JPH08292735A - Crossconversion system of light emission control signal for color display and tristimulus values of object color and crossconversion method - Google Patents

Abstract

PURPOSE: To provide a crossconversion system of the light emission control signals RGB of the light source colors displayed on a color display screen and the object colors expressed by tristimulus values XYZ in arbitrary observation environment and only by the color matching experiment (adjustment) with respect to lightness. CONSTITUTION: This crossconversion system consists of a luminance-to-lightness converting means for converting luminance Y to lightness L, a lightness converting means for converting the lightness L to new lightness L' by linear conversion and a lightness-to-luminance converting means for converting the lightness L' to the luminance Y'. The system includes a means for calculating the light emission control signals of the color display with calculates the light emission control signals RGB of the color display from the tristimulus values XYZ and a means for calculating the tristimulus values which calculates the tristimulus values XYZ from the light emission control signals RGB of the color display. A color reflection original and the color original displayed on the color display are visually observed and the conversion coeffts α, β in the lightness converting means are determined so that both colors in view coincide with each other.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a CRT (Cathode).
RAY TUBE) and the like, and an interconversion system and an interconversion method between a light emission control signal that is light source color data of a color displayed on a color display and a tristimulus value that is object color data, and in particular, the interconversion system and the mutual conversion method. The present invention relates to a color matching technique using a conversion method.

[0002]

2. Description of the Related Art In recent years, desktop publishing (D
With the spread of TP), a color image is read by a scanner, the image is displayed on a color display such as a CRT, and the image is confirmed on a CRT color display (also called a CRT color monitor) and a computer graphic device (CG) is displayed. There is an increasing number of cases in which a color image is output by a color image output device such as a thermal sublimation type, an inkjet type, an electrophotographic type, or a printing method after the image is processed or modified by using the image. Further, the number of cases in which a designer directly creates a color design image on a CRT color display without using a scanner and outputs a color image by the above-mentioned color image output device, is also increasing.

A major problem in handling such color images is a color scanner or CRT.
This means that the same color cannot be reproduced between the devices due to the color reproduction characteristic mismatch between the color display and the color image output device. In other words, the original image read by the scanner is different from the color in visual observation when it is displayed on the CRT color display, or the color displayed on the CRT color display and the color output by the color image output device, The problem is that the colors are visually different. Therefore, attention has been focused on a technique for matching the color reproduction among the devices even when the color reproduction characteristics differ among the devices.

As a method for matching the color reproduction between different output devices, a database called a profile which describes characteristics relating to color reproduction for each output device is created, and a color called a color management system (CMS) is created. There are already commercially available management systems that use the profile so that different output devices, such as different printers, can produce the same color (actually a closer color). In response to such movements in the world, standardization of profile forms and standard signal forms connecting devices are being standardized. For example, standard signals connecting devices include R, G, B signals in the conventional RGB color system, and XY of CIE (International Commission on Illumination).
X, Y, Z, or C which are tristimulus values in the Z color system
Color values such as L, a, and b (L is lightness, a and b are chromaticness indices), which are IE uniform color spaces, tend to be adopted, and a light source D50, 2 ° field of view, etc. are considered as observation conditions. If the printer is a printer, the profile includes a conversion matrix from a standard signal (for example, tristimulus values X, Y, Z) to an output signal (for example, C, M, Y, K) peculiar to the printer, and a gamma of the printer. If the coefficient or the like is a scanner, a photoelectric conversion signal by reading (for example, R, G,
The conversion matrix from B) to standard signals, the gamma coefficient of the scanner, etc., and in the case of a CRT color display, the gamma coefficient of the monitor, the chromaticity point of the phosphor, the color temperature of white, etc. are expected to be described. is there.

Most of CMSs on the market are intended for color matching between an original image read by a scanner and an output image when the original image is output by a printer. In this case, the objects to be matched in color are both surface colors (object colors) colored on a medium such as paper, and the visual effect is the same when the human visually observes them. The degree of matching can be quantitatively evaluated by the same measuring device such as a colorimeter, and it is relatively easy to realize matching of colors. On the other hand, the CRT color display is a light source color, and when considering the color matching with the above-mentioned surface color by visual observation, the visual effect on human beings is different, and the color of both colors is quantitatively determined. Since there is no measuring instrument for measuring the difference, the current situation is that CMS technology that can withstand practical use has not been developed.

Therefore, a mutual conversion method is proposed which enables mutual conversion between the light emission control signal of the light source color displayed on the CRT color display screen and the tristimulus value of the object color in the actual CRT color display and the object color observation system. (Japanese Patent Application Laid-Open No. 2222523 “Mutual conversion method of emission control signal of CRT color display and CIE tristimulus value of object color”). In the present invention, the light emission control signals Rc, Gc, Bc of the CRT color display whose tristimulus values X, Y, Z match the known object color are obtained by visual comparison, and the two are compared from the relationship of the following equation. The undetermined coefficient is obtained, and the light emission control signal of the color display and the tristimulus value of the object color are converted.

[0007]

(Equation 3) Where x _R , y _R and z _R are CIE chromaticity coordinates of the red phosphor of the CRT color display, and x _G , y _G and z _G are CRTs.
CIE chromaticity coordinates of the green phosphor of the color display, x
_B , y _B and z _B are CIE chromaticity coordinates of the blue phosphor of the CRT color display, and f ₁ , f ₂ and f ₃ are Rc, Gc and Bc converted into values proportional to the actual light emission brightness of the color display. It represents the function to do (gamma correction).

[0008]

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention
The invention described in Japanese Patent Publication converts the R, G, B emission control signals of the light source color displayed on the screen of the CRT color display into tristimulus values X, Y, Z of the surface color (same as the object color). The method describes that the light emission control signals of the light source colors displayed on the CRT color display screen where the tristimulus values X, Y, and Z are perceived as the same color as the known object color and visual observation are R, G, and B. In this case, the mutual conversion coefficient was calculated from the tristimulus values X, Y and Z and the light emission control signals R, G and B of the light source color.

However, the biggest problem with this method is that
Light emission color control signals R, G, B and tristimulus values X, Y, Z
The point is that the correspondence with is obtained by visual observation. In other words, when a human repeats an experiment in which the color of the light source color is adjusted with respect to the object color and the color is perceived as a uniform color,
It is necessary to make adjustments for three independent color sensations such as saturation, which causes a large individual difference, and also results that cannot be ignored in the same subject. Since the error at this time greatly affects the conversion accuracy, if the conversion coefficient created by a single person is not satisfied by another person,
It is conceivable that the above-mentioned color matching error causes a conversion error for a specific color gamut (particularly gray balance). further,
Since the psychological sensitivity of human beings varies depending on the target color to be color-matched, the above-mentioned error is greatly influenced.

