JPH08321959A - Color correction method for color image signal - Google Patents

Abstract

PURPOSE: To confirm color reproduction in advance by pseudo-reproducing a color obtained by a 1st system in the environmental condition set to convert a color signal of a 2nd system on the basis of the environmental condition and the cross reference. CONSTITUTION: A measurement value in each environmental condition of a printer 3 and a measured value of a color printer 2 are used to obtain a color difference between both the measured values. In this case, the cross reference between a density of the printer 3 and a density of the printer 2 are obtained to generate lookup tables a-n on the cross reference. The lookup tables a-n are generated by a computer 1 and transferred to a color correction device 5 of the printer 2, in which the lookup tables a-n are used for simulating the print. The device 5 references the lookup tables a-n under the designated environment condition. The printer 2 references the lookup tables a-n under the designated environmental condition to read a density to display a coloring of the printer 3 corresponding to the environmental condition. Thus, the user recognizes how the hue is printed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color correction method for color image signals, and more particularly to different color reproducing means (printing machine, thermal transfer printer, etc.) when forming a color image from color signals of digital data. The present invention relates to a color correction method of a color image signal for correcting the colors reproduced by the same color.

[0002]

2. Description of the Related Art In recent years, with the development of computers, a technique of printing images based on color image signals provided by creating or allocating images on the computer has become widespread. Generally, each pixel of color image information supplied from a computer for printing is defined by three primary colors of C (cyan), M (magenta), and Y (yellow), and density values of four color components of K (black). Expressed.

However, even if printing is performed on the basis of exactly the same color image information given from the computer, printing conditions such as ink colors corresponding to each of C, M, Y and K colors used in the printing machine vary. Therefore, the same color is not always reproduced. In particular, proofs are sublimated by thermal transfer (su
When a color printer that performs blimation transfer) is used, the color of the hard copy obtained by the color printer based on the CMYK data is not the color of the printed matter printed by the printing machine based on the same CMYK data. Generally does not match. Therefore, normally, hard copy or printing is performed after color correction is performed on the CMYK data provided from the computer.

As a general method for performing such color correction, there is a color correction method using a primary masking equation. In this color correction, for example, the temperature value data before correction, which is a normal color separation signal, that is, the color signal of the first method is substituted into a well-known masking equation, Neugebauer equation, or the like, and this equation is calculated. As a result, the corrected temperature value data, that is, the color signal of the second equation is converted and color correction is performed.

Further, as a method for further reducing the error of color correction using the above-mentioned first-order masking equation, the applicant of the present invention has improved the ordinary second-order masking equation, and disclosed in Japanese Patent Laid-Open No.
The invention described in No. 4-12382 was made. This method
The present invention relates to a color correction device that separates a color signal of a first method into a quaternary color component by a predetermined conversion, corrects each component individually, and then combines the components to perform color correction.

Furthermore, the applicant of the present application, as a method of correcting the difference in color reproduction between different color reproduction systems for the entire color space, a color chart (color chart) capable of expressing the entire color reproduction range of each color reproduction system. Was used (Japanese Patent Laid-Open Nos. 1-234251 and 2-214266.
issue).

According to Japanese Patent Laid-Open No. 2-214266, first, a large number of color targets corresponding to the data of each method are created so that the color gamut of each color reproducing method can be expressed over the entire area. Next, this color chart is measured to form a color space for each method. When the color space of one method is narrower than the color space of the other method, the narrower color space is reproduced as a signal that can be reproduced with a signal exceeding the limit that can be reproduced by the method that formed this color space, To expand the color space. Then, the correspondence relationship of the data that associates the measurement values in each color space is obtained, the color signal of the first method is converted based on this correspondence relationship, and the color reproduced by the second method is the desired color. That is.

According to this prior invention, the difference in color reproduction by different systems is corrected over the entire color space.
The color reproduced by the second method can be a desired color, and even when one color space is narrower than the other color space, the reproduced color does not become light and both reproduced colors are reproduced. The effect of being able to surely match is obtained.

