KR20180000037A - Method for compensating data in organic light emitting display device - Google Patents

Abstract

A data driving method of an organic light emitting display device comprises the following steps of: comparing gradation data of an (n-1)^th pixel row (herein, n is a natural number of 2 or more) with input gradation data of an n^th pixel row to calculate a delta and a changing direction; calculating each of a first delta sum and a second delta sum with respect to the entire n^th pixel row, and calculating each of the number of first pixels corresponding to an increasing direction and the number of second pixels corresponding to a decreasing direction; calculating a net coupling direction, a net coupling sum, and the number of coupling-induced pixels with respect to the entire n^th pixel row on the basis of the first delta sum and the second delta sum; comparing the net coupling sum with a preset coupling compensation threshold value to determine a compensation limit step; performing first coupling compensation for compensating input gradation data of each of the coupling-induced pixels on the basis of the compensation limit step, delta, and changing direction; and performing second coupling compensation for compensating input gradation data of each of inverse compensation pixels that are remaining pixels except the coupling-induced pixels among the pixels, in the opposite direction of the first coupling compensation.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method of compensating data in an organic light-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a display device, and more particularly, to an OLED display device and a data compensation method thereof.

The intervals between the metal lines such as the data lines, the scan lines, the power supply lines, and the like disposed on the display panel are narrowed according to the increase in the resolution of the organic light emitting display device (UHD or higher). As the densities of the metal lines and the variation amount of the gray-scale data are increased, the coupling phenomenon between the metal lines affects the image distortion of high resolution (gradation data, data voltage, change in power supply voltage, etc.).

It is an object of the present invention to provide a data compensation method of an organic light emitting display device which compensates gradation data of coupling-induced pixels and inverse compensation pixels included in the same pixel row in different ways.

It is another object of the present invention to provide an organic light emitting diode (OLED) display device that operates according to the data compensation method.

It should be understood, however, that the present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the spirit and scope of the invention.

According to an aspect of the present invention, there is provided a method of compensating data in an OLED display device, comprising: a first step of generating gradation data of an n- (N) pixel rows of the n-th pixel row, and outputs a delta representing the absolute value of the data variation amount corresponding to each of the plurality of pixels included in the n-th pixel row and a changing direction indicating whether the magnitude of the gradation data is relatively increased or decreased And calculates a second delta sum, which is the sum of the delta corresponding to the increasing direction in the changing direction, and the second delta sum, which is the sum of the delta corresponding to the decreasing direction in the changing direction, The first pixel count corresponding to the increasing direction and the second pixel count corresponding to the decreasing direction, respectively, and the first pixel count corresponding to the first delta sum and the second pixel count corresponding to the decreasing direction, Calculating a net coupling direction, a net-coupling sum, and a number of coupling-induced pixels that are one of the first pixel number and the second pixel number for the entire nth pixel row, Determining a compensation limit step of comparing the net-coupling sum with a predetermined coupling compensation threshold to limit the degree of compensation of the coupling distortion by being applied to the input gray-scale data of each of the coupling-induced pixels, Performing first coupling compensation to compensate the input gray-scale data of each of the coupling-induced pixels based on the limiting step, the delta and the changing direction, And performing a second coupling compensation to compensate the input grayscale data of each of the inverse compensation pixels in a direction opposite to the first coupling compensation .

According to one embodiment, the coupling-induced pixels may have the same direction of change as the forward-coupling direction.

According to an embodiment, the gradation data of the (n-1) -th pixel row may be the compensation data of the (n-1) -th pixel row in which the first coupling compensation is performed.

According to one embodiment, the compensation data of the n-1 pixel row, the delta of the n pixel row and the change direction may be temporarily stored in the line buffer, respectively.

According to one embodiment, calculating the forward-coupling direction, the forward-coupled sum and the number of coupled-induced pixels may comprise calculating an absolute value of a difference between the first delta sum and the second delta sum, Coupling sum of the first delta sum and the second delta sum, and determines the change direction corresponding to a larger value of the first delta sum and the second delta sum as the forward-coupling direction, Lt; RTI ID = 0.0 > number of coupling-induced pixels. ≪ / RTI >

According to an embodiment, the calculating of the compensation limit step may comprise calculating the first delta sum or the second delta sum and the coupling compensation threshold value, if the net-coupling sum is greater than the coupling compensation threshold, And calculating the total compensation limit value by dividing the total compensation limit value by the number of the coupling-induced pixels.

According to an embodiment, the calculating of the total compensation limit value may include calculating the total compensation limit value by adding the coupling compensation threshold value and the second delta sum when the forward-coupling direction is the increasing direction, And calculating the total compensation limit value by adding the coupling compensation threshold and the first delta sum when the forward-coupling direction is the decreasing direction.

According to one embodiment, the calculating of the compensation limiting step may include calculating the compensation limit step in such a manner that the forward-coupling direction of the (n-1) -th pixel row derived from the forward-coupling direction and the grayscale data of the , The method may further include increasing the compensation continuation count in the same direction and increasing or decreasing the compensation limit step according to the counted result.

According to an embodiment, when the forward-coupling direction is the increasing direction, the compensation limit step may increase as the compensation continuous count count increases. If the forward-coupling direction is the decreasing direction, the compensation limit step may decrease as the compensation continuation count count increases.

According to one embodiment, the calculating of the compensation limiting step includes calculating, when the forward-coupling direction is different from the forward-coupling direction of the (n-1) -th row of pixels, And counting the count to 1 to maintain the compensation limiting step.

According to an embodiment, when the net-coupling sum is less than or equal to the coupling compensation threshold value, compensation of the input gray-scale data of the nth pixel row may be terminated.

