KR101561871B1 - Apparatus and Method for generating Correction data, and Image quality correction system thereof - Google Patents

Abstract

A correction data generation device, a correction data generation method thereof, and an image quality correction system are provided. The correction data generation method detects brightness of a display panel, determines a non-uniform area of the display panel for each of the RGB colors based on the detected brightness, and calculates a screen division size and a correction amount for correcting the image quality of the display panel based on non- And generates correction data for a non-uniform area, and stores the generated correction data. At this time, the correction data is stored in a storage unit of the display device controlling the display panel, and the display device corrects the image quality of the display panel using the correction data.

Description

TECHNICAL FIELD [0001] The present invention relates to a correction data generation apparatus, a correction data generation method, and an image quality correction system,

More particularly, the present invention relates to a correction data generation device for generating correction data for correcting non-uniformity of a display panel, a correction data generation method thereof, a correction data generation method, And an image quality correction system.

The display panel exhibits uneven image quality characteristics due to various factors in the manufacturing process. For example, a particular area of the display panel may appear darker or lighter than other areas, or the color temperature of the display panel may be red or blue overall.

In particular, as the display panel becomes larger and thinner, various types of uneven image quality characteristics are appearing. For example, uneven image quality characteristics may appear only in a specific gradation period or a specific area of the display panel.

In the conventional method of improving the panel nonuniformity, only the limited form and the predetermined gradation can be corrected based on the luminance alone. However, there is a problem in that it is only limited to the characteristics of the display panel appearing in various forms and colors with a fixed fixed method. In addition, a panel with limited or only excessive correction may be generated, which may affect the productivity of the panel.

It is an object of the present invention to provide correction data for a nonuniform area of a display panel and to provide the correction data to a display device, A generating device, a correction data generating method thereof, and a picture quality correcting system.

According to an aspect of the present invention, there is provided a method of generating correction data, the method comprising: detecting brightness of a display panel; Determining a nonuniform region of the display panel according to the RGB colors based on the detected brightness; Generating correction data for the uneven area by determining a screen division size and a correction interval for correcting an image quality of the display panel based on the uneven area; And storing the generated correction data, wherein the correction data is stored in a storage unit of a display device controlling the display panel, and the display device displays the image quality of the display panel using the correction data Can be corrected.

The generating step may determine whether each of the R, G, and B colors is corrected based on the uneven area determined for each of the R, G, and B colors.

In addition, in the generating step, when a plurality of hues are required to be corrected, each of the correction periods may be determined for each color that needs to be corrected.

The generating may include: calculating a correction value for each of the correction intervals based on the determined screen size; And generating correction data including the calculated correction value and correction information, wherein the correction information includes at least one of information on the correction period, whether or not the correction is performed by the RGB color, and information on the screen size .

The number of data of the correction data may be calculated by adding the number of correction value data and the number of correction information data.

In addition, the generating step may allocate an address to the information on the correction period, whether the RGB color is corrected, and the screen size, so that the calculated correction value can be classified.

In addition, the display device may process the correction data using one of a timing controller, a frame rate controller, a scaler, and a separate hardware.

According to another aspect of the present invention, there is provided an apparatus for generating correction data comprising: a detector for detecting a luminance of a display panel; A determination unit for determining a non-uniform area of the display panel according to the RGB colors based on the detected brightness; A correction data generation unit for generating correction data for the uneven area by determining a screen division size and a correction interval for correcting an image quality of the display panel based on the uneven area; And a storage unit for storing the generated correction data, wherein the correction data is stored in a display device that controls the display panel, and the display device corrects the image quality of the display panel using the correction data .

The correction data generation unit may determine whether each of the RGB colors is corrected based on the nonuniform region determined for each of the RGB colors.

The correction data generation unit may determine a correction interval for each of the plurality of hues that requires color correction.

The correction data generation unit may calculate a correction value for each of the correction intervals based on the determined screen division size and generate correction data including the calculated correction value and correction information, The information on the correction interval, whether or not the RGB color is corrected, and information on the screen division size.

The number of data of the correction data may be calculated by adding the number of correction value data and the number of correction information data.

The correction data generation unit may allocate a separate address to be able to classify the correction period, the correction for each RGB color, and the screen division size to the calculated correction value.

