KR102149480B1 - Method and apparatus for compensating a mura of display device - Google Patents

Abstract

The present invention relates to a method and apparatus for compensating spots in a display device, in which test data of the same gray scale is displayed on all pixels of a display panel, and a first camera in an on-focus state with a focus set on the screen of the display panel is used. Capturing an image displayed on the screen of the display panel, and when a first spot with a clear boundary is detected in an image captured by the first camera, generating first compensation values for removing the first spot ; First modulated data is generated by adding or subtracting the first compensation values to the test data, and the first modulated data is displayed on the display panel, and a focus is set in a defocused state in front of or behind the screen. 2 capturing an image displayed on the display panel using a camera; And generating second compensation values for removing the second spot when a second spot whose luminance gradually changes between two points of the screen captured by the second camera is detected.

Description

Method and apparatus for compensating spots in a display device TECHNICAL FIELD

The present invention relates to a method and apparatus for compensating for spots in a display device.

Flat panel displays include Electroluminescence Display (ELD) such as Liquid Crystal Display (LCD), Organic Light Emitting Diode Display (OLED Display), and Field Emission Display. Display, FED), Plasma Display Panel (PDP), Electrophoresis Display (EPD), etc.

The liquid crystal display device displays an image by modulating light incident from a backlight unit by controlling an electric field applied to a liquid crystal layer. Active matrix type liquid crystal display devices have the advantage of excellent image quality and low power consumption by driving liquid crystal cells using a thin film transistor (hereinafter referred to as "TFT"). As a result of this, it is rapidly developing with large size and high resolution. Such liquid crystal display devices are widely used in application fields such as portable computers such as notebook PCs, office automation devices, audio/video devices, and indoor/outdoor advertisement display devices.

The manufacturing process of the liquid crystal display device is a semiconductor process including a photolithography process to manufacture a TFT array substrate. The photolithography process includes a series of exposure, development, and etching processes.

Various types of stains may be found in the inspection process for inspecting the display state of the finished substrate due to non-uniformity in the exposure amount in the photolithography process. The spot can be measured based on a result of displaying data of the same gray scale on the display panel and measuring luminance on the screen of the display panel. These blobs look different in luminance or chroma compared to other normal pixels. The cause of the spots is a pixel with spots such as the overlapping area between the gate and drain of the TFT, the height of the spacer, the parasitic capacitance between the signal lines, and the parasitic capacitance between the signal lines and the pixel electrodes due to the difference in exposure amount in the photolithography process. This is due to the difference in position from other pixels on the normal display surface.

The stain can be improved by improving the process technology or through the repair process, but there are limitations. Recently, in order to compensate for the spot to be removed only by improving the process technology, a method of removing spots from the display image by adding or subtracting a preset compensation value to the data to be displayed on the pixels at the spot location is applied using a compensation circuit. Technology to reduce the reduction is being applied. However, the conventional blob compensation method using a compensation circuit sets a compensation value to compensate for a specific type of blob without performing accurate luminance calculation for each pixel in the blob measurement step, so blobs of various luminance characteristics and blobs of various types are automatically Couldn't compensate.

The present invention provides a method and apparatus for compensating spots in a display device capable of automatically compensating spots having various luminance characteristics and shapes.