According to one embodiment, performing the first coupling compensation comprises comparing the delta with the compensation limiting step to calculate a compensation parameter of each of the coupling-induced pixels, and comparing the input of each of the coupling- And calculating the compensation data by applying the compensation parameter to the gray-scale data.

According to an embodiment, calculating the compensation parameter may include determining the difference between the delta and the compensation limit step as the compensation parameter if the delta leaves the compensation limit step, and if the delta leaves the compensation limit step And if so, determining the compensation parameter to be zero.

According to an embodiment, when the forward-coupling direction is the increasing direction, the compensation data of each of the coupling-induced pixels may be a value obtained by subtracting the compensation parameter from the input gray-scale data.

According to an embodiment, when the forward-coupling direction is the decreasing direction, the compensation data of each of the coupling-induced pixels may be a value obtained by adding the compensation parameter to the input gradation data.

According to one embodiment, performing the second coupling compensation comprises determining the pixels having the direction of change different from the forward-coupling direction of the pixels as the inverse compensation pixels, And calculating the compensation data by comparing the input grayscale data of each of the inverse compensation pixels with each other.

According to one embodiment, the inverse compensation parameter may correspond to the extracted tone corresponding to the total compensation limit value for limiting the amount of data change to the coupling compensation threshold value or less.

According to an embodiment, the calculation of the compensation data may be performed when the input grayscale data of each of the inverse compensation pixels is greater than or equal to the inverse compensation parameter, the input grayscale data of each of the inverse compensation pixels and the inverse compensation parameter And determining the compensation data as a predetermined compensation value when the input grayscale data of each of the inverse compensation pixels is smaller than the inverse compensation parameter.

According to an embodiment, when the forward-coupling direction is the increasing direction, the compensation value may correspond to a minimum gradation of the display panel.

According to an embodiment, when the forward-coupling direction is the decreasing direction, the compensation value may correspond to a maximum gradation of the display panel.

The OLED display and the data compensation method thereof according to the embodiments of the present invention may be applied to the comparison result between the gray level data (for example, the first compensation data of the previous pixel row) of the previous pixel row and the input gray level data of the current pixel row Coupling-compensating pixels can be subjected to coupling compensation in different ways based on the coupling-induced pixels and the inverse compensation pixels. Accordingly, the voltage and data distortion due to coupling between the wirings in an ultra-high resolution (UHD or higher) display panel in which the wirings are very dense can be relatively accurately compensated, and image distortion due to the coupling can be reduced or eliminated.

In addition, since the data compensation method is implemented by the line buffer and the software algorithm, the layout limitations of the pixels and the display panel can be overcome, and the load by the coupling compensation drive can be reduced.

However, the effects of the present invention are not limited to the effects described above, and may be variously extended without departing from the spirit and scope of the present invention.

1 is a block diagram illustrating an organic light emitting display according to embodiments of the present invention.
2 is a flowchart illustrating a method of compensating data of an OLED display according to embodiments of the present invention.
3 is a diagram for explaining coupling-induced pixels included in a pixel row and inverse compensation pixels.
4 is a flowchart showing an example of a method of calculating a delta and a change direction of input gradation data included in the data compensation method of FIG.
FIG. 5 is a flowchart showing an example of a method of calculating a forward-coupling direction, a forward-coupling sum, and a number of coupling-induced pixels included in the data compensation method of FIG.
FIG. 6 is a flowchart showing an example of a method for determining a compensation limit step included in the data compensation method of FIG. 2. FIG.
7 is a flow chart illustrating an example of a method for determining the compensation limiting step of FIG.
8A to 8C are diagrams showing examples in which the compensation limiting step of FIG. 6 is determined.
9 is a flowchart showing an example of a method of performing first coupling compensation included in the data compensation method of FIG.
FIGS. 10A to 10D are views showing examples in which the first coupling compensation of FIG. 9 is performed.
11 is a flowchart showing an example of a method of performing a second coupling compensation included in the data compensation method of FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals are used for the same constituent elements in the drawings and redundant explanations for the same constituent elements are omitted.

1 is a block diagram illustrating an organic light emitting display according to embodiments of the present invention.

1, the OLED display 1000 may include a display panel 100, a timing controller 200, a scan driver 300, a coupling compensator 400, and a data driver 500 .

The display panel 100 includes a plurality of pixels P, and can display an image. Specifically, the display panel 100 may include pixels P formed at positions corresponding to the intersections of the plurality of scan lines SL1 to SLn and the plurality of data lines DL1 to DLm . In one embodiment, the display panel 100 implements a high resolution picture quality over UHD (Ultra High Definition).

The timing controller 200 may control the driving of the scan driver 300, the coupling compensator 400, and the data driver 500. The timing controller 200 receives image data (IDATA) from an external video source or the like. The timing controller 200 provides the scan driver 300, the coupling controller 400 and the data driver 500 with the first to third control signals CON1, CON2 and CON3 to the scan driver 300 ), The coupling control unit 400, and the data driver 500.

The scan driver 300 may provide a scan signal to the pixels P of the display panel 100 through the scan lines SL1 to SLn based on the first control signal CON1.

The coupling compensating unit 400 may compensate the coupling of the input image data DATA based on the second control signal CON2 and provide the compensated image data CDATA to the data driver 500. [ The coupling compensating unit 400 can compensate for the distortion due to the coupling based on the input gradation data of the current pixel row and the compensated image data of the previous pixel row. The coupling compensation unit 400 may be included in the timing control unit 200 or the data driving unit 500. The coupling compensation unit 400 may be implemented by software (or an algorithm). The operation of the coupling compensating unit 400 will be described in detail with reference to FIG. 2 to FIG.

The data driver 500 may provide a data signal to the display panel 100 based on the third control signal CON2 and the compensated image data CDATA.

Accordingly, the display panel 100 can display an image in which data distortion due to coupling between data lines, power supply lines, and scan lines is compensated.

