JP2006038976A - Image correction method for image display device - Google Patents

Abstract

An image display apparatus that suppresses the occurrence of color unevenness in all gradations that can be taken by input data.
An operation of supplying input data of a predetermined gradation level to an image display device to display an image and obtaining the output data by measuring the image is performed by changing the gradation level of the input data. Step 1 for measuring input / output characteristic data according to the above, and correction data for correcting an input signal for image display, all correction data for bringing the input / output characteristic data close to predetermined reference input / output characteristic data And step 2 for determining the gradation level.
[Selection] Figure 2

Description

  The present invention relates to a method for correcting an image displayed on an image display device such as a plasma display.

  An image displayed on an image display device such as a plasma display is desired to be a uniform image without color unevenness. However, in actuality, for example, in the case of a plasma display, an image display device is caused by various variations such as electrical characteristics of a drive circuit and non-uniformity of physical characteristics of the plasma display due to a defect in a manufacturing process. Color unevenness may occur in the image displayed on the screen.

Conventionally, in order to correct this color unevenness, it has been performed to correct image data of pixels in which color unevenness occurs in an image display device. For example, Patent Document 1 measures the distribution of color unevenness in an achromatic image at a certain halftone and a uniform image (referred to as a whole surface uniform display image) in which all pixels have the same color, and all of the image display devices are measured. Data for correcting the luminance levels of red (R), green (G), and blue (B) in the pixel to be the same is determined based on input / output characteristics of the image display device. A method is disclosed.
JP 2001-209358 A

  Here, in the above-described conventional method, color unevenness correction is performed for an achromatic entire surface uniform display image at a certain intermediate gradation of the input data level, and correction for other gradations is not performed. However, for example, in the case of a plasma display, even if a uniform image without color unevenness is displayed at a certain intermediate gradation due to a difference in light emission characteristics of RGB phosphors, color unevenness at other gradations is displayed. May occur. Therefore, even if an image having no color unevenness in a certain intermediate gradation can be realized, it cannot be guaranteed that the color unevenness of the plasma display is sufficiently corrected. For this reason, it is necessary to obtain correction data for color unevenness in all gradations that can be obtained by the value of input data. Further, in the above-described conventional method, in determining the color unevenness correction data, the correction data is obtained by approximating the nonlinear input / output characteristic data as being linear, which may cause an error. Yes.

  The present invention has been made to solve such a problem, and an object of the present invention is to obtain an image display device that suppresses occurrence of color unevenness in all gradations that can be taken by input data.

  In order to achieve the above object, the present invention provides an operation of supplying input data of a predetermined gradation level to an image display device to display an image and measuring the image to obtain output data. A step of measuring input / output characteristic data by changing a gradation level, and correction data for correcting an input signal for image display, wherein the input / output characteristic data is added to predetermined reference input / output characteristic data; And an image correction method for an image display device, comprising: determining correction data to be approximated for all gradation levels.

  According to the present invention, it is possible to obtain an image display device that suppresses occurrence of color unevenness in all gradations that can be taken by input data.

  According to a first aspect of the present invention, an operation of supplying input data of a predetermined gradation level to an image display device to display an image and measuring the image to obtain output data is performed on the input data. A step of measuring input / output characteristic data by changing a gradation level, and correction data for correcting an input signal for image display, wherein the input / output characteristic data is added to predetermined reference input / output characteristic data; And an image correction method for an image display device, comprising: determining correction data to be approximated for all gradation levels.

  According to a second aspect of the present invention, in the first aspect of the invention, the correction data in each pixel of the image display device is determined using input / output characteristic data of each pixel. .

  According to a third aspect of the present invention, in the first aspect of the present invention, the entire pixel region of the image display device is divided into a plurality of pixel regions, and the input / output characteristic data of each pixel in each pixel region. The average input / output characteristic data is obtained by calculating the average value of the above, and the correction data determined using the average input / output characteristic data is used as the correction data for all the pixels in each pixel region.

  According to a fourth aspect of the present invention, in the first aspect of the invention, the gradation level of the input data is divided into a plurality of gradation areas, and correction data at all gradation levels in each gradation area is obtained. The correction data determined at the intermediate gradation level in the gradation area is used.

  According to a fifth aspect of the present invention, in the invention according to the fourth aspect, when the gradation level of the input data is divided into a plurality of gradation areas, the input data is changed according to a change rate of the input / output characteristic data. The range of the gradation area is determined.

