KR0128706B1 - Tonal conversion method for pictures - Google Patents

Abstract

The present invention is to provide a color scanner that can always produce a chain plate having a halftone array according to the plate-making design, a reduced gray scale conversion plate, and to produce a printed disc of halftone gradation from a color photograph image of continuous gradation. In the color scanner, (i) the density measuring unit of each pixel (n point) of the color photographic document of the color scanner has the sharpest part (H), its vicinity and its darkest part (S), and its representative concentration value (DH) in its vicinity. _av and DS _av ), and (ii) the tone converter of the color scanner defines (a) the vertical axis (D axis) indicating the density value and the horizontal axis (X axis) indicating the image information value correlated with the light quantity in the DX rectangular coordinate system. (B) converting the density value Dn of each pixel into an image information value Xn correlated with the amount of light using the density characteristic curve of the photographic material provided for photographing the color photograph document. To the estimated Bochy (Xn) by using the gray-scale transformation and being configured to convert the halftone dot area percentage value (y).

Gradation Conversion

y = y _H + [α (1-10 ^-KX ) / (α-β)] × (y _s -y _H )

Description

Color scanner

1 shows the photo density characteristic curve of the color photographic photosensitive material.

2 is a schematic diagram illustrating the dispersion state of silver particles in an emulsion layer within the field of view of a color scanner.

3 is a view for explaining the device configuration of the color scanner of the present invention.

* Explanation of symbols for main parts of the drawings

1: detection unit, 2: color separation unit,

3: gradation adjusting unit, 4: output unit,

5: color photo document, 6: conversion unit,

7: log amplifier, 8: basic masking unit,

9: color correction unit, 10: VCR / UCA unit,

11: gradation conversion unit, 12: color channel selector,

13: A / D conversion part, 14: dot control part

Industrial use field

The present invention relates to a color scanner (making machine) for manufacturing a printing disc.

More specifically, the present invention provides a density measuring unit and an appropriate density value from the density measuring unit for excluding the non-uniformity of the measured density values of the sharpest part (H) and the darkest part (S) of the color photographic document which greatly affect the image quality of the printed image. And a gradation converting section for converting a continuous gradation of an original image into a halftone gradation of a printed image based on a new gradation conversion formula.

Conventional technology

As is well known, in the conventional photographic or electronic engraving technology, a photographic printing camera was used from a continuous gradation of original images (single or multicolor photographic images, forge and negative photographic images, reflection and transmission photographic images, etc.). A film separation operation (which includes colorimetric and network photography) using an electronic engraving machine such as a monochrome scanner, a color scanner, a total scanner, etc. I am writing.

In the above-mentioned color separation operation, R / G / B-based image information (Red) obtained from photographic documents such as a masking equation or a Neugebauer equation for the "color separation process" (narrow meaning color separation). Reasonable to convert the image information obtained by the color filter, the green filter, and the blue filter) into C / M / Y-based image information (image information in which each ink of cyan, magenta, and yellow is displayed in a mixed color system). Approach is once developed.

However, the important factors for expressing the printed image are `` C / M / Y angular color ink '' (more precisely the reflection density of ink) and `` dotted dot '' to which the ink is applied (more precisely the size of dot, dot area%). Chi) are two types, and the reality is that there is no scientific and rational approach to the latter.

In other words, it is not an exaggeration to say that there is no scientific approach to determine what size dot dots are to be arranged for each pixel over the entire range (Dynamic range) of the brightest part H and the darkest part S of the printed image.

As described above, the printed image is reproduced on the basis of the interaction between the dots and the printed ink coated on it. It is needless to say that the interaction is not limited to only the dot of the pixel of interest, but also includes the interaction with the array of dot arrays around it.

Therefore, the scientific management of "dot dots" in consideration of the above-mentioned interactions is an extremely important problem in the creation of printed images having excellent image quality.

However, the advantage is lacking in the prior art as described above.

Needless to say, the above-mentioned rational management technique of "dot dots" is called "gradation conversion technique", and this term is used in the following description.

An example of immaturity in the prior art which is the above-described gradation conversion technique will be described below.

That is, the gradation conversion technology of the image converting from the current continuous gradation original image to the halftone gradation print image is essentially still experienced by human designers and designers of plate making equipment such as color scanners or workers using the same. Or, what is done on the basis of one or more fixed conditions of data is real, unscientific, unreasonable, and lacking flexibility at all.

In addition, when using the advanced engraving equipment such as monochrome scanners or color scanners to perform gradation conversion by performing color separation (chromometry) and network photography, the job standard characteristic curve (gradation conversion curve, state) Reproduction curves, color separation curves, etc.) are used by the device manufacturer in advance based on experience, feeling, or data based on a limited number of fixed conditions, which are stored in the device's memory.

Therefore, the operator who uses a synchronous machine is subject to basic constraints on the quality and number, which are technical and operational choices, in the plate making operation, according to the irrational and unscientific knowledge of the design engineer of the synchronous machine. In addition, the quality and scope of technical and operational responses to high and diverse demands of print images and non-standard manuscript images (images of color manuscripts with quality other than those envisaged by the designer of the engraving machine, etc.). Is limited, and only toward the adjustment of the gradation of the image based on the experience and feeling of the operator.

In addition, the inventors of the present invention, as described above, do not have the necessary and sufficient knowledge of plate making and printing, and the design technology of the advanced engraving machine such as a monochrome scanner and a color scanner is not available. It is composed of color separation theory based on systematic photographic masking method, and it is thought that repeated improvement of motivation is basically a coping therapy action based on the color separation theory.

That is, in the conventional design technique of the scanner device, when the gradation is converted from the continuous gradation image of the photographic document to the dot gradation image by the color separation operation, the gradation adjustment of the image is performed with the first purpose as the color correction or color masking. The reason for this is that it is failing to stabilize and improve the image quality of printed images.

