JP2004349980A - Image processing method and image processing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image processing method and an image processing apparatus by which a smooth gradation can be obtained by keeping saturation and reducing roughness while reducing the total amount of ink for every hue by an easy arithmetic operation. <P>SOLUTION: In the image processing method and , and original RGB data is inputedt, color-separated into CMYK data and outputted. The image processing apparatus is provided with; an initial value setting step of setting first CMYK data correspondingly to the combination of original RGB data; a hue discrimination step of discriminating which hue of R, G, B, C, M, and Y the first CMY belongs; a maximum value limiting step of obtaining second CMY data by limiting the first CMY data to a maximum value or smaller of each color preliminarily set per hue on the basis of the result of the hue discrimination step; and a total amount adjustment step of adjusting the second CMY data to obtain CMYK data for output on the basis of the total amount of the second CMY data and the first K data. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image processing method and an image processing apparatus for decomposing input color image data into YMCK data.
[0002]
[Prior art]
In a color print process in an inkjet printer or the like, color reproduction is usually performed using color materials of C (cyan), M (magenta), Y (yellow), and K (black). Recently, color materials (inks) of C, M, and K having a low density are often used for improving image quality. In such a printer, there is a limit on the printable amount per unit area, and if printing is performed beyond that amount, ink overflow or bleeding will occur and the image quality will deteriorate, so the total ink amount is limited. .
[0003]
As a conventional technique, it is well known that when the total ink amount exceeds the limit value, K maintains the ink amount, and C, M, and Y inks maintain the original ratio and reduce the ink amount. I have.
[0004]
However, if the ink is limited by the conventional method, the component constituting the main density of the corresponding color in a portion corresponding to a dark color is excessively reduced under the constraint of the amount of ink applied, and the saturation tends to be large.
[0005]
On the other hand, if the data is processed so as to reduce the main density in a portion containing a large amount of ink in advance, the reduction can be suppressed to some extent. For example, there is known a method of reducing the amount of ink as a result of adjusting the saturation from the average value and the original values of R (red), G (green), and B (blue) in the RGB space (Patent Document 1). , 2).
[0006]
[Patent Document 1] Japanese Patent Application Laid-Open No. 8-275010
[Patent Document 2] JP-A-9-314864
[0007]
[Problems to be solved by the invention]
However, in these conventional techniques, there is no idea of reducing the main and sub-density components by looking at the hue. Further, there was no idea that the thin K ink was positively used before the dark C and M inks.
[0008]
In view of the above, the present invention provides an image processing method and an image processing apparatus capable of reducing the total amount of ink for each hue by a simple operation, maintaining saturation, reducing roughness, and obtaining a smooth gradation. Make it an issue.
[0009]
Other objects of the present invention will become apparent from the following description of the present specification.
[0010]
[Means for Solving the Problems]
(1) An image processing method for inputting original RGB data, performing color separation on CMYK data and outputting the same, wherein an initial value setting step of setting first CMYK data corresponding to a combination of the original RGB data; A hue determination step of determining which hue the first CMY data belongs to among R, G, B, C, M, and Y; and, based on a result of the hue determination step, the first CMY data A maximum value limiting step of obtaining second CMY data by limiting the maximum CMY data to a maximum value of each color set for each color; and a second CMY data based on a total amount of the second CMY data and the first K data. And a total amount adjusting step of adjusting the values to obtain CMYK data for output.
[0011]
According to the first aspect of the present invention, the amount of ink can be reduced. At this time, since the total amount is limited after being suppressed to a constant value, a decrease in the main density component in the corresponding color can be suppressed. Further, since a lightness range from pure color to black can be secured, color matching processing can be easily and stably performed.
[0012]
(2) An image processing method for inputting original RGB data, color-separating the original RGB data into CMYK data, and outputting the same, wherein an initial value setting step of setting first CMYK data corresponding to a combination of the original RGB data; A hue determination step of determining which hue the first CMY data belongs to among R, G, B, C, M, and Y; and, based on a result of the hue determination step, the first CMY data A maximum value limiting step of obtaining the second CMY data by limiting the maximum CMY data to the maximum value of each color, a gray level calculating step of calculating a gray level from the first CMY data, and the second CMY A gray amount calculating step of calculating an amount of gray from the data; and a step of reducing CMY data from the second CMY data using the gray degree and the gray amount to obtain third CMY data. An adjusting step of adjusting the third CMY data to obtain output CMYK data based on the total amount of the third CMY data and the first K data. Image processing method.
[0013]
According to the second aspect of the invention, it is possible to suppress the amounts of C, M, and Y inks in a high to medium lightness region where the saturation is relatively low.