The present invention has been made in view of the above circumstances, and is an emission control signal of a light source color displayed on a CRT color display screen only in an arbitrary observation environment and only by a color matching experiment (adjustment) with respect to brightness. It is an object to present an interconversion system and an interconversion method for R, G, B and a surface color (object color) represented by tristimulus values X, Y, Z.

[0011]

In order to solve the above-mentioned problems, a mutual conversion system of a color display light emission control signal and an object color tristimulus value according to claim 1, wherein an image read by an image reading device is displayed on the color display. An image input system for displaying on the above, or an image output system for outputting a color image produced or modified on a color display by any image output device, or a system combining the image input system and the image output system, A system for displaying on the color display screen a color that is the same as the color of the original image that was read or the image that was output, and the light source that illuminates the reflective original in the observation environment for color comparison. In the above system, which can be regarded as the same as the light source that gives the color value of the signal, the brightness is changed to the brightness. Luminance-lightness conversion means for converting, lightness conversion means for converting lightness to new lightness by linear conversion, lightness-luminance conversion means for converting lightness to luminance, and color display light emission control signal calculated from tristimulus values. A color display light emission control signal calculation means and a tristimulus value calculation means for calculating a tristimulus value from the color display light emission control signal are provided, and the color reflection original and the color original displayed on the color display are visually observed, and both It is characterized in that the conversion coefficient in the above-mentioned lightness conversion means is determined so that the appearances of the colors of A and B match.

Next, a second aspect of the present invention is a mutual conversion method used in the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to the first aspect, in which the brightness information and the color of the output image are held. The subject is to present an optimum mutual conversion method with the brightness information of the image displayed on the display.

In order to solve this problem, the mutual conversion method of the color display light emission control signal and the object color tristimulus value according to claim 2 is an image input system for displaying an image read by an image reading device on a color display. ,
Alternatively, an image output system for outputting a color image produced or modified on a color display by an arbitrary image output device, or a system combining the image input system and the image output system, and a standard signal exchanged between the devices. Is a system that uses tristimulus values or color values that can be converted into tristimulus values, and displays a light source color that is the same as the object color of the read original image or output image on a color display screen. In the system, in the color display, the relationship between the color display light emission control signals Rc, Gc, Bc and the tristimulus values X, Y, Z of the light source color to be emitted at that time is known by the following equation (1), In the observation environment where color comparison is performed, the light source that illuminates the object color is the same as the measurement light source of the standard signal that is the color value. System, tristimulus values X, Y, Z
Is prepared, the Y representing the luminance among the tristimulus values of the color reflection original is converted into the lightness L by the following formula (2), and the lightness L is calculated by the following formula using constants α and β. The lightness L ′ is converted to a new lightness L ′ by (3), the lightness L ′ is converted to a luminance Y ′ by the formula (4), and the converted tristimulus value X,
The color display emission control signals Rc, Gc, Bc are calculated from the relationship between Y ', Z and the following equation (1), and when the color original is displayed on the color display screen, the visual observations should be consistent. Is a constant α of the following equation (3),
β is determined, and by using the determined α and β, the mutual conversion between the tristimulus values X, Y and Z of the arbitrary color original and the color display emission control signals Rc, Gc and Bc is calculated from the following formula (1). It is characterized by performing using (4).

[0014]

[Equation 4] Where x _R , y _R , z _R are the CIE chromaticity coordinates of the red phosphor of the color display, x _G , y _G , z _G are the CIE chromaticity coordinates of the green phosphor of the color display, x _B , y _B , z _B
Is the CIE chromaticity coordinate of the blue phosphor of the color display,
f ₁ , f ₂ , and f ₃ represent functions (gamma correction) for converting Rc, Gc, and Bc into values proportional to the actual light emission luminance of the color display.

[0015]

(Equation 5) However, Yn is the tristimulus value Y of the perfect diffuse reflection surface, and
α and β are constants.

According to the first and second aspects of the present invention, the mutual conversion between the color display emission control signal and the object color tristimulus value can be performed more easily than in the method described in JP-A-2-22523 by adjusting only the lightness axis direction. Although it is possible, there are still two parameters for the adjustment, and in order to further reduce the burden on the user, we would like to further reduce the adjustment parameter.

In order to solve this problem, the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 3 is the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 1. A mutual conversion system using the color display emission control signal and the object color tristimulus value mutual conversion method according to claim 2, wherein the coefficient β is used in the correction formula for the lightness represented by the formula (3). It is characterized in that the value of is a constant value determined by the document type.

According to the first, second and third aspects of the present invention, at least one of the lightness conversion parameters must be determined by a human being by visual observation, which is a complicated task for the user.

In order to solve this problem, the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 4 is the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 1. A mutual conversion system using the mutual conversion method of a color display light emission control signal and an object color tristimulus value according to claim 2, wherein the illuminance of an observation environment for performing color comparison between a reflective original and a color display is measured. The illuminance measuring means and the luminosity conversion coefficient determining means for deciding the luminosity conversion coefficient from the obtained illuminance of the observation environment are provided.

The invention according to claims 1, 2 and 3 is limited to the case where the measurement light source for the tristimulus value of the object color and the illumination light source in the observation environment are the same, but actually, in various observation environments. In most cases, color comparison is performed between the color display and the object color, which is not possible.

In order to solve this problem, the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 5 is the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 1. A mutual conversion system using the mutual conversion method of a color display light emission control signal and an object color tristimulus value according to claim 2, wherein the reflective original is in an observation environment for color comparison between the reflective original and the color display. When the light source for illuminating and the light source representing the color value of the color display emission control signal are different, and the chromaticity point information of the both light sources is known, from the chromaticity point information of the both light sources, the color value due to the illumination light shift It is characterized in that it is provided with an illumination light shift calculation means for mutually calculating the change of.

According to a fifth aspect of the present invention, the chromaticity point change due to the illumination light shift is obtained only between the light source for measuring the tristimulus value of the object color and the limited light source whose illumination light source in the observation environment is known. However, it is necessary to supplement or substitute a light source close to the actual light source for other light sources, and the versatility was limited.

