which is repeatedly inverted to (+). Furthermore, positive data signals are applied to the first liquid crystal pixels of the first and second low lines. As a result, the odd-numbered (+) data signal, the positive (+) data signal, and the negative polarity are present in the odd-numbered liquid crystal pixels on the 4i-3rd, 4i-2nd, 4i-1th, and 4ith rowlines. The negative data signal and the negative data signal are supplied, respectively, and the even-numbered liquid crystal pixels on the 4i-3, 4i-2, 4i-1, and 4i lolines are provided with negative polarity ( Data signal of-), data signal of negative (-), data signal of positive (+) and data signal of positive (+) are respectively applied.

4B shows the polarity of the data signals supplied to the liquid crystal pixels in the third frame period. Referring to FIG. 4B, data signals of positive (+) and negative (-) appear alternately as the display proceeds from the left liquid crystal pixel to the right liquid crystal pixel. The data signals supplied to the liquid crystal pixels on the second to last row lines of the liquid crystal panel are negative polarity (-) to positive polarity (+) and negative polarity (−) per two row lines. It has a voltage of reverse polarity. In addition, the data signals supplied to the liquid crystal pixels on the first low line are repeatedly inverted from the positive (+) to the negative (-) and from the negative (-) to the positive (+) for each column line. Has a voltage. Furthermore, positive data signals and negative data signals are applied to the first liquid crystal pixels of the first and second low lines. As a result, the odd-numbered liquid crystal pixels on the 4i-3rd, 4i-2nd, 4i-1th and 4ith rowlines have a positive data signal, a negative data signal, and a negative polarity. A negative data signal and a positive data signal are supplied, respectively, and the even-numbered liquid crystal pixels on the 4i-3, 4i-2, 4i-1, and 4i low lines are provided with negative polarity ( Data signal of-), data signal of positive polarity (+), data signal of positive polarity (+) and data signal of negative polarity (-) are respectively applied.

4C shows the polarity of the data signals supplied to the liquid crystal pixels in the second frame period. Referring to FIG. 4C, the data signals supplied to the liquid crystal pixels on the liquid crystal panel have voltages of polarities repeatedly inverted for each column line. The data signals supplied to the liquid crystal pixels located on the left side of the second to last row lines of the liquid crystal panel are positive (+) to negative (-) and negative (-) for every two row lines. It has a voltage of polarity reversed to positive polarity (+). In addition, the data signals supplied to the liquid crystal pixels on the first low line are repeatedly inverted from the negative (-) to the positive (+) and from the positive (+) to the negative (-) per column line. Has a voltage. Furthermore, a negative data signal and a positive data signal are respectively applied to the first liquid crystal pixels of the first and second row lines. In other words, the odd-numbered liquid crystal pixels on the 4i-3rd, 4i-2nd, 4i-1th and 4ith rowlines have a negative data signal, a positive data signal, and a positive data signal. A polarity (+) data signal and a negative (-) data signal are respectively supplied, and positive polarities are provided to the even-numbered liquid crystal pixels on the 4i-3, 4i-2, 4i-1 and 4i low lines. Positive data signals, negative data signals, negative data signals, and positive data signals are applied respectively.

4D shows the polarities of the data signals supplied to the liquid crystal pixels on the liquid crystal panel in the fourth frame period. In the fourth frame period, as shown in Fig. 4D, the data signals applied to the liquid crystal pixels on the first and second row lines are negative (-) to positive (+) and positive (+) per column line. It has a voltage of polarity which is repeatedly inverted to negative (-) at. The data signals supplied to the liquid crystal pixels located at the left end of the first to last row lines of the liquid crystal panel are negative to positive and positive to negative every two rows. It has a voltage of polarity that is repeatedly inverted to polarity (-). Furthermore, a negative data signal is applied to all of the first liquid crystal pixels of the first and second low lines. As a result, the negative liquid crystal pixels on the 4i-3rd, 4i-2nd, 4i-1th and 4ith rowlines have a negative data signal, a negative data signal, and a positive polarity. A positive data signal and a positive data signal are supplied, respectively, and the even-numbered liquid crystal pixels on the 4i-3, 4i-2, 4i-1, and 4i lower lines have positive polarity ( A data signal of +), a data signal of positive (+), a data signal of negative (-) and a data signal of negative (-) are applied respectively.