FIG. 2 is a flowchart illustrating a method of compensating data in an OLED display according to embodiments of the present invention. FIG. 3 is a view for explaining coupling-induced pixels and inverse compensation pixels included in a pixel row.

2 and 3, the data compensation method of the organic light emitting diode display 1000 includes a method of compensating for the delta of the input tone data PDATA of the n-th pixel row PR (N) (where n is a natural number of 2 or more) (ABS1), a second delta sum (ABS2), a first pixel number (NUM1), and a second pixel number (NUM2) (S100) ), The net coupling direction NDIR, the net-coupling sum NSUM, and the number of coupling-induced pixels CPX (CNUM) of the nth pixel row PR (N) (Step S300), and determines the compensation step STEP for the coupling-induced pixels CPX (S400). Then, the input coupling data PDATA of the coupling-induced pixels CPX is subjected to the first coupling Compensation is performed (S500), and the second coupling compensation is performed on the input gradation data PDATA of the inverse compensation pixels RCPX.

In one embodiment, the organic light emitting diode display 1000 may display a high-resolution image of UHD or higher.

The gradation data of the (n-1) -th pixel row PR (N-1) is compared with the input gradation data PDATA of the n-th pixel row PR (N) (ABS) representing the absolute value of the data change amount corresponding to each of the plurality of pixels and the change direction (DIR) indicating whether the magnitude of the gradation data is relatively increased or decreased can be calculated (SlOO) . The delta (ABS) and the change direction (DIR) can be calculated for each of the pixels of the nth pixel row PR (N).

In one embodiment, the input gradation data PDATA may increase in size as the gradation increases (or as the brightness increases). For example, when the gradation (or luminance) of the nth pixel row PR (N) is higher than the nth pixel row PR (N-1) The input gradation data PDATA is larger than the gradation data of the (n-1) th pixel row PR (N-1) and the change direction DIR of the data (i.e., gradation data) may be an increasing direction. Conversely, when the gradation of the nth pixel row PR (N) is higher than that of the n-1th pixel row PR (N-1), the input gradation data PDATA (N ) Is smaller than the grayscale data of the (n-1) th pixel row PR (N-1), and the change direction DIR of the data (i.e., grayscale data) may be a decreasing direction.

In one embodiment, the grayscale data of the (n-1) th pixel row PR (N-1) may be the compensation data of the (n-1) th pixel row on which the first coupling compensation is performed. That is, the compensation data of the (n-1) -th pixel row may be the compensated data only of the gray-level data of the coupling-induced pixels of the (n-1) th pixel row PR (N-1). The compensation data of the (n-1) -th pixel row PR (N-1) may be stored in each line buffer.

In one embodiment, the delta (ABS) and the change direction (DIR) of the nth pixel row PR (N) may also be temporarily stored in each line buffer. The compensation data delta (ABS) and the change direction (DIR) of the (n-1) th pixel row may be processed in the form of First In First Out (FIFO). Accordingly, in the data compensation process, a frame memory or the like corresponding to the entire frame occupying a large driving load is not required.

Of the first delta sum (ABS1) and the change direction (DIR) which is the sum of the delta (ABS) corresponding to the increase direction among the change direction (DIR) The second delta sum ABS2 which is the sum of the corresponding delta (ABS) is calculated, and the first pixel number corresponding to the increasing direction and the second pixel number corresponding to the decreasing direction can be calculated (S200), respectively . The first number of pixels is the total number of pixels used in the first delta sum ABS1 and the second number of pixels is the total number of pixels used in the second delta sum ABS2. The sum of the first number of pixels and the second number of pixels is not always equal to the total number of pixels of the nth pixel row PR (N). The first delta sum (ABS1) and the second delta sum (ABS2) are data for calculating the size of the net-coupling.

A net coupling direction NDIR for the entire nth pixel row PR (N) based on the first delta sum ABS1 and the second delta sum ABS2, a net- And the number CNUM of coupling-induced pixels CPX which is one of the first pixel number and the second pixel number may be calculated S300.

The net-coupling direction NDIR means the direction in which the gradation data of the n-th pixel row PR (N) is entirely coupled. That is, the first delta sum (ABS1) is compared with the second delta sum (ABS2), and the coupling mainly occurs to the larger side. For example, when the first delta sum (ABS1) is larger than the second delta sum (ABS2), the input gradation data PDATA of the nth pixel row PR (N) may be mainly coupled in the increasing direction have. Conversely, when the first delta sum ABS1 is smaller than the second delta sum ABS2, the gradation data PDATA of the nth pixel row PR (N) may be mainly coupled in the decreasing direction.

The net-coupling sum (NSUM) may mean a net data variation amount that cancels both the data change in the increase direction and the data change in the decrease direction in the entire nth pixel row PR (N). The coupling-induced pixels CPX can be derived by canceling the data increase / decrease. For example, the net-coupling sum (NSUM) can be calculated as the absolute value of the difference between the first delta sum (ABS1) and the second delta sum (ABS2).

The coupling-induced pixels CPX may be defined as pixels having the same direction of change DIR as the forward-coupling direction NDIR. That is, the coupling-induced pixels CPX may correspond to one of the first pixels and the second pixels. If coupling compensation is not performed, data coupling to the coupling-induced pixels (CPX) occurs in the forward-coupling direction (NDIR), and the image may be distorted.

As shown in Fig. 3, the display panel 100 can display a dark background (OBJECT) with a light background and a low tone. At this time, the input grayscale data PDATA corresponding to the object OBJECT among the n-th pixel rows PR (N) may have a value smaller than the grayscale data of the (n-1) In this case, the direction of change (DIR) of the data may be a decreasing direction. Further, when the forward-coupling direction NDIR is calculated in the decreasing direction, the object OBJECT, The coupling-induced pixels CPX may be coupled to the coupling-induced pixels CPX in the data reduction direction, for example, if coupling compensation is not performed. And the luminance may be lowered.

