JP2006138670A - Inspection device and method for inspecting color unevenness of color filter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To inspect color unevenness of a color filter with accuracy. <P>SOLUTION: To irradiate the color filter formed inside of a panel 2 with light from a light source 4. An optical spectrometer 8 automatically measures the transmission spectrum of the color filter. The computation device 6 calculates the illuminance value and chromaticity value, and then detects color unevenness. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an inspection apparatus and an inspection method for inspecting color unevenness of a color filter.

  In the manufacturing process of a color cathode ray tube, there are a black coating process, a microfilter process, a screen coating process and the like as a process for forming a fluorescent screen. Among these, in the microfilter process for forming a color filter, after forming the color filter, defects generated in the blue (B), red (R), and green (G) filters formed in a periodic pattern are removed. An inspection process is performed. In this inspection process, in general, a light source such as white light is irradiated from the back surface of the color filter, and an inspector visually observes the light transmitted through the color filter from the surface side of the color filter, so that the manufacturing conditions such as coating or drying are satisfied. It is inspected for the presence of color unevenness and point-like defects caused by fluctuations.

  In this inspection method, since it is difficult to confirm the change in color unevenness of the color filter by human visual observation, there is a problem that the inspection accuracy varies depending on individual differences and physical condition of the inspector.

In Patent Document 1, a complementary color filter is arranged between a light source and a color filter to be inspected, and an indirect achromatic color instead of spectral color light is visually inspected to determine the presence or absence of light and dark in the same color. An inspection method that facilitates the above has been proposed.
JP-A-7-209194

  However, with respect to a filter in which a slight change in film thickness of the color filter causes a color unevenness defect, even with the method of Patent Document 1, it is difficult to judge with human sensitivity, and it is very difficult to inspect color unevenness with high accuracy. . Further, there is a problem that a color filter composed of a plurality of color filters formed in a periodic pattern cannot simultaneously inspect each color unevenness of different color filters.

  The present invention has been made in view of the above-described drawbacks, and an object of the present invention is to provide a color filter color unevenness inspection apparatus and inspection method capable of accurately inspecting color unevenness.

  The color filter color unevenness inspection apparatus according to the present invention is a color filter color unevenness inspection apparatus provided with at least two or more types of filters having different transmittance characteristics, the light source for irradiating the color filter with light, A spectroscopic measurement device that automatically measures a transmission spectrum of a color filter, and a calculation device that calculates a luminance value and a chromaticity value from the transmission spectrum and detects color unevenness are provided.

  The color filter color unevenness inspection method of the present invention is a color filter color unevenness inspection method including at least two or more types of filters having different transmittance characteristics, and automatically measures a transmission spectrum of the color filter, A luminance value and a chromaticity value are calculated from the transmission spectrum obtained by measurement, and color unevenness is detected.

  According to the present invention, the color unevenness of the color filter can be inspected with high accuracy.

  In the color unevenness inspection apparatus according to the present invention, it is preferable that the arithmetic device performs enhancement processing on the luminance value and the chromaticity value calculated from the transmission spectrum. This makes it possible to easily detect slight changes in the luminance value and the chromaticity value, thereby improving the inspection accuracy for color unevenness.

  Further, it is preferable that the arithmetic device detects color unevenness of the filter based on a luminance value calculated using a transmission spectrum in a wavelength region with low transmittance in the transmittance characteristic of the filter. Alternatively, it is preferable that the arithmetic device detects color unevenness of the filter based on a chromaticity value calculated using a transmission spectrum in a wavelength region in which the transmittance greatly changes in the transmittance characteristics of the filter. By selecting the optimum wavelength range for detecting the luminance value and the chromaticity value in accordance with the characteristics of the color filter to be inspected, highly accurate color unevenness inspection can be performed.

  When two or more types of the filters are simultaneously included in the measurement region of the spectroscopic measurement device, the measurement position is changed and two or more measurements are performed, and the transmission spectrum obtained by the two or more measurements is averaged. It is preferable to detect the color unevenness by calculating the luminance value and the chromaticity value from the transmission spectrum. Thereby, the dispersion | variation in the test | inspection precision by the difference in a measurement position can be suppressed.

