WO2014017066A1 - Method of inspecting liquid crystal display panel, and liquid crystal display panel inspection device - Google Patents

Abstract

In order to suitably perform inspection of a liquid crystal display panel, first image data is obtained by picking up an image of a liquid crystal display panel to be inspected that is arranged between the camera and a backlight. Defects of the liquid crystal display panel are detected based on the first image data and prescribed second image data. The prescribed second image data is image data corresponding to the image data obtained when an image of a liquid crystal display panel that does not have a bright spot defect is arranged between the camera and a backlight is picked up. In this defect detection, defects of the liquid crystal display panel are detected by (S103) removing bright spot images contained in the second image data from the bright spot images contained in the first image data.

Description

Liquid crystal display panel inspection method and liquid crystal display panel inspection apparatus

The present invention relates to an inspection method and an inspection apparatus for inspecting the presence or absence of defects in a liquid crystal display panel.

In order to obtain a liquid crystal display panel capable of high-quality image display, various automatic inspection methods for display defects of the liquid crystal display panel have been proposed. For example, a method of inspecting a liquid crystal display panel for a display defect by illuminating the liquid crystal display panel with a backlight and photographing a defect of the liquid crystal display panel with an imaging device, for example, a camera using a CCD (charge-coupled device) Has been proposed.

More specifically, for example, a backlight arranged to face the back surface of the liquid crystal display panel is turned on, and the backlight light transmitted through the liquid crystal display panel is arranged to face the surface of the liquid crystal display panel. A defect of the liquid crystal display panel is inspected by photographing with the CCD camera (see, for example, Patent Document 1).

Japanese Patent Laid-Open No. 11-326123

However, in the inspection method of the liquid crystal display panel described in Patent Document 1, when foreign matter such as dust or dirt adheres to the surface of the backlight, not only the defect of the liquid crystal display panel itself but also the surface of the backlight. The attached foreign matter is also photographed by the CCD camera. Therefore, there is a problem that the liquid crystal display panel may not be properly inspected.

The present invention has been made in view of the above points, and an object of the present invention is to appropriately inspect a liquid crystal display panel even when foreign matters such as dust and dirt adhere to the surface of the backlight. There is to do.

The first invention is
A defect detection method for a liquid crystal display panel,
An imaging process for obtaining a first image data by arranging and photographing a liquid crystal display panel to be inspected between a camera and a backlight;
A defect detection step of detecting a defect of the liquid crystal display panel to be inspected based on the first image data and the predetermined second image data;
Including
The predetermined second image data is image data corresponding to image data when a liquid crystal display panel having no bright spot defect is photographed by arranging it between the camera and the backlight,
The defect detecting step detects a defect of the liquid crystal display panel to be inspected by removing the bright spot image included in the second image data from the bright spot image included in the first image data. And

As a result, even when foreign matter such as dust or dirt adheres to the surface of the backlight, it is possible to properly inspect the liquid crystal display panel for defects by removing the bright spot image due to the foreign matter on the backlight. .

The second invention is
An inspection method for a liquid crystal display panel according to a first invention,
The defect detection step includes, for each pixel in the first and second image data, normalized data obtained by dividing the difference between the luminance of each pixel and the average value of the luminance of a plurality of surrounding pixels by the average value. Based on this, a defect of the liquid crystal display panel to be inspected is detected.

The third invention is
An inspection method for a liquid crystal display panel according to a second invention,
The liquid crystal display panel to be inspected is provided with a color filter,
Each of the pixels and a plurality of surrounding pixels are pixels of the same color.

As a result, a difference in photographing sensitivity corresponding to the color of each pixel in the liquid crystal display panel is compensated, and therefore, appropriate inspection can be easily performed.

The fourth invention is:
An inspection method for a liquid crystal display panel according to any one of the second and third inventions,
Each of the pixels and a plurality of surrounding pixels are pixels separated by a predetermined distance.

Thus, by using the luminance of the pixels outside the range of the size of the foreign matter, the luminance can be normalized without being affected by the foreign matter.

The fifth invention is:
An inspection method for a liquid crystal display panel according to any one of the first to fourth inventions,
In the defect detection step, it is determined that the defect is not a defect when the number of pixels in a pixel group in which pixels having a luminance exceeding a predetermined threshold are continuous is equal to or less than a predetermined number.

