KR101970561B1 - Organic light emitting diode display device and method for driving the same - Google Patents

Abstract

The present invention provides an organic light emitting diode display device which simplifies the circuit configuration and lowers the product price while preventing overcurrent generation of the image display panel by modulating and displaying image data in every frame according to the frame current amount of the image display panel. A driving method comprising: an image display panel including a plurality of pixel regions, a gate driver driving gate lines of the image display panel, a data driver driving data lines of the image display panel, and an RGB input from an external device. A timing controller for aligning data to the size of the image display panel and generating data and gate control signals to control the data and gate drivers; and analyzing current image data from the timing controller on a frame-by-frame basis; Detecting And an image data converter configured to modulate the next frame data and supply the next frame data to the data driver according to a result of comparing the detected current frame current amount with a preset reference current amount.

Description

Organic light emitting diode display and its driving method {ORGANIC LIGHT EMITTING DIODE DISPLAY DEVICE AND METHOD FOR DRIVING THE SAME}

The present invention provides an organic light emitting diode display device which simplifies the circuit configuration and lowers the product price while preventing overcurrent generation of the image display panel by modulating and displaying image data in every frame according to the frame current amount of the image display panel. The driving method is related.

Recently, flat panel displays are emerging as liquid crystal displays, field emission displays, plasma display panels, and organic light emitting diode displays. Emitting Diode Display). Among them, the organic light emitting diode display has high luminance, low driving voltage, and ultra-thin film, which is usefully applied to mobile communication devices such as smart phones and tablet pads.

Each of the pixels constituting the organic light emitting diode display includes an organic light emitting diode (OLED) pixel including an organic light emitting layer between an anode and a cathode, a pixel circuit driving each OLED pixel independently, and a pixel circuit driving each pixel circuit. A drive control circuit is provided.

The driving control circuit for driving the organic light emitting diode display subdivides the preset reference gamma voltage level into gamma voltage for each gray level, and converts digital data into an analog data signal (current or voltage signal) using the subdivided gamma voltage. do. The analog data signals are supplied to respective pixel circuits so that an image is displayed through each OLED pixel.

Thus, the brightness of light emitted from the OLED pixel is determined by the amount of current flowing through the OLED pixel. Therefore, the brighter the brightness of the image to be displayed, the more current flows through the OLED pixel. Increasing the current consumption of the OLED pixel inevitably increases the power consumption of the OLED display panel, the larger the current consumption has a problem that the life of the OLED is quickly reduced.

In the related art, the frame current amount is controlled by storing image data in at least one frame unit and then setting the maximum brightness according to the brightness of the stored frame data to display the image below the set maximum brightness. However, the conventional frame current amount control method requires additional memories to store the frame data until the maximum brightness is set and the data are modulated. Therefore, there is a problem that the circuit configuration is complicated, the cost is increased, and the time taken to modulate the image data according to the maximum brightness every frame unit is long.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and the image data of each frame unit is modulated and displayed according to the frame current amount of the image display panel, thereby preventing overcurrent generation of the image display panel while simplifying circuit configuration and reducing product prices. It is an object of the present invention to provide an organic light emitting diode display and a method of driving the same.

In accordance with another aspect of the present invention, an organic light emitting diode display includes an image display panel including a plurality of pixel regions, a gate driver driving gate lines of the image display panel, and the image display panel. A data driver for driving data lines of the data controller; a timing controller configured to align RGB data input from the outside to a size of the image display panel and generate data and gate control signals to control the data and gate drivers; An image data converter for analyzing current image data every frame to detect current amount of the current frame, modulating the next frame data according to a result of comparing the detected current frame current amount with a preset reference current amount, and supplying it to the data driver. We have special thing Gong.

