KR20080033807A - Apparatus for driving plasma display panel and method thereof - Google Patents

Abstract

A method and an apparatus for driving a plasma display panel are provided to achieve a smooth oblique line at edges of an image by displaying images in respective sub-pixels forming a pixel. An apparatus for driving a PDP(Plasma Display Panel) includes an edge detector, a line error detector(263), and a line error compensator(264). The edge detector detects edge information from image data and detects an edge pixel corresponding to the edge information. The line error detector, including an edge information detector(261) and an edge pixel detector(262), detects a line error of the edge pixel. The line error compensator displays an image in respective sub-pixels based on the line error to compensate for the image data. The edge detector includes..

Description

Apparatus for driving plasma display panel and method

1 is a perspective view showing an internal structure of a three-electrode surface discharge plasma display panel to which a driving device of a display panel according to the present invention is applied.

2 is a block diagram schematically showing a driving apparatus of a plasma display panel as a preferred embodiment of the present invention.

3 is a timing diagram illustrating an embodiment of a drive signal output from each driver of FIG. 2.

4 is a diagram schematically illustrating a case where a line to be displayed exists on pixels.

FIG. 5 is a diagram schematically illustrating a case where a line to be displayed does not exist on pixels.

6 schematically illustrates an example of methods for detecting an edge.

7 is a diagram schematically showing an embodiment in which line errors are corrected by a method of driving a plasma display panel according to the present invention.

8 is a flowchart illustrating a method of driving a plasma display panel as a preferred embodiment of the present invention.

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

22: logic controller, 23: address driver,

24: X drive unit, 25: Y drive unit,

261: edge information detector, 262: edge pixel detector,

263: line error detection unit, 264: line error correction unit.

The present invention relates to an apparatus for driving a display panel and a method of driving the same. More particularly, the present invention relates to a display panel for generating an image data for each pixel unit and displaying an image for each pixel unit. A driving device and a driving method thereof are provided.

As flat panel display devices, plasma display panels (PDPs), which are easy to manufacture large panels, have attracted attention. A plasma display panel is a display device that displays an image by using a discharge phenomenon. In general, a plasma display panel can be classified into a direct current type and an alternating current type according to the type of driving voltage. Due to the disadvantages, the development of the AC plasma display panel has been made a lot.

An AC plasma display panel includes a three-electrode AC surface discharge type plasma display panel having three electrodes and driven by an AC voltage. The conventional three-electrode surface discharge plasma display panel is composed of a multi-layered plate, and is thinner, lighter, and wider than a conventional cathode ray tube (CRT), which is spatially advantageous.

As an example of a conventional plasma display panel, a three-electrode surface discharge plasma display panel, a driving apparatus thereof, and a driving method thereof are disclosed in US Patent No. 6,744,218 (name: Method of driving a plasma display panel in which the). width of display sustain pulse varies). Matters related to the plasma display panel, the driving apparatus, and the driving method disclosed in the above-mentioned US patent are included in the present specification, and a detailed description thereof will be omitted.

The plasma display panel includes a plurality of display pixels formed in a region where the sustain electrode and the address electrode cross each other, and one pixel includes three discharge cells (red, green, and blue), and discharges the discharge cells. The gray level of the image is expressed by adjusting the state. The sustain electrode consists of an X electrode and a Y electrode.

In order to express the gray scale of the plasma display panel, one frame applied to the plasma display panel may be configured with eight subfields having different emission counts to express 256 gray scales. That is, in the case where the image is to be displayed with 256 gray levels, the frame period (16.67 ms) corresponding to 1/60 second is divided into eight subfields. There is a reset period, an address period, and a sustain discharge period in each of the sub-fields to drive the plasma display panel.

In a typical plasma display panel, image data is generated in units of pixels with respect to an image signal input from the outside to represent an image in units of pixels. Therefore, the image displayed on the panel is represented by each pixel when it is expressed most precisely. In this case, each pixel may include two or more discharge cells, and in general, a unit pixel includes three subpixels of red, green, and blue to represent full color.

