JP2014150522A - Image processing method, image processing program, and image processing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image processing method capable of easily performing correction parameter setting according to the different types of recording media.SOLUTION: An image processing system 10 acquires spectral reflectance of a non-standard recording medium (recording medium used by a user) used for output, set a correction parameter for the recording medium, performs fluorescence correction to an input image on the basis of the correction parameter, forms an image with a printer, and outputs the image. With this configuration, correction parameter setting can be easily performed according to recording media having different fluorescent characteristics, and the consumption of a recording medium and color material can be minimized.

Description

  The present invention relates to an image processing method, an image processing program, and an image processing system for reproducing an image on a non-standard recording medium including fluorescence to form an image.

In color management of printers and copiers, ideally always output in the same color even when output is performed on non-standard recording media having different fluorescence characteristics. For this reason, a technique for performing a correction process for correcting a difference between non-standard recording media or creating and applying a color profile corresponding to the non-standard recording medium is already known. When outputting images with a color copier or color printer, users can use various non-standard recording media, such as plain paper, recycled paper, and paper containing fluorescence (fluorescent paper), depending on the application. ing.
In particular, the fluorescent paper is selected according to the user's preference, and it is desired that a desired color is output on the non-standard recording medium.
However, this fluorescent property is manifested by a fluorescent whitening agent contained as a special paint for making the human eye look whiter than the original color of the material. This fluorescent whitening agent has a characteristic of absorbing light from the short wavelength to the ultraviolet wavelength region in the visible light region and emitting light at a longer wavelength side. As described above, in the non-standard recording medium using the fluorescent brightener, the white color of the non-standard recording medium is perceived by human eyes as a brighter white than the original color of the non-standard recording medium. . On the other hand, in strict color matching performed using a color profile or the like, the perceptual effect varies depending on the amount and characteristics of the fluorescent whitening agent.
Therefore, in the case of non-standard recording media containing fluorescence, the effect on color appearance is large, and simple color conversion processing using a color adaptation model or color appearance model or simple white point correction is performed. Even so, there is a problem that the color reproducibility is different.

Therefore, as a technique paying attention to the difference between the nonstandard recording media, a technique has been proposed in which, when an image is read, the characteristics of the nonstandard recording medium are automatically detected and corrected based on the acquired information. For example, in Patent Document 1, in consideration of the influence of the fluorescent whitening agent and the observation environment, the number necessary for creating a white profile of a medium and a color profile formed on the medium for the purpose of creating a simple and highly accurate profile. The color patch spectral reflectance is measured, and when it is determined that the optical brightener is contained in the media based on the measured value of the white part, the color patch measurement value is corrected, and the corrected color patch colorimetry is performed. A process of creating a color profile based on values and viewing environment information is disclosed.
Further, in Patent Document 2, not only the white paper portion but also the reproduction color of an image area that has a fluorescent whitening effect and cannot be corrected appropriately by conversion using a chromatic adaptation model or simple white point correction is appropriate for fluorescent paper. For the purpose of color correction, the paper white processing that converts the paper white of the standard recording medium to the paper white of the fluorescent paper is performed when there is no fluorescent light source, and correction that multiplies the relative fluorescent coefficient and environmental coefficient when the light source is fluorescent. That is, there is disclosed an image processing apparatus that outputs a paper white with a yellow color depending on the paper in order to correct the appearance of the color with the light source without fluorescence.
In Patent Document 3, for the purpose of highly accurately correcting an output error between spectrophotometer models, a reference spectral reflectance obtained by measuring a patch image with a spectrophotometer as a reference machine, and a correction target As a correction coefficient, a coefficient indicating a correlation curve for each wavelength is used so that the reference spectral reflectance approaches the correction target spectral reflectance from the correction target spectral reflectance obtained by measuring the patch image with a spectroscopic measuring machine The structure which correct | amends the spectral reflectance produced | generated and measured with the correction | amendment object machine is disclosed.

Japanese Patent Application Laid-Open No. H10-228561 describes that the white spectral reflectance and color patch colorimetric values are acquired and correction is performed in consideration of the influence of the fluorescent brightener. However, since it is necessary to measure the color by outputting many color patches for each paper, the problem that the user cannot do easily, the problem of consuming paper and color materials, and the difference in the colorimeter model are corrected. The problem of not having a mechanism to do this has not been solved.
Japanese Patent Application Laid-Open No. H10-228561 describes that correction is performed in consideration of the influence of the fluorescent brightener contained in the paper. However, when performing the fluorescence correction processing to match the reproduction color of the image area affected by the fluorescent whitening material included in the paper with that of the standard recording medium, it is matched with either the absolute value or the relative value with respect to the standard recording medium. The problem that the user's request cannot be easily dealt with and the problem that the mechanism for correcting the model difference between the colorimeters is not solved.
Japanese Patent Application Laid-Open No. H10-228561 describes a point of correcting an error due to a difference in model of the spectrocolorimeter. However, since it is a means to correct for all colors and wavelengths with parameters dependent on the paper, it is necessary to set parameters for colorimeter correction for each paper, and the difference in models of spectral colorimeters The problem that it cannot be easily corrected has not been solved.
As described above, conventionally, when setting correction parameters corresponding to non-standard recording media having different fluorescence characteristics, it is necessary to output a large number of color patches for each non-standard recording medium and perform color measurement. Problems such as non-standard recording media and color material consumption, problems that cannot be easily met by the user's desire to match the standard recording medium with either absolute values or relative values, and standard recording media When the spectral reflectance of the non-standard recording medium is different from the spectral reflectance of the non-standard recording medium, there is a problem that there is no means to easily correct the error due to the difference of the spectral colorimeter. It was.

  The present invention has been made in view of the above, and an object thereof is to provide an image processing method capable of easily performing correction parameter setting corresponding to different non-standard recording media.

  In order to solve the above problems, the invention described in claim 1 is characterized in that an apparent color of an image formed on a non-standard recording medium having a spectral reflectance of a surface different from that of the standard recording medium is formed on the standard recording medium. An image processing method for setting a correction parameter so as to match an apparent color of an image to be acquired, an acquisition step of acquiring a spectral reflectance of the non-standard recording medium, a spectral reflectance of the non-standard recording medium, And correction for matching the apparent color of the image formed on the non-standard recording medium with the apparent color of the image formed on the standard recording medium based on the spectral reflectance of the standard recording medium. A correction parameter setting step for setting a parameter, a color profile storage step for storing a color profile of the standard recording medium in a storage unit, and a correction parameter based on the correction parameter The color profile of the standard recording medium is corrected to a value commensurate with the non-standard recording medium, a color profile generation step of generating a color profile corresponding to the non-standard recording medium, characterized by comprising a.

  According to the present invention, the spectral reflectance of the non-standard recording medium is acquired and formed on the non-standard recording medium based on the spectral reflectance of the non-standard recording medium and the spectral reflectance of the standard recording medium. A correction parameter for matching the apparent color of the image with the apparent color of the image formed on the standard recording medium is set, the color profile of the standard recording medium is stored in the storage means, and based on the correction parameter, Correction parameter settings corresponding to different non-standard recording media can be easily performed by correcting the color profile of the standard recording medium to a value suitable for the non-standard recording medium and generating a color profile corresponding to the non-standard recording medium. Is possible.