The image data converting unit analyzes the gradation distribution of the image data sequentially input from the timing controller in every frame unit, and extracts and extracts an average or maximum luminance value in each frame unit using the analyzed gradation distribution. A luminance correction controller for generating a luminance correction gain value by comparing the average or maximum luminance value determined with the preset reference current amount, and detecting the frame current amount and comparing the frame current amount with the preset reference current amount according to a comparison result The overcurrent prevention unit for generating a data gain value for modulating the next frame data so that the frame current amount according to the next frame data is equal to or less than the preset reference current amount, and the luminance correction of the image data for each frame unit input from a timing controller; Gain value According to the present invention, the data modulation unit generates modulated data in units of frames by performing primary modulation and second modulation to the data gain value, and supplies the modulated data to the data driver.

The overcurrent protection unit is a current calculation unit for sequentially detecting the frame current amount (frame_current (k-1)) for each frame unit using the following equation 1,

[Equation 1]

Using Equation 2 below,

[Equation 2]

The overcurrent (over_current (k-1)) is detected by extracting the case where the difference between the display current amount frame_current (k-1) and the preset reference current amount MAX_CURRENT (R_OI) of one frame is 1 or more, and the detected overcurrent and a data correction control unit for generating the data gain value gain (k) using the (over_current (k-1)) value.

When it is confirmed that the overcurrent (over_current (k-1)) occurs, the data correction controller generates the data correction gain value as the smallest number or 0 smaller than 1 and outputs the frame current amount as soon as possible, or the following equation Using 3a,

Equation 3a

Setting and outputting a data gain value gain (k) such that the magnitude of the frame current amount to be reduced from the next image display line becomes larger than the detected overcurrent amount over_current (k-1),

는 앞으로 출력할 라인들에서 소비할 전류량이기 때문에 계산하는 시점에서는 알 수 없는 전류량인 것을 특징으로 한다. remind

Since the amount of current to be consumed in the lines to be output in the future is characterized in that the amount of current unknown at the time of calculation.

The data correction control unit

Under the assumption that the average amount of current to be consumed in the remaining image display lines is the same as the current amount, the current amount predicted value (predicted_current (k)) is set using Equation 4 below,

[Equation 4]

Under the assumption that the most recently displayed line is similar to the lines to be displayed, the current amount prediction value is set using Equation 5 below.

[Equation 5]

The weight is characterized by 2 ⁿ .

The data correction controller sets the data gain value gain (k) in consideration of not only the amount of overcurrent generated so far but also the amount of change in current when the remaining image display lines are output, but the remaining image is not displayed yet. The current variation of the lines is predicted using Equation 6 below,

[Equation 6]

By adding the current change amount predicted through Equation 6 and the amount of overcurrent generated so far, the summed overcurrent amount (predicted_total_over_current (k)) of each frame is predicted as shown in Equation 7 below.

[Equation 7]

Through Equation 8 below,

[Equation 8]

The final data gain value (gain (k)) to be applied to the lines on which the next image is to be displayed is determined.

In addition, a method of driving an organic light emitting diode display according to an embodiment of the present invention for achieving the above object comprises the steps of driving the gate and data lines of the image display panel; Controlling data and gate drivers by aligning RGB data input from the outside to a size of the image display panel and generating data and gate control signals to drive the gates and data lines; And analyzing the image data every frame to detect the current amount of the current frame, and modulating the next frame data according to a result of comparing the detected current frame current amount with a preset reference current amount to supply the data driver to the data driver. It is characterized by.

The modulating the next frame data may include analyzing a gray scale distribution of the image data every frame unit, extracting an average or maximum luminance value every frame unit using the analyzed gray scale distribution, and extracting the extracted average or maximum luminance. Generating a brightness correction gain value by comparing the brightness value determined by the preset reference current amount with a value, detecting the frame current amount and comparing the value with the preset reference current amount, and according to a comparison result, the frame current amount according to the next frame data. Generating a data gain value for modulating the next frame data to be equal to or less than the preset reference current amount, and firstly modulating the image data of each frame unit according to the luminance correction gain value and the data gain Frame-by-frame by quadratic modulation of the value Generating the modulated data and supplying the modulated data to the data driver.

