JPH0998444A - Method and device for processing image - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform appropriate correction at the time of signal conversion between object chrominance signals and light source chrominance signals. SOLUTION: Input chrominance signals obtained from an image input part 1 are converted into optional chrominance signals provided with luminance components in a color correction part 2, the correction for the feature luminance components is added and the chrominance signals are finally converted to output chrominance signals required in an image output part 8. The image input part 1 and the image output part 8 display light source colors and the object colors respectively. For instance, a combination for which a color monitor is used as a light source color display device and a color printer is used as an object color display device is adopted. As the input chrominance signals or the output chrominance signals, RGB signals are used in the color monitor and CMY signals are used in the color printer (intrinsic to input/output equipments). Also, the optional chrominance signals provided with the luminance components are, for instance, XYZ.L*a*b*.xyY.u'v'Y.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image processing method and apparatus for performing color processing.

[0002]

2. Description of the Related Art FIG. 2 shows a conventional example of an image signal processing device for performing signal conversion between a light source color signal and an object color signal. The light source color is the color of the light emitted from the light source, and the object color is the color of the object that reflects or transmits the light. In this apparatus, the input color signal obtained from the image input unit 201 is corrected by the color correction unit 202, and the correction data is sent to the image output unit 207. A device characteristic conversion circuit 2 using the signal from the image input unit 201 and the input device characteristic read from the ROM 205.
03 signal conversion, the corrected signal further ROM206
It is converted to an output color signal using the output device characteristics read from the.

As described above, in the conventional color correction section, when the colors of the object color and the light source color are matched with each other, the luminance component of the object color is not corrected at all.

[0004]

However, when the human being recognizes the light source color and the object color as the same color, when the color patches of each are actually measured by the method based on JIS, The brightness values of are very different. Therefore, there is a problem that the light source color and the object color look different if only the conventional color signal correction method is used for the data conversion of the light source color and the object color.

Accordingly, an object of the present invention is to provide
An object of the present invention is to provide an image processing method and apparatus capable of performing appropriate correction when performing signal conversion between an object color signal and a light source color signal.

Another object of the present invention is to provide an image processing method and apparatus capable of constant color correction without considering the display characteristics of the display device used.

Further, another object of the present invention is to obtain a concrete and appropriate correction mode not only in the conversion from the light source color display to the object color display but also in the conversion from the object color display to the light source color display. An object is to provide an image processing method and apparatus.

Another object of the present invention is to correct a color appearance shift caused by the relationship between the light source and the display device, based on information about the light source in the display device when performing color matching between input and output images. At the same time, an image processing method and apparatus capable of performing correction based on information of each light source in order to correct a color appearance shift caused by a difference in color temperature between each light source of the input / output image. is there.

Still another object of the present invention is to correct the color shift caused by the mode difference between the object color and the light source color when matching the colors of the input and output images, and to obtain the input and output images. An object of the present invention is to provide an image processing method and apparatus capable of correcting a color appearance shift caused by a difference in color temperature between light sources, based on information of each light source.

[0010]

According to the image processing method of the present invention, a light source color display for displaying a visible image by coloring and a visible image by adhering a coloring material on a recording material are displayed. When the object color display is matched with the object color display, the luminance component of the object color display is corrected to be larger than the luminance component of the light source color display. Here, it is preferable that the correction of the luminance component is performed after conversion into a color space signal that does not depend on the characteristics of the visible image display device used. More specifically, in the conversion from the input signal of the light source color display to the output signal of the object color display, the luminance component is increased, and in the conversion of the output signal of the light source color display from the input signal of the object color display, Perform correction to reduce the luminance component.

The image processing apparatus according to the present invention includes a light source color display apparatus for displaying a visible image by performing color development and an object color for displaying a visible image by applying a coloring material onto a recording material. An image signal processing device for matching display colors on both display devices using a display device, wherein the brightness component of the display image by the object color display device is the brightness component of the display image by the light source color display device. It is provided with a correction means for correcting to a larger value. Here, it is preferable that the correction of the luminance component by the correction means is performed after conversion into a color space signal that does not depend on the characteristics of the visible image display device used. More specifically, the correction means increases the luminance component in the conversion from the input signal of the light source color display to the output signal of the object color display, and in the conversion of the input signal of the object color display from the output signal of the light source color display. Is a correction for lowering the luminance component. Further, the correction means can change the mode of correction according to the type of the recording material.