The pixels other than the coupling-induced pixels CPX in the nth pixel row PR (N) may be determined as the inverse compensation pixels RCPX. The inverse compensation pixels RCPX may correspond to pixels having no change direction or gradation data change opposite to the forward-coupling direction NDIR.

Compensation limiting step STEP may be determined (S400) by comparing the net-coupling sum NSUM with a predetermined coupling compensation threshold. The compensation step STEP may be applied to the input gradation data PDATA of each of the coupling-induced pixels CPX to limit the degree of compensation of the coupling distortion. The coupling compensation threshold value is a threshold value for determining whether or not the coupling compensation operation is performed. That is, when the pure-coupling sum (NSUM) is smaller than the coupling compensation threshold value, image distortion due to coupling or deterioration in image quality is not recognized. Therefore, the algorithm for the coupling compensation is performed only if the net-coupling sum NSUM is greater than the coupling compensation threshold, and a compensation limiting step STEP can be generated.

If the amount of data change between adjacent pixel rows changes abruptly, image distortion can be seen. Therefore, the gradation or luminance change between the pixel rows can be smoothly recognized by calculating the compensation step (STEP) which limits the degree of coupling compensation (i.e., the first coupling compensation). This will be described in detail with reference to FIGS. 6 to 8C. In one embodiment, the size of the compensation limit step (STEP) changes stepwise according to the continuity of the net-coupling direction (NDIR) of the pixel rows, and the luminance to the target gradation can be changed stepwise.

The first coupling compensation for compensating the input gradation data PDATA of each of the coupling-induced pixels CPX is performed (S500) based on the compensation limiting step STEP, the delta ABS and the changing direction DIR . In one embodiment, the first coupling compensation compares the delta (ABS) with the compensation limit step (STEP) to calculate the compensation parameters of each of the coupling-induced pixels CPX and the coupling-induced pixels CPX The first compensation data can be calculated by applying the compensation parameter to the input gray-scale data PDATA.

In one embodiment, when the delta (ABS) (the amount of data change between the previous pixel row and the current pixel row) is greater than the compensation limit step (STEP), the first compensation data by the first coupling compensation is input gradation data PDATA ) May be added to or subtracted from the compensation step (STEP). For example, when the forward-coupling direction NDIR is the increasing direction, the first compensation data may correspond to the sum of the input gradation data PDATA and the compensation limit step STEP. When the net-coupling direction NDIR is the decreasing direction, the first compensation data may correspond to the difference between the input gradation data PDATA and the compensation limiting step STEP.

In one embodiment, when the delta (ABS) is smaller than or equal to the compensation limit step (STEP), the first compensation data by the first coupling compensation is obtained by adding delta (ABS) to the input gradation data PDATA ≪ / RTI > That is, when the delta (ABS) is smaller than or equal to the compensation limit step (STEP), the first coupling compensation is not performed. For example, when the forward-coupling direction NDIR is the increasing direction, the first compensation data may correspond to the sum of the input gradation data PDATA and the delta (ABS). When the pure-coupling direction NDIR is the decreasing direction, the first compensation data may correspond to a difference between input gradation data PDATA and delta (ABS).

The image distortion in the coupling-induced pixels CPX can be eliminated or reduced in accordance with the first coupling compensation. Also, the first coupling compensation is not performed on the inverse compensation pixels RCPX.

A second coupling compensation may be performed (S600) in which the input grayscale data PDATA of each of the inverse compensation pixels RCPX is compensated in a direction opposite to the first coupling compensation. The second coupling compensation may determine the inverse compensation pixels RCPX and compute the second compensation data by comparing the input tone data PDATA of the inverse compensation pixels RCPX with the predetermined inverse compensation parameter have.

The inverse compensation pixels RCPX include pixels whose data has decreased in the direction opposite to the forward-coupling direction (NDIR) or pixels without data change. Therefore, the data can be distorted by the current pixel row (i.e., the main coupling direction NDIR of the nth pixel row PR (n)).

For example, when the transition of gradation data occurs from a high gradation to a low gradation direction (for example, a decreasing direction, shown in FIG. 3), the inverse compensation pixels RCPX having relatively high gradation data, Coupling may also occur in the decreasing direction. Thus, the inverse compensation pixels RCPX, which should display a high gray level (or a bright image), can be viewed dark.

Further, when the transition of the gradation data occurs in a low gradation to a high gradation direction (for example, an increasing direction), the inverse compensating pixels RCPX having relatively high gradation data are also coupled in the decreasing direction Lt; / RTI > Therefore, the inverse compensation pixels RCPX, which should display a low gray level (or dark image), can be seen relatively bright.

The second coupling compensation may be performed to compensate for the coupling distortion of the inverse compensation pixels RCPX. For example, when the data change direction (DIR) of the inverse compensation pixel is the decrease direction, the second compensation data compensated by the second coupling compensation may have a value smaller than the input tone data PDATA . On the other hand, when the data change direction DIR of the inverse compensation pixel is the increasing direction, the second compensation data compensated by the second coupling compensation may have a larger value than the input tone data PDATA.

As described above, the data compensation method of the organic light emitting diode display according to the embodiments of the present invention is a method of compensating the gray level of the previous pixel row (for example, the first compensation data of the previous pixel row) The coupling-induced pixels CPX and the inverse-compensated pixels RCPX can perform coupling compensation in different ways based on the comparison result of the PDATA. Therefore, the voltage and data distortion due to the coupling between the wirings in the ultra-high resolution (UHD) display panel in which the wirings are very dense can be relatively accurately compensated, and the image distortion due to the coupling can be reduced or eliminated.

