KR102126550B1 - Organic light emitting diode display device and driving method the same - Google Patents

Abstract

The present invention relates to an OLED display device and a driving method thereof, wherein each pixel includes a display panel including an OLED; A converted image data generation unit that analyzes the input image data to detect a high gradation region, and converts gradation values of image data corresponding to the high gradation region to transmit converted image data; The converted image data applied to each pixel is accumulated every frame to store average accumulated grayscale data and deterioration duration for each pixel in a memory, and input according to the average accumulated grayscale data for each pixel and deterioration duration. And a timing controller for adding and outputting a gain value to the converted image data; The converted image data generation unit detects a center coordinate of the high gradation region, defines an area within a specific distance from the center coordinates as a central region within the high gradation region, and excludes the central region from within the high gradation region. It is characterized in that the gradation values of the image data corresponding to the remaining areas are varied low.

Description

OLED display device and its driving method {ORGANIC LIGHT EMITTING DIODE DISPLAY DEVICE AND DRIVING METHOD THE SAME}

The present invention relates to an OLED display device and a driving method thereof.

Recently, OLED display devices using organic light emitting diodes (hereinafter referred to as "OLEDs") have been widely applied to TVs, monitors, and mobile information devices.

In an OLED display device, an OLED is a self-luminous element, and as the driving time of the element increases, driving characteristics deteriorate. Therefore, in the prior art, in order to compensate for a decrease in driving characteristics of the OLED, the threshold voltage and mobility of the OLED are calculated, and image data for driving the OLED is corrected based on the calculated threshold voltage and mobility of the OLED.

However, the factor that changes the driving characteristics of the OLED is temperature in addition to the driving time. Therefore, there is a problem that the driving characteristics of the OLED cannot be accurately compensated by only calculating the threshold voltage and mobility of the OLED and correcting the image data.

The present invention is to solve the above problems, and an object of the present invention is to provide an OLED display device and a driving method capable of more accurately and accurately compensating for deterioration in driving characteristics of an OLED.

In order to achieve the above object, an OLED display device according to an exemplary embodiment of the present invention includes a display panel in which each pixel includes an OLED; A gate driver driving gate lines of the display panel; A data driver driving data lines of the display panel; A converted image data generation unit that analyzes the input image data to detect a high grayscale region, and differentially varies grayscale values of the image data corresponding to the high grayscale region to transmit converted image data; The converted image data provided from the converted image data generation unit are arranged and supplied to the data driver, a plurality of control signals for controlling the gate driver and the data driver are output, and the converted image applied to each pixel A timing controller which accumulates data every frame to store cumulative gradation data for each pixel in a memory, and adds a gain value to the input converted image data according to the cumulative gradation data for each pixel and outputs it; The converted image data generation unit detects a center coordinate of the high gradation region, defines an area within a specific distance from the center coordinates as a central region within the high gradation region, and excludes the central region from within the high gradation region. It is characterized in that the gradation values of the image data corresponding to the remaining areas are varied low.

The converted image data generation unit includes an edge detection unit that extracts an edge region from the input image data; A calculation unit configured to set a corresponding region as the high gradation region when an average gradation value calculated by averaging the gradation values of each region among a plurality of regions divided according to the edge region is greater than a reference gradation value; It is characterized in that it comprises an image modulator for changing the gradation values corresponding to the remaining region among the gradation values corresponding to the high gradation region to a lower value as it moves away from the center coordinates.

The converted image data generation unit further includes an image separation unit that separates the input image data into image data for each color; The edge detector extracts the edge region by analyzing the image data for each color; The calculating unit sets the high gradation area in the image data for each color; The image modulating unit is characterized in that the gradation values of the remaining regions included in the image data for each color are varied.

The timing controller includes a look-up table to which the gain values are mapped corresponding to the average cumulative grayscale data and the deterioration durations; The memory in which the average cumulative grayscale data for each pixel and the deterioration duration are updated every frame; And a deterioration compensator configured to set the gain value for each pixel by referring to the look-up table and the memory, and add and output the gain value to the converted image data input to each pixel.

The gain values may include compensation grayscale data information for compensating degradation of the OLED generated by continuously applying the average accumulated grayscale data for the deterioration duration for the OLED of each pixel.

