JP2001285656A - Color image processing method and color image processing apparatus, and color image forming device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a color image processing apparatus that applies accurate color correction/black signal generation independently of received image data so as to obtain a reproduced image with high image quality without a tone gap where a visually natural black signal is generated. SOLUTION: A 1st color coordinate conversion section 21 converts RBG image data into L*a*b* data in a uniform color space and a lightness and saturation calculation section 22 obtains the lightness and saturation on the basis of the L*a*b* data. A black generating quantity calculation section 23 obtains a black generating quantity from a product between a 1st consecutive function, specifying a relation between the lightness and the black generating rate, and a 2nd consecutive function, specifying a relation between the saturation and the black generating rate on the basis of the obtained lightness and saturation and 2nd color coordinate conversion section 24 converts the L*a*b* data into CMYK image data on the basis of the obtained black generating quantity.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color-compatible image processing method and an image processing apparatus applied to a digital color copying machine, a color printer, a color scanner, a color facsimile, and the like. The present invention relates to a color image processing method, a color image processing apparatus, and a color image forming apparatus that perform image processing on input color image data and convert the color image data into color image data including black having a different color system.

[0002]

2. Description of the Related Art In a color image forming apparatus such as a digital color copying machine, an image input section for reading a color original usually reads image data of three colors of R (red), G (green) and B (blue). , The image forming unit uses a different color system C
(Cyan), M (Magenta), Y (Yellow), K
An image is formed using four color materials (black). Therefore, the RGB image data read by the image input unit is
After being converted into CMYK image data in the image processing unit, the data is output to the image forming unit.

[0003] In principle, a full-color image can be formed using only three color materials of CMY. However, CMY
When three color materials are used, the black represented by the three colors becomes incomplete black with some coloring, and cannot express high-density black. There is a problem that color fringing occurs around the area.

Therefore, conventionally, a black color material has been used in addition to the three color materials of CMY, and the undercolor removal (Un
derColor Removal (UCR), and black (K) corresponding thereto is added to perform black generation / under color removal processing to obtain the same color reproduction as in the case of three CMY colors.

As described above, by using the black color material, the achromatic color tone is stabilized, the color reproduction range in a low lightness part is widened, and the consumption of the color material such as toner and ink is reduced. There are advantages such as being suppressed.

Japanese Patent Application Laid-Open No. Sho 62-203475 describes a technique for obtaining the amount of black generation in consideration of gray level, that is, chroma information. The invention described in this publication is intended to suppress the occurrence of moiré. However, the minimum value Dmin and the maximum value Dmax of the CMY signal level (density level) are obtained to obtain the saturation information Dmin. /
Dmax is calculated, a coefficient f (Dmin / Dmax) that differs depending on the saturation is obtained using a function f, and the coefficient is multiplied by a gray component (min of Di) based on the minimum value of CMY to obtain a black signal level K. Is to be determined. That is,

[0007]

(Equation 1)

It is described that a gray component function f ′ (min of Di) can be used instead of the second term in the above equation.

[0009]

However, the above-mentioned prior art has the following problems. That is, in all of the techniques, the minimum value of the signal level of the CMY signal is used as the gray component, but this value often does not become the gray component. Therefore, when black generation is performed based on the gray component, the amount of black generation cannot be appropriately controlled, and as a result, image quality is reduced.

Further, in the invention described in the above-mentioned publication, it is described that black generation is performed in consideration of chroma information in addition to the gray component. , Dmin / Dmax, where Dmin / Dmax is different from the actual saturation. As a result, the calculated black generation amount is not appropriate, and visually unnatural black generation is performed.
Also in this case, the image quality is reduced.

[0011] Further, although the invention described in the above-mentioned publication discloses that saturation information is considered,
There is no description of ideal control of the amount of black generation, such as suppression of generation of a tone gap (discontinuity of gradation) in a low density portion.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and performs accurate color correction / black generation irrespective of input image data, thereby producing a visually natural black generation without a tone gap. It is an object of the present invention to provide a color image processing method, a color image processing apparatus, and a color image forming apparatus capable of obtaining a reproduced image with high image quality.

[0013]

According to the color image processing method of the present invention, in order to solve the above-mentioned problems, image data of the first color system is converted to image data of the second color system including black. In the color image processing method having the color correction / black generation processing for converting to data, the color correction / black generation processing converts the image data of the first color system into color data on a uniform color space. A second step of obtaining lightness and saturation based on the color data in the uniform color space converted in the first step; and a second step of obtaining lightness and saturation obtained in the second step. A third continuous function that defines the relationship between lightness and the black generation rate and a second continuous function that defines the relationship between the saturation and the black generation rate; And the color data on the uniform color space is obtained from the second color system based on the black generation amount obtained in the third step. It is characterized by a fourth step of converting the that image data.

According to the above method, the brightness and the saturation are obtained by temporarily converting the image data of the first color system into the color data on the uniform color space. Is obtained from the product of a first continuous function that defines the lightness and the black generation rate and a second continuous function that defines the saturation and the black generation rate.

The relationship between the lightness and the black generation rate is such that the black generation rate decreases as the lightness increases, and can be defined in the form of a continuous decreasing function. Further, when the black generation rate changes abruptly in a low-density portion having high brightness, the above-described tone gap occurs. Therefore, by defining the function form such that the black generation rate in the high lightness area changes gradually, the occurrence of a tone gap can be suppressed.

On the other hand, between the saturation and the black generation rate, in an achromatic image having the lowest saturation, the use of a large amount of black improves the image quality, and conversely, the saturation is the degree of vividness. Is higher, the image quality is better when the use of black is reduced, and the saturation and the black generation rate can be defined in the form of a continuous decreasing function.

That is, the relationship between the lightness and the black generation rate and the relation between the saturation and the black generation rate are each defined by a continuous function, and the amount of black generation is controlled by the product of the two continuous functions. The amount of generation can be easily adjusted according to the brightness and the saturation.