It is a figure for demonstrating the image processing method which concerns on 1st Embodiment of this invention. It is a block diagram which shows the structure of the fluorescence correction | amendment part which performs the image processing method which concerns on 1st Embodiment of this invention. It is a block diagram which shows the structure of the correction parameter setting part which performs the image processing method which concerns on 1st Embodiment of this invention. It is a block diagram of the fluorescence level difference calculation processing module which performs the image processing method which concerns on 1st Embodiment of this invention. (A)-(c) is a figure for demonstrating the fluorescence level difference computed by fluorescence level difference calculation. It is a figure for demonstrating the basic waveform of the difference with and without UV cut filter used by fluorescence level difference calculation. It is a figure for demonstrating the colorimeter parameter (mc0, mc1) which correct | amends the model difference of a colorimeter. It is a block diagram which shows the structure of the fluorescence level conversion which performs the image processing method which concerns on 1st Embodiment of this invention. (A) (b) is a figure for demonstrating the spectral reflectance difference estimation between non-standard recording media. It is a figure for demonstrating the color material masking parameter used by spectral reflectance difference estimation between recording media. (A)-(g) is a figure for demonstrating the patch spectral reflectance formed in the standard recording medium, and a synthesis | combination. It is a figure for demonstrating the modification of the correction parameter setting part in the image processing method which concerns on 1st Embodiment of this invention. It is a figure for demonstrating the modification in the image processing method which concerns on 1st Embodiment of this invention. It is a figure for demonstrating the image processing method which concerns on 2nd Embodiment of this invention. It is a block diagram which shows the structure of the nonstandard recording medium difference correction & color conversion part which performs the image processing method which concerns on 2nd Embodiment of this invention. It is a block diagram which shows the structure of the correction parameter setting part which performs the image processing method which concerns on 2nd Embodiment of this invention. It is a flowchart for demonstrating parameter switching. It is a figure for demonstrating the modification in the image processing method which concerns on 2nd Embodiment of this invention. It is a block diagram which shows the structure of the color conversion part which performs the image processing method which concerns on 2nd Embodiment of this invention. It is a flowchart in order to demonstrate parameter switching. It is a figure for demonstrating the image processing system which concerns on 3rd Embodiment of this invention.

An embodiment of the present invention will be described.
The present invention has the following features when setting correction parameters or creating color profiles corresponding to non-standard recording media having different fluorescence characteristics.
According to the present embodiment, by using the colorimetric values of a large number of patches formed on the standard recording medium, the colorimetry relating to the nonstandard recording medium is significantly reduced (only one white point of the nonstandard recording medium is measured). In addition, there is no need for color patch output for each non-standard recording medium.
Further, the white point conversion performed before the fluorescence correction is switched, so that both the case of matching with the standard recording medium with the absolute value and the case of matching with the relative value are characteristic.
Furthermore, even if the color reflectance measurement of the recording medium is performed using a colorimeter different from that of the standard recording medium, the user can easily input the color measuring device information of the recording medium. It is characterized by being able to respond.
Embodiments of the present invention will be described below with reference to the drawings.

<First Embodiment>
FIG. 1 is a diagram for explaining an image processing method according to the first embodiment of the present invention.
FIG. 1 is a diagram showing a configuration of an image forming system that executes an image processing method according to the first embodiment of the present invention. The image processing system 10 is realized by, for example, a control PC and expansion hardware and control software installed in the control PC.
The control PC includes a ROM (Read Only Memory), a RAM (Random Access Memory), a CPU (Central Processing Unit), and an HDD (Hard Disk Drive). The control PC reads the operating system OS from the HDD, expands it on the RAM and starts the OS, reads a program (processing module) from the HDD under the OS management, and executes various processes.
As shown in FIG. 1, the image processing system 10 includes an input image acquisition unit 1, a fluorescence correction unit 2A, a color conversion unit 3A, and a printer output unit 4 as functional configurations for realizing an image processing process. I have. Further, the image processing system 10 includes a recording medium spectral reflectance acquisition unit 5A, a recording medium colorimeter information acquisition unit 11, a correction parameter setting unit 6, and a recording unit 7.
The image processing system 10 acquires the spectral reflectance of a non-standard recording medium (non-standard recording medium used by a user) used for output, sets a correction parameter, and corrects fluorescence for the input image based on the correction parameter. The image is formed by a printer and output.
A medium other than the “standard recording medium” such as a sheet, and a medium such as a sheet used by the user is referred to as a “recording medium”. The color conversion parameter corresponding to “recording medium” is not held in the recording unit 7.

The non-standard recording medium spectral reflectance acquisition unit 5A acquires the spectral reflectance of the non-standard recording medium using a colorimeter without a UV cut filter. Alternatively, the spectral reflectance is not directly measured and acquired, but a non-standard recording medium is measured with three bands of RGB (red, green, and blue) to detect a characteristic amount of spectral characteristics. As described above, the non-standard recording medium spectral reflectance acquisition unit 5A executes the step of acquiring the spectral reflectance of the non-standard recording medium.
The recording medium colorimeter information acquisition unit 11 acquires the colorimeter information (model information) of the colorimeter used in the recording medium spectral reflectance acquisition unit 5A by the user.
The correction parameter setting unit 6 includes a spectral reflectance of the non-standard recording medium, colorimeter information of the non-standard recording medium, and a number of color patch spectral reflectances formed on the standard recording medium (measured in advance and stored in the storage unit 7). Based on the stored data, correction parameters are set for matching the apparent color of the image formed on the non-standard recording medium with the apparent color of the image formed on the standard recording medium. In this way, the correction parameter setting unit 6 executes a step for matching the apparent color of the image formed on the non-standard recording medium with the apparent color of the image formed on the standard recording medium.
The input image acquisition unit 1 acquires input image data formed in RGB colors. Here, the input image acquisition unit 1 executes a step of acquiring input image data formed on a non-standard recording medium.

The fluorescence correction unit 2A determines that the apparent color of the image formed on the non-standard recording medium based on the correction parameter set by the correction parameter setting unit 6 is the apparent color of the image formed on the standard recording medium. The color value is corrected so as to be the same. The color value after the fluorescence correction is output as a color value in the Lab uniform color space.
The color conversion unit 3A converts the color value of the Lab uniform color space based on the standard recording medium profile stored in the storage unit 7 into CMYK (cyan, magenta, and color values corresponding to the color material color used for output. Yellow / black).
The printer output unit 4 forms an image by placing toner, which is a color material, on a non-standard recording medium based on the color value CMYK.
The recording unit 7 stores a color profile corresponding to the standard recording medium. As described above, the recording unit 7 executes the step of storing the color profile corresponding to the standard recording medium.

FIG. 2 is a block diagram showing a configuration of the fluorescence correction unit 2A that executes the image processing method of the present invention.
At startup, the control PC reads the operating system OS from the HDD, expands it on the RAM and starts the OS. Under the management of the OS, the control PC reads a processing module as a program from the HDD and executes various processes. Hereinafter, processing modules executed by the CPU in the fluorescence correction unit 2A will be described.
The matrix conversion processing module 22 performs matrix conversion on the tristimulus values XYZ values captured as the colors of the input image. Thereby, even when the amount of the fluorescent brightening agent contained in the non-standard recording medium is different from that of the standard recording medium, the color value is corrected so that the color reproduction between the non-standard recording media is the same.
In order to realize conversion with XYZ values, RGB values are converted into Lab values by the RGB → Lab conversion processing module 20 as color space conversion before and after matrix conversion. Next, the Lab → XYZ conversion processing module 21 converts the Lab value into an XYZ value, and then the matrix conversion processing module 22 performs matrix conversion. Next, the X′Y′Z ′ → L′ a′b ′ conversion processing module 23 converts the X′Y′Z ′ value after matrix conversion into an L′ a′b ′ value.

The RGB → Lab conversion processing module 20 converts input image data composed of RGB values into color values in the uniform color space Lab. The Lab → XYZ conversion processing module 21 converts the color value of the uniform color space Lab into an XYZ value.
The matrix conversion processing module 22 performs conversion from XYZ values to X′Y′Z ′ values according to the following Equation 1. The matrix coefficients m _{11 to} m ₃₄ applied here are correction parameters set by the correction parameter setting unit 6.
The X′Y′Z ′ → L′ a′b ′ conversion processing module 23 converts the X′Y′Z ′ value into the color value L′ a′b ′ in the uniform color space.

FIG. 3 is a block diagram showing a configuration of the correction parameter setting unit 6 that executes the image processing method according to the embodiment of the present invention.
Matrix coefficients m _{11 to} m ₃₄ are calculated as correction parameters from the spectral reflectance of the non-standard recording medium and the number of color patch spectral reflectances formed on the standard recording medium. The correction parameter setting unit 6 executes a step of correcting the color profile corresponding to the standard recording medium based on the correction parameter and generating a color profile corresponding to the non-standard recording medium. Further, a fluorescence level difference calculating step for calculating a fluorescence level difference between the non-standard recording medium and the standard recording medium based on the spectral reflectance of the non-standard recording medium, and based on the fluorescence level difference and the spectral reflectance of the standard recording medium. The step of setting the correction parameter is executed.