In addition, the display device may process the correction data using one of a timing controller, a frame rate controller, a scaler, and a separate hardware.

According to another aspect of the present invention, there is provided an image quality correction system for detecting a luminance of a display panel, determining a non-uniform area of the display panel for each of RGB colors based on the detected luminance, A correction data generation device for generating correction data for the uneven area by determining a screen division size and a correction interval for correcting the image quality of the display panel based on the uneven area; And a display device for storing the generated correction data and processing the image of the uneven area among the images input based on the correction data.

According to various embodiments of the present invention as described above, it is possible to improve uniformity of image quality of a display panel, thereby realizing the same image quality in any area of the display panel. Further, by determining the correction method according to the characteristics of the display panel, it is possible to reduce the time for generating data to be used for correction, thereby minimizing the production cost.

1 is a block diagram schematically showing a configuration of a correction data generating apparatus according to an embodiment of the present invention;
Figures 2A-2D illustrate non-uniform areas of a display panel according to various embodiments of the present invention;
Figs. 3A to 3C are diagrams showing a configuration of a display device for correcting a non-uniform area, according to various embodiments of the present invention; Fig.
4 is a flowchart for explaining a correction data generation method according to an embodiment of the present invention;
5 is a flowchart specifically illustrating a method of generating correction data for a non-uniform area according to an embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the drawings. 1 is a block diagram showing a configuration of a correction data generation apparatus 100 according to an embodiment of the present invention. 1, the correction data generation apparatus 100 includes a detection unit 110, a determination unit 120, a correction data generation unit 130, and a storage unit 140.

The detection unit 110 detects the luminance of the display panel included in the display device. In particular, the detection unit 110 can detect the luminance by changing the input image of the display panel from a low gray level to a high gray level or from a high gray level to a low gray level based on white. In addition, the detection unit 110 may detect the luminance of an input image having a plurality of colors (e.g., red, green, and blue) of the display panel.

The determination unit 120 may detect a non-uniform area of the display panel based on the detected brightness. At this time, the determination unit 120 may determine a nonuniform region with respect to a single color (e.g., white), but this is only an example, and it is possible to determine a nonuniform region for each of a plurality of RGB colors.

On the other hand, the uneven region of the display panel refers to an area where an image different from the image to be displayed by the display panel is output. For example, the non-uniform area of the display panel may be a pixel line 210 that is output at a different luminance from the pixels of the other lines, as shown in FIG. 2A. As another example, the non-uniform area of the display panel may be a region 220 in the form of a long block, which outputs an image at a luminance different from that of pixels in other regions for a specific color, as shown in FIG. 2B. As another example, the non-uniform area of the display panel may be an area 230-1 or 230-2 in the form of a forward block that outputs an image having a different width from the pixels of other areas, as shown in FIG. 2C. At this time, the first region 230-1 and the second region 230-2 may be non-uniform regions for different colors. For example, the first area 230-1 may be a non-uniform area for green, and the second area 230-2 may be a non-uniform area for red. As another example, the uneven area of the display panel may be the entire area of the display panel in which the hue of the input image is generally shifted to a specific color (e.g., red) as shown in Fig. 2D.

The correction data generation unit 130 generates correction data for the uneven area determined by the determination unit 120. [

Specifically, the correction data generation unit 130 can determine whether or not the non-uniform area is corrected for each of a plurality of colors. At this time, when the display panel outputs a single color image (e.g., white image), the correction data generation unit 130 determines whether the display panel outputs a color other than a single color, It is possible to judge whether or not the correction is performed. For example, when the display panel outputs a white image, when the first area of the display panel outputs green and the second area outputs red, the correction data generation unit 130 generates the correction data, It is determined that correction for green is required for the first region and correction for red is required for the second region.

In addition, when the display panel outputs RGB images, the correction data generator 130 may determine whether a plurality of colors are corrected by determining whether there is a nonuniform region in the image from which each color is output. For example, when the display panel outputs a red image and another color is output to the red image, the correction data generator 130 may determine that red correction is necessary.