  It is preferable that the color filter is a color filter formed on a panel for a color cathode ray tube, which includes three types of filters that respectively transmit light in each wavelength band of red, green, and blue. Thereby, since the inspection accuracy of the color filter is improved, the production yield of the color CRT can be improved.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 shows the configuration of a color filter color nonuniformity inspection apparatus to which the present invention is applied. The color cathode ray tube panel 2 having a color filter formed on the inner surface is installed on the stage 1 with the surface on which the color filter is formed facing downward. The light from the light source device 4 using a light source that emits white light (for example, a halogen lamp) is irradiated toward the surface of the panel 2 on which the color filter is formed. The light transmitted through the color filter and the panel 2 enters the lens 9 of the spectroscopic measurement device 8 and is converged on the light receiving head 10 which is a spectral light receiving element. The light receiving head 10 detects the spectral sensitivity data of the color filter, and the detected spectral sensitivity data is transmitted to the spectroscopic calculation device 7 through a cable such as an optical fiber, and is processed by the spectroscopic calculation device 7 to obtain a transmission spectrum. Converted to data and saved. The transmission spectrum is usually measured at a fine interval of 0.5 nm in the measurement wavelength range of 300 nm to 800 nm in order to measure with high accuracy. Although not shown, it is desirable that a plurality of spectrometers 8 are installed in order to improve the measurement speed.

  The stage 1, the light source device 4, and the spectroscopic measurement device 8 are motor-controlled by the drive device 3, and can freely move independently in the X axis, Y axis, and Z axis directions. The measurement position is freely changed by motor control, and the transmission spectrum of the entire surface of the color filter formed on the panel 2 is automatically measured. Here, the Z axis means a tube axis of a cathode ray tube in which the panel 2 is used, and substantially coincides with the normal direction at the center of the surface on which the color filter is formed. The X axis means an axis parallel to the long side of the panel 2 and perpendicular to the Z axis, and the Y axis means an axis parallel to the short side of the panel 2 and perpendicular to the X axis and the Z axis.

  As shown in FIG. 2, the color filter has a pattern in which three types of stripe-shaped filters that transmit light of each color of blue (B), red (R), and green (G) are periodically and repeatedly arranged. When the measurement region (measurement visual field) 11 is larger than the stripe width of each color filter, two or more types of filters are included in the measurement region 11 at the same time, so that blue (B), red (R), green The mixing ratio of the light transmitted through each filter of (G) is different. Therefore, there arises a problem that the transmission spectrum data varies depending on the measurement position. In order to solve this problem, in this apparatus, for example, when the color filter is a repetitive pattern of stripe filters having a width P as shown in FIG. 2, the direction orthogonal to the longitudinal direction of the stripe (for example, the Y-axis direction) The measurement region 11 is moved by the repetition pitch (ie, stripe width) P in the X-axis direction (for example, in the X-axis direction), and the measurement is performed as many times as the number of filter types (3 in this example). Average the data. Thereby, it is possible to acquire transmission spectrum data in which the mixture ratio of light transmitted through the blue (B), red (R), and green (G) filters is constant regardless of the measurement position.

  The arithmetic device 6 performs a calculation process of luminance values and chromaticity values that are optimal for color unevenness inspection based on the transmission spectrum calculated by the spectral calculation device 7. The processing result is displayed on the display device 5 as the color unevenness inspection result and is transmitted to the inspector.

  Next, a method for inspecting color unevenness by calculating optimum luminance values and chromaticity values for color unevenness inspection based on the transmission spectrum will be described in detail.

First, in the automatic measurement of the transmission spectrum of the color filter by this apparatus, as shown in FIG. 3, the rectangular area where the color filter of the panel 2 is formed is divided into m short sides and n long sides. By doing so, it is divided into a total of m × n areas 12. Then, a transmission spectrum is obtained for each area 12. The tristimulus values X, Y, and Z are obtained from the obtained transmission spectrum using the color matching function, and this is also a Yu ^* v ^* color space which is one of CIE display systems defined by the CIE (International Commission on Illumination) And expressed as Y, u ^* , v ^* .