As shown in Figs. 4A to 4D, the data signals supplied to the fourth i-th liquid crystal pixels are positive polarity (+) positive polarity (+) negative polarity (-) every four frames. It has a polarity period pattern that changes in the form of negative polarity (-), and the data signal supplied to the fourth i-th even-numbered liquid crystal pixels has a negative polarity (-)-> negative polarity (-)-> positive polarity every four frames. It has a polar period pattern that changes in the form of (+)-positive polarity (+). The polarity pattern changes in the form of positive polarity (+)-negative polarity (-)-positive polarity (+)-negative polarity (-) every four frames. The data signal supplied to the fourth i-th even-numbered liquid crystal pixels is in the form of negative polarity (-)-> positive polarity (+)-> negative polarity (-)-> positive polarity (+) every four frames. It has a changing polarity pattern. The polarity pattern changes in the form of negative polarity (-)-negative polarity (-)-positive polarity (+)-positive polarity (+) every four frames. The data signal supplied to the 4i-2th even-numbered liquid crystal pixels is in the form of positive polarity (+)-> positive polarity (+)-> negative polarity (-)-negative polarity (-) every four frames. It has a changing polarity pattern. The data signal supplied to the fourth i-th liquid crystal pixels has a polar period pattern that changes from negative polarity (-) to positive polarity (+) to negative polarity (+) every four frames. The data signal supplied to the fourth i-th even-numbered liquid crystal pixels has a polar period pattern that changes from positive polarity (+) to negative polarity (-) to positive polarity (+) to negative polarity (-) every four frames. Will have

As described above, the 2-dot inversion type liquid crystal panel driving method prevents visual amplification by repeating polarities of data signals supplied to liquid crystal pixels on the liquid crystal panel every four frames. As a result, the liquid crystal panel driving method of the two-dot inversion method can prevent the wave noise from appearing in the image, and can further improve the image quality.

5 schematically illustrates a two-dot inversion liquid crystal panel driving apparatus according to an exemplary embodiment of the present invention.

The liquid crystal panel driver of FIG. 5 includes a gate driving IC chip 12 for driving the gate lines GL1 to GLn on the liquid crystal panel 10 and source lines intersecting the gate lines GL1 to GLn. A source driving-IC chip 14 for driving (SL1 to SLn) is provided. The liquid crystal panel 10 has pixels PE arranged in regions respectively bent by the gate lines GL1 to GLn and the source lines SL1 to SLm. Each pixel PE includes a liquid crystal cell CLC for adjusting the amount of transmitted light in response to an electric field (that is, a data signal), and a source line SL for a liquid crystal cell CLC in response to a gate signal on the gate line GL. And a thin film transistor (TFT) selectively connected to the.

The gate driving IC chip 12 sequentially drives the n gate lines GL1 to GLn for each frame in horizontal synchronization periods in response to a gate control signal from a timing controller (not shown).

The source driving-IC chip 14 supplies one line of pixel data to the source lines SL1 to SLm whenever the gate line GL is enabled in response to a source control signal from the timing controller. . At this time, one line of data has a polarity opposite to that of adjacent pixel data. In other words, the source driving-IC chip 14 has a polarity in which one line of pixel data is repeatedly inverted in accordance with the pixel (or source line).

In addition, the source driving-IC chip 14 is configured to supply the data signals supplied to the pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines every four frame periods in response to the polarity control signal from the timing controller. Causes the polar pattern to be repeated. To this end, the polarity control signal supplied to the source driving IC chip 14 has a phase pattern repeated every four frame periods. The polarity pattern of the polarity control signal and the data signals will be described in detail.

The polarity control signal supplied to the source driving-IC chip 14 has a phase of " 0 ", a duty rate of 50%, and a period of four in a 4i-3 frame period as shown in Fig. 6A. It has the form of a spherical pulse train corresponding to the horizontal scanning period. At this time, the source driving-IC chip 14 is configured such that data signals supplied to the odd-numbered pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines are "+", "+", "-" and The voltages of "-" and the data signals supplied to even-numbered pixels on the 4i-3, 4i-2, 4i-1 and 4i gate lines are the voltages of "-", "-", "+" and "+". Have each of them.