In order to solve this problem, a mutual conversion system of a color display light emission control signal and an object color tristimulus value according to a sixth aspect of the invention is provided. A mutual conversion system using the mutual conversion method of a color display light emission control signal and an object color tristimulus value according to claim 2, wherein the reflective original is in an observation environment for color comparison between the reflective original and the color display. When the light source for illuminating and the light source representing the color value of the color display emission control signal are different, and the chromaticity point information of the both light sources is known, from the chromaticity point information of the both light sources, the color value due to the illumination light shift It is characterized in that the illumination light shift calculation for mutually calculating the change is performed by the chromatic adaptation prediction formula.

The invention described in claims 5 and 6 is limited to the case where the measurement light source for the tristimulus value of the object color and the illumination light source in the observation environment are known. However, many users do not know the light source type of the observation environment, and this has significantly narrowed the range of use of the invention.

In order to solve this problem, the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 7 is the color display light emission control signal and the object color tristimulus value according to claim 5 or 6. In the mutual conversion system of stimulus values, the chromaticity point of the light source that illuminates the object color in an observation environment in which the color of the light source displayed on the color display screen is compared with the color original document which is the object color. And a chromaticity point measuring means of a light source for transmitting the chromaticity point information to the system as an electric signal.

As described above, when the change in the illumination light source of the environment is read by the sensor and the correction is automatically performed, the user does not notice the change in the environment until the correction becomes impossible. For example, if the chromaticity changes due to deterioration of the light source, it will not be noticed until the light source is turned off. In this way, if you do not let the user notice the changes in the environment,
Inconvenience may occur in some cases.

In order to solve this problem, the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 8 is the color display light emission control signal and the object color tristimulus value according to claim 5 or 6. In the mutual conversion system of stimulus values, the chromaticity point of the environment is already set from the chromaticity point information obtained by the chromaticity point measuring means for measuring the chromaticity point of the illumination light source of the observation environment according to claim 7. The present invention is characterized in that a warning is issued to the user when the difference between the chromaticity point and the color difference caused by the change in the chromaticity point of the light source of the specific color viewed under the observation environment exceeds a certain value.

As described above, the sensor for measuring the chromaticity point of the light source in the environment is expensive because of the spectroscopic analysis, and the system is expensive after all.

In order to solve this problem, the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 9 is the color display light emission control signal and the object color tristimulus value according to claim 5 or 6. In the mutual conversion system of stimulus values, in a viewing environment for color comparison between a reflective original and a color display, the light source for illuminating the reflective original and the light source representing the color value of the color display emission control signal are different, and When the chromaticity point information of the light source is unknown, the chromaticity point information storage / holding means for holding the chromaticity point information for a plurality of light sources, and the color for selecting any chromaticity point information from the chromaticity point information storage / holding means Degree point information selection means and illumination light shift calculation for converting the color value of the color display emission control signal into a color value under the light source having the selected chromaticity point information. It is characterized in that provided with the stage.

As described above, in order for the user to search the memory for the one close to the chromaticity point of the current environmental light source, trial and error are inevitably required, which is inefficient and burdens the user. .

In order to solve this problem, the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 10 is the color display light emission control signal and the object color tristimulus value according to claim 5 or 6. In the mutual conversion system of stimulus values, a reflection original made of at least one color, a color display emission control signal having color information when the reflection original is placed under a known light source, and a plurality of light sources are provided. Light source setting means for setting, illumination light shift calculation means for converting the color display light emission control signal into a color under the light source set by the light source setting means, and a plurality of colors converted under different light sources A plurality of image side-by-side display means for displaying images side by side in a color display, the reflective original document placed under an observation environment,
It is possible to obtain the chromaticity point information of the environmental light source by visually comparing the colors of multiple images that have been converted into colors under different light sources displayed side by side and determining the image with the closest color. It is a feature.

[0032]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the inventions of claims 1 and 2,
When the light emission control signals of a color display (CRT color monitor, etc.) are Rc, Gc, and Bc, the light source colors displayed on the screen are not affected by the luminous flux from the surroundings and the background (for example, in the dark. Emission control of the color display by determining the undetermined coefficients K _R , K _G , and K _B in the following formula (1) from the tristimulus values X, Y, and Z obtained by measuring the color with a monitor An interconversion formula between the signals Rc, Gc, Bc and the tristimulus values X, Y, Z of the light source color displayed on the screen is obtained in advance.

[0033]

(Equation 6) Where x _R , y _R , z _R are the CIE chromaticity coordinates of the red phosphor of the color display, x _G , y _G , z _G are the CIE chromaticity coordinates of the green phosphor of the color display, x _B , y _B , z _B
Is the CIE chromaticity coordinate of the blue phosphor of the color display,
f ₁ , f ₂ , and f ₃ represent functions (gamma correction) for converting Rc, Gc, and Bc into values proportional to the actual light emission luminance of the color display.

Tristimulus value X in the same light source as the observation environment,
A color manuscript 2 (Y and Z are known) and is composed of a plurality of color patches (a constitution example of the color manuscript is shown in FIG. 2) is set in a state in which an object color is compared with an ordinary color display, and the mutual conversion formula (1 ) Is used to calculate and display the light emission control signals Rc, Gc, Bc for displaying the tristimulus values of the color original on the color display screen. At this time, as a method of installing the surface color, as shown in FIG. 1, the screen of the color display 1 and the color original 2 placed on the original table 4 are placed adjacent to each other so that they are located in the same plane, and ,
A partition 5 is provided between the color display 1 and the color original 2.
It is most preferable that the light source 3 for illuminating the observation environment illuminates only the color original 2 and does not illuminate the color display screen, and the background color of the color original 2 is achromatic. By reproducing the color original 2 including the background color on the color display screen, it is possible to reduce the influence on the appearance of the color due to the difference in the background color, but the present invention is not limited to this. Absent.

Here, the tristimulus values of the known object color are:
Y value of tristimulus value (= Y for a virtual perfect diffuse reflection surface measured in accordance with JIS Z8722 of Japanese Industrial Standards)
n) is a dimensionless quantity standardized to be 100,
Further, since the tristimulus value handled by the above mutual conversion formula is a photometric amount, the object color and the color reproduced on the color display screen do not match as they are.

Therefore, in the mutual conversion system of the present invention, Y of the tristimulus value of the object color is converted into the lightness L using the following formula (2), and the conversion of the following formula (3) is performed for the lightness L. Then, the tristimulus value Y ′ is calculated using the following formula (4), and the tristimulus values X, Y ′, and Z of the color original document obtained are used to calculate the mutual conversion formula (1). Display on the color display 1. At this time, the observer 6 adjusts the undetermined coefficients α and β in the equation (3) so that the light source color on the screen of the color display 1 and the object color of the color original 2 match each other in color perception by visual observation. decide. This allows
Mutual conversion between the tristimulus values X, Y, Z of the object color and the emission control signals Rc, Gc, Bc of the color display is possible.
An example of the configuration of the mutual conversion system of the present invention is shown in FIG.

