KR20170127294A - Apparatus for image compensation and display device including the same - Google Patents

Abstract

The present invention provides an image compensation device which adaptively compensates a gradation level of a specific area among image signals by an operation time of a display device and can generate image data, and the display device including the same. The image compensation device selects one among multiple compensation values having different levels according to a result counting the operation time of the display device, and compensates the gradation level of the specific area of the image signal by using the compensation value to generate the image data.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image compensation apparatus,

The present invention relates to an image compensation apparatus, and more particularly, to an image compensation apparatus capable of performing adaptive image compensation on a specific region of an image as the operation time of the display apparatus increases, and a display apparatus including the same.

Examples of flat panel display devices include a liquid crystal display (LCD), a plasma display panel (PDP), a field emission display (FED), a light emitting diode (LED) Diode Display Device) are continuously being developed. Of these flat panel display devices, liquid crystal display devices are being applied to a variety of applications due to advantages of mass production technology, ease of driving means, high image quality and large screen realization.

The liquid crystal display comprises a liquid crystal panel in which a plurality of liquid crystal cells are arranged in a matrix form, a backlight unit for supplying light to the liquid crystal panel, and a driving circuit for driving the liquid crystal panel and the backlight unit. In the liquid crystal display device, the arrangement state of the liquid crystal is changed according to the voltage formed between the pixel electrode and the common electrode for each liquid crystal cell, and the image is displayed by adjusting the transmittance of the light supplied from the backlight unit through the arrangement of the liquid crystal.

A liquid crystal panel of a liquid crystal display includes an array substrate having a plurality of thin film transistors (TFT) manufactured by a semiconductor process including a photolithography process. At this time, due to the deviation of the photolithography process, for example, the unevenness of the exposure process, line-shaped unevenness appears on the array substrate. Such an unevenness is caused by an overlap area between electrodes of a thin film transistor, a parasitic capacitance between a plurality of signal wirings, a parasitic capacitance between a signal wiring and a pixel electrode due to unevenness of the exposure process in the manufacturing process of the array substrate.

Fig. 1A shows an example of line-shaped unevenness occurring on a screen displayed on a liquid crystal display device.

The smear region RB is generated in the liquid crystal panel of the liquid crystal display device due to the unevenness of the exposure process described above. The brightness of the stray area RB is lower than that of the other area, i.e., the steady area RA. Therefore, the brightness deviation between the steady area RA and the stray area RB in the image IS displayed on the liquid crystal panel . Therefore, the display quality of the liquid crystal display device is deteriorated due to the luminance deviation.

Accordingly, compensation methods for a smear region RB of a liquid crystal panel have been proposed. In a conventional liquid crystal display device, as shown in FIG. 1B, a gradation level of a video signal corresponding to a smear region RB is set to a compensation value? ) To compensate for the decrease in the luminance of the streak area RB. When the image IS is displayed at the same gradation level in the liquid crystal panel by this image compensation method, the deviation between the normal region luminance LA1 and the smear region luminance LB1 is eliminated, and accordingly, the display quality of the liquid crystal display device .

Here, the compensation value alpha used for image compensation is a gradation level due to the luminance deviation between the normal region RA and the smudge region RB, and is set to a fixed value in the inspection step performed before shipment of the liquid crystal display device .

Meanwhile, the conventional image compensation method does not consider the operation time of the liquid crystal display device. In other words, as the operation time of the liquid crystal display device is increased, the performance of the backlight unit deteriorates, thereby lowering the brightness of light emitted from the backlight unit. The deviation between the steady region luminance LA2 and the stray region luminance LB2 shown in Fig. 1C is smaller than the deviation between the steady region luminance LA1 and the stray region luminance LB1 shown in Fig. do.

However, the compensation value alpha of the conventional image compensation method is set according to the initial state, that is, the luminance deviation between the steady-state luminance LA1 and the stray area luminance LB1 shown in Fig. 1B. Thus, when the liquid crystal display device is operated for several hundred hours or more and the gradation level of the image signal is compensated by the conventional image compensation method, as shown in FIG. 1C, the compensation value? The region RB is overcompensated.

