JP3437906B2 - Method and apparatus for detecting color of color display - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color display color detection method and apparatus for detecting an ideal color space value of a fluorescent paint of a color display having a known chromaticity value, and in particular, using a dedicated measuring machine. The present invention relates to a color detection method and apparatus for a color display that enables detection of an ideal color space value of a fluorescent paint of the color display.

[0002]

2. Description of the Related Art In order to notify a third party of a color displayed on a color display, it is necessary to find an ideal color space value of the color represented by XYZ.

When the ideal color space value is obtained, the color can be reproduced by another color display or printing machine by notifying it. Since the additive color mixture model is established in the color space, the ideal color space value of the color displayed on the color display can be obtained by a simple calculation process if the ideal color space value of the fluorescent paint of the color display is obtained. .

Conventionally, a structure has been adopted in which the ideal color space value of the fluorescent paint of this color display is obtained by using a dedicated measuring machine.

[0005]

However, according to such a conventional technique, the ideal color space value of the fluorescent paint of the color display cannot be obtained without preparing an expensive dedicated measuring machine. was there.

There is a problem that the ideal color space value of the fluorescent paint of the color display cannot be obtained unless there is a dedicated operator who is familiar with the operation of the dedicated measuring machine.

The present invention has been made in view of the above circumstances, and a new color display color detection for detecting the ideal color space value of the fluorescent paint of the color display without using a dedicated measuring instrument. It is an object to provide a method and an apparatus.

[0008]

1 and 2 show the principle configuration of the present invention. In the figure, 1 is a color display,
2 is the first display area of the color display 1, 3
Is a second display area of the color display 1, and 4 is a display area of the color display 1.

The present invention whose principle configuration is shown in FIG. 1 detects an ideal color space value of a fluorescent paint of a color display 1 whose chromaticity value is known. First process P1 of identifying the correspondence with lightness
And a second step P2 for specifying an achromatic color having the same brightness or brightness as the monochromatic light exhibiting the highest level, and a third step P3 for calculating the ideal color space value of the fluorescent paint of the color display 1. Take the composition.

In the present invention whose principle configuration is shown in FIG. 1 constructed in this way, in the first process P1, a plurality of non-existing luminance or brightness unknowns are displayed in the first display area 2 of the color display 1. The colored grid pattern is displayed and, in association with it, the achromatic color is displayed in the second display area 3 of the color display 1 while changing the RGB values. When the operator receives the display of the achromatic color and the operator displays the achromatic color having the same brightness or brightness as the grid pattern, he / she inputs the fact, so by monitoring the response to this display. , By specifying an achromatic color that has the same brightness or brightness as the grid pattern and setting it as a component of a new grid pattern, the achromatic color and the brightness or brightness that it has Specify the correspondence relationship of.

At this time, the achromatic color and the brightness or lightness of the achromatic color are not changed by changing the area ratio of the lattice pattern instead of changing the achromatic color forming the lattice pattern. Correspondence may be specified.

Subsequently, in the second process P2, the highest level 3 is displayed in the first display area 2 of the color display 1.
The two monochromatic lights are displayed in sequence (may be simultaneous), and in association with that, the achromatic color is displayed in the second display area 3 of the color display 1 while changing the RGB value, and the achromatic color is displayed. , When the operator displays an achromatic color with the same brightness or brightness as monochromatic light,
Since a message to that effect is input, by monitoring the response to this display, an achromatic color having the same luminance or brightness as those of the monochromatic lights having the highest level is specified.

Subsequently, in the third process P3, the first process P
The brightness of the achromatic color specified in the second process P2 is calculated according to the correspondence relationship calculated in step 1, and the specified value is calculated using this brightness and the chromaticity value of the fluorescent paint of the color display that is known in advance. The ideal color space value of the fluorescent paint of the color display 1 is calculated according to the formula.

As described above, in the present invention whose principle configuration is shown in FIG. 1, the fluorescence of the color display 1 is changed by interacting with an operator who does not know anything about color management without using a dedicated measuring machine. It becomes possible to detect the ideal color space value of the paint.

On the other hand, the present invention whose principle configuration is shown in FIG. 2 is for detecting the ideal color space value of the fluorescent paint of the color display 1 whose chromaticity value is known. A first process P1 for displaying three monochromatic lights indicating levels in order (may be simultaneous), a second process P2 for inputting the brightness of a gradation color chip, and an ideal color space for the fluorescent paint of the color display 1. A configuration including a third process P3 of calculating a value is adopted.