Another image processing apparatus according to the present invention is an image processing apparatus for performing color matching of input and output images, and a color generated in the relationship between the light source and the display apparatus based on information about the light source in the display apparatus. First to correct the shift in the appearance of
And a second correcting means for correcting the color appearance shift caused by the difference in color temperature between the light sources of the input and output images, based on the information of each light source. Here, it is preferable that the first correction unit independently corrects each component value of the input image data based on the information regarding the light source in the display device. Also, the second
It is preferable that the correction means of (1) performs the correction based on the chromatic adaptation formula. Furthermore, it is possible to have a third correction means for performing correction according to the recording medium. It is preferable that the first correction means or the second correction means performs correction on a color space that does not depend on the input / output device.

Another image processing apparatus according to the present invention is an image processing apparatus that performs color matching of input and output images, and is a first image processing apparatus that corrects a color shift caused by a mode difference between an object color and a light source color. In order to correct the color appearance shift caused by the difference in color temperature between the light source of the input and output images,
It has a 2nd correction | amendment means which correct | amends based on the information of each light source.

Another image processing method according to the present invention is an image processing method for performing color matching of input and output images, wherein colors generated in the relationship between the light source and the display device are based on information about the light source in the display device. Is corrected based on the information of each light source so as to correct the color shift of appearance caused by the difference in color temperature between the light sources of the input and output images.

Further, another image processing method according to the present invention is an image processing method for performing color matching of input and output images, and corrects color shift caused by a mode difference between an object color and a light source color. In order to correct the deviation of the color appearance caused by the difference in color temperature between the light sources of the input / output image, the correction is performed based on the information of each light source.

[0016]

DETAILED DESCRIPTION OF THE INVENTION FIG. 1 shows an embodiment of the present invention. In the embodiment shown in the figure, in order to make the object color and the light source color appear to match each other, the luminance is increased in the conversion from the input signal of the light source color display to the output signal of the object color display, A color correction unit 2 is provided for performing a correction for lowering the brightness in converting an input signal for color display into an output signal for light source color display.

That is, the input color signal obtained from the image input unit 1 is converted into a color signal containing a luminance component in the color correction unit 2, and the luminance component correction which is the feature of the present invention is added to finally obtain the color signal. The color signal is converted into an output color signal required by the image output unit 8.

Here, the image input unit 1 and the image output unit 8 are
One displays the light source color and the other displays the object color.
For example, a combination is used in which a color monitor is used as the light source color display device and a color printer is used as the object color display device. As an input color signal or an output color signal, an RGB signal is used in a color monitor and a CMY signal is used in a color printer (specific to an input / output device). The arbitrary color signal including the luminance component is, for example, XYZ.L ^* a ^* b ^* .xyY.u'v'Y.

[0019]

Embodiment 1 Focusing on luminance conversion according to the present invention, the image input unit 1 of FIG. 1 is a color monitor 301 for displaying a light source color, and the image output unit 8 is a color printer 314 for displaying an object color. Color printer 3 for the light source color to be displayed on the color monitor 301
An example of matching the object colors formed in 14 will be described as a first embodiment with reference to FIG. Here, the XYZ system (tristimulus value) is used as the color signal including the luminance component.

In FIG. 3, the monitor characteristics are stored in the ROM 304. The monitor characteristics indicate the relationship between the RGB data from the color monitor 301 and XYZ obtained by measuring the colors of the image on the color monitor displayed by the signals. There are two types of this relationship, and the relationship between XYZ and the brightness of the phosphor is the matrix represented by the following equation (1), the brightness of the phosphor and the RGB signal that is the monitor signal.
The relation of is in the form of a function called γ function.