[0014]
(3) An image processing method for inputting original RGB data, performing color separation on CMYK data, and outputting the same, wherein an initial value setting step of setting first CMYK data corresponding to a combination of the original RGB data; A hue determination step of determining which hue the first CMY data belongs to among R, G, B, C, M, and Y; and, based on a result of the hue determination step, the first CMY data A maximum value limiting step of obtaining second CMY data by limiting the maximum CMY data to a maximum value of each color set for each color; and a second CMY data based on a total amount of the second CMY data and the first K data. Total amount adjusting step of obtaining the fourth CMYK data by adjusting the first CMYK data, gray level calculating step of calculating the gray level from the first CMY data, and gray level calculating the gray level from the fourth CMY data An image processing method comprising: outputting a CMY data from the fourth CMY data using the gray degree and the gray amount to obtain CMYK data for output. .
[0015]
According to the third aspect of the invention, it is possible to suppress the amounts of C, M, and Y inks in a high to medium lightness region where the saturation is relatively low. In particular, it is suitable when it is desired to further reduce the amount of ink near the maximum density.
[0016]
(4) The correspondence between the generated original RGB data and the CMYK data is held as a three-dimensional table, and the color separation from the original RGB data to the CMYK data is performed using the three-dimensional table. 4. The image processing method according to 2 or 3.
[0017]
According to the fourth aspect of the invention, it is possible to speed up the operation for color conversion from RGB to CMYK.
[0018]
(5) The image processing method according to (4), wherein a smoothing process is performed on the data stored in the three-dimensional table.
[0019]
According to the fifth aspect of the invention, it is possible to smoothly change the values of CMYK in the conversion relationship, and to improve the continuity of colors and gradations.
[0020]
(Claim 6) At least C, M, and K are composed of two or more types of dots having different densities per unit area, and a light K dot is smaller than a C or M dot having a lighter brightness when printed in the same amount per unit area. The image processing method according to any one of claims 1 to 5, wherein the color separation output is output to an output device having a low dot and a dot higher than the dark C and M dots.
[0021]
According to the sixth aspect of the present invention, the region having relatively low saturation and high lightness can be constituted by the Y ink and the C and M inks on the lower density side, and the medium lightness is defined by the ink and the density. Since it can be composed of the low-side K ink, the appearance of dark C and M dots that are conspicuous at low to medium densities can be delayed, and roughness can be suppressed.
[0022]
(Claim 7) CMYK data corresponding to the original RGB data is output based on the color separation relationship, printing is performed based on the values, the reproduction characteristics of the output device are obtained from the colorimetric data, and the target input is obtained. After performing color matching between the device and the output device, creating color correction data between input and output, and combining with the color separation, the relationship between the input data and the final CMYK output is made into one multidimensional table. The image processing method according to claim 1, wherein:
[0023]
According to the invention described in claim 7, color conversion from the target color can be performed at high speed.
[0024]
(8) An image processing apparatus which inputs original RGB data, performs color separation on CMYK data, and outputs the same, wherein initial value setting means for setting first CMYK data corresponding to a combination of the original RGB data; Hue determining means for determining which of the hues the first CMY data belongs to R, G, B, C, M, and Y; and determining the first CMY data in advance based on the determination result by the hue determining means. Maximum value limiting means for obtaining the second CMY data by limiting to a maximum value of each color set for each hue, and a second CMY based on a total amount of the second CMY data and the first K data. An image processing apparatus comprising: a total amount adjusting unit that adjusts data to obtain CMYK data for output.
[0025]
According to the invention described in claim 8, the amount of ink can be reduced. At this time, since the total amount is limited after being suppressed to a constant value, a decrease in the main density component in the corresponding color can be suppressed. Further, since a lightness range from pure color to black can be secured, color matching processing can be easily and stably performed.
[0026]
(9) An image processing apparatus which inputs original RGB data, performs color separation on CMYK data, and outputs the same, wherein initial value setting means for setting first CMYK data corresponding to a combination of the original RGB data; Hue determining means for determining which of the R, G, B, C, M, and Y colors the first CMY data belongs to, and the first CMY data based on the determination result of the hue determining means. A maximum value limiting unit that obtains second CMY data by limiting the color value to a maximum value of each color set for each hue, a gray degree calculating unit that calculates a gray level from the first CMY data, A gray amount calculating means for calculating the amount of gray from the CMY data; and a method for reducing the CMY data from the second CMY data using the gray degree and the gray amount to obtain third CMY data. And a total amount adjusting unit that adjusts the third CMY data to obtain output CMYK data based on a total amount of the third CMY data and the first K data. Image processing apparatus.