[0009]

However, in the color reproduction method of a printing machine or the like, adjustment is made so that the best image quality can be obtained under a certain standard environmental condition. There was a problem that would fluctuate significantly. Environmental conditions that change the color reproduction may include temperature, humidity, ink type, paper type, printing machine condition, and machine-to-machine characteristic difference.

In order to prevent this variation, as in the above-mentioned conventional technique, a color reproduced by a color reproduction system of a printing machine or the like is simulated by another color reproduction system. However, since these simulations are performed under constant environmental conditions, accurate color comparison may not be possible in some cases.

Further, even if it is known that the printing machine has different environmental conditions from the standard environmental conditions, it is necessary to make a plate once, make a plate, and mount the plate on the printing machine to try printing. is there. When the printing result is different from the expected color, environmental conditions such as temperature and humidity are measured, the condition of the printing machine is adjusted based on the measurement result, and plate making is performed again. For this reason, the same work is repeated until the expected print result is obtained, resulting in a lot of waste from the viewpoint of time and labor.

Therefore, the present invention has been made to solve the above conventional problems. That is, a first object of the present invention is to artificially reproduce a color change caused by a change in environmental conditions in one color reproduction method in another color reproduction method.

A second object of the present invention is to automatically correct color fluctuations due to changes in environmental conditions.

[0014]

FIG. 1 is a diagram showing the principle of the present invention. The color correction method for a color image signal according to claim 1 is for adjusting colors reproduced by a plurality of different color reproduction systems (2, 3, etc.) when forming a color image from a color signal of digital data. In the color correction method of the color image signal, the color reproduction method is the first method (for example, a printing machine) in which the reproduced color changes due to changes in environmental conditions.
3 is the color code CC (a, b, ..., N) capable of expressing the color gamut of the first method over the entire area,
A plurality of color density values for appropriately expressing the color of the method are created for each of a plurality of different environmental conditions, and the color reproduction method does not change the reproduced color due to the change of the environmental condition. Method (for example, a thermal transfer color printer) 2 is a color code CC (p) capable of expressing the color gamut of the second method over the entire area, and the density for expressing the color of the second method. Create a plurality of values that are appropriately changed, measure each created color code CC under the same measurement conditions, form a color space for each color code based on the measurement result, and set the color space in the second method. The correspondence between the constituent data and the data constituting the color space for each environmental condition in the first method is determined, and when the color reproduction in the second method is performed, the desired environmental condition is set, Second person based on the set environmental conditions and correspondence Converting the color signals supplied to, to reproduce the color obtained by the first method in the set environmental conditions artificially.

A color correcting method for a color image signal according to a second aspect is the color correcting method for a color image signal according to the first aspect, in which the environmental condition in the first method is detected, and the color condition is detected in the detected environmental condition. The color signal supplied to the second method is converted based on the correspondence between the data of the first method and the data of the second method when the desired color is reproduced,
The converted color signal is supplied to the first system.

A color correction method for a color image signal according to a third aspect of the present invention is a color reproduction method for reproducing a color from a color signal of digital data, when the reproduced color changes due to a change in environmental conditions. In the color correction method of the color image signal to match the reproduced color with the color reproduced under the standard environmental conditions, it is a color chart that can express the color reproduction range of the color reproduction method as a whole and expresses the color of the method. For each of the different color conditions, create multiple color density values that are appropriately changed, measure each created color target under the same measurement conditions, and form a color space for each color target based on the measurement results. However, when the correspondence between the data that constitutes the color space for standard environmental conditions and the data that constitutes each color space for other environmental conditions is found for each environmental condition, and when performing color reproduction by the method, , To detect the environmental conditions in the system,
The color signal is converted based on the one correspondence relationship in the detected environmental condition, and the color reproduction by the method is performed based on the converted color signal.

[0017]

The color correction method for a color image signal according to the first aspect achieves the first object.