The speckle compensation method according to an embodiment of the present invention displays test data of the same gradation on all pixels of a display panel, and displays the display using a first camera in an on-focus state with a focus set on the screen of the display panel. Capturing an image displayed on the screen of the panel; Generating first compensation values for removing the first spot when a first spot with a clear boundary is detected in an image captured by the first camera; First modulated data is generated by adding or subtracting the first compensation values to the test data, and the first modulated data is displayed on the display panel, and a focus is set in a defocused state in front of or behind the screen. 2 capturing an image displayed on the display panel using a camera; Generating second compensation values for removing the second spot when a second spot whose luminance gradually changes between two points of the screen captured by the second camera is detected; And modulating pixel data of an input image by using the first compensation values and the second compensation values and displaying on the display panel.
The spot compensation apparatus according to an embodiment of the present invention displays test data of the same gray scale on all pixels of a display panel, and displays the display using a first camera in an on-focus state with a focus set on the screen of the display panel. By taking an image displayed on the screen of the panel, a first spot with a clear boundary is detected in the image, and the image displayed on the screen is captured using a second camera in a defocused state with a focus set in front or behind the screen. A spot detection device for detecting a second spot in which luminance gradually changes between two points on the screen; A compensation circuit that modulates pixel data of an input image using preset first compensation values to remove the first spot and preset second compensation values to remove the second spot; And a driver configured to display data output from the compensation circuit on the display panel.
According to another exemplary embodiment of the present invention, the speckle compensation method displays test data of the same gradation on all pixels of a display panel, and an image displayed on the screen in an on-focus state that sets the focus of a camera on the screen of the display panel. Photographing an image; Generating first-order compensation values for removing the first spot when a first spot with a clear boundary is detected in an image captured by the camera; Firstly modulated data is generated by adding or subtracting the first compensation values to the test data, and the first modulated data is displayed on the display panel, and the focus of the camera is changed to the front or back of the screen, Capturing an image displayed on the screen; Generating secondary compensation values for removing the second spot when a second spot whose brightness gradually changes between two points of the screen captured by the camera is detected; And modulating pixel data of an input image by using the first compensation values and the second compensation values and displaying on the display panel.
The spot compensation apparatus according to another embodiment of the present invention displays test data of the same gradation to all pixels of a display panel, and captures an image displayed on the screen of the display panel by focusing a camera on the screen of the display panel. Thus, a first spot with a clear boundary is detected in the image, and the image displayed on the screen is captured by changing the focus of the camera to the front or back of the screen, and a second spot whose luminance gradually changes between the two points of the screen is A spot detection device to detect; A compensation circuit that modulates pixel data of an input image using preset first compensation values to remove the first spot and preset second compensation values to remove the second spot; And a driving unit configured to display data output from the compensation circuit on pixels of the display panel.

The present invention accurately captures an image displayed on a display panel, removes a first spot with a clear boundary from the image as primary compensation values, and removes a second spot with progressively visible luminance in an image from which the first spot is removed. Eliminate it as the difference compensation values. As a result, the present invention can automatically compensate for unevenness in a display device having various luminance characteristics and shapes.

1 is a diagram showing a stain measurement method and a stain compensation principle.
2 and 3 are diagrams illustrating a method of compensating for spots.
4 is a diagram showing a spot compensation apparatus according to an embodiment of the present invention.
5 is a diagram showing an example of a first blob measured in a first blob compensation step and compensation values thereof.
6 is a diagram illustrating an example of a second blob measured in a second blob compensation step and compensation values thereof.
FIG. 7 is a diagram illustrating a stain compensation result when a first stain compensation step and a second stain compensation step are sequentially applied.
8 is a diagram showing a focal length between a camera lens and a screen in an on-focus and defocus state.
9 is a diagram illustrating a gray scale section in which a compensation value generated by an interpolation method is calculated from a gamma characteristic curve.
10 is a diagram showing an interpolation method.
11 and 12 are block diagrams illustrating a display device according to an exemplary embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numbers throughout the specification mean substantially the same elements. In the following description, when it is determined that detailed descriptions of known functions or configurations related to the present invention may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted. The component names used in the following description may be selected in consideration of the ease of writing the specification, and may be different from the names of parts of the actual product.

The display device of the present invention is a liquid crystal display (LCD), a field emission display (FED), an organic light emitting diode display (OLED Display), a plasma display panel (PDP), an electrophoresis display (Electrophoresis Display, EPD), etc. It is also applicable to flat panel display devices.

1 to 3, in the spot detection step (S1), data of the same gradation is written to all pixels of a display panel, the luminance at that time is captured with a camera, and then an image of the camera is analyzed. To measure the luminance of the pixels. In the spot detection step (S1), the image captured by the camera is analyzed, the difference in luminance of the display panel compared to the center of the screen is measured for each pixel, and the luminance characteristic and shape of the spot are determined based on the result.