The fluorescence level difference calculation processing module 600 includes a standard recording medium spectral reflectance (non-standard recording medium included in the spectral reflectance of the non-standard recording medium, the colorimeter information of the non-standard recording medium, and the patch spectral reflectance formed on the standard recording medium. Based on the fluorescence level prediction parameter stored in the storage unit 7, the fluorescence level difference is calculated from the spectral reflectance of the white background patch of the standard recording medium.
The fluorescence level conversion processing module 60 converts the patch spectral reflectance formed on the standard recording medium according to the fluorescence level difference, and obtains the predicted spectral reflectance when the same color patch group is formed on the non-standard recording medium.
The spectral reflectance → XYZ conversion processing module 61 calculates a patch spectral reflectance formed on the standard recording medium, an estimated spectral reflectance when formed on the nonstandard recording medium, and a spectral reflectance of the nonstandard recording medium. Convert to stimulus value XYZ.
The multiple regression analysis processing module 62 performs conversion that is the inverse conversion of fluorescence level conversion between XYZ signals, that is, a conversion matrix that predicts XYZ of a patch formed on a standard recording medium from XYZ of a patch formed on a non-standard recording medium The coefficients a11 to a34 are calculated. The XYZ values of the patches formed on the standard recording medium are (Xs1, Ys1, Zs1), (Xs2, Ys2, Zs2), (Xs3, Ys3, Zs3),.

白色補正処理モジュール６３は、非標準記録媒体の分光反射率をＸＹＺに変換した値（Ｘｗ、Ｙｗ、Ｚｗ）と、蛍光レベル変換処理モジュール６０の出力に含まれる非標準記録媒体の白色に関する予測分光反射率をＸＹＺに変換した値（Ｘｕｗ、Ｙｕｗ、Ｚｕｗ）のズレを補正するための変換マトリクスを、重回帰分析処理モジュール６２により求めた変換マトリクスに乗算して、補正パラメータｍ_１１〜ｍ_３４を算出する。算出式は式３になる。

The XYZ predicted values (values obtained by converting the predicted spectral reflectance, which is the output of the fluorescence level conversion processing module 60 into XYZ values) of each patch in the non-standard recording medium, are (Xu1, Yu1, Zu1), (Xu2, Yu2, Zu2). ), (Xu3, Yu3, Zu3),. Substituting the set of XYZ of the patches of the standard recording medium and the non-standard recording medium into Equation 2, matrix coefficients a _{11 to} a ₃₄ are obtained by multiple regression analysis (mean square error minimum).

The white color correction processing module 63 predicts the spectroscopic spectrum related to the white color of the non-standard recording medium included in the values (Xw, Yw, Zw) obtained by converting the spectral reflectance of the non-standard recording medium into XYZ and the output of the fluorescence level conversion processing module 60. A conversion matrix for correcting a deviation of values (Xuw, Yuw, Zuw) obtained by converting the reflectance into XYZ is multiplied by the conversion matrix obtained by the multiple regression analysis processing module 62, and correction parameters m _{11 to} m ₃₄ are obtained. calculate. The calculation formula is Formula 3.

FIG. 4 is a block diagram of a fluorescence level difference calculation processing module 600 that executes the image processing method according to the first embodiment of the present invention.
In the fluorescence intensity prediction processing module 604, the fluorescence intensity prediction value fu is calculated from the spectral reflectance of the standard recording medium according to the equation 4-1 described later.
The fluorescence intensity prediction processing module 605 calculates a fluorescence intensity predicted value fs from the spectral reflectance of the non-standard recording medium according to Equation 4-2 described later.
The colorimeter parameter selection processing module 606 selects a corresponding colorimeter parameter according to the model information of the colorimeter used in the colorimetry of the nonstandard recording medium.
In the colorimeter model difference correction processing module 607, the colorimeter used for acquiring the spectral reflectance of the standard recording medium and the colorimeter used for acquiring the spectral reflectance of the non-standard recording medium according to Equation 4-3 described later. Correct the model difference. The predicted fluorescence intensity calculated from the spectral reflectance obtained using the colorimeter used for obtaining the spectral reflectance of the standard recording medium, based on the predicted fluorescent intensity calculated from the spectral reflectance of the non-standard recording medium. Convert to fu ′.
The fluorescence level difference prediction processing module 608 predicts the fluorescence level difference between the standard recording medium and the non-standard recording medium according to Equation 5-2 described later.

FIG. 5 is a diagram for explaining the fluorescence level difference calculated by the fluorescence level difference calculation.
FIG. 5A shows the spectral reflectance of a non-standard recording medium without a UV cut filter, which is measured with no UV cut filter attached to the colorimeter.
FIG. 5B shows the spectral reflectance of a non-standard recording medium with a UV cut filter measured in a state where the UV cut filter is attached to the colorimeter.
As can be seen from FIGS. 5A and 5B, the spectral reflectance waveforms of (a) and (b) are greatly different in non-standard recording media with a large amount of fluorescent brightening agent (high fluorescence level). The non-standard recording medium with less fluorescent whitening agent (low fluorescence level) has similar spectral reflectance waveforms of (a) and (b).
As shown in FIG. 5C, (a) the spectral reflectance of the non-standard recording medium without the UV cut filter and (b) the spectrum of the non-standard recording medium with the UV cut filter attached to the colorimeter. The peak height of the waveform (c), which is the difference from the reflectance, is defined as the fluorescence level of each non-standard recording medium. The peak appears at a wavelength around 440 nm. The difference in fluorescence level is a difference from the standard recording medium having a spectral reflectance at a peak, that is, 440 nm.

FIG. 6 is a diagram for explaining the basic waveform of the difference between the absence of the UV cut filter used in the fluorescence level difference calculation.
The fluorescence level difference calculation processing module 600 calculates the fluorescence levels of the non-standard recording medium and the standard recording medium. The fluorescence level of the standard recording medium may be calculated in advance and stored in the storage unit 7.
5C can be approximated by a shape obtained by multiplying the basic waveform of FIG. 6 by a coefficient. That coefficient is the fluorescence level. Ra (λ) is the spectral reflectance of the target non-standard recording medium for calculating the fluorescence level without UV cut, and Rs (λ) is the spectral reflectance of the standard recording medium without UV cut. Let the calculated fluorescence level be RF (f). Spectral reflectance difference at 440 nm which is a peak of Rs (λ) and Rw (λ) and 520 nm which is a boundary between a short wavelength side affected by the fluorescent whitening agent and a long wavelength side which is not affected by the fluorescent whitening agent Let (fluorescence intensity prediction value) be fs and fu as shown in equations 4-1 and 4-2. Using the colorimeter parameters (mc ₀ , mc ₁ ) that correct the model difference between the colorimeters used to acquire Rs (λ) and Rw (λ), the fluorescence of the non-standard recording medium is expressed as shown in Equation 4-3. The strength prediction value fu is linearly converted to fu ′. The colorimeter parameters (mc ₀ , mc ₁ ) are set to (1, 0) when the colorimeter models used for obtaining Rs (λ) and Rw (λ) are the same. The fluorescence level RF (f) can be approximated by (a) linear conversion of the fluorescence intensity predicted value f without UV cut as shown in Equation 5-1.

The linear conversion parameters α and β in Equation 5 are set in advance. Several non-standard recording media having a relatively high fluorescence level are colorimetrically measured. (A) Spectral reflectance of non-standard recording medium without UV cut and (b) Spectral reflection of non-standard recording medium with UV cut The rate is obtained, and (c) the difference between with and without the UV cut filter is obtained.
The horizontal axis of the two-dimensional plane is the difference between 440 nm and 520 nm of each non-standard recording medium (= fluorescence intensity predicted value f), and the vertical axis is the difference value at 440 nm of each non-standard recording medium (= fluorescence level RF (f)). To obtain an approximate line. The intercept of the approximate line is α and the slope is β.
Next, the fluorescence level difference is calculated. When the fluorescence level of the non-standard recording medium is RF (fu) and the fluorescence level of the standard recording medium is RF (fs), RF (fu ′) − RF (fs) becomes the fluorescence level difference. In the actual calculation, as shown in Equation 5-2, the calculation is performed directly from the linear conversion parameters β, fu ′, and fs without using RF (fs) and RF (fu). That is, it is only necessary to store only β among the linear conversion parameters α and β. The linear conversion parameter β and the basic waveform of FIG. 6 are stored in the storage unit 7 in advance as a fluorescence level prediction parameter.