In addition, in order to achieve the above object, the driving method of the OLED display device according to the embodiment of the present invention analyzes the image data input by the converted image data generation unit to detect a high gradation region, and corresponds to the high gradation region. Transmitting the converted image data by differentially varying the gradation values of the image data; A timing controller arranges the converted image data provided from the converted image data generator and supplies it to a data driver, accumulates the converted image data applied to each pixel every frame, and stores accumulated grayscale data for each pixel in a memory And adding and outputting a gain value to the input converted image data according to the accumulated grayscale data for each pixel; The converted image data generation unit detects a center coordinate of the high gradation region, defines an area within a specific distance from the center coordinates as a central region within the high gradation region, and excludes the central region from within the high gradation region. It is characterized in that the gradation values of the image data corresponding to the remaining areas are varied low.

The converting image data generating unit transmitting the transformed image data may include extracting an edge region from the input image data; Setting a corresponding region as the high gradation region when an average gradation value calculated by averaging gradation values of each region among a plurality of regions divided according to the edge region is greater than a reference gradation value; It characterized in that it comprises the step of varying the gray value corresponding to the rest of the gradation values corresponding to the high gradation region as the distance away from the center coordinates.

The converting image data generating unit transmitting the converted image data may include separating the input image data into color-specific image data; Analyzing the image data for each color and extracting the edge region; And setting the high gradation area in the image data for each color, and varying the gradation values of the remaining areas included in the image data for each color.

The timing controller includes a look-up table to which the gain values are mapped corresponding to the average cumulative grayscale data and the deterioration durations; The memory in which the average cumulative grayscale data for each pixel and the deterioration duration are updated every frame; And a deterioration compensator configured to set the gain value for each pixel by referring to the look-up table and the memory, and add and output the gain value to the converted image data input to each pixel.

The gain values may include compensation grayscale data information for compensating degradation of the OLED generated by continuously applying the average accumulated grayscale data for the deterioration duration for the OLED of each pixel.

In the present invention, the converted image data generation unit analyzes the image data input from the outside to detect a high gradation region, and generates converted image data by differentially varying the gradation values of the image data corresponding to the detected high gradation region. Accordingly, the present invention compensates for variations in deterioration characteristics of the OLED due to temperature variations occurring between the central portion and the outer boundary portion in the high gradation region of the input image data.

In addition, according to the present invention, a timing controller accumulates converted image data for each pixel to generate a gain value, and adds and outputs a gain value to the converted image data input to each pixel. Accordingly, the present invention compensates for variations in deterioration characteristics of the OLED due to temperature variations occurring between the high gradation region and the low gradation region of the input image data.

As described above, the present invention compensates for the deterioration of the OLED by taking into account not only the temperature deviation between the high gradation region and the low gradation region of the input image data, but also the temperature deviation within the high gradation region, thereby more accurately compensating for the deterioration characteristics of the OLED It can be done, so the image quality is excellent.

1 is a configuration diagram of a flat panel display device of the present invention.
2 is a block diagram of the converted image data generation unit 10 shown in FIG. 1.
3A to 3D are exemplary views for explaining the method of driving the transformed image data generation unit 10 illustrated in FIG. 2 step by step.
4 is a configuration diagram of the converted image data generation unit 10 shown in FIG. 1.
FIG. 5 is an exemplary view illustrating the method of driving the converted image data generation unit 10 illustrated in FIG. 4 step by step.
6 is a configuration diagram of the timing controller 8 shown in FIG. 1.

Hereinafter, a flat panel OLED display device and a driving method thereof according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a flat panel display device of the present invention.

The flat panel display shown in FIG. 1 includes a display panel 2, a gate driver 4, a data driver 6, a timing controller 8, and a converted image data generator 10.

The display panel 2 includes a plurality of gate lines GL1 to GLn intersecting each other and a plurality of data lines DL1 to DLm. A plurality of pixels P are disposed in an intersection area between the gate line GL and the data line DL. Each pixel P includes an OLED and a pixel driving circuit for driving the OLED.

The pixel driving circuit includes a switching TFT, a driving TFT, and a capacitor. The switching TFT charges the capacitor with the data voltage supplied from the data line DL in response to the scan pulse supplied from the gate line GL. The driving TFT controls the amount of current supplied to the OLED according to the data voltage charged in the capacitor to adjust the amount of light emitted from the OLED.

1, the gate driver 4 may be embedded in a non-display area of the display panel 2. Further, the gate driver 4 is not shown, but may be integrated and connected to one side of the display panel 2. The gate driver 4 includes a gate shift register for supplying scan pulses to the plurality of gate lines GL1 to GLn according to the plurality of gate control signals GCS provided from the timing controller 8.

The data driver 6 converts the converted image data MRGB input from the timing controller 8 into data voltages using a plurality of gamma compensation voltages according to a plurality of data control signals DCS provided from the timing controller 8. do. In addition, the data driver 6 supplies data voltages to the plurality of data lines DL. To this end, the data driver 6 includes a data shift register for outputting a sampling signal, a latch for latching image data, and a digital-to-analog converter.