Such pixel-based image display has a problem in that an edge is not smoothly represented in the edge representation and a step phenomenon occurs. In this case, the problem that the stair phenomenon occurs in the oblique pattern occurs because there is no physical pixel in the coordinate value to represent the actual line.

SUMMARY OF THE INVENTION An object of the present invention is to provide an apparatus for driving a display panel and a method of driving the display panel capable of smoothly expressing an oblique line in edge representation by expressing an image in units of subpixels constituting pixels using edge information of image data. It is.

According to an embodiment of the present invention, image data is generated in units of pixels with respect to an image signal input from the outside to display an image in units of pixels, and the pixels drive the display panel including at least two subpixels.

(a) an edge detection step of detecting edge information in the image data and detecting edge pixels which become edges from the edge information;

(b) a line error detection step of detecting a line error for the edge pixel; And

and (c) a line error correction step of correcting the image data by expressing an image in units of subpixels with respect to the line error.

Step (a) may include: (a1) detecting the edge information from the image data; And (a2) detecting the edge pixel from the edge information.

In the step (a1), it is preferable to detect the edge information from the luminance difference of the adjacent pixels for each pixel.

In the step (a2), it is preferable to recognize the edge pixel when the luminance difference is greater than a preset reference value.

In the step (a1), all the pixels constituting the display panel are ordered, and in turn, the edge information is detected from the luminance difference with surrounding pixels surrounding the center pixel. It is desirable to be.

In the step (b), it is preferable to detect the line error by irradiating the eight peripheral pixels diagonally adjacent to the edge pixel and the four peripheral pixels adjacent up, down, left and right.

In the step (b), when a pixel displayed adjacent to the eight peripheral pixels with respect to the edge pixel is found, the adjacent displayed pixel becomes a second center pixel, and the When a third center pixel that is a pixel displayed adjacent to four neighboring pixels is found, or when a pixel that is displayed adjacent to the four peripheral pixels relative to the edge pixel is found, the adjacent displayed pixel is a second center. Preferably, the line error is detected when a third center pixel that is a pixel is found and is displayed adjacent to the eight peripheral pixels with respect to the second center pixel.

Among the displayed subpixels, a subpixel positioned at the center becomes a central subpixel, and in the step (c), the image data is arranged such that a line to be displayed with respect to the pixel having the line error passes through the central subpixel. It is desirable to be corrected.

In the step (c), it is preferable that the image data is corrected so that the line to be displayed does not pass the subpixel which is not displayed.

Preferably, the subpixels forming the pixels are adjacent to the left and right.

Another aspect of the present invention is to generate an image data in units of pixels for an image signal input from the outside to display an image in units of pixels, and the pixel includes at least two subpixels to drive a display panel. An edge detector which detects edge information from the image data and detects edge pixels which become edges from the edge information; A line error detector for detecting a line error with respect to the edge pixel; And a line error correction unit for correcting the image data by representing an image in units of subpixels with respect to the line error.

An edge information detector configured to detect the edge information from the image data; And an edge pixel detector for detecting the edge pixel from the edge information.

Preferably, the edge information detector detects the edge information from the luminance difference of the pixels adjacent to each of the pixels.

Preferably, the edge pixel detection unit recognizes the edge pixel when the luminance difference is greater than a preset reference value.

In the edge information detection unit, all pixels constituting the display panel are determined, the center pixels are sequentially formed in the order, and the edge information is detected from a luminance difference with surrounding pixels surrounding the center pixels. It is preferable.

Preferably, the line error detector detects the line error by irradiating the eight peripheral pixels diagonally adjacent to the edge pixel and the four peripheral pixels adjacent up, down, left, and right.