[0037]

(Equation 7) However, Yn is the tristimulus value Y of the perfect diffuse reflection surface, and
α and β are constants.

The above is the structure and operation of the inventions of claims 1 and 2, which are based on the following experimental results. That is, in the environment in which the chromaticity points of the light source of the observation environment and the light source for color measurement of the above-mentioned color original are equal, the test subject was made to reproduce the color that looks the same as each color patch in the color original on the color display. Moreover, the experiment was repeated while changing the brightness of the light source for illuminating the color original. FIG. 3 shows the result. The abscissa of the graph of FIG. 3 is obtained by converting Y of the tristimulus value of the object color into the lightness by the equation (2), and the ordinate is calculated from the light emission control signal of the color display in which the subject has the same color as the object color. The tristimulus values X, Y, and Z of the light source color of the color display screen are the white tristimulus when the emission control signals Rc, Gc, and Bc of the color display are the maximum values (255 when the control signal is 0 to 255). Value X
₀ , Y ₀ , Z ₀ are used to convert the brightness value by using Y ₀ instead of Y n in the equation (2). As can be seen from FIG. 3, the lightness value calculated by the above method for the light source color that is linearly related to each other and has the lightness value L = 20 is almost 0, and the slope of the straight line is the color patch. It can be seen that it varies depending on the brightness of the light source that illuminates (i.e., ambient illuminance). Further, although not shown in the figure, when the light source color and the surface color have the same characteristics for a and b of the CIELab uniform color space, they are in good agreement. Therefore, FIG.
The appearances of the light source color and the object color can be made to match by performing the correction described in the first and second aspects of the invention only on the lightness L shown in FIG.

Regarding the invention of claim 1, formula (2)
Not limited to (4) to (4), some relational expression is used as a means for converting the luminance Y and the lightness L. In the invention of claim 2, the luminance Y
And the lightness L are converted using equations (2) to (4). The formula (2) is a brightness-brightness conversion formula recommended by the International Commission on Illumination (CIE).

Next, the invention of claim 3 will be described. In the inventions of claims 1 and 2, the correction term β corresponding to the intercept with the horizontal axis of FIG. 3 corresponds to the minimum lightness in the image of the object color in the case of the document surface illuminance of 600 and 900 lux. Also,
When the illuminance on the document surface is as high as 1900 lux, the black in the image looks like whitish.
In this case, the lightness value of the color display corresponding to black of the object color image takes a value other than zero. However, this value of 1900 lux is so bright that it rarely exists in a normal office environment.

According to a third aspect of the present invention, the illuminance of the original surface is 400 to 90.
This is particularly effective for a normal lighting environment of 0 lux. That is, the minimum lightness of the target image to be matched with the color display is set in advance by measurement or the like, and this is replaced with the correction coefficient β in the inventions of claims 1 and 2. As a result, by determining only the coefficient α in the equation (3), the tristimulus values XYZ of the object color and the color display emission control signal RGB can be obtained as in the inventions of claims 1 and 2.
Mutual conversion with (Rc, Gc, Bc described above) can be performed. That is, since the degree of freedom of adjustment is reduced, the same effect can be obtained more easily than the inventions of claims 1 and 2. The minimum brightness of the target image referred to here is the minimum brightness reproduced by the image forming method depending on the image forming method such as photography, printing, and electrophotography. For example,
The density of black in a photograph is about 2.0, and the density of an electrophotographic photograph is about 1.5, and the lightness also varies accordingly.

Next, the invention of claim 4 will be described. As can be seen from FIG. 3, the inclination is large depending on the illuminance of the observation environment (original surface illuminance). This inclination is the lightness conversion coefficient α itself, and the lightness conversion coefficient α can be obtained as a function of the observation environment. Therefore, in the mutual conversion system according to claim 4, an illuminance measuring means (sensor or the like) for measuring the illuminance of the observation environment is installed near the color display and the original, and the brightness conversion coefficient determining means calculates from the measured illuminance or by a table. The lightness conversion coefficient α is determined. An example of the configuration of the mutual conversion system of the present invention is shown in FIG.

Next, the invention of claim 5 will be described. The inventions of claims 1 and 2 relate to the case where the chromaticity point of the illumination light source in the object color observation environment is the same as the chromaticity point of the light source representing the color value of the standard signal. However, it is not practical in practice to always make the color comparison environment of the light source color and the object color match the standard light source (for example, D50, D65, C light source, etc.) that is often used in the measurement of the object color. Therefore, the present invention is
When the tristimulus value of the object color measured under the light source representing the color value of the standard signal and the illumination light source in the object color observation environment are different, a light source color that is the same color as the object color is displayed under the light source. A system for performing mutual conversion with a color display light emission control signal is presented, and a configuration example thereof is shown in FIG.

For the change of the chromaticity point when the illumination light source changes (hereinafter referred to as illumination light shift), a conversion formula can be obtained if the light sources before and after the shift are known in advance. FIG.
In the 0 system, it is difficult in practice to obtain a prediction formula of chromaticity change due to illumination light transition between illumination light sources in all observation environments, so a typical light source such as that presented by CIE or the like is used. A prediction formula for chromaticity change due to illumination light shift between is calculated, and in practice, a chromaticity point conversion is performed by selecting a combination that is closest to the actual combination. Then, after the chromaticity point conversion is performed and the chromaticity point under the same light source is obtained, the same conversion as in claims 1 to 4 is performed.

Next, the invention of claim 6 will be described. As a method of predicting what kind of tristimulus value (a human being) the object color placed under a certain light source looks like under different light sources, von Kries' chromatic adaptation prediction formula,
There are chromatic adaptation prediction formulas (also called CIE chromatic adaptation prediction formulas) by Naya et al. (See Noboru Ohta, "Color Optics", published by Tokyo Denki University Press, pages 186-191). Therefore, in the present invention, the tristimulus value of the object color (that is, the color original document described above) measured under the standard light source is converted into the corresponding tristimulus value by the light source of the observation environment by using the above-mentioned chromatic adaptation prediction formula, By obtaining the conversion coefficients α and β on the lightness axis by the method according to the inventions of claims 1 to 4, mutual conversion between the color display light emission control signal RGB and the tristimulus values XYZ of the object color is performed. It should be noted that an example of the configuration of the mutual conversion system of the present invention is shown in FIG.
It is shown in FIG.

