TWI463475B - Driving method for delta panel - Google Patents

Description

Triangle panel driving method

The present invention relates to a triangular panel driving method, and more particularly to a triangular panel driving method that is driven by a plurality of data polarity conversion methods.

With the widespread adoption of flat panel displays, many sophisticated driving methods have been used in such displays that combine pixels into a single image. Since the arrangement of pixels in a matrix is the pixel arrangement pattern that was adopted earlier in such displays, most of the driving methods are designed for such matrix-arranged displays.

Please refer to FIG. 1A , which is a table of positive and negative polarities of displayed data in pixels generated by the two-point conversion driving method which is currently widely used. In the two-point conversion driving method, each display line supplies display data to each pixel in a manner of changing the polarity of the data by two pixels. Such a driving method results in a display result as shown in FIG. 1B for a display in which pixels are arranged in a matrix. Please refer to FIG. 1B , which is a schematic diagram of display data generated when a display of matrix-arranged pixels is driven by a two-point conversion driving method. As shown in FIG. 1B, in the pixels displaying the three primary colors red (R), green (G), and blue (B), the pixels having the positive polarity of the stored data and the pixels having the negative polarity of the stored data are uniformly distributed. . For example, in the first and fourth columns of pixels from top to bottom, the red pixel R+ with positive data polarity and the red pixel R- with negative data polarity are spaced apart; similarly, in the second and fifth columns of pixels, The green pixel G+ with positive data polarity and the green pixel G- with negative data polarity are also spaced apart, and in the third and sixth columns of pixels, the blue pixel B+ with positive data polarity and the blue pixel with negative data polarity B- is also an interval distribution. borrow From the uniform distribution of the positive and negative polarities, the same color data can be displayed at any point in the display to get the closest result.

However, such a driving method which can be said to have an excellent effect in a matrix-arranged pixel display cannot be suitably used in a display in which pixels are arranged in a delta manner.

Please refer to FIG. 1C , which is a schematic diagram of display data generated when a display of triangular pixels is driven by a two-point conversion driving method. Since the arrangement of the pixels in such a display is different, if the display driving is performed by the two-point conversion driving method, the data polarity distribution in each of the primary color pixels is uneven. As can be seen from FIG. 1C, the polarity data in the red pixel in the block 100 is positive (R+), and the polarity data in the red pixel in the block 110 is negative (R-). Such polarity data is unevenly distributed, so that the display may show uneven color patches when displaying the same color data.

Another data driving method is a two-column conversion driving method as shown in FIG. 2A. Such a driving method not only causes a non-uniform distribution of polarity data as shown in FIG. 2B when used on a display in which pixels are arranged in a matrix, but also occurs when used on a display in which pixels are arranged in a triangular manner. The situation in which the polarity data is unevenly distributed as shown in Fig. 2C. Referring to FIG. 2C, it can be clearly seen that the polar data in the red pixels in the blocks 200 and 220 are both positive (R+), and the polar data in the red pixels in the block 210 are negative (R). -). Thus, the uneven distribution of such polar data also causes the display to appear uneven color patches when displaying the same color data.

In summary, since there is currently a pixel driving method designed for a display in which pixels are arranged in a triangular manner, it has become an important subject to develop a driving method capable of displaying a display with a triangular arrangement of pixels.

One of the objects of the present invention is to provide a driving method capable of reducing the unevenness of color block display in a triangular panel.

The present invention proposes a triangular panel driving method suitable for driving a triangular panel in which pixels are arranged in a triangular manner. The triangular panel includes a plurality of data lines and first, second, third, and fourth pixels. The first and second pixels are located on both sides of the first data line and are electrically coupled to the first data line. The third and fourth pixels are also located on both sides of the first data line and are also electrically coupled to the first data. a line; or the first and second pixels are located between the two data lines and the third and fourth pixels are adjacent and located between the same two data lines. The first pixel and the second pixel display a portion of one display line in one frame, and the third pixel and the fourth pixel display a portion of another display line in the frame picture. The triangular panel driving method provides the first display material to the first pixel, the second display material to the second pixel, the third display material to the third pixel, and the fourth display material to be provided in the frame image Up to the fourth pixel, and wherein the first display material and the second display material are of the same polarity, but the third display material and the fourth display material are of different polarities.