The data gain value generating step may include sequentially detecting a frame current amount (frame_current (k-1)) in each frame unit by using Equation 1 below;

[Equation 1]

Using Equation 2 below,

[Equation 2]

The overcurrent (over_current (k-1)) is detected by extracting the case where the difference between the display current amount frame_current (k-1) and the preset reference current amount MAX_CURRENT (R_OI) of one frame is 1 or more, and the detected overcurrent and generating the data gain value gain (k) using the value of (over_current (k-1)).

In the generating of the data gain value, when the occurrence of the overcurrent (over_current (k-1)) is confirmed, the data correction gain value is generated as a decimal number or the smallest value smaller than 1 to output the frame current amount as soon as possible, or

Using Equation 3a below,

Equation 3a

Setting and outputting a data gain value gain (k) such that the magnitude of the frame current amount to be reduced from the next image display line becomes larger than the detected overcurrent amount over_current (k-1),

는 앞으로 출력할 라인들에서 소비할 전류량이기 때문에 계산하는 시점에서는 알 수 없는 전류량인 것을 특징으로 한다. remind

Since the amount of current to be consumed in the lines to be output in the future is characterized in that the amount of current unknown at the time of calculation.

In the data gain value generating step, a current amount predicted value (predicted_current (k)) is set using Equation 4 below on the assumption that the average amount of current to be consumed in the remaining image display lines is equal to the current amount.

[Equation 4]

Under the assumption that the most recently displayed line is similar to the lines to be displayed, the current amount prediction value is set using Equation 5 below.

[Equation 5]

The weight is characterized by 2 ⁿ .

The data gain value generation step sets the data gain value gain (k) in consideration of the amount of overcurrent generated up to now and the amount of current change when outputting the remaining image display lines, but has not yet been outputted. The current variation of the image display lines is predicted using Equation 6 below.

[Equation 6]

By adding the current change amount predicted through Equation 6 and the amount of overcurrent generated so far, the summed overcurrent amount (predicted_total_over_current (k)) of each frame is predicted as shown in Equation 7 below.

[Equation 7]

Through Equation 8 below,

[Equation 8]

The final data gain value (gain (k)) to be applied to the lines on which the next image is to be displayed is determined.

In the organic light emitting diode display and the driving method thereof, the image data of each frame unit is modulated and displayed according to the frame current amount of the image display panel, thereby generating overcurrent of the image display panel. Can be prevented, and the life and reliability of the product can be improved. Particularly, in the present invention, the image data is modulated and displayed according to the frame current amount without configuring a separate frame data storage memory, thereby simplifying circuit configuration and lowering product price.

1 is a block diagram illustrating an organic light emitting diode display according to an exemplary embodiment of the present invention.
FIG. 2 is a configuration diagram illustrating in detail the image data converter illustrated in FIG. 1. FIG.
3 is a view showing an image of one frame that is displayed such that occurrence of overcurrent is suppressed.
4 is another diagram showing an image of one frame that is displayed such that occurrence of overcurrent is suppressed.
5 is another diagram showing an image of one frame displayed so that occurrence of overcurrent is suppressed.
FIG. 6 is a diagram showing an experimental result in which the frame current amount is controlled by a data gain value set by a data correction control unit. FIG.

Hereinafter, an organic light emitting diode display and a driving method thereof according to an exemplary embodiment of the present invention having the above characteristics will be described in detail with reference to the accompanying drawings.

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

The organic light emitting diode display shown in FIG. 1 includes an image display panel 1 including a plurality of pixel regions, a gate driver 2 driving the gate lines GL1 to GLn of the image display panel 1, and an image. The data driver 3 driving the data lines DL1 to DLm of the display panel 1 and the first and second power signals VDD and GND are applied to the power lines PLn to PLm of the image display panel. The power supply unit 4 and the RGB data RGB inputted from the outside in accordance with the size of the image display panel 1 and generate data and gate control signals DVS and GPS to generate the data and gate drivers 3 and 2. ) To analyze the current data of the current frame by analyzing the image data (Data) from the timing controller 5 and the timing controller 5 on a frame-by-frame basis, and the detected current frame current amount and the predetermined reference current amount R_OI. ) According to the comparison result By modulating the data and a picture data conversion unit (6) for supply to the data driver (3).