[0027]
According to the ninth aspect of the present invention, it is possible to suppress the amounts of C, M, and Y inks in a high to medium lightness region where the saturation is relatively low.
[0028]
(10) An image processing apparatus which inputs original RGB data, performs color separation on CMYK data, and outputs the same, wherein initial value setting means for setting first CMYK data corresponding to a combination of the original RGB data; Hue determining means for determining which of the R, G, B, C, M, and Y colors the first CMY data belongs to, and the first CMY data based on the determination result of the hue determining means. Maximum value limiting means for obtaining the second CMY data by limiting to a maximum value of each color set for each hue, and a second CMY based on a total amount of the second CMY data and the first K data. A total amount adjusting means for adjusting data to obtain fourth CMYK data; a gray degree calculating means for calculating a gray degree from the first CMY data; and a gray level calculating means for calculating an amount of gray from the fourth CMY data. An image, comprising: an amount calculating unit; and a gray amount adjusting unit configured to reduce CMY data from the fourth CMY data using the gray degree and the gray amount to obtain CMYK data for output. Processing equipment.
[0029]
According to the tenth aspect, it is possible to suppress the amounts of C, M, and Y inks in a high to medium lightness region where the saturation is relatively low. In particular, it is suitable when it is desired to further reduce the amount of ink near the maximum density.
[0030]
(Claim 11) A storage means for holding a correspondence from the generated original RGB data to CMYK data as a three-dimensional table, wherein color separation from the original RGB data to CMYK data is performed using the three-dimensional table. The image processing device according to claim 8, 9, or 10.
[0031]
According to the eleventh aspect, the operation for color conversion from RGB to CMYK can be speeded up.
[0032]
12. The image processing apparatus according to claim 11, further comprising a smoothing processing unit that performs smoothing processing on the data stored in the three-dimensional table.
[0033]
According to the twelfth aspect of the present invention, it is possible to smoothly change each of the CMY values in the conversion relationship, and to improve the continuity of color and gradation.
[0034]
(Claim 13) At least C, M, and K are composed of two or more types of dots having different densities per unit area, and a light K dot has a lower brightness than a C or M dot having the same lightness when recorded in the same amount per unit area. The image processing apparatus according to any one of claims 8 to 12, wherein the color separation output is output to an output device having a low dot and a dot higher than the dark C and M dots.
[0035]
According to the thirteenth aspect of the present invention, the region having relatively low saturation and high lightness can be constituted by the Y ink and the C and M inks on the lower density side, and the medium lightness is defined by the ink and the density. Since it can be composed of the low-side K ink, the appearance of dark C and M dots that are conspicuous at low to medium densities can be delayed, and roughness can be suppressed.
[0036]
(Claim 14) CMYK data corresponding to the original RGB data is output based on the color separation relationship, printing is performed based on the values, and the reproduction characteristics of the output device are obtained from the colorimetric data to obtain the target input. After performing color matching between the device and the output device, creating color correction data between input and output, and combining with the color separation, the relationship between the input data and the final CMYK output is made into one multidimensional table. The image processing apparatus according to claim 8, wherein:
[0037]
According to the fourteenth aspect, color conversion from the target color can be performed at high speed.
[0038]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0039]
FIG. 1 shows a configuration example of an image processing system using an image processing apparatus according to the present invention. The image processing system includes an image input device 1, an image processing device 2, and an image output device 3.
[0040]
The image input device 1 is, for example, a computer, a television camera, a scanner, or the like, and outputs RGB multi-tone color image data (original RGB data). Here, the description will be made assuming that the gradation values of the multi-tone color image data have 256 gradations of 0 to 255 by 8 bits for each color.
[0041]
The image processing apparatus 2 according to the present invention includes: a color conversion process for performing color matching between an input color image and an output image; a color separation process for decomposing the color-converted image into CMYK multi-tone data; In order to represent the color-separated data on the image output device 3, quantization processing such as error diffusion processing is performed, and CMYK data of several gradations is output to the image output device 3. The color separation processing described below constitutes one function in the image processing apparatus 2. In this specification, a component related to the color separation processing in the image processing apparatus 2 is referred to as a color separation unit.
[0042]
The image output device 3 creates a print based on the image data output from the image processing device 2. The image output device 3 is configured by a printer, such as an ink jet printer, which has different shades of ink and cannot express many gradations in pixel units.
[0043]
(1st Embodiment)
FIG. 2 is a block diagram illustrating a configuration of the color separation unit according to the first embodiment in the image processing apparatus 2. The color separation process in the image processing device 2 is for decomposing an RGB input (original RGB data) from the image input device 1 into CMYK output data for output to the image output device 3, as shown in FIG. , A CMY generation unit 21, a K generation unit 22, a hue determination and tint calculation unit 23, a maximum value restriction unit 24, and a total amount restriction calculation unit 25.