  According to a sixth aspect of the invention, in the invention of the fourth aspect, when the gradation level of the input data is divided into a plurality of gradation areas, the luminance is obtained using the input / output characteristic data, The number of gradation areas is determined according to a luminance value.

  An embodiment of the present invention will be described below with reference to the drawings. Here, in the following description, the case of a plasma display panel will be described as an example.

(Embodiment 1)
First, the structure of the plasma display panel will be described with reference to FIG. 11 which is a perspective view showing the main part. As shown in FIG. 11, a plurality of display electrode pairs 2 made of scan electrodes and sustain electrodes are formed on a glass front substrate 1, and a dielectric layer 3 made of dielectric glass so as to cover the display electrode pairs 2. The protective layer 4 made of magnesium oxide (MgO) is formed on the dielectric layer 3.

  On the other hand, a plurality of address electrodes 6 are formed on the glass back substrate 5, a dielectric layer 7 is formed so as to cover the address electrodes 6, and a plurality of parallel to the address electrodes 6 are formed on the dielectric layer 7. A partition wall 8 is formed, and a phosphor layer 9 that emits light of each color of R, G, and B is formed between adjacent partition walls 8. The address electrode 6 is located between the adjacent partition walls 8.

  The front substrate 1 and the rear substrate 5 which are a pair of substrates are arranged to face each other so that the display electrode pair 2 and the address electrode 6 are orthogonal to each other, and the peripheral portions of these substrates are sealed using a sealing member (not shown). Sealed. A discharge gas made of neon and xenon is sealed in a discharge space formed between the front substrate 1 and the back substrate 5, and a discharge cell is formed at a three-dimensional intersection between the display electrode pair 2 and the address electrode 6. . This discharge cell is a unit light-emitting region for displaying an image, and one pixel is formed by three adjacent discharge cells on which phosphor layers 9 emitting light in R, G, and B colors are formed.

  In this plasma display panel, an image is displayed by generating a discharge in each discharge cell. That is, an initialization signal voltage is applied to the scan electrode and the sustain electrode to initialize the state of each discharge cell. Next, a discharge voltage to be displayed is selected by applying a scan voltage to the scan electrode and applying a write voltage to the address electrode 6 based on the image data, and then a sustain voltage (sustain voltage) is alternately applied to the scan electrode and the sustain electrode. By applying a pulse, a sustain discharge is caused in the selected discharge cell. Thereafter, an erasing voltage is applied to the sustain electrode to stop the sustain discharge. As a result, ultraviolet rays are generated in the discharge cells in which the sustain discharge has occurred, and visible light of each color is emitted from the phosphor layer 9 excited by the ultraviolet rays, and image display is performed.

  FIG. 1 is a block diagram showing a schematic configuration of an entire system for determining color unevenness correction data according to an embodiment of the present invention. This system includes an image display device 10, an uneven color correction data calculation device 20, a display imaging camera 30, and a control device 40.

  The image display device 10 is a lighting device for the plasma display panel 11. The plasma display panel 11 is supplied with an initialization signal voltage, a write voltage, a sustain voltage, an erase voltage, and the like necessary for lighting, and is lit. Then, an image represented by the signal supplied by the signal supply device 12 is displayed on the plasma display panel 11. The image correction circuit 13 corrects a signal supplied from the outside of the image correction circuit 13 based on the correction data obtained by the color unevenness correction data calculation device 20, and includes a memory for storing the correction data. ing. When color unevenness correction is not performed, the function of the image correction circuit 13 can be stopped. The gradation changing circuit 15 is a circuit that issues a command for sequentially displaying on the plasma display panel 11 an achromatic entire surface uniform display image from 0 gradation to 255 gradation in the process of obtaining input / output characteristics. Here, in general, the number of gradations of image luminance (intensity) displayed on the plasma display panel 11 is determined by the number of sustain pulses supplied from the driving circuit 14, and the number of sustain pulses is 0 to 255 gradations. The signal level can be realized. The control device 16 is a device for controlling the image display device 10 and is controlled by a control device 40 which is a device for controlling the entire system for determining color unevenness correction data.

  In addition, the plasma display panel 11, the image correction circuit 13, and the drive circuit 14 can operate independently as the plasma display television 50, and can display an image according to an external signal.