In the line error detection unit, when a pixel displayed adjacent to the edge pixels is found in the eight peripheral pixels, the adjacent pixel becomes a second center pixel, and the fourth pixel corresponds to the second center pixel. When a third center pixel that is a pixel displayed adjacent to each other in neighboring pixels is found, or when a pixel that is displayed adjacent in the four peripheral pixels with respect to the edge pixel is found, the adjacent displayed pixel is the second center pixel. If a third center pixel, which is a pixel displayed adjacent to the eight peripheral pixels with respect to the second center pixel, is found, the line error is preferably detected.

In the line error correcting unit, it is preferable that the image data is corrected such that a line to be displayed with respect to the pixel in which the line error has occurred passes through the center subpixel.

In the line error correcting unit, it is preferable that the image data is corrected such that the line to be displayed does not pass a subpixel that is not displayed.

According to the present invention, by using the edge information of the image data to represent the image in each sub-pixel unit constituting the pixel, it is possible to smoothly represent the oblique line in the edge representation.

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

1 is an internal perspective view showing the structure of a three-electrode surface discharge plasma display panel.

Referring to the drawings, between the front and rear glass substrates 10 and 13 of the surface discharge plasma display panel 1, the address electrode lines A _{R1 to} A _Bm , the dielectric layers 11 and 15, and the Y electrode line (Y ₁ to Y _n ), X electrode lines (X ₁ to X _n ), fluorescent layer 16, partition wall 17, and magnesium monoxide (MgO) layer 12 as a protective layer are provided.

The address electrode lines A _{R1 to} A _Bm are formed in a predetermined pattern on the front side of the rear glass substrate 13. The lower dielectric layer 15 is applied to the entire surface in front of the address electrode lines A _{R1 to} A _Bm . In front of the lower dielectric layer 15, barrier ribs 17 are formed in a direction parallel to the address electrode lines A _{R1 to} A _Bm . The partition walls 17 function to partition the discharge area of each discharge cell 14 and to prevent optical cross talk between the discharge cells 14. The fluorescent layer 16 is formed on the inner surface of the space formed between the lower dielectric layer 15 and the partition walls 17 formed on the rear glass substrate 13.

The X electrode lines X ₁ to X _n and the Y electrode lines Y ₁ to Y _n have a constant pattern on the rear side of the front glass substrate 10 to be orthogonal to the address electrode lines A _{R1 to} A _Bm . Is formed. Each intersection sets a corresponding discharge cell 14. Each X electrode line (X _{1 to} X _n ) and each Y electrode line (Y _{1 to} Y _n ) are combined with a transparent electrode line made of a transparent conductive material such as indium tin oxide (ITO) and a metal electrode line for increasing conductivity. Is formed. Here, the X electrode lines X ₁ to X _n become sustain electrodes in the respective discharge cells 14, and the Y electrode lines Y ₁ to Y _n correspond to scan electrodes in the respective discharge cells 14. And become an address electrode in the discharge cell 14 of each of the address electrode lines A _{R1 to} A _Bm .

In this case, scan electrodes are sequentially applied to select discharge cells to be displayed on the Y electrode lines. In addition, the X electrode lines become sustain electrodes that cause sustain discharge between the Y electrode lines.

2 is a block diagram schematically showing a driving apparatus of a plasma display panel as a preferred embodiment of the present invention.

Referring to the drawing, the driving device 20 of the plasma display panel includes an image processor 21, a logic controller 22, an address driver 23, an X driver 24, and a Y driver 25. The image processor 21 converts an external analog image signal into a digital signal to generate internal image signals. The internal video signal may be 8 bits of red (R), green (G), and blue (B) image data, a clock signal, a vertical and horizontal synchronization signal, and the like. The logic controller 22 generates driving control signals S _A , S _Y , and S _X according to an internal image signal from the image processor 21.

In this case, the driving unit such as the address driver 23, the X driver 24, and the Y driver 25 receives input from the driving control signals S _A , S _Y , and S _X , and generates respective driving signals. The applied driving signal to each of the electrode lines.