FIG. 7 is a diagram for explaining the colorimeter parameters (mc ₀ , mc ₁ ) for correcting the model difference between the colorimeters.
The colorimeter parameters (mc ₀ , mc ₁ ) are different from those of the colorimeter 1 that uses several non-standard recording media including those of various fluorescence levels when measuring the standard recording media. The color is measured with the color device 2 and set in advance. The colorimeter 2 is intended for all models that may be used for colorimetry on non-standard recording media. Parameters (mc ₀ , mc ₁ ) are set for each of the plurality of colorimeters 2.
The difference between 440 nm and 520 nm (= predicted fluorescence intensity f) obtained from the spectral reflectance of each non-standard recording medium obtained using the colorimeter 2 on the horizontal axis of the two-dimensional plane, and the colorimeter 2 on the vertical axis. The difference between 440 nm and 520 nm (= the predicted fluorescence intensity f) obtained from the spectral reflectance of each non-standard recording medium obtained using is plotted to obtain an approximate line. The intercept of the approximate straight line is mc ₁ and the slope is mc ₀ .

FIG. 8 is a block diagram showing a configuration of fluorescence level conversion for executing the image processing method according to the first embodiment of the present invention.
Estimate the difference in spectral reflectance between recording media according to the difference in fluorescence level between the non-standard recording medium and the standard recording medium, and combine it with the patch spectral reflectance formed on the standard recording medium to predict the patch on the non-standard recording medium Obtain the spectral reflectance.
The inter-recording medium spectral reflectance difference estimation processing module 601 estimates the difference value due to the fluorescence level difference among the spectral reflectance differences between the non-standard recording medium and the standard recording medium. Based on the fluorescence level prediction parameter (basic waveform in FIG. 6) and the color material masking parameter stored in the storage unit 7, a difference value corresponding to each of the patch spectral reflectances formed on the standard recording medium is estimated.
The composition processing module 602 adds the estimated difference value to the patch spectral reflectance formed on the standard recording medium.

FIG. 9 is a diagram for explaining the inter-recording medium spectral reflectance difference estimation process.
In the inter-recording medium spectral reflectance difference estimation processing module 601, the value obtained by multiplying the calculated fluorescence level difference by the basic waveform shown in FIG. 6 is the spectral of the non-standard recording medium between the standard recording medium and the non-standard recording medium. It becomes a reflectance difference estimated value.
Based on the spectral reflectance difference estimation value of the nonstandard recording medium and the color material masking parameter stored in advance in the storage unit 7, the color patch spectral reflectance difference between the nonstandard recording media is estimated.
The color material masking parameters Pw, Pc, Pm, Py... Are set at 16 points of 4D-LUT (four-dimensional LUT (Look Up Table)). The color patch spectral reflectance difference estimated value corresponding to each vertex is a value obtained by multiplying the spectral reflectance difference estimated value of the non-standard recording medium by the color material masking parameter. For example, the color patch spectral reflectance difference estimated value of (C, M, Y, K) = (100, 0, 0, 0) is multiplied by the color material masking parameter Pc to the spectral reflectance difference estimated value of the non-standard recording medium. It becomes the value.
The color patch spectral reflectance difference estimated value corresponding to the intermediate point (other than the vertex) of the 4D-LUT is calculated by linearly interpolating the spectral reflectance difference estimated value of the vertex at a ratio corresponding to the color patch dot area ratio.

FIG. 10 is a diagram for explaining the color material masking parameters used in the estimation of the spectral reflectance difference between recording media.
The optical brightener contained in the non-standard recording medium absorbs ultraviolet light and emits blue light. When a color material with a low ultraviolet light transmittance is placed on a non-standard recording medium, it exhibits an effect similar to a UV cut filter in a colorimeter, and is emitted because the ultraviolet light irradiated to the non-standard recording medium is reduced. Blue light is also reduced. For this reason, the spectral reflectance difference between non-standard recording media having different fluorescence levels is reduced.
The color material masking parameter is a parameter reflecting the ultraviolet light transmittance of each color material. In contrast to the parameter PW = 1 for the non-standard recording medium white, the Y (yellow) single color material masking parameter is PY = 0.02, which indicates that the color material has low ultraviolet light transmittance. It has become.

FIG. 11 is a diagram for explaining the patch spectral reflectance formed on the standard recording medium and synthesis.
It is assumed that the patch spectral reflectance formed on the standard recording medium is previously measured for 2401 color patches corresponding to the lattice points in FIG. 11 and stored in the storage unit 7.
The inter-recording medium spectral reflectance difference estimation processing module 601 calculates a color patch spectral reflectance difference estimated value corresponding to each grid point, and the synthesis processing module 602 adds the added value to the patch spectral reflectance formed on the standard recording medium. Ask. The added value becomes the predicted spectral reflectance of the patch in the non-standard recording medium.

FIG. 12 is a diagram for explaining a modification of the correction parameter setting unit in the image processing method according to the first embodiment of the present invention.
In FIG. 3, the first embodiment of the correction parameter setting unit 6 is shown. In the embodiment, processing is performed only by the spectral reflectance of the non-standard recording medium that varies for each non-standard recording medium.
Therefore, instead of storing the patch spectral reflectance formed on the standard recording medium in the storage unit 7, here, the correction parameters m _{11 to} m for each fluorescence level difference using the patch spectral reflectance previously formed on the standard recording medium. _The result of calculating ₃₄ may be stored.
The correction parameter selection processing module 603 selects the correction parameters m _{11 to} m ₃₄ corresponding to the fluorescence level difference calculated by the fluorescence level difference calculation processing module 600 from the correction parameter table for each fluorescence level difference stored in the storage unit 7. And output.

FIG. 13 is a diagram for explaining a modification of the image processing method according to the first embodiment of the present invention.
Here, a profile correction unit 8 is provided instead of the fluorescence correction unit 2A in the first embodiment (FIG. 1). In the present embodiment, the correction parameters m _{11 to} m ₃₄ set by the correction parameter setting unit 6 are applied to the profile correction unit 8.
The profile correction unit 8 generates a recording medium profile by correcting the standard recording medium profile. The color conversion unit 3A performs color conversion of the input image using the generated recording medium profile.
In the profile correction unit 8, the Lab value after the RGB → Lab conversion processing module 20 in the fluorescence correction unit (FIG. 2) in the first embodiment is input, and the CMYK after the color conversion unit 3A is output based on the standard recording medium profile. A recording medium profile is generated so that