  The color unevenness correction data calculation device 20 is a device that obtains color unevenness correction data based on an image captured by the camera 30, and includes a color unevenness correction value calculation circuit 21, an input / output characteristic measurement circuit 22, and a memory 23. It is configured. The color unevenness correction value calculation circuit 21 is a circuit for obtaining color unevenness correction data based on the input / output characteristics measured by the input / output characteristic measurement circuit 22, and the obtained color unevenness correction data is the image correction circuit described above. 13 is sent to the memory included in the memory. The memory 23 stores the input / output characteristics measured by the input / output characteristic measuring circuit 22.

  The camera 30 is an imaging means for capturing an image displayed on the plasma display panel 11, and the image captured by the camera 30 is corrected for color unevenness for measurement of input / output characteristics and calculation of color unevenness correction data. The data is supplied to the data calculation device 20. Here, it is desirable that the camera 30 has a resolution with which the pixel of the camera can measure at least one pixel number with respect to one pixel of the plasma display panel 11.

  The system for determining color unevenness correction data having the above-described configuration operates in the order of the steps in the flowchart shown in FIG. 2, and the input / output characteristics of all the pixels of the image display device 10 are arbitrarily input. The correction is made so as to approach the output characteristic N. The input / output characteristic N can be arbitrarily selected by the user, and the white balance can be adjusted by selecting the input / output characteristic N. Hereinafter, this input / output characteristic N is referred to as color unevenness correction reference input / output characteristic data. As shown in FIG. 2, the system for determining color unevenness correction data measures input / output characteristics by the camera 30 and the input / output characteristic measurement circuit 22 in step 1, and in the next step 2, based on the input / output characteristics. In step 3, the uneven color correction data is stored in the memory. Next, each of these steps will be described.

(1) Step 1: Measurement of input / output characteristics by a camera and an input / output characteristic measuring circuit The signal supply device 12 outputs a signal of level 0 gradation as input data to the R phosphor according to a command from the gradation changing circuit 15. Then, the plasma display panel 11 displays the entire R uniform display image, and the camera 30 captures the image. Then, output data of each pixel at that time is stored in the memory 23. The above operation is sequentially performed from 0 gradation to 255 gradation for the R entire uniform display image, thereby measuring input / output characteristics of all pixels of the R uniform display image and storing the result in the memory 23. . When the obtained input / output characteristic data is represented in a graph with the horizontal axis representing the input data and the vertical axis representing the output data, for example, the graph shown in FIG. 3 is obtained. The number of input / output characteristic data corresponding to the number of pixels is measured.

  Further, in the same manner as the method for measuring the input / output characteristics of each pixel in the R entire surface uniform display image, the input / output characteristics data of all pixels are also obtained in each of the G entire surface uniform display image and the B entire surface uniform display image. Measure and store the results in the memory 23.

  With the above operation, the input / output characteristics of the image display apparatus 10 can be measured.

(2) Step 2: Determination of color unevenness correction data based on input / output characteristics Color unevenness correction reference input / output characteristic data (for R) stored in the memory 23 in advance in the color unevenness correction value calculation circuit 21 Then, the input / output characteristic data of the entire R uniform display image obtained in step 1 is read from the memory 23. As an example, the R input / output characteristic data read at this time is indicated by a solid line a in FIG. 4, and the color unevenness correction reference input / output characteristic data is indicated by a broken line b in FIG. Then, the color unevenness correction value calculation circuit 21 obtains color unevenness correction data necessary for the input / output characteristic data of the entire R uniform display image to approach the color unevenness correction reference input / output characteristic data (for R). This is determined by comparing the R input / output characteristic data with the color unevenness correction reference input / output characteristic data (for R).

  Details of the determination of color unevenness correction data in the first embodiment will be described below. Here, in determining actual color unevenness correction data, all pixels of each color of R, G, and B are sequentially performed from 0 gradation to 255 gradation, but here, a certain pixel of the entire R uniform display image A method of determining color unevenness correction data in a certain intermediate gradation (RI1) of P1 will be described with reference to FIG.

First, the value (RO1) of color unevenness correction reference input / output characteristic data when the input data is RI1 is obtained. Next, an input data value (S (RO1)) is obtained such that the output data value in the R input / output characteristic data is RO1. Next, from RI1 and S (RO1), the value of color unevenness correction data (C (RI1)) in gradation RI1 is
C (RI1) = S (RO1) -RI1
It is calculated by the following formula. This C (RI1) is R color unevenness correction data in the pixel P1, and when actually correcting the color unevenness of the plasma display panel 11 using C (RI1), C (RI1) is added to the input signal. Thus, a new input signal is obtained. Then, by obtaining C (RI1) by changing the value of RI1, it is possible to determine color unevenness correction data in each gradation from 0 gradation to 255 gradation.