Problems to be Solved by the Invention

As described above, in the conventional gradation conversion technique from a continuous gradation image to a halftone gradation image, the density value at an arbitrary sampling point (pixel point) of the continuous gradation image and the corresponding sample point of the halftone gradation image There was no means to reasonably and universally correlate the halftone percentage of halftone dots.

In order to reasonably produce a printed image, the inventors of the present invention, before the improvement of the color correction (correction) technology of the two core technologies, gradation control (coloration) and color correction (correction) technology Based on the idea that the gradation conversion technique for reasonably converting the density gradation of each pixel must be important, the research has been intensively attempted to overcome the limitations of the conventional irrational and unscientific gradation conversion techniques.

As a result, a novel gradation conversion method is proposed in which the basic concentration value of an arbitrary sample point in the sequential gradation image as the original image and the percentage of halftone area at the sample point in the halftone gradation image corresponding thereto are devised. This new, rational and scientific gradation conversion method has been sufficiently applied to conventional plate making equipment, and it has also been found to overcome the limitations of the conventional color separation technology to express excellent effects. 135825 and 2-5524.

The above-described technique proposed by the inventors of the present invention is to use a gradation conversion equation similar to the present invention in gradation conversion of an image (as described below, the operating conditions of the gradation conversion equation are completely different). In order to produce reproducibly printed images, there is still room for improvement.

The above room for improvement is that the measured concentration values of H and S of the original image are inevitably accompanied by nonuniformity, and if the advantages are not solved, it is impossible to produce a reproducibly printed image with excellent image quality according to the plate making design. to be.

The color scanner of the present invention solves the above-mentioned problems, and obtains image information values correlated with the amount of light based on the density measurement unit excluding the nonuniformity in the measured concentration values of the original image H and S and the density values from the density measurement unit. The gradation conversion unit that converts gradations thereon is added to the components of the conventional scanner, whereby the printed image according to the plate making design can be produced with good reproducibility.

Means to solve the problem

SUMMARY OF THE INVENTION The present invention provides a color scanner for producing a printed negative-tone printed disc from continuous color photographs, i) the density measurement unit of each pixel (n point) of the color photograph document of the color scanner. (H), its near portion, and its darkest portion (S) and its representative concentration values (DH _av and DS _av ) in its vicinity, and (ii) the gradation conversion section of the color scanner (a) The density value Dn of each pixel by using the density characteristic curve of the photographing material provided for photographing the color photograph document specified in the DX rectangular coordinate system of the horizontal axis (X axis) indicating the image information value correlated with the amount of light. And (b) convert the image information value X _n correlated to the light amount into a halftone area% value y using the following gray scale conversion equation. To color scanner Will.

Gradation Conversion

y = y _H + [α (1-10 ^-KX ) / (α-β)] × (y _s -y _H )

In the gradation conversion equation, the basic light quantity value expressed by X: X = (X _n -X _H ), that is, the density value D _n of any pixel (n point) on the original is specified in the DX rectangular coordinate system. A difference between the image information value (X _n ) correlated with the amount of light determined through the density characteristic curve and the image information value (X _H ) correlated with the light amount corresponding to the average concentration value (DH _av ) of the H portion.

y: halftone area% value of the pixel on the printed disc corresponding to an arbitrary pixel (n point) on the original

y _H :% value of the halftone area preset in advance for H on the printed disc corresponding to H on the original

y _s :% of the halftone area preset in advance for S on the printed original corresponding to S of the original image.

α: surface reflectivity of printing paper.

β: numerical value determined by β = 10 ^−γ .

K: A value determined by K = γ / (X _s -X _H ).

In the above formula, X _s denotes an image information value correlated with the amount of light obtained from the representative concentration value DS _av of the S section through the density characteristic curve defined in the DX rectangular coordinate system.

γ: arbitrary coefficient

Respectively.

Hereinafter, the technical configuration of the present invention will be described in detail.

First of all, in order to help the understanding of the present invention, an important concept of image information that is a target of gradation conversion, that is, image information correlated with light quantity (hereinafter referred to simply as light quantity value) and its light quantity value ), And more specifically, a method for setting the tone conversion curve (color separation curve) will be described.

As described above, the present inventors have made intensive studies to make the setting technique of the gradation conversion curve (color separation curve, state reproduction curve) which forms the core of the color separation work rational. Among them, the conventional color plate (C / M / Y plate), for example, when manufacturing C plate, which is the standard of plate making, is defined in the relationship between the concentration value obtained through the complementary R (red) filter and the halftone area% value. Instead of the setting technology for the color plated C-curve that is used for the C plate, the exposure value is determined by using the photoconcentration characteristic curve of the photosensitive member of the color photographic film on which the original image is taken (as described later in the present invention, the concept is called a light quantity value). (The term "light quantity value" is used hereafter), and the light quantity value is converted by a specific tone conversion formula to obtain the halftone area% value, that is, the color separation curve specified in the relationship between the light quantity value and the halftone area% value. When setting the, the image quality of the original image under the color separation curve (e.g. under / over exposure is extremely high). Difficulties, documents with various color flows, faded documents, etc.) Printed images having excellent gradation characteristics have been obtained.

In addition, the color separation curve for each color plate defined in the relationship between the conventional density value and the halftone area% value described above is important for image information from the density (Density) in the characteristic curve of the photo film photosensitive material. It is called axial chromatization curve.

On the other hand, the color separation curve for each color plate defined in the relationship between the light quantity value and the halftone area% value of the present invention is important in that the image information from the light quantity axis of the horizontal axis (X axis) in the characteristic curve is X-axis. It is called color separation curve.