Generally, if there is only a slight change in film thickness, color unevenness occurs, but if the color unevenness is determined, the change in chromaticity value is negligible. Therefore, even if the color unevenness inspection is performed from the chromaticity value and the luminance value obtained as described above, the accuracy is not good. Therefore, in this apparatus, the enhancement processing calculation is performed so that the examiner can recognize a slight change in the chromaticity value and the luminance value. First, average values Y _avr , u ^* _avr , v ^* _avr of Y, u ^* , v ^* for each of the m × n areas 12 are _obtained . If i is an integer from 1 to n, j is an integer from 1 to m, and Y, u ^* , v ^* for area 12 at position (i, j) are Yij, u ^* ij, v ^* ij, the average Yij, u ^* ij and v ^* ij are emphasized by performing the following operations using the values Y _avr , u ^* _avr and v ^* _avr . Here, k is the enhancement magnification.

Yij = (Yij−Y _avr ) × k + Y _avr
u ^* ij = (u ^* ij−u ^* _avr ) × k + u ^* _avr
v ^* ij = (v ^* ij−v ^* _avr ) × k + v ^* _avr

If the data expressed in the Yu ^* v ^* color space color system is used as it is, colors cannot be directly displayed on the display device 5. Therefore, the color data Yij, u ^* ij, v ^* ij in the area 12 at the position (i, j) is converted into data expressed in the RGB color system defined by the CIE so that it can be displayed on the display device 5. , Rij, Gij, Bij are calculated. The data of all m × n areas 12 are converted into data in the RGB color system, and the maximum value RGBmax is obtained from all the converted data. Next, Rij, Gij, Bij by the RGB color system of each area is converted into a gradation display of 0 to 255 by performing the following calculation.

Rij = Rij / RGBmax × 255
Gij = Gij / RGBmax × 255
Bij = Bij / RGBmax × 255

  By using Rij, Gij, Bij, and Yij in each of the m × n areas 12 obtained as described above, the color is displayed on the display device 5, and the color unevenness inspection result is transmitted to the inspector. This inspection result is based on the emphasized chromaticity value and luminance value, and high-precision color unevenness inspection can be performed by viewing the screen.

  FIG. 4 shows an example of the transmittance characteristics 13, 15, and 14 of the blue (B) filter, red (R) filter, and green (G) filter constituting the color filter. In this way, when the transmission wavelength ranges of the filters overlap with each other, if the filters have color unevenness, it is generally difficult to accurately detect the color unevenness. With respect to this problem, in this apparatus, the wavelength range of the spectrum used by the calculation device 6 for calculation processing can be freely selected. In accordance with the characteristics of the formed color filter, it is possible to select a wavelength range where color unevenness is most easily detected.

  When inspecting color unevenness from the luminance value, a transmission spectrum in a wavelength region where the luminance change is large, that is, a wavelength region where the transmittance is low and the transmittance is low is used. For example, when inspecting the color unevenness of a blue (B) filter, the transmittance characteristic 13 of the blue (B) filter is a region having a small transmittance, and the transmittance characteristic 15 of the red (R) filter is large. A wavelength region 16 that has transmittance and, as a result, is less affected by red (R) luminance change is selected. Thereby, the color unevenness of the blue filter can be detected based on the luminance value change in the wavelength region 16.

  When inspecting color unevenness from chromaticity values, a transmission spectrum is used in a wavelength region where the chromaticity change is large, that is, in a wavelength region where a change in transmittance appears significantly. For example, when inspecting the color unevenness of the blue (B) filter, the wavelength region 17 in which the transmittance change is large in the transmittance characteristic 13 of the blue (B) filter is selected. Thereby, the color unevenness of the blue filter can be detected based on the chromaticity value change in the wavelength region 17.

  As shown in FIG. 5, the inspection result is displayed on the display screen 18 of the display device 5 as an overall panel diagram for each of the blue (B) filter 19, the red (R) filter 21, and the green (G) filter 20. The inspector can see the color unevenness of the three filters of blue, red, and green at the same time on one screen. The color unevenness can be displayed as, for example, a linear pattern 30a or a brightness unevenness pattern 30b having a region where brightness gradation is different from the surroundings, and can be intuitively understood. In this device, the optimum wavelength range for color unevenness detection of each filter is selected for each filter, and furthermore, the brightness value and chromaticity value enhancement processing calculation is performed. Inspection accuracy is improved.

  This apparatus can be incorporated in a color filter forming system as shown in FIG. The panel 2 before the color filter is formed is input to the input port 22 of the system. Next, the identification display giving device 23 gives the panel 2 a display such as a number, a barcode, or various symbols for identifying each panel. Next, the filter forming device 24 forms a color filter on the inner surface of the panel by a known method. Thereafter, the panel is inspected for color unevenness of the color filter by the color unevenness inspection apparatus 25 of the present invention, and is then carried out from the carry-out port 26 of the system.