  Although a certain pixel P1 has been described here, other pixels in the entire R uniform display image are also calculated from the input / output characteristic data of each pixel and the reference input / output characteristic data for color unevenness correction by the above calculation method. Obtain uneven color correction data. Thereby, color unevenness correction data in all gradations from 0 gradation to 255 gradations of the input data is determined for the R entire surface uniform display image.

  As described above, color unevenness correction data for all R pixels and all gradations can be obtained. For G and B, by using the same method as R, color unevenness correction data for all the R, G, and B pixels and all the gradations of the image display device 10 can be obtained.

(3) Step 3: Storage of Color Unevenness Correction Data in Memory The color unevenness correction data obtained in step 2 as described above is stored in a memory provided in the image correction circuit 13. When a signal is input to the plasma display television 50, the input signal is corrected based on the uneven color correction data stored in the image correction circuit 13. That is, the color unevenness correction data is added to the input signal, and the signal is supplied to the plasma display panel 11. By storing the color unevenness correction data in the image correction circuit 13, the plasma display television 50 can correct the color unevenness for all external signals.

  As described above, the uneven color correction data can be stored in the plasma display television 50 by performing the steps 1 to 3.

  Here, if all the R, G, and B color unevenness correction reference input / output characteristic data are the same, the output characteristics of R = G = B are obtained for all pixels and all gradations of the plasma display panel 11. Although it is possible to obtain an entire uniform display image having an arbitrary whiteness, it is possible to adjust the white balance by selecting the reference input / output characteristic data for correcting R, G, and B color unevenness. . For example, if color unevenness correction reference input / output characteristic data is selected such that the output value of R is larger than G and B, the whiteness of the plasma display panel 11 can be moved in the red direction.

  As described above, according to the first embodiment, the color unevenness can be corrected, and the color unevenness of the image display apparatus 10 can be reduced. Further, the image display device 10 can be adjusted to an arbitrary whiteness level by a method for selecting color unevenness correction reference input / output characteristic data.

(Embodiment 2)
The schematic configuration of the entire system for determining uneven color correction data in the second embodiment of the present invention is the same as that in FIG. 1 described in the first embodiment, and the operation flow diagram of the system is the same as that in FIG. The second embodiment is different from the first embodiment in a method for determining color unevenness correction data in step 2 of the flowchart shown in FIG. Each step will be described below.

  First, in step 1, the input / output characteristics of the image display apparatus 10 are measured in the same manner as in step 1 in the first embodiment. When the input / output characteristic data obtained here is represented in a graph with the horizontal axis representing input data and the vertical axis representing output data, a graph such as that shown in FIG. 3 can be obtained.

  In the next step 2, the color unevenness correction value calculation circuit 21 stores the color unevenness correction reference input / output characteristic data (for R) stored in the memory 23 in advance and the entire surface of R obtained in step 1 above. Reads input / output characteristic data of uniform display image. At this time, both the color unevenness correction reference input / output characteristic data and the input / output characteristic data of the entire R uniform display image have information on all the pixels of the plasma display panel 11. For example, as shown in FIG. 5, the color unevenness correction value calculation circuit 21 divides the area of all the pixels of the plasma display panel 11 into a plurality of arbitrary pixel areas (a certain pixel area P2 is represented by diagonal lines). The average input / output characteristic data is obtained by calculating the average value of the input / output characteristic data in each divided pixel area. As an example, the average input / output characteristic data in a certain pixel region P2 is indicated by a solid line a in FIG. 6, and the color unevenness correction reference input / output characteristic data is indicated by a broken line b in FIG.

  Next, the color unevenness correction value calculation circuit 21 causes the average input / output characteristic data in each pixel area of the entire R uniform display image to approach the color unevenness correction reference input / output characteristic data (for R). Necessary color unevenness correction data is determined by comparing R average input / output characteristic data and color unevenness correction reference input / output characteristic data (for R).

  Details of the determination of the color unevenness correction data will be described below. Here, in determining actual color unevenness correction data, all pixels of each color of R, G, and B are sequentially performed from 0 gradation to 255 gradation, but here, a certain pixel of the entire R uniform display image A method for determining color unevenness correction data in a certain intermediate gradation (RI2) in the region P2 will be described with reference to FIG.