In a preferred embodiment of the present invention, the polarity of the display data of the pixels for displaying the same display line is selected from the following four:

(1) Starting with double positive polarity, followed by staggered arrangement of double negative polarity and double positive polarity.

(2) Starting with a single positive polarity, followed by a staggered arrangement of double negative polarity and double positive polarity.

(3) Starting with a single negative polarity, followed by a staggered arrangement of double positive polarity and double negative polarity.

(4) Starting with double negative polarity, followed by staggered arrangement of double positive polarity and double negative polarity.

The invention adopts a plurality of regular display data polarity arrangement manners, and arranges the order of use of the polarity arrangement manners of the display materials according to certain conditions, so that the triangular primary panel can be matched with the special primary color pixel arrangement manner of the triangular panel. The color is more uniform.

The above and other objects, features and advantages of the present invention will become more <RTIgt;

In order to make the color rendering of the Delta Panel more uniform, it is important to evenly display the display materials of different polarities stored in the pixels of the same primary color in an entire panel.

Please refer to FIG. 3A , which is a list of display data polarity rows of a delta panel according to an embodiment of the invention. As shown in FIG. 3A, in the pixel group for displaying the first and second display lines in a certain frame picture, the display data polarity of the first pixel in each display line is positive polarity (+). Next, the double negative polarity (-) and the double positive polarity are sequentially staggered; in the pixel group for displaying the third and fourth display lines in the frame picture, each display line is double negative polarity. And the bipolar polarity is sequentially staggered; in the pixel group for displaying the fifth and sixth display lines in the frame of the frame, the polarity of the display data of the first pixel in each display line is negative polarity, Downward, the double positive polarity and the double negative polarity are sequentially staggered; and in the pixel group for displaying the seventh and eighth display lines in the frame picture, each display line is a double positive polarity and a double negative polarity, respectively. Sexually staggered. In addition, the polarity of the display data after the ninth display line is repeated by repeating the order of the display data polarities of the first eight display lines.

When the above-mentioned display data polarity arrangement is specifically presented on the triangular panel, a better display effect can be obtained. Please refer to FIG. 3B, which is to make A schematic diagram of the display data generated when the triangular panel is driven by the display data polarity row list of FIG. 3A. On the triangular panel shown in FIG. 3B, a plurality of data lines 320a, 320b, and 320c, and pixels that are imaginarily divided into a plurality of pixel groups 310a to 310h are disposed. Each of the pixels is electrically coupled to one of the data lines 320a, 320b, and 320c, and is controlled by a corresponding scan line to determine whether to receive the display material from the electrically coupled data line. The pixels in each of the pixel groups 310a-310h correspondingly display one display line in one frame of the picture, that is, correspondingly receive a horizontal display material as shown in FIG. 3A.