The sixth invention is:
An inspection method for a liquid crystal display panel according to a fifth invention,
An inspection method for a liquid crystal display panel according to any one of the first to fifth inventions,
In the defect detection step, it is determined that the defect is not a defect when the total luminance of pixels in a pixel group in which pixels having a luminance exceeding a predetermined threshold are continuous is equal to or less than a predetermined value.

The seventh invention
An inspection method for a liquid crystal display panel according to any one of the fifth and sixth inventions,
The defect detection step includes
An average value of luminance of pixels in a pixel group in which pixels having luminance exceeding a predetermined threshold are continuous, is equal to or lower than a predetermined value; and
When the size of the region of the upper predetermined number of pixels in the pixel group is equal to or smaller than a predetermined size, it is determined that the pixel is not defective.

Thus, for example, even when so-called unevenness or charging of the liquid crystal display panel occurs, it can be determined that the liquid crystal display panel is defective due to foreign matter or the like, and erroneous detection can be prevented.

The eighth invention
An inspection method for a liquid crystal display panel according to any one of the fifth to seventh inventions,
The defect detection step includes
An average value of luminance of pixels in a pixel group in which pixels having luminance exceeding a predetermined threshold are continuous, is equal to or lower than a predetermined value; and
When the size of the upper predetermined number of luminance pixels in the pixel group exceeds a predetermined size, it is determined that the liquid crystal display panel is defective due to adhesion of foreign matter.

As a result, defects due to foreign matter adhering to the liquid crystal display panel are discriminated as bright spot defects for each display pixel of the liquid crystal display panel, and erroneous detection is prevented even when the liquid crystal display panel is charged. can do.

The ninth invention
An inspection method for a liquid crystal display panel according to any one of the fifth to seventh inventions,
The defect detection step includes
The number of pixels in a pixel group in which pixels with a luminance exceeding a predetermined threshold are continuous exceeds a predetermined number; and
The total luminance of the pixels in the pixel group exceeds a predetermined value, and
When the average value of the luminance of the pixels in the pixel group exceeds a predetermined value, it is determined that the display pixel in the liquid crystal display panel is defective.

Thereby, it is possible to determine a bright spot defect for each display pixel of the liquid crystal display panel as a defect due to adhesion of foreign matter to the liquid crystal display panel.

According to the present invention, the liquid crystal display panel is appropriately inspected even when foreign matter such as dust or dirt adheres to the surface of the backlight.

1 is a block diagram illustrating a schematic configuration of an inspection system including an inspection apparatus 101 according to an embodiment of the present invention. 3 is a flowchart showing processing performed in the inspection apparatus 101. It is explanatory drawing which shows the example of normalization of image data. It is explanatory drawing which shows the example of the specific calculation of normalization of image data. It is explanatory drawing which shows the example of the removal of the bright spot image by the foreign material adhering to the backlight. It is explanatory drawing which shows the example of a defect discrimination | determination.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

As shown in FIG. 1, a camera 102 using a CCD, for example, is connected to an inspection apparatus 101 (imaging processing unit, defect detection unit) that inspects the liquid crystal display panel 104 to be inspected. The image data (first image data) of an image obtained by photographing the liquid crystal display panel 104 disposed between the first and second devices 103 is input. The backlight 103 is configured by providing a polarizing plate 103b on a backlight main body 103a. The liquid crystal display panel 104 is formed by providing a color filter 104b on a liquid crystal panel 104a.

The inspection apparatus 101 detects a display defect by photographing, with the camera 102, light that is irradiated with light from the backlight 103 and transmitted through the liquid crystal display panel 104 from the back side of the liquid crystal display panel 104, for example. . Specifically, in the inspection apparatus 101, for example, the processing as shown in FIG. 2 and the following is performed.