Therefore, the first continuous function defining the relationship between the lightness and the black generation rate and the second continuous function defining the relationship between the saturation and the black generation rate are obtained without a tone gap. In addition, by setting the amount of black generation to be a visually natural amount, it is possible to control the black generation amount to a suitable amount without a tone gap or visually unnatural.

As a result, the reproduced image formed by the image data of the second color system based on the black generation amount obtained in this manner has no tone gap and high image quality. Become.

Further, the saturation used here is a value converted from the color data on the uniform color space, and is compared with the saturation information composed of Dmin / Dmax used in the above-mentioned conventional publication. Since it is accurate, the black generation rate according to the saturation becomes accurate, and accurate color correction / black generation processing becomes possible.

A color image processing apparatus according to the present invention is a color image processing apparatus capable of performing the above-described color image processing method according to the present invention, wherein image data having a first color system is
In a color image processing apparatus including a color correction / black generation unit that converts image data into a second color system including black, the color correction / black generation unit uniformly converts the image data having the first color system. First color coordinate conversion means for converting into color data on a color space, and brightness / saturation for obtaining brightness and saturation based on the color data on a uniform color space converted by the first color coordinate conversion means. A first continuous function that defines a relationship between lightness and a black generation rate based on the lightness and the saturation calculated by the lightness / saturation calculation means; And a second continuous function that defines the relationship between the black color generation amount and the black color generation amount calculated by the black generation amount calculation unit. Color coordinate conversion means for converting the color data into image data of a second color system. It is characterized.

According to this, the first color coordinate conversion means:
The image data composed of the first color system is converted into color data on a uniform color space, and the brightness / saturation calculating means calculates a brightness and a saturation based on the converted color data on the uniform color space. Ask. The saturation calculated here is a value converted from data on the uniform color space, and is more accurate than the saturation information composed of Dmin / Dmax used in the above-mentioned conventional publication.

When the brightness and the saturation are obtained in this way, the black generation amount calculating means determines the relationship between the brightness and the black generation rate based on the obtained brightness and the saturation. A black generation amount is obtained from a product of the function and a second continuous function that defines a relationship between the saturation and the black generation rate. Based on the obtained black generation amount, the second color coordinate conversion means , And converts the color data on the uniform color space into image data of the second color system.

As described above, the lightness and the black generation rate can be defined by a continuous decreasing function, and the chroma and the black generation rate can be defined by a continuous decreasing function. Therefore, the first continuous function defining the relationship between the lightness and the black generation rate and the second continuous function defining the relationship between the saturation and the black generation rate are obtained without a tone gap, The black generation amount is controlled to a suitable value without tone gap or visually unnatural by setting the black generation amount to be a natural black generation amount and calculating the black generation amount by the product of both continuous functions. It becomes possible.

As a result, the reproduced image formed by the image data of the second color system based on the black generation amount obtained in this way has no tone gap and exhibits high image quality. .

In the above color image processing apparatus, it is preferable that the first and second continuous functions have a function form determined based on the order and the inflection point of each differential function.

Various forms of the first and second continuous functions are conceivable. By defining the function form of the continuous function with a small number of parameters such as the order of the differential function and the inflection point, two continuous functions are determined. Control and adjustment of the black generation amount using the product of the functions can be realized with a simpler circuit configuration.

In such a case, it is more preferable to provide a parameter setting means for changing the order and the inflection point of each differential function.

By providing the parameter setting means, it becomes possible for the user to change the parameter value as appropriate to adjust the desired black generation amount, and not only to improve the image quality of the reproduced image, but also to make the reproduced image The effect that the preference can be reflected can also be obtained.

In the above color image processing apparatus, a plurality of first continuous functions are provided in accordance with the type of the image, and the black generation amount calculating means calculates an image based on the plurality of first continuous functions. It is preferable that a configuration suitable for the type is selected.

When the original is a photographic paper photograph, a lot of dark and vivid colors are included. Therefore, if black is frequently used in a low lightness part, there arises a problem that vivid colors cannot be reproduced. On the other hand, in the case of print photographs, unlike photographic paper photographs, dark and vivid colors can hardly be expressed, so even if the black generation rate in low lightness areas is increased, the saturation decrease due to black generation hardly occurs. do not do. On the other hand, in a text document, even thin characters need to be reproduced well, so that it is necessary to set a high black generation rate in the middle lightness / low lightness portions.

Therefore, a plurality of first continuous functions for defining the lightness and the black generation rate are provided in accordance with the characteristics (type of image) of each original image, and the first continuous function is provided according to the type of image. By making the selection, the black generation rate can be more appropriately controlled, the original image can be faithfully reproduced, and the image quality of the reproduced image can be further improved.

As a method for the black generation amount calculating means to specify the type of the original image, an image mode signal which is a signal for notifying the image mode selected by the user according to the type of the original image using the operation panel or the like, Alternatively, an area identification signal or the like, which is a result of an area separation process for separating each pixel or block of a document image into one of a photograph, a halftone dot, and a character, can be used.

In the above-described color image processing apparatus, the second continuous function that defines the relationship between the saturation and the black generation rate has a function form with respect to lightness. It is preferable to calculate the black generation rate according to the saturation by using the above.

Since the relationship between lightness and the black generation rate is defined by the first continuous function, it is assumed that only the saturation and the black generation rate are uniformly defined regardless of the lightness by the second continuous function. In a high-brightness portion having a small black generation rate, a tone gap may be generated due to a change in saturation. Therefore, it is assumed that the function form of the second continuous function that defines the relationship between the saturation and the black generation rate is determined for the lightness, and the function form of the second continuous function is changed according to the lightness, thereby achieving high brightness. The occurrence of a tone gap due to a change in saturation can be suppressed in the entire brightness range from brightness to low brightness.

Further, the color image forming apparatus of the present invention comprises the above-described color image processing apparatus of the present invention, image input means for inputting image data of a first color system, and a second color system. Image forming means for forming a color image on a recording material using a plurality of visible coloring materials based on the image data.