As described above, the present invention does not depend on the image quality of a color document (either a positive, negative, transmissive, reflective type, etc.) to be plated, and for example, an original of an over / normal / under exposure, In order to create a print of excellent image quality from high-key / low-key originals, various color-blurred or faded originals, and the like, the light quantity value is used as image information because of gradation conversion. This is a remarkable difference from the prior art.

In the gradation conversion (conversion of continuous gradation to halftone gradation), the reason for using the "light intensity value" rather than the "concentration value" of the original image is as follows.

In order to rationally convert various original images of the above-described image quality, the `` concentration value '' is not used only depending on the photo density characteristic curve of each color film sensor. When the light quantity value from the incident subject (the literal base of the original image. The actual image snow scene) is used, the image information does not depend on the photograph density characteristic curve (characteristic of the photographic material). Even if it is based on the invention of the present inventors etc., whether the tone conversion may be rational uniformly.

Next, a method of setting the X-axis color separation curve of each color plate, for example, C plate, using the light quantity value will be described.

First, a light quantity value must be obtained from the color photograph document as image information.

The light quantity value can be easily obtained from the photographic density by using the characteristic curve of the color photographic film sensitizer (photosensitive emulsion) on which the original image is photographed, the so-called photoglaphic characteristic curve. .

The photographic concentration characteristic curve is represented by a D-X rectangular coordinate system in which the vertical axis represents the concentration D, and the horizontal axis X represents the exposure dose.

In order to obtain the light quantity value, the photograph density characteristic curve of the color photographic film sensitizer on which the original image is photographed must be functionalized.

Thereby, the light quantity value X _n of the corresponding pixel can be obtained from the density value D _n of any pixel point (n point) in the original image. The photo density characteristic curve is a function of what can be obtained from each photographing material maker as technical data.

For example, in FIG. 1, the photoconcentration characteristic curves of the acta chromium 64 made by Ek company, and the propane film (daylight) were shown.

The method of functionalizing the photographic concentration characteristic curve is not particularly limited and may be in accordance with a desired method. Needless to say, as shown in FIG. 1, each of the photosensitive emulsions of R / G / B of the color photographic film has a characteristic curve, so that the amount of light for the production of the corresponding color plate must be obtained by functionalizing them.

The results are shown in Table 1, and in Table 1, the formulating division is plural in order to formulate the photograph density characteristic curve as accurately as possible.

TABLE 1

In the present invention, when the photograph density characteristic curve as shown in Fig. 1 is functionalized, the scale of the X axis indicating the light amount value represented by the scale of the D-axis representing the density value of the color photograph document and the Log E of the subject (real image). The functionalization of D and X was performed by making into the same thing.

Scaling about this D-axis and X-axis was performed from the following viewpoint, and it is thought that it is completely reasonable for this inventor.

That is, in the photographic concentration lateral curve, the logarithmic value (log E = log I x t) of the exposure dose E is nailed to the X-axis so that its physical quantity is evaluated by the logarithmic distinction characteristic of the contrast of human vision.

On the other hand, the physical quantity related to the concentration of the D axis is also evaluated algebraically from the human perspective. Therefore, it is considered that there is no unreasonableness even when the D-axis and the X-axis are correlated under the same scaling.

In addition, in this invention, said graduation is a kind of simple method, and it goes without saying that it is not limited to this. For example, it may be functionalized in the numerical relationship between the D-axis and the X-axis shown in FIG. Including the above state meaning, in the present invention, the physical quantity of the X-axis is expressed by the term "light quantity value" which is a concept including an exposure amount value.

The present invention is not based on the density value (D _n value) of the color photograph document in the gray scale conversion as described above, but rather is an image information value provided by a subject (real image or real view), that is, a light amount value appearing on the X axis ( X _n value).

Since the correlation by the function formula of D _n value and the X _n value and the X = F (D) as described by hamsuhwa of picture density characteristic curve as described above, as shown in Table 1 easily from D _n value X _n value You can get it.

As described above, the light quantity value X _n contributed by the subject (real image) can be obtained. Subsequently, the X-axis color decomposition curve that focuses on the amount of light instead of the D-axis color separation curve that focuses on the conventional density information value, i.e., by using the X _n value reasonably obtained and the gray-scale conversion equation can be obtained. It is only. Further, from the density value D _n at any pixel (n point) on the color photograph document under a predetermined photograph density characteristic curve, the light quantity value X _n of the pixel on the corresponding subject (real image) is obtained, and X _By substituting the _n value into the gradation conversion equation, the halftone area% value, which is the gradation intensity value, is calculated, and the X-axis color separation curve is set.

The operation of the gradation conversion _formula is performed by using the light amount values X _H and X _S corresponding to the density values D _H and D _S of the sharpest part H and the darkest part S designated on the original image.

However, it is a central subject of the present invention to recognize that unevenness inevitably arises in the concentration measurement values of the sharpest part H and the darkest part S, and to solve the serious drawback caused by this. This advantage is described later in detail.

In the operation of the gradation conversion _formula , the light quantity value X _n must be converted into the basic light quantity value X _n as described above, but this is the halftone area% value (y ₁₁ , y _S ) is the contrast needed to secure. In addition, in order to produce a C plate of halftone gradation, the dot generator of the color scanner only needs to be operated in accordance with the X-axis color separation curve for the C plate.

Next, the derivation process of the above-described gradation conversion formula of the present invention and its characteristics will be briefly described here.

In the production of printed images which are halftone gradations, the tone conversion formula for calculating the numerical value y of the halftone area value set for each pixel in the original image is a density formula (photo density, optical density), which is generally accepted.

That is, D = log I ₀ / I = log 1 / T

However, it is derived based on I ₀ = incident light amount, I = reflected light amount or transmitted light amount, and T = I / I ₀ = reflectance or transmittance.