First, the value (RO2) of the reference input / output characteristic data for color unevenness correction when the input data is RI2 is obtained. Next, an input data value (S (RO2)) is obtained such that the output data value in the R average input / output characteristic data is RO2. Next, from RI2 and S (RO2), as the value of color unevenness correction data (C (RI2)) in gradation RI2,
C (RI2) = S (RO2) -RI2
It is calculated by the following formula. This C (RI2) is R color unevenness correction data for all the pixels in the pixel region P2, and when actually correcting the color unevenness of the plasma display panel 11 using C (RI2), C (RI2) (RI2) is added to obtain a new input signal. Then, by obtaining C (RI2) by changing the value of RI2, color unevenness correction data in each gradation from the 0th gradation to the 255th gradation can be determined.

  Although the pixel area P2 has been described here, the average value of the input / output characteristic data in each pixel area and the reference input / output characteristic data for correcting color unevenness are also obtained for the other pixel areas in the entire R uniform display image. From the above, color unevenness correction data is obtained by the above calculation method. Thereby, color unevenness correction data in all gradations from 0 gradation to 255 gradations of the input data is determined for the R entire surface uniform display image.

  As described above, color unevenness correction data in all R pixel regions and all gradations can be obtained. By using the same method as R for G and B, it is possible to obtain color unevenness correction data for all pixel regions and all gradations of R, G, and B of the image display device 10.

  In the next step 3, the color unevenness correction data obtained in step 2 is stored in a memory provided in the image correction circuit 13. When a signal is input to the plasma display television 50, the input signal is corrected based on the uneven color correction data stored in the image correction circuit 13. That is, the color unevenness correction data is added to the input signal, and the signal is supplied to the plasma display panel 11. By storing the color unevenness correction data in the image correction circuit 13, the plasma display television 50 can correct the color unevenness for all external signals.

  As described above, the uneven color correction data can be stored in the plasma display television 50 by performing the steps 1 to 3.

  Here, if all the R, G, and B color unevenness correction reference input / output characteristic data are the same, the output characteristics of R = G = B are obtained for all pixels and all gradations of the plasma display panel 11. Although it is possible to obtain an entire uniform display image having an arbitrary whiteness, it is possible to adjust the white balance by selecting the reference input / output characteristic data for correcting R, G, and B color unevenness. . For example, if color irregularity correction reference input / output characteristic data is selected such that the output value of R is larger than G and B, the whiteness of the plasma display panel can be moved in the red direction.

  As described above, according to the second embodiment, color unevenness can be corrected, and color unevenness of the image display apparatus 10 can be reduced. Compared with Embodiment 1, this method can reduce the processing time because the number of pixels to be calculated is reduced. Further, the image display device 10 can be adjusted to an arbitrary whiteness level by a method for selecting color unevenness correction reference input / output characteristic data.

(Embodiment 3)
The schematic configuration of the entire system for determining uneven color correction data in the third embodiment of the present invention is the same as that in FIG. 1 described in the first embodiment, and the operation flow diagram of the system is the same as that in FIG. The third embodiment is different from the first embodiment in the color unevenness correction data determination method in step 2 of the flowchart shown in FIG. Each step will be described below.

  First, in step 1, the input / output characteristics of the image display apparatus 10 are measured in the same manner as in step 1 in the first embodiment. When the input / output characteristic data obtained here is represented in a graph with the horizontal axis representing input data and the vertical axis representing output data, a graph such as that shown in FIG. 3 can be obtained.

  In the next step 2, the color unevenness correction value calculation circuit 21 stores the color unevenness correction reference input / output characteristic data (for R) stored in the memory 23 in advance and the entire surface of R obtained in step 1 above. Reads input / output characteristic data of uniform display image. Here, the color unevenness correction value calculation circuit 21 obtains, for example, the rate of change (slope) in each gradation of the input / output characteristic data shown in FIG. When the slope obtained at this time is represented on the graph with the vertical axis and the input data as the horizontal axis, the graph shown in FIG. 7 is obtained. In FIG. 7, the solid line a is input / output characteristic data, and the solid line b is the slope of each gradation of the input / output characteristic data.