In addition, the correction data generation unit 130 may determine a screen size for screen correction for improving the image quality of the display panel. Specifically, the correction data generation unit 130 can determine the screen division size based on the size and shape of the uneven region. More specifically, the correction data generation unit 130 can determine the maximum area in which the uneven area can be divided as the screen division size for screen correction. For example, when a non-uniform region 220 as shown in FIG. 2B occurs, the correction data generation unit 130 may determine the screen division size for screen correction to be a region of (1x3) size. As another example, when non-uniform areas 230-1 and 230-2 as shown in FIG. 2C are generated, the correction data generator 130 may determine the screen size for screen correction to be a (2x2) size area. As described above, it is possible to generate the correction data having the smallest data amount as much as possible by determining the maximum area in which the uneven area can be divided based on the size and shape of the uneven area as the screen dividing size for screen correction.

Further, the correction data generation unit 130 can determine the correction period for the uneven region. At this time, the correction data generation unit 130 can determine a correction interval having a constant interval. For example, the correction data generation unit 130 can determine a correction period having eight intervals for 256 gradations. In addition, the correction data generation unit 130 can determine a correction interval having an irregular interval. At this time, the correction data generation unit 130 may have a correction section of a narrow section near the gradation where the uneven region is generated, and a correction section of the wide section near the gradation where the uneven region is not generated. For example, when a non-uniform region occurs at 25 gradations and 230 gradations, the correction data generator 130 may be set to have a narrower correction interval in the vicinity of 25 gradations and 230 gradations, Can be set to have a correction period of.

The correction data generation unit 130 may determine a correction value for a non-uniform area for each hue and correction interval. Specifically, when correction for a single color is required, the correction data generation unit 130 can determine a correction value for a non-uniform area according to a correction period of a single color. For example, when a nonuniform region occurs in a second correction period (for example, 20 gradations to 40 gradations) and a sixth correction period (for example, 100 gradations to 120 gradations) for a white image, The controller 130 may determine the correction values for the second and sixth correction periods.

When a plurality of hues are required to be corrected, the correction data generation unit 130 can determine a correction value for a non-uniform area according to a correction interval for each color that needs to be corrected. For example, when a non-uniform region occurs in the first correction period (for example, 0 to 15 gradations) and the seventh correction period (205 to 215 gradations) for the red image, and the third correction period (55 gradation to 70 gradation), the correction data generation unit 130 can determine the correction values for the first correction period and the seventh correction period of the red image, and the correction data for the third The correction value for the correction period can be determined.

In particular, the correction data generation unit 130 can determine the correction value such that the luminance and hue of the uneven region become the same as the other regions. For example, when the output luminance of the non-uniform region of the first correction period is higher than the normal luminance, the correction data generation unit 130 can determine the correction value so as to lower the output luminance of the first correction period. As another example, when a non-uniform region of the second correction region with respect to the white image is outputted in red, the correction data generation unit 130 may calculate the correction value so that the color of the second correction region with respect to the white image may be output in white It can be judged.

Then, the correction data generation unit 130 determines whether the output image is uniform by applying the correction value. When the output image obtained by applying the correction value is uniform, the correction data generation unit 130 can generate correction data including correction values and correction information. At this time, the correction information may include at least one of information on correction interval, whether RGB color is corrected, and information on a screen division size. When the output image is not uniform by applying the correction value, the correction data generation unit 130 may generate the correction value by performing the above-described process again. At this time, the correction data generation unit 130 may repeat the process described above until a uniform image is output.

The storage unit 140 stores the generated correction data. At this time, the generated correction data may include correction values and correction information as described above. Therefore, the number of data stored in the correction data can be determined as the sum of the number of correction value data and the number of correction information data.

At this time, the number of correction value data can be calculated by the following equation (1).

Here, H _p and V _p are the number of horizontal pixels and vertical pixels, respectively, of the display panel, H _blocksize and V _blocksize are the number of horizontal pixels and the number of vertical pixels of the correction screen division region, P _n is the number of correction intervals, _{Whether or not the} R _{correction is performed} , _whether the G _{correction is performed} , and _whether the B _correction is performed may be whether RGB color correction is performed.

Further, the number of pieces of correction information data can be calculated by Equation (2).

At this time, the correction information data included in the correction data is stored in a predefined specific address so as to be distinguished from the correction value data, and the number of correction data and addresses per correction interval can be determined so as to correspond to the correction information data.