As shown in FIG. 3B, the pixels in the pixel group 310a corresponding to the first display line are sequentially the red primary color pixel R+ storing the positive polarity display data, the green primary color pixel G- storing the negative polarity display data, and the storage negative electrode. The blue primary color pixel B- of the data display material, the red primary color pixel R+ storing the positive polarity display data, the green primary color pixel G+ storing the positive polarity display data, and the blue primary color pixel B- storing the negative polarity display data. The pixels in the pixel group 310b corresponding to the second display line are sequentially the green primary color pixel G+ storing the positive polarity display material, the blue primary color pixel B- storing the negative polarity display data, and the red storing the negative polarity display data. The primary color pixel R-, the green primary color pixel G+ storing the positive polarity display material, the blue primary color pixel B+ storing the positive polarity display material, and the red primary color pixel R- storing the negative polarity display material. The pixels in the pixel group 310c corresponding to the third display line are sequentially the red primary color pixel R- storing the negative polarity display data, the green primary color pixel G- storing the negative polarity display data, and the blue storing the positive polarity display data. The primary color pixel B+, the red primary color pixel R+ storing the positive polarity display material, the green primary color pixel G- storing the negative polarity display material, and the blue primary color pixel B- storing the negative polarity display data. The pixels in the pixel group 310d corresponding to the fourth display line are sequentially the green primary color pixel G- storing the negative polarity display data, and the blue primary color pixel storing the negative polarity display data. B-, a red primary color pixel R+ storing positive polarity display data, a green primary color pixel G+ storing positive polarity display data, a blue primary color pixel B- storing negative polarity display data, and a red primary color pixel R- storing negative polarity display data. The pixels in the pixel group 310e corresponding to the fifth display line are sequentially the red primary color pixel R- storing the negative polarity display data, the green primary color pixel G+ storing the positive polarity display data, and the blue storing the positive polarity display data. The primary color pixel B+, the red primary color pixel R- storing the negative polarity display material, the green primary color pixel G- storing the negative polarity display data, and the blue primary color pixel B+ storing the positive polarity display data. The pixels in the pixel group 310f corresponding to the sixth display line are sequentially the green primary color pixel G- storing the negative polarity display data, the blue primary color pixel B+ storing the positive polarity display data, and the red storing the positive polarity display data. The primary color pixel R+, the green primary color pixel G- storing the negative polarity display material, the blue primary color pixel B- storing the negative polarity display data, and the red primary color pixel R+ storing the positive polarity display data. The pixels in the pixel group 310g corresponding to the seventh display line are sequentially the red primary color pixel R+ storing the positive polarity display data, the green primary color pixel G+ storing the positive polarity display data, and the blue primary color storing the negative polarity display data. The pixel B-, the red primary color pixel R- storing the negative polarity display data, the green primary color pixel G+ storing the positive polarity display data, and the blue primary color pixel B+ storing the positive polarity display data. The pixels in the pixel group 310h corresponding to the eighth display line are sequentially the green primary color pixel G+ storing the positive polarity display data, the blue primary color pixel B+ storing the positive polarity display data, and the red primary color storing the negative polarity display data. The pixel R-, the green primary color pixel G- storing the negative polarity display material, the blue primary color pixel B+ storing the positive polarity display material, and the red primary color pixel R+ storing the positive polarity display data.

Obviously, such a display data polarity conversion method is quite similar to the two-point conversion driving method previously stated. However, compared to the two-point conversion drive In the method, the polarity of the display data provided by the embodiment can be used to display a more uniform distribution of the polarity of the display data stored in the pixels of the same primary color when used in the triangular panel. Comparing FIG. 1C with FIG. 3B, it is apparent that the polarity distribution of the display material stored in the red primary color pixels in the blocks 100 and 110 shown in FIG. 1C in FIG. 3B no longer has a very sharp concentration. At the same time, as shown in FIG. 3B, the polarity distribution of the display material stored in the green primary color pixel and the blue primary color pixel is also quite uniform, and the concentration distribution of the display data polarity similar to the red primary color pixel in FIG. 1C does not occur. .

Inspired by the needs and the above design, this proposal summarizes a driving method that can effectively contribute to the improvement of the color uniformity of the triangular panel. The feature point of this driving method is to integrate different types of display data polarity conversion methods in the image display process of the same frame. To be more precise, the polarity relationship of the displayed data between two pixels located in the same environment may vary differently depending on the location. It must be explained in detail that the so-called "bit in the same environment" means that it is also between two adjacent data lines, or is also on the left and right sides of a certain data line and is also electrically coupled. At this point in the data online.

If the meaning of the so-called "bit in the same environment" is explained by a practical example, reference may be made to the pixels 330-344 indicated in FIG. 3B. Among the indicated pixels, the pixels 330 and 332 are on both sides of the data line 320a and are electrically coupled to the data line 320a, and the pixels in the same environment as the pixels 330 and 332 are referred to as being in the same data. Both sides of line 320a are electrically coupled to pixels of data line 320a, such as pixels 340 and 342. From another point of view, pixels 332 and 334 are between data lines 320a and 320b, and pixels in the same environment as pixels 332 and 334 are referred to as data line 320a. Pixels between 320b, such as pixels 342 and 344.