According to the present invention whose principle configuration is shown in FIG. 2 constructed in this way, in the first process P1, three monochromatic lights showing the highest level are sequentially displayed in the display area 4 of the color display 1 (even at the same time). Good) to display.

In response to this display, the operator inputs the brightness of the gradation color chip having the same brightness or brightness as the monochromatic light, and then, in the second process P2, in the first process P1. For each monochromatic light to be displayed, the brightness notified in response to this display is input.

Subsequently, in the third process P3, the second process P
Using the luminance input in 2 and the chromaticity value of the fluorescent paint of the color display which is known in advance, the ideal color space value of the fluorescent paint of the color display 1 is calculated according to the specified calculation formula.

In this way, in the present invention whose principle configuration is shown in FIG. 2, the fluorescence of the color display 1 is changed by interacting with an operator who does not know anything about color management without using a dedicated measuring machine. It becomes possible to detect the ideal color space value of the paint.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in detail according to embodiments. FIG. 3 illustrates an embodiment of the data processing device 10 including the present invention.

As shown in this figure, the data processing apparatus 10 including the present invention uses the first display area 2 / second display area 3 of the color display 1 to interact with the operator to display the color. The color management program 100 for detecting the ideal color space value of the fluorescent paint of the color display 1 of which the degree value is known is developed.

4 to 6 show an embodiment of a processing flow executed by the color management program 100. Next, the present invention will be described in detail according to this processing flow.

When the color management program 100 is started by the operator, as shown in the process flow of FIGS. 4 to 6, first, in step 1, the first display area 2 is displayed with an area ratio of 50%. Display a grid pattern of achromatic colors with the highest brightness (R = G = B = 255, brightness = 100) and achromatic colors with the lowest brightness (R = G = B = 0, brightness = 0). .

That is, the grid pattern as shown in FIG. 7 is displayed. This grid pattern will appear as a gray shade between the highest and lowest brightness when viewed at some distance.

Here, the gray brightness Y seen at this time is
If the brightness of the higher brightness of the grid pattern is represented by YH, the brightness of the lower brightness of the grid pattern is represented by YL, and the area ratio of the brightness YH is represented by A%,

[0026]

[Equation 1]

It will be obtained according to. Further, between the brightness Y and the brightness L,

[0028]

[Equation 2]

Since the relational expression of is satisfied, if the brightness Y is obtained, the lightness L of the gray color seen at this time can also be obtained. Then, in step 2, it is determined whether or not the specified number of times of processing has been repeated, and when it is determined that the specified number of times of processing has not been repeated, the process proceeds to step 3 and the RGB values are displayed in the second display area 3. Achromatic colors (R = G = B = n) are sequentially displayed while changing the. For example, achromatic colors generated by decrementing the RGB values one by one are sequentially displayed.

Upon receiving the display in the second display area 3,
The operator, when the brightness of the achromatic color displayed in the lattice pattern displayed in the first display area 2 and the brightness of the achromatic color displayed in the second display area 3 are the same, inputs that effect. Therefore, in the subsequent step 4, it is monitored whether or not there is an input response of the same lightness, and the achromatic color displayed in the second display area 3 is changed until the input response is received.

When it is determined in step 4 that there is an input response having the same lightness, the level value n (R = G = B =) of the achromatic color displayed in the second display area 3 at that time is determined.
n) is specified, and the brightness that it has is specified.
That is, since the achromatic luminance displayed at this time is the same as the lattice pattern displayed in the first display area 2, it can be obtained according to the above-mentioned [Equation 1], and therefore it is obtained.

Subsequently, the process proceeds to step 5, and an achromatic color (R = G = B = 255, brightness = 100) having the highest brightness composed of an area ratio of 50% is displayed in the first display area 2, and the step After displaying the grid pattern with the achromatic color having the brightness (brightness) specified in 4, the process returns to step 2.

By repeating the processing of step 2 to step 5 in this manner, a luminance larger than the gray level in the middle of the lattice pattern of the achromatic color having the highest brightness and the achromatic color having the lowest brightness is obtained. The corresponding relationship between the gray level value of the gray level and its brightness is obtained.