In addition, since the data compensation method is implemented by the line buffer and the software algorithm, the layout limitations of the pixels and the display panel can be overcome, and the load by the coupling compensation drive can be reduced.

4 is a flowchart showing an example of a method of calculating a delta and a change direction of input gradation data included in the data compensation method of FIG.

Referring to Figs. 2 to 4, the gradation data REF_DATA of the previous pixel row (i.e., the (n-1) th pixel row) and the input gradation data PDATA of the current pixel row (ABS) representing the absolute value of the data change amount corresponding to each of the plurality of pixels included in the n-th pixel row PR (N) and a change direction DIR indicating whether the magnitude of the gradation data is increased or decreased ) May be calculated (S100).

In one embodiment, the grayscale data (REF_DATA) of the previous pixel row may be compensation data in which the first coupling compensation is performed.

The gradation data REF_DATA of the previous pixel row and the input gradation data PDATA of the current pixel row may be compared (S110, S120).

 When the input gradation data PDATA of the current pixel row is larger than the gradation data REF_DATA of the previous pixel row, the delta (ABS) is calculated as PDATA REF_DATA and the change direction DIR of the gradation data is determined as the increasing direction (S130) .

If the input gradation data PDATA of the current pixel row is smaller than the gradation data REF_DATA of the previous pixel row, the delta (ABS) is calculated as REF_DATA PDATA and the change direction DIR of the data is determined as the decreasing direction (S140) .

If the input gradation data PDATA of the current pixel row and the gradation data REF_DATA of the previous pixel row are the same, the change direction DIR of the delta (ABS) and the gradation data may be determined to be 0 (S150).

According to the above process, the delta (ABS) and the change direction (DIR) of the gray level data for all the pixels in the current pixel row can be calculated. The computed delta (ABS) and the change direction (DIR) of the gradation data can be temporarily stored in the line buffer.

FIG. 5 is a flowchart showing an example of a method of calculating a forward-coupling direction, a forward-coupling sum, and a number of coupling-induced pixels included in the data compensation method of FIG.

Referring to Figures 2 and 5, a net coupling direction (n) for the entire nth pixel row PR (N) based on the first delta sum (ABS1) and the second delta sum (ABS2) And the number CNUM of coupling-induced pixels CPX which are one of the first pixel number, the second pixel number NDIR, the net-coupling sum NSUM and the first pixel number and the second pixel number can be calculated S300.

The first delta sum ABS1 may be the sum of the delta (ABS) values corresponding to the increasing direction (i.e., the direction in which the gradation data increases or the brightness increases) in the changing direction DIR. The second delta sum ABS2 may be the sum of the delta (ABS) corresponding to the decreasing direction in the change direction DIR (i.e., the direction in which the gradation data decreases, or the direction in which the brightness decreases). The net-coupling direction NDIR is derived from a larger one of the first delta sum (ABS1) and the second delta sum (ABS2), and means the direction in which the gradation data PDATA of the current pixel row is entirely coupled .

The net-coupling sum NSUM may be determined as the absolute value of the difference between the first delta sum (ABS1) and the second delta sum (ABS2) (S320). The net-coupling sum (NSUM) may mean a net data variation amount that cancels both the data change in the increasing direction and the data change in the decreasing direction over the entire current pixel row. Coupling induced pixels (CPX) can be derived by coupling offset by the data increment / decrement.

The direction of change of the gradation data corresponding to a larger one of the first delta sum (ABS1) and the second delta sum (ABS2) may be determined (S340) in the forward-coupling direction (NDIR). For example, when the first delta sum (ABS1) is larger than the second delta sum (ABS2), the input gradation data PDATA of the nth pixel row PR (N) may be mainly coupled in the increasing direction have. Conversely, when the first delta sum ABS1 is smaller than the second delta sum ABS2, the gradation data PDATA of the nth pixel row PR (N) may be mainly coupled in the decreasing direction.

The number CNUM of coupling-induced pixels having the direction of change of the input gradation data PDATA equal to the net-coupling direction NDIR can be calculated (S360). A compensation limit step or the like can be calculated based on the number of coupling-induced pixels (CNUM).

FIG. 6 is a flowchart showing an example of a method for determining a compensation limit step included in the data compensation method of FIG. 2. FIG.

Referring to FIGS. 2 and 6, the compensation step STEP may be determined (S400) by comparing the net-coupling sum NSUM with a predetermined coupling compensation threshold value CPTH. The compensation step STEP may be applied to the input gradation data PDATA of each of the coupling-induced pixels CPX to limit the degree of compensation of the coupling distortion. The coupling compensation threshold value CPTH is a threshold value for determining whether or not the coupling compensation operation is performed.

The net-coupling sum NSUM and the coupling-compensation threshold CPTH may be compared (S410).

That is, when the pure-coupling sum (NSUM) is smaller than the coupling compensation threshold value, image distortion due to coupling or deterioration in image quality is not recognized. Therefore, coupling compensation is not performed.

That is, when the net-coupling sum NSUM is larger than the coupling compensation threshold value, the first delta sum (ABS1) or the second delta sum (ABS2) and the coupling compensation threshold value (CPTH) The value CLIMIT may be calculated (S420, S430, S440). Here, the total compensation limit value CLIMIT is a value for limiting the change amount of the gray level data to the coupling compensation threshold value CPTH or less.

If the net-coupling sum (NSUM) is greater than the coupling-compensation threshold, the net-coupling direction (NDIR) may be determined (S420). When the forward-coupling direction NDIR is the increasing direction, the total compensation limit value CLIMIT is calculated as the sum of the coupling compensation threshold value CPTH and the second delta sum ABS2, which is the sum of the decreasing direction gradation data variation amounts (S430). When the forward-coupling direction NDIR is the decreasing direction, the total compensation limit value CLIMIT is calculated as the sum of the coupling compensation threshold value CPTH and the first delta sum ABS1, which is the sum of the increasing direction gradation data variation amounts (S440). Therefore, the threshold value of the first coupling compensation can be fixed since the value for the compensation restriction is reflected in the offset of the grayscale data increase / decrease.