  In such a forming system, the filter forming device 24 transmits identification display data unique to each panel and process data relating to forming conditions of the color filter for the panel to the data recording device 27 (arrow 28). Further, the color unevenness inspection device 25 transmits identification display data unique to each panel and data related to the color unevenness inspection result of the color filter formed on the panel to the data recording device 27 (arrow 29). Here, the data related to the color unevenness inspection result may be, for example, data obtained by automatically quantifying the color unevenness evaluation classification or data obtained by ranking the data. Thus, a large number of process data relating to the color filter formation conditions and color filter color unevenness inspection result data are stored in the data recording device 27 in association with each other via the identification display data given to the panel. The

  According to such a color filter formation system, by using a technique such as data mining, which is one of the methods for elucidating the cause of defects, the cause of color unevenness and the quality determining factors of color filters and various manufacturing processes The relationship with the conditions can be investigated, and the manufacturing process conditions can be changed and improved easily and quickly.

  The field of use of the present invention is not particularly limited, but it can be particularly preferably used in the inspection process of the color filter formed on the inner surface of the panel in the manufacturing process of the color cathode ray tube.

FIG. 1 is a configuration diagram of a color filter color nonuniformity inspection apparatus according to an embodiment of the present invention. FIG. 2 is a diagram showing a measurement region in the color filter color nonuniformity inspection apparatus according to the embodiment of the present invention. FIG. 3 is a diagram showing an example of area division when measuring the color filter in the color filter color nonuniformity inspection apparatus according to the embodiment of the present invention. FIG. 4 is a diagram illustrating an example of transmittance characteristics of the three types of filters constituting the color filter. FIG. 5 is a diagram showing an example of the color unevenness inspection result displayed on the display device in the color filter color unevenness inspection apparatus according to the embodiment of the present invention. FIG. 6 is a schematic configuration diagram of a color filter forming system using a color filter color nonuniformity inspection apparatus according to an embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Stage 2 Panel 3 Drive apparatus 4 Light source apparatus 5 Display apparatus 6 Arithmetic apparatus 7 Spectroscopic calculation apparatus 8 Spectroscopic measurement apparatus 9 Lens 10 Light receiving head 11 Measurement area (measurement visual field)
12 areas

Claims (7)

  A color unevenness inspection apparatus for a color filter having at least two or more types of filters having different transmittance characteristics, a light source for irradiating the color filter with light, and a spectrometer for automatically measuring a transmission spectrum of the color filter And a color filter color non-uniformity inspection apparatus for calculating color non-uniformity by calculating a luminance value and a chromaticity value from the transmission spectrum.   2. The color filter color unevenness inspection apparatus according to claim 1, wherein the arithmetic device performs enhancement processing on the luminance value and the chromaticity value calculated from the transmission spectrum.   2. The color unevenness of the color filter according to claim 1, wherein the arithmetic device detects the color unevenness of the filter based on a luminance value calculated using a transmission spectrum in a wavelength region having a low transmittance in the transmittance characteristic of the filter. Inspection device.   2. The color filter according to claim 1, wherein the arithmetic device detects color unevenness of the filter based on a chromaticity value calculated using a transmission spectrum in a wavelength region in which the transmittance greatly changes in the transmittance characteristics of the filter. Color unevenness inspection device.   When two or more types of the filters are simultaneously included in the measurement region of the spectroscopic measurement device, the measurement position is changed and two or more measurements are performed, and the transmission spectrum obtained by the two or more measurements is averaged. The color filter color nonuniformity inspection apparatus according to claim 1, wherein a luminance value and a chromaticity value are calculated from a transmission spectrum to detect color nonuniformity.   The color of the color filter according to claim 1, wherein the color filter is a color filter formed on a panel for a color cathode ray tube, which is composed of three types of filters that respectively transmit light in each wavelength band of red, green, and blue. Unevenness inspection device. A method for inspecting color unevenness of a color filter including at least two kinds of filters having different transmittance characteristics, wherein a transmission spectrum of the color filter is automatically measured, and a luminance value and a color are determined from the transmission spectrum obtained by the measurement. A method for inspecting color unevenness of a color filter, comprising calculating a degree value and detecting color unevenness.

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