Next, the invention of claim 7 will be described. In the inventions of claims 5 and 6, the chromaticity point of the light source under the environment for observing the object color is known. However, it is difficult for the system user to manage the chromaticity point of the light source in the color comparison environment and obtain the chromaticity point in advance in an actual usage situation. Therefore, the present invention is provided with a device (illuminating light chromaticity point measuring instrument or the like) for measuring the chromaticity point of the light source of the observation environment for performing the color comparison in the mutual conversion system shown in FIG. 10 or FIG. Alternatively, the chromaticity point is measured at the time of request, and the CIE tristimulus value of the color original measured by the colorimeter is used to determine the color in the observation environment by using, for example, the color adaptation prediction formula described in the invention of claim 6. The tristimulus value corresponding to the appearance is converted, and the light emission control signal of the color display and the CIE tristimulus value of the object color are mutually converted using the same method as described in the first and second aspects of the invention.

The chromaticity point measuring device of the observation environment light source disperses the luminous flux from the environment light source, for example, a spectroscopic means such as a grating or a bandpass filter for dividing visible light into a plurality of stages, and the spectroscopic spectral light. A device that obtains tristimulus values from the spectral distribution of the light source by combining photoelectric conversion elements that detect light may be used, or the tristimulus values XYZ can be directly obtained by a filter and a photoelectric conversion element that correspond to the color matching function of the CIEXYZ color system. It may be a device that obtains an electric signal corresponding to. Although the present invention does not limit the method for obtaining the chromaticity point, the measuring instrument provides the system with information on the chromaticity point as an electric signal.

Next, the invention of claim 8 will be described. In reality, it is often the case that the environment changes due to deterioration of the light source in the observation environment or replacement of the light source. In the invention of claim 7, the apparatus for measuring the chromaticity point of the environment installed in the system detects the change of the chromaticity point of the environment, and when the change of the chromaticity point of a certain value or more occurs, This is to warn the user. This allows the user to change the chromaticity point of the environment already set in the system to the newly measured one, or
Alternatively, it is possible to select whether to remove the cause of the change in chromaticity point. The degree of change in the chromaticity point to be warned is set according to the degree of accuracy required by the user. The setting value is
The specified color on the color display obtained from the color when a specific color is displayed on the color display using the chromaticity point of the environmental light source already set in the system and the chromaticity point of the newly measured light source By managing with the color difference value with the color, it is possible to manage with a constant value without depending on the type of the specific color to be managed or the color temperature of the light source. As for the colors to be managed, for example, when it is desired to manage in consideration of the influence on the entire color space, it is said that the visual sensitivity characteristic is the most severe with respect to the change in color, and all the color components are included. An achromatic color seems to be suitable, but if the appearance of a specific color (for example, skin color) does not have to be influenced by the surrounding environment depending on the work, it may be managed by the target color. However, the present invention does not limit the colors to be managed.

Next, the invention of claim 9 will be described. According to the present invention of claim 7, the chromaticity point of the light source in the observation environment is measured without using a device for measuring the chromaticity point of the light source in the observation environment and transmitting the chromaticity point information of the light source to the system as an electric signal. By setting close chromaticity points, it is possible to perform mutual conversion between the color display emission control signal and the tristimulus value of the object color as in the invention of claim 7. As described in the above description of claim 5, if the chromaticity point information of the light source of the observation environment and the light source that represents the color value of the image data is known, the change of the chromaticity point due to the change of the light source is obtained. Is possible. Regarding the chromaticity point information of the light source that represents the color value that the image data has, information has come to be provided as standard, but for the observation environment, usually use a light source whose chromaticity point is known,
It is practically difficult for many users to know the chromaticity point of the light source of the environment by only measuring or measuring.

A reflection original and image data for displaying the reflection original on a color display are prepared, and both are set in a comparable state (see FIG. 1). The user claims claim 5.
As described above, the above-described image data is converted into a color under the selected light source by using the prediction formula of the chromaticity change due to the illumination light transition between the typical light sources. further,
The brightness conversion coefficient is determined by the method according to claims 1 to 4, and the final image is displayed on the color display. The user repeats such work for multiple chromaticity change prediction formulas prepared in advance, and the one in which the color appearance of the image reflected on the display and the image displayed on the display are the same is used as the observation light source and the lightness conversion coefficient at that time. Set. Such setting may be performed once at the initial setting of the system unless there is a large change in the environment, and an expensive measuring device such as that of the invention of claim 7 is unnecessary. It should be noted that the same operation can be performed by using the chromatic adaptation prediction formula as in the invention of claim 6.

Next, the invention of claim 10 will be described.
The present invention is different from the invention of claim 9, but like the invention of claim 9, some representative chromaticity change prediction formulas of the light source are held in advance, and the reflection original and the reflection original are colored. Prepare the image data to be displayed on the display and set them so that they can be compared. Then, a plurality of images converted into colors when the reflection original is viewed under different light sources are displayed side by side on the color display screen. FIG. 4 is a diagram showing a display example in the color display screen,
This is an example in which eight color originals 2a to 2h having the same color as the object color are displayed under different observation environment light sources. If a color original cannot be presented for all of the previously held chromaticity change prediction formulas within one screen, it is displayed over multiple screens. After setting the lightness conversion coefficient, the user selects the color originals displayed in parallel on the color display screen which appear to be the closest in color to the color appearances of the color originals under the actual observation environment. By doing so, the observation light source and the brightness conversion coefficient at that time are set.

[0052]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, an embodiment of a mutual conversion system of a color display light emission control signal and an object color tristimulus value according to the present invention will be described.

FIG. 5 is a diagram showing an embodiment of the present invention, and is a block diagram showing an example of the construction of a mutual conversion system having a brightness conversion coefficient setting means and a data flow. Hereinafter, a method of setting the lightness conversion coefficient will be described. (1) First, the brightness conversion coefficient setting image is set at a position where an observer performs color comparison with a normal color display (see FIG. 1). (2) Convert the data of the brightness conversion coefficient setting image into RGB (or XYZ or Lab). In the example of FIG. 5, the image data is in the RGB format. When the data of the image to be stored is XYZ, the “RGB → XYZ conversion means” is unnecessary, and when the data is Lab, the “RGB → XYZ conversion means” and the “brightness-brightness conversion means” are unnecessary. (3) The brightness conversion means performs a predetermined conversion using an arbitrary initial value stored in the brightness conversion coefficient storage device at the start of setting the brightness conversion coefficient. (4) The value in the brightness conversion coefficient storage device is rewritten by the brightness conversion coefficient setting device at any time, and the brightness conversion device reads the coefficient value from the brightness conversion coefficient storage device at any time and performs a predetermined conversion. An image with different coefficients is displayed on the color display. (5) The brightness conversion coefficient setting image is visually compared with the image displayed on the color display, and the brightness conversion coefficient setting means sets the coefficients α and β so that the two images match or are the most permissible image. Adjust the value.