In this way, the spectral reflectance of the non-standard recording medium is acquired, and the non-standard recording medium is measured based on the spectral reflectance of the non-standard recording medium, the colorimeter information of the non-standard recording medium, and the spectral reflectance of the standard recording medium. A correction parameter is set to match the apparent color of the image formed on the standard recording medium with the apparent color of the image formed on the standard recording medium, and the color profile of the standard recording medium is stored in the storage means. Based on the correction parameters, the color profile of the standard recording medium is corrected to a value suitable for the non-standard recording medium, and a color profile corresponding to the non-standard recording medium is generated, thereby correcting for the different non-standard recording medium. Parameter setting can be performed easily.
In addition, just by measuring the spectral reflectance of the recording medium with respect to the recording medium, the correction parameter setting or color profile corresponding to the recording medium can be obtained using the colorimetric values of a large number of patches formed on the standard recording medium acquired in advance. Since creation is performed, the user can easily perform correction parameter setting or color profile creation corresponding to recording media having different fluorescence characteristics, and the consumption of the recording media and color materials can be minimized.
In addition, the colorimeter information used when acquiring the spectral reflectance of the non-standard recording medium is acquired, and when setting the correction parameters, the spectral reflectance of the non-standard recording medium and the spectral reflectance of the standard recording medium are set. A fluorescence level difference between the non-standard recording medium and the standard recording medium is calculated based on the rate and the colorimeter information, and a correction parameter is set based on the calculated fluorescence level difference. Thereby, in the correction of the fluorescence characteristic difference between sheets, it is possible to easily perform the model difference correction of the colorimeter.
Furthermore, the fluorescence intensity of the non-standard recording medium is predicted from the spectral reflectance of the non-standard recording medium, and the fluorescence intensity of the standard recording medium is predicted from the spectral reflectance of the standard recording medium. The colorimeter parameters are set, the fluorescence intensity of the non-standard recording medium is corrected using the colorimeter parameters, and the corrected fluorescence intensity of the non-standard recording medium and the fluorescence intensity of the standard recording medium are corrected. Based on this, the fluorescence level difference between the non-standard recording medium and the standard recording medium is predicted. Thereby, in the correction of the fluorescence characteristic difference between sheets, it is possible to easily perform the model difference correction of the colorimeter.
As a result, even if the colorimetric measurement of the spectral reflectance of the recording medium is performed using a colorimeter different from that of the standard recording medium, the user can simply input the colorimeter information of the recording medium. It can correspond to.

Second Embodiment
FIG. 14 is a diagram for explaining an image processing method according to the second embodiment of the present invention.
In the image processing system 10 according to the second embodiment, as a functional configuration for realizing an image processing process, as shown in FIG. 14, an input image acquisition unit 1, an RGB → Lab conversion unit 20, and a recording medium difference correction & Color conversion unit 3B and printer output unit 4 are provided. Further, the image processing system 10 includes a recording medium side color value acquisition unit 50, a correction parameter setting unit 6, a recording unit 7, and an absolute value / relative value selection unit 9.
In the image processing system 10, the patch output to the non-standard recording medium used for output and the colorimetric value of the white background portion of the non-standard recording medium are acquired and the correction parameter is set. Next, the image processing system 10 performs color conversion on the input image based on the non-standard recording medium difference correction based on the correction parameter and the standard recording medium profile, forms an image with a printer, and outputs the image.

The non-standard recording medium colorimetric value acquisition unit 5B uses a colorimeter without a UV cut filter to measure the colorimetric values of patches output to the non-standard recording medium and the white background part of the non-standard recording medium. Acquires the color value (spectral reflectance). The light source of the colorimeter is a D50 standard light source.
Note that the present invention can be applied even when the light source is changed. Since the colors of the input image and the output image are relatively compared and corrected, the light source can be unified and applied to the images to be compared in this case.
Spectral reflectance measurement includes, for example, a colorimetric sensor as a technique for detecting spectral characteristic feature amounts by measuring an image formed by three bands of three primary colors of RGB on a non-standard recording medium. . For the measurement of spectral reflectance, a technique for recording light source information determined by this sensor on a non-standard recording medium or a multiband camera that performs imaging through various types of filters with different transmission wavelength ranges may be used. Good. Accordingly, the subject may be recorded as an image having a spectral distribution or spectral reflectance, or a commercially available side color meter may be used.
The recording medium colorimeter information acquisition unit 11 acquires the colorimeter information (model information) of the colorimeter used in the recording medium spectral reflectance acquisition unit 5B by the user.

The correction parameter setting unit 6 includes a colorimetric value for a non-standard recording medium patch and a white background part of the non-standard recording medium, colorimeter information used for colorimetry of the white part of the non-standard recording medium, and a standard recording medium. A correction parameter is set based on a large number of formed color patch colorimetric values (data previously measured and stored in the storage unit 7). The set correction parameters are stored in the storage unit 7 so that it is not necessary to acquire colorimetric values and set correction parameters again when the non-standard recording medium is output next time.
The input image acquisition unit 1 acquires input image data composed of three bands of RGB (red, green, and blue). Here, the description will be made assuming that the input image is an image represented by sRGB which is a standard color space.

The RGB → Lab conversion unit 2B converts the image data represented by sRGB into image data represented by a Lab value that is a uniform color space.
The non-standard recording medium difference correction & color conversion unit 3B forms an apparent color of an image formed on the non-standard recording medium on the standard recording medium based on the correction parameter set by the correction parameter setting unit 6. The color value is corrected so as to be the same as the apparent color of the image.
Further, in the color value correction processing, correction reflecting the result selected by the user by the absolute value / relative value selection unit 9 is performed. When the user selects an absolute value, the color value is corrected so that the apparent color of the image formed on the non-standard recording medium matches the apparent color of the image formed on the standard recording medium in absolute value. To do. In this case, some non-standard recording media may be output with a color such as yellow on the white background. If the user selects a relative value, the color value is corrected so that the apparent color of the image formed on the non-standard recording medium matches the relative color of the apparent color of the image formed on the standard recording medium. To do. In this case, the white background portion is output in white (no color) regardless of the non-standard recording medium. Color value correction processing is performed before and after color conversion performed based on the standard recording medium profile, and correction processing after color conversion is performed on CMYK, which is a color value corresponding to the color material color.
The printer output unit 4 forms an image by placing toner as a color material on a non-standard recording medium based on CMYK (cyan, magenta, yellow, black).

FIG. 15 is a block diagram showing a configuration of a recording medium difference correction & color conversion unit for executing the image processing method of the present invention.
Based on the correction parameters [A] to [F] set by the correction parameter setting unit 6, the color value correction and color conversion are specifically performed in the following procedure.
The Lab → XYZ conversion processing module 301 converts Lab into tristimulus values XYZ. The white point (L, a, b) of Lab = (100, 0, 0) is the white point of the D50 standard light source (X, Y, Z) = (96.42, 100.0, 82.49) Is converted to
The white point conversion 1 processing module 302 uses the Bradford conversion, which is a general chromatic adaptation conversion method, to convert the white point XYZ of the standard light source of the CIE standard light source D50 into the XYZ value of paper white of the standard recording medium, or non- Conversion into XYZ values of the white portion of the standard recording medium.
The Bradford conversion is a matrix conversion using a 3 × 3 conversion matrix for the tristimulus values XYZ, and the correction parameters [A] and [C] correspond to 3 × 3 conversion matrix coefficients. In accordance with an absolute value or relative value selection signal, the parameter switching processing module 303 selects either correction parameter [A] or [C].

The fluorescence correction processing module 304 performs the conversion process from XYZ to X′Y′Z ′ according to the above-described formula 1, and thus occurs due to the difference in the amount of fluorescent brightener contained in the standard recording medium and the non-standard recording medium. The color difference between recording media under the standard light source of the CIE standard light source D50 is corrected. The matrix coefficients m11 to m34 correspond to the correction parameter setting unit [D]. According to the fluorescence correction processing module 304, the white background portion XYZ of the non-standard recording medium is substantially corrected to the white background portion XYZ of the standard recording medium.
The white point conversion 2 processing module 305 converts the XYZ value of the white background portion of the standard recording medium into the white point XYZ of the D50 standard light source by using Bradford conversion processing. The correction parameter [D] corresponds to the 3 × 3 transformation matrix coefficient of the Bradford transformation process, and this is applied. The white point conversion 2 processing module 305 is an inverse conversion process when the white point conversion 1 processing module 302 applies the correction parameter [A] for the absolute value.
The XYZ → Lab conversion processing module 306 converts the color value represented by the tristimulus value XYZ into a color value in the uniform color space Lab. The white point XYZ of the standard light source of the CIE standard light source D50 is converted into the Lab white point, and the color value in the Lab space is restored.

The color conversion processing module 307 converts Lab values into CMYK values by a 3D-LUT (three-dimensional LUT (Look Up Table)) based on the standard recording medium profile.
The distortion correction processing module 308 corrects gamut distortion caused by transfer characteristics caused by a difference between non-standard recording media (a difference in surface roughness between a standard recording medium and a non-standard recording medium) by a correction parameter [E] and distortion correction processing. Process. Gamut distortion means that the color placed on the top of a non-standard recording medium is reduced in toner density due to the effect of residual transfer. In other words, the decrease in the density of the color placed on the top indicates that gamut distortion has occurred.
The TRC correction processing module 309 performs gradation correction based on TRC (Tone Reproduction Curve). The correction parameter [F] corresponds to TRC.