The smear region luminance LB2 of the image IS displayed on the liquid crystal display device is increased as compared with the normal region luminance LA1 and the smear region RB appears brighter than the normal region RA, The display quality of the apparatus is degraded.

The present invention provides an image compensation apparatus capable of performing adaptive image compensation with respect to a specific region of an image as the operation time of a display apparatus increases, and a display apparatus including the same.

According to an aspect of the present invention, an image compensation apparatus compensates a gradation level of a video signal from a selected one of a plurality of compensation values according to an operation time of a display apparatus to generate image data. The image compensation apparatus includes a storage unit, a counter, a selection unit, and a data generation unit.

In the storage unit of the image compensation apparatus, a plurality of compensation values having different levels according to the operation time of the display apparatus are stored. The counter outputs a selection signal according to the result of counting the operation time of the display device. The selection unit selects one of a plurality of compensation values of the storage unit in response to the selection signal and outputs the compensation data. The data generator compensates the gradation level of the specific area of the video signal according to the compensation data to generate the image data.

According to an aspect of the present invention, there is provided a display device including an image compensator that compensates a gradation level of a specific region among image signals input from an external system according to an operation time of a display panel to generate image data.

The image compensation apparatus according to the present invention can prevent the gradation level and the compensation of the image signal by decreasing the gradation level compensation magnitude for a specific region of the image signal as the operation time of the display apparatus is increased. Therefore, even when the operation time of the display device is increased, the luminance deviation between the normal region and the smudged region can be eliminated in the displayed image, and thus, the luminance unevenness due to the luminance variation prevents the occurrence of image quality defects in the display image .

Fig. 1A shows an example of line-shaped unevenness occurring on a screen displayed on a liquid crystal display device.
1B and 1C are views showing a method of compensating an image of a conventional liquid crystal display device.
2 is a view showing a display device according to an embodiment of the present invention.
3 is a diagram showing the configuration of the image compensation unit shown in FIG.
4 is an operation flowchart showing the operation of the image compensating unit.
5 is a diagram illustrating an example of a compensation value stored in the image compensation unit.
6A to 6C are diagrams showing signal waveforms according to the operation of the image compensating unit.

Hereinafter, an image compensation apparatus and a display device including the image compensation apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing a display device according to an embodiment of the present invention.

Referring to Fig. 2, the display apparatus 100 of the present embodiment may include a display panel 101, a backlight unit 102, and driving circuits for driving them. The driving circuits may include a timing control unit 106, a gate driving unit 103, a data driving unit 104, and a backlight driving unit 105.

The display panel 101 may be a liquid crystal panel in which a liquid crystal layer (not shown) is interposed between two substrates, for example, an array substrate (not shown) and a color filter substrate (not shown). The display panel 101 may include a plurality of gate lines GL and a plurality of data lines DL which intersect with each other to define pixel regions. A pixel P including the thin film transistor T and the liquid crystal cell LC may be formed in each pixel region.

The thin film transistor T of each pixel P has a gate electrode connected to the gate line GL, a source electrode connected to the data line DL and a drain electrode connected to one end of the liquid crystal cell LC. One end of the liquid crystal cell LC is connected to the drain electrode of the thin film transistor T, and a common voltage is applied to the other end.

The thin film transistor T is turned on by the gate signal applied through the gate line GL and transfers the pixel voltage applied through the data line DL to the liquid crystal cell LC. The liquid crystal cell LC charges the pixel voltage transferred from the thin film transistor T and holds the charged pixel voltage until the next frame of the display panel 101. [ Further, the liquid crystal cell LC changes the arrangement state of the liquid crystal according to the electric field formed by the charged pixel voltage and the common voltage applied to the other end, thereby adjusting the light transmittance, thereby displaying an image.

