KR100806889B1 - Liquid crystal display for wide viewing angle, and driving method thereof - Google Patents

Abstract

The present invention discloses a liquid crystal display for a wide viewing angle mode and a driving method thereof for reducing the occurrence of lower gray level inversion.

The liquid crystal display panel according to the present invention comprises: a first data electrode line for transmitting a first data voltage; A second data electrode line for transmitting a second data voltage; A first pixel electrode formed in a predetermined region between the gate electrode line and the first data electrode line; A first switching element connected to the first data electrode line and the gate electrode line, respectively, and turned on / off according to a scan signal to output a first data voltage to the first pixel electrode; A second pixel electrode formed in a predetermined region between the gate electrode line and the second data electrode line; And a second switching element connected to the second data electrode line and the gate electrode line, respectively, and turned on / off according to a scan signal to output a second data voltage to the second pixel electrode. As a result, by dividing the pixel, one gray pixel data voltage is applied to one pixel among the divided pixels, and a gray voltage voltage smaller than the gray data normally applied to the other pixel is applied to the liquid crystal display. The wide viewing angle mode of the device can be realized.

LCD, wide viewing angle, gray level inversion, bottom gray level inversion, gray, gray level

Description

Liquid crystal display for wide viewing angle mode and its driving method {LIQUID CRYSTAL DISPLAY FOR WIDE VIEWING ANGLE, AND DRIVING METHOD THEREOF}

1 is a diagram for describing an arrangement of a liquid crystal director relative to a voltage applied to a liquid crystal cell.

2 is a view for explaining a liquid crystal display panel for a wide viewing angle mode according to an embodiment of the present invention.

3 is a view for explaining a liquid crystal display using the liquid crystal display panel for a wide viewing angle mode according to an embodiment of the present invention.

4 is a diagram for describing an arrangement of a liquid crystal director relative to a voltage applied to a liquid crystal.

5A to 5B are graphs showing simulation results of transmittance versus upper and lower viewing angles when the pixel division is not performed in the related art and an enlarged graph thereof.

6A to 6B are graphs showing simulation results of transmittance versus upper and lower viewing angles when the pixels are divided according to the present invention, and enlarged graphs thereof.

FIG. 7 is a diagram for describing a first exemplary embodiment for calculating m and m ′ for a specific n on a gamma curve of a liquid crystal display panel.

FIG. 8 is a view for explaining a second embodiment for calculating m and m 'for a specific n on a gamma curve of a liquid crystal display panel. FIGS. 9A to 9B are upper and lower gray level characteristics of a conventional liquid crystal display. Graph and its enlarged graph.

10A to 10B are graphs showing upper and lower gray scale characteristics and an enlarged graph thereof according to the present invention.

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

100: scan driver 210, 220: gamma voltage generator

310, 320: data driver 400: liquid crystal display panel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display (hereinafter referred to as LCD) and a driving method thereof, and more particularly, to a liquid crystal display for wide viewing angle mode and a driving method thereof for reducing occurrence of lower gray level inversion.

In general, the reason why lower gray level inversion occurs in a twisted nematic (TN) type LCD is as follows. For convenience of description, the following description will be made using an electrically controlled birefringence (ECB) mode. Here, in the ECB type LCD, the rubbing direction of the vertical alignment layer is the same or opposite, the twist angle is 0 °, the transmission axes of the polarizing plate and the analyzer are perpendicular to each other, and the transmission axis of the polarizing plate is 45 ° with respect to the rubbing direction.

When a voltage applied to the liquid crystal cell is applied to each of the voltages V1 <V2 <V3, the liquid crystal directors are arranged as shown in FIGS. 1A to 1C.                         

1 is a diagram for describing an arrangement of a liquid crystal director relative to a voltage applied to a liquid crystal cell.

As shown in FIG. 1, when light is incident perpendicularly to the liquid crystal cell array plane, phase retardation due to the liquid crystal becomes smaller as the applied voltage increases. This will not pass. In other words, as the voltage increases, the transmittance decreases.

However, when the light is inclined at a certain angle with respect to the liquid crystal cell array plane, the phase delay gradually decreases as the applied voltage increases from V1 to V2, and the transmittance decreases. Will increase.

In other words, when the voltage is applied higher than a certain angle, the transmittance becomes larger than when applying a lower voltage, which is gray level inversion.