In the image display panel 1, a plurality of sub-pixels P are arranged in a matrix form in each pixel area to display an image. Each sub-pixel P includes a light emitting diode and a light emitting diode. A diode driving circuit for driving independently is provided. Specifically, one sub-pixel P is disposed between a diode driving circuit connected to any one of the gate line GL, the data line DL, and the power supply line PL, between the diode driving circuit and the second power signal GND. A connected light emitting diode is provided.

The diode driving circuits respectively supply the analog data signal from the connected data line DL to the light emitting diodes while charging the analog data signal to maintain the light emitting state.

The gate driver 2 receives the gate control signal GVS from the timing controller 5, for example, a gate on signal in response to a gate start pulse GSP and a gate shift clock GSC. Are sequentially generated and the pulse width of the gate-on signal is controlled according to a gate output enable (GOE) signal. The gate-on signals are sequentially supplied to the gate lines GL1 to GLn. Here, the gate off voltage is supplied to the gate lines GL1 to GLn during the period when the gate on voltage is not supplied.

The data driver 3 uses an image data converter by using a source start pulse SSP and a source shift clock SSC from among the data control signals DVS from the timing controller 5. 6) converts the modulated data (MData) modulated every frame unit into an analog voltage, that is, an analog video signal. In addition, an image signal is supplied to each of the data lines DL1 to DLm in response to a source output enable (SOE) signal. Specifically, the data driver 3 latches the image data (Data) input according to the SSC, and then one horizontal line every one horizontal period in which scan pulses are supplied to the gate lines GL1 to GLn in response to the SOE signal. Minute video signal is supplied to each of the data lines DL1 to DLm.

The power supply unit 4 supplies the first power signal VDD and the second power signal GND to the image display panel 1. Here, the first power signal VDD means a driving voltage for driving the light emitting cell OEL, and the second power signal GND may mean a ground voltage or a low voltage. Due to the difference between the first power signal VDD and the second power signal GND, a current corresponding to an image signal may also flow in each sub-pixel P. FIG.

The timing controller 5 arranges the RGB data RGB input from the outside to be suitable for driving the image display panel 1 and supplies the RGB data RGB to the image data converter 6. In addition, the timing controller 5 generates the gate and data control signals GVS and DVS using the synchronization signals MCLK, DE, Hsync, and Vsync input from the outside, and generates the gate driver 2 and the data driver ( Supply to 3).

The image data converter 6 analyzes the image data Data sequentially input from the timing controller 5 on a frame-by-frame basis to detect the current amount of the current frame, and detects the detected current frame current amount and the predetermined reference current amount R_OI. ). The data correction gain value is set to be varied according to the comparison result, and the image data of the next frame is modulated with the data correction value and supplied to the data driver 3.

FIG. 2 is a block diagram illustrating in detail the image data converter illustrated in FIG. 1.

The image data converter 6 shown in FIG. 2 is a data analyzer 11 which analyzes the grayscale distribution HData of the image data Data sequentially input from the timing controller 5 in units of frames, and the analyzed data. The luminance correction gain value Gse1 is extracted by extracting an average or maximum luminance value every frame unit using the gray scale distribution HData and comparing the extracted average or maximum luminance value with a luminance value determined by a predetermined reference current amount R_OI. The luminance correction control unit 12 for generating a frame current detects a frame current amount and compares the frame current amount with the preset reference current amount R_OI, and accordingly compares the frame current amount with the next frame data to be equal to or less than the preset reference current amount R_OI. An overcurrent prevention unit 14 for generating a data gain value Gset2 for modulating the frame data, and an image for every frame input from the timing controller 5. The data Data is first-modulated according to the luminance correction gain value Gse1 and second-modulated according to the data gain value Gset2 to generate modulated data MData in units of frames, and the data driver 3 And a data modulator 13 for supplying to the.