That is, when a color image is formed from color signals of digital data, the color reproduction method causes a change in reproduced color due to a change in environmental conditions (for example, temperature, humidity, and ink volume). Method (for example, printing machine) 3
Is a color chart (for example, a color chart) CC (a to n) capable of expressing the color gamut of the method over the entire area, and a density value (for example, cyan (C)) for expressing the color of the method. , Magenta (M), and yellow (Y) are appropriately changed for each of a plurality of different environmental conditions.

When the color reproduction system is the second system (for example, sublimation type thermal transfer color printer) 2 in which the reproduced color does not change due to the change of environmental conditions, the color reproduction range of the system is entirely covered. The color code CCp that can be expressed,
The density value (cyan (c),
A plurality of magenta (m) and yellow (y) are appropriately created.

Each of these color charts is measured under the same measurement conditions (for example, a colorimeter and a densitometer). A color space is formed for each color chart based on the measurement result. Then, the correspondence relationship between the data forming the color space in the second method and the data forming the color space in each environmental condition in the first method is obtained. This correspondence is, for example, Japanese Patent Laid-Open No. 2-2
The correspondence described in No. 14266 is used. In the unlikely event that one color space is narrower than the other color space, this color space is virtually expanded as it can be reproduced with a signal that exceeds the limit that can be reproduced by the method in which the narrower color space is formed. Perform processing such as

When performing color reproduction in the second method,
A desired environmental condition is set, and the color signal supplied to the second method is converted based on the set environmental condition and the corresponding relationship. Then, under the set environmental conditions, the color obtained by the first method is simulated.

A color correction method for a color image signal according to a second aspect achieves the second object. First, the first
Method (for example, printing machine) environmental conditions (for example,
"The temperature is detected as 10 degrees in the printing press and the humidity is 50%").

When performing color reproduction in the second method (for example, sublimation type thermal transfer color printer), the data of the first method in the detected environmental conditions and the desired color (for example, fixed environmental conditions) are used. The color signal supplied to the second method is converted based on the correspondence relationship between the data of the second method when the ideal balanced color reproduction state in FIG. Supply to the scheme.

Therefore, according to the present invention, it is possible to confirm in advance by the second method what kind of hue the color reproduction by the first method will be. Then, the color reproduction by the second method is performed according to the hue. That is, color reproduction based on the color accepted by the user is performed.

The color correcting method of the color image signal according to the third aspect also achieves the second object. That is,
A plurality of color charts capable of expressing the color gamut of the color reproduction method over the entire area and appropriately changing the density value for expressing the color of this method are created for each of a plurality of different environmental conditions. Next, each created color chart is measured under the same measurement condition, and a color space is formed for each color chart based on the measurement result. Further, the correspondence relationship between the data forming the color space for the standard environmental conditions and the data forming the color spaces for the other environmental conditions is obtained for each environmental condition.

When performing color reproduction by this method, environmental conditions in the method are detected, and color signals are converted based on one correspondence relationship in the detected environmental conditions. Finally, color reproduction by this color reproduction method is performed based on the converted color signal.

Therefore, according to the present invention, color reproduction is performed under the standard environmental conditions defined by the user, without being affected by environmental changes. That is, color reproduction is performed based on the environmental conditions set by the user.

[0028]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the apparatus of the present invention will be described with reference to the drawings. ( I) First Example A first example of the present invention is an application of the invention described in claim 1.

FIG. 2 shows a color correcting apparatus of the first embodiment to which the present invention is applied. In the color correction apparatus 100 of the first embodiment, the computer 1 converts the color image signal stored in the hard disk 4 into a color signal S ₂ used for the color printer ₂ and a color signal S ₁ used for the printing machine 3. To do.

The color signal is a parameter for expressing lightness, hue and saturation. Here, S ₁ is represented by cyan (c), magenta (m) and yellow (y), and S 1
₂ for cyan (/ c), magenta (/ m), yellow (/
Expressed as y).