(S101) First, the luminance is normalized in order to compensate for the difference in the photographing sensitivity according to the color of each pixel in the liquid crystal display panel 104. That is, for example, when attention is paid to the central red pixel Rc shown in FIG. 3, the following is used by using the average luminance of the surrounding eight pixels Rp2 of the same color separated by a predetermined distance (for example, vertical and horizontal distances) equal to or greater than the distance r. Such an operation is performed. Here, in FIG. 3, for simplification of explanation, the green and blue pixels are omitted, and only the pixel of interest Rc and the eight red pixels Rp1 and Rp2 inside and outside the peripheral distance r are drawn. .

Normalized luminance = 100 × (Rc luminance−Rp2 average luminance) / Rp2 average luminance However, when the calculation result is negative, 0 is assumed.

Specifically, for example, in the captured image, assuming that the pixels of the same color separated by the predetermined distance have the luminance as shown in FIG. 4, the normalized luminance is obtained for the pixel having a luminance of 50 near the center of the figure. = 100 × (50−20) / 20 = 150, and a pixel with luminance 20 is normalized luminance = 100 × (20−23.75) /23.75=−57.89 (thus 0).

Here, normalization is performed using the luminance of pixels (for example, Rp2 instead of Rp1 in FIG. 3) separated by a predetermined distance as described above on the surface of the backlight 103 or the inside of the liquid crystal display panel 104. This is because when a bright spot is generated by the attached foreign matter P1 or P2 (FIG. 1), proper luminance cannot be obtained by using the luminance of the pixel within the size range of the foreign matter. The foreign matter as described above is not limited to a single foreign matter, and may be, for example, granular foreign matter aggregation in which small foreign matters having a size of about 1 to 2 μm are aggregated. Further, the pitch of pixels of the same color in the liquid crystal display panel 104 corresponds to the pitch of 21 pixels of camera pixels in the camera 102, and the pitch of one pixel of camera pixels is 131 μm. Assuming that the separated camera pixels are Rp1 and Rp2, respectively, the distance between Rc and Rp1 and the distance between Rc and Rp2 are about 2.75 mm or about 5.5 mm, respectively. Therefore, for example, assuming that the size of the above-described foreign substance at the position of the pixel Rc on the camera pixel is 3 mm, the pixel Rp1 is a pixel within the foreign substance (in the bright spot area), but the pixel Rp2 is outside the foreign substance (luminescent spot). Therefore, by using the luminance of the pixel Rp2 as described above, the luminance of the pixel Rc can be normalized without being affected by foreign matter. In order to eliminate the influence of the foreign matter, the distance may be equal to or larger than the size of the assumed foreign matter. However, the distance as close as possible is usually other factors such as uneven brightness of the backlight 103, for example. This is preferable in that it suppresses the influence of luminance change due to. Further, the number of pixels Rp2 used for normalization is not limited to eight, and may be larger or smaller.

(S102) The image data based on the normalized luminance obtained as described above is binarized by a predetermined binarization threshold value to be binarized image data.

(S103) The image data (second image data) corresponding to the image data when the liquid crystal display panel 104 having no bright spot defect due to the foreign matter P1 or the like held in advance is captured is the same as the first image data. Using the binarized and binarized image data, the bright spot image due to the foreign matter P2 on the backlight 103 is removed from the binarized image data based on the first image data. Specifically, for example, as shown in FIG. 5, masking is performed by luminance subtraction for each pixel of the two binary image data. However, the present invention is not limited to this, and an exclusive OR operation of these binarized image data is performed, or the binarized image data is inverted based on the second image data and binarized based on the first image data. An AND operation with image data may be performed. Further, the luminance difference calculation may be performed using the image data before binarization. Further, for example, the position of the bright spot pixel is obtained for each of the two image data, and the bright spot image due to the foreign matter P2 may be removed by comparing and collating the positions.

Here, the second image data may be obtained in advance by photographing the liquid crystal display panel 104 or dummy liquid crystal display panel 104 or the like that does not actually have a bright spot defect due to the foreign matter P1 or the like. The above liquid crystal display panel 104 may be photographed, image data may be compared, and a bright spot detected from any of them may be detected as a bright spot image by the foreign matter P2 on the backlight 103. Furthermore, when the plurality of liquid crystal display panels 104 are inspected, the second image data may be sequentially updated by comparing the image data of the plurality of liquid crystal display panels 104 as needed.

(S104) Next, the following values are obtained.