  The color unevenness correction value calculation circuit 21 divides input data into a plurality of gradation areas, obtains an average value in each gradation area with respect to the slope shown in FIG. 7, and rounds the average value to an integer value. Thus, as shown in FIG. 8, the average value of the gradient in each gradation region is obtained. The average value of the slope is 0 in the areas A4 and A8, the average value of the slope is 1 in the areas A3 and A5, and the average value of the slope is 2 in the areas A1, A2, A6, and A7. Note that the solid lines a and b in FIG. 8 are the same as the solid lines a and b in FIG. 7, respectively. In this example, the input data is divided into eight gradation areas, but the division range of the input data can be arbitrarily set. If the average value of the gradient obtained at this time is 0 or 1, color unevenness correction data is obtained for the range of the gradation region by the method described below. If the average value of the gradient is an integer n of 2 or more, the gradation area is divided into n pieces, and the color unevenness correction data is obtained by the method described below in each of the divided gradation areas. Ask. Here, this division method can be arbitrarily set such that no more than 2 is divided.

  Next, the color unevenness correction value calculation circuit 21 obtains color unevenness correction data necessary for the input / output characteristic data of the entire R uniform display image to approach the color unevenness correction reference input / output characteristic data (for R). , R input / output characteristic data and color unevenness correction reference input / output characteristic data (for R) are compared.

  Details of the determination of the color unevenness correction data will be described below. Here, the actual color unevenness correction data is determined for all the gradation regions for all the pixels of R, G, and B, but here, for a certain pixel P3 of the entire R uniform display image, A method of determining color unevenness correction data in a certain gradation area RIA3 will be described with reference to FIG. In FIG. 9, a solid line a is input / output characteristic data, which is the same as that indicated by the solid line a in FIG. A broken line b is color unevenness correction reference input / output characteristic data (for R).

First, the value (RO3) of the reference input / output characteristic data for color unevenness correction when the input data is RI3 is obtained. Here, RI3 is an intermediate value of a certain gradation area RIA3, and the gradation area RIA3 in FIG. 9 corresponds to the area A5 in FIG. Next, an input data value (S (RO3)) is determined such that the output data value in the R input / output characteristic data is RO3. Next, from RI3 and S (RO3), as the value of color unevenness correction data (C (RI3)) of gradation RI3,
C (RI3) = S (RO3) -RI3
It is calculated by the following formula. This C (RI3) is R correction data of the pixel P3 in all gradations in the gradation area (RIA3), and when actually correcting the color unevenness of the plasma display panel 11 using C (RI3). , C (RI3) is added to the input signal to obtain a new input signal. Then, by obtaining C (RI3) for each gradation region, it is possible to determine color unevenness correction data in each gradation from 0 gradation to 255 gradation.

  Hereinafter, for the other pixels in the entire R uniform display image, the color unevenness correction data is obtained by the above calculation method from the input / output characteristic data of each pixel and the color unevenness correction reference input / output characteristic data. Thereby, color unevenness correction data in all gradations from 0 gradation to 255 gradations of the input data is determined for the R entire surface uniform display image.

  As described above, color unevenness correction data for all R pixels and all gradations can be obtained. For G and B, by using the same method as R, color unevenness correction data for all the R, G, and B pixels and all the gradations of the image display device 10 can be obtained.

  In the next step 3, the color unevenness correction data obtained in step 2 is stored in a memory provided in the image correction circuit 13. When a signal is input to the plasma display television 50, the input signal is corrected based on the uneven color correction data stored in the image correction circuit 13. That is, the color unevenness correction data is added to the input signal, and the signal is supplied to the plasma display panel 11. By storing the color unevenness correction data in the image correction circuit 13, the plasma display television 50 can correct the color unevenness for all external signals.

  As described above, the uneven color correction data can be stored in the plasma display television 50 by performing the steps 1 to 3.

  In the third embodiment, when the gradation level of the input data is divided into a plurality of gradation areas, the division method is determined according to the change rate of the input / output characteristic data. Here, since the range of the gradation area is narrowed when the rate of change of the input / output characteristic data is large, color unevenness correction is performed in more detail when the rate of change of the input / output characteristic data is large. Data can be obtained, and accurate color unevenness correction data can be obtained efficiently for all gradation regions. Further, if all the R, G, and B color unevenness correction reference input / output characteristic data are the same, an output characteristic of R = G = B is obtained for all pixels and all gradations of the plasma display panel 11. However, the entire uniform display image having arbitrary whiteness can be obtained and the white balance can be adjusted by selecting the reference input / output characteristic data for correcting R, G, and B color unevenness. For example, if color irregularity correction reference input / output characteristic data is selected such that the output value of R is larger than G and B, the whiteness of the plasma display panel can be moved in the red direction.