As described above, the generated correction data can be stored in a display device that controls the display panel, and the display device can correct and output the RGB data of the image using the correction data. At this time, the display device can process the correction data using one of a timing controller, a frame rate controller, a scaler, and a separate hardware. This will be described with reference to FIGS. 3A to 3C.

3A is a diagram for explaining an embodiment in which a timing controller processes correction data according to the first embodiment of the present invention.

The first storage unit 311 stores correction data. At this time, the first storage unit 311 may be implemented as a persistent storage device. For example, the first storage unit 311 may be implemented as one of a flash memory and an EEPROM.

When the display device 300 is driven, the data loading unit 312 of the timing controller 310 may load the correction data and classify the data into correction value data and correction information data based on the previously designated address. The data loading unit 312 outputs the correction value data to the second storage unit 313 and outputs the correction information data to the correction information decoder 315. [ The second storage unit 313 may be implemented as a temporary storage device. For example, the second storage unit 313 may be implemented as DDR or EDRAM. The second storage unit 313 may output the correction value data to the third storage unit 314, which is a calculation storage space before performing the calculation of the correction coefficient. However, as described above, the correction value data is temporarily stored in the second storage unit 313, and then output to the third storage unit 314 is merely an embodiment. As shown in FIG. 6A, Value data may be output to the third storage unit 314 directly from the data loading unit 312. [ The correction information decoder 315 may decode the correction information data and output information on the correction section, information on whether or not the correction is performed for each RGB color, and information on the correction screen division size to the operation section 316, respectively.

The operation unit 316 included in the timing controller 310 receives the correction value data output from the third storage unit 314 and information on the correction period output from the correction information decoder 315, And the correction screen division size can be used to calculate a correction coefficient for a non-uniform area.

The correction unit 317 included in the timing controller 310 performs a correction operation using the correction coefficient calculated by the calculation unit 316 and the RGB data processed by the external image processing unit. The timing controller 310 can output image data using the corrected RGB data.

3B is a diagram for explaining an embodiment in which the image processing unit 320 processes correction data according to the second embodiment of the present invention. At this time, the image processing unit 320 may be configured for image processing such as a frame rate controller (FRC) or a scaler.

The first storage unit 321 stores correction data. At this time, the first storage unit 321 may be implemented as a persistent storage device. For example, the first storage unit 321 may be implemented as one of a flash memory and an EEPROM.

When the display device 300 is driven, the data loading unit 322 of the image processing unit 320 may load the correction data and classify the data into correction value data and correction information data based on the previously designated address. The data loading unit 322 outputs the correction value data to the second storage unit 323 and outputs the correction information data to the correction information decoder 325. [ The second storage unit 323 may be implemented as a temporary storage device. For example, the second storage unit 323 may be implemented as DDR or EDRAM. The second storage unit 323 may output the correction value data to the third storage unit 324, which is a calculation storage space before performing the calculation of the correction coefficient. However, as described above, the correction value data is temporarily stored in the second storage unit 313, and then output to the third storage unit 314 is merely an embodiment. As shown in FIG. 6B, Value data may be output to the third storage unit 314 directly from the data loading unit 312. [ The correction information decoder 325 may decode the correction information data and output information on the correction period, information on whether or not correction is performed for each RGB color, and information on the correction screen division size to the operation unit 326, respectively.

The calculation unit 326 included in the image processing unit 320 receives the correction value data output from the third storage unit 324 and information on the correction interval output from the correction information decoder 325, And the correction screen division size can be used to calculate a correction coefficient for a non-uniform area.

The correction unit 327 included in the image processing unit 320 performs a correction operation using the correction coefficient calculated by the calculation unit 326 and the input RGB data. The image processing unit 320 can output the corrected RGB data to the timing controller.

3C is a diagram for explaining an embodiment in which the separate hardware 330 for color correction processes the correction data according to the third embodiment of the present invention.

The first storage unit 331 stores correction data. At this time, the first storage unit 331 may be implemented as a persistent storage device. For example, the first storage unit 331 may be implemented as one of a flash memory and an EEPROM.