The sum of normalized luminance (total luminance) in a bright spot pixel group in which pixels of high luminance (for example, value 1) in binary image data are continuous,
The number of pixels in the bright pixel group (binarized area),
Average value of normalized luminance in the bright spot pixel group, that is, total luminance / binarized area (average luminance).

(S105) In addition, for example, five pixels (the top five pixels of luminance) are extracted in order of the normalized luminance in the bright spot pixel group.

(S106) Further, for example, as schematically shown in FIG. 6, the diagonal length D of the rectangular area surrounding the upper five pixels P of the luminance (for example, the number of pixels H in the horizontal direction on the captured image or the display screen of the liquid crystal display panel 104, And the square root of the square sum of the number V of vertical pixels). In addition to the diagonal length D, the total of the horizontal pixel number H and the vertical pixel number V is obtained, the size of the circle surrounding the top five pixels of luminance, and the distance between the farthest pixels are obtained. Etc. Further, it may be determined whether at least one or both of the horizontal pixel number H and the vertical pixel number V exceed a predetermined threshold.

(S107) Whether or not the binarized area exceeds a predetermined threshold is determined, and if it is a minute luminescent spot that is equal to or less than the threshold, the pseudo defect, that is, the cause of high luminance is the so-called unevenness ( Uneven brightness at the pixel level) or charging of the liquid crystal display panel 104 (when a local voltage remains on the panel, it appears to be charged and dimly lit), which is a problem due to foreign matter P1 and the like. It is determined that the liquid crystal display panel 104 is not defective.

(S108) Further, whether or not the total luminance exceeds a predetermined threshold is determined. If the total luminance is equal to or less than the threshold, that is, even when the binarized area is large, the total luminance of pixels in those regions is relatively low. If it is low, it is determined that it is a pseudo defect.

(S109) Also, it is determined whether or not the average luminance exceeds a predetermined threshold value. If the average luminance value exceeds the predetermined threshold value, that is, the binarized area of the bright spot pixel group exceeds the predetermined threshold value, the total luminance exceeds the predetermined threshold value. When the average luminance exceeds the predetermined threshold value, it is determined that the display pixel itself of the liquid crystal display panel 104 is a bright spot defect.

(S110) On the other hand, if it is determined in (S109) that the average luminance is equal to or smaller than the predetermined threshold, it is further determined whether or not the diagonal length D exceeds the predetermined threshold. For example, it is determined that the defect is due to the foreign matter P1 or the like in the liquid crystal display panel 104. On the other hand, if it is equal to or less than the threshold value, it is determined that the defect is a pseudo defect. That is, in the case of a defect due to the foreign matter P1 or the like, or in the case of a defect due to unevenness or electrification, the light is generally brightened over a relatively wide range. However, in the case of a defect due to the foreign matter P1 or the like, for example, fine foreign matters are densely gathered, the light distribution of the foreign matter portion is disturbed, and light leakage occurs, so that a difference in luminance (brightness unevenness) between adjacent pixels is compared. The pixels P having a large size and high brightness are often distributed over a relatively wide range as shown in FIG. 6A, for example. It is considered that the high-luminance pixels P are often concentrated in a relatively narrow range as shown in FIG. Therefore, it is possible to discriminate between a defect due to the foreign matter P1 in the liquid crystal display panel 104 and a pseudo defect by the above determination.

In the above example, the camera 102 and the backlight 103 are provided separately from the inspection apparatus 101. However, the present invention is not limited to this, and one or both of the camera 102 and the backlight 103 are included in the inspection apparatus 101. May be included.

As described above, the present invention is useful for an inspection method and an inspection apparatus for inspecting the presence or absence of defects in a liquid crystal display panel.