Next, FIG. 6 is a diagram showing another embodiment of the present invention, which is an example of the construction of a mutual conversion system provided with means for determining the lightness conversion coefficient from the illuminance of the observation environment in claim 4. 3 is a block diagram showing the flow of data. The method of determining the lightness conversion coefficient will be described below. (1) An illuminance or a sensor for performing an output corresponding to the illuminance is installed near the position where the color display is installed, and the A / D-converted sensor output value is input to the brightness conversion coefficient calculation unit of the brightness conversion coefficient determination means. (2) The brightness conversion coefficient calculation unit determines the brightness conversion coefficient using the illuminance data input in (1) above and the maximum brightness value that can be displayed on the color display or a value corresponding to the brightness value. (3) The determined lightness conversion coefficient is stored in the lightness conversion coefficient storage device.

Next, FIG. 7 is a diagram showing another embodiment of the present invention, which is a mutual conversion system of a color display emission control signal and an object color tristimulus value using the brightness conversion in claims 1 to 4. FIG. 3 is a block diagram showing a configuration example and a data flow. The left side of FIG. 7 shows a data flow when an object color is present first and a color that is equal to the object color is reproduced on the color display, and corresponds to FIGS. 5 and 6. The input image data is digitized by means of a scanner or the like. Further, the diagram on the right side shows the flow of data when an image created by a designer or the like on a color display is converted into image data to be output by an existing output machine. The brightness reverse conversion means (circuit) in the right side of FIG. 7 performs the reverse conversion of the brightness conversion means (circuit) on the left side.

Next, FIG. 8 illustrates the data flow in the lightness conversion circuit shown in FIG. The lightness L and the coefficients α and β given from the lightness conversion coefficient storage device are input to the lightness conversion circuit. The conversion is β from the input L value
The brightness conversion is performed by subtracting and multiplying it by α.

Next, FIG. 9 illustrates the data flow in the lightness inverse conversion circuit shown in FIG. To the lightness conversion circuit, the lightness L ', the color values C1 and C2 indicating the tint, and the coefficients α and β provided from the lightness conversion coefficient storage device are input. The conversion is performed by multiplying the input value of L ′ by the reciprocal of α and adding β to this value to perform the lightness conversion.

Next, FIG. 10 is a diagram showing still another embodiment of the present invention, and is a block diagram showing an example of the construction of the mutual conversion system and the flow of data in claims 5 and 7. The flow of the image data conversion processing when the chromaticity point of the illumination light source and the chromaticity point of the light source representing the color value of the image data in the reflection original observation environment are different will be described below. (1) The chromaticity points measured by the illumination light chromaticity point measuring device in the observation environment are A / D converted and input to the illumination light shift calculation parameter determining means. (2) The chromaticity point of the light source, which represents the color value of the input image data, is given in a format such as a file separately from the image data. For example, there is an ICC color profile or the like as a data file that describes color information regarding image data, which is used by many color management software. (3) In the illumination light shift calculation parameter determination means, when the light source set in the input image is changed to the light source in the observation environment based on the chromaticity point information obtained in (1) and (2) above. Determine the coefficients of the polynomial that calculates the colorimetric chromaticity point shift. (4) The types of standard light sources set by the input image data are very limited, and for example, D50, D60, C, A light sources are mainly used. A fluorescent lamp is most commonly used as a general illumination light source, but a standard fluorescent lamp is one of F1 to F12 in CIE.
Two types are defined, and the types of light sources are classified into finite types, which are not so many. Therefore, color values (for example, XYZ, Lab) when the illumination light changes between these light sources.
Etc.) is obtained in advance and the coefficients thereof are stored in the form of a table or the like. If a quadratic polynomial is used as the polynomial for conversion, the average color difference is 1 or less as a conversion error, and sufficient accuracy can be obtained. (5) From the chromaticity point information before and after the conversion inputted in the illumination light shift calculation parameter determining means, the closest one is selected from the already stored light sources, and the calculation parameter in that case is selected as the illumination light shift calculation circuit. Output to. (6) In FIG. 10, the illumination light shift calculation circuit is a tristimulus value X, Y,
Although it is set to convert Z, it may be performed for L, C1 and C2.

Next, FIG. 11 is a diagram showing still another embodiment of the present invention, and is a block diagram showing a constitutional example of the mutual conversion system and data flow in claims 6 and 7. In the system of FIG. 11, the illumination light shift is calculated using the polynomial in FIG. 10, but this is substituted by the chromatic adaptation prediction formula. Chromatic adaptation is that when the illumination light source changes, the human visual characteristics also change and the appearance of colors also changes. The chromatic adaptation prediction formula was developed to predict the color that humans actually perceive as a result of chromatic adaptation. The color difference between the chromaticity point obtained by the colorimetrically determined illumination light shift and the chromaticity point obtained by the color adaptation prediction formula is about 2
It was about. The system of FIG. 11 is inferior in accuracy to the case of using the polynomial shown in FIG. 10, but it is not necessary to obtain conversion parameters in advance, and conversion can be performed only from the chromaticity point information of the light source before and after conversion. Therefore, the system configuration can be simplified and any illumination light can be dealt with. Since the chromatic adaptation prediction formula converts tristimulus values, the chromatic adaptation prediction calculation circuit must be installed at the position shown in the figure.

In each of the mutual conversion systems shown in FIGS. 5 to 11, each of the determining means, the calculating means, and the converting means are composed of a circuit using, for example, a microprocessor unit,
An input device such as a keyboard is applied to the setting means, and a memory such as a well-known RAM or ROM is applied to the storage device. Further, it can be configured by applying a microcomputer system.

[0061]

As described above, in the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 1, the light source showing the color value of the displayed image data and the illumination light source of the observation environment are provided. If they are the same, only the lightness information is converted in the color value information of the image data, and unnecessary conversion to the hue direction is not performed, so that the object color of the displayed image data and the color display are displayed on the color display. The object color included in the displayed image data and the color display light emission control signal can be mutually converted so that the displayed color matches.