For example, when the LCD panel is viewed from the front, the normal gradation level can be checked, but the lower the gradation level than the front, the abnormal gradation level can be confirmed. That is, when observing the panel at a lower angle or more, there is a problem in that white gray is inverted to black gray and white to gray.

The lower gray level inversion causes one problem of narrowing the viewing angle of the liquid crystal display and causing the narrow viewing angle.

As described above, the compensation film may be used as a method for solving the narrow viewing angle problem of the liquid crystal display. However, the method using the compensation film is excellent in improving the contrast ratio (CR), but the gray scale reversal characteristic is large. There is a problem that is not improved.

In addition, although the IPS mode or the vertical alignment (VA) mode may be used as a method for solving the narrow viewing angle problem of the liquid crystal display, the adoption of such a mode requires a complicated process and has a high defect rate.

Accordingly, the present invention provides a liquid crystal display device for a wide viewing angle mode to reduce the occurrence of lower gray level inversion.

Another object of the present invention is to provide a method of driving the liquid crystal display device for the wide viewing angle mode described above.

A liquid crystal display device for a wide viewing angle mode according to one feature for realizing the object of the present invention described above,

A gate driver unit sequentially outputting predetermined scan signals;

A first gamma voltage generator configured to output a first gamma voltage;

A first data driver unit outputting a first data voltage in response to the first gamma voltage;

A second gamma voltage generator configured to output a second gamma voltage;                     

A second data driver unit outputting a second data voltage in response to the second gamma voltage; And

And a liquid crystal display panel configured to display a predetermined image in response to the first data signal or the second data signal based on the scan signal. Here, the first data voltage is a voltage obtained by adding a first correction data voltage to a normal data voltage normally applied using one pixel electrode, and the second data voltage corresponds to a second correction data voltage to the normal data voltage. It is preferable that it is a subtracted voltage.

In this case, the first correction data voltage and the second correction data voltage are respectively set corrected transmittances having a predetermined transmittance difference on the basis of a specific light transmittance corresponding to the specific tone data, and the tone data corresponding to the set transmittance respectively. It is characterized by.

In addition, the first correction data voltage and the second correction data voltage may include first grayscale data having a gray range in a predetermined range in a forward direction with respect to specific grayscale data, and a second grayscale having a gray level in a predetermined range in a negative direction. It is characterized in that the data is arbitrarily set, the respective points for which gray level inversion is not generated while adjusting the set first and second gray level data are fixed, and the gray level data corresponding to the respective fixed points. Here, the gray level of the above-mentioned constant range is a value of any one of 15-50, It is preferable that 30 grains are among them.

In addition, the driving method of the liquid crystal display device for the wide viewing angle mode according to another aspect of the present invention includes a plurality of gate electrode lines and a first data electrode line perpendicular to the gate electrode line. And a second data electrode line formed adjacent to the first data electrode line in parallel with each other, and a first formed between the gate electrode line and the first data electrode line and between the gate electrode line and the second data electrode line. And a second pixel electrode, a first switching element connected to the first data electrode line and the first pixel electrode, and a second switching element connected to the second data electrode line and the second pixel electrode. A driving method of an apparatus, comprising: receiving image data for image display from an external image signal source and converting the image data into an image voltage The step;

Generating a first gamma voltage and a second gamma voltage;

Generating a first data voltage based on the image voltage and the first gamma voltage, and generating a second data voltage based on the image voltage and the second gamma voltage;

Sequentially supplying a scan signal for outputting the image data to the gate line; And

And supplying the first data voltage to the first data electrode line and the second data voltage to the second data electrode line.

Here, the first data voltage is a voltage obtained by adding a first correction data voltage to a normal data voltage normally applied using one pixel electrode, and the second data voltage corresponds to a second correction data voltage to the normal data voltage. It is preferable that it is a subtracted voltage.

In addition, the first correction data voltage and the second correction data voltage may be set to each of the correction transmittance having a predetermined transmittance difference on the basis of a specific light transmittance corresponding to the specific grayscale data, respectively, it is grayscale data corresponding to each of the set transmittance desirable.