The general formula for this concentration D is applied to plate making and printing as follows.

Density (D ') in plate making and printing = log I ₀ / I = log (reflectance of unit area x paper) / {(unit area-halftone area) x reflectance of paper + halftone area x ink surface reflectivity} = logαA / [α {A- (d ₁ + d ₂ +… d _n )} + β (d ₁ + d ₂ +… d _n )]

Where A is the unit area, d _n is each dot area within the unit area, α is the reflectance of the printing paper, and β is the surface reflectivity of the printing ink.

The present invention uses the light quantity value instead of the density value as image information based on the density equation (D ') relating to the plate making printing, and the basic light quantity value at the sample point (pixel) (n point) of the original image in continuous gradation. The relationship between the numerical value y of the net surface area% value of the halftone at the sample point of the printed image corresponding to the halftone gradation corresponding to this is derived from the gradation conversion equation so that the actual value of the theoretical value coincides.

In the operation of the gradation conversion equation of the present invention, the parameters of y _H and y _S are thus integerized, for example, 5% for y _CH of the C plate, 95% for y _CS , y _MH = A% of halftone area is used, which is 3% for y _YH and 90% for y _MS = y _YS . In addition, in the operation of the gradation conversion equation, the X _n value obtained in relation to the D _n value measured by the densitometer is used, and if the percentage value (% value) is used for y _H and y _S , the y value is also calculated as a percentage value. do.

In the operation of the tone conversion equation of the present invention, the value of another important parameter γ may be considered to be generally purified in setting the color separation curve for the C plate for the following reason. That is, in setting of the X-axis color separation curve for C plate, you may fix at gamma value = 0.45. This is derived from the fact that the present inventors have developed a gray scale conversion formula employing the density value as the image information value during the development of the gray scale conversion formula of the present invention, and is supported by many experimental examples.

However, the parameter γ is an extremely important parameter because it is possible to convert the shape of the color separation curve to a purpose, that is, to produce a printed matter having a desired gradation characteristic by operating the γ value for a purpose. It is not fixed.

The numerical setting of the gradation conversion parameter of the present invention is intended to produce a position where the state of a given subject (substantial image) is faithfully reproduced as a printed image to the last, and a print studio in which the state is consciously adjusted (modified or changed). It depends on your position. In the latter case, by changing the gamma value consciously, the shape of the X-axis color separation curve can be changed to a desired one (i.e., one having a desired gradation), so that printed images of various states can be obtained. For example, when the shape of the X-axis color separation curve is desired to be in the shape of a shape (in order to emphasize the state of the H part to the midtone (middle, light and dark), the value of γ is greater than zero. When the value is approximately linear, the value of γ is close to 0. On the contrary, when the value of γ is lowered (when the state of the midtone to the S portion is emphasized), the value of γ may be set to-.

In the operation of the gradation conversion formula of the present invention, it is free to use it by transforming as follows as well as by using any processing, deformation, induction, or the like.

y = y _H + E (1-10 ^-kX ) · (y _S -y _H )

Provided that E = 1 / (1-β) = 1 / (1-10 ^-γ )

In the above modification, α = 1.

This is, for example, 100% of the surface reflectivity of a printing paper (substrate) used to express a print image. Arbitrary values can be taken as the value of α, but in practice, the value may be set to 1.0 because of zero adjustment of the whiteness of the paper.

According to the modification (α = 1.0), y _H can be set to the brightest part H of the printed image as desired and y _S to the darkest part S, which is a great feature of the gradation conversion equation. This means that X = (X _n- X _H ) = 0 according to the definition of the outermost part H of the printed image, and X = X _S -X _H of the darkest part S.

-k X = -γ (X _S -X _H ) / (X _S -X _H ) =-γ

It is obvious from becoming.

In this way, by using the gradation conversion formula of the present invention (a variation of α = 1), it is always possible to set y _H and y _S as intended in the _H and _{S portions} of the printed image. It is also very important.

For example, if desired values are set for y _H and y _S in the printed image and the γ value is changed (where α = 1.0), various X-axis color separation curves are obtained. And the printed image obtained under these X-axis color separation curve can be easily evaluated in relationship with (gamma) value.

Particularly important in plate making practice is that the X-axis bird's-eye decomposition curve obtained in the present invention is different from the conventional D-axis color-resolved curve to display gradation characteristics and state characteristics ranging from H to S of the printed image as a final product. to be. That is, the plate-making worker can examine the shape of the final printed image from the X-axis color separation curve obtained under the desired y _H , y _S and γ values from the X-axis color separation curve obtained under the γ values. You can accurately predict completion. This is due to the great feature of the gradation conversion method of the present invention that all the X-axis chromatic separation curves set for a plurality of original images having different image quality (for example, different exposure conditions) all converge on one and the same chromatic separation curve. . On the other hand, conventional D-axis color separation curves (which employ the same y _H , y _S, and γ values) obtain curves corresponding to original images of different image quality, and the shape is complicated. Therefore, the plate making operation cannot accurately predict what the final printed image will be just by considering the curve.

The meaning of the above is extremely important and the platemaking operator can accurately predict the completion of the final printed image by displaying, for example, the X-axis chromatic separation curves of each color plate (C, M, Y) and the ink plate (B) on a monitor. As a result, various calibration operations can be made unnecessary. That is, the present invention enables direct plate making (Direct plate making method).

In the operation of the gradation conversion equation of the present invention, the k value may be normalized so that the (x _S -X _H ) value is 1.0. Normalizing such (X _S -X _H ) dynamics at 0 to 1 = 1.0 facilitates comparative review between the X-axis chromatic separation curves and facilitates calculation of the gradation conversion equation. Fundamentally, the light quantity value X of each image quality in the dynamic range changes according to the normalization, but because it is a relative change, it does not cause any trouble in setting the color separation curve. Furthermore, in the following description, the calculation of the gamma value is calculated with the value of the normalization arc.