When the display device 300 is driven, the data loading unit 332 of the color correction hardware 330 may load the correction data and classify the data into correction value data and correction information data based on the previously designated address. The data loading unit 332 outputs the correction value data to the second storage unit 333 and outputs the correction information data to the correction information decoder 335. [ The second storage unit 333 may be implemented as a temporary storage device. For example, the second storage unit 333 may be implemented as DDR or EDRAM. The second storage unit 333 may output the correction value data to the third storage unit 334, which is a calculation storage space before performing the calculation of the correction coefficient. However, as described above, the correction value data is temporarily stored in the second storage unit 313, and then output to the third storage unit 314 is merely an embodiment. As shown in FIG. 6C, Value data may be output to the third storage unit 314 directly from the data loading unit 312. [ Then, the correction information decoder 335 can output the information on the correction section, information on whether or not correction is performed for each RGB color, and information on the correction screen division size to the operation section 336 by decoding the correction information data.

The operation unit 336 included in the color correction hardware 330 receives the correction value data output from the third storage unit 334 and information on the correction period output from the correction information decoder 335, The correction coefficient for the non-uniform area can be calculated using the information and the information on the screen division size for correction.

The correction unit 337 included in the color correction hardware 330 performs a correction operation using the correction coefficients calculated by the calculation unit 326 and the RGB data input from the image processing unit (for example, FRC or scaler) do. The color correction hardware 320 can output the corrected RGB data to the timing controller.

According to the various embodiments as described above, the display device 300 can perform the color correction operation for the non-uniform area.

Hereinafter, a correction data generating method will be described with reference to Figs. 4 and 5. Fig. 4 is a flowchart for explaining a correction data generation method according to an embodiment of the present invention.

First, the correction data generation device 100 detects the luminance of the display panel (S410). Specifically, the correction data generation apparatus 100 can detect the luminance while changing the input image of the display panel from a low gray level to a high gray level or a high gray level to a low gray level on a white basis. Further, the correction data generation apparatus 100 can detect the luminance of an input image having a plurality of colors (e.g., red, green, blue, and the like) of the display panel.

Then, the correction data generation device 100 determines a non-uniform area based on the detected luminance (S420). At this time, the correction data generation apparatus 100 can determine a nonuniform region with respect to a single color (e.g., white), but this is merely an embodiment, have.

Then, the correction data generation device 100 generates correction data for a nonuniform area (S430). This will be described in detail with reference to FIG.

First, the correction data generation apparatus 100 determines whether or not correction is performed for each of RGB colors (S510).

Then, the correction data generation apparatus 100 determines a correction screen division size (S520). At this time, the correction data generation apparatus 100 can determine the size of the divisional screen for correction based on the size and shape of the non-uniform region to a maximum size that can divide the non-uniform region.

Then, the correction data generation apparatus 100 determines a correction interval for each color (S530). At this time, the correction data generation apparatus 100 can determine the correction period based on the number of gradations at which the uneven region appears.

Then, the correction data generation apparatus 100 determines a correction value of the uneven region for each hue and correction interval (S540).

Then, the correction data generation apparatus 100 again determines whether the corrected screen of the display panel according to the correction value is uniform (S550).

If the corrected screen is uniform (S550-Y), the correction data generation device 100 generates correction data including correction values and correction information (S560). At this time, the correction information may include information on whether or not the RGB color is corrected, the size of the screen division for correction, and the correction interval. If the corrected screen is not uniform (S550-N), the correction data generation apparatus 100 may return to step S510 and perform the correction operation again.

Referring again to FIG. 4, the correction data generation device 100 stores the generated correction data (S440).

Thus, the uniformity of the image quality of the display panel is improved, and the same image quality can be realized in any area of the display panel. Further, by determining the correction method according to the characteristics of the display panel, it is possible to reduce the time for generating data to be used for correction, thereby minimizing the production cost.

The program code for carrying out the task management method according to various embodiments as described above may be stored in a non-transitory computer readable medium. A non-transitory readable medium is a medium that stores data for a short period of time, such as a register, cache, memory, etc., but semi-permanently stores data and is readable by the apparatus. In particular, the various applications or programs described above may be stored on non-volatile readable media such as CD, DVD, hard disk, Blu-ray disk, USB, memory card, ROM,

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the present invention.