In addition, the first correction data voltage and the second correction data voltage may include first grayscale data having a gray level in a predetermined range in a forward direction based on specific grayscale data, and second grayscale data having a gray level in a predetermined range in a negative direction. Is arbitrarily set, and each point where gray level inversion is not generated while adjusting the set first and second gray level data is fixed, and the gray level data corresponding to each fixed point is preferable. Here, the gray level of the above-mentioned constant range is a value of any one of 15-50, It is preferable that 30 grains are among them.

According to the liquid crystal display for the wide viewing angle mode and the driving method thereof, pixels are divided and formed, one of the divided pixels is applied with a grayscale data voltage larger than the grayscale data normally applied, and the other pixel is normally By applying a gradation voltage smaller than the gradation data to be applied, the wide viewing angle mode of the liquid crystal display device can be realized. Then, embodiments will be described so that those skilled in the art can easily implement the present invention.

FIG. 2 is a diagram for describing a liquid crystal display panel for a wide viewing angle mode according to an exemplary embodiment of the present invention. In particular, FIG. 2 is a view for explaining a pixel located between a gate line and a data line.

Referring to FIG. 2, one pixel is divided into two pixels I and II, and each division pixel includes a switching element TFT. In this case, the first voltage V + dV applied to the data line D _{p on the} left side and applied to the pixel I through one switching element has one pixel at a specific gray voltage V when the pixels are implemented as one. It is the sum voltage of the 1st correction gradation voltage dV for making the angle which gray level reversal generate | occur | produce while making it the same as the front of a VT curve at the time.

In addition, the second voltage V-dV 'applied to the data line D _{p + 1 on the} right and applied to the pixel II through another switching element is a specific gray voltage V when the pixels are implemented as one. Is the difference voltage of the second correction gray voltage dV for increasing the angle at which gray scale reversal occurs while being equal to the front of the VT curve when there is one pixel.

In FIG. 2, the position of the switching element connected to each division pixel is implemented as an example between the division pixel and the after gate line, but the position of the switching element is divided into the division pixel and the previous gate line. It can be implemented between gate lines.

In addition, the structure in which each switching element is connected may be arranged alternately after the gate line and the previous gate line in column units or line units.

Next, an example of the liquid crystal display device to which the above-mentioned divided pixel is applied will be described with reference to the accompanying drawings.

3 is a view for explaining a liquid crystal display using the liquid crystal display panel for a wide viewing angle mode according to an embodiment of the present invention.

Referring to FIG. 3, a liquid crystal display according to an exemplary embodiment of the present invention may include a scan driver 100, first and second gamma voltage generators 210 and 220, and first and second data driver 310. 320 and a liquid crystal display panel 400.

The scan driver 100 receives a gate clock signal Gate clk and a vertical line start signal Vstart from a timing controller (not shown), including a shift register, a level shifter, a buffer, and the like, and includes a gate driving voltage generator. The voltages Von, Voff, and Vcom are provided from (not shown) to open a path so that voltage values of each pixel on the liquid crystal display panel 400 are transferred to the pixels.

The first gamma voltage generator 210 may be configured based on the number of bits of RGB data R [0: N], G [0: N], and B [0: N] provided from a graphic controller or a timing controller. Accordingly, grayscale voltages V0, V1, V2, ..., V3n suitable for the digital code value are generated and provided to the first data driver 310, respectively.

For example, if R data is applied with 6 bits (R [0: 5]), 2 ⁶ = 64 gradations are produced and R of 64 gradations is represented. Here, the gray voltage generator 210 extracts a voltage corresponding to the gray of the negative side and the positive side VT from the built-in resistor array and outputs a gray voltage adapted to each gray level to the first data driver 310. .

Similar to the first gamma voltage generator 210, the second gamma voltage generator 220 generates a gray voltage suitable for a digital code value according to the number of bits of the RGB data to be input, thereby generating a second data driver ( To 320).

The first data driver 310 receives the R, G, and B digital data R [0: N], G [0: N], and B [0: N] from the timing controller and stores the received digital data. When a load signal LOAD for commanding 400 to be applied is applied, an LCD corresponding to the respective data is selected by interlocking with the gray voltages provided from the first and second gray voltage generators 210 and 220. The first data voltages D1, D3, D5,..., Dm-2, and Dm are transmitted to the panel 400.