Next, how to obtain this monitor characteristic will be described. First, the relationship between XYZ and the brightness of the phosphor is expressed by equation (1).
When the pure RGB colors are displayed on the color monitor, each color chart is measured by using a colorimeter, and the obtained tristimulus values are calculated by the equations (2), (3), The matrix is obtained by substituting each of (4). The other γ function is obtained by measuring the luminance of the phosphor with respect to the RGB value that is the monitor signal, and has the form as shown in equation (5). When measuring the brightness of the phosphor, a dark state is desirable in order to increase the reliability of the data.

[0022]

[Equation 1]

[0023]

[Equation 2]

[0024]

(Equation 3)

[0025]

[Equation 4]

[0026]

L _r = f (R) L _g = f (G) (5) L _b = f (B) In the device characteristic conversion circuit 303, the color monitor 30 is used.
The input signal RGB from 1 is calculated by using the matrix stored in the monitor characteristic ROM 304 and the γ function to obtain the equation (5).
By performing the inverse conversion of Expression (1), the color signal X ₀ Y ₀ Z ₀ including the luminance component is converted.

[0027]

L _r = f (R) L _g = f (G) (6) L _b = f (B)

[0028]

(Equation 7)

Color monitor 301 and color printer 31
In order to make the four colors look the same, it is necessary to convert the luminance component. Therefore, the luminance conversion circuit 305 performs luminance conversion in order to compensate for a color appearance shift caused by a mode difference between the light source color and the object color. From the signal X ₀ Y ₀ Z ₀ of the color monitor 301 which is the light source color display device to the signal X of the color printer 314 which is the object color display device.
Luminance component conversion to ₁ Y ₁ Z ₁ is conversion for increasing the luminance component. Here, a case will be described in which equation (8) is used as the correction method. It can be said that a in the formula (8) is a number satisfying a> 1.0, and preferably in the range of 3 to 5.

The value of a may be preset or may be manually set by the user.

[0031]

X ₁ = aX ₀ (a> 1.0) Y ₁ = aY ₀ (a> 1.0) (8) Z ₁ = aZ ₀ (a> 1.0) The input image light source information ROM 307 is an input device. The information on the external light received by the color monitor 301 is the chromaticity value x
It is stored as yY value and XYZ value. Similarly, the output image light source information ROM 309 stores information about external light received by the color printer 314, which is an output device, as chromaticity values xyY values and XYZ values. This information is xyY, XY
Chromaticity values other than Z or spectral data may be used. Further, when the position where the input / output device is located and the light source for observing the actual image are different, the observation light source information of the input image and the observation light source information of the output image can be replaced.

Further, it is also possible to input the observation condition of the input / output image measured by using a sensor or the like.

In the input image light source information adding circuit 306,
A correction that is specific to the display image and takes into consideration the influence of the input image light source is performed.

That is, the monitor 3 for the input image light source
Correction such as surface reflection from the display screen 01 is performed based on the relationship between the input image light source and the light emission from the monitor.

It should be noted that the tristimulus value X _K1 Y _K1 Z _K1 which is the correction amount
Is stored in the ROM 307 in advance based on experience based on the relationship between the input image light source and the monitor.

The tristimulus values X _k1 Y _k1 Z _k1 stored in the input image light source information ROM 307 are substituted into the following equation (9) to correct X ₁ Y ₁ Z ₁ .

[0037]

X ₂ = X ₁ + X _k1 Y ₂ = Y ₁ + Y _k1 (9) Z ₂ = Z ₁ + Z _{k1 In the} conversion circuit 308 based on the light source information, the color monitor 30 is used.
In order to make the color of the image of No. 1 and the color of the image output by the color printer 314 look the same, the light source information of the input image (stored in the ROM 307) and the light source information of the output image (stored in the ROM 309). ) Is added. For this correction, the correction formula (11) using the von Kries chromatic adaptation formula is used, and X ₂ Y ₂ Z _{2 is changed} to X ₃ Y ₃ Z
Convert to ₃ . Difference in color temperature of each light source, using the chromaticity value of the light source of the input image, the chromaticity value of the light source of the output image, and the chromaticity value of the light source that measured the color chart when calculating the printer characteristics, which are stored as light source information Correction is performed to compensate for the difference in color appearance due to.