Thus, the image data of the first color system read by the image input means is converted by the color image processing apparatus to the second color system including black whose black generation amount is appropriately adjusted. Therefore, the reproduced image output from the image forming means is faithfully reproduced from the original image, and the color image forming apparatus can provide a high quality image. In addition, by adopting a configuration provided with parameter setting means, it is possible to finely adjust the black generation amount according to the user's preference, and to provide a highly convenient color image forming apparatus that can meet the needs of the user. Can be provided.

[0038]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention is shown in FIGS.
The following is a description based on FIG.

FIG. 2 is a block diagram showing the configuration of a digital color copying machine according to an embodiment, which includes a color image processing section 1 to which the configuration of the color image processing method and the color image processing apparatus of the present invention is applied. Show.

As shown in FIG. 2, the color image processing unit 1
Are an A / D conversion unit 10, a shading correction unit 11, an input gradation correction unit 12, an area separation processing unit 13, a color correction / black generation unit 14, a spatial filter processing unit 15, and an output gradation correction unit 1.
6 and a tone reproduction processing section 17, to which the color image input section 2 and the color image forming section 3 are connected, to constitute a digital color copying machine as a whole.

The color image input section (image reading means) 2
For example, it is configured by a scanner unit having a CCD (Charge Coupled Device), and reads a reflected light image from a document as an RGB analog signal by the CCD and inputs the image to the color image processing unit 1.

The analog signal read by the color image input unit 2 is transmitted to the A / D conversion unit 1 in the color image processing unit 1.
0, shading correction unit 11, input gradation correction unit 12,
The image data is sent in the order of the area separation processing unit 13, the color correction / black generation unit 14, the spatial filter processing unit 15, the output gradation correction unit 16, and the gradation reproduction processing unit 17, and forms a color image as CMYK digital color signals. Output to the unit 3.

A / D (analog / digital) converter 10
Is a device for converting an RGB analog signal into a digital signal. The shading correction unit 11 includes an A / D conversion unit 10.
The digital RGB signal sent from the color image input unit 2 is subjected to a process of removing various types of distortion generated in an illumination system, an imaging system, and an imaging system of the color image input unit 2.

The input tone correction unit 12 outputs an RGB signal (R) from which various distortions have been removed by the shading correction unit 11.
In addition to adjusting the color balance with respect to the GB reflectance signal), the signal is converted into a signal such as a density signal which can be easily handled by the image processing system employed in the image processing unit 1.

The segmentation processing unit 13 converts the RGB signals into
This is to separate each pixel or a block composed of a plurality of pixels in the input image into any of a character area, a halftone area, and a photograph area. The region separation processing unit 13 outputs a region identification signal indicating which region a pixel or a block belongs to based on the separation result to the color correction / black generation unit 14 and the spatial filter processing unit 1.
5 and the tone reproduction processing unit 17, and outputs the input signal from the input tone correction unit 12 to the subsequent color correction / black generation unit 14 as it is.

As a separation method in the region separation processing unit 13, for example, a document “Method of identifying halftone dots” (IEICE Transactions 1987/2 Vol.2 J70-B No.2 p.222)
~ P.232.) "Block separation conversion method"
(Block Separate Transformation Method: BSTM
Method) can be used. In this method, image data to be processed is divided into blocks, and non-halftone areas (characters / photographs) and halftone areas are separated based on density changes in the blocks. At this time, in the halftone dot region, since the halftone dots are periodically arranged, a feature that pixels with high density are spatially dispersed is used. Hereinafter, an outline of this method will be described.

(1) The image data to be processed is divided into blocks of (m × n) pixels. (2) Find the maximum value Lmax, minimum value Lmin, and Lmax-Lmin of the image signal level in the block. (3) The value of Lmax-Lmin is compared with a predetermined reference value P. If Lmax-Lmin <P, it is determined to be a non-dot (photograph) area. If Lmax-Lmin ≧ P, furthermore, (Four)
The following processing is performed. (4) Each pixel is binarized into “0” and “1” using the average value of the image signal levels in the block. (5) "0" between pixels consecutive in the main scanning direction in the block
The number of changes K _H of “1” is obtained, and the number of changes K _V of “0” and “1” is similarly obtained in the sub-scanning direction. (6) Compare the obtained numerical value with a predetermined reference value T,
If K _H ≧ T and K _V ≧ T, it is determined as a halftone dot area, and if K _H <T or K _V <T, it is determined as a character area.

However, since the above method alone is not sufficient, a correction process is performed to suppress erroneous determination in a character portion, and the identification accuracy in a coarse halftone dot region is reduced. If the number is large, the reference value T of the number of density changes of the current block is reduced, and correction is performed to improve the determination accuracy of the halftone dot area. The region separation processing unit 13
Is not limited to such a method for separating each block, but may be a method for separating each pixel.

The color correction / black generation unit 14 converts the RGB signals (image data of the first color system) into CMY signals (image data of the second color system: color correction signals). The processing is performed. Further, in order to realize faithful color reproduction, a process for removing color turbidity based on the spectral characteristics of the CMY color materials including unnecessary absorption components is performed. Further, a black generation process for generating a black (K) signal from the corrected CMY signal and an undercolor removal process for generating a new CMY signal by subtracting the K signal obtained by the black generation from the CMY signal are performed. , CMY signals are converted to CMYK signals. The details of the color correction / black generation unit 14 will be described later.

The spatial filter processing unit 15 performs a spatial filter process on the image data of the CMYK signal input from the color correction / black generation unit 14 using a digital filter based on the region identification signal to correct the spatial frequency characteristics. The processing is performed so as to prevent the output image from being blurred and the graininess from deteriorating.

For example, in order to enhance the reproducibility of a black character or a color character in particular, the region separated into characters by the region separation processing unit 13 has a high frequency of The emphasis amount is increased. At the same time, the tone reproduction processing unit 17 selects binarization or multi-value processing on a high-resolution screen suitable for reproduction of a high frequency.