In the 4i-2 frame period, the polarity control signal has a phase delay of "90 degrees" as shown in Fig. 6B, a duty ratio of 50%, and a period having the form of a spherical pulse string corresponding to four horizontal scanning periods. Then, the source driving-IC chip 14 has the data signals supplied to the odd-numbered pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines "+", "-", "-" and " The voltages of + "and the data signals supplied to the even-th pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines produce voltages of"-"," + "," + ", and"-". Have each one.

In the 4i-1 frame period, the polarity control signal is delayed in phase "270 °" as shown in Fig. 6C, the duty ratio is 50%, and the period forms a rectangular pulse string corresponding to four horizontal scanning periods. do. At this time, the source driving-IC chip 14 has data signals supplied to the odd-numbered pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines "-", "+", "+" and The voltages of "-" and the data signals supplied to even-numbered pixels on the 4i-3, 4i-2, 4i-1 and 4i gate lines are the voltages of "+", "-", "-" and "+". Have each of them.

Finally, in the 4i frame period, the polarity control signal is delayed in phase "90 degrees" as shown in Fig. 6D, the duty ratio is 50%, and the period forms a rectangular pulse string corresponding to four horizontal scanning periods. . Then, the source driving-IC chip 14 has data signals supplied to the odd-numbered pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines "-", "-", "+" and " The voltages of + "and the data signals supplied to the even-th pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines produce voltages of" + "," + ","-", and"-". Have each one.

In other words, the data signal supplied to the odd pixels on the 4i-3 gate line and the data signal supplied to the even pixels are "+ → + →-→-" and "-→-→ + every four frame periods. → in the form of + ", each has a repeating polar pattern. The data signal supplied to the odd-numbered pixels on the 4i-2 gate line and the data signal supplied to the even-numbered pixels are divided into "+ →-→-→ +" and "-→ + → + →-" every four frame periods. Each of these has a polar pattern that is changed repeatedly. The data signal supplied to the odd-numbered pixels on the 4i-1 gate line and the data signal supplied to the even-numbered pixels are divided into "-→ + → + →-" and "+ →-→-→ +" every four frame periods. Each of these has a polar pattern that is changed repeatedly. Lastly, the data signal supplied to the odd pixels on the 4i gate line and the data signal supplied to the even pixels are "-→-→ + → +" and "+ → + →-→-every 4 frame periods. It will have a polar pattern that changes repeatedly in the form of ".

As described above, the liquid crystal panel driving apparatus of FIG. 5 prevents the visual amplification phenomenon by repeating the polar pattern of the data signal supplied to the pixels on the liquid crystal panel every four frame periods. As a result, the two-dot inversion type liquid crystal panel driving apparatus can prevent the wave noise from appearing in the image, and further improve the image quality.

7A to 7B show data supplied to each pixel on the liquid crystal panel when 31 gray level data and 0 gray level data are displayed alternately in both the horizontal and vertical directions (in other words, when a check-animation is displayed on the screen). The polarity pattern of signals is shown. As shown in Figs. 7A to 7D, four frames of 31 gray level signals supplied to odd-numbered pixels on 4i-3 and 4i-1 gate lines and even-numbered pixels on 4i-3 and 4i-1 gate lines are provided. During this process, different polar patterns are obtained. In addition, the zero gray level signals supplied to the even-numbered pixels on the 4i-3 and 4i-1 gate lines and the odd-numbered pixels on the 4i-3 and 4i-1 gate lines have different polarity patterns during four frames. Will have

In detail, the 31 gray level data signals supplied to the odd and 4i-2 even pixels on the 4i-3 gate line are "+ → + →-→-" and "-→ + →-→ every 4 frame periods. In the form of + ", each has a repeating polar pattern. The 31 gray level data signals supplied to the odd-numbered pixels on the 4i-1 gate line and the even-numbered pixels on the 4i gate line are divided into "-→-→ + → +" and "+ →-→ + →-" every four frame periods. Each of these has a polar pattern that is changed repeatedly. On the other hand, the zero gray level data signals supplied to the even-numbered pixels on the 4i-3 gate line and the odd-numbered pixels on the 4i-2 gate line are "-→-→ + → +" and "+ →-→ + every four frame periods. ≧ a zero gray level data signal supplied to the even-numbered pixels on the 4i-1 gate line and the odd-numbered pixels on the 4i gate line is " every 4 frame periods " + → + →-→-"and"-→ + →-→ + "in the form of a repeating polar pattern, respectively.