The data analyzing unit 11 analyzes the gray scale distribution (HData) by counting or histogramizing the number of image data Data in each frame unit for each gray level. The analyzed grayscale distribution (HData) information is supplied to the luminance correction controller 12.

The luminance correction controller 12 extracts an average or maximum luminance value every frame unit using the analyzed gray scale distribution HData, and calculates the luminance value determined by the extracted average or maximum luminance value and a predetermined reference current amount R_OI. Are compared to generate the luminance correction gain value Gse1.

For example, when the average luminance value of one frame data is extracted through the gray scale distribution HData, the extracted luminance value is compared with the luminance value determined by the preset reference current amount R_OI. Create a gain value (Gse1) as 1. When the extracted average luminance value is smaller than the luminance value determined by the preset reference current amount R_OI, the luminance correction gain value Gse1 may be generated as a prime number larger than 1, for example, any one of 1.11 to 2.0. have. On the other hand, when the extracted average luminance value is greater than the luminance value determined by the preset reference current amount R_OI, the luminance correction gain value Gse1 may be generated as a prime number smaller than 1, for example, any one of 0.1 to 0.99. . Accordingly, the data modulator 13 primarily multiplies the image data Data grays or luminance values input from the timing controller 5 by the luminance correction gain value Gse1, respectively. Modulate the luminance values.

The overcurrent protection unit 14 sequentially detects the frame current amount in each frame unit and compares the frame current amount with a preset reference current amount R_OI. According to a result of comparing the detected frame current amount with the preset reference current amount R_OI, a data gain value for modulating the next frame data such that the frame current amount by the next frame data is equal to or smaller than the preset reference current amount R_OI ( Create Gset2).

For example, when the detected frame current amount is equal to the preset reference current amount R_OI, the overcurrent protection unit 14 may generate the data gain value Gset2 as 1. In this case, the next frame data may be kept the same. However, when the detected frame current amount is smaller than the preset reference current amount R_OI, the luminance correction gain value Gse1 may be generated as a value greater than one. When the detected frame current amount is larger than the preset reference current amount R_OI, the luminance correction gain value Gse1 may be generated to be smaller than one. Accordingly. The data modulator 13 generates the modulated data MData in units of frames by multiplying the first-modulated image data according to the luminance correction gain value Gse1 by the data gain value Gset2 and performing second-order modulation. Supply to the drive unit (3).

The overcurrent protection unit 14 of FIG. 2 is a current calculation unit 21 which sequentially detects a frame current amount (frame_current (k-1)) for each frame unit by using Equation 1 below, Equation 2 below. The overcurrent (over_current (k-1)) is detected by comparing each frame current amount (frame_current (k-1)) with a preset reference current amount (MAX_CURRENT; R_OI) by using Equations 3 and 4, respectively. A data correction controller 22 for generating the data gain value (gain (k); Gset2) and a current amount of a previous frame in at least one pixel row or column, and provide the data correction controller 22 to the data correction controller 22. A buffer unit 14 is provided.

The current calculator 21 sequentially detects the frame current amount frame_current (k-1) in units of frames by using Equation 1 below.

[Equation 1]

Here, line_current (line) is the amount of current in the line on which the current image is displayed, and prev_line_current (line) is the amount of current displayed up to now. Therefore, the frame current amount frame_current (k-1) is the accumulated sum current amount of all the pixels.

The data correction controller 22 uses the following equation 2 to determine the overcurrent (over_current (k-1)) according to a result of comparing the frame current amount frame_current (k-1) and the preset reference current amount MAX_CURRENT R_OI. Detect.

[Equation 2]

That is, the overcurrent over_current (k-1) is detected by extracting a case where the difference between the display current amount frame_current (k-1) and the preset reference current amount MAX_CURRENT R_OI of one frame is 1 or more.

3 is a view showing an image of one frame displayed to suppress the occurrence of overcurrent.