Here, the first data voltage transmitted is the first voltage V + dV described with reference to FIG. 3. In addition, the first data driver 310 has a polarity of pixels arranged on the LCD panel 400 every frame. The data voltages D1, D2, D3, ..., D _m are output so as to be inverted different from each other. In this case, the inversion of the pixels so that the polarities are different every frame is due to the general characteristics of the liquid crystal, as is already known.

Similar to the first data driver 310, the second data driver 320 selects a voltage corresponding to each data in cooperation with the gray voltage according to the application of the load signal, thereby selecting the second data voltage D2,. D4, D6, ..., D _m-3 , D _m-1 ). Here, the second data voltage transferred is the second voltage V-dV 'described with reference to FIG. 3.

The liquid crystal display panel 400 includes m data lines, n gate lines arranged orthogonal to the data lines, and two divided pixels (or pixels) respectively formed in predetermined regions arranged in a lattice arrangement between the data lines and the gate lines. Electrode) and two switching elements, and the first and second data drivers 310 and 320 are applied as the gate voltages G1, G2, ..., Gn provided from the scan driver 100 are applied to the corresponding pixels. The first data voltage D1, D3, D5, ..., D _m-2 , D _m and the second data voltage D2, D4, D6, ..., D _m-3 , D _m- In response to ₁ ), the corresponding embedded pixel electrode is driven.

Then, the lower gray level inversion is reduced through the pixel division driving as described above in detail with reference to the accompanying drawings for realizing the wide viewing angle mode of the LCD.

4 is a diagram for describing an arrangement of a liquid crystal director relative to a voltage applied to a liquid crystal.

As shown in FIG. 4, when a pixel is divided into two regions and a voltage is slightly applied, gray level inversion may be prevented to a certain level.

As shown, the average of the amount of light emitted from the two divided regions is not different from the case of not dividing the pixel when the light is the front incident to the liquid crystal cell, but is different when the light is oblique incident. In other words, when the pixels are not divided, the light passing in the diagonal direction has a transmittance of zero (zero), but when the pixels are divided, the light has a predetermined transmittance.

This increases the angle at which gray level reversal occurs. Of course, gray scale inversion may still occur, but the angle at which gray scale inversion occurs is increased, compared to a general liquid crystal display panel without pixel division.                     

5A to 5B are graphs showing simulation results of transmittance versus upper and lower viewing angles when no pixel division is performed according to the related art, and FIGS. 6A to 6B are transmittances versus upper and lower viewing angles when pixel division is performed according to the present invention. The simulation result graph for and its enlarged graph.

Particularly, the top curve is a curve corresponding to the gradation of the gradation level (for example, 256 gradations) on the basis of the front (0 °) of the panel among the graphs when displaying images from 1 gradation to 265 gradations on the graph described above. The lowest curve is a curve corresponding to the gradation of the lowest gradation level (for example, 1 gradation).

As shown in FIGS. 5A to 5B, when pixel division is not performed, gray level inversion does not occur at the front (0 °) or the upper side of the panel, but gray level inversion occurs toward the lower side of the panel. For example, in the gradation phase of the highest level, gradation inversion does not occur for each of the front and the upper and lower sides, but as the gradation level decreases, the lower gradation inversion occurs, and in particular, it is confirmed that the generation angle is closer to the front (0 °). Can be.

However, as shown in Figs. 6A to 6B, when the pixel division is similar as when no pixel division is performed, it can be seen that the angle at which the lower gray level inversion occurs is increased when compared with the same gray level.

Then, the first grayscale G (n + m) for applying to the odd-side data electrode line for displaying the specific nth grayscale G (n) and the second grayscale G (n) for applying to the even-side data electrode line -m ') describes how to compute m and m' respectively for displaying them.

FIG. 7 is a diagram for describing a first exemplary embodiment for calculating m and m ′ for a specific n on a gamma curve of a liquid crystal display panel. In this case, a gamma curve represents a relationship between each gray scale and light transmittance.

Referring to FIG. 7, the values of m and m 'are obtained by finding G (n + m) and G (n-m') that differ by ΔI with respect to the light transmittance I (n) of a specific grayscale G (n). . Here, it is only necessary to obtain a ΔI value in which gray scale reversal does not occur within a range that does not seriously affect visibility while adjusting the magnitude of the ΔI value.