[0038]

(Equation 10)

[0039]

[Equation 11]

The matrix M1 of the equation (11) uses the light source 1 as the observation light source of the input image and the light source 2 as the observation light source of the output image, and the chromaticity values xy values stored in the input / output light source information are represented by the equation (10). It is obtained by substituting into.

The matrix M2 uses the light source 1 as the observation light source of the output image, and the light source 2 as the light source (for example, C light source) for measuring the color chart when calculating the printer characteristics, and the input / output light source information RO.
It is obtained by substituting the chromaticity value xy value stored in M into the equation (10).

By performing the above-described correction, it is possible to perform the correction according to the color temperature of the observation light source, and to make the colors of the images match even if the color temperatures of the light sources of the input image and the output image are different. Can be done.

Even when the printer output is performed on paper, the color of the paper and the absorption of ink may differ. Therefore, a correction formula for maximizing this characteristic is stored in the output information ROM 311, and the conversion circuit 310 according to the output information is stored. Is corrected in. For example, in the case of plain paper, the correction is not performed, but in the case of coated paper, the correction is performed according to the correction formula stored in the output information.

Printer characteristics are stored in the ROM 313. This printer characteristic is the color printer 31.
4 shows the relationship between the CMY data input in 4 and the XYZ when the color chart printed by the input data is measured.
This relationship between CMY and XYZ is stored as an LUT.

Next, how to obtain this printer characteristic will be calculated using FIG. A certain CMY data 401 is input to the printer and a certain color chart is printed. The color chart 402 is measured with a colorimeter under a standard light source (for example, C light source),
Obtain the XYZ values 404. The XYZ values here are not the reflectance obtained using a standard white plate, but the absolute values obtained as a colorimetric measurement, and the luminance is a unit. In this way, the relationship between the N cubed CMY data and the XYZ values is L.
Required in the form of UT. As the relationship between CMY and XYZ, LUT interpolation or the like can be used.

Returning to FIG. 3 again, the device characteristic conversion circuit 312
Then, the color signal XYZ whose luminance component is corrected in this way is
The printer output signal CMY is converted using the LUT in which the printer characteristics are stored.

As described above, the luminance conversion circuit 305 can compensate for the shift in the appearance of colors due to the mode difference between the light source color and the object color.

Therefore, it is possible to perform color matching between output devices having different modes such as a monitor and a printer.

Further, the influence of the input / output image light source can be compensated by adding input light source information (306) and converting by the light source information (308). That is, color correction can be performed irrespective of the input / output image light source by performing correction unique to the display image such as surface reflection and correction for the difference in color temperature.

Furthermore, since the correction based on the characteristics of the recording medium, which is peculiar to the image forming apparatus for forming an image on the recording medium, is performed by the conversion (310) by the output information, the color matching can be performed regardless of the recording medium. .

Second Embodiment As a reverse conversion to the first embodiment, as shown in FIG. 5, a case where object color data is converted into light source color data will be described. That is, this is a case where a print image is previewed on the color monitor 513 based on a signal sent to the color printer 501. In other words, the color printer 501 that outputs the object color is used as the image input unit,
A color monitor 513 that displays a light source color as an image output unit
The case of using will be described with reference to FIG.

The color printer 5 is displayed on the color monitor 513.
When previewing based on the 01 signal, the color correction unit 502 corrects the input signal value from the color printer 501, and this correction value becomes the input signal value of the color monitor 513. Next, the color correction unit 502 will be described in detail.

The printer characteristics stored in the ROM 505 are obtained by the same method as in the first embodiment. That is, CMY data input to the color printer 501 and XY when the color chart printed by the input data is measured.
The relationship with Z is stored as an LUT.