The backlight unit 102 is disposed below the display panel 101 and can provide light of a predetermined brightness to the display panel 101 under the control of the backlight driver 105. [ The backlight unit 102 may include a light source (not shown) such as a lamp or a light emitting diode. The backlight unit 102 can reduce the brightness of light emitted from the light source as the operating time of the display device 100 is increased.

The timing control unit 106 can generate the gate control signal GCS, the data control signal DCS and the backlight control signal BCS in accordance with the control signal CNT provided from an external system (not shown). The control signal CNT may include a horizontal synchronization signal Hsync, a vertical synchronization signal Vsync, a data enable signal DE and a clock signal DCLK. The gate control signal GCS may be output to the gate driver 103 and the data control signal DCS may be output to the data driver 104 and the backlight control signal BCS may be output to the backlight driver 105. [ The gate control signal GCS may include a gate start pulse GSP, a gate shift clock GSC, an output enable signal GOE, and the like. The data control signal DCS may include a source start pulse SSP, a source sampling clock SSC, an output enable signal SOE, a polarity control signal POL, and the like. The backlight control signal BCS may include a dimming signal or the like.

The timing controller 106 can generate image data (DATA) from a video signal (RGB) input from an external system. The video data DATA may be output to the data driver 104 together with the data control signal DCS.

The image data DATA output from the timing controller 106 may be data in which the gradation level of the data corresponding to the pixel P in the specific area of the display panel 101 is compensated. For example, in the display panel 101, defects such as spots appear in a specific area due to a variation in a manufacturing process. Due to such a defect, the image of a specific region of the image displayed on the display panel 101 is displayed with a reduced luminance. The timing controller 106 performs image compensation for increasing the gradation level of the image signal RGB corresponding to the specific area where the image is spots in the display panel 101. The image data DATA Can be output. The image displayed on the display panel 101 by this image data (DATA) has a uniform luminance distribution.

For this, the timing controller 106 may include an image compensator 110. The image compensation unit 110 may generate image data DATA by compensating for a video signal RGB corresponding to a specific area of the display panel 101 among the image signals RGB input from the external system. The image compensation unit 110 stores a plurality of compensation values and can perform image compensation to increase the gradation level of the image signal RGB. Each of the plurality of compensation values may include information on a coordinate for a specific area where the speckle is generated in the display panel 101, and a gradation level compensation size accordingly.

The image compensating unit 110 may adjust the gradation level compensating size of the image signal RGB by selectively using the compensation value according to the operation time of the display panel 101, that is, the operation time of the display device 100 .

That is, the image compensating unit 110 performs image compensation so that the compensation size of the gradation level for a specific region of the image signal RGB is reduced as the operation time of the display device 100 increases, Can be generated. Accordingly, the image compensating unit 110 can prevent the luminance of the specific area in which the smear is generated in the display panel 101 from being increased from the peripheral area, even if the light luminance is reduced by the increase of the operation time of the display device 100 have. The configuration and operation of the image compensating unit 110 will be described later in detail with reference to the drawings.

The gate driver 103 may generate a gate signal in accordance with the gate control signal GCS provided from the timing controller 106. [ The gate signal may be sequentially output to the plurality of gate lines GL of the display panel 101. [

The data driver 104 can generate a data signal, that is, a pixel voltage, from the image data (DATA) in accordance with the data control signal DCS provided from the timing controller 106. [ The pixel voltage can be simultaneously output to the plurality of data lines DL of the display panel 101. [

The backlight driving unit 105 may generate a backlight driving signal in accordance with the backlight control signal provided from the timing control unit 106. [ The backlight driving signal is outputted to the backlight unit 102 to operate it. The backlight unit 102 can provide the display panel 101 with light generated by the backlight driving signal.

3 is a diagram showing the configuration of the image compensation unit shown in FIG.

3, the image compensation unit 110 may include a storage unit 120, a selection unit 140, a counter 130, and a data generation unit 150. FIG.