FIG. 16 is a block diagram illustrating a configuration of a correction parameter setting unit that executes an image processing method according to the second embodiment of the present invention.
The correction parameter setting unit 6 includes processing modules 161 to 163 for setting parameters [A] to [C] used in white point conversion performed before and after the fluorescence correction processing module 304, respectively.
In the correction parameter setting unit 6, the fluorescence correction parameter setting processing module 164 sets the correction parameter [D] of the fluorescence correction processing module 304. The distortion correction parameter setting processing module 165 sets the correction parameter [E] of the distortion correction processing module 308. The TRC correction parameter setting processing module 166 sets the correction parameter [F] of the TRC correction processing module 309.

In the setting processing modules 161 to 163 for setting white point conversion parameters, 3 × 3 conversion matrix coefficients for Bradford conversion processing are set. Set based on the white point before and after conversion. As a setting method, a known technique of conversion parameter setting is used.
The white point conversion parameter A setting processing module 161 sets conversion matrix coefficients for converting the tristimulus value XYZ value of the white point of the D50 standard light source into the tristimulus value XYZ value of the white background portion of the standard recording medium.

The white point conversion parameter B setting processing module 162 sets conversion matrix coefficients for converting the XYZ value of the white background portion of the standard recording medium into the white point XYZ of the D50 standard light source.
The white point conversion parameter C setting processing module 163 sets conversion matrix coefficients for converting the tristimulus value XYZ value of the white point of the D50 standard light source into the XYZ value of the white background portion of the non-standard recording medium.
The fluorescence correction parameter setting processing module 164 sets the correction parameters m _{11 to} m ₃₄ based on the spectral reflectances of the standard recording medium and the non-standard recording medium and the colorimeter information of the non-standard recording medium. Details of the correction parameters m _{11 to} m ₃₄ will be described later.
The distortion correction parameter setting processing module 165 sets four correction parameters (Ty, Tm, Tc, Tk). The set four correction parameter groups are set as a correction parameter [E].

As the distortion correction processing, gamut distortion generated due to roughness on the surface of the non-standard recording medium is corrected. Specifically, correction is performed by applying different equations defined by linear transformation functions for each color of YMCK.
The TRC correction parameter setting processing module 166 ensures that the color of 3C gray (C = M = Y patch), which is a representative color of which the color difference is worrisome between non-standard recording media, matches the standard recording medium. The TRC is set based on the 3C gray patch colorimetric value output to the standard recording medium and the patch colorimetric value of the color near 3C gray output to the non-standard recording medium. The set TRC is set as a correction parameter [F].

FIG. 17 is a flowchart for explaining parameter switching.
In step S11, it is accepted that the user has selected an absolute value or a relative value for a button provided on an operation unit (not shown). When the user selects an absolute value, the process proceeds to step S13 based on the determination result in step S12, and parameter [A] is selected.
When the user selects a relative value, the process proceeds to step S14 based on the determination result in step S12, and parameter [C] is selected.
First, a case where a relative value is selected (step S11) will be described.
When the relative value is selected, the white point conversion 1 processing module 302 performs matrix conversion using the correction parameter [C], so that the white point tristimulus value XYZ value of the D50 standard light source becomes the white background portion of the non-standard recording medium. Are converted into XYZ values.
In the fluorescence correction processing module 304, the tristimulus value XYZ value of the white background portion of the non-standard recording medium is corrected to the white background portion XYZ value of the standard recording medium. Therefore, before and after the white point conversion 1 and the fluorescence correction, the D50 standard light source The white point XYZ value is corrected to the white background XYZ value of the standard recording medium.
Then, the white point conversion 2 processing module 305 converts the XYZ value of the white portion of the standard recording medium into the white point XYZ value of the D50 standard light source. That is, before and after the white point conversion 1 to the white point conversion 2, the white point XYZ value of the D50 standard light source is converted into the white point XYZ value of the D50 standard light source, and the white point is substantially unconverted. This ensures that the white background is output in white regardless of the non-standard recording medium.

Next, a case where an absolute value is selected in step S11 will be described.
When the absolute value is selected, the white point conversion 1 processing module 302 performs matrix conversion using the correction parameter [A], so that the tristimulus value XYZ value of the white point of the D50 standard light source becomes the white background portion of the standard recording medium. Converted to XYZ values.
In the fluorescence correction processing module 304, the white background XYZ value of the non-standard recording medium is corrected to the white background XYZ value of the standard recording medium. At the same time, the white background XYZ value of the standard recording medium, which is the white point immediately before the fluorescence correction, is the opposite if the non-standard recording medium is paper that has more fluorescence than the standard recording medium and appears blue. It is corrected to a color like yellow. On the other hand, if the non-standard recording medium is paper that has less fluorescence than the standard recording medium and looks yellow, the color is corrected to the opposite color, such as blue. The reason why the fluorescence correction is performed in the direction opposite to the color of the paper is to make it coincide with the color formed on the standard recording medium when an image is formed on the paper and visually confirmed together with the paper. .

Then, in the white point conversion 2 processing module 305, the XYZ value of the white background portion of the standard recording medium (not the white point at this time) is converted into the white point XYZ of the D50 standard light source. That is, before and after the white point conversion 1 to the white point conversion 2, a point different from the white point XYZ of the D50 standard light source is converted to the white point XYZ of the D50 standard light source.
The white point XYZ of the D50 standard light source is converted to a yellowish color if the non-standard recording medium has more fluorescence than the standard recording medium, and the non-standard recording medium has less fluorescence than the standard recording medium. If so, it will be converted into a color like blue. As a result, depending on the amount of fluorescent whitening material contained in the paper, the white background is colored and output.

FIG. 18 is a diagram for explaining a modification of the image processing method according to the second embodiment of the present invention.
In the modification in the second embodiment, the recording medium difference correction & color conversion unit 3 in the second embodiment (FIG. 14) is replaced with a profile correction unit 8 and a color conversion unit 3A.
The profile correction unit 8 corrects the standard recording medium profile based on the correction parameters [A] to [F] set by the correction parameter setting unit 6 to generate a non-standard recording medium profile. The color conversion unit 3A performs color conversion of the input image using the generated recording medium profile.
A plurality of mounting forms of the profile correction unit 8 and the color conversion unit 3A are conceivable. One of them is shown.

The profile correction unit 8 sets 3 × 4 matrix coefficients based on input / output data from the white point conversion 1 processing module 302 to the white point conversion 2 processing module 305 shown in FIG. At the same time, the profile correction unit 8 sets a 3D-LUT (3D LUT (Look Up Table)) coefficient based on input / output data from the XYZ → Lab conversion processing module 306 to the TRC correction processing module 309 shown in FIG. To do. The set value is included in the recording medium profile.
In the 3 × 4 matrix coefficient setting, the matrix coefficients ma _{11 to} ma ₃₄ when the absolute value correction parameter [A] is selected by the parameter switching processing module 303 shown in FIG. 15, and the parameter switching processing module shown in FIG. A total of two sets of matrix coefficients mc _{11 to} mc ₃₄ when the correction parameter [C] for relative value is selected in 303 is set according to Expression 6 and Expression 7. Here, the correction parameter [A] is A _{11 to} A ₃₃ , the correction parameter [B] is B _{11 to} B ₃₃ , and the correction parameter [C] is C _{11 to} C ₃₃ .

In the 3D-LUT coefficient setting, a 3D-LUT is created from a set of input XYZ values to the XYZ → Lab conversion processing module 306 and output CMYK of the TRC correction processing module 309.
According to FIG. 18, since the color conversion processing module 307 applies the 3D-LUT of the standard recording medium profile, the 3D-LUT created here is a standard recording created based on the 3D-LUT coefficient of the standard recording medium profile. This is a modified version of the media profile.
The generated recording medium profile is stored in the storage unit 7 so that it is not necessary to acquire a colorimetric value, set a correction parameter, or modify a profile again when the recording medium profile is output next time.