In step S2 of generating the spot compensation value, a compensation value having an inverse relationship with the luminance distribution characteristic is generated. The compensation value can be expressed as in Equation 1. The spot detection step S1 and the spot compensation value generation step S2 are repeated several times while changing the gray level.

Here, C is the compensation value of the n-th pixel (n is a positive integer). L _pn is the luminance of the n-th pixel, and L _pc is the luminance of the center pixel (reference pixel) of the screen. The gain _p is the gain reflecting the gamma deviation for each pixel.

The spot detection step S1 and the spot compensation value generation step S2 are divided into a first spot compensation step S21 and a second spot compensation step S21. The first spot compensation step (S21) performs spot measurement (S101), compensation value derivation (S102), and compensation value application and confirmation step (S103) as shown in FIG. Create a compensation value to compensate. In the second spot compensation step (S22), a spot measurement (S104), a compensation value derivation (S105), and a compensation value application and confirmation step (S106) are performed on the screen of the display panel to which the first spot compensation result is applied. Then, compensation values for compensating for a spot in which luminance gradually changes within a plane of a predetermined size are generated.

The compensation values are stored in a memory (ROM in Fig. 12) of the display device (S3). When the data of the input image is input to the display device, the compensation circuit of the display device modulates the data by adding or subtracting the compensation values to the data of the input image to compensate for spots on the screen (S4). As a result, a display image in which spots are not visible on the display panel can be displayed.

4 is a diagram showing a spot compensation apparatus according to an embodiment of the present invention. 5 is a diagram showing an example of a first blob measured in a first blob compensation step and compensation values thereof. 6 is a diagram illustrating an example of a second blob measured in a second blob compensation step and compensation values thereof. FIG. 7 is a diagram illustrating a stain compensation result when a first stain compensation step and a second stain compensation step are sequentially applied.

The spot compensation apparatus according to an embodiment of the present invention writes input data (test data) having the same gray scale to all pixels of a display panel and captures an image displayed on the screen of the display panel with a camera. Subsequently, when a first spot with a clear boundary is detected in an image captured by the camera, the spot compensation device generates first-order compensation values for removing the first spot. Subsequently, the spot compensation device adds or subtracts the primary compensation values to the input data to generate primary modulated data, writes the primary modulated data on the display panel, and captures the image displayed on the display panel with a camera. Check the reward effect.

The spot compensation device generates secondary compensation values for removing the second spot when a first spot with a clear boundary is removed from an image captured by a camera and a second spot whose luminance gradually changes between two points on the screen is detected. . Subsequently, the spot compensation device adds or subtracts the secondary compensation values to the primary modulated data to generate secondary modulated data, writes the secondary modulated data to the display panel, and captures the image displayed on the display panel with a camera. Check the secondary spot compensation effect.

The spot compensation device sets the compensation values to be stored in the memory of the display device by changing the gray level of the input data (test data) and repeating the above process to generate primary and secondary compensation values of different gray levels.

The camera may be divided into a first camera CAM1 for detecting a first spot and a second camera CAM2 for detecting a second spot as shown in FIG. 4. The first camera CAM1 may capture an image displayed on the display panel in an on-focus state focused on the screen of the display panel as shown in FIG. 8. The second camera CAM2 may capture an image displayed on the display panel in a defocus state focusing on the front or back of the screen of the display panel.

4 to 7, the spot compensation apparatus includes first and second cameras CAM1 and CAM2, a spot detection and compensation value generation unit 12, a compensation value supply unit 14, and a compensation status display unit 16. Includes.

The first camera CAM1 may be used as an image sensor for detecting spots with distinct boundaries such as dots and lines. The first camera CAM1 captures an image displayed on the display panel 18 by adjusting the focus in an on-focus state on the screen of the display panel 18. The second camera CAM2 is used as an image sensor for detecting a spot in which a boundary is not clearly visible and a difference in luminance gradually changes. The second camera CAM2 captures an image displayed on the display panel 18 by adjusting the focus in a defocus state on the screen of the display panel 18. The resolution of the first camera CAM1 may be higher than that of the first camera CAM2. The first and second cameras CAM1 and CAM2 may be mono cameras.