According to the above definition, it can be easily explained that the feature of this proposal is that the pixels in the same environment are displayed in the same environment, and the polarity of the displayed data between the two pixels used to display the same display line is The displayed display lines are different and there are cases where the display data has the same polarity as the displayed data. Referring to FIG. 3B, the pixel groups 310a and 310h are used to view (the pixel groups 310a and 310h are respectively used to display one display line), and the pixel data of the pixels 330 and 332 in the pixel group 310a are opposite in polarity (pixels). 330 is positive polarity, and pixel 332 is negative polarity. In pixel group 310h, the display data polarities of pixels 340 and 342 in the same environment as pixels 330 and 332 are the same (pixels 340 and 342 are both It is positive polarity). From another point of view, the display data of pixels 332 and 334 in pixel group 310a have the same polarity (pixels 332 and 334 are both negative), and among pixel group 310h, pixels 332 and 334. The display data polarities of the pixels 342 and 344 in the same environment are opposite (pixel 342 is positive polarity, and pixel 344 is negative polarity).

In order to more systematically express the above concepts, this proposal organizes the possible conversion methods of display data polarity into four types:

(1) Starting with double positive polarity, followed by staggered arrangement of double negative polarity and double positive polarity, for example, the seventh display line (Line 7) and the eighth display line (Line 8) shown in FIG. 3A. .

(2) Starting with a single positive polarity, followed by a staggered arrangement of double negative polarity and double positive polarity, such as the first display line (Line 1) and the second display line (Line 2) shown in FIG. 3A. .

(3) Starting with a single negative polarity, followed by a staggered arrangement of double positive polarity and double negative polarity, such as the fifth display line (Line 5) and the sixth display line (Line 6) shown in FIG. 3A. .

(4) Starting with double negative polarity, followed by staggered arrangement of double positive polarity and double negative polarity, for example, the third display line (Line 3) and the fourth display line (Line 4) shown in FIG. 3A. .

Various combinations are performed in the above four manners, and the same display data polarity conversion method used in each combination is not limited to one time, so that a plurality of polarity switching combinations can be obtained. These polarity switching combinations themselves, or combinations of these polarity switching combinations, as long as they enable pixels in the same environment within the same frame, and display data polarity relationships between two pixels displaying the same display line, The triangular panel can exhibit a good display effect because the display data has the same polarity and the opposite polarity of the displayed data.

Referring to FIGS. 4A-4H, respectively, a display polarity conversion combination table obtained by combining different display data polarity conversion methods is shown. Fig. 4A sequentially uses two types (2) of display data polarity conversion methods and one type (4) of display data polarity conversion methods. Fig. 4B sequentially uses two types (4) of display data polarity conversion methods and one type (3) of display data polarity conversion methods. Fig. 4C sequentially uses two types (3) of display data polarity conversion methods and one type (1) of display data polarity conversion methods. Figure 4D uses two types (1) of display data polarity conversion methods and one type (2) of display data polarity conversion methods. Fig. 4E sequentially uses a type (2) display data polarity conversion method and two types (1) display data polarity conversion methods. Fig. 4F sequentially uses a display data polarity conversion method of one type (1) and a display data polarity conversion method of two types (3). Fig. 4G uses a type (3) display data polarity conversion method and two types (4) display data polarity conversion methods. Figure 4H uses a display data polarity conversion method of one category (4) and a display data polarity conversion method for two types (2).

4A to 4H use a display data polarity conversion combination table formed by a group of three display lines, but the actual design does not need to be limited thereto. In order to design with a physical line, two display lines may be used as a group, or four or more display lines may be used as a group to display a data polarity conversion combination table.

If the display data polarity conversion combination table shown in FIGS. 4A to 4D is further combined in order, and the first display line of each display data polarity conversion combination table and the first display data polarity conversion combination table are displayed. By coincidence, the list of display data polarity rows for driving the triangular panel shown in FIG. 3A can be obtained. In other words, under such a combination, the display line 1 and the display line 2 of FIG. 4A respectively correspond to the display line 1 and the display line 2 of FIG. 3A, and the display line 1 and the display line 2 of FIG. 4B respectively correspond to the display line of FIG. 3A. 3 and the display line 4, the display line 1 and the display line 2 of FIG. 4C respectively correspond to the display line 5 and the display line 6 of FIG. 3A, and the display line 1 and the display line 2 of FIG. 4D respectively correspond to the display line 7 of FIG. 3A and Display line 8. At the same time, the display line 3 of FIG. 4A and the display line 1 of FIG. 4B also correspond to the display line 3 of FIG. 3A, and the display line 3 of FIG. 4B and the display line 1 of FIG. 4C also correspond to the display line 5 of FIG. 3A. The display line 3 of FIG. 4C corresponds to the display line 1 of FIG. 4D to the display line 7 of FIG. 3A. The display line 3 of FIG. 4D and the display line 1 of FIG. 4A also correspond to the display line 9 of FIG. 3A, or it can be said. It corresponds to the display line 1 of Fig. 3A.