That is, the address driver 23 applies the display data signal corresponding to the address signal S _A input from the logic controller 22 to the address electrode lines A _{R1 to} A _Bm . The X driver 24 processes the X drive control signal S _X input from the logic controller 22, and applies the X drive control signal S _X to the X electrode lines X ₁ to X _n . The Y driver 25 processes the Y drive control signal S _Y input from the logic controller 22 and applies it to the Y electrode lines Y ₁ to Y _n .

In addition, the driving apparatus 20 of the plasma display panel is driven by the driving method of the plasma display panel shown in FIG. 8, and the specific driving method may be driven by the method shown in FIG. 8. The driving device 20 of the plasma display panel generates image data in units of pixels with respect to an image signal input from the outside, and displays an image in units of pixels, and the pixel includes at least two subpixels. Drive the panel.

The driving device 20 of the plasma display panel includes edge detection units 261 and 262; A line error detector 263; And a line error correction unit 264. The edge detectors 261 and 262 detect edge information from image data and detect edge pixels that become edges from the edge information. The edge information detectors 261 include: an edge information detector 261; And an edge pixel detector 262.

The edge information detector 261 detects edge information from the image data. The edge pixel detector 262 detects an edge pixel from the edge information. The line error detector 263 detects a line error with respect to the edge pixel. The line error correction unit 264 corrects the image data by expressing the image in units of subpixels with respect to the line error.

In the present embodiment, the driving device 20 of the plasma display panel will be described, but the present invention is not limited thereto. That is, the display panel driving apparatus including the edge detector, the line error detector, and the line error corrector may drive various kinds of display devices including LCDs, OLEDs, CRTs, and the like.

3 is a timing diagram illustrating an embodiment of a drive signal output from each driver of FIG. 2.

Referring to the drawings, a unit frame for driving the plasma display panel (1 of FIG. 3) is divided into a plurality of subfields, and each subfield SF includes a reset period PR, an address period PA, and a sustain period. Divided into (PS).

First, in the reset period PR, a reset pulse consisting of a rising pulse and a falling pulse is applied to the Y electrode lines Y ₁ to Y _n , and the falling pulse is applied to the X electrode lines X ₁ to X _n from the time of applying the falling pulse. Two voltages (bias voltages) are applied to perform reset discharge. All discharge cells are initialized by reset discharge. The rising pulse rises from the sustain discharge voltage (Vs) by the rising voltage (V _set ) and finally reaches the rising maximum voltage (V _set + Vs), and the falling pulse falls from the sustain discharge voltage (Vs) and finally falls The voltage V _nf is reached.

In the address period PA, scanning pulses are sequentially applied to the Y electrode lines Y ₁ to Y _n , and display data signals are applied to the address electrode lines A _{R1 to} A _Bm in accordance with the scanning pulses. Discharge is performed. The discharge cells to be subjected to the sustain discharge occurring in the sustain period PS by the address discharge are selected. The scan pulse has a scan high voltage (Vsch) and sequentially has a scan low voltage (Vscl) whose voltage is lower than the scan high voltage (Vsch), and the display data signal is adapted to the scan low voltage (Vscl) of the scan pulse. It has a positive address voltage Va.

In the sustain period PS, sustain pulses are alternately applied to the X electrode lines X ₁ to X _n and the Y electrode lines Y ₁ to Y _n to perform sustain discharge. Luminance is expressed according to the gray scale weight allocated to each subfield by the sustain discharge. The sustain pulse has an alternating discharge voltage Vs and a ground voltage Vg.

On the other hand, it is possible to output a drive signal different from that shown in Figure 3 from each of the driving unit of Figure 2 is not limited to that shown in FIG.

6 schematically illustrates an example of methods for detecting an edge. 7 is a diagram schematically showing an embodiment in which line errors are corrected by a method of driving a plasma display panel according to the present invention. 8 is a flowchart illustrating a method of driving a plasma display panel as a preferred embodiment of the present invention.