The storage unit 120 may include a plurality of lookup tables LUT1 to LUTn. Compensation values having different levels, e.g., the first compensation value a1 through the N compensation value an, may be stored in correspondence with the plurality of lookup tables LUT1 through LUTn, respectively. Each of the first compensation value a1 to the N compensation value an may include a plurality of representative values each corresponding to at least four representative gradations of the image displayed on the display panel 101. [

5, the first lookup table LUT1 of the storage unit 120 stores a plurality of first representative values a1-1 through a1-4 having a predetermined level, 1 compensation value a1 is stored. The plurality of first representative values a1-1 to a1-4 may correspond to at least four representative gradations of the image. For example, the 1-1 second representative value a1-1 of the first compensation value a1 corresponds to the 32nd gradation, the 1-2 representative value a1-2 corresponds to the 64th gradation, -3 representative value a1-3 corresponds to the 128th gradation, and the 1-4 representative value a1-4 corresponds to the 192nd gradation.

The second lookup table LUT2 of the storage unit 120 stores a second compensation value a2 including a plurality of second representative values a2-1 to a2-4 having a predetermined level. A plurality of second representative values a2-1 to a2-4 may correspond to at least four representative gradations of the image in the same manner as the plurality of first representative values a1-1 to a1-4 . For example, the 2-1 representative value a2-1 of the second compensation value a2 corresponds to the 32nd gradation, the 2-2 representative value a2-2 corresponds to the 64th gradation, -3 representative value a2-3 corresponds to the 128th gradation, and the 2-4 representative value a2-4 corresponds to the 192nd gradation. At this time, the level of each of the second representative values a2-1 to a2-4 may be smaller than the level of the corresponding first representative values a1-1 to a1-4 at the same gray level.

The N-th lookup table LUTn of the storage unit 120 stores an N-th compensation value an including a plurality of N-th representative values an-1 to an-4 having a predetermined level. The plurality of Nth representative values an-1 to an-4 may correspond to at least four representative gradations of the image as the plurality of second representative values a2-1 to a2-4 respectively . For example, the N-1th representative value an-1 of the Nth compensation value an corresponds to the 32nd gradation, the N-2 representative value an-2 corresponds to the 64th gradation, -3 representative value an-3 corresponds to the 128th gradation, and the (N-4) representative value (an-4) corresponds to the 192nd gradation. At this time, the levels of the plurality of Nth representative values an-1 to an-4 may be smaller than the levels of the corresponding second representative values a2-1 to a2-4 at the same gray level.

Each of the first compensation value a1 to the N compensation value an may further include a representative value corresponding to the 0th gradation and the 255th gradation of the image displayed on the display panel 101, The representative value of each compensation value may be all zero.

The first compensation value a1 to the N compensation value an stored in the storage unit 120 may be a value set in the inspection process of the display device 100. [ For example, the first compensation value a1 is set in correspondence with the initial motion of the display device 100, the second compensation value a2 is set in correspondence with the first motion of the display device 100, The value an may be set corresponding to the Nth movement opening of the display apparatus 100. [

Here, the initial operation period of the display apparatus 100 may mean a range from the initial operation time to several tens of hours. The first operation period of the display device 100 may mean a range from several hours to several hundred hours. The Nth operation period of the display device 100 may mean a range of several hundred hours to several thousand hours. The initial operation period, the first operation period, and the Nth operation period of the display apparatus 100 may be defined at the same time intervals or may be defined at different time intervals.

As described above, the storage unit 120 of the present embodiment may include a plurality of lookup tables LUT1 to LUTn that respectively store compensation values a1 to an of different levels according to the operation time of the display device 100 . Each of the plurality of compensation values a1 to an may include information on coordinates of an area where image compensation is to be performed and information on the size of the image compensation among the image signals RGB. One of the plurality of compensation values a1 to an may be selected by the selection unit 140 to be described later and the image compensation unit 110 may compensate the compensation signal for the video signal & (R, G, and B).