The spot detection and compensation value generation unit 12 receives the image captured by the first camera CAM1 in the first spot compensation step S21 and analyzes the image to determine the difference in luminance of each pixel compared to the center pixel of the screen. By measuring, as shown in FIG. 5, a spot with a clear boundary is detected. In addition, the spot detection and compensation value generator 12 generates primary compensation values C1, C2, and C3 for compensating the luminance of the spot. The primary compensation values (C1, C2, C3) are set to low values (C1, C2) for pixels with high luminance compared to the center pixel of the screen, while relatively high values for pixels with low luminance compared to the center pixel of the screen. It is set to the value (C3). The primary compensation values C1, C2, and C3 may be set in units of a column line or in units of a row line. For example, the first compensation value C1 may be set to the same value for all pixels located in the same column line. If the first compensation values are set in this way, the number of first compensation values can be reduced, and thus the memory capacity can be reduced.

The compensation value supply unit 14 inputs the primary compensation values C1, C2, and C3 to the driving unit of the display panel 18. The driving unit of the display panel 18 includes primary compensation values C1, C2, and C3. Is added or subtracted to the data of the input image, modulates the data, and writes in pixels of the display panel 18. When data for which the first compensation values C1, C2, and C3 are compensated are written to the display panel 18, a result of removing the border spots as shown in FIG. 7 may be obtained.

The spot detection and compensation value generation unit 12 receives the image captured by the second camera CAM2 in the second spot compensation step (S21), analyzes the image, and measures the luminance difference as shown in FIG. It detects spots that are not distinct and whose luminance difference gradually changes. In addition, the spot detection and compensation value generator 12 generates secondary compensation values (see FIG. 6) for compensating the luminance of the spot. Secondary compensation values may be generated in units of blocks B1 to Bn of a predetermined size as shown in FIG. 6. Secondary compensation values may include only compensation values of pixels located at four corners of a block for each block to reduce memory capacity. The remaining pixels in the block may be generated by interpolation in the compensation circuit.

The compensation value supply unit 14 supplies primary compensation values and secondary compensation image values input from the spot detection and compensation value generation unit 12 to a compensation circuit built in a driving unit of the display panel.

The compensation status display unit 16 displays an image captured through the cameras CAM1 and CAM2 on the monitor so that the test process operator can visually check the first and second spot compensation steps.

Two cameras are not required to detect the first and second spots. As shown in FIG. 8, focus and defocus from one camera may be adjusted by adjusting the lens position. Thus, it is possible to measure the primary and secondary spots using one camera.

In the first spot compensation step and the second spot compensation step, compensation values are generated while changing gray levels. Setting compensation values for all grayscales and all pixels increases the memory capacity. In order to reduce the memory capacity of the compensation circuit, compensation values are not generated in all gray levels, but the first and second compensation of some gray levels (G1, G2, G3, G4) divided at equal intervals in the gamma characteristic curve as shown in FIG. You can create values.

The primary compensation values and secondary compensation values are stored in a memory (ROM in FIG. 12) of the display device. The compensation circuit generates compensation values of other pixels and compensation values of different gray levels by using the first and second compensation values optimized for some pixels and some gray levels, and uses the compensation values as an input image. Remove the stain by adding or subtracting the data of

In the compensation circuit of the present invention, as shown in FIG. 7, after compensating for blobs with clear boundaries using first compensation values in the first blob compensation step, the remaining blobs are removed using the second compensation values in the second blob compensation step. do. The memory of the display device (Fig. 12, ROM) stores only the pixels at the sampled position on the screen and compensation values optimized for the sampled grayscale, and the compensation circuit calculates the compensation values of the remaining pixels and the remaining grayscales by an interpolation method. Accordingly, new compensation values are generated, and spots are compensated by modulating data of the input image using the compensation values and compensation values input from the memory.