The sublimation type color printer 2 uses the color signal S ₂
A hard copy is output based on the
Print the printed matter using color ink etc. based on ₁ .
Here, it is assumed that the color printer 2 operates under constant environmental conditions, but the reproduced color of the printing machine 3 varies depending on environmental conditions such as temperature, humidity, and ink volume.

The hard disk 4 stores a predetermined color image signal. Actual printing is performed by taking out the color image signal in the hard disk 4 via the computer 1 and creating a film original plate based on the color image signal.

As a preliminary preparation for actual printing, it is safe to check whether or not a desired printing result can be obtained by the printing machine 3. In particular, a normal printing machine reproduces different colors every time the environmental conditions are different, even when the same color signal is supplied. Therefore, it is important to confirm whether or not a desired print result can be obtained under the expected environmental conditions at the present time or at the time of printing.

For this confirmation, the present invention makes a hard copy by the color printer 2. That is, the color printer 2 is based on the color image signal in the hard disk 4.
Make a hard copy with. As described above, even if the color image signals having the same contents in the hard disk 4 are used, the hue reproduced by the printing machine 3 and the hue on the hard copy reproduced by the color printer 2 are different.

Therefore, in this embodiment, the color printer 2
The color correction device 5 is incorporated therein, and the color signal S ₂ is converted so that the color tone of the hard copy obtained by the color printer 2 becomes equal to the color tone of the actual printed matter.

The color image signal in the hard disk 4 is
It is transferred via the computer 1 and the pixel density is converted in the color printer 2. In the color printer 2, density values (parameters) of cyan (/ c), magenta (/ m), and yellow (/ y) based on the color signal S ₂
Are supplied to the color correction device 5. The density values / c, / m, / y supplied to the color correction device 5 are converted into density values c ', m', y'that can display the color tone of the printing machine 3 by a look-up table (LUT). . The conversion of this density value is
As will be described later in detail, in the color printer 2,
This is for reproducing the color tone under a predetermined environmental condition in the printing machine 3.

Next, the operation of the first embodiment including the creation of the above-mentioned lookup table will be described based on the flowchart shown in FIG. In step S1, first, a large number of color charts (color charts) capable of expressing the entire color reproduction area are created by the printing machine 3 and the color printer 2. These color indicators are density values (parameters) c, m, y (printing machine) and / c, / m, and
It is created by appropriately changing / y (color printer).

Since the color printer 2 is used under substantially constant environmental conditions, the color chart created by the color printer 2 is for this constant environmental condition. On the other hand, there are many color targets for the printing machine 3 because the color reproduction varies depending on the environmental conditions as described above. That is, as shown in FIG. 4, it is created by the printing machine 3 while appropriately changing the environmental conditions.

For example, the color code for the printing machine 3 is created by setting only environmental conditions such as temperature and humidity, changing the temperature every 0 ° to 5 °, and changing the humidity every 0% to 10%. The number of environmental conditions and the amount of change in parameters for each condition are appropriately determined in consideration of the environment that occurs in actual printing. The color code for each environmental condition is 256 per density value.
It is created by changing the density value from 0% to 100% with the gradation resolution. For example, as shown in FIG. 4, the density value of magenta (M) is 16 in the vertical axis direction, the density value of cyan (C) is 16 in the horizontal axis direction, and the overall density is 16 in yellow (Y). To create a set of color charts. Further, since the color printer 2 fixes the environmental condition to one, a set of 16 color targets is created in total. The printing machine 3 creates a set of 16 color sheets in the same number of sets as the number of necessary environmental conditions.

Color marks are created for all changes in the parameters that determine the environmental conditions. For example, the temperature and humidity are changed individually or simultaneously to create the color chart. Further, the color mark may be created by changing only one of the environmental conditions. For example, the color chart is created by fixing the humidity and changing only the temperature in a predetermined range. Alternatively, a color mark is created by fixing the temperature and changing only the humidity within a predetermined range.