When the overcurrent generation is confirmed according to the overcurrent (k-1) result detected through Equation 2, the data correction controller 22 displays the image data displayed after the corresponding pixel line as shown in FIG. 3. Modulation suppresses the occurrence of overcurrent. As an example, when the occurrence of the overcurrent (k-1) is confirmed (k-line display time), the data correction controller 22 may set the data correction gain value Gset2 to the smallest decimal number or zero, which is smaller than one. Can be generated to reduce the frame current as soon as possible. Accordingly, the data modulator 13 modulates the modulated data MData to reduce the amount of frame current as soon as possible by second-modulating the data gain value Gset2 supplied as 0.1 or 0 to the image data having the primary luminance modulated. Generation and supply to the data driver (3).

4 is another diagram illustrating an image of one frame that is displayed such that occurrence of overcurrent is suppressed.

The data correction control unit 22 may generate the luminance correction gain value Gse1 to be the smallest prime number or zero set in advance so that the frame current amount is reduced as soon as possible, but the amount of the frame current amount that should be reduced is detected by the overcurrent amount (over_current ( The data gain value Gset2 may be determined and applied to be larger than k-1)).

In other words, the data correction controller 22 uses the following Equation 3 so that the size of the frame current amount to be reduced from the next image display line becomes larger than the detected overcurrent amount (over_current (k-1)). The value Gset2 (gain (k)) can be set.

When the current amount is reduced using the data gain value Gset2 (gain (k)) according to Equation 3a below, whether or not the overcurrent amount (over_current (k-1)) is corrected through several image display lines The data gain value Gset2 (gain (k)) may vary. Accordingly, the data gain value Gset2 (gain (k)) according to Equation 3a is equal to the overcurrent amount (over_current (k-1)) generated in the k-1th line of FIG. 4 to the k + mth line in the future. It is theoretically derived considering the decrease over time.

Equation 3a

는 앞으로 출력할 라인들에서 소비할 전류량이기 때문에 계산하는 시점에서는 알 수 없는 전류량이다. here,

Is the amount of current unknown at the time of calculation because it is the amount of current to be consumed in the lines to be output.

On the other hand, at the time of outputting the k-1th line in the current frame, the data of the previous frame is still output after the kth. Thus, as shown in FIG. The data gain value Gset2 (gain (k)) may be determined to be the same. The data gain value Gset2 (gain (k)) in this case can be obtained by the following equation (3b).

[Equation 3b]

는 앞으로 출력할 라인들에서 소비할 전류량이기 때문에 계산하는 시점에서는 알 수 없는 전류량이기 때문에, 나머지 영상 표시 라인들에 대한 전류량 예측치가 설정되어야 한다. In the above equations

Since is the amount of current to be consumed in the lines to be output in the future, since the amount of current is unknown at the time of calculation, the current amount prediction value for the remaining image display lines should be set.

Accordingly, the data correction controller 22 may set the current amount predicted value (predicted_current (k)) by using Equation 4 below on the assumption that the average amount of current to be consumed in the remaining image display lines is the same as the current amount.

[Equation 4]

On the other hand, under the assumption that the most recently displayed line is similar to the lines on which the next image is to be displayed, the current amount prediction value may be set using Equation 5 below. Here, the weight may be defined as 2 ⁿ for convenience of implementation.

[Equation 5]

5 is another diagram showing an image of one frame that is displayed such that overcurrent generation is suppressed.

In order to generate the data gain value Gset2 (gain (k)), the data correction controller 22 considers not only the amount of overcurrent generated so far but also the amount of current change when outputting the remaining image display lines (Gset2). ; gain (k)) can be set. In this case, the current variation of the remaining image display lines which are not yet output can also be estimated using Equation 6 below.

[Equation 6]

Accordingly, the data correction controller 22 adds the amount of current change predicted through Equation 6 and the amount of overcurrent generated so far to predict the summed overcurrent amount (predicted_total_over_current (k)) of each frame as shown in Equation 7 below. .

[Equation 7]

As such, when the summed overcurrent amount (predicted_total_over_current (k)) of one frame is predicted through Equation 7, the final data gain value (gain (k) to be applied to the lines to which the next image is displayed through Equation 8 below. ) Can be determined.