On the other hand, when it is judged in step 2 that the processing of steps 2 to 5 has been repeated a prescribed number of times, the operation proceeds to step 6, and the first display area 2 has the minimum lightness with an area ratio of 50%. With achromatic color (R = G =
B = 0, brightness = 0) and an achromatic color having the brightness (brightness) specified first in step 4 are displayed.

Subsequently, in step 7, it is judged whether or not the specified number of times of processing has been repeated, and when it is judged that the specified number of times of processing has not been repeated, the process proceeds to step 8 and the second display area 3 is displayed. , Achromatic colors (R = G = B = n) are sequentially displayed while changing the RGB values. For example, achromatic colors generated by decrementing the RGB values one by one are sequentially displayed.

Upon receiving the display in the second display area 3,
The operator, when the brightness of the achromatic color displayed in the lattice pattern displayed in the first display area 2 and the brightness of the achromatic color displayed in the second display area 3 are the same, inputs that effect. Therefore, in a succeeding step 9, it is monitored whether or not there is an input response having the same lightness, and the achromatic color displayed in the second display area 3 is changed until the input response is received.

When it is judged in step 9 that there is an input response having the same lightness, the level value n (R = G = B =) of the achromatic color displayed in the second display area 3 at that time is determined.
n) is specified, and the brightness that it has is specified.
That is, since the achromatic luminance displayed at this time is the same as the lattice pattern displayed in the first display area 2, it can be obtained according to the above-mentioned [Equation 1], and therefore it is obtained.

Subsequently, the process proceeds to step 10, and an achromatic color (R = G = B = 0, brightness = 0) having a minimum brightness composed of an area ratio of 50% is displayed in the first display area 2, and a step 9
After displaying the grid pattern with the achromatic color having the brightness (brightness) specified in step 1, the process returns to step 7.

By repeating the processing of steps 7 to 10 in this manner, a luminance smaller than the gray level in the middle of the lattice pattern of the achromatic color having the highest brightness and the achromatic color having the lowest brightness is obtained. The corresponding relationship between the gray level value of the gray level and its brightness is obtained.

According to the above processing, as shown in FIG.
The correspondence relationship between the level value of the achromatic color and the brightness of the achromatic color is obtained. Then, the process proceeds to step 11 (FIG. 5) to display the monochromatic light “red” (R = 255, G = B = 0) having the highest level value in the first display area 2, and the following step 12 Then, the achromatic colors (R = G = B = n) are sequentially displayed in the second display area 3 while changing the RGB values. For example, achromatic colors generated by decrementing the RGB values one by one are sequentially displayed.

In response to the display in the second display area 3,
When the brightness of the monochromatic light “red” displayed in the first display area 2 and the brightness of the achromatic color displayed in the second display area 3 are the same, the operator inputs that fact. Therefore, in the following step 13, it is monitored whether or not there is an input response of the same brightness, and until this input response is received,
The achromatic color displayed in the second display area 3 is changed.

When it is determined in step 13 that there is an input response having the same brightness, the level value n (R = G = B) of the achromatic color displayed in the second display area 3 at that time is determined.
= N), and the level value n
Is used to search the correspondence relationship in FIG. 8 to specify the luminance Y of the achromatic color.

Then, in step 15, the chromaticity value (x, y) of the fluorescent paint "red" of the color display 1 and the specified luminance Y are used to calculate the chromaticity value (x, y) and the ideal value. Established between color space values (X, Y, Z)

[0044]

[Equation 3]

According to the relational expression of, the color display 1
Calculate the ideal color space values (XR, YR, ZR) of the fluorescent paint "red" of. Then, in step 16, the first display area 2
The monochromatic light “green” with the highest level value (G = 255,
R = B = 0) is displayed, and in the following step 17, the achromatic color (R =
G = B = n) is displayed in order. For example, achromatic colors generated by decrementing the RGB values one by one are sequentially displayed.

In response to the display in the second display area 3,
When the brightness of the monochromatic light “green” displayed in the first display area 2 and the brightness of the achromatic color displayed in the second display area 3 are the same, the operator inputs that effect. Therefore, in the following step 18, it is monitored whether or not there is an input response of the same brightness, and until the input response is received,
The achromatic color displayed in the second display area 3 is changed.

When it is determined in step 18 that there is an input response having the same brightness, the level value n (R = G = B) of the achromatic color displayed in the second display area 3 at that time is determined.
= N), and in the following step 19, the level value n
Is used to search the correspondence relationship in FIG. 8 to specify the luminance Y of the achromatic color.