The counter 130 counts the operation time DT of the display device 100 and can output the selection signal SS accordingly. The counter 130 can count the operation time DT of the display device 100 in such a manner as to count cumulatively from the time of the first operation of the display device 100. [ The counter 130 then compares the count value of the operation time DT with the N reference values Refn and outputs the selection signal SS according to the comparison result. Here, the N reference values Refn may be set according to the operation time of the display device 100 and may be the same as the number of the lookup tables LUT1 to LUTn of the storage unit 120 described above.

On the other hand, the counter 130 counts the operation time DT from the moment the first display device 100 is powered on, and temporarily turns off the power of the display device 100 by the user. off, the count value for the operation time DT can be stored.

The selecting unit 140 selects one of the plurality of compensation values a1 to an of the storage unit 120 in response to the selection signal SS output from the counter 130, . As described above, since the plurality of compensation values a1 to an stored in the storage unit 120 have different levels according to the operation time of the display device 100, the selection unit 140 selects the selection signal SS, A of different levels according to the operation time of the display device 100 according to the operation time of the display device 100. [

The data generator 150 may compensate the gradation level for a specific area of the image signal RGB according to the compensation data ΔA outputted from the selector 140 and generate image data DATA corresponding thereto have. The data generator 150 may generate the image data DATA by compensating for the increase of the gradation level in a specific region of the image signal RGB according to the compensation data ΔA. The image data (DATA) may be output to the data driver (104).

Here, the compensation data? A output from the selector 140 includes compensation values corresponding to four representative gradations of the image. Accordingly, the data generating unit 150 can generate the image data (DATA) by applying the linear compensation method using the compensation data (? A) to the remaining gradations excluding the four representative gradations of the image signal (RGB) .

For example, if image compensation is performed on a video signal RGB corresponding to the 60th gray level of the video signal RGB, the data generator 150 generates the 32nd gray level and the 32nd gray level of the compensation values of the compensation data? The image data (DATA) can be generated by linearly compensating the image signal of the 60th gradation by using the compensation value corresponding to each of the 64 gradations.

As described above, the image compensator 110 selects one of a plurality of compensation values a1 to an at different levels stored according to the operation time of the display device 100, So as to increase the gradation level of the image. Therefore, even if the brightness of the backlight unit 102 is reduced due to an increase in the operation time of the display device 100, the image compensation unit 110 of the present embodiment can reduce the size of the image compensation for a specific region of the image signal RGB It can be adjusted adaptively. This makes it possible to prevent the gradation level of the specific area of the display panel 101 from being over compensated, thereby improving the occurrence of image quality defects in the displayed image.

FIG. 4 is a flowchart illustrating the operation of the image compensating unit of the present invention, and FIGS. 6A to 6C are diagrams showing signal waveforms according to the operation of the image compensating unit.

3 and 4, the counter 130 of the image compensating unit 110 may count the operation time DT of the display device 100 (S10). Here, the counter 130 can count the operation time DT of the display device 100 in a cumulative manner.

Next, the counter 130 may compare the count value of the operation time DT with a plurality of reference values Ref (n-1), Refn. Then, the counter 130 can output the selection signal SS according to the comparison result (S20).

As described above, the plurality of reference values (Ref (n-1), Refn) may be set to N values according to the operation time of the display device 100. The counter 130 includes a plurality of reference values ( Ref (n-1), Refn), the selection signal SS corresponding to the range corresponding to the count value can be output.

For example, if the count value is between the reference values forming a range between the initial operating positions of the display device 100 among the plurality of reference values Ref (n-1), Refn, The count value may be set to a range between the first movement openings of the display device 100 among the plurality of reference values Ref (n-1) and Refn The counter 130 can output the selection signal SS corresponding to the first operation hole of the display device 100. If the count value is larger than the number of reference values Ref n -1, and Refn, the counter 130 counts the selection signal SS corresponding to the Nth operation port of the display device 100, Can be output.