The device characteristic conversion circuit 503 converts the signal CMY from the color printer 501 into a color signal X ₀ Y ₀ Z ₀ containing a luminance component using the matrix stored as the printer characteristics.

When the printer output is performed on paper, the color of the paper, the absorption of ink, and the like may differ depending on the type. Therefore, a correction formula for maximizing this characteristic is stored in the output information ROM 506. In the conversion circuit 504 based on the output information, the conversion reverse to that in the first embodiment is performed, and the color signal X ₁ that does not include the correction based on the output information.
Convert to Y ₁ Z ₁ .

In order to faithfully reproduce the image output from the color printer 501 on the color monitor 513 so that the colors of both images appear to match, it is necessary to convert the luminance component. Therefore, the luminance conversion circuit 507 converts the signal X ₁ Y ₁ Z ₁ of the color printer 501 which is the object color display device into the signal X ₂ Y ₂ Z ₂ of the color monitor 513 which is the light source color display device. In this case, conversion for lowering the luminance component is performed. Here, a case will be described where Expression (12), which is the inverse conversion of Expression (8), is used as the correction method.

[0057]

X ₂ = 1 / a × X ₁ (a> 1.0) Y ₂ = 1 / a × Y ₁ (a> 1.0) (12) Z ₂ = 1 / a × Z ₁ (a> 1.0) The input image light source information ROM 510 stores information on external light received by a color printer as an input device, and the output image light source information ROM 511 stores information on external light received by a color monitor as an output device. Chromaticity value xyY value and XY
It is stored as a Z value.

In order to make the image on the color printer 501 observed under different light sources and the image displayed on the color monitor 513 look like the same color, the light source information conversion circuit 508 converts the light source information of the input image ( ROM5
10) and the light source information of the output image (ROM
(Stored in 511) is added. As in the first embodiment, the chromaticity value of the light source of the input image, the chromaticity value of the light source of the output image, and the chromaticity value of the light source obtained by measuring the color chart when calculating the printer characteristics are stored as the light source information. The correction can be made by substituting the expressions (10) and (11) in

The matrix M1 of the equation (11) is a chromaticity value xy stored in the input / output light source information, where the light source 1 is a light source for measuring the color chart when calculating the printer characteristics, and the light source 2 is an observation light source of the input image. It is obtained by substituting the value into the equation (10).

Further, the matrix M2 substitutes the chromaticity values xy values stored in the input / output light source information ROM into the equation (10) with the light source 1 as the observation light source for the input image and the light source 2 as the observation light source for the output image. Required by

By performing the correction as described above, it is possible to perform the correction according to the observation light source, and the colors of the images can be matched even if the light sources of the input image and the output image are different.

The monitor characteristics stored in the ROM 512 are obtained by the same method as in the first embodiment. That is, the monitor characteristics represent the relationship between the RGB data from the color monitor 513 and the XYZ obtained by measuring the color of the image on the monitor displayed by the signal, and the relationship is the matrix and the form of the γ function. Has become.

In the device characteristic conversion circuit 509, the monitor characteristic ROM 51 is calculated from the XYZ values thus corrected.
By performing conversion using the matrix stored in 2 and the γ function, the output color signal RG of the color monitor 513 is output.
Convert to B

In each of the above-mentioned embodiments, the correction formula using the proportional constant is used for the brightness correction. However, in addition to this, in the case of being proportional to the square, in the case of offsetting, in the case of γ function, the difference is obtained. There is a case where it is corrected using. In either case, the correction may be performed so that the brightness of the object color is higher than the brightness of the light source color.

[0065]

As described above, according to the present invention, it is possible to match the two colors by correcting the luminance component regardless of the environment in which the light source color and the object color are observed. Can be done.

That is, according to the present invention, it is possible to obtain an image processing method and apparatus capable of performing appropriate correction when performing signal conversion between an object color and a light source color.

Further, according to the present invention, it is possible to obtain an image processing method and apparatus capable of constant color correction without considering the display characteristics of the display device used.