Then, the measured value for each density of the printed or hard-copy color target is measured by a measuring device such as a colorimeter or a densitometer (steps S2a to S2n). When using a color chart in which only one parameter is changed, an interpolation calculation is performed during the measurement in steps S2a to S2n to indirectly calculate the measured value. For example, the humidity is fixed at 0%, only the temperature is changed from 0 degree to 40 degrees, and the rate of change of the measured value with the increase of this parameter is obtained. In steps S2a to S2n, when a plurality of parameters are changed at the same time with respect to the input environmental condition (for example, humidity of 30%) on the basis of the color mark and the change rate when only one parameter is changed. The measured value of is calculated by interpolation.

From the above, the environmental condition n (n is an arbitrary
Number c) density value c of printing machine 3_n, M_n, Y_n(0 ≦
c_n, M_n, Y_nMeasurement value of each color code corresponding to ≦ 255)
L (c _n, M_n, Y_n), A (c_n, M_n, Y_n), B
(C_n, M_n, Y_n) And the density value of the color printer 2 /
Pair c, / m, / y (0 ≦ / c, / m, / y ≦ 255)
The measured values L (/ c, / m, / y), a (/
c, / m, / y), b (/ c, / m, / y) are measured
It

In step S3, the color difference ΔE between the measured values of the printer 3 and the color printer 2 is obtained by using the measured values of the printer 3 and the color printer 2. From the combination that minimizes the color difference, the correspondence relationship between the density value of the printing machine 3 and the density value of the color printer 2 at that time is obtained. The lookup table (a
~ N) are created (step S4).

When the color space obtained by the measurement values of the printing machine 3 is narrower than the color space of the color printer 2, the method described in the prior art (Japanese Patent Laid-Open No. 2-21).
No. 4266) to expand the color space. Furthermore, when the measured value of the color chart in the color printer 2 and the measured value of the color chart in the printing machine do not correspond in the color space, the interpolation work is performed using various known techniques.

The look-up table obtained by the above processing is created by, for example, the computer 1 as shown in FIG. 2, transferred to the color correction device 5 of the color printer 2, and the printing simulation of step S5. Used for.

In step S5, for example, when the user examines the finish of printing under any environmental condition, a predetermined inspection color signal is transferred to the color printer 2 via the computer 1. In the color correction device 5, the look-up table under the environmental condition n (n means a predetermined environmental condition) designated by the user is referred to. The color printer 2 refers to the look-up table in the specified environmental condition n, and the density value c _n ′ for displaying the hue of the printing machine 3 corresponding to the environmental condition n,
Read m _n ', y _n '. Finally, a hard copy is performed using this density value.

Thus, the user can simulate what kind of color the original image will be printed under arbitrary environmental conditions before printing. (II) Second Embodiment A second embodiment of the present invention is an application of the invention described in claim 2. That is, the color signal transferred to the printing machine is corrected according to the color reproduced by the color printer.

The configuration of this embodiment is also the first one shown in FIG.
The configuration is the same as that of the embodiment. Further, according to the first embodiment, it is assumed that the look-up table under each environmental condition of the printing machine 3 is already stored in the color correction device 5 of the color printer 2.

FIG. 5 shows a flow chart for explaining the operation of the second embodiment. As described above, it is assumed that the steps up to the creation of the lookup table have already been completed (FIG. 1: steps S1 to S4). Furthermore, in the present embodiment, instead of step S5 (FIG. 1) of the first embodiment, operations after step S10 (FIG. 10) are performed.

In step S10, environmental conditions are detected by a thermometer, a hygrometer and the like provided in the printing machine 3, and the environmental conditions around the printing machine are fetched as an environmental condition signal S _C. In step S11, the detected environmental condition signal S _C is transferred to the color correction device 5 of the color printer 2. The color correction device 5 compares the environmental condition indicated by the transferred environmental condition signal S _{C with} the environmental condition at the time of creating the look-up table, and the environmental condition closest to the environmental condition indicated by the environmental condition signal S _C. Select the lookup table obtained in.
On the other hand, since the color printer 2 keeps the environmental conditions constant, the color signal S to be transferred to the printing machine 3 is based on a predetermined color space when color reproduction is performed in the color printer 2.
Correct ₁ That is, the color space in which the printing machine 3 reproduces a color with the same color shade as the color represented by the color printer 2 is selected corresponding to the color space in the color printer 2. Then, the difference between the selected color space and the color space obtained under the actual environmental conditions is obtained.