The compensation step STEP may be calculated (S450) by dividing the total compensation limit value CLIMIT by the number of coupling induced pixels CNUM. That is, by dividing the maximum limit value of the coupling compensation by the number of coupling induced pixels (CNUM), the difference in the amount of change of the gradation data between the pixels due to the first coupling compensation can be relatively uniform. By setting the compensation step STEP, the second coupling compensation for the inverse compensation pixels can also be relatively uniform.

The compensation limiting step (STEP) can prevent a sudden change in picture quality (gradation) by limiting the amount of change in the gradation data for compensation of the coupling.

FIG. 7 is a flowchart showing an example of a method for determining the compensation limiting step in FIG. 6, and FIGS. 8A to 8C are views showing examples in which the compensation limiting step in FIG. 6 is determined.

6 through 8C, a method for calculating (S450) the compensation limit step includes calculating a net-coupling direction (NDIR) of the current pixel row and the net-couple of the previous pixel row derived from the previous pixel row (S452), counts the number of consecutive compensations (S454), and increases or decreases the compensation limit step (STEP) according to the counted result (S456).

If the net-coupling direction NDIR of the current pixel row is equal to the forward-coupling direction of the previous pixel row, the count of the number of consecutive compensations in the net-coupling direction NDIR can be increased by one (S454) have. For example, if the forward-coupling direction of the pixel row is the increasing direction and the forward-coupling direction (NDIR) of the current row of pixels is also the increasing direction, the number of consecutive compensations is counted twice in the increasing direction . However, if the number of consecutive compensations of the previous pixel row was two or three, the compensation consecutive number of the current pixel row may be counted as three or four.

The compensation step STEP may be increased or decreased (S456) according to the count result. In one embodiment, if the net-coupling direction NDIR is the increasing direction, the compensation step STEP may increase as the compensation continuation count increases. Also, in one embodiment, when the net-coupling direction NDIR is the decreasing direction, the compensation step STEP may decrease as the compensation continuation count increases. That is, when the forward-coupling direction (NDIR) is continuously the same, the range of the data change amount allowed by the compensation limiting step (STEP) can be widened. In one embodiment, the increasing range or decreasing range of the compensation limiting step (STEP) may not be constant.

(I.e., the compensation step (STEP) calculation method of FIG. 6), the previous data REF_DATA (i.e., the gray scale data of the previous pixel row), as shown in FIG. 8A, And the current data PDATA (input gradation data of the current pixel row) can be determined as the compensation step STEP.

8B, when the net-coupling direction NDIR of the gradation data of successive three pixel rows is the increasing direction, the compensation limiting steps STEP1 and STEP2 are increased in accordance with the progress of the pixel row, > STEP2). 8C, when the net-coupling direction NDIR of the gray-scale data of successive three-pixel rows is the decreasing direction, the compensation limiting steps STEP1 and STEP2 are reduced STEP1 -> STEP2). The increasing range or decreasing range of the compensation limiting step (STEP) may not be constant. The range of the data change amount allowed by the compensation step STEP can be broadened according to the progress of the pixel row.

In one embodiment, if the net-coupling direction NDIR is different from the forward-coupling direction of the previous row of pixels, the calculated compensation step STEP, counted in the forward-coupling direction NDIR, (S458). In this case, the compensation limiting step STEP as shown in Fig. 8A can be calculated.

In this manner, the image distortion can be reduced by calculating the compensation limit step (STEP) for limiting the coupling compensation amount (amount of data change by compensation). Further, the coupling compensation can be performed step by step as the range of the data change amount permitted by the compensation limiting step (STEP) becomes wider according to the continuity of the forward-coupling direction (NDIR).

FIG. 9 is a flowchart showing an example of a method of performing first coupling compensation included in the data compensation method of FIG. 2, and FIGS. 10A to 10D are diagrams illustrating examples in which the first coupling compensation of FIG. These are the drawings.

Referring to FIGS. 2 and 9 to 10D, the method for performing the first coupling compensation compares the delta (ABS) of each of the coupling-induced pixels CPX with the compensation limiting step STEP (S510) The first compensation data CDATA1 can be calculated S540 and S550 based on the compensation parameter CPARA by calculating the compensation parameter CPARA of each of the coupling induced pixels CPX.

Coupling compensation is not performed if the delta (ABS) does not exceed the compensation step (STEP). In this case, image distortion due to the coupling is not visually recognized, so that coupling compensation is not necessary. In one embodiment, if the delta (ABS) does not leave the compensation limit step (STEP), the compensation parameter CPARA may be determined to be zero (S520).

When the delta (ABS) is out of the compensation limit step (STEP), the amount of change in the gradation data is reduced. In one embodiment, when the delta (ABS) is out of the compensation limit step (STEP), the difference between the delta (ABS) and the compensation limit step (ABS) (i.e., ABS-STEP) is determined as the compensation parameter CPARA ).

In one embodiment, when the net-coupling direction NDIR of the current pixel row is the increasing direction, the first compensation data CDATA1 of each of the coupling-induced pixels CPX is input to the input gradation data PDATA with the compensation parameter < (CDATA = PDATA CPARA) obtained by subtracting (CPARA) (S540).

Further, in one embodiment, when the net-coupling direction NDIR of the current pixel row is the decreasing direction, the first compensation data CDATA1 of each of the coupling-induced pixels CPX is input to the input gradation data PDATA It is possible to correspond to the value (CDATA = PDATA + CPARA) obtained by adding the compensation parameter CPARA (S540).