However, in grayscales close to white and black, the condition of (I (n) + ΔI)> I (64) may be satisfied or the condition of (I (n) + ΔI) <I (1). In this case, m and m 'satisfying the conditions of (I (n) + ΔI) = I (64) or (I (n) + ΔI) = I (1) are used, respectively. Naturally, in this region, ΔI has a value different from that of the intermediate region.

Table 1 is a table for explaining the gray level inversion angle according to the first embodiment described above, and is a table for explaining the gray level inversion angle according to the set I value, and in particular, ΔI is 5% and 10% of I (64), respectively. , 15%.

Gray scale inversion (°) Intensity 5 Intensity 10 Intensity 15 _{Prize 26 ° Ha 38 ° Prize 30 ° Ha 40 ° Prize 34 ° Ha 50 ° Left > 80 ° Ooh > 80 ° Left > 80 ° Ooh > 80 ° Left > 80 ° Ooh > 80 °}

As shown in Table 1, it can be seen that the gray scale inversion angle increases as ΔI increases.                     

FIG. 8 is a diagram for describing a second exemplary embodiment for calculating m and m ′ for a specific n on a gamma curve of a liquid crystal display panel.

Referring to FIG. 8, first, as a specific gradation is designated, the LCD designer sets arbitrary m and m 'values, and calculates the ΔI value where gradation inversion does not occur within a range that does not seriously affect visibility. The m and m 'values corresponding to the determined ΔI values are obtained. At this time, ΔI values are different for each gray level, but have the same ΔI value for a specific gray level.

That is, when obtaining I (n) corresponding to G (n), which is a specific gray level, [(n + m)-(n-m ') = (n "+ m")-(n "-m") = 2m "= constant] to find m and m 'that satisfy I (n) = (I (n + m) + (n-m')) / 2. That is, when n = 32, m "= 10. At this time, it can be seen that n "= 30. M = 8 and m '= 12.

As shown in FIG. 8, the m " value without gray scale inversion can be obtained while adjusting m " within a range that does not seriously affect visibility. In grays close to white and black, (n + m)> 64 or (n-m ') <0, where (n + m) = 64 or (n-m') = 1 do.

Table 2 is a table for explaining the gray level inversion angle according to the second embodiment.

Gray scale inversion (°) Gray 10 Gray 30 Gray 50 _{Prize 28 ° Ha 38 ° Prize 32 ° Ha 56 ° Prize 34 ° Ha > 80 ° Left > 80 ° Left > 80 ° Left > 80 ° Ooh > 80 ° Left > 80 ° Ooh > 80 °}

In Table 2, the grays 10, 30, and 50 set the light transmittance by making the gray level constant among the methods for obtaining m and m ', and calculate m and m' based on the set light transmittance.

As shown in Table 2, it can be seen that as the gray increases, the lower gray level inversion angles increase by 38 ° 56 ° 80 °, respectively. In particular, in the case of gray 50, gray level inversion does not occur at all, but there is a problem in terms of visibility.

That is, due to the gray level difference between the pixels adjacent in the diagonal direction, there is a problem that a predetermined stripe occurs in the diagonal direction of the pixels. Therefore, gray has the best characteristics at about 30 degrees.

9A to 9B are graphs of upper and lower gray scale characteristics and an enlarged graph thereof according to a conventional liquid crystal display, and FIGS. 10A to 10B are graphs of upper and lower gray scale characteristics and an enlarged graph thereof according to the present invention.

As shown in FIGS. 9A to 9B, in the conventional general liquid crystal display, it may be confirmed that gray level inversion occurs in the lower 38 degrees.

However, according to the present invention, the lower gray level inversion is generated at 56 °, so it can be seen that gray level inversion occurs at an angle increased by about 20 ° compared with the conventional art.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope of the invention as set forth in the claims below. It will be appreciated.

As described above, according to the present invention, a pixel of a predetermined region formed between the data line and the gate line is divided into two unit pixels, and one unit pixel of the divided unit pixels is applied with a data voltage larger than the normal data voltage. By applying a data voltage smaller than the normal data voltage to the other unit pixel, the problem of the lower gray level inversion in which the gray level is reversed as it goes down from the front side on the liquid crystal display panel can be solved.