Specifically, the density values / c, / m, / y in the color printer 2 and the density values c, m, when the printing machine 3 reproduces a color with the same color tone as the color printer.
A lookup table LUT ₀ that associates y with y is selected. On the other hand, the look-up table LUT ₁ showing the correspondence between the printing press and the color printer under the environmental condition (m) indicated by the environmental condition signal S _C is selected.

Next, the two look-up tables are compared with each other. That is, the density values c ₀ , m ₀ , y for obtaining the color tone in the color printer 2 for the printing machine 3 are obtained.
Concentration values of environmental conditions m for ₀ c _{m, m} m, y _m
Calculate the percentage of. This ratio indicates how the concentration value changed due to the change in the environment.

In step S12, the printing machine 3 is actually caused to print. The computer 1 performs a calculation on the data of the color signal S ₁ supplied to the printing machine 3 so as to cancel the change in density. For example, each data of the color signal S ₁ is corrected by multiplying it by the reciprocal of the obtained change rate.

By the above processing, even under the environmental condition m, it is possible to print on the printing machine with the same color tone as the simulation result of the color printer. (III) Third Embodiment A third embodiment of the present invention applies the invention of claim 3.

The configuration of the third embodiment is mainly the computer 1 in the configuration of the first embodiment (see FIG. 2).
And the printing machine 3. In the second embodiment, the color reproduced by the color printer is reproduced as it is in the printing machine, but this embodiment does not use the color printer. That is, the printing machine 3 is controlled by the computer 1 to perform color reproduction under a predetermined constant environmental condition.
Always maintain on the printing press.

The operation of the third embodiment will be described with reference to the flowchart of FIG. As a premise for starting the operation of this embodiment, it is assumed that the printing machine 3 has created the color chart under each environmental condition according to the processing of the first embodiment. Further, among these environmental conditions, the environmental condition under which the best printing result is obtained in the printing machine 3 to be printed is defined as a standard environmental condition (for example, temperature 20 degrees, humidity 30).
%).

Now, in step S21, the color mark corresponding to the standard environment condition set is measured to obtain the measured values L, a, and b. Next, the color chart created for each environmental condition is measured to obtain measured values / L, / a, / b (steps S22a to S22n).

Measured values L, a, b and measured values / L, / a, /
b is compared, and the correspondence between the color space for standard environmental conditions and the color space for other environmental conditions is determined from the combination of the measured values that minimizes the color difference ΔE calculated from both measured values (step S23). Then, a lookup table is created based on this correspondence (step S24). At this time, if the color space for the standard environmental conditions is narrower than the color space for other environmental conditions, the color for the virtual standard environmental conditions is virtually determined by the method described in the related art. Expand the space.

With the above, the preparation for printing is completed, and the actual printing process is started (steps S25 to S27). First, the printing machine 3 detects an environmental condition with a thermometer, a hygrometer, etc., and supplies it to the computer 1 as an environmental condition signal S _C (step S25).

The computer 1 selects the look-up table for the environmental condition closest to the detected environmental condition. Then, based on the correspondence relationship stored in the selected look-up table, the computer 1 to the printing machine 3
The color signal S ₁ to be transferred to is sequentially converted (step S26).

The printing machine 3 starts printing based on the converted color signal S ₁ (step S27). By the above processing, the printing machine 3 corrects the color signal corresponding to the environmental change even if the environmental condition at the time of printing changes from the standard environmental condition, so that the most preferable color reproduction is always maintained. it can.

(IV) Other Modifications Various modifications are possible without being limited to the above embodiments of the present invention.
Although the present invention is applied to the color matching of the printed matter and the hard copy by the thermal transfer printer in the above embodiment, the scope of application of the present invention is not limited to this. That is, it can be applied to color matching between printing methods having different coloring materials.