In response to the selection signal SS output from the counter 130, the selection unit 140 selects one of a plurality of compensation values a1 to an stored in the storage unit 120, And can output the data as? A (S30). The compensation data (? A) may include information on the coordinates of the area where the image compensation is to be performed among the image signals (RGB) and information on the compensation size.

The data generating unit 150 performs image compensation to compensate the gradation level of the specific region of the image signal RGB according to the compensation data ΔA output from the selector 140, (DATA) and output it (S40).

Since the compensation data? A outputted from the selection unit 140 have different levels according to the operation time of the display device 100, the data generation unit 150 generates the compensation data? Accordingly, the gradation level compensation magnitude of the video signal RGB can be made different.

For example, the display panel 101 is provided with a normal region (RA in FIG. 1A) in which an image with normal brightness is displayed due to a process variation, and a smear region (in FIG. 1A, ) May exist.

The data generating unit 150 of the image compensating unit 110 generates the image signal RGB corresponding to the smear region RB of the display panel 101 in accordance with the compensation data? ) Of the gray level. The data generator 150 can prevent the brightness deviation of the normal region RA and the smear region RB from occurring on the display panel 101 by outputting the image data DATA according to the image compensation.

Here, the image compensation unit 110 may adaptively adjust the compensation size of the image signal RGB according to the operation time of the display device 100. [ For example, in the initial operation of the display apparatus 100, the luminance deviation between the normal region RA and the stain region RB of the display panel 101 is large.

6A, in the initial operation period of the display apparatus 100, the selector 140 of the image compensator 110 outputs the first compensation value a1 as compensation data? A . Accordingly, the data generating unit 150 performs image compensation for increasing the gradation level of the area corresponding to the smoothing area RB by the first compensation value a1 in the image signal RGB to output the image data DATA . Accordingly, in the image displayed on the display device 100, there is no deviation between the steady-state luminance LA1 and the smudge-area luminance LB1, so that image quality defects do not occur. Here, the initial operation period may range from the initial operation time of the display apparatus 100 to several tens of hours.

However, when the operating time of the display apparatus 100 is increased, the luminance of the light emitted due to the degradation of the performance of the backlight unit 102 is reduced, The luminance deviation is gradually reduced.

6B, in the first operation period in which the operation time of the display apparatus 100 is increased, the selection unit 140 of the image compensation unit 110 multiplies the second compensation value a2 by the compensation data (DELTA A). The data generating unit 150 performs image compensation for increasing the gradation level of the area corresponding to the smudge region RB by the second compensation value a2 in the image signal RGB to output the image data DATA . Thus, in the image displayed on the display device 100, there is no deviation between the steady-state luminance LA2 and the smudge-area luminance LB2, so that image quality defects do not occur.

Here, the second compensation value a2 has a level lower than the first compensation value a1 output from the selection unit 140 in advance. That is, when the operation time of the display apparatus 100 is increased, the image compensating unit 110 compensates the first compensation value a1 used for image compensation in the initial operation period of the display apparatus 100, 2 compensation value a2 to output image data DATA. As a result, in the display apparatus 100, it is possible to prevent image quality defects due to over compensation of the smear region RB. The first operation period may range from several tens of hours of operation time of the display apparatus 100 to hundreds of hours.

6C, in the N-th operation period in which the operation time of the display apparatus 100 is further increased, the selector 140 of the image compensator 110 compensates the N-th compensation value an Can be output as the data (? A). Accordingly, the data generating unit 150 performs image compensation to increase the gradation level of the area corresponding to the smudge region RB by the Nth compensation value an in the image signal RGB to output the image data DATA . Thus, in the image displayed on the display device 100, there is no deviation between the steady area luminance (LAn) and the smudge area luminance (LBn), so that image quality defects do not occur.