As such, 31 gray level data signals applied to the odd-numbered pixels on the 4i-3 and 4i-1 gate lines, the even-numbered pixels on the 4i-2 and 4i gate lines, and the 4i-3 and 4i-1 gate lines. Each of the even-numbered pixels in the image and the zero gray level data signals applied to the odd-numbered pixels on the 4i-2 and 4i gate lines each have a polar pattern that is repeated every four frame periods, thereby preventing visual amplification.

As described above, in the method and apparatus for driving the liquid crystal panel according to the present invention, the polarization pattern of the data signal supplied to the pixels on the liquid crystal panel is repeated every four frame periods so that visual amplification does not occur. As a result, the liquid crystal panel driving method and apparatus of the two-dot inversion method according to the present invention can prevent the appearance of wave noise in the image, and can further improve the image quality.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present 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.

Claims (5)

Data signals supplied to the odd pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel display voltages of "+", "+", "-", and "-" and 4i-. Driving the data signals supplied to even-numbered pixels on the 3, 4i-2, 4i-1 and 4i gate lines to have voltages of "-", "-", "+" and "+", respectively; The data signals supplied to the odd pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel have voltages of "+", "-", "-", and "+" and 4i. Driving the data signals supplied to the even-numbered pixels on the -3, 4i-2, 4i-1, and 4i gate lines to have voltages of "-", "+", "+", and "-", respectively; Data signals supplied to the odd pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel are drawn with voltages of "-", "+", "+", and "-". Driving the data signals supplied to the even-numbered pixels on the -3, 4i-2, 4i-1, and 4i gate lines to have voltages of "+", "-", "-", and "+", respectively; And The data signals supplied to the odd pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel are drawn with voltages of "-", "-", "+", and "+". Driving the data signals supplied to the even-numbered pixels on the -3, 4i-2, 4i-1, and 4i gate lines to have voltages of "+", "+", "-", and "-", respectively. Liquid crystal panel driving method comprising a. The method of claim 1, The voltage polarity of each of the data signals supplied to the odd and even pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel is controlled by a polarity control signal whose phase is constantly changed every four frame periods. Liquid crystal panel driving method characterized in that it is changed. The method of claim 2, The polarity control signal has a phase of 0 °, -90 °, -270 ° and 180 ° as four frames proceed. A liquid crystal panel having liquid crystal pixel cells positioned in each of regions separated by gate lines and source lines crossing each other; Gate driving means for sequentially driving the gate lines; Radix on the 4i-3, 4i-2, 4i-1 and 4i gate lines of the liquid crystal panel in response to a polarity control signal having phases of 0 °, -90 °, -270 ° and 180 ° as the frame proceeds. The liquid crystal panel cells have different polar patterns and the even-numbered liquid crystal pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel have different polar patterns. And a source driving means for driving the lines. The method of claim 4, wherein The source driving means In the 4i-3 frame period, data signals supplied to the odd-numbered pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel are "+", "+", "-" and " And the data signals supplied to the even-th pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines, the voltages of "-", "-", "+" and "+". To drive each one, In the 4i-2 frame period, data signals supplied to the odd pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel are "+", "-", "-" and " The voltages of + "and the data signals supplied to the even-th pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines produce voltages of"-"," + "," + ", and"-". To drive each one, In the 4i-1 frame period, data signals supplied to the odd-numbered pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel are "-", "+", "+" and " And the data signals supplied to the even-numbered pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines provide voltages of "+", "-", "-", and "+". To drive each one, and In the 4i frame period, data signals supplied to the odd pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines of the liquid crystal panel are "-", "-", "+", and "+". And the data signals supplied to even-numbered pixels on the 4i-3, 4i-2, 4i-1, and 4i gate lines have voltages of "+", "+", "-", and "-", respectively. Liquid crystal panel drive device characterized in that the drive.