Then, in step 20, the chromaticity value (x, y) of the fluorescent paint "green" of the color display 1 and the specified luminance Y are used to calculate the chromaticity value (x, y) and the ideal value. The ideal color space value (XG, YG, ZG) of the fluorescent paint "green" of the color display 1 is calculated according to the relational expression of [Equation 3] established between the color space value (X, Y, Z). To do.

Then, in step 21, in the first display area 2, the monochromatic light "blue" (B = 25) having the highest level value.
5, R = G = 0) is displayed, and in the subsequent step 22, the second
In the display area 3 of, achromatic colors (R = G = B = n) are sequentially displayed while changing the RGB values. For example, R
The achromatic colors generated by decrementing the GB value from the maximum value one by one are displayed in order.

Upon receiving the display in the second display area 3,
When the brightness of the monochromatic light “blue” displayed in the first display area 2 and the brightness of the achromatic color displayed in the second display area 3 are the same, the operator inputs that fact. Therefore, in the following step 23, it is monitored whether or not there is an input response of the same brightness, and until the input response is received,
The achromatic color displayed in the second display area 3 is changed.

When it is determined in step 23 that there is an input response having the same lightness, the level value n (R = G = B) of the achromatic color displayed in the second display area 3 at that time is determined.
= N), and in the subsequent step 24 (FIG. 6), the level value n is used to search the correspondence relationship of FIG.
The luminance Y of the achromatic color is specified.

Then, in step 25, the chromaticity value (x, y) of the fluorescent paint "blue" of the color display 1 and the specified luminance Y are used to calculate the chromaticity value (x, y) and the ideal value. The ideal color space value (XB, YB, ZB) of the fluorescent paint "blue" of the color display 1 is calculated according to the relational expression of [Equation 3] established between the color space value (X, Y, Z). To do.

Finally, in step 26, the fluorescent paint "red" of the color display 1 obtained in step 15 is obtained.
And the ideal color space value (XG, YG, ZG) of the fluorescent paint "green" of the color display 1 obtained in step 20 and the color display 1 obtained in step 25. Value of the ideal color space (XB, YB,
ZB) is output and the process ends.

As described above, in the present invention, the ideal color space value of the fluorescent paint of the color display 1 is detected by interacting with an operator who does not know anything about color management without using a dedicated measuring machine. To do.

When the ideal color space value of the fluorescent paint of the color display 1 is obtained, the ideal color space value of any color (R = r, G = g, B = b) displayed on the color display 1 is additively mixed. According to the model, it becomes possible to obtain by a linear interpolation formula.

When the processing flow of FIGS. 4 to 6 is followed, the color management program 100 changes the achromatic color forming the grid pattern to change the brightness (luminance) of the achromatic color shown by the grid pattern. The configuration was changed, but by changing the area ratio of the achromatic colors that make up the grid pattern, it is possible to change the brightness (luminance) of the achromatic color that the grid pattern shows. Is.

FIG. 9 shows another embodiment of the processing flow executed by the color management program 100. In this embodiment, a gradation color chip whose luminance Y is known is used to detect the ideal color space value of the fluorescent paint of the color display 1.

When the color management program 100 follows the processing flow of FIG. 9, when it is started by the operator, first, in step 1, in the first display area 2 or the second display area 3, The monochromatic light “red” (R = 255, G = B = 0) having the highest level value is displayed.

In response to this display, the operator searches for a gradation color chip having the same lightness as the monochromatic light "red" displayed in the display area and inputs the luminance Y possessed by the gradation color chip. Then, in step 2, the input of the brightness Y of the gradation color chart is waited for, and when it is input, the process proceeds to step 3 and the brightness Y and the color of the fluorescent paint "red" of the color display 1 are held. Using the chromaticity value (x, y), the chromaticity value (x, y
y) and the ideal color space value (X, Y, Z), the ideal color space value (XR, YR) of the fluorescent paint "red" of the color display 1 is calculated according to the above-mentioned relational expression of [Equation 3]. , ZR) is calculated.