According to the mutual conversion method of the color display light emission control signal and the object color tristimulus value described in claim 2, when the measurement light source of the object color (surface color) tristimulus value and the illumination light source of the observation environment are the same, With respect to the lightness information of the color value data of the color, the color image whose tristimulus values X, Y and Z are known by using the correction coefficients α and β and the color image displayed on the color display screen are visually observed. By performing the conversion of the equation (3) that is determined to be color-matched, an arbitrary image represented by the tristimulus value of the object color is displayed on the color display screen that is color-matched in the actual visual observation system. It can be converted into a light emission control signal of a light source color. On the contrary, it is possible to perform mutual conversion from the light emission control signal of the light source color displayed on the color display screen to the object color tristimulus value. Further, by using the method of claim 2 in the mutual conversion system of claim 1 and approximating the lightness conversion by a linear function, the load on the calculation can be minimized. Also, the most effective conversion system can be achieved experimentally.

In the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 3, the tristimulus value X,
The correction coefficient β, which has been determined using Y and Z using a known color image, is set as the lightness value of black determined by the document type, and the only correction coefficient to be determined is α. It is possible to reduce the load of, and it is possible to shorten the time required to determine the coefficient.

In the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to the fourth aspect, since the brightness conversion coefficient is obtained from the illuminance of the environment, the user determines the brightness conversion coefficient. Since the complicated work of is not required, the conversion can be performed without imposing a load on the user.

In the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 5, the illumination light shift prediction means converts the color information of the object color into the color information under the illumination light source of the observation environment. Therefore, even when the measurement light source of the tristimulus value of the object color and the illumination light source of the observation environment are different, the object color of an arbitrary image and the color display screen can be displayed on the color display screen in the same manner as the inventions of claims 1 to 4. The light emission control signal of the displayed light source color can be mutually converted.

In the mutual conversion system of the color display emission control signal and the object color tristimulus value according to claim 6, since the chromatic adaptation prediction formula is used as the illumination light shift prediction means,
Since it is possible to calculate the illumination light transition of a color with an arbitrary chromaticity only from the chromaticity points of the light source before and after the transition, it is not necessary to calculate the illumination light transition prediction formula between various light sources in advance, and the system construction is easy. And the versatility increases.

In the mutual conversion system of the color display emission control signal and the object color tristimulus value according to claim 7, there is provided a device for measuring the chromaticity point of the illumination light source in the observation environment and transmitting it as an electric signal to the system. Therefore, even if the measurement light source of the tristimulus value of the object color and the illumination light source of the observation environment are different, and the chromaticity point of the illumination light source of the observation environment is unknown, Even if the degree point changes, an arbitrary image represented by the object color tristimulus value using the correct chromaticity point of the environmental light source is always displayed on the color display screen that matches colors in the actual visual observation system. Mutual conversion can be performed with high accuracy into light emission control signals of light source colors.

In the mutual conversion system of the color display emission control signal and the object color tristimulus value according to claim 8, a device for measuring the chromaticity point of the illumination light source of the observation environment according to claim 7 and transmitting it to the system as an electric signal. By this, a warning is given when the chromaticity point of the illumination light source in the observation environment changes, so that deterioration of the light source and the influence of reflectors in the observation environment can be detected early, and the observation environment can always be kept constant. .

In the mutual conversion system of the color display emission control signal and the object color tristimulus value according to claim 9, the chromaticity point of the illumination light source of the observation environment which is expensive according to claim 7 is measured and transmitted to the system as an electric signal. Since the chromaticity point of the light source that is similar to the illumination light source in the observation environment can be obtained without installing the device, the effect similar to that of claim 7 can be obtained at low cost.

In the mutual conversion system of the color display light emission control signal and the object color tristimulus value according to claim 10, the colors when the object colors are viewed under different viewing environment light sources are presented in parallel on the color display screen. Therefore, the light source of the actual observation environment can be easily selected without repeating trial and error, so that the burden on the user can be reduced and the efficiency can be improved.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of an example of the present invention, and is a diagram illustrating an installation example of a color comparison environment.

FIG. 2 is a diagram showing a configuration example of a color original for determining correction coefficients α and β.

FIG. 3 is a diagram showing results of color matching experiments.

FIG. 4 is a diagram showing a presentation example in which a plurality of color originals having the same color as an object color are juxtaposed and displayed on a color display under different viewing environment light sources.

5 is a diagram showing an embodiment of the present invention, and is a block diagram showing a configuration example and a data flow of a mutual conversion system including a brightness conversion coefficient setting unit in claim 1. FIG.

FIG. 6 is a diagram showing another embodiment of the present invention, showing a configuration example and a data flow of a mutual conversion system including means for determining a lightness conversion coefficient from illuminance of an observation environment in claim 4; It is a block diagram shown.

FIG. 7 is a diagram showing still another embodiment of the present invention,
It is a block diagram which shows the structural example of the mutual conversion system of the color display light emission control signal and the object color tristimulus value which used the brightness conversion in Claims 1-4, and the flow of data.

8 is a diagram illustrating a data flow in the brightness conversion circuit shown in FIG.

9 is a diagram illustrating a data flow in the lightness inverse conversion circuit shown in FIG. 7.

FIG. 10 is a diagram showing still another embodiment of the present invention, and is a block diagram showing a configuration example of a mutual conversion system and a data flow in claims 5 and 7;

FIG. 11 is a diagram showing still another embodiment of the present invention, and is a block diagram showing a configuration example of a mutual conversion system and a data flow in claims 6 and 7;

[Explanation of symbols]

 1 Color Display 2 Color Document 3 Light Source 4 Platen 5 Partition 6 Observer

Claims (10)