On the other hand, for the area separated into halftone dots by the area separation processing section 13, the spatial filter processing section 16 performs appropriate processing such as low-pass filter processing for removing input halftone dot components. . Then, the output tone correction unit 16 performs an output tone correction process of converting a signal such as a density signal into a dot area ratio which is a characteristic value of the color image forming unit 3, and then performs a tone reproduction process unit 17. Finally, a tone reproduction process (halftone generation) is performed to separate the image into pixels so that each tone can be reproduced. For the area separated into photographs by the area separation processing unit 13, binarization or multi-value processing is performed on a screen that emphasizes tone reproducibility.

The image data of the CMYK signal subjected to each of the above-described processes is temporarily stored in a storage unit (not shown), read out at a predetermined timing, and input to the color image forming unit 3. This color image forming section (image forming means) 3
Is for outputting image data on a recording material (for example, paper), and is not particularly limited. For example, an image forming unit using an electrophotographic system or an inkjet system can be used.

The details of the color correction / black generator 14 will be described below.

FIG. 1 shows the configuration of the color correction / black generation section 14 in the color image processing section 1. As shown in FIG. 1, the color correction / black generation unit 14 includes a first color coordinate conversion unit 21 and a second color coordinate conversion unit 21.
, A color coordinate conversion unit 24, a lightness / saturation calculation unit 22, and a black generation amount calculation unit 23.

The first color coordinate conversion section 21 converts the RGB signal image data input from the input gradation correction section 12 (see FIG. 2) into CIE (Commission Internationale de l'Ecl).
airage: CIE 1976 L ^* a ^* b ^* color space (CIELAB color space), which is a uniform color space defined by the International Commission on Illumination
It is to be converted to data. In the above L ^* a ^* b ^* data, L ^* represents lightness and a ^* b ^* represents chromaticity.

As a method of color coordinate conversion, for example,
A method can be used. That is, a color chart manuscript
Measure each color patch with a colorimeter^*a^*b^*Find a value
(L^*a^*b^*For colorimetric data)
Read the color chart document from the color image input unit 2.
To obtain RGB data, and thus obtained L^*a^*b
^*A coefficient for associating the values with the RGB values based on the values.
Neural network and masking operation coefficient determination method
, And color coordinate conversion is performed using the obtained coefficients.

The circuit configuration of the first color coordinate conversion unit 21 may be a masking operation using a matrix or a look-up table (LUT: Look U).
p Table, hereafter referred to as LUT). The data subjected to the color coordinate conversion is output to the lightness / saturation calculation unit 22 and the second color coordinate conversion unit 24, respectively.

The lightness / saturation calculation unit 22 calculates lightness L ^* and saturation C ^* from the L ^* a ^* b ^* data converted by the first color coordinate conversion unit 21 based on the following equation. Black generation amount calculation unit 2
3 is output.

[0060]

(Equation 2)

The second color coordinate converter 24 converts the L ^* a ^* b ^* data converted by the first color coordinate converter 21 into C (cyan), M (magenta), and Y (yellow). At the same time, the output value C′M′Y ′ is obtained by subtracting the black generation amount K obtained by the black generation amount calculation unit 23 from the converted CMY value as in the following equation (under color removal), and this is output as CMY The signal is output to the spatial filter processing unit 15 (see FIG. 2) as a signal.

[0062]

(Equation 3)

Here, α is a constant satisfying 0 <α <1.

As a conversion method for converting L ^* a ^* b ^* data into CMY data, for example, the following method can be used. That is, color image data (CMY) having color coordinates that can be output by the color image forming unit 3 is output, and the color image data is measured by the above-described colorimeter to obtain data of the L ^* a ^* b ^* color system.
Image data of color-measured L ^* a ^* b ^* values and color coordinates (CMY
K), a coefficient between the L ^* a ^* b ^* value and the CMY value is determined by a neural network or a masking operation coefficient determination method, and color coordinate conversion is performed using the obtained coefficient.

Also in this case, the circuit configuration in the second color coordinate conversion unit 24 may be the above-described masking operation using a matrix or a system that performs an interpolation operation using an LUT.

The black generation amount calculation unit 23 calculates the relationship between the lightness L ^* and the black generation rate k1 and the saturation based on the data of the lightness L ^* and the saturation C ^* sent from the lightness / saturation calculation unit 22. The relationship between C ^* and the black generation rate k2 is defined by each function, the black generation amount K of the second color system is obtained from the black generation function obtained by the product of these functions, and the second color coordinate conversion is performed. This is output to the section 24 and the spatial filter processing section 15 (see FIG. 2).

First, a function that defines the relationship between the lightness L ^* and the black generation rate k1 and the relation between the saturation C ^* and the black generation rate k2 will be described. The requirements as a function change smoothly over the entire input range. → Both the target function and its differential function are continuous functions. No tone gap (tone discontinuity) occurs near the maximum value and the minimum value. → The slope of the function is 0 at the maximum value and the minimum value. The curvature of the first half and the second half of the function and the inflection point can be specified. → The curvature can be specified by the order of the differential function, and the inflection point can be specified by the slope change part.

A function satisfying such a necessary condition is shown in FIG.
It becomes a function as shown in. The broken line indicates the objective function f (x), and the solid line indicates its differential function f ′ (x). Here, the order of the differential function f ′ (x) in the first half is h (h> 0),
Assuming that the order of the differential function f ′ (x) in the second half is i (i> 0) and the position of the inflection point is p (0 <p <1), the objective function f
(x) is represented by the following equation.

[0069]

(Equation 4)

In the above equation, the constant J represents the output [0:
1] is a constant for normalizing to

[0071]

(Equation 5)

Is obtained. At this time, the differential function f ′ (x) is

[0073]

(Equation 6)

Is represented by

Therefore, the order h ·· of the differential function f ′ (x)
By setting i and the inflection point p as parameters and setting these parameters h, i, and p, an arbitrary function can be created (in FIG. 3, h = i = 1.0, p = 0.5).
Is calculated as FIG. 4 shows a function (first continuous function) of lightness ratio-black generation ratio k1 adopted by the present digital color copying machine, which is created by setting the parameters h, i, and p.