[Equation 8]

The data modulator 13 applies the data gain value Gset2 or the final data gain value gain (k) set from the data corrector 22 to the image data primarily modulated by the luminance correction gain value Gse1. By multiplying and performing secondary modulation, modulated data MData in a frame unit is generated and supplied to the data driver 3.

6 is a diagram illustrating an experiment result in which a frame current amount is controlled by a data gain value set by a data correction controller.

If the data gain value Gse2 is set to a minimum value so that the frame current amount decreases as soon as possible, or the size and amount of the frame current amount that should be predicted to be reduced in the future is set and applied to be larger than the detected overcurrent amount, it is shown in FIG. As described above, the frame current amount may be maintained below the preset reference current amount MAX_CURRENT (R_OI).

In the present invention, by detecting the amount of frame current and the amount of predicted current to prevent overcurrent, image data can be modulated so that overcurrent does not occur without configuring a separate frame data storage memory, thereby simplifying circuit configuration and reducing product prices. Can be lowered.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

1: Image display panel 2: Gate driver
3: data driver 4: power supply
5: timing control unit 6: image data conversion unit
11: data analyzer 12: luminance correction controller
13: Data Modulator 14: Overcurrent Protection Unit
21: current calculation unit 22: data correction control unit
23: buffer part

Claims (12)