If the display data polarity conversion combination table shown in FIGS. 4E to 4H is further combined in order, the first line of each display data polarity conversion combination table and the next display data polarity conversion combination table are also the same. The display lines are coincident, and another display data polarity row list for driving the triangular panel can be obtained, as shown in FIG.

Please refer to FIG. 5 at the same time, which is a list of display data polarity rows of a triangular panel according to another embodiment of the present invention. Wherein, the display line 1 and the display line 2 of FIG. 4E Corresponding to the display line 1 and the display line 2 of FIG. 5 respectively, the display line 1 and the display line 2 of FIG. 4F respectively correspond to the display line 3 and the display line 4 of FIG. 5A, and the display line 1 and the display line 2 of FIG. 4G respectively correspond to To the display line 5 and the display line 6 of FIG. 5, the display line 1 and the display line 2 of FIG. 4H correspond to the display line 7 and the display line 8 of FIG. 5, respectively. At the same time, the display line 3 of FIG. 4E and the display line 1 of FIG. 4F also correspond to the display line 3 of FIG. 5, and the display line 3 of FIG. 4F and the display line 1 of FIG. 4G also correspond to the display line 5 of FIG. The display line 3 of FIG. 4G corresponds to the display line 1 of FIG. 4H to the display line 7 of FIG. 5A. The display line 3 of FIG. 4H and the display line 1 of FIG. 4E also correspond to the display line 9 of FIG. 5, or it can be said. It corresponds to the display line 1 of FIG.

As shown in FIG. 5, when a certain frame is displayed by using the first eight display lines (Line 1) to the eighth display line (Line 8), the first and eighth pieces are displayed. In the pixel group of the display line, the polarity of the display data of the first pixel in each display line is positive polarity, and then the double negative polarity and the double positive polarity are sequentially staggered; in the screen for displaying the frame In the pixel group of the two display lines and the third display line, each display line is alternately arranged in a double positive polarity and a double negative polarity; in order to display the pixels of the fourth and fifth display lines in the frame of the frame In the group, the polarity of the display data of the first pixel in each display line is negative polarity, and then the double positive polarity and the double negative polarity are sequentially staggered; and the sixth strip in the picture for displaying the frame is In the pixel group of the seventh display line, each display line is alternately arranged in a double negative polarity and a double positive polarity. Similarly, the polarity of the display data after the ninth display line is arranged by repeating the order of the polarity of the display data of the previous eight display lines.

With the above arrangement, the polarity distribution pattern of the pixels displaying the same primary color can also be made less concentrated, thereby achieving a relatively uniform display effect.

In summary, the present invention adopts a variety of regular display data polarity arrangement manners, and arranges the order of use of the display data polarity arrangement manner according to certain conditions, so that it can be matched with the special primary color pixel arrangement mode of the triangular panel. Make the color of the triangle panel more uniform.

While the present invention has been described in its preferred embodiments, the present invention is not intended to limit the invention, and the present invention may be modified and modified without departing from the spirit and scope of the invention. The scope of protection is subject to the definition of the scope of the patent application.

100, 110, 200, 210, 220‧‧‧ blocks

310a, 310b, 310c, 310d, 310e, 310f, 310g, 310h‧‧‧ pixel groups

320a, 320b, 320c‧‧‧ data lines

330, 332, 334, 340, 342, 344‧ ‧ pixels

FIG. 1A is a table of positive and negative polarities of displayed data in pixels generated by a two-point conversion driving method.