[Claims] 1. An image input system for displaying an image read by an image reading device on a color display,
Alternatively, an image output system for outputting a color image produced or modified on a color display by an arbitrary image output device, or a system combining the image input system and the image output system, and the read original image or A system for displaying on the color display screen a color that is the same as the color of the output image, and a light source for illuminating the reflective original in an observation environment for color comparison, and a light source for giving the color value of the image signal. In the system that can be regarded as the same, a brightness-brightness conversion means for converting brightness to brightness, a brightness conversion means for converting brightness to a new brightness by linear conversion, and a brightness-brightness conversion means for converting brightness to brightness. A color display light emission control signal calculating means for calculating a color display light emission control signal from the tristimulus values; A tristimulus value calculating means for calculating a tristimulus value from the color display light emission control signal, and visually observing the color reflection original document and the color original document displayed on the color display so that the color appearances of the two may match. A mutual conversion system of a color display light emission control signal and an object color tristimulus value, characterized in that a conversion coefficient in the brightness conversion means is determined. 2. An interconversion method used in an interconversion system of a color display emission control signal and an object color tristimulus value according to claim 1, wherein an image read by an image reading device is displayed on a color display. An input system, or an image output system for outputting a color image created or modified on a color display by an arbitrary image output device, or a system combining the image input system and the image output system, which is exchanged between the devices. In the above system, which uses tristimulus values or color values convertible to tristimulus values as a standard signal, a light source color that is the same as the object color of the read original image or output image is displayed on the color display screen. In the system for displaying on a color display, the color display is a color display emission control. The relationship between the control signals Rc, Gc, Bc and the tristimulus values X, Y, Z of the light source color that is emitted at that time is known from the following formula (1), and the object color in the observation environment for color comparison is In the system in which the light source for illuminating is the same as the measurement light source for the standard signal having the color value, a color original having known tristimulus values X, Y, Z is prepared, and the luminance among the tristimulus values of the color reflection original is set. Is converted into a lightness L by the following formula (2), and the lightness L is converted into a new lightness L ′ by the following formula (3) using the constants α and β.
The lightness L'is converted into the luminance Y'by the formula (4), and the color display emission control signals Rc, Gc, Bc are calculated from the relationship between the converted tristimulus values X, Y ', Z and the following formula (1). Then, when the color original is displayed on the color display screen, the constants α and β of the following formula (3) are determined so that the visual observations match, and the determined α and β are arbitrarily used. Mutual conversion between the tristimulus values X, Y, Z of the color original document and the color display light emission control signals Rc, Gc, Bc is performed using the following formulas (1) to (4). Mutual conversion method between control signal and tristimulus value of object color. [Equation 1] However, x _R , y _R , and z _R are C of the red phosphor of the color display.
IE chromaticity coordinates, x _G , y _G , and z _G are C of the green phosphor of the color display.
IE chromaticity coordinates, x _B , y _B , z _B are C of the blue phosphor of the color display
The IE chromaticity coordinates, f ₁ , f ₂ , and f ₃ represent functions (gamma correction) for converting Rc, Gc, and Bc into values proportional to the actual light emission luminance of the color display. [Equation 2] However, Yn is the tristimulus value Y of the perfect diffuse reflection surface, and
α and β are constants. 3. A mutual conversion system for a color display light emission control signal and an object color tristimulus value according to claim 1, which uses the mutual conversion method for a color display light emission control signal and an object color tristimulus value. In the above mutual conversion system, the value of the coefficient β in the correction formula for the lightness represented by the above formula (3) is set to a constant value determined by the document type, and the color display light emission control signal and the object color tristimulus are characterized. Mutual conversion system of values. 4. A mutual conversion system of a color display light emission control signal and an object color tristimulus value according to claim 1, which uses the mutual conversion method of a color display light emission control signal and an object color tristimulus value. In the mutual conversion system, the illuminance measuring means for measuring the illuminance of the observing environment for color comparison between the reflective original and the color display and the luminosity converting coefficient determining means for deciding the luminosity converting coefficient from the obtained illuminance of the observing environment are provided. Mutual conversion system of characteristic color display emission control signal and tristimulus value of object color. 5. A mutual conversion system of a color display light emission control signal and an object color tristimulus value according to claim 1, which uses the mutual conversion method of a color display light emission control signal and an object color tristimulus value. In the mutual conversion system, the light source that illuminates the reflective original and the light source that represents the color value of the color display emission control signal are different in the observation environment in which the color of the reflective original and the color display are compared, and the chromaticity points of both light sources are different. When the information is known, a color display light emission control signal and an object are provided, which are provided with an illumination light shift calculation means for mutually calculating the change in color value due to the illumination light shift from the chromaticity point information of the both light sources. Mutual conversion system of color tristimulus values. 6. A mutual conversion system of a color display light emission control signal and an object color tristimulus value according to claim 1, which uses the mutual conversion method of a color display light emission control signal and an object color tristimulus value. In the mutual conversion system, the light source that illuminates the reflective original and the light source that represents the color value of the color display emission control signal are different in the observation environment in which the color of the reflective original and the color display are compared, and the chromaticity points of both light sources are different. When the information is known, an illumination light shift calculation for mutually calculating a change in the color value due to the illumination light shift is performed from the chromaticity point information of the both light sources by a color adaptation prediction formula. Mutual conversion system of emission control signal and tristimulus value of object color. 7. The mutual conversion system of the color display emission control signal and the object color tristimulus value according to claim 5 or 6, wherein the color original document is a light source color and an object color displayed on a color display screen. In an observation environment for performing a color comparison with, measuring the chromaticity point of a light source that illuminates the object color,
A mutual conversion system of a color display light emission control signal and an object color tristimulus value, comprising a chromaticity point measuring means of a light source for transmitting the chromaticity point information to the system as an electric signal. 8. A chromaticity for measuring a chromaticity point of an illumination light source in an observation environment according to claim 7 in the mutual conversion system of the color display emission control signal and the object color tristimulus value according to claim 5 or 6. From the chromaticity point information obtained by the point measuring means, it is caused by the difference between the chromaticity point of the environment and the already set chromaticity point, or the chromaticity point change of the light source of the specific color seen under the observation environment. A mutual conversion system between a color display light emission control signal and an object color tristimulus value, which is configured to issue a warning to a user when the color difference exceeds a certain value. 9. The mutual conversion system of the color display emission control signal and the object color tristimulus value according to claim 5 or 6, wherein the reflective original is placed in an observation environment for color comparison between the reflective original and the color display. When the illuminating light source and the light source representing the color value of the color display emission control signal are different and the chromaticity point information of the light source in the observation environment is unknown, the chromaticity point information holding the chromaticity point information for a plurality of light sources The memory holding means, the chromaticity point information selecting means for selecting arbitrary chromaticity point information from the chromaticity point information storing and holding means, and the color value of the color display emission control signal have the selected chromaticity point information. An interconversion system of a color display emission control signal and an object color tristimulus value, comprising illumination light shift calculation means for converting into a color value under a light source. 10. The mutual conversion system of the color display emission control signal and the object color tristimulus value according to claim 5 or 6, wherein a reflective original made of at least one color and a reflective light source of a known light source are used. Color display light emission control signal having color information when placed below, light source setting means for setting a plurality of light sources, and color display light emission control signal to a color under the light source set by the light source setting means Illuminating light shift calculation means for converting the above, and a plurality of image juxtaposition display means for juxtaposing and displaying a plurality of images converted into colors under different light sources in a color display, and the reflection placed under an observation environment. By visually comparing the colors of the original and multiple images converted to colors under different light sources displayed side by side, and determining the image with the closest color ,
A mutual conversion system between a color display emission control signal and an object color tristimulus value, which is characterized by obtaining chromaticity point information of a light source of the environment.