Subsequently, in step 4, the monochromatic light "green" (G = 255, R = B = 0) having the highest level value is displayed in the first display area 2 or the second display area 3. . In response to this display, the operator searches for a gradation color chip having the same brightness as the monochromatic light “green” displayed in the display area and inputs the brightness Y of the gradation color chip. Waiting for the input of the luminance Y of the gradation color chart in 5, when it is input, the process proceeds to step 6 and the luminance Y
And the chromaticity value (x, y) of the fluorescent paint "green" of the color display 1 between the chromaticity value (x, y) and the ideal color space value (X, Y, Z). The ideal color space value (XG, YG, ZG) of the fluorescent paint "green" of the color display 1 is calculated according to the above-described relational expression of [Equation 3].

Subsequently, in step 7, the monochromatic light "blue" (B = 255, R = G = 0) having the highest level value is displayed in the first display area 2 or the second display area 3. . In response to this display, the operator searches for a gradation color chip having the same brightness as the monochromatic light “blue” displayed in the display area, and inputs the brightness Y possessed by the gradation color chip. At 8, the input of the luminance Y of the gradation color chart is waited for, and when it is input, the process proceeds to step 9, where the luminance Y
And the chromaticity value (x, y) of the fluorescent paint “blue” of the color display 1 between the chromaticity value (x, y) and the ideal color space value (X, Y, Z). The ideal color space value (XB, YB, ZB) of the fluorescent paint "blue" of the color display 1 is calculated according to the above-described relational expression of [Equation 3].

Finally, at step 10, the ideal color space value (XR, YR, ZR) of the fluorescent paint "red" of the color display 1 obtained at step 4 and the fluorescence of the color display 1 obtained at step 6 are obtained. The ideal color space value (XG, YG, ZG) of the paint "green" and the ideal color space value (XB, YB, ZB) of the fluorescent paint "blue" of the color display 1 obtained in step 9.
And are output to end the processing.

In this way, the color management program 100
Even when the processing flow of FIG. 9 is followed, the ideal color space value of the fluorescent paint of the color display 1 can be detected.

Although the present invention has been described in detail according to the illustrated embodiments, the present invention is not limited thereto. For example, the area ratio of the lattice pattern described in the processing flow of FIGS. 4 to 6 is not limited to 50%. Further, although the structure in which the monochromatic light to be displayed in the first display area 2 and the like is displayed in order is adopted, it is also possible to adopt the structure in which the monochromatic lights are displayed simultaneously.

[0065]

As described above, according to the present invention,
By interacting with an operator who does not know anything about color management, without using a dedicated measuring machine, it becomes possible to detect the ideal color space value of the fluorescent paint of the color display.

[Brief description of drawings]

FIG. 1 is a principle configuration diagram of the present invention.

FIG. 2 is a principle configuration diagram of the present invention.

FIG. 3 is an example of the present invention.

FIG. 4 is an example of a processing flow executed by a color management program.

FIG. 5 is an example of a processing flow executed by a color management program.

FIG. 6 is an example of a processing flow executed by a color management program.

FIG. 7 is an explanatory diagram of a lattice pattern.

FIG. 8 is an explanatory diagram of a correspondence relationship.

FIG. 9 is an example of a processing flow executed by a color management program.

[Explanation of symbols]

1 color display 2 First display area 3 second display area 4 display areas

Continuation of front page (56) Reference JP-A-9-18902 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) G01J 3/00-3/52 G01M 11/00 H04N 17 / 00-17/06 JISST file (JOIS)

Claims (6)