FIG. 1B is a schematic diagram of display data generated when a display of matrix-arranged pixels is driven by a two-point conversion driving method.

FIG. 1C is a schematic diagram of display data generated when a display of triangular pixels is driven by a two-point conversion driving method.

2A is a table of positive and negative polarities of displayed data in pixels generated by the two-column conversion driving method.

2B is a schematic diagram of display data generated when a display of matrix-arranged pixels is driven by a two-column conversion driving method.

2C is a schematic diagram of display data generated when a display of triangular pixels is driven by a two-column conversion driving method.

FIG. 3A is a list of display data polarity rows of a triangular panel according to an embodiment of the invention. FIG.

FIG. 3B is a schematic diagram of display data generated when the triangular panel is driven using the display data polarity arrangement of FIG. 3A.

4A to 4H are respectively a display data polarity conversion combination table obtained by combining different image data polarity conversion methods.

FIG. 5 is a list of display data polarity rows of a triangular panel according to another embodiment of the present invention.

Line‧‧‧ display line

Claims (10)

A triangular panel driving method is suitable for driving a triangular panel in which pixels are arranged in a triangular manner, the triangular panel includes a plurality of data lines and a first pixel, a second pixel, a third pixel and a fourth pixel; the triangle The panel driving method includes: providing a first display material to the first pixel in a frame image; and providing a second display material to the second pixel in the frame image; in the frame image, a third display material is provided to the third pixel; and a fourth display material is provided to the fourth pixel in the frame image, wherein the first pixel and the second pixel are located in the data lines a first data line is electrically coupled to the first data line, and the third pixel and the fourth pixel are located on both sides of the first data line and are electrically coupled to the first data line; The first pixel and the second pixel display a part of a display line, the third pixel and the fourth pixel display a part of another display line, and the first display material is the same as the second display material. polarity, The third display data and display data for the fourth different polarity. The method for driving a triangular panel according to claim 1, wherein the polarity of the display data of the triangular panel is two-point inversion. The method for driving a triangular panel according to the first aspect of the invention, wherein the display data polarity arrangement manner of the pixels displaying the same display line is one of the following four: Starting with double positive polarity, followed by staggered arrangement of double negative polarity and double positive polarity; starting with single positive polarity, followed by staggered arrangement of double negative polarity and double positive polarity; starting with single negative polarity Then, the double positive polarity and the double negative polarity are sequentially staggered; and the double negative polarity is used as the beginning, and then the double positive polarity and the double negative polarity are sequentially arranged alternately. The method for driving a triangular panel according to claim 3, wherein the polarity of the display data of the pixels for displaying the eight consecutive display lines is sequentially: displaying the first display of the eight consecutive display lines. The display data polarity arrangement manner of the pixels of the line is started with a single positive polarity; the display data polarity arrangement manner of the pixels of the second display line of the continuous eight display lines is started with a single positive polarity Displaying the polarity of the display data of the pixels of the third display line of the continuous eight display lines is the beginning of the double negative polarity; displaying the fourth display lines of the eight consecutive display lines The polarity of the display data of the pixel is the beginning of the double negative polarity; the polarity of the display data of the pixels of the fifth display line of the continuous eight display lines is the beginning of the single negative polarity; the display is continuous The display data polarity of the pixels of the sixth display line of the eight display lines is arranged with a single negative polarity as the beginning; the seventh of the continuous eight display lines is displayed. The display data polarity arrangement manner of the pixels of the display line is started with the double positive polarity; The polarity of the display data of the pixels of the eighth display line of the continuous eight display lines is displayed as the beginning of the double positive polarity. The method for driving a triangular panel according to claim 3, wherein the polarity of the display data of the pixels for displaying the eight consecutive display lines is sequentially: displaying the first display of the eight consecutive display lines. The polarity of the display data of the pixels of the line is arranged with a single positive polarity; the polarity of the display data of the pixels of the second display line of the continuous eight display lines is started with the double positive polarity. Displaying the polarity of the display data of the pixels of the third display line of the continuous eight display lines is started with the double positive polarity; displaying the fourth display lines of the consecutive eight display lines The polarity of the display data of the pixel is the beginning of the single negative polarity; the polarity of the display data of the pixels of the