The timing controller 8 arranges the converted image data MRGB input from the converted image data generation unit 10 according to the size and resolution of the display panel 2 and supplies it to the data driver 6.

The timing controller 8 outputs a plurality of control signals GCS and DCS using synchronization signals SYNC input from the outside. The plurality of control signals GCS and DCS includes a gate control signal GCS and a data control signal DCS. The gate control signal GCS is a signal for controlling the gate driver 4, and the data control signal DCS is a signal for controlling the data driver 6. The synchronization signals SYNC include a dot clock DCLK, a data enable signal DE, a horizontal synchronization signal Hsync, and a vertical synchronization signal Vsync.

The timing controller 8 accumulates the converted image data MRGB applied to each pixel every frame and stores the accumulated grayscale data for each pixel in a memory. Then, the timing controller 8 adds a gain value GAIN to the converted image data MRGB input according to the accumulated grayscale data for each pixel, and outputs the gain value GAIN. The timing controller 8 will be described later in detail with reference to FIG. 6.

The converted image data generator 10 analyzes the image data RGB input from the outside to detect the high grayscale region HGA, and the grayscale values of the image data RGB corresponding to the detected high grayscale region HGA The differentially varied to generate converted image data (MRGB).

For reference, in the OLED display, when image data having a high gradation is repeatedly applied to a specific pixel of the display panel, the temperature of the high gradation region including the specific pixel rises compared to other regions. Therefore, as the driving time elapses, a temperature deviation occurs between the high grayscale region and the low grayscale region, and a characteristic variation of the OLED occurs for each high grayscale region and low grayscale region due to the temperature variation. On the other hand, the temperature deviation of the display panel also exists in the high gradation region. Specifically, the temperature of the high gradation region is highest in the central portion, and lowers toward the outer boundary portion from the central portion. As described above, in the OLED display device, temperature deviations are generated for each high grayscale region and low grayscale region according to input image data, and temperature variations are generated between the central portion and the outer boundary portion within the high grayscale region.

In the present invention, the converted image data generator 10 analyzes the image data RGB input from the outside to detect the high grayscale region HGA, and the image data RGB corresponding to the detected high grayscale region HGA. The gradation values of these are differentially varied to generate converted image data (MRGB). Accordingly, the present invention compensates for variations in deterioration characteristics of the OLED due to temperature variations occurring between the central portion and the outer boundary portion in the high gradation region of the input image data.

In addition, according to the present invention, the timing controller 8 accumulates converted image data MRGB for each pixel to generate a gain value, and adds a gain value to the converted image data RGB input to each pixel and outputs it. Accordingly, the present invention compensates for variations in deterioration characteristics of the OLED due to temperature variations occurring between the high gradation region and the low gradation region of the input image data.

2 is a block diagram of the converted image data generation unit 10 shown in FIG. 1. 3A to 3D are exemplary views for explaining the driving method of the transformed image data generation unit 10 illustrated in FIG. 2 step by step.

The converted image data generation unit 10 includes an edge detection unit 12, an operation unit 14, and an image modulation unit 16.

The edge detector 12 extracts the edge region by analyzing the input image data RGB. For example, it is assumed that the image data RGB input from the outside includes a circle having a relatively high gradation and a rectangle having a relatively low gradation as shown in FIG. 3A. Then, the edge detector 12 extracts the outer border of the circle and the square, as shown in Figure 3b.

The calculation unit 14 sets a region in which the average gradation value calculated by averaging the gradation values of each region is brighter than the reference gradation value among the multiple regions divided according to the edge region as the high gradation region (HGA). In addition, the calculation unit 14 sets a region in which the average gradation value calculated by averaging the gradation values of each region among the multiple regions divided according to the edge region is darker than the reference gradation value as the low gradation region (LGA). Accordingly, as illustrated in FIG. 3B, the calculation unit 14 sets an area corresponding to a circle as a high gray level area (HGA) and an area corresponding to a rectangle as a low gray level area (LGA).

Referring to FIG. 3C, the image modulator 16 detects the center coordinates of the high grayscale region HGA, and defines the center regions A1 of adjacent regions within a specific distance from the center coordinates within the high grayscale region HGA. do. In addition, the image modulating unit 16 changes the gradation value of the image data RGB corresponding to the remaining regions A2, A3, and A4 excluding the central region A1 in the high gradation region HGA. The image modulator 16 maintains the initial input default value of the gradation value of the central area A1, and the gradation value of the remaining areas A2, A3, and A4 varies as the distance from the center coordinates decreases. Therefore, the calculation unit 10 maintains the initial input default value of the grayscale value of the area A1 adjacent to the center coordinate, lowers the grayscale values relatively largely for the A4 area, and relatively smallest grayscale values for the A2 area. Lowers.