(57) [Claims] 1. A color detection method of a color display for detecting an ideal color space value of a fluorescent paint of a color display of which chromaticity value is known, wherein the color display has a plurality of brightness- or brightness-unknown colors. By displaying a colored grid pattern and displaying the achromatic color while changing the RGB values in association with the colored grid pattern and monitoring the response to the achromatic color display, it is possible to obtain the same brightness or brightness as the grid pattern. A first process of specifying the correspondence between the achromatic color and the brightness or brightness of the achromatic color by repeating the process of specifying the color and setting it as a component of a new grid pattern, Table for each of the three monochromatic light, and displays the shown to monochromatic light highest level color display, in association therewith, the achromatic while changing the RGB values By observing the response to the display of the achromatic color, the achromatic color having the same brightness or lightness as the monochromatic light is specified for each of the monochromatic lights, and is obtained in the first step. The brightness of the achromatic color specified in the second step is calculated according to the correspondence relationship, and the brightness and the chromaticity value are used to calculate the ideal color space value of the fluorescent paint of the color display according to the specified calculation formula. 3. A color detection method for a color display, comprising: 2. A color detection method of a color display for detecting an ideal color space value of a fluorescent paint of a color display having a known chromaticity value, wherein the color display has a plurality of brightness- or brightness-unknown. By displaying a colored grid pattern and displaying the achromatic color while changing the RGB values in association with the colored grid pattern and monitoring the response to the achromatic color display, it is possible to obtain the same brightness or brightness as the grid pattern. By specifying the chromatic color and repeating this while changing the area ratio of the lattice pattern, the first process of specifying the correspondence between the achromatic color and the brightness or lightness of the achromatic color, and the three monochromatic light for each, and displays the shown to monochromatic light highest level color display, in association therewith, to display an achromatic color while changing the RGB value, the achromatic By monitoring the response to the display of, the second process of specifying an achromatic color having the same brightness or brightness as the monochromatic light for each monochromatic light, and the first process according to the correspondence relationship obtained in the first process. The third step of obtaining the luminance of the achromatic color identified in the step 2 and using the luminance and the chromaticity value to calculate the ideal color space value of the fluorescent paint of the color display according to the specified calculation formula. A color detection method for a color display, comprising: 3. A color display color detecting method for detecting an ideal color space value of the fluorescent paint color display known chromaticity value, for each of the three monochromatic light, the color display, the highest a first step of displaying a single color light shows the levels for each monochromatic light to be displayed in a first step, a second step of inputting the Brightness that will be notified in response to the display of the single color light, A color display characterized by comprising a third step of calculating an ideal color space value of a fluorescent paint of a color display according to a prescribed calculation formula using the luminance and the chromaticity value input in the second step. Color detection method. 4. A color detection device for a color display for detecting an ideal color space value of fluorescent paint of a color display having a known chromaticity value. By displaying a colored grid pattern and displaying the achromatic color while changing the RGB values in association with the colored grid pattern and monitoring the response to the display of the achromatic color, a grid pattern having the same brightness or brightness as the grid pattern is displayed. A first means for specifying the correspondence between an achromatic color and the brightness or brightness of the achromatic color by repeating the process of specifying the color and setting it as a component of a new lattice pattern, Table for each of the three monochromatic light, and displays the shown to monochromatic light highest level color display, in association therewith, the achromatic while changing the RGB values The second means for identifying the achromatic color having the same luminance or lightness as the monochromatic light for each monochromatic light by monitoring the response to the display of the achromatic color and the first means. The brightness of the achromatic color specified by the second means is obtained according to the correspondence, and the ideal color space value of the fluorescent paint of the color display is calculated according to a prescribed calculation formula using this brightness and the chromaticity value. 3. A color detection device for a color display, comprising: 5. A color detection device for a color display for detecting an ideal color space value of fluorescent paint of a color display having a known chromaticity value, wherein the color display has a plurality of brightness- or brightness-unknown colors. By displaying a colored grid pattern and displaying the achromatic color while changing the RGB values in association with the colored grid pattern and monitoring the response to the achromatic color display, it is possible to obtain the same brightness or brightness as the grid pattern. By specifying the chromatic color and repeating this while changing the area ratio of the lattice pattern, the first means for specifying the correspondence relationship between the achromatic color and the brightness or lightness of the achromatic color, and the three monochromatic light for each, and displays the shown to monochromatic light highest level color display, in association therewith, to display an achromatic color while changing the RGB value, the achromatic By monitoring the response to the display, the second means for specifying the achromatic color having the same luminance or brightness as the monochromatic light for each monochromatic light and the first means in accordance with the correspondence relationship obtained by the first means. And a third means for calculating the ideal color space value of the fluorescent paint of the color display in accordance with a prescribed calculation formula using the brightness and the above chromaticity value. A color detection device for a color display, comprising: 6. A color detecting apparatus of a color display to detect the ideal color space value of the fluorescent paint color display known chromaticity value, for each of the three monochromatic light, the color display, the highest first means for displaying a single color light shows the levels for each monochromatic light to be displayed in the first means, second means for inputting a bright degree that will be notified in response to the display of the single color light, A color display characterized by comprising: a third means for calculating an ideal color space value of the fluorescent paint of the color display according to a prescribed calculation formula, using the luminance input by the second means and the chromaticity value. Color detection device.