fifth display line of the continuous eight display lines is the beginning of the single negative polarity; the display is continuous The polarity of the display data of the pixels of the sixth display line of the eight display lines is the beginning of the double negative polarity; the seventh of the eight consecutive display lines is displayed. The display data polarity arrangement manner of the pixels of the display line is a start with a double negative polarity; and the display data polarity arrangement manner of the pixels of the eighth display line of the continuous eight display lines is a single positive polarity For the starter. A triangular panel driving method is suitable for driving a triangular panel in which pixels are arranged in a triangular manner, the triangular panel includes a plurality of data lines and a first pixel, a second pixel, a third pixel and a fourth pixel; the triangle Panel driver The method includes: providing a first display material to the first pixel in a frame picture; providing a second display material to the second pixel in the frame picture; in the frame picture, Providing a third display data to the third pixel; and providing a fourth display material to the fourth pixel in the frame image, wherein the first pixel is adjacent to the second pixel and located in the data lines Between a first data line and a second data line, and the third pixel is adjacent to the fourth pixel and located between the first data line and the second data line; wherein the first pixel and the first pixel The second pixel displays a portion of a display line, the third pixel and the fourth pixel display a portion of another display line, and the first display material and the second display material have the same polarity, and the third display data It is different in polarity from the fourth display material. The method for driving a triangular panel according to claim 6, wherein the polarity of the display data of the triangular panel is two-point inversion. The method for driving a triangular panel according to claim 6, wherein the polarity of the display data of the pixels displaying the same display line is formed by one of the following four: starting with a double positive polarity, and then The double negative polarity and the double positive polarity are sequentially staggered; the single positive polarity is the beginning, then the double negative polarity and the double positive polarity are sequentially staggered; the single negative polarity is the beginning, then the double positive polarity and the double The negative polarity is staggered in sequence; Starting from the double negative polarity, then the double positive polarity and the double negative polarity are staggered in sequence. The method for driving a triangular panel according to claim 8, wherein the polarity of the display data of the pixels for displaying the eight consecutive display lines is sequentially: displaying the first display of the eight consecutive display lines. The display data polarity arrangement manner of the pixels of the line is started with a single positive polarity; the display data polarity arrangement manner of the pixels of the second display line of the continuous eight display lines is started with a single positive polarity Displaying the polarity of the display data of the pixels of the third display line of the continuous eight display lines is the beginning of the double negative polarity; displaying the fourth display lines of the eight consecutive display lines The polarity of the display data of the pixel is the beginning of the double negative polarity; the polarity of the display data of the pixels of the fifth display line of the continuous eight display lines is the beginning of the single negative polarity; the display is continuous The display data polarity of the pixels of the sixth display line of the eight display lines is arranged with a single negative polarity as the beginning; the seventh of the continuous eight display lines is displayed. The display data polarity arrangement manner of the pixels of the display line is a start with a double positive polarity; and the display data polarity arrangement manner of the pixels of the eighth display line of the continuous eight display lines is a double positive polarity For the starter. The method for driving a triangular panel according to claim 8 , wherein the polarity of the display data of the pixels for displaying the eight consecutive display lines is sequentially: Displaying the polarity of the display data of the pixels of the first display line of the eight consecutive display lines as a single positive polarity; displaying the pixels of the second display line of the eight consecutive display lines The display data polarity arrangement mode is the start of the double positive polarity; the display data polarity arrangement manner of the pixels of the third display line of the continuous eight display lines is the start of the double positive polarity; the display is continuous eight The display data polarity of the pixels of the fourth display line in the display line is arranged in a manner of starting with a single negative polarity; displaying the polarity of the display data of the pixels of the fifth display line of the continuous eight display lines The method is to start with a single negative polarity; the display data polarity of the pixels of the sixth display line of the continuous eight display lines is arranged in a manner of starting with a double negative polarity; displaying the continuous eight display lines The display data polarity arrangement manner of the pixels of the seventh display line is a start with a double negative polarity; and displaying the pixels of the eighth display line of the continuous eight display lines Information for the polarity arrangement shown in those beginning with a single positive polarity.