Setting the X-axis color separation curve of each color plate for the multicolor plate (generally, four plates of the C + plate, the M plate, the Y plate, and the B (weak plate) are one set) by operating the gray scale conversion formula of the present invention. In order to do this, it is good to make it like the said C board under a desired plate making design.

The above description is an outline of the gradation conversion technology employed in the color scanner of the present invention, in particular, the gradation conversion unit which is a core component thereof.

The following describes the improvement of the color scanner, in particular, the gradation conversion unit, of the present invention.

It goes without saying that the gradation conversion equation is incorporated in the gradation conversion unit of the color scanner of the present invention, and the gradation conversion is performed by the gradation conversion equation.

As described above, in the gradation conversion formula, the brightest part H and the darkest part S are designated on the color photograph document, and the density values D _H and D _S of the H and S are measured, and the density values D _H , The light quantity value (X _H , X _S ) corresponding to D _S ) is obtained, and the gray scale conversion equation is obtained using the light quantity value (X _H , X _S ) like other parameters (γ value, y _H , y _S value). Operation to perform gradation conversion (setting of the X-axis color separation curve).

An extremely important problem in this case is that unevenness arises unavoidably in the measurement of the concentration values of H and / or S of color photographic documents.

The nonuniformity of the measured concentration values of H and S adversely affects the state of the color print image produced after the gradation conversion, that is, the gradation gradation, color tone, and gray balance (maintenance of the equivalent neutral density), and is therefore intended for trial design. An extremely important problem arises that no printed image is produced.

In addition, Table 2 shows the results of investigating the inconsistency of the measured concentration values of H and / or S with respect to various originals (light originals, standard originals, and dark originals) in the production of the C plate. In addition, the results of Table 2 were examined using a sample color photographic document (Daylight ASA 100 to F company) and a color scanner 455 manufactured by ISOMET company.

TABLE 2

The influence of the non-uniformity of the measured concentrations of H and / or S on the reproduction of the color plate image of the halftone gradation after the gradation conversion when the chromium 100 and Puropepetnal D (Daylike) film were used was investigated. The results are shown in Tables 3 to 7. Also,

Table 3 shows light color film originals: density range of comparative center originals from 0.175 to 2.225

Table 4 shows the standard color film originals: density range 0.300∼2.700

Table 5: Dark Color Film Originals: Concentration Range of Comparative Center Documents 0.500 ~ 2.7500

Table 6 shows an extremely light color film document: 0.125 to 1.850 density range for the comparative document.

Table 7 shows the extremely dark color film originals: density range of 0.900 to 3.100

Table 3 to Table 7 were prepared under the following conditions, showing the results when each color film document was used.

(i) The F company daylight film was used as a examination object of the nonuniformity of the measurement concentration value in H and S.

(ii) In the operation of the tone conversion equation, y _H = 5%, y _S = 95%, and γ = 0.45, assuming that a C plate was produced. It is needless to say that the numerical values in the tables are the gamma value (the half-dot area value) which is the calculation result of the gray scale conversion equation.

In Tables 3 to 7, the headings of the tables indicate color film originals (that is, non-uniformity of measurement, hereinafter referred to as comparative center manuscripts) in which the measurement of H and S was performed according to the plate making design. In each table, the comparative central manuscript and the non-uniform manuscript should be compared and examined.

In the table, 1/8, 1/4, 1/3, 1/2, and 3/4 in the column of density indicate the control points of the gradation conversion, and the numerical values below the concentration range values of the comparative center manuscripts ( Dynami crange) is the concentration value at the control point in which the ratio from H to 1/8, 1/4, 1/3, 1/2, 3/4 is increased.

From Tables 3 to 7, it is easy to see how the% value of the halftone area is different from that of the comparative manuscript due to the nonuniformity of the measured concentration value in the control point.

TABLE 3

TABLE 4

TABLE 5

TABLE 6

TABLE 7

The said Table 3-Table 7 were created in consideration of the nonuniformity of the density | concentration measurement of the said Table 2, and has shown clearly that the deviation which is quite large than the plate making design value in each control point. In particular, control points such as 1/8, 1/4, 1/3, etc. are important areas in producing printed images having excellent image quality, and there is a large gap in these control points.

Therefore, in order to produce a printed image according to the plate making design, it is essential to clearly recognize that the nonuniformity of the measured concentration values of H and / or S means and to solve the problem.

The nonuniformity of the measured concentration values of H and / or S is inevitable when a color photograph (film) document is used as the original image.

Its main cause is due to the size, shape and particle distribution state of the silver particles in the color film emulsifier and the aperture (or slit) size on the side of the color scanner. In the density measurement of H, the scanning luminous flux (scanning luminous flux) transmits (or reflects) a predetermined pixel of the original, and is then photoelectrically converted through an aperture of a predetermined size corresponding to the scanning pixel to measure the density value of each pixel.

2 shows the relationship between the silver particles and the aperture as a model.

The size of the silver particles contained in the B / G / B emulsion layer of the color film is generally 1 to 3 m ² , while the aperture diameter is generally 1 to several mm.

In the gradation conversion section of the color scanner of the present invention, since the gradation conversion operation is carried out by operating the gradation conversion formula, the head of the color scanner must be placed in the designated H and S region first, and the density measurement of the H and S must be performed. . At this time, the above-mentioned nonuniformity in the silver particle size, the incorrect arrangement of H and S on the aperture side, and the like interact with each other, resulting in nonuniformity in the measured concentration values of H and S.

That is, when the density measurement of H and S in the color photograph document specified by the plate making designer, the plate making operator, or the like is performed.