10A shows the first compensation data CDATA1 when the delta (ABS) is out of the compensation limit step (STEP) and the net-coupling direction (NDIR) of the current pixel row is the increasing direction. The first compensation data CDATA1 may correspond to a value obtained by subtracting the compensation parameter CPARA from the input gray-scale data PDATA. Also, the first compensation data CDATA1 can be expressed by the sum of the previous gradation data REF_DATA and the compensation limit step STEP (i.e., CDATA1 = REF_DATA + STEP). At this time, the amount of change of the gradation data is limited by the compensation limiting step (STEP).

FIG. 10B shows the first compensation data CDATA1 when the delta (ABS) does not leave the compensation limit step (STEP) and the net-coupling direction (NDIR) of the current pixel row is the increasing direction. The first compensation data CDATA1 may correspond to the input gradation data PDATA. Also, the first compensation data CDATA1 can be expressed by the sum of the previous gradation data REF_DATA and the delta ABS (i.e., CDATA1 = REF_DATA + ABS).

FIG. 10C shows the first compensation data CDATA1 when the delta (ABS) is out of the compensation limit step (STEP) and the net-coupling direction (NDIR) of the current pixel row is the decreasing direction. The first compensation data CDATA1 may correspond to a value obtained by adding the compensation parameter CPARA to the input gradation data PDATA. Also, the first compensation data CDATA1 may be expressed by the difference between the previous gradation data REF_DATA and the compensation limit step STEP (i.e., CDATA1 = REF_DATA-STEP). At this time, the amount of change of the gradation data is limited by the compensation limiting step (STEP).

FIG. 10D shows the first compensation data CDATA1 when the delta (ABS) does not go out of the compensation limit step (STEP) and the net-coupling direction (NDIR) of the current pixel row is the decreasing direction. The first compensation data CDATA1 may correspond to the input gradation data PDATA. Also, the first compensation data CDATA1 may be expressed by the difference between the previous gradation data REF_DATA and the delta (i.e., CDATA1 = REF_DATA-ABS).

As described above, the first compensation data (CPX) compensating the coupling of the coupling-induced pixels CPX based on the difference between the data amount of the previous gradation data REF_DATA and the current gradation data PDATA and the compensation limiting step STEP CDATA1) may be generated.

11 is a flowchart showing an example of a method of performing a second coupling compensation included in the data compensation method of FIG.

Referring to FIGS. 2 and 11, the second coupling compensation method determines (S610) the inverse compensation pixels RCPX and determines the inverse compensation pixels RCPARA and RCPX, It is possible to compare the data PDATA (S620) and calculate the second compensation data CDATA2 (S630).

The inverse compensation pixels RCPX may be determined (S610). The inverse compensation pixels RCPX may be the remaining pixels except the coupling-induced pixels CPX in the current pixel row. The inverse compensation pixels RCPX may correspond to pixels having no change direction or gradation data change opposite to the forward-coupling direction NDIR.

In one embodiment, the inverse compensation parameter RCPARA may correspond to the extracted tone corresponding to the total compensation limit value CLIMIT (see FIG. 6) for limiting the amount of data change to a coupling compensation threshold value or less. For example, the inverse compensation parameter RCPARA corresponding to the total compensation limit value may be set by the lookup table.

In one embodiment, when the input gradation data PDATA of each of the inverse compensation pixels RCPX is equal to or greater than the inverse compensation parameter RCPARA, the input gradation data PDATA of each of the inverse compensation pixels RCPX, The difference of the compensation parameter RCPARA can be calculated (S630) as the second compensation data CDATA2 (i.e., CDATA2 = PDATA RCPARA).

The second compensation data CDATA2 may be determined to be a predetermined compensation value S640 if the input tone data PDATA of each of the inverse compensation pixels RCPX is smaller than the inverse compensation parameter RCPARA. In one embodiment, when the net-coupling direction NDIR is the increasing direction, the compensation value (or second compensation data CDATA2) may correspond to the minimum gradation (e.g., 0 gradation level) of the display panel (Or the second compensation data CDATA2 corresponds to the maximum gradation (e.g., 255 gradation level) of the display panel if the net-coupling direction NDIR is a decreasing direction, in one embodiment. .

As described above, the data compensation method of the organic light emitting diode display according to the embodiments of the present invention is a method of compensating the gray level of the previous pixel row (for example, the first compensation data of the previous pixel row) The coupling-induced pixels CPX and the inverse-compensated pixels RCPX can perform coupling compensation in different ways based on the comparison result of the PDATA. Therefore, the voltage and data distortion due to the coupling between the wirings in the ultra-high resolution (UHD) display panel in which the wirings are very dense can be relatively accurately compensated, and the image distortion due to the coupling can be reduced or eliminated.

In addition, since the data compensation method is implemented by the line buffer and the software algorithm, the layout limitations of the pixels and the display panel can be overcome, and the load by the coupling compensation drive can be reduced.

The present invention can be applied to all electronic apparatuses having a display device. For example, the present invention can be applied to a television, a computer monitor, a notebook, a digital camera, a mobile phone, a smart phone, a smart pad, a PDA, a PMP, an MP3 player, a navigation system, a camcorder, .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the following claims. It can be understood that it is possible.