Further, according to the present invention, not only the conversion from the light source color display to the object color display, but also the conversion from the object color display to the light source color display, a specific and appropriate correction mode can be obtained. A method and apparatus can be obtained.

Further, the color matching of the input and output images can be performed with high accuracy.

[Brief description of drawings]

FIG. 1 is a diagram showing an embodiment of the present invention.

FIG. 2 is a diagram focusing on color correction of a conventional image input / output device.

FIG. 3 is a diagram showing a first embodiment of the present invention.

FIG. 4 is a diagram showing how to obtain printer characteristic values.

FIG. 5 is a diagram showing a second embodiment of the present invention.

[Explanation of symbols]

 1 Image Input Unit 2 Color Correction Unit 3 Device Characteristic Conversion Circuit 4 Luminance Conversion Circuit 5 Device Characteristic Conversion Circuit 6 Input Device Characteristic (Stored) ROM 7 Output Device Characteristic (Stored) ROM 8 Image Output Unit

Claims (15)

[Claims] 1. When matching a light source color display for displaying a visible image by color development and an object color display for displaying a visible image by adhering a coloring material on a recording material, the object color An image processing method, comprising: correcting so that a display brightness component is larger than a brightness component of the light source color display. 2. The image processing method according to claim 1, wherein the correction of the luminance component is performed after conversion into a color space signal that does not depend on the characteristics of the visible image display device used. 3. The brightness component is increased in the conversion from the input signal of the light source color display to the output signal of the object color display according to claim 1, and the output signal of the light source color display is increased from the input signal of the object color display. The image processing method is characterized by lowering the luminance component in the conversion. 4. A light source color display device for displaying a visible image by performing color development, and an object color display device for displaying a visible image by applying a coloring material onto a recording material,
An image processing device for matching display colors on both display devices, wherein the luminance component of a display image by the object color display device is corrected to be larger than the luminance component of a display image by the light source color display device An image processing apparatus comprising means. 5. The image processing device according to claim 4, wherein the correction of the luminance component by the correction means is performed after conversion into a color space signal that does not depend on the characteristics of the visible image display device used. . 6. The correction means according to claim 4, wherein the correction means raises a luminance component in conversion from an input signal of the light source color display to an output signal of the object color display, and outputs the light source color display from the input signal of the object color display. An image processing device characterized in that a luminance component is lowered in signal conversion. 7. The image processing apparatus according to claim 4, wherein the correction unit changes a correction mode according to the type of the recording material. 8. An image processing device for performing color matching between input and output images, the first image processing device correcting color appearance deviation caused by the relationship between the light source and the display device, based on information about the light source in the display device. And a second correcting means for correcting the color appearance shift caused by the difference in color temperature between the light sources of the input and output images, based on the information of each light source. Image processing device. 9. The image processing apparatus according to claim 8, wherein the first correction unit independently corrects each component value of the input image data based on the information regarding the light source in the display device. 10. The image processing apparatus according to claim 8, wherein the second correction unit performs correction based on a chromatic adaptation formula. 11. The image processing apparatus according to claim 8, further comprising a third correction unit that performs correction according to a recording medium. 12. The image processing apparatus according to claim 8, wherein the first correction unit or the second correction unit performs correction on a color space that does not depend on an input / output device. 13. An image processing device for performing color matching between input and output images, comprising: first correction means for correcting a color shift caused by a mode difference between an object color and a light source color; and the input and output images. 2. An image processing apparatus comprising: a second correction unit that corrects a color appearance shift caused by a difference in color temperature between the respective light sources, based on information of each light source. 14. An image processing method for performing color matching between input and output images, which corrects a color appearance shift caused by a relationship between the light source and the display device based on information about the light source in the display device. An image processing method characterized by performing correction based on information of each light source so as to correct a color appearance shift caused by a difference in color temperature between each light source of a written output image. 15. An image processing method for performing color matching between input and output images, which corrects a color shift caused by a mode difference between an object color and a light source color, and sets a color between each light source of the input and output images. An image processing method characterized by performing correction based on information of each light source so as to correct a color appearance shift caused by a difference in temperature.