As described above, when the image modulator 16 applies a gradient effect that becomes darker from the center coordinates to the outer boundary line of the high gradation region HGA with respect to the high gradation region HGA, conversion image data is generated. The unit 10 outputs the converted image data MRGB as shown in FIG. 3D.

Meanwhile, as illustrated in FIG. 4, the converted image data generation unit 10 may further include an image separation unit 18 that separates the input image data RGB into image data for each color. For reference, in the present invention, the color of the image data RGB is composed of red (R), green (G), and blue (B), or red (R), green (G), blue (B), and white (W) ).

For example, if the color of the image data RGB is composed of red (R), green (G), blue (B), and white (W), the edge detection unit 12, as shown in Figure 5, the edge The detector 12 analyzes image data (R, G, B, W) for each color to extract an edge region, and the calculator 14 extracts high gradations from the image data (R, G, B, W) for each color. The area HGA is set, and the image modulator 16 applies a gradient effect that becomes darker toward the outer boundary line from the center coordinates with respect to the remaining areas included in the image data R, G, B, and W for each color. .

The converted image data generation unit 10 combines image data for each color to which the gradation effect is applied to generate final converted image data (MRGB).

Hereinafter, the timing controller 8 of the present invention will be described in detail.

6 is a configuration diagram of the timing controller 8 shown in FIG. 1.

Referring to FIG. 6, a control signal generation unit 20, an image alignment unit 22, a memory 24, a look-up table 26, and a deterioration compensation unit 28 are provided.

The control signal generator 20 outputs a plurality of control signals GCS and DCS using synchronization signals SYNC input from the outside.

The image alignment unit 22 outputs the converted image data MRGB input from the converted image data generation unit 10 according to the size and resolution of the display panel 2.

The memory 24 stores cumulative grayscale data for each pixel calculated by accumulating converted image data (MRGB) applied to each pixel every frame. The cumulative grayscale data may be grayscale data accumulated for each frame or cumulative average data obtained by averaging grayscale data accumulated for each frame. In addition, the deterioration duration may be further stored in the memory 24.

For example, as shown in Table 1, if the first applied image data for a specific pixel is 255 gradations, and if applied for 3 frames, the average cumulative gradation data is 255 gradations. Subsequently, if the image data applied to the specific pixel is 250 gradations and is applied for 7 frames, the total degradation duration is 10 frames, and the average cumulative gradation data is updated to 252 gradations. Subsequently, if the image data applied to the specific pixel is 128 gradations and is applied for 5 frames, the total degradation duration is 15 frames, and the average cumulative gradation data is updated to 210 gradations. The memory 24 stores average accumulated grayscale data and deterioration duration for each pixel in this manner.

The look-up table 26 is stored by mapping gain values GAIN corresponding to average cumulative grayscale data and deterioration durations.

The gain values GAIN include compensation gradation data information for compensating deterioration of the OLED generated by continuously applying average cumulative gradation data during the deterioration duration for the OLED of each pixel.

The deterioration compensator 28 refers to the look-up table 26 and the memory 24 to set a gain value GAIN for each pixel, and a gain value GAIN to the converted image data MRGB input to each pixel And output.

As described above, according to the present invention, the converted image data generation unit 10 analyzes the image data RGB input from the outside to detect the high grayscale region HGA, and detects the high grayscale region HGA. The gradation values of the corresponding image data RGB are differentially varied to generate converted image data MRGB. Accordingly, the present invention compensates for variations in deterioration characteristics of the OLED due to temperature variations occurring between the central portion and the outer boundary portion in the high gradation region of the input image data.

In addition, according to the present invention, the timing controller 8 accumulates converted image data MRGB for each pixel to generate a gain value, and adds a gain value to the converted image data RGB input to each pixel and outputs it. Accordingly, the present invention compensates for variations in deterioration characteristics of the OLED due to temperature variations occurring between the high gradation region and the low gradation region of the input image data.