Further, in the second embodiment, only one kind of environmental condition is given to the color printer, but a plurality of environmental conditions may be set for the color printer. However, in this case, the user pre-selects the environmental conditions used in the color printer. The printing result of the printing machine is
It is adjusted to be equivalent to the shade obtained with the color printer under the selected environmental conditions.

[0064]

According to the first aspect of the invention, since the color variation due to the change in the environmental conditions in the first method can be reproduced by the second method in a pseudo manner, it is possible to reduce the change in the environmental conditions. It is possible to confirm in advance (for example, before printing) how color reproduction is performed.

According to the second aspect of the present invention, even if the environmental conditions in the first system change, the influence of the color variation due to the change in the environmental conditions is corrected, and the color reproduction in the second system is performed. It is possible to reproduce colors with the same hue. For example, the colors tested by a color printer can be printed on a printing machine.

According to the third aspect of the invention, even if the environmental conditions change, the color signals are corrected so as to obtain the same result as the color reproduction under the standard environmental conditions. The reproduction can be continued.

[Brief description of drawings]

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

FIG. 2 is a configuration diagram of a color correction device according to a first embodiment.

FIG. 3 is a flowchart illustrating the operation of the first embodiment.

FIG. 4 is an explanatory diagram of color charts.

FIG. 5 is a flowchart illustrating the operation of the second embodiment.

FIG. 6 is a flowchart illustrating the operation of the third embodiment.

[Explanation of symbols]

 1 ... Computer 2 ... Thermal transfer color printer 3 ... Printing machine 4 ... Hard disk

Claims (3)

[Claims] 1. A color correction method of a color image signal for matching colors reproduced by a plurality of different color reproduction methods when forming a color image from color signals of digital data, wherein the color reproduction method is an environment In the case of the first method that causes a change in the color to be reproduced due to a change in conditions, the first target is a color target that can express the color reproduction range of the method over the entire area.
A plurality of color density values for appropriately expressing the color of the method are created for different environmental conditions, and the color reproduction method does not change the reproduced color due to the change of the environmental condition. In the case of the method, a color chart that can express the color gamut of the method over the entire area, in which the density value for expressing the color of the second method is appropriately changed, is created. Each color chart is measured under the same measurement condition, a color space is formed for each color chart based on the result of the measurement, and data forming the color space in the second method and each environment in the first method The correspondence with the data forming the color space for each condition is obtained, and when performing color reproduction in the second method, a desired environmental condition is set, and based on the set environmental condition and the correspondence. The color signal supplied to the second method A color correction method for a color image signal, characterized in that the color obtained by the first method is reproduced in a pseudo manner under the set environmental conditions. 2. The color correction method for a color image signal according to claim 1, wherein the environmental condition in the first system is detected, and the data of the first system in the detected environmental condition and a desired The color signal supplied to the second system is converted based on the correspondence between the second system data when the color is reproduced and the second system data, and the converted color signal is converted to the first system. A color correction method for a color image signal, which is characterized by supplying the color image signal. 3. A color reproduction method for reproducing a color from a color signal of digital data, wherein when the reproduced color changes due to changes in environmental conditions, the changed color is reproduced under standard environmental conditions. In a color correction method of a color image signal for matching with a color, a color mark capable of expressing a color reproduction range of the color reproduction method over a whole area, in which a density value for expressing a color of the method is appropriately changed. For each of the different environmental conditions, measure each created color standard under the same measurement conditions, and form a color space for each color standard based on the results of the measurement. The correspondence between the data forming the color space and the data forming each color space for other environmental conditions is determined for each of the environmental conditions, and when performing color reproduction by the method, the corresponding method is used. Of the color image signal, which detects the environmental conditions, converts the color signal based on the one correspondence relationship in the detected environmental conditions, and performs color reproduction by the method based on the converted color signal. Color correction method.