It is difficult to precisely arrange an aperture having a predetermined aperture ratio for performing mining (measured the amount of reflected light or transmitted light from the document) due to the concentration measurement for the designated H and S sites.

In addition, even if the aperture is precisely arranged with respect to the designated H and S sites, there is a nonuniformity on the side of the silver particles at the site, and there may be an optimal H and S site in the vicinity thereof. The presence of nonuniformity on the silver particle side is usually easily understood since the concentration measurement of the H and S sites is performed while observing the site with a magnifying glass. What may be the case of concentration measurement may interact with each other, resulting in non-uniformity in the concentration measurement of H and S.

In the color scanner of the present invention, in order to solve the drawback caused by the nonuniformity of the measurement concentrations of H and S, the concentration measuring unit of the color scanner has the representative concentration value (DH _av ) and the darkest portion in the brightest portion (H) and its vicinity. It is configured to output the representative concentration value DS _{av at} (S) and its vicinity.

The gray scale conversion unit of the color scanner obtains the corresponding light amount values X _H and X _S from the representative concentration values DH _av and DS _{av and} performs gray scale conversion by the gray scale conversion equation.

In the present invention, the method for determining the representative concentration values (DH _av , DS _av ) is not particularly proposed as long as it solves the nonuniformity of the measured concentration values.

For example, it goes without saying that average values, mode values, standard deviations, and the like may be used as the representative concentration values (DH _av , DS _av ). In addition, the following description demonstrates using an average concentration value as a representative concentration value.

What is necessary is just to measure the average density | concentration value in the said sharpest part H and its vicinity, and the darkest part S and its vicinity by the method suitable for the structure of a color scanner. For example, in the case of a drum type scanner, the operator may perform the drum while finely moving, or may give fine vibration to the aperture part. In the case of a flat bed, for example, the density precision value of the pixels around the predetermined pixels accumulated in the CCD may be averaged. In addition, the ultra-thin glass fibers may be combined with a desired number, and the concentration values may be measured and averaged for each glass fiber.

In the case of obtaining the average concentration value, it is sufficient to measure and average 3 to 5 times from many experimental examples, for example, in the example of measuring by shifting the measurement area around the brightest part H. What is necessary is just to determine this measurement frequency suitably in consideration of the kind of film used, the structure of an aperture, etc.

Next, the gradation improvement effect of the halftone gradation image (printing plate for C plate) of the scanner output when the nonuniformity of the measured concentration values of H and S is adjusted is shown in Tables 8-11.

In the present invention, the effect of improving the gradation characteristics of the halftone gradation image of the scanner output is (i) when the nonuniformity of the measured concentration values of H and S is adjusted by the average concentration values (DH _av , DS _av ), and (ii) In addition to adjusting the average concentration values (DH _av , DS _av ), when the γ value of the gradation conversion equation is also adjusted, it can be evaluated by (the above-described fact that the gradation characteristics can be reasonably changed by adjusting the γ value). .

Tables 8 to 9 show the improvement effect in the case of the above (i). A comparison of Tables 3 to 7 and Tables 8 to 9 and Tables 10 to 11 shows that the approach of (i) and the approach of (ii) are extremely effective. In addition, Tables 8-11 are understood from the following conditions.

Sample color film original (D company's daylight film): Standard quality color document

Density range of film originals based on adjustment management: 2.4000 (0.3000 to 2.7000)

Grayscale parameter: y _H = 5% y _S : 95%

γ value = 0.4500 for Tables 8 to 9

γ value = Table 10 to Table 11 are adjusted

In addition, the heading of each table indicates the degree of nonuniformity with respect to the concentration of H (0.3000) and the concentration of S (2.7000) of the reference manuscript. Needless to say, the degree of nonuniformity is improved because it is pinged and adjusted than the nonuniformity in Tables 3 to 7.

TABLE 8

TABLE 9

TABLE 10

TABLE 11

Next, an example of the device configuration of the color scanner of the present invention will be described with reference to FIG.

The color scanner of the present invention uses the density measuring instrument and the average concentration value capable of outputting the average concentration values (DH _av , DS _av ) from the designated H and S and its vicinity in the original image as described above. In addition, it is characterized in that a tone conversion mechanism for performing tone conversion by a tone conversion equation is provided. That is, since the other components are the same as the conventional ones, the conventional scanner can be reconfigured to the scanner of the present invention only by incorporating the above mechanism.

In FIG. 3, the drum type color scanner includes a detector 1 for inputting an original, a color separation unit 2 for converting an output signal from the detector 1 into color separation signals of Y, M, C, and K, and the gray level. It consists of four blocks of the gradation adjusting unit 3 which obtains an appropriate halftone gradation using a conversion formula and the output unit 4 which performs raw film exposure by laser light due to the output signal of the gradation adjusting unit 3. In the configuration of the color scanner, a block having the same shape as a conventional color scanner is adopted as the block of the color separation unit 2 and the output unit 4, and the detection unit 1 includes the brightest part H, its vicinity and the darkest part. One point differs from the conventional one in that it is a mechanism for detecting the average concentration value from (S) and its vicinity, and the gradation adjustment unit 3 is subjected to the gradation conversion under the gradation conversion equation.

The detector 1 detects transmitted or reflected light of each pixel of the color film document 5 such as a photomultiplier, and outputs R, G, B, and USM signals as current values, and converts the signals into A / V converters ( In 6), the signal is converted into a voltage signal.

In addition, as described above, the detection unit 1 is a mechanism capable of detecting the transmitted light (or reflected light) for obtaining the average concentration values DH _av , DS _av from the H and S and its vicinity.