The interpolation method estimates the value between the points using a linear approximation equation for a straight line connecting two separate points. As shown in FIG. 10, a linear approximation equation for a straight line passing through an arbitrary 3n point (x _i , f(x _i )), (x _{i +1} , f(x _{i +1} )) is the same as in Equation 2. g(x) is a linear approximation of any x value between (xi, xi1).

When power is applied to the display device, pixels sampled from an external memory (ROM in FIG. 12) and primary and secondary compensation values of the sampled gradation are input to the internal memory of the compensation circuit. The compensation circuit generates compensation values for the remaining pixels other than the sampled pixels and the other gray levels other than the sampled gray levels by an interpolation method and stores them in the internal memory. In the example of FIG. 6, if the compensation values of the sampled pixels corresponding to the positions of the vertices (P1, P2, P3, P4) of the block are known, the compensation value to be applied to the pixel of the P5 position between the pixels is calculated by the interpolation method. I can. If the compensation values of the gradations G1, G2, G3, and G4 sampled in FIG. 9 are known, the compensation values for the gradations between them may be calculated by an interpolation method. Compensation values calculated by the interpolation method are stored in the internal memory of the compensation circuit and added or subtracted to the data of the input image. Accordingly, the method of compensating for spots according to the present invention can significantly reduce a memory capacity, thereby significantly reducing hardware resources and circuit costs.

11 and 12 are block diagrams illustrating a display device according to an exemplary embodiment of the present invention.

11 and 12, the display device of the present invention includes a compensation circuit 200, a driver 110, and a display panel 100.

The display panel 100 includes a pixel array in which an input image is displayed. The pixel array includes data lines DL supplied with a data voltage, gate lines (or scan lines, GL) that are orthogonal to the data lines DL and supplied with a gate pulse (or scan pulse), and data lines. It includes pixels arranged in a matrix form defined by the intersection of the (DL) and the gate lines (GL). Each of the pixels may include one or more TFTs and capacitors.

When power is supplied to the display device, the first and second compensation values sampled from the ROM (Read Only Memory) 120 are input to the compensation circuit 200. The sampled first and second compensation values are compensation values generated with optimized values in some pixels and some gray levels based on the spot compensation method as shown in FIGS. 2 and 3. The compensation circuit 200 generates first and second compensation values at all gray levels for all pixels at the spot location by an interpolation method and stores them in an internal memory. The compensation circuit 200 adds or subtracts the first compensation values to the digital video data RGB of the input image, modulates the data RGB first, and removes spots with clear boundaries on the screen of the display panel 100. , Secondary compensation values are added to or subtracted from the first modulated data to secondly modulate the first modulated data to remove spots in which the difference in luminance gradually changes on the screen of the display panel 100.

The driver 110 writes the data RGB' modulated by the compensation circuit 200 to the pixels PIX of the display panel 100. The driver 110 includes a data driver 101, a gate driver (or scan driver) 102, and a timing controller 103. The compensation circuit 200 may be embedded in the timing controller 103.

The data driver 101 converts digital video data (RGB') of an input image input from the timing controller 103 into an analog gamma compensation voltage to generate a data voltage, and supplies the data voltage to the data lines DL. do. The gate driver 102 generates a gate pulse synchronous to the data voltage, and sequentially supplies the gate pulses to the gate lines GL while shifting the gate pulse.

The timing controller 103 receives digital video data (RGB) of an input image from a host system (not shown), and also receives vertical/horizontal synchronization signals (Vsync, Hsync), data enable signals (DE), and main clock (DCLK). It receives timing signals such as. The timing controller 103 transmits the digital video data RGB' compensated by the compensation circuit 200 to the data driver 101. In addition, the timing controller 103 generates timing control signals DDC and GDC for controlling the operation timing of the data driver 101 and the gate driver using the timing signals Vsync, Hsync, DE, and CLK.

The host system may be any one of a television system, a set-top box, a navigation system, a DVD player, a Blu-ray player, a personal computer (PC), a home theater system, and a phone system.

It will be appreciated by those skilled in the art through the above description that various changes and modifications can be made without departing from the technical idea of the present invention. Accordingly, the present invention should not be limited to the content described in the detailed description, but should be defined by the claims.