DESCRIPTION OF SYMBOLS 101 Inspection apparatus 102 Camera 103 Backlight 103a Backlight main-body part 103b Polarizing plate 104 Liquid crystal display panel 104a Liquid crystal panel 104b Color filter P1, P2 Foreign material Rp1, Rp2 Pixel

Claims (10)

1. A defect detection method for a liquid crystal display panel,
   An imaging process for obtaining a first image data by arranging and photographing a liquid crystal display panel to be inspected between a camera and a backlight;
   A defect detection step of detecting a defect of the liquid crystal display panel to be inspected based on the first image data and the predetermined second image data;
   Including
   The predetermined second image data is image data corresponding to image data when a liquid crystal display panel having no bright spot defect is photographed by arranging it between the camera and the backlight,
   The defect detecting step detects a defect of the liquid crystal display panel to be inspected by removing the bright spot image included in the second image data from the bright spot image included in the first image data. Inspection method for liquid crystal display panels.
2. An inspection method for a liquid crystal display panel according to claim 1,
   The defect detection step includes, for each pixel in the first and second image data, normalized data obtained by dividing the difference between the luminance of each pixel and the average value of the luminance of a plurality of surrounding pixels by the average value. An inspection method for a liquid crystal display panel, comprising detecting a defect in the liquid crystal display panel to be inspected based on the above.
3. An inspection method for a liquid crystal display panel according to claim 2,
   The liquid crystal display panel to be inspected is provided with a color filter,
   The method for inspecting a liquid crystal display panel, wherein each of the pixels and a plurality of surrounding pixels are pixels of the same color.
4. An inspection method for a liquid crystal display panel according to any one of claims 2 and 3,
   The method for inspecting a liquid crystal display panel, wherein each of the pixels and a plurality of surrounding pixels are pixels separated by a predetermined distance.
5. A method for inspecting a liquid crystal display panel according to any one of claims 1 to 4,
   The method for inspecting a liquid crystal display panel, wherein the defect detection step determines that the defect is not a defect when the number of pixels in a pixel group in which pixels having a luminance exceeding a predetermined threshold are continuous is equal to or less than a predetermined number.
6. An inspection method for a liquid crystal display panel according to claim 5,
   A method for inspecting a liquid crystal display panel according to any one of claims 1 to 5,
   The method for inspecting a liquid crystal display panel, wherein the defect detection step determines that the defect is not a defect when a total luminance of pixels in a pixel group in which pixels having a luminance exceeding a predetermined threshold are continuous is equal to or less than a predetermined value.
7. A method for inspecting a liquid crystal display panel according to any one of claims 5 and 6,
   The defect detection step includes
   An average value of luminance of pixels in a pixel group in which pixels having luminance exceeding a predetermined threshold are continuous, is equal to or lower than a predetermined value; and
   A method for inspecting a liquid crystal display panel, characterized in that when the size of a pixel region having a predetermined upper number of luminances in the pixel group is not larger than a predetermined size, it is determined that there is no defect.
8. A method for inspecting a liquid crystal display panel according to any one of claims 5 to 7,
   The defect detection step includes
   An average value of luminance of pixels in a pixel group in which pixels having luminance exceeding a predetermined threshold are continuous, is equal to or lower than a predetermined value; and
   A liquid crystal display panel characterized in that when the size of a pixel region having a predetermined upper number of luminances in the pixel group exceeds a predetermined size, it is determined that the liquid crystal display panel is defective due to adhesion of foreign matter. Inspection method.
9. A method for inspecting a liquid crystal display panel according to any one of claims 5 to 7,
   The defect detection step includes
   The number of pixels in a pixel group in which pixels with a luminance exceeding a predetermined threshold are continuous exceeds a predetermined number; and
   The total luminance of the pixels in the pixel group exceeds a predetermined value, and
   An inspection method for a liquid crystal display panel, characterized in that, when an average value of luminances of pixels in the pixel group exceeds a predetermined value, it is determined that the display pixel in the liquid crystal display panel is defective.
10. A defect detection device for a liquid crystal display panel,
    An imaging processing unit for obtaining a first image data by arranging and inspecting a liquid crystal display panel to be inspected between a camera and a backlight;
    A defect detector for detecting a defect of the liquid crystal display panel to be inspected based on the first image data and the predetermined second image data;
    Including
    The predetermined second image data is image data corresponding to image data when a liquid crystal display panel having no bright spot defect is photographed by arranging it between the camera and the backlight,
    The defect detection unit detects a defect of the liquid crystal display panel to be inspected by removing the bright spot image included in the second image data from the bright spot image included in the first image data. Liquid crystal display panel inspection equipment.
    

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