Referring to the drawing, the method of driving a plasma display panel (S800) generates image data in units of pixels with respect to an image signal input from the outside to display an image in units of pixels, and the pixels are at least two subpixels. Driving the display panel including the edge detection steps (S810 and S820); Line error detection step S830; And a line error correction step (S840).

In the edge detection steps S810 and S820, edge information is detected from image data, and edge pixels which become an edge are detected from the edge information. In the line error detection step S830, a line error is detected for the edge pixel. In the line error correction step (S840), the image data is corrected by representing an image in subpixel units with respect to the line error.

The edge detection steps S810 and S820 include an edge information detection step S810 and an edge pixel detection step S820. Edge information detection step (S810) detects the edge information from the image data. In the edge pixel detection step S820, an edge pixel is detected from the edge information.

4 illustrates a case where a line to be displayed exists on the pixels, and FIG. 5 illustrates a case where a line to be displayed does not exist on the pixels. In general, an image to be displayed is displayed in units of pixels in a display panel. In FIG. 4, a pixel is accurately positioned at a coordinate value to be represented by a line to be displayed.

However, in FIG. 5, the pixel is not exactly positioned at the coordinate value to be expressed by the line to be displayed. Therefore, it is mapped to the pixel closest to the coordinate value to be expressed. In this case, a difference occurs between the coordinate value originally intended to be expressed and the position of the pixel actually displayed, and an error on the display occurs. This error may be a line error in which the edge line to be displayed is not properly represented.

Therefore, in the present invention, the line error is detected in the line error detection step S830, and the line error is corrected in the line error correction step S840. In the line error correcting operation S840, an image is expressed in subpixel units with respect to a pixel in which a line error occurs and the image data is corrected.

As illustrated in FIG. 7, an image is displayed in units of subpixels when a pixel in which a line error occurs is represented, thereby representing some subpixels of the current pixel and some subpixels of an adjacent pixel as one pixel. In this embodiment, two or more subpixels adjacent to the left and right, for example, three subpixels of red, green, and blue form respective pixels. However, the present invention is not limited thereto and may be applied to a display panel having a subpixel structure having various structures.

In the edge information detection step S810, edge information is detected from a luminance difference between pixels adjacent to each pixel. To this end, all pixels constituting the panel (1 in FIG. 1) are ordered, and in this order, the center pixels are sequentially formed, and edge information can be detected from luminance differences with surrounding pixels surrounding the center pixels. have.

Conventional detection methods may be used as a method for detecting edge information in the edge information detection step S810. Information can be detected.

6 shows an example of detecting edge information, and (b) shows an example of detecting edge information by a sobel method with respect to the original image of (a). (c) shows an example in which edge information is detected by the prewitt method with respect to the original video of (a). (d) shows an example in which edge information is detected by a laplacian method with respect to the original image of (a).

In the edge pixel detection step S820, an edge pixel is detected from the edge information. In this case, when the luminance difference with the surrounding pixels surrounding the center pixel is larger than a preset reference value, the edge pixel may be recognized. In this case, the reference value may be an average luminance value of all pixels. However, the method of setting the reference value is not limited thereto, and the reference value may be determined experimentally. That is, it may be determined by various repetitive experiments for displaying images of various conditions and detecting edge pixels accordingly.

In the line error detection step S830, a line error is detected for the edge pixel. To this end, the line error may be detected by irradiating diagonally adjacent eight peripheral pixels and four peripheral pixels adjacent to each other vertically, vertically, and horizontally.

When a pixel displayed adjacent to the eight peripheral pixels with respect to the edge pixel is found, the adjacent displayed pixel becomes a second center pixel and is adjacent to the four peripheral pixels with respect to the second center pixel. A line error is detected when a third center pixel, which is a pixel displayed by the above, is found.

When a pixel displayed adjacent to the four peripheral pixels with respect to the edge pixel is found, the adjacent displayed pixel becomes a second center pixel and is adjacent to the eight peripheral pixels with respect to the second center pixel. A line error is detected when a third center pixel, which is a pixel displayed by the above, is found.