Here, the Nth compensation value 'an' has a level lower than the second compensation value 'a2' output from the selection unit 140 in advance. That is, when the operation time of the display apparatus 100 is further increased, the image compensating unit 110 may reduce the level of the second compensation value a2, which is smaller than the second compensation value a2 used for image compensation in the first operation period of the display apparatus 100 The N-th compensation value 'an' of the image data 'DATA'. As a result, in the display apparatus 100, it is possible to prevent image quality defects due to over compensation of the smear region RB. The Nth operation period of the display apparatus 100 may range from several hundred hours of operation time of the display apparatus 100 to several thousand hours.

As described above, the image compensating unit 110 of the present invention reduces the magnitude of compensating the gradation level of the image signal RGB as the operation time of the display device 100 increases, Can be prevented. Therefore, even if the operation time is increased, the display device 100 of the present invention can eliminate the luminance deviation between the normal region RA and the smudged region RB in the displayed image, thereby preventing occurrence of image quality defects due to luminance unevenness can do.

On the other hand, in the present invention, the display device 100 is a liquid crystal display device including the display panel 101 and the backlight unit 102 as an example. However, the present invention is not limited thereto, and the present invention can be applied even when the display device 100 is an organic light emitting display device (OLED). That is, according to the present invention, as the use time of the display apparatus 100 is increased, the luminance deviation between the steady area RA and the smear area RB of the display panel 101 is reduced and the image signal RGB is compensated The structure of the present invention can be similarly applied to the organic light emitting display device.

While a number of embodiments have been described in detail above, it should be construed as being illustrative of preferred embodiments rather than limiting the scope of the invention. Therefore, the invention should not be construed as limited to the embodiments described, but should be determined by equivalents to the appended claims and the claims.

100: display device 101: display panel
102: backlight unit 103: gate driver
104: Data driver 105: Backlight driver
106: timing control unit 110: image compensation unit
120: storage unit 130: counter
140: selection unit 150: data generation unit

Claims (11)

A storage unit storing a plurality of compensation values having different levels for each operation time of the display device;
A counter for outputting a selection signal according to a result of counting the operation time of the display device;
A selection unit for selecting one of the plurality of compensation values stored in the storage unit in response to the selection signal and outputting the compensation data as compensation data; And
And a data generator for generating image data by compensating a gradation level of a video signal according to the compensation data. The method according to claim 1,
Wherein the storage unit includes a plurality of lookup tables each storing first to Nth compensation values. 3. The method of claim 2,
And the Nth compensation value has a level lower than the first compensation value. The method according to claim 1,
Wherein each of the plurality of compensation values includes a plurality of representative values each corresponding to at least four representative gradations of the image signal. 5. The method of claim 4,
Wherein the four representative gradations are the 32nd gradation, the 64th gradation, the 128th gradation, and the 192nd gradation of the video signal. 5. The method of claim 4,
Wherein the data generating unit linearly compensates the remaining gray scales of the video signal except for the four representative gray scales according to the compensation data. The method according to claim 1,
Wherein the counter counts the operation time of the display device in a cumulative manner. 8. The method of claim 7,
Wherein the counter compares a count value for the operation time with a plurality of reference values, and outputs the selection signal according to a comparison result. 9. The method of claim 8,
Wherein the plurality of reference values are values set for each operation time of the display device. The method according to claim 1,
Wherein each of the plurality of compensation values includes information on coordinates and size of an image compensation region. Display panel; And
And an image compensator configured to compensate a gradation level of a specific area among the image signals input from the external system according to the operation time of the display panel to generate and output image data,
Wherein the image compensating unit comprises:
A storage unit for storing a plurality of compensation values having different levels for each operation time of the display panel;
A counter for outputting a selection signal according to a result of counting the operation time of the display panel;
A selection unit for selecting one of the plurality of compensation values stored in the storage unit in response to the selection signal and outputting the compensation data as compensation data; And
And a data generating unit for generating the image data by compensating the gradation level of the image signal according to the compensation data.

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