  As described above, according to the third embodiment, color unevenness can be corrected, and color unevenness of the image display device 10 can be reduced. Compared with the first embodiment, this method can reduce the processing time because the number of gradations of input data to be calculated is reduced. Further, the image display device 10 can be adjusted to an arbitrary whiteness level by a method for selecting color unevenness correction reference input / output characteristic data.

(Embodiment 4)
The schematic configuration of the entire system for determining color unevenness correction data in the fourth embodiment of the present invention is the same as that of FIG. 1 described in the first embodiment, and the operation flowchart of the system is the same as that of FIG. The fourth embodiment is different from the first embodiment in a method for determining color unevenness correction data in step 2 of the flowchart shown in FIG. Each step will be described below.

  First, in step 1, the input / output characteristics of the image display apparatus 10 are measured in the same manner as in step 1 in the first embodiment. When the input / output characteristic data obtained here is represented in a graph with the horizontal axis representing input data and the vertical axis representing output data, a graph such as that shown in FIG. 3 can be obtained.

In the next step 2, the color unevenness correction value calculation circuit 21 stores the color unevenness correction reference input / output characteristic data (for R) stored in the memory 23 in advance and the entire surface of R obtained in step 1 above. Reads input / output characteristic data of uniform display image. Then, the color unevenness correction value calculation circuit 21 outputs an R whole surface uniform display image, a G whole surface uniform display image, and a B whole surface uniform display image of 255 gradations (highest gradation) stored in the memory 23. The brightness is calculated using the data. The color unevenness correction value calculation circuit 21 divides input data of input / output characteristic data into a plurality of gradation regions based on the obtained luminance value. For example, the 10 gray scale region if the luminance is 100 cd / m ² or less obtained, 100~200cd / m ² if the 20 gradation region, 200~300cd / m ² if 30 floors Divide into key areas. Taking the case where the luminance of the panel is 90 cd / m ² as an example, the input data is divided into 10 gradation regions.

  Next, the color unevenness correction value calculation circuit 21 obtains color unevenness correction data necessary for the input / output characteristic data of the entire R uniform display image to approach the color unevenness correction reference input / output characteristic data (for R). , R input / output characteristic data and color unevenness correction reference input / output characteristic data (for R).

  Details of the determination of the color unevenness correction data will be described below. Here, the actual color unevenness correction data is determined for all gradation regions for all pixels of each of the R, G, and B colors. Here, for a certain pixel P4 of the entire R uniform display image, A method for determining correction data in a certain gradation area RIA4 will be described with reference to FIG. In FIG. 10, the input / output characteristic data of the entire R uniform display image is indicated by a solid line a, and the color unevenness correction reference input / output characteristic data (for R) is indicated by a broken line b.

The value (RO4) of the reference input / output characteristic data for color unevenness correction when the input data is RI4 is obtained. Here, RI4 is an intermediate value of the gradation area RIA4. Next, an input data value (S (RO4)) is obtained such that the output data value in the R input / output characteristic data is RO4. Next, from RI4 and S (RO4), as the value of color unevenness correction data (C (RI4)) in gradation RI4,
C (RI4) = S (RO4) -RI4
It is calculated by the following formula. This C (RI4) is R correction data of the pixel P4 in all the gradations in the gradation area RIA4. When actually correcting the color unevenness of the plasma display panel 11 using C (RI4), it is input. C (RI4) is added to the signal to obtain a new input signal. Further, by obtaining C (RI4) for other gradation areas, it is possible to determine color unevenness correction data in each gradation from 0 gradation to 255 gradation.

  Hereinafter, for the other pixels in the entire R uniform display image, the color unevenness correction data is obtained by the above calculation method from the input / output characteristic data of each pixel and the color unevenness correction reference input / output characteristic data. Thereby, color unevenness correction data in all gradations from 0 gradation to 255 gradations of the input data is determined for the R entire surface uniform display image.

  As described above, color unevenness correction data for all R pixels and all gradations can be obtained. For G and B, by using the same method as R, color unevenness correction data for all the R, G, and B pixels and all the gradations of the image display device 10 can be obtained.

  In the next step 3, the color unevenness correction data obtained in step 2 is stored in a memory provided in the image correction circuit 13. When a signal is input to the plasma display television 50, the input signal is corrected based on the uneven color correction data stored in the image correction circuit 13. That is, the color unevenness correction data is added to the input signal, and the signal is supplied to the plasma display panel 11. By storing the color unevenness correction data in the image correction circuit 13, the plasma display television 50 can correct the color unevenness for all external signals.