Claims (10)

A gate driver unit sequentially outputting predetermined scan signals; A first gamma voltage generator configured to output a first gamma voltage; A first data driver unit outputting a first data voltage in response to the first gamma voltage; A second gamma voltage generator configured to output a second gamma voltage; A second data driver unit outputting a second data voltage in response to the second gamma voltage; And a liquid crystal display panel configured to display a predetermined image in response to the first data voltage and the second data voltage based on the scan signal. Liquid crystal display device for a wide viewing angle mode comprising a. The liquid crystal display panel of claim 1, wherein A gate electrode line transferring a predetermined scan signal; A first data electrode line vertically crossing the gate electrode line to transfer the first data voltage; A second data electrode line formed to be adjacent to the first data electrode line and transferring the second data voltage; A first pixel electrode formed in a predetermined region between the gate electrode line and the first data electrode line; A first end is connected to the first data electrode line, a second end is connected to the gate electrode line, and is turned on / off according to the scan signal to transfer the first data voltage to the first pixel through a third end; A first switching element output to the electrode; A second pixel electrode formed in a predetermined region between the gate electrode line and the second data electrode line; And A first end is connected to the second data electrode line, a second end is connected to the gate electrode line, and is turned on / off according to the scan signal to transfer the second data voltage to the second pixel through a third end; A liquid crystal display device for a wide viewing angle mode comprising a second switching element output to an electrode. The method of claim 2, The first data voltage is, A voltage obtained by adding the first correction data voltage to a normal data voltage normally applied using one pixel electrode, The second data voltage is, A liquid crystal display device for a wide viewing angle mode, wherein the voltage is obtained by subtracting a second correction data voltage from the normal data voltage. The method of claim 3, The first correction data voltage and the second correction data voltage, The liquid crystal display device for the wide viewing angle mode, wherein the corrected transmittances having a predetermined transmittance difference are respectively set on the basis of the specific light transmittance corresponding to the specific tone data, and the tone data respectively correspond to the set transmittance. The method of claim 3, The first correction data voltage and the second correction data voltage, While arbitrarily setting the first grayscale data having a gray level in a constant range in the forward direction and the second grayscale data having a gray level in the negative direction in a negative direction based on the specific grayscale data, and adjusting the set first and second grayscale data. A liquid crystal display device for a wide viewing angle mode, wherein each point at which gray level inversion is not generated is fixed, and gray level data corresponding to each fixed point. A plurality of gate electrode lines, a first data electrode line perpendicular to the gate electrode line, a second data electrode line formed to be adjacent to the first data electrode line in parallel, the gate electrode line and the first data First and second pixel electrodes respectively formed between the electrode lines and between the gate electrode line and the second data electrode line, a first switching element connected to the first data electrode line and the first pixel electrode, and the second A driving method of a liquid crystal display device comprising a data electrode line and a second switching element connected to the second pixel electrode, the method comprising: receiving image data for an image display from an external image signal source and converting the image data into an image voltage; Generating a first gamma voltage and a second gamma voltage; Generating a first data voltage based on the image voltage and the first gamma voltage, and generating a second data voltage based on the image voltage and the second gamma voltage; a scan signal for outputting the image data Sequentially supplying to the gate line; And Supplying the first data voltage to the first data electrode line and supplying the second data voltage to the second data electrode line Method of driving a liquid crystal display device for a wide viewing angle mode comprising a. The method of claim 6, The first data voltage is a voltage obtained by adding a first correction data voltage to a normal data voltage normally applied using one pixel electrode. The second data voltage is, And a voltage obtained by subtracting a second correction data voltage from the normal data voltage. The method of claim 7, wherein The first correction data voltage and the second correction data voltage, A method of driving a liquid crystal display device for a wide viewing angle mode, wherein the corrected transmittances having a predetermined transmittance difference are respectively set on the basis of a specific light transmittance corresponding to the specific tone data, and the tone data respectively correspond to the set transmittance. The method of claim 7, wherein The first correction data voltage and the second correction data voltage, While arbitrarily setting the first grayscale data having a gray level in a constant range in the forward direction and the second grayscale data having a gray level in the negative direction in a negative direction based on the specific grayscale data, and adjusting the set first and second grayscale data. A method of driving a liquid crystal display device for a wide viewing angle mode, wherein each point at which gray level inversion is not generated is fixed, and gray level data corresponding to each fixed point. 10. The method of claim 9, wherein the gray range of the predetermined range is any one of 15 to 50.

Images