Since both the lightness and the black generation rate k1 and the saturation and the black generation rate k2 have a relationship that the black generation rate decreases as the lightness or the saturation increases, the function of the lightness and the black generation rate k1 and the color As the function of the degree and the black generation rate k2, a decreasing function such that 1 → 0 is used.

Then, as a function of the brightness and the black generation rate k1,
Normalize the lightness represented by numerical values from 0 to 100 to [0: 1]
And a function F of lightness rate-black generation rate k1
1 (L ^*). To normalize the brightness to [0: 1]
In this case, the value of 0 to 100 should not be normalized as it is.
The minimum value of the actual lightness is 0, and the maximum value of the actual lightness is 1
And The minimum value of the brightness varies depending on the type of the image.
For example, in a photographic paper photograph, a lightness of about 5 is the minimum value. one
The maximum value of brightness differs depending on the type of original paper,
For example, if the original is plain paper, the maximum brightness is about 90.
Value.

Then, in the case of this digital color copying machine,
Function F1 (L) of lightness rate-black generation rate k1 ^*) Is the image type
Is set for each image mode selected in accordance with. Figure
In FIG. 4, what is indicated by a solid line is the photographic paper photograph mode.
The function F1 (L^*)
The one shown by the dotted line is the lightness ratio in print photo mode-black.
The function F1 (L^*), Those indicated by broken lines
Function F1 (L) of lightness rate-black generation rate k1 in the character mode.^*)so
is there.

The above function F1 (L ^* ) in each image mode
The parameters h, i, and p are set in consideration of the following feature points for each image mode.

That is, the photographic paper photographic document has a characteristic feature that it contains many dark and vivid (deep) colors. In the case of a deep color, if a black color material is frequently used, saturation is reduced, and image quality is impaired. In addition, the photographic paper photograph has a feature that characters are rarely included. Therefore, the function F1 (L ^* ) in the photographic paper photograph mode is set so that the black generation rate in the low lightness part is lower than in the other image modes. By lowering the black generation rate in the low lightness portion, a black color material is not frequently used even in a deep color, and a decrease in saturation can be avoided. Also, if the black generation rate in the low lightness portion is lowered, a problem occurs at the time of character reproduction. However, such a problem does not occur because characters are rarely included. In FIG. 4, h = 0.1, i = 0.9, and p = 0.4.

A printed photographic document is more likely to include characters than a photographic paper photograph, and because of the area gradation, unlike a photographic paper photograph, it is hardly possible to express dark, vivid and deep colors. Even if the black generation rate is increased in the low lightness region, almost no decrease in saturation due to black generation occurs. Therefore, the function F1 (L ^* ) in the print photograph mode is set so that the black generation rate in the low lightness part is higher than that of the photographic paper photograph so that good black can be reproduced. By making the black generation rate in the low lightness portion higher than that of a photographic paper photograph, even if characters are included, it can be reproduced well. In FIG. 4, h =
1.3, i = 1.1, p = 0.25.

Even if the saturation of a printed photograph is reduced, it is necessary for a character original to reproduce thin black characters satisfactorily. Therefore, the function F1 (L ^* ) in the character mode is set so as to have a high black generation rate not only in the low brightness portion but also in the low brightness portion to the middle brightness portion. In FIG. 4, h =
2.5, i = 1.3, and p = 0.3.

Since the high-brightness portion having a low density is a region where the black color material starts to be used and a tone gap is conspicuous, it is used in the photographic paper mode, the print mode, and the character mode. In any case, the parameters h, i, and p are set so that the rising edge at which black starts to be output changes particularly slowly.

The region generation signal from the region separation processing unit 13 and the image mode signal indicating the image mode selected by the user are input to the black generation amount calculation unit 23.
The black generation amount calculation unit 23 selects one of three types of functions F1 (L ^* ) according to the image mode based on the region identification signal or the image mode signal.

The image mode can be selected by using a mode setting button (mode setting means) provided on an operation panel 20 (see FIG. 2) provided in the copying machine main body. The user operates the mode setting button to sequentially display the image modes on a display unit such as a liquid crystal display of the operation panel 20, and selects a desired image mode.

Here, the area identification signal is set to a default. Therefore, the black generation amount calculation unit 23 selects the function F1 (L ^* ) using the area identification signal unless the image mode signal is input. That is, when the corresponding pixel is separated into the photograph area, the function F1 (L ^* ) in the photographic paper mode is selected, and when the pixel is separated into the halftone area, the function F1 (L ^* ) is selected in the print photograph mode. select function F1 (L ^*), if it is separated into a character region, selecting the function at the time of character mode F1 (L ^*). When an image mode signal is input, the image mode signal is used.
Note that a configuration in which the opposite image mode signal is set as a default is also conceivable.

When the image mode signal is used, a small number of parameters such as the image mode (here, photographic paper photograph,
The function F1 (L ^* ) can be switched between the three types of print photo and character).
Black generation according to an image mode can be performed with a simple circuit configuration. When the area identification signal is used, there is an advantage that the amount of black generation can be controlled according to the area to which each pixel or block belongs.

Next, FIG. 5 shows a function (second continuous function) of the saturation rate-black generation rate k2, which is created by setting the parameters h, i, and p and is adopted in this digital color copying machine. )
Is shown.

As the function of the saturation and the black generation rate k2, a decreasing function such that 1 → 0 is used similarly to the lightness. Then, even with the function of the saturation and the black generation rate k2, the minimum value of the saturation is set to 0,
The maximum value of the saturation is set to 1, normalized to [0: 1] and treated as a saturation rate, and a function F2 (
L ^* , C ^* ). The minimum value of the saturation was an achromatic color, and the maximum value of the saturation was a saturation value that would not be unnatural even when black was generated. Therefore, the maximum value of the saturation differs depending on the color.