As described above, the present invention compensates for the deterioration of the OLED in consideration of not only the temperature deviation between the high gradation region and the low gradation region of the input image data, but also the image quality is excellent.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and it is common in the technical field to which the present invention pertains that various substitutions, modifications and changes are possible without departing from the spirit of the present invention. It will be clear to those who have the knowledge of

10: conversion image data generation unit 12: edge detection unit
14: operation unit 16: image modulation unit
20: control signal generation unit 22: image alignment unit
24: memory 26: lookup table
28: deterioration compensation unit

Claims (10)

A display panel in which each pixel includes an OLED;
A gate driver driving gate lines of the display panel;
A data driver driving data lines of the display panel;
A converted image data generation unit that analyzes the input image data to detect a high gradation region, and transmits transformed image data by differentially varying gradation values of the image data corresponding to the high gradation region;
The converted image data provided from the converted image data generation unit are arranged and supplied to the data driver, a plurality of control signals for controlling the gate driver and the data driver are output, and the converted image applied to each pixel A timing controller that accumulates data every frame to store cumulative grayscale data for each pixel in a memory, and adds a gain value to the converted image data according to the cumulative grayscale data for each pixel and outputs it;
The converted image data generation unit
The center coordinates of the high gradation region are detected, and an adjacent region within a specific distance from the center coordinates is defined as a central region within the high gradation region, and an image corresponding to the remaining regions excluding the center region in the high gradation region OLED display device characterized in that the gradation value of the data is varied low. The method according to claim 1,
The converted image data generation unit
An edge detector extracting an edge region from the input image data;
A calculation unit configured to set a corresponding region as the high gradation region when an average gradation value calculated by averaging the gradation values of each region among a plurality of regions divided according to the edge region is greater than a reference gradation value;
And a grayscale value corresponding to the remaining area among the grayscale values corresponding to the high grayscale area, wherein an image modulating unit is configured to change as the distance from the center coordinates becomes lower. The method according to claim 2,
The converted image data generation unit
And an image separator for separating the input image data into image data for each color;
The edge detector extracts the edge region by analyzing the image data for each color;
The calculating unit sets the high gradation area in the image data for each color;
The image modulator is an OLED display device, characterized in that the gradation values of the remaining areas included in the image data for each color are varied. The method according to claim 1,
The timing controller
The memory in which the average accumulated grayscale data which is the accumulated grayscale data for each pixel and the deterioration duration are updated every frame;
A lookup table to which the gain values are mapped corresponding to the average cumulative grayscale data and the deterioration durations;
And a deterioration compensator configured to set the gain value for each pixel by referring to the look-up table and the memory, and add and output the gain value to the converted image data input to each pixel. Display device. The method according to claim 4,
The gain values are
An OLED display device comprising compensation grayscale data information for compensating degradation of the OLED generated by continuously applying the average cumulative grayscale data for the deterioration duration for the OLED of each pixel. Analyzing the image data input by the converted image data generation unit to detect a high grayscale region, and transmitting the converted image data by differentially varying grayscale values of the image data corresponding to the high grayscale region;
A timing controller arranges the converted image data provided from the converted image data generator and supplies it to a data driver, accumulates the converted image data applied to each pixel every frame, and stores accumulated grayscale data for each pixel in a memory And adding and outputting a gain value to the converted image data according to the accumulated grayscale data for each pixel;
The converted image data generation unit
The center coordinates of the high gradation region are detected, and an adjacent region within a specific distance from the center coordinates is defined as a central region within the high gradation region, and an image corresponding to the remaining regions excluding the center region in the high gradation region A method of driving an OLED display, characterized in that the gradation values of data are varied low. The method according to claim 6,
The step of transmitting the converted image data by the converted image data generation unit
Extracting an edge region from the input image data;
Setting a corresponding region as the high gradation region when an average gradation value calculated by averaging gradation values of each region among a plurality of regions divided according to the edge region is greater than a reference gradation value;
And a step of changing the grayscale values corresponding to the remaining regions among the grayscale values corresponding to the high grayscale region to a lower value as the distance from the center coordinates decreases. The method according to claim 7,
The step of transmitting the converted image data by the converted image data generation unit
Separating the input image data into image data for each color;
Analyzing the image data for each color and extracting the edge region;
And setting the high gradation area from the image data for each color, and varying the gradation values of the remaining areas included in the image data for each color. The method according to claim 6,
The timing controller
The memory in which the average accumulated grayscale data which is the accumulated grayscale data for each pixel and the deterioration duration are updated every frame;
A lookup table to which the gain values are mapped corresponding to the average cumulative grayscale data and the deterioration durations;
And a deterioration compensator configured to set the gain value for each pixel by referring to the look-up table and the memory, and add and output the gain value to the converted image data input to each pixel. Method of driving the display device. The method according to claim 9,
The gain values are
And compensating gradation data information for compensating for deterioration of the OLED generated by continuously applying the average cumulative gradation data for the deterioration duration for the OLED of each pixel.

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