110: Detection unit 120:
130: correction data generation unit 140:

Claims (15)

In the correction data generation method,
Detecting luminance of the display panel;
Determining a nonuniform region of the display panel according to the RGB colors based on the detected brightness;
Generating correction data for the uneven area by determining a screen division area and a correction interval for correcting the image quality of the display panel based on the unevenness area; And
And storing the generated correction data,
Wherein the correction data is stored in a storage unit of a display device controlling the display panel, the display device corrects the image quality of the display panel using the correction data,
Wherein the generating comprises:
A screen division area which is a maximum area in which the nonuniform area can be divided is determined based on at least one of the size and the shape of the uneven area and the correction data is generated based on the size of the screen division area Data generation method. The method according to claim 1,
Wherein the generating comprises:
And determining whether each of the RGB colors is corrected based on the uneven region determined for each of the RGB colors. 3. The method of claim 2,
Wherein the generating comprises:
Wherein when the correction for a plurality of colors is required, each of the correction periods is determined for each of the colors that need to be corrected. 3. The method of claim 2,
Wherein the generating comprises:
Calculating a correction value for each of the correction intervals based on the determined screen division area; And
And generating correction data including the calculated correction value and correction information,
Wherein the correction information includes at least one of the correction interval, whether or not the RGB color is corrected, and information on the screen division area. 5. The method of claim 4,
Wherein the number of data of the correction data is calculated by adding the number of correction value data and the number of correction information data. 5. The method of claim 4,
Wherein the generating comprises:
Wherein an address is allocated so that the correction period, the correction for each RGB color, and the information about the screen division area can be classified with the calculated correction value. The method according to claim 1,
The display device includes:
Wherein the correction data is processed using one of a timing controller, a frame rate controller, a scaler, and a separate hardware. In the correction data generation device,
A detector for detecting the brightness of the display panel;
A determination unit for determining a non-uniform area of the display panel according to the RGB colors based on the detected brightness;
A correction data generation unit for generating a correction data for the uneven area by determining a screen division area and a correction interval for correcting an image quality of the display panel based on the unevenness area; And
And a storage unit for storing the generated correction data,
Wherein the correction data is stored in a display device controlling the display panel, the display device corrects the image quality of the display panel using the correction data,
Wherein the correction data generation unit comprises:
A screen division area which is a maximum area in which the nonuniform area can be divided is determined based on at least one of the size and the shape of the uneven area and the correction data is generated based on the size of the screen division area Data generating device. 9. The method of claim 8,
Wherein the correction data generation unit comprises:
And determines whether or not each of the RGB colors is corrected on the basis of the uneven region determined for each of the RGB colors. 10. The method of claim 9,
Wherein the correction data generation unit comprises:
And when the correction for a plurality of colors is required, each of the correction periods is determined for each color requiring correction. 10. The method of claim 9,
Wherein the correction data generation unit comprises:
Calculates a correction value for each of the correction sections based on the determined screen division area, generates correction data including the calculated correction value and correction information,
Wherein the correction information includes at least one of the correction interval, whether or not the RGB color is corrected, and information on the screen division area. 12. The method of claim 11,
Wherein the number of data of the correction data is calculated by adding the number of correction value data and the number of correction information data. 12. The method of claim 11,
Wherein the correction data generation unit comprises:
Wherein the correction data generation unit assigns a separate address so that the correction period, the correction for each RGB color, and the information about the screen division area can be classified with the calculated correction value. 9. The method of claim 8,
The display device includes:
Wherein the correction data is processed using one of a timing controller, a frame rate controller, a scaler, and a separate hardware. A picture quality correction system comprising:
The method includes determining brightness of a display panel, determining a non-uniform area of the display panel for each of the R, G, and B colors based on the detected brightness, determining a screen division area and a correction area for correcting the image quality of the display panel based on the non- A correction data generation device for generating correction data for the uneven area; And
And a display device for storing the generated correction data and processing an image of the uneven area among the images input based on the correction data,
Wherein the correction data generation device comprises:
Determining a screen division area which is a maximum area in which the nonuniform area can be divided based on at least one of a size and a shape of the uneven area and generating the correction data based on the size of the screen division area Correction system.

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