In this embodiment, line errors are detected by examining adjacent 3x3 pixels for each edge pixel. However, the present invention is not limited thereto, and the line error may be detected by examining adjacent 5 × 5 pixels, or 7 × 7 pixels or more neighboring pixels for each edge pixel.

In the line error correction step (S840), the image data is corrected by representing an image in subpixel units with respect to the line error. To this end, the image data is corrected such that a line to be displayed with respect to the pixel in which the line error has occurred passes through the center subpixel. At this time, among the subpixels forming each pixel to be displayed, the subpixel located at the center becomes the center subpixel of each pixel. Alternatively, the image data may be corrected such that the line to be displayed in the line error correction step S840 does not pass the sub-pixel that is not displayed.

In the embodiment shown in FIG. 7, in the line error detection step S830, each of the pixels is formed of red subpixels, green subpixels, and blue subpixels adjacent from left to right. Here, a second center pixel is found, which is a pixel displayed adjacently at eight peripheral pixels diagonally adjacent to the first edge pixel. In addition, a third center pixel, which is a pixel displayed adjacent to each other in four peripheral pixels that are vertically, vertically and horizontally adjacent to the second center pixel, is found. Thus, a line error is detected at the second center pixel.

Accordingly, in the line error correction step S840, the green subpixel and the blue subpixel of the second center pixel are not turned on, but instead the green subpixel and the blue subpixel of the adjacent pixel are first positioned in the direction of the reference pixel. Lights up. By rendering in units of sub pixels as described above, line errors can be minimized while expressing the same color. That is, in the embodiment of FIG. 7, before the correction, the line to be displayed passes through a portion where the line is not displayed, but does not pass through the portion where the line to display is not displayed.

In the line error correction method according to the present invention, since the correction is performed using a 3 × 3 mask which is the minimum unit in which the line error can occur, the line error can be effectively corrected even for a larger line error. In addition, since the subpixels are not diffused but transferred to the subpixels of the neighboring pixels, blurring of lines does not occur. In addition, the logic circuit can be easily implemented.

According to the driving apparatus of the display panel and the driving method thereof according to the present invention, by using the edge information of the image data to express the image in units of each sub-pixel constituting the pixel, it is possible to smoothly represent the diagonal line in the edge representation.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, it is merely an example, and those skilled in the art may realize various modifications and equivalent other embodiments therefrom. I can understand. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

Claims (28)