FIG. 19 is a block diagram showing a configuration of a color conversion unit that executes the image processing method of the present invention.
The Lab → XYZ conversion processing module 311 converts the Lab value of the input image into an XYZ value, and then 3 × 4 matrix coefficients and 3D-LUT coefficients of the recording medium profile inclusion set by the profile correction unit 8. The 4 matrix conversion processing module 313 performs 3 × 4 matrix conversion, and the 3D-LUT conversion processing module 314 performs 3D-LUT conversion. 3 × 4 matrix conversion processing module 313, according to the selection signal of the absolute value or relative value, applying one of the matrix coefficients _ma 11 _{to Ma 34} or _mc 11 _{to MC 34} selected by the parameter switching processing module 312.

絶対値が選択された場合、相対値が選択された場合、それぞれ白色点がどのように変換されるかについては、図１７のところで説明したのと同じ結果が得られる。
このように、蛍光補正前に行う白色点変換を切り替えることで、標準記録媒体に対して絶対値で合わせる場合と相対値で合わせる場合の両方に対応するので、記録媒体に含まれる蛍光増白材の影響が及ぶ画像領域の再現色を標準記録媒体と一致させる蛍光補正を行う場合に、標準記録媒体に対して絶対値又は相対値のいずれかで合わせるユーザの要望に、容易に対応することができる。 FIG. 20 is a flowchart for explaining parameter switching.
In step S11, it is accepted that the user has selected an absolute value or a relative value for a button provided on an operation unit (not shown). When the user selects an absolute value, matrix coefficients ma _{11 to} ma ₃₄ are selected in step S15 according to the determination result (Yes) in step S12. The 3 × 4 matrix conversion processing module 313 performs the conversion of Expression 8.
When the user selects a relative value, the matrix coefficients mc _{11 to} mc ₃₄ are selected in step S16 based on the determination result (No) in step S12. The 3 × 4 matrix conversion processing module 313 performs the conversion of Expression 9.

When the absolute value is selected, or when the relative value is selected, the same result as described with reference to FIG. 17 is obtained as to how each white point is converted.
In this way, by switching the white point conversion performed before the fluorescence correction, both the case of matching with the standard recording medium with the absolute value and the case of matching with the relative value are supported, so the fluorescent whitening material included in the recording medium When performing fluorescence correction to match the reproduction color of an image area affected by the same as that of a standard recording medium, it is possible to easily respond to a user's request to match the standard recording medium with either an absolute value or a relative value. it can.

<Third Embodiment>
FIG. 21 is a diagram for explaining the image processing system 10 according to the third embodiment of the present invention. With reference to FIG. 21, an image forming apparatus connected to a server via a network will be described.
A server 101 and an image forming apparatus 102 including a printer output unit 4 are connected via a network 100.
In the third embodiment, in the image forming apparatus 102 according to the first embodiment, the correction parameter setting unit 6 and the storage unit 7 are provided in the server 101, and other processing blocks are provided in the image forming apparatus 102. It may be configured.
Alternatively, in the third embodiment, among the modifications of the image forming apparatus according to the first embodiment, the correction parameter setting unit 6, the storage unit 7, and the profile correction unit 8 are placed in the server 101, and other processing blocks are imaged. It may be configured to be provided in the forming apparatus 102.

The server 101 includes a receiving unit (not shown) that receives the spectral reflectance of the nonstandard recording medium acquired by the image forming apparatus 102. The server 10 also has an image formed on the standard recording medium with an apparent color of the image formed on the non-standard recording medium based on the spectral reflectance of the non-standard recording medium and the spectral reflectance of the standard recording medium. A correction parameter setting unit (not shown) for setting a correction parameter for matching the apparent color. The server 101 also includes a color profile storage unit (not shown) that stores the color profile of the standard recording medium. Furthermore, the server 101 includes a transmission unit (not shown) that transmits the correction parameter and the color profile of the standard recording medium read from the color profile storage unit to the image forming apparatus 102 via the network.
The image forming apparatus 102 uses, for example, four colors of cyan (C), magenta (M), yellow (Y), and black (K) as basic color materials, and forms a full-color image on a recording medium using these mixed colors.

The user gives a transmission instruction to the image forming apparatus 102, and transmits the spectral reflectance of the nonstandard recording medium acquired by the image forming apparatus 102 to the server 101.
The server 101 receives the spectral reflectance of the nonstandard recording medium acquired by the image processing apparatus 102 via the network 100. The server 101 is an image formed on the standard recording medium with an apparent color of the image formed on the non-standard recording medium based on the spectral reflectance of the non-standard recording medium and the spectral reflectance of the standard recording medium. Set the correction parameter to match the apparent color. Next, the set correction parameters and the color profile of the standard recording medium are transmitted to the image processing apparatus 102 via the network.
By configuring the image processing system 10 in this way, each image forming apparatus 102 stores a correction parameter table for each patch spectral reflectance or fluorescence level difference formed on a standard recording medium that requires a relatively large storage capacity. No need to remember. For this reason, the image forming apparatus 102 that does not have the large-capacity storage unit 7 can easily correct the fluorescence characteristics corresponding to the recording medium.
The image processing system 10 is connected to a recording medium spectral reflectance acquisition unit 5A or a recording medium side color value acquisition unit 5B for an image formed on the recording medium by the image forming apparatus 102. For example, a spectrocolorimeter is used as the recording medium spectral reflectance acquisition unit 5A or the recording medium side color value acquisition unit 5B. A scanner can be used instead.
In addition, when the recording medium spectral reflectance acquisition unit 5A or the recording medium side color value acquisition unit 5B is assumed to use a plurality of types of colorimeters, the colorimeter information of the nonstandard recording medium is stored in the nonstandard recording medium. Are transmitted to the server 101 as a set with the spectral reflectance. On the other hand, the server 101 is formed on the non-standard recording medium based on the spectral reflectance of the non-standard recording medium received from the image processing apparatus 102, the colorimeter information of the non-standard recording medium, and the spectral reflectance of the standard recording medium. A correction parameter for matching the apparent color of the image to be formed with the apparent color of the image formed on the standard recording medium may be set. Thereby, in the correction of the fluorescence characteristic difference between sheets, it is possible to easily perform the model difference correction of the colorimeter.

DESCRIPTION OF SYMBOLS 1 ... Input image acquisition part, 2A ... Fluorescence correction | amendment part, 2B ... RGB-> Lab conversion part, 11 ... Recording-medium colorimeter information acquisition part, 20 ... RGB-> Lab conversion processing module, 21 ... Lab-> XYZ conversion processing module, 22 ... Matrix conversion processing module, 23 ... X'Y'Z '→ L'a'b' conversion processing module, 3A ... Color conversion unit, 3B ... Recording medium difference correction & color conversion unit, 301 ... Lab → XYZ conversion processing Module 302 302 White point conversion 1 processing module 303 Parameter switching processing module 304 Fluorescence correction processing module 305 White point conversion 2 processing module 306 XYZ → Lab conversion processing module 307 Color conversion processing module 308 ... Distortion correction processing module, 311 ... Lab → XYZ conversion processing module, 312 ... Parameter cut 313 ... 3 × 4 matrix conversion processing module, 314 ... 3D-LUT conversion processing module, 4 ... printer output unit, 5A ... recording medium spectral reflectance acquisition unit, 5B ... recording medium side color value acquisition unit, 6 ... Correction parameter setting unit, 60 ... Fluorescence level conversion processing module, 61 ... Spectral reflectance → XYZ conversion processing module, 62 ... Multiple regression analysis processing module, 63 ... White correction processing module, 600 ... Fluorescence level difference calculation processing module, 601 ... Inter-recording medium spectral reflectance difference estimation processing module, 602 ... Synthesis processing module, 603 ... Correction parameter selection processing module, 604 ... Fluorescence intensity prediction processing module, 605 ... Fluorescence intensity prediction processing module, 606 ... Colorimeter parameters Selection processing module, 607 ... Colorimeter model difference correction processing module 608 ... fluorescence level difference prediction processing module, 609 ... TRC correction processing module, 7 ... recording unit, 8 ... profile correction unit, 9 ... absolute / relative value selection unit, 10 ... image processing system, 100 ... network, 101 ... Server, 102 ... image forming apparatus