Here, the function of the saturation rate—the black generation rate k2 is
Defines the functional form with respect to the lightness L ^*, the containing lightness L ^* as a variable in the case of high brightness, because of the low overall black generation rate, saturation index - the curvature of the function of the black generation rate k2 Is uniformly defined, and if the same as in the case of low brightness having a high black generation rate as a whole, a tone gap due to a change in saturation occurs. As described above, by changing the curvature of the function of the saturation rate-the black generation rate k2 according to the brightness, it is possible to suppress the occurrence of a tone gap due to the saturation change in all brightness areas from low brightness to high brightness. Can be.

In FIG. 5, the solid line indicates the lightness L.
^* Saturation rate when == 20-Black generation rate k2 function F2 (
L ^* , C ^* ), h = 0.8, i = 2.3, p = 0.
5 is set. Further, what is indicated by a dashed line is a function F of the saturation rate−the black generation rate k2 when the lightness L ^* = 50.
2 (L ^* , C ^* ), h = 0.68, i = 1.79,
p is set to 0.5. What is indicated by a broken line is a function F2 (L ^* , C ^* ) of the saturation rate-black generation rate k2 when the lightness L ^* = 90, and h = 0.5, i = 1.
0 and p = 0.5 are set.

As can be seen from FIG. 5, the function F2 (L ^* , C ^* ) of the saturation rate-the black generation rate k2 is such that as the lightness increases, the curvature of the function decreases so that the tone gap becomes less noticeable. Is set to Also, in FIG.
Parameter h, i, p, when the lightness factor and L _0, are set with the following relationship equation including lightness index L _0.

[0093]

(Equation 7)

In the above equation, when the brightness is maximum, L ₀ = 1,
Been assigned a lightness index L ₀ such that L ₀ = 0 when the brightness minimum, the parameters h, i, p is set.

That is, the black generation amount calculation unit 23 uses the above formula based on the lightness L ^* obtained by the lightness / saturation calculation unit 22 to calculate the function F2 (L ^* , L ^* , C ^* ), and using the created function F2 (L ^* , C ^* ), the saturation C ^*
Is determined.

The black generation amount calculation unit 23 obtains the black generation ratio k1 corresponding to the lightness L ^* and the black generation ratio k2 corresponding to the saturation C ^* in this manner. By multiplying by k2, the black generation rate k is obtained. That is, when expressed in the form of a function, the black generation function g (L ^* , a ^* , b) as a whole
^* ) Is represented by g (L ^* , a ^* , b ^* ) = F1 (L ^* ) * F2 (L ^* , C ^* ), and F1 (L ^* ) * F2 (L ^* , C ^* ) = black The generation rate is k. The black generation amount K is in the output range [0:25].
5], K = 255 × k.

FIG. 6 is a flowchart showing the procedure of the color correction / black generation processing in the color correction / black generation section 14 described above. The color image processing unit 1 including the color correction / black generation unit 14
Are configured by a CPU (Central Procedures not shown).
sing Unit).

In the color correction / black generation processing, first, the first
The color coordinate conversion unit 21 converts the RGB input image data, which is the first color system, into L ^* a ^* b, which is color data on a uniform color space.
^* Data (S1: first step), and then the lightness / saturation calculator 22 calculates the lightness L ^* based on the L ^* a ^* b ^* data ^.
And chroma C ^* (S2: second step).

When the lightness L ^* and the saturation C ^* are obtained, the black generation amount calculation unit 23 first selects one function F1 (L ^* ) of the lightness ratio-black generation ratio k1 according to the image mode signal. Then, a black generation rate k1 corresponding to the lightness L ^* is obtained (S3).

Subsequently, the black generation amount calculation unit 23 calculates the value of the lightness L ^* obtained in S2 as a function F2 of the saturation rate-black generation rate k2.
(L ^* , C ^* ), a function F2 (L ^* , C ^* ) of the saturation rate-black generation rate k2 is created (S4), and S2 is added to the created function.
The black generation rate k2 corresponding to the saturation C ^* is obtained by substituting the value of the saturation C ^* obtained in step 2 (S5).

As described above, when the black generation rate k1 according to the lightness L ^* and the black generation rate k2 according to the saturation C ^* are obtained,
The black generation amount calculation unit 23 calculates the total black generation ratio k by multiplying the black generation ratios k1 and k2 (S6), and calculates the black generation amount K based on the total black generation ratio k (S7: S3 ~
S7 is a third step).

Finally, the second color coordinate conversion unit 24 calculates L ^* a ^* b ^* based on the black generation amount K in the black generation amount calculation unit 23 ^.
The data is converted into CMY color data, which is the second color system, suitable for the color image forming unit 3 (S8: fourth step).

As described above, in the digital color copying machine of the present embodiment, the color correction /
The black generation unit 14 converts the RGB image data into L ^* a ^* b ^* data on a uniform color space once, thereby obtaining the lightness L ^* and the saturation C ^*.
*, And the generation amount of CMYK black (K) is calculated as the lightness rate−
Function F1 (L ^* ) of black generation rate k1 and saturation rate-black generation rate k
2 and a function F2 (L ^* , C ^* ).

Therefore, a function F1 (L ^* ) of the lightness rate-black generation rate k1 and a function F2 of the saturation rate-black generation rate k2
By setting (L ^* , C ^* ) to be such that there is no tone gap and a visually natural black generation amount, suitable black generation without tone gap and visually unnatural is obtained. As a result, the reproduced image formed by the CMYK image data based on the black generation amount obtained in this manner has no tone gap and exhibits high image quality. Become.

In the digital color copying machine, a function F1 (L ^* ) of lightness ratio-black generation ratio k1 and a function F2 (L ^* , C ^* ) of saturation ratio-black generation ratio k2 are calculated as follows. Since the function form is determined based on the order and inflection point of each differential function, the amount of black generation can be calculated by defining the function form of a continuous function with a small number of parameters such as the order of the differential function and the inflection point. The unit 23 can be realized with a simpler circuit configuration.