100: display panel 110: driving unit
200: compensation circuit

Claims (8)

Displaying test data of the same gradation on all pixels of the display panel, and capturing an image displayed on the screen of the display panel by using a first camera in an on-focus state with a focus set on the screen of the display panel;
Generating first compensation values for removing the first spot when a first spot with a clear boundary is detected in an image captured by the first camera;
First modulated data is generated by adding or subtracting the first compensation values to the test data, and the first modulated data is displayed on the display panel, and a focus is set in a defocused state in front of or behind the screen. 2 capturing an image displayed on the display panel using a camera;
Generating second compensation values for removing the second spot when a second spot whose luminance gradually changes between two points of the screen captured by the second camera is detected; And
And modulating pixel data of an input image using the first compensation values and the second compensation values, and displaying the pixel data on the display panel. The method of claim 1,
The first camera has a higher resolution than the second camera,
A method of compensating for spots in a display device in which each of the cameras is a mono camera. Test data of the same gradation is displayed on all pixels of the display panel, and an image displayed on the screen of the display panel is captured using a first camera in an on-focus state with a focus set on the screen of the display panel. A first spot with a clear boundary is detected, and an image displayed on the screen is captured using a second camera in a defocused state in which the focus is set in front or behind the screen, and the luminance gradually changes between two points of the screen. 2 spot detection device for detecting spots;
A compensation circuit that modulates pixel data of an input image using preset first compensation values to remove the first spot and preset second compensation values to remove the second spot; And
And a driver configured to display the data output from the compensation circuit on the display panel. The method of claim 3,
When the screen is divided into blocks of a predetermined size, the compensation values applied to the sampled pixels at the vertices of each of the blocks and the compensation corresponding to the sampled grayscale divided at equal intervals in the gamma characteristic curve Further comprising a first memory storing values,
The compensation circuit,
By using the compensation values input from the first memory, the compensation values to be applied to the remaining pixels other than the sampled pixels and the compensation values for gray levels other than the sampled gray level are generated by an interpolation method. A spot compensation apparatus for a display device, characterized in that storing it in a second memory. The method of claim 1,
Secondly modulated data is generated by adding or subtracting the second compensation values to the first modulated data, displaying the second modulated data on the display panel, and an image displayed on the display panel with at least one of the cameras Checking a stain removal state by taking an image; And
And generating the first and second compensation values of different gray levels based on the image captured by the cameras by changing the gray level of the test data. Displaying test data of the same gray scale on all pixels of the display panel, and capturing an image displayed on the screen in an on-focus state in which a focus of a camera is set on the screen of the display panel;
Generating first-order compensation values for removing the first spot when a first spot with a clear boundary is detected in an image captured by the camera;
Firstly modulated data is generated by adding or subtracting the first compensation values to the test data, and the first modulated data is displayed on the display panel, and the focus of the camera is changed to the front or back of the screen, Capturing an image displayed on the screen;
Generating secondary compensation values for removing the second spot when a second spot whose brightness gradually changes between two points of the screen captured by the camera is detected; And
And modulating pixel data of an input image using the first compensation values and the second compensation values, and displaying the pixel data on the display panel. The method of claim 6,
Secondly modulated data is generated by adding or subtracting the second compensation values to the first modulated data, displaying the second modulated data on the display panel, and an image displayed on the display panel with at least one of the cameras Checking a stain removal state by taking an image; And
And generating the first and second compensation values of different gray levels based on the image captured by the cameras by changing the gray level of the test data. Test data of the same gradation is displayed on all pixels of the display panel, and the image displayed on the display panel is captured by focusing the camera on the screen of the display panel to detect a first spot with a clear boundary in the image And a spot detection device configured to detect a second spot whose luminance gradually changes between two points of the screen by changing the focus of the camera to the front or back of the screen to capture an image displayed on the screen;
A compensation circuit that modulates pixel data of an input image using preset first compensation values to remove the first spot and preset second compensation values to remove the second spot; And
And a driver configured to display data output from the compensation circuit on pixels of the display panel.

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