100: display panel 200: timing controller
300: scan driver 400: coupling compensation unit
500: data driver 1000: organic light emitting display

Claims (20)

(N is an integer equal to or greater than two) pixel rows and the input gradation data of the n-th pixel row to determine the absolute value of the data variation amount corresponding to each of the plurality of pixels included in the n-th pixel row Calculating a change direction indicating a relative increase or decrease in the magnitude of the gradation data;
The first delta sum being a sum of delta corresponding to an increasing direction in the changing direction and the second delta sum being a sum of delta corresponding to the decreasing direction in the changing direction, Calculating a first number of pixels corresponding to the reduction direction and a second number of pixels corresponding to the reduction direction, respectively;
A net coupling direction, a net-coupling sum, and a second pixel sum of the first pixel number and the second pixel number, based on the first delta sum and the second delta sum, Calculating a number of coupling-induced pixels;
Determining a compensation limit step of comparing the net-coupling sum with a predetermined coupling compensation threshold to limit the degree of compensation of coupling distortion by being applied to the input gray-scale data of each of the coupling-induced pixels;
Performing a first coupling compensation to compensate the input gradation data of each of the coupling-induced pixels based on the compensation limiting step, the delta, and the changing direction; And
Performing second coupling compensation to compensate the input grayscale data of each of the inverse compensation pixels that are pixels other than the coupling-induced pixels among the pixels in a direction opposite to the first coupling compensation. A method of compensating data in a light emitting display device. The method of claim 1, wherein the coupling-induced pixels have the same direction of change as the forward-coupling direction. 3. The method of claim 2, wherein the gradation data of the (n-1) th pixel row is compensation data of the (n-1) th pixel row in which the first coupling compensation is performed. 4. The method of claim 3, wherein the compensation data of the n-1 pixel rows, the delta of the n pixel rows and the change direction are temporarily stored in the line buffers. 3. The method of claim 2, wherein calculating the forward-coupling direction, the forward-coupling sum, and the number of coupling-
Determining an absolute value of a difference between the first delta sum and the second delta sum as a net-coupling sum;
Determining the direction of change corresponding to a larger value of the first delta sum and the second delta sum in the forward-coupling direction; And
And calculating the number of coupling-induced pixels having the same direction of change as the net-coupling direction. 3. The method of claim 2, wherein calculating the compensation step comprises:
Calculating a total compensation limit value by adding the first delta sum or the second delta sum and the coupling compensation threshold if the net-coupling sum is greater than the coupling compensation threshold; And
And dividing the total compensation limit value by the number of coupling-induced pixels to calculate the compensation limit step. 7. The method of claim 6, wherein calculating the total compensation limit value comprises:
Calculating the total compensation limit value by adding the coupling compensation threshold and the second delta sum when the forward-coupling direction is the increasing direction; And
Further comprising calculating the total compensation limit value by adding the coupling compensation threshold and the first delta sum when the forward-coupling direction is the decreasing direction. Compensation method. 8. The method of claim 7, wherein calculating the compensation step comprises:
When the forward-coupling direction of the (n-1) -th pixel row derived from the forward-coupling direction and the grayscale data of the (n-1) -th pixel row is the same direction, the compensation continuation count in the same direction is increased step; And
Further comprising increasing or decreasing the compensation limit step according to the counted result. ≪ Desc / Clms Page number 19 > 9. The method of claim 8, wherein when the forward-coupling direction is the increasing direction, the compensation limit step is increased as the compensation continuation count count increases,
Wherein when the forward-coupling direction is the decreasing direction, the compensation limit step decreases as the compensation continuation count increases. 9. The method of claim 8, wherein calculating the compensation step comprises:
Maintaining the compensation constraint step while counting the compensation consecutive number count to 1 in the forward-coupling direction when the forward-coupling direction is different from the forward-coupling direction of the (n-1) -th pixel row The method of claim 1, further comprising: 7. The OLED display according to claim 6, wherein when the net-coupling sum is smaller than or equal to the coupling compensation threshold, the compensation of the input gray-scale data of the n-th pixel row is ended Compensation method. 2. The method of claim 1, wherein performing the first coupling compensation comprises:
Comparing the delta with the compensation limiting step to calculate a compensation parameter of each of the coupling-induced pixels; And
And calculating compensation data by applying the compensation parameter to the input gray-scale data of each of the coupling-induced pixels. 13. The method of claim 12, wherein calculating the compensation parameter comprises:
Determining a difference between the delta and the compensation limit step as the compensation parameter when the delta is out of the compensation limit step; And
And determining the compensation parameter to be 0 if the delta does not exceed the compensation limit step. 13. The organic light emitting display according to claim 12, wherein when the forward-coupling direction is the increasing direction, the compensation data of each of the coupling-induced pixels is a value obtained by subtracting the compensation parameter from the input gradation data. / RTI > 13. The organic light emitting display according to claim 12, wherein when the forward-coupling direction is the decreasing direction, the compensation data of each of the coupling-induced pixels is a value obtained by adding the compensation parameter to the input gradation data. / RTI > 2. The method of claim 1, wherein performing the second coupling compensation comprises:
Determining, among the pixels, the pixels having the direction of change different from the forward-coupling direction as the inverse compensation pixels; And
And calculating compensation data by comparing the input grayscale data of each of the inverse compensation pixels with a predetermined inverse compensation parameter. The organic light emitting diode display according to claim 16, wherein the inverse compensation parameter corresponds to a gray level extracted corresponding to a total compensation limit value for limiting the data change amount to less than or equal to the coupling compensation threshold value. Way. 17. The method of claim 16, wherein calculating the compensation data comprises:
Calculating the difference between the input grayscale data and the inverse compensation parameter of each of the inverse compensation pixels as the compensation data when the input grayscale data of each of the inverse compensation pixels is greater than or equal to the inverse compensation parameter; And
And determining the compensation data as a predetermined compensation value when the input tone data of each of the inverse compensation pixels is smaller than the inverse compensation parameter. The method of claim 18, wherein when the forward-coupling direction is the increasing direction, the compensation value corresponds to a minimum gradation of the display panel. 19. The method of claim 18, wherein when the forward-coupling direction is the decreasing direction, the compensation value corresponds to a maximum gradation of the display panel.

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