The color separation unit 2 converts the voltage signals of the R, G, B, and USM signals of the detection unit 1 into logarithms and converts them into concentrations. In the basic masking (BM) 8, Gray (k) component is isolate | separated from concentration, and each component of Y, M, and C is also isolate | separated.

The log amplifier 7 converts the transmitted light (or reflected light) voltage signal detected by the detection unit 1 to find the average concentration values DH _av , DS _av , and then calculates the average concentration value. This is sent to the gradation conversion section 3 to be described later to become an important integer term for the operation of the gradation conversion formula.

Next, in the chromaticity (CC) section 9, the Y plate component, the M plate component, and the C plate component are controlled for each of the original colors of R, G, B, and Y, M, and C. In the UCR / Under Color Removal (UCR) or UCA (Under Color Addition) of the UCR / UCA section 10, the ratio of the components represented by the three editions of Y, M and C and the ratio represented by the K edition are determined.

After these Y, M, C, and K components are obtained, conventionally, the halftone execution area ratios ye ', me', ce ', and ke' of each component are obtained in the concentration control section of the gray scale conversion section (IMC), and are obtained by the inverse log transform section. Although the inverse log conversion was performed, in the scanner configuration shown in FIG. 3, the tone control unit 11 is used instead of the density control unit and the inverse log conversion unit, where Y ', me', ce from Y, M, C, and K are used. The conversion to 'ke' is performed. The gradation converting section 11 has the algorithm of the gradation conversion formula therein to obtain ye ', me', ce ', and ke' by applying the gradation conversion formula to Y, M, C, and K, respectively.

The gradation converting section 11 holds a gradation conversion algorithm as software, and is an electric circuit implemented by a general-purpose IC by logic of a general-purpose computer and algorithm having an I / F (inter phase) of A / D and D / A. It can take various forms, such as an electric circuit including a ROM which holds the calculation result of an algorithm, a PAL which implemented the algorithm as an internal logic, a gate array, a caste IC, etc.

The halftone effective area ratio obtained by the gradation converter 11 is input to the color channel selector 12, and the color channel selector 12 selectively outputs ye ', me', ce ', and ke' sequentially. This output is A / D converted by the A / D conversion unit 13 and input to the output unit 4. The output section 4 controls the laser beam in the dot control section 14 by the output of the gradation adjusting section 3.

Example

Hereinafter, the present invention will be described in more detail with reference to Examples.

Color film originals, color scanners, and color proofing used in the examples are as follows.

(i) color film originals

As a color film manuscript, a female figure of standard quality photographed at Fujiclom 100D, 4 × 5, manufactured by F Company was used.

The manuscript was measured with an X-RITE densitometer, that is, 2.72 in the H section 0.31 and S section, and its dynamic range was 2.41.

In addition, since the measured concentration values of H and S of the color film document are almost the same as those of Table 4 (standard color film document), the color scanner output due to the nonuniformity of the measured concentration values of H and S to be performed in the stage of plate making design before color separation. Data on the stabilization effect of the gray scale of the output color image by adjusting the gray scale image and adjusting the measured concentration values of H and S according to the present invention, or by adjusting the γ value in the gray scale conversion equation are shown in Tables 4, 9 and See Table 11.

(ii) color scanner

As a color scanner used for color separation, 455) DIGITAL COLOR SCANNER made by ISOMET was selected to give the following functions.

① The concentration measuring unit displays and outputs the average concentration value (DH _av ) at H and its vicinity and the average concentration value (DH _av ) at S and its vicinity.

It measured m times as an average concentration value (m is arbitrary integer), and incorporated the arithmetic mean into digital display and output. In this example, m = 5 times.

(2) In addition, the gradation conversion section is equipped with software which can convert the light quantity value (normalized light quantity value) (X _n ) obtained from the density value (D _n ) by the gradation conversion _formula of the present invention into a halftone area% value (y). It was.

In addition, at the site of the desired light quantity value (or concentration value), software for automatically obtaining a gamma value giving a desired halftone area% value, for example, 50%, was also installed.

(iii) color correction

As the color correction after color separation by a color scanner, the D company chromamarine method was adopted.

(iv) color separation

In the experiment, the effect of the present invention, that is, the effect of reducing the nonuniformity of the measured concentration values of H and S of the color film document, and more specifically, the nonuniformity of H and S in the range of 0.0200 and 0.0500, respectively In order to confirm the effect and the adjustment effect by the coefficient γ value in the gradation conversion equation of the present invention, in addition to the above effect, two persons of A and A were selected as operators.

Then, the parts of H and S were set on the color film document, and color separation was performed so that the former effect on the worker's head and the latter effect on the worker's body could be confirmed.

The operating conditions of the gradation conversion formula for setting the color separation curve of each color plate (C, M, Y plate) were as follows.

C version: y ₁₁ = 5%, y _S = 95%

M = y version: y _H = 3% y _S = 90%

γ value: 0.45 (fixed method) or arbitrarily changed (see Tables 10 to 11)

The former measured 10 concentrations of H and S each using a scanning head of a color scanner. In addition, each measurement concentration is derived from the average of five times.

The results are shown in Table 12.

In the same manner as in the case, the concentration values of H and S were measured five times. The results are shown in Table 13.

TABLE 12

TABLE 13

As a result, the range of the nonuniformity of the measured values of H and S by the former is 0.3100-0.2940 = 0.0160 and 27320-2.6840 = 0.0480 in Table 12.Either H is 0.020 and Table S is within the allowable range of 0.0500. It was confirmed to enter. The color separation work was carried out in Table 12. Based on the data of 7, the results were satisfactory.

In addition, it was confirmed by Table 13 that the range of the nonuniformity of the measured values of H and S falls within the range of the nonuniformity predetermined in Table 9 in the same shape. In addition, the color separation operation was carried out in No. Based on the data of 2, the same results were obtained.