An image display panel having a plurality of pixel regions;
A gate driver for driving gate lines of the image display panel;
A data driver for driving data lines of the image display panel;
A timing controller for aligning the RGB data input from the outside to the size of the image display panel and generating data and gate control signals to control the data and gate drivers;
Analyzing the image data from the timing control unit every frame to detect the current amount of the current frame, and modulates the next frame data according to the comparison result of the detected current frame current amount and the predetermined reference current amount (R_OI) to the data driver A video data conversion unit for supplying
The image data converter
A data analyzer for analyzing the gradation distribution of image data sequentially input from the timing controller in units of frames;
Luminance correction which extracts an average or maximum luminance value every frame unit using the analyzed grayscale distribution and compares the extracted average or maximum luminance value with a luminance value determined by the preset reference current amount to generate a luminance correction gain value. Control,
The frame current amount is detected and compared with the preset reference current amount, and a data gain value (gain (k) for modulating the next frame data such that the frame current amount according to the next frame data is equal to or less than the preset reference current amount according to the comparison result. Overcurrent protection to generate)), and
Firstly modulate the image data of each frame unit input from the timing controller according to the luminance correction gain value, and generate modulated data of the frame unit by second-modulation according to the data gain value, and supply it to the data driver. An organic light emitting diode display comprising a data modulator. delete The method of claim 1,
The overcurrent prevention unit sequentially detects the frame current amount (frame_current (k-1)) representing the accumulated sum current of all pixels when outputting up to the k-1th line of the current frame in each frame unit. ,
When the data of the k-1th line of one frame is outputted, the data from the display current amount (frame_current (k-1)) and the preset reference current amount R_OI is 1 or more is extracted. A data correction control unit for detecting an overcurrent (over_current (k-1)) generated when outputting and generating the data gain value (gain (k)) using the detected overcurrent (over_current (k-1)) value. An organic light emitting diode display comprising: a. The method of claim 3, wherein
The data correction control unit,
When the occurrence of the overcurrent (over_current (k-1)) is confirmed, the data gain value is generated to be the smallest prime number or zero among the prime numbers having a digit smaller than 1 digit and output so that the amount of frame current is reduced.
characterized in that the data gain value (gain (k)) is set and output so that the magnitude of the frame current amount to be reduced from the kth image display line becomes larger than the detected overcurrent amount (over_current (k-1)). LED display. The method of claim 3, wherein
The data correction control unit,
Some image display lines in which the current frame data is not output on the assumption that the average amount of current to be consumed in the image display lines after the k-th line of the current frame is the same as the average current amount when outputting up to the data of the k-1th line of the current frame Setting the predicted current amount (predicted_current (k))
Assuming that the most recently displayed line is similar to the lines to be displayed next, the current amount prediction value (predicted_current (k)) is set in some image display lines in which the current frame data is not output. LED display. The method of claim 3, wherein
The data correction control unit,
The data gain value (gain (k)) in consideration of the amount of overcurrent generated when the data of the k-1th line of the current frame is output as well as the amount of current change when outputting image display lines in which the current frame data is not output. ),
Predict the amount of current change in the remaining image display lines for which the current frame data is not output, and add the estimated current change amount and the amount of overcurrent generated when outputting up to the data of the k-1th line of the current frame, and then add the overcurrent amount of each frame. and predicting (predicted_total_over_current (k)) to determine a final data gain value (gain (k)) to be applied to the lines on which the image in which the current frame data is not output is displayed. Driving gate and data lines of the image display panel;
Controlling data and gate drivers by aligning RGB data input from the outside to a size of the image display panel and generating data and gate control signals to drive the gates and data lines; And
Analyzing the image data every frame unit to detect the current amount of the current frame, and modulating the next frame data according to the comparison result of the detected current frame current amount and the preset reference current amount to supply to the data driver,
Modulating the next frame data
Analyzing the gray level distribution of the image data every frame unit;
Extracting an average or maximum luminance value every frame by using the analyzed grayscale distribution, and generating a luminance correction gain value by comparing the extracted average or maximum luminance value with the luminance value determined by the preset reference current amount;
Detecting the frame current amount and comparing it with the preset reference current amount, and generating a data gain value for modulating the next frame data such that the frame current amount according to the next frame data is equal to or less than the preset reference current amount according to a comparison result; , And
And generating modulated data in frame units by first modulating the image data in every frame unit according to the luminance correction gain value and secondly modulating in accordance with the data gain value, and supplying the modulated data in a frame unit. A method of driving an organic light emitting diode display, characterized in that. delete The method of claim 7, wherein
The data gain value generation step,
Sequentially detecting the frame current amount (frame_current (k-1)) representing the accumulated sum current amount of all pixels when outputting up to the k-1th line of the current frame in each frame unit;
When the data of the k-1th line of one frame is output, the case where the difference between the display current amount (frame_current (k-1)) and the preset reference current amount (MAX_CURRENT; R_OI) is 1 or more is extracted. Detecting an overcurrent (over_current (k-1)) when the data is output, and generating the data gain value (gain (k)) using the detected overcurrent (over_current (k-1)) value Method of driving an organic light emitting diode display, characterized in that it comprises a. The method of claim 9,
The data gain value generation step,
When the occurrence of the overcurrent (over_current (k-1)) is confirmed, the data gain value is generated to be the smallest prime number or zero among the prime numbers having a digit smaller than 1 digit and output so that the amount of frame current is reduced.
characterized in that the data gain value (gain (k)) is set and output so that the magnitude of the frame current amount to be reduced from the kth image display line becomes larger than the detected overcurrent amount (over_current (k-1)). Method of driving LED display device. The method of claim 9,
The data gain value generation step
Some image display lines in which the current frame data is not output on the assumption that the average amount of current to be consumed in the image display lines after the k-th line of the current frame is the same as the average current amount when outputting up to the data of the k-1 line of the current frame Setting their current predicted value (predicted_current (k)),
An organic light emitting diode comprising setting a current amount prediction value (predicted_current (k)) of some image display lines for which current frame data is not output, assuming that the most recently displayed line is similar to the lines to be displayed next image. Method of driving display device. The method of claim 9,
The data gain value generation step
The data gain value (gain (k)) in consideration of the amount of overcurrent generated when the data of the k-1th line of the current frame is output as well as the amount of current change when outputting image display lines in which the current frame data is not output. ),
It estimates the current variation of the remaining undisplayed image display lines of the current frame, and adds the estimated current variation to the overcurrent generated when outputting up to the data of the k-1th line of the current frame. and predicting predicted_to_over_current (k)) to determine a final data gain value (gain (k)) to be applied to the lines on which the image in which the current frame data is not output.

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