In this case, it is preferable that the digital color copying machine is provided with parameter setting means for enabling the degree of each differential function and the inflection point to be changed. Each parameter h, i, p of the function F1 (L ^* ) of the generation rate k1 and the function F2 (L ^* , C ^* ) of the saturation rate-black generation rate k2 can be changed by the user according to his / her preference. Make up.

That is, the user inputs a function F1 (L ^* ) of lightness rate-black generation rate k1 and a function F2 of saturation rate-black generation rate k2 on a display unit such as a liquid crystal display provided on the operation panel 20. When the parameters h, i, and p of (L ^* , C ^* ) are sequentially displayed and a numerical value is input using a numeric keypad or the like provided on the operation panel 20, the input range of the numerical value and the magnitude of the numerical value are associated with the numerical input. Is displayed on the display unit, for example, in the form of a message indicating that the reproduced image becomes brighter or darker, or a sample image (an image prepared in advance rather than a document). .

The user checks the message and the sample image displayed on the display unit, and presses the decision button when the displayed message and the sample image meet the request. If there is a next parameter by pressing the decision button, the next parameter is displayed and the same operation is repeated. In addition,
If you change the value, press the clear button and enter it again. In the above description, the reason why the sample image is displayed is that, in order to display an actual document image, it is necessary to perform pre-scanning or temporarily perform predetermined image processing to obtain output data.

In addition, a configuration in which parameters are changed using a mouse may be used. That is, a function F1 (L ^* ) of the lightness rate-black generation rate k1 and a function F2 (L ^* , C ^* ) of the saturation rate-black generation rate k2 are displayed on the display section in the form of a graph, and the mouse and cursor are displayed. The function may be used to directly change the form of the function. When the form of the function is changed, what the output image looks like may be displayed on the display unit using a message or a sample image in the same manner as described above, and the same may be applied to the above.

In addition, for example, the intensity of the brightness and the intensity of the vividness can be set in a step-by-step manner using keys, and the black generation amount calculation unit 2 can be set in accordance with each designated intensity level.
The parameters h, i, and p are automatically changed on the third side, and a function F1 (L ^* ) of a lightness rate-black generation rate k1 and a function F2 (L ^* , C ^* ) is set, and what the output image looks like is displayed on the display unit by using a sample image or the like.

By providing such a configuration in which the parameter settings can be changed, it becomes possible for the user to change the parameter value as appropriate to adjust the desired black generation amount, and only to improve the image quality of the reproduced image. In addition, the effect that the user's preference can be reflected in the reproduced image is also obtained.

In the digital color copying machine, a plurality of functions F1 (L ^* ) of lightness ratio-black generation ratio k1 are provided corresponding to the image mode, and are switched according to the image mode. Therefore, the black generation rate can be controlled more appropriately, the original image can be faithfully reproduced, and the image quality of the reproduced image can be further improved.

In the digital color copying machine, a function representing the relationship between the saturation and the black generation rate is defined by the brightness as a function F2 (L ^* , C ^* ) of the saturation rate-the black generation rate k2. Therefore, the occurrence of a tone gap due to a change in saturation can be suppressed in the entire brightness range from high brightness to low brightness.

In the above-described embodiment, a color copying machine to which the color image processing method and the color image processing apparatus according to the present invention are applied has been exemplified, but not only the color copying machine but also the above-described color image input unit. 2 and the color image processing unit 1 constitute a color scanner.
The color image processing unit 1 and the color image forming unit 3 constitute a color printer. Further, a fax function is further added, and the present invention can be applied to a color fax or the like.

[0115]

According to the color image processing method of the present invention, as described above, the color correction / black generation processing converts the image data of the first color system into color data on a uniform color space. A second step of obtaining lightness and saturation based on the color data in the uniform color space converted in the first step, and a lightness and saturation obtained in the second step. Based on a product of a first continuous function defining the relationship between lightness and the black generation rate and a second continuous function defining the relationship between the saturation and the black generation rate, And a fourth step of converting color data on a uniform color space into image data of a second color system based on the black generation amount obtained in the third step. is there.

Thus, the first continuous function defining the relationship between the lightness and the black generation rate and the second continuous function defining the relationship between the saturation and the black generation rate can be obtained without a tone gap. Also, by setting the black generation amount to be a visually natural black generation amount, it is possible to control the black generation amount to a suitable value without a tone gap or visually unnatural, and as a result, the tone There is an effect that it is possible to provide a high-quality reproduced image without a gap or unnatural black generation.

In the color image processing apparatus of the present invention, as described above, the color correction / black generation means converts the image data of the first color system into color data on a uniform color space. Coordinate conversion means, lightness / saturation calculation means for obtaining lightness and saturation based on the color data on the uniform color space converted by the first color coordinate conversion means, and lightness / saturation calculation means A product of a first continuous function defining a relationship between lightness and a black generation rate and a second continuous function defining a relationship between saturation and a black generation rate based on the obtained brightness and saturation. From the black generation amount calculation means for obtaining the black generation amount, and the color data on the uniform color space based on the black generation amount obtained by the black generation amount calculation means,
And second color coordinate conversion means for converting the image data into image data of the color system.

Thus, the first continuous function defining the relationship between the lightness and the black generation rate and the second continuous function defining the relationship between the saturation and the black generation rate can be obtained without a tone gap. Also, by setting the black generation amount to be a visually natural black generation amount and calculating the black generation amount by the product of the bicontinuous functions, the black generation amount can be reduced to a suitable value without tone gap or visually unnatural. This makes it possible to provide a high-quality reproduced image without tone gaps or unnatural black generation.

In the above color image processing apparatus, it is preferable that the first and second continuous functions have a function form determined based on the order and the inflection point of each differential function. As described above, by determining the function form of the continuous function with a small number of parameters such as the order of the differential function and the inflection point, the control and adjustment of the black generation amount using the product of the two continuous functions can be realized with a simpler circuit configuration. The effect is also achieved.