  As described above, the uneven color correction data can be stored in the plasma display television 50 by performing the steps 1 to 3.

  Here, if all the R, G, and B color unevenness correction reference input / output characteristic data are the same, the output characteristics of R = G = B are obtained for all pixels and all gradations of the plasma display panel 11. Although it is possible to obtain an entire uniform display image having an arbitrary whiteness by selecting the reference input / output characteristic data for correcting R, G, and B color unevenness, white balance can be adjusted. . For example, if color irregularity correction reference input / output characteristic data is selected such that the output value of R is larger than G and B, the whiteness of the plasma display panel can be moved in the red direction.

  As described above, according to the fourth embodiment, color unevenness can be corrected, and color unevenness of the image display apparatus 10 can be reduced. Compared with the first embodiment, this method can reduce the processing time because the number of gradations of input data to be calculated is reduced. In addition, the image display device can be adjusted to an arbitrary whiteness level by a method of selecting color unevenness correction reference input / output characteristic data.

  In each of the first to fourth embodiments, the image correction method has been described by taking the image display device using the plasma display panel 11 as an example. However, other image display devices such as a liquid crystal display and a projector are described. The present invention can also be applied to. For example, the second embodiment and the third embodiment can be combined, or the second embodiment and the fourth embodiment can be combined.

  Further, in each of the above-described embodiments, the case of correcting color unevenness in an image display device that displays a color image has been described, but when correcting unevenness in luminance in an image display device that displays a monochrome image, The present invention can be applied.

  As described above, according to the present invention, it is possible to obtain an image display device that suppresses occurrence of color unevenness in all gradations that can be taken by input data, which is useful when correcting color unevenness.

The block diagram which shows schematic structure of the whole system for color nonuniformity correction data determination in one embodiment of this invention Flow chart showing operation steps of the system The figure which shows the input-output characteristic data of the whole surface uniform display image of R The figure explaining the determination method of the color nonuniformity correction data in Embodiment 1 of this invention The figure which shows the example which divides | segments the area | region of all the pixels of a plasma display panel into several pixel area | regions The figure explaining the determination method of the color nonuniformity correction data in Embodiment 2 of this invention The figure which shows the ratio of the change of the input-output characteristic in Embodiment 3 of this invention The figure which shows the average value of the ratio of the change of an input-output characteristic in FIG. The figure explaining the determination method of the uneven color correction data in Embodiment 3 of this invention The figure explaining the determination method of the uneven color correction data in Embodiment 4 of this invention The perspective view which shows the principal part of a plasma display panel

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Image display apparatus 11 Plasma display panel 12 Signal supply apparatus 13 Image correction circuit 14 Drive circuit 15 Gradation change circuit 16 Control apparatus 20 Color unevenness correction data calculation apparatus 21 Color unevenness correction value calculation circuit 22 Input / output characteristic measurement circuit 23 memory 30 camera 40 control device

Claims (6)

Input / output characteristics by supplying the input data of a predetermined gradation level to the image display device, displaying the image, and obtaining the output data by measuring the image by changing the gradation level of the input data. Correction data for correcting the input signal for image display and the step of measuring data for correcting the input / output characteristic data to predetermined reference input / output characteristic data for all gradation levels And an image correction method for an image display device. 2. The image correction method for an image display device according to claim 1, wherein the correction data in each pixel of the image display device is determined using input / output characteristic data of each pixel. Dividing the entire pixel area of the image display device into a plurality of pixel areas and calculating the average input / output characteristic data of each pixel in each pixel area to obtain the average input / output characteristic data. The image correction method for an image display device according to claim 1, wherein the correction data determined using the characteristic data is used as correction data for all the pixels in each pixel region. The gradation level of the input data is divided into a plurality of gradation areas, and the correction data determined at the intermediate gradation level in the gradation area is used as correction data for all gradation levels in each gradation area. The image correction method for an image display device according to claim 1. 5. The image according to claim 4, wherein when the gradation level of the input data is divided into a plurality of gradation areas, the range of the gradation area is determined in accordance with a change rate of the input / output characteristic data. Image correction method for display device. When the gradation level of the input data is divided into a plurality of gradation areas, luminance is obtained using input / output characteristic data, and the number of gradation areas is determined according to the luminance value. The image correction method of the image display apparatus of Claim 4.

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