Generating image data in units of pixels with respect to an image signal input from the outside to display an image in units of pixels, and the pixels drive the display panel including at least two subpixels. (a) an edge detection step of detecting edge information in the image data and detecting edge pixels which become edges from the edge information; (b) a line error detection step of detecting a line error for the edge pixel; And and (c) a line error correction step of correcting the image data by representing an image in units of subpixels with respect to the line error. The method of claim 1, In step (a), (a1) detecting the edge information from the image data; And (a2) detecting the edge pixel from the edge information. The method of claim 2, And in the step (a1), detecting the edge information from the luminance difference of the pixels adjacent to each of the pixels. The method of claim 3, And in step (a2), recognizes the edge pixel when the luminance difference is greater than a preset reference value. The method of claim 4, wherein And the reference value is an average luminance value of all the pixels. The method of claim 2, And the edge information is detected by at least one of a sobel method, a prewitt method, and a laplacian method in the step (a1). The method of claim 2, In the step (a1), all the pixels constituting the display panel are ordered, and in turn, the edge information is detected from the luminance difference with surrounding pixels surrounding the center pixel. Method of driving a display panel. The method of claim 7, wherein And (b) detecting the line error by irradiating diagonally adjacent eight peripheral pixels and up, down, left, and right adjacent pixels around the edge pixel. The method of claim 8, In step (b), When a pixel displayed adjacent to the eight peripheral pixels with respect to the edge pixel is found, the adjacent displayed pixel becomes a second center pixel and is adjacent to the four peripheral pixels with respect to the second center pixel. The third center pixel that is the pixel being displayed is found, When a pixel displayed adjacent to the four peripheral pixels with respect to the edge pixel is found, the adjacent displayed pixel becomes a second center pixel and is adjacent to the eight peripheral pixels with respect to the second center pixel. If a third center pixel, which is the displayed pixel, is found, And a display panel for detecting the line error. The method of claim 1, Among the displayed subpixels, a subpixel positioned at the center becomes a central subpixel, and in the step (c), the image data is arranged such that a line to be displayed with respect to the pixel having the line error passes through the central subpixel. Method of driving the display panel to be corrected. The method of claim 1, Among the displayed subpixels, a subpixel positioned at the center becomes a central subpixel, and in the step (c), the image data is corrected so that the image data is corrected so as not to pass the subpixel where no line is displayed. Driving method. The method of claim 1, And the subpixels forming the pixels are adjacent to the left and right. The method of claim 1, And the pixel is formed by adjoining three subpixels from side to side. The method of claim 3, A method of driving a display panel for detecting the edge information from a luminance difference with adjacent 3x3, 5x5, or 7x7 pixels for each pixel. Generating image data in units of pixels with respect to an image signal input from the outside to display an image in units of pixels, and the pixels drive the display panel including at least two subpixels. An edge detector for detecting edge information from the image data and detecting edge pixels which become edges from the edge information; A line error detector for detecting a line error with respect to the edge pixel; And And a line error correcting unit to correct the image data by expressing the image in the sub-pixel units with respect to the line error. The method of claim 15, The edge detector, An edge information detector for detecting the edge information from the image data; And And an edge pixel detector for detecting the edge pixel from the edge information. The method of claim 16, And the edge information detector detects the edge information from the luminance difference of the pixels adjacent to each of the pixels. The method of claim 17, And the edge pixel detection unit recognizes the edge pixel when the luminance difference is greater than a preset reference value. The method of claim 18, And the reference value is an average luminance value of all the pixels. The method of claim 16, And the edge information detection unit detects the edge information by at least one of a sobel method, a prewitt method, and a laplacian method. The method of claim 16, In the edge information detection unit, all pixels constituting the display panel are determined, the center pixels are sequentially formed in the order, and the edge information is detected from a luminance difference with surrounding pixels surrounding the center pixels. Drive of display panel. The method of claim 21, And the line error detector detects the line error by irradiating the eight peripheral pixels diagonally adjacent to the edge pixel and the four peripheral pixels adjacent up, down, left, and right. The method of claim 22, In the line error detection unit, When a pixel displayed adjacent to the eight peripheral pixels with respect to the edge pixel is found, the adjacent displayed pixel becomes a second center pixel and is adjacent to the four peripheral pixels with respect to the second center pixel. The third center pixel that is the pixel being displayed is found, When a pixel displayed adjacent to the four peripheral pixels with respect to the edge pixel is found, the adjacent displayed pixel becomes a second center pixel and is adjacent to the eight peripheral pixels with respect to the second center pixel. If a third center pixel, which is the displayed pixel, is found, And a driving device of the display panel in which the line error is detected. The method of claim 15, Among the displayed subpixels, the subpixel positioned at the center becomes the central subpixel, and the image data is corrected such that the line to be displayed for the pixel in which the line error occurs in the line error correction unit passes through the central subpixel. Drive of the display panel. The method of claim 15, Driving of the display panel in which the image data is corrected so that the subpixel positioned at the center of the displayed subpixels becomes the center subpixel and the line error correcting unit does not pass the subpixel where the line to be displayed is not displayed. Device. The method of claim 15, And the subpixels forming the pixels are adjacent to the left and right. The method of claim 15, And the pixel is formed by adjoining three subpixels from side to side. The method of claim 17, And the edge information is detected for each pixel from the luminance difference from adjacent 3x3, 5x5, or 7x7 pixels.

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