In this case, it is more preferable that parameter setting means is provided for enabling the order of each differential function and the inflection point to be changed. In this way, the user can adjust the parameter value as appropriate to adjust the desired black generation amount, and not only can provide a high quality reproduced image,
An effect that the user's preference can be reflected in the reproduced image is also provided.

In the above color image processing apparatus, a plurality of first continuous functions are provided in accordance with the type of the image, and the black generation amount calculating means calculates the image of the image from the plurality of first continuous functions. It is preferable to select a configuration suitable for the type. With this, the relationship between the lightness and the black generation rate changes according to the type of the document image. The effect is that the image can be faithfully reproduced, and the image quality of the reproduced image can be further enhanced.

Further, in the above-described color image processing apparatus, the second continuous function that defines the relationship between the saturation and the black generation rate has a function form defined for lightness. It is preferable to calculate the black generation rate according to the saturation by using the above. As a result, the function form of the second continuous function changes depending on the lightness, so that the black generation rate can be more appropriately controlled, and the occurrence of a tone gap due to a change in chroma can be suppressed in the entire lightness range from high lightness to low lightness. This has the effect of further improving the image quality of the reproduced image.

Further, as described above, the color image forming apparatus of the present invention includes the above-described color image processing apparatus of the present invention,
Forming a color image on a recording material using a plurality of visible color materials based on image input means for inputting image data of a first color system and image data of a second color system And an image forming unit.

Accordingly, the input image data of the first color system includes the second image including the black whose black generation amount has been suitably adjusted.
Is converted into color image output image data, so that a color image forming apparatus capable of providing a high quality image can be realized.
Furthermore, by adopting a configuration with parameter setting means, it is possible to finely adjust the amount of black generation according to the user's preference, and realize a highly convenient color image forming apparatus that can meet the needs of the user. it can.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a color correction / black generation unit of a color image processing unit included in a digital color copying machine according to an embodiment of the present invention.

FIG. 2 is a block diagram showing an overall configuration of the digital color copying machine.

FIG. 3 is an explanatory diagram showing a method for obtaining a function that defines a relationship between lightness and a black generation rate and a function that respectively defines a relation between saturation and a black generation rate according to the present invention.

FIG. 4 is an explanatory diagram showing a relationship between a lightness ratio and a black generation ratio, using three types of image modes of characters, print photographs, and photographic paper photographs as parameters.

FIG. 5 is an explanatory diagram showing a relationship between a saturation rate and a black generation rate using lightness as a parameter.

FIG. 6 is a flowchart illustrating a procedure of a color correction / black generation process in the color correction / black generation unit.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 color image processing unit (color image processing device) 2 color image input unit (image input unit) 3 color image forming unit (image forming unit) 13 region separation processing unit 20 operation panel (parameter setting unit) 21 first color coordinates Conversion unit (first color coordinate conversion unit) 22 Lightness / saturation calculation unit (lightness / saturation calculation unit) 23 Black generation amount calculation unit (black generation amount calculation unit) 24 Second color coordinate conversion unit (second Color coordinate conversion means)

Continued on the front page F term (reference) 2C262 AA24 AA26 BA01 BA12 BA16 BA19 BC19 5B057 AA11 CA01 CA08 CA12 CB01 CB08 CB12 CE17 CE18 DB02 DB06 DB09 5C077 MP08 PP32 PP33 PP35 PP36 PP37 PP38 PQ08 PQ12 5C079 HB01 H02B PA03

Claims (7)

[Claims] 1. A color image processing method comprising a color correction / black generation process for converting image data of a first color system into image data of a second color system including black. / Black generation processing is based on a first step of converting image data of the first color system into color data on a uniform color space, and based on the color data on the uniform color space converted in the first step. A second step of obtaining lightness and chroma; a first continuous function defining a relationship between lightness and black generation rate based on the lightness and chroma obtained in the second step; From the product of the second continuous function that defines the relationship between the saturation and the black generation rate,
A third step of obtaining a black generation amount; and a third step of converting the color data on the uniform color space into image data of a second color system based on the black generation amount obtained in the third step. 4. A color image processing method comprising the steps of: 2. A color image processing apparatus comprising: a color correction / black generation means for converting image data of a first color system into image data of a second color system including black. / Black generating means, a first color coordinate conversion means for converting image data composed of a first color system into color data on a uniform color space, and a uniform color data converted by the first color coordinate conversion means. Lightness / saturation calculating means for obtaining lightness and chroma based on color data in a color space; and lightness and black generation rate based on the lightness and chroma calculated by the lightness / saturation calculating means. Black generation amount calculating means for obtaining a black generation amount from a product of a first continuous function that defines the relationship between the first color and the second continuous function that defines the relationship between the saturation and the black generation rate; Based on the black generation amount obtained by the generation amount calculation means, the color data on the uniform color space is converted into a second color system. Color image processing apparatus characterized by comprising a second color coordinate conversion means for converting the image data to be. 3. A color image processing apparatus according to claim 2, wherein said first and second continuous functions have a function form determined based on an order of each differential function and an inflection point. apparatus. 4. The color image processing apparatus according to claim 3, further comprising parameter setting means for changing the order and the inflection point. 5. A plurality of the first continuous functions are provided in accordance with the type of the image, and the black generation amount calculating means is one which is suitable for the type of the image among the plurality of first continuous functions. The color image processing apparatus according to claim 2, wherein the color image processing apparatus selects: 6. The second continuous function that defines the relationship between the saturation and the black generation rate has a function form defined for lightness, and uses a function determined by lightness to generate black according to saturation. The color image processing apparatus according to claim 2, wherein a rate is obtained. 7. A color image processing apparatus according to claim 2, an image input means for inputting image data comprising a first color system, and a second color system. A color image forming apparatus for forming a color image on a recording material using a plurality of visible color materials based on the image data.