Next, the color separation operation was carried out in No. In addition to using the data shown in FIG. 2, the gamma value in the gray scale conversion equation of the present invention is adjusted. It was tested whether the same result as the color separation work (fixed type of (gamma) = 0.45) based on the data of 7 is obtained.

No. of Table 13 The reason for employing the data shown in Fig. 2 is shown in Table 12. This was because the difference in data was the largest with respect to the data of 7, and it was considered an optimal comparison case for confirming the effect of the present invention.

As shown in the comparison column of Tables 12 to 13, according to the plate making design data, when the value of γ in the tone conversion equation is γ = 0.45

No. of former Netting area% value of 1/4 part C board in case of 7 (Table 12). 50.4104

No. of Dot area% value of 1/4 part C board in case of 2 (Table 13). 49.3713

Both are not identical. In other words, both are not strictly printed images of the same gradation.

Thus, the value of? The color separation operation was performed using the data of 2 (Table 13). In addition, when (gamma) = 0.4921, the% value of the halftone area of the C board of a quarter part will be 50.4089 (%).

As compared with the color correction printed image of A and A produced as described above, both images were almost homogeneous. As a result of the above experiments, the present invention can achieve the effect as scheduled, and by specifying the positions of H and S in advance, the size, shape, distribution irregularity of silver particles in the photographing material, and the operation of the scanner operator The color printing image having a stable state (gradation and color tone) can be produced at all times by eliminating the adverse effect on the color scanner output color plate image due to the nonuniformity of the measured density values of H and S of the color film document, without depending on the difference between the two and the like.

When using a color scanner to produce a halftone gradation printed disc (print plate) from a continuous gradation color photograph document, the halftone pattern has a halftone arrangement from the brightest part (H) to the darkest part (S). It is extremely difficult to make a printing plate. In other words, it is extremely difficult to produce the desired printed image stably and efficiently by converting the gradation according to the plate making design.

The color scanner of the present invention has a gradation conversion section that reasonably controls the gradation conversion by a specific gradation conversion formula, but the density measurement of the H and S of the original must be performed in order to set the initial condition because of the gradation conversion.

Otherwise, the measurement of the concentrations of H and S involves unavoidable nonuniformity, and it is quantitatively understood from the output result of the gradation conversion formula that the measured concentration value has a very bad effect on the dot array (gradation conversion). The nonuniformity by measuring the concentrations of H and S causes a difference in halftone arrangement in the H to midtone, which is an important area for gray scale reproduction. This has a great influence on the human visual ability.

Since the color scanner of the present invention incorporates a means for eliminating the nonuniformity of the concentration measurement of H and S, for example, a density measuring unit for averaging the measured values to obtain an average concentration value, the printed disc (print plate) always according to the plate making design. Can be produced. The significance of this is extremely large and contributes to the efficiency of plate making, that is, reducing or eliminating damaged plates, saving related materials, reducing working hours, and short-term delivery of products.

Furthermore, since the color scanner of the present invention performs rational and quantitative gray scale conversion, the quantitative and scientific education of the operator regarding color separation (gradation and coloring, the latter includes color correction), and customer's request Excellent effect in terms of realization

Claims (4)

In a color scanner for producing printed dots of halftone gradation from a color photograph image of continuous gradation, (i) the density measurement unit of each pixel (n point) of the color photograph manuscript of the color scanner includes the brightest portion (H) and its vicinity; Representative concentration values (DH _av and DS _av ) in the darkest part S and its vicinity are output, and (ii) the gradation conversion part of the color scanner correlates to the vertical axis (D axis) indicating the density value and the amount of light. Image information value correlating density value (D _n ) of each pixel to the amount of light using the density characteristic curve of the photographic material provided for photographing the color photograph document specified in the DX rectangular coordinate system on the horizontal axis (X axis) representing one image information value. (b) a color scanner, characterized in that is configured to convert the image information value (X _nx) to the gradation conversion formula dot area% value (y) using the correlation to the quantity of light, along with converting a (X _n). Gradation Conversion y = y _H + [α (1-10 ^-KX ) / (α-β)] ° (y _S -y _H ) However, in the gradation conversion formula X: Basic light quantity value represented by X = (X _n -X _H ) That is, from the density value D _n of an arbitrary pixel (n point) on the original, the image information value X _n correlated with the amount of light obtained through the density characteristic curve defined in the DX rectangular coordinate system and the representative concentration value of the H portion ( DH _av ) represents the difference of the image information value X _H correlated to the amount of light corresponding to DH _av ). y: halftone area% value of the pixel on the printed disc corresponding to an arbitrary pixel (n point) on the original y _H : The halftone area% value preset for H on the printed disc corresponding to H on the original y _S : halftone area% value preset for S on the printed disc corresponding to S on the original α: surface reflectivity of printing paper β: numerical value determined by β = 10 ^-r k: numerical value determined by k = γ / (X _S -X _H ) In the above formula, X _S represents an image information value correlated with the amount of light determined from the representative density value DS _av of the S part through the density characteristic curve defined in the DX rectangular coordinate system. γ: arbitrary coefficient Respectively. 2. The color scanner according to claim 1, wherein the density characteristic curve is a photographic concentration lateral curve showing a correlation between the blackening degree (concentration D) of the photographic photosensitive material and the logarithmic value (log E) of the exposure amount E. The color scanner according to claim 2, wherein the X-axis scale is the same as the D-axis scale in scaling of the D (vertical) axis-X (horizontal) axis of the D-X rectangular coordinate system that defines the density characteristic curve. The method according to claim 1, wherein the image information value X _n correlated with the light quantity is a normalized light quantity value when the [X _S -X _H ] value (dynamic range of the image information value correlated with the light quantity) is adjusted to 1.0. Color scanner.