JP 2009-278362 A JP 2008-060719 A JP2012-142920A

Claims (13)

A correction parameter is set so that the apparent color of the image formed on the non-standard recording medium having the spectral reflectance of the surface different from that of the standard recording medium matches the apparent color of the image formed on the standard recording medium. An image processing method to be set,
Obtaining the spectral reflectance of the non-standard recording medium;
Based on the spectral reflectance of the non-standard recording medium and the spectral reflectance of the standard recording medium, the apparent color of the image formed on the non-standard recording medium is changed to that of the image formed on the standard recording medium. A correction parameter setting step for setting a correction parameter to match the apparent color;
A color profile storage step of storing a color profile of the standard recording medium in a storage means;
A color profile generation step of correcting the color profile of the standard recording medium to a value suitable for the non-standard recording medium based on the correction parameter, and generating a color profile corresponding to the non-standard recording medium. An image processing method characterized by the above. The correction parameter setting step calculates a fluorescence level difference between the non-standard recording medium and the standard recording medium based on the spectral reflectance of the non-standard recording medium and the spectral reflectance of the standard recording medium. A fluorescence level difference calculating step;
The image processing method according to claim 1, further comprising a setting step of setting a correction parameter based on the fluorescence level difference calculated in the fluorescence level difference calculating step. Obtaining colorimetric information used when obtaining the spectral reflectance of the non-standard recording medium,
The correction parameter setting step includes:
Fluorescence for calculating a fluorescence level difference between the non-standard recording medium and the standard recording medium based on the spectral reflectance of the non-standard recording medium, the spectral reflectance of the standard recording medium, and the colorimeter information A level difference calculating step;
The image processing method according to claim 1, further comprising a setting step of setting the correction parameter based on the fluorescence level difference calculated in the fluorescence level difference calculating step. The fluorescence level difference calculating step includes:
A first fluorescence intensity prediction step for predicting the fluorescence intensity of the non-standard recording medium from the spectral reflectance of the non-standard recording medium;
A second fluorescence intensity prediction step for predicting the fluorescence intensity of the standard recording medium from the spectral reflectance of the standard recording medium;
A colorimeter parameter setting step for setting colorimeter parameters according to the colorimeter information;
Using the colorimeter parameters, a colorimeter model difference correction step for correcting the fluorescence intensity of the non-standard recording medium,
The fluorescence level between the non-standard recording medium and the standard recording medium based on the fluorescence intensity of the non-standard recording medium corrected by the colorimeter model difference correcting step and the fluorescence intensity of the standard recording medium The image processing method according to claim 3, further comprising: a fluorescence level difference prediction step for predicting the difference. An image acquisition step of acquiring input image data to be formed on the non-standard recording medium;
The image processing method according to claim 1, further comprising: a correction step of correcting an apparent color value of the image of the input image data based on the correction parameter. The color profile storing step stores the spectral reflectance of the standard recording medium in the storage means,
The correction parameter setting step is based on a color patch colorimetric value formed on the standard recording medium and a value obtained by converting the color patch colorimetric value formed on the standard recording medium into a fluorescence level according to the fluorescence level difference. 2. The image processing method according to claim 1, wherein correction parameters are set. The color profile storing step stores a correction parameter calculated for each fluorescence level difference based on a color patch colorimetric value formed on the standard recording medium in the storage unit,
The correction parameter setting step selects a correction parameter corresponding to the fluorescence level difference calculated in the fluorescence level difference calculation step from correction parameters calculated for each fluorescence level difference. Image processing method. A selection step for selecting whether the correction parameter matches color with an absolute value or a relative value with respect to a standard recording medium;
A first white point conversion step of converting the color value of the white point into a color value corresponding to an absolute value or a color value corresponding to a relative value;
A non-standard recording medium spectral reflectance acquisition step of acquiring spectral reflectances of a standard recording medium and a non-standard recording medium in a predetermined light source;
A fluorescence level difference calculating step for calculating a fluorescence level difference between the standard recording medium and the non-standard recording medium based on the spectral reflectance of the non-standard recording medium acquired by the non-standard recording medium spectral reflectance acquisition step; ,
The color value after the first white point conversion step is formed on the non-standard recording medium under the predetermined light source based on the fluorescence level difference calculated by the fluorescence level difference calculation step. A fluorescence correction step for performing fluorescence correction to match the apparent color of the image to the apparent color of the image formed on the standard recording medium,
2. The color value corresponding to the absolute value is a color value of a white background portion of a standard recording medium, and the color value corresponding to the relative value is a color value of a white background portion of a non-standard recording medium. The image processing method according to claim 1. Regardless of whether it is an absolute value or a relative value with respect to the color value after the fluorescence correction step, the color value of the white background portion of the standard recording medium is changed to the white point of the conversion source in the first white point conversion step. A second white point conversion step for converting to a color value;
The image processing method according to claim 8, further comprising: A non-standard recording medium profile generation step of generating a non-standard recording medium profile by modifying a standard recording medium profile based on the correction parameter;
A color conversion step of performing color conversion of an input image using the profile of the non-standard recording medium generated by the non-standard recording medium profile generation step,
The profile of the non-standard recording medium used in the color conversion step includes a matrix conversion coefficient corresponding to an absolute value, a matrix conversion coefficient corresponding to a relative value, and a 3D-LUT coefficient. The image processing method according to claim 7. A correction parameter is set so that the apparent color of the image formed on the non-standard recording medium having the spectral reflectance of the surface different from that of the standard recording medium matches the apparent color of the image formed on the standard recording medium. An image processing program to be set,
Obtaining the spectral reflectance of the non-standard recording medium;
Based on the spectral reflectance of the non-standard recording medium and the spectral reflectance of the standard recording medium,
A correction parameter setting step for setting a correction parameter for matching the apparent color of the image formed on the non-standard recording medium with the apparent color of the image formed on the standard recording medium;
A color profile storage step of storing a color profile of the standard recording medium in a storage means;
A color profile generating step for correcting the color profile of the standard recording medium to a value suitable for the non-standard recording medium based on the correction parameter, and generating a color profile corresponding to the non-standard recording medium, and An image processing program for causing a computer to execute a step. A server, and an image processing apparatus connected to the server via a network, the image processing apparatus having a spectral reflectance of a surface different from that of a standard recording medium using correction parameters received from the server An image processing system for setting correction parameters so as to match an apparent color of an image formed on a non-standard recording medium with an apparent color of an image formed on a standard recording medium,
The image processing apparatus includes:
Obtaining means for obtaining spectral reflectance of the non-standard recording medium;
Transmission means for transmitting the spectral reflectance of the non-standard recording medium acquired by the acquisition means to a server,
The server
Receiving means for receiving a spectral reflectance of the non-standard recording medium acquired by the image processing apparatus;
Based on the spectral reflectance of the non-standard recording medium and the spectral reflectance of the standard recording medium, the apparent color of the image formed on the non-standard recording medium is changed to the appearance of the image formed on the standard recording medium. Correction parameter setting means for setting a correction parameter for matching with the above color;
Color profile storage means for storing a color profile of the standard recording medium;
An image processing system comprising: a transmission unit configured to transmit the correction parameter set by the correction parameter setting unit and the color profile of the standard recording medium read from the color profile storage unit to the image processing apparatus. . The image processing apparatus includes:
Colorimeter information acquisition means for acquiring colorimeter information used when acquiring the spectral reflectance of the non-standard recording medium;
Transmission means for transmitting the colorimeter information acquired by the colorimeter information acquisition means to the server;
The server
The apparatus further comprises receiving means for receiving the colorimeter information acquired by the image processing apparatus,
The correction parameter setting means includes an apparent color of an image formed on the non-standard recording medium based on the spectral reflectance of the non-standard recording medium, the spectral reflectance of the standard recording medium, and the colorimeter information. 13. The image processing system according to claim 12, wherein a correction parameter is set so as to match an apparent color of an image formed on the standard recording medium.

Images