[0044]
The CMY generation unit 21 receives the RGB data from the image input device 1, sets CMY data (first CMY data) corresponding to the combination of the original RGB data, and sets the K generation unit 22, The data is output to the calculating unit 23 and the maximum value limiting unit 24. The conversion from RGB data to CMY data is performed as follows.
[0045]
C = 255-R
M = 255-G
Y = 255-B
[0046]
The K generation unit 22 receives the CMY data generated by the CMY generation unit 21 and generates K data (first K data). Here, the K data was generated as a function of min (C, M, Y) from a table set experimentally as shown in FIG. The K data thus generated is output to the total amount limit calculation unit 25. Note that the CMY generation unit 21 and the K generation unit 22 may be logically formed as one block, and a configuration may be adopted in which CMYK data (first CMYK data) is generated from RGB data collectively.
[0047]
The CMY generation unit 21 and the K generation unit 22 constitute an initial value setting unit of the present invention, and the processing constitutes an initial value setting step of the present invention.
[0048]
The hue determination and tint calculation unit 23 receives the CMY data generated by the CMY generation unit 21 and calculates and determines which of the six hues R, G, B, C, M, and Y belongs. .
[0049]
The hue determination / color calculation unit 23 constitutes a hue determination unit of the present invention, and this processing constitutes a hue determination step of the present invention.
[0050]
In FIG. 2, maxhue indicates which of the six hues R, G, B, C, M, and Y the input CMY data belongs to, and what color indicating the maximum value among the following dB to dC is Is output to the maximum value limiting unit 24.
[0051]
dB = {f (f (C−Y) − | C−M |) + f (f (M−Y) − | C−M |)} / 2
dG = {f (f (C−M) − | C−Y |) + f (f (Y−M) − | C−Y |)} / 2
dR = {f (f (MC)-| MY-) | + (f (Y-C)-| MY-)} / 2
dY = {f (f (Y-C)-| CM-) + f (f (Y-M)-| CM-)} / 2
dM = {f (f (M−Y) − | C−Y |) + f (f (M−C) − | C−Y |)} / 2
dC = {f (f (C−M) − | M−Y |) + f (f (C−Y) − | M−Y |)} / 2
[0052]
However, f (x) = x (x ≧ 0) and 0 (x <0).
[0053]
Here, for example, dB indicates the closeness (color) of the corresponding color to B (blue). If C = 255 and M = Y = 0, dC = 255 and the other components are 0. Alternatively, if C = M = 255 and Y = 0, dB = 255 and the other components are zero. Therefore, the maximum value of dB to dC can be set as the hue of the color. An example using the values of dB to dC will be described later.
[0054]
The maximum value limiter 24 appropriately sets the maximum value of each of the C, M, and Y components in advance for each of the six hues of R, G, B, C, M, and Y based on the ink density and the total amount limit value. That is, the maximum value limiting unit 24 determines in advance for each hue the CMY data input from the CMY generation unit 21 based on the corresponding hue and the CMY data input from the hue determination / color tint calculation unit 23. C′M′Y ′ data (second CMY data) is calculated by limiting the data to the set maximum value or less for each color, and is output to the total amount limit calculation unit 25.
[0055]
Here, the maximum value of each color is set in advance for each hue as in (1) and (2) below.
[0056]
{Circle around (1)} For the R, G, C, M, and Y hues, the maximum value of the color corresponding to the sub-density is limited to 25%.
[0057]
{Circle around (2)} For the B hue, the maximum value of Y corresponding to the auxiliary density is limited to 15%. Also, the maximum values of M and C corresponding to the main density are limited to 90%.
[0058]
The main density means M, Y color for R color, C, Y color for G color, C, M color for B color, C color for C color, M color for M color, and Y color for Y color. The sub-densities are C color for R color, M color for G color, Y color for B color, M, Y color for C color, C, Y color for M color, and C, M color for Y color. That is.
[0059]
Here, the reason for changing the limit value for the B hue from the other hues is that the Y color in the dark portion has a small contribution to the density and has a large effect of increasing the ink amount, and the M and C have been increased. If it is too much, the lightness point of the pure color is lowered, the lightness range from B to K is reduced, and color matching becomes difficult.
[0060]
The latter will be described with reference to FIG. FIG. 4 shows the locus of white to B to black on the L * -C * ab plane. In FIG. 4, points a and b indicate the chromaticity of B with and without limiting the maximum values of M and C, respectively. Also, c indicates a black point. As is clear from this figure, when the maximum value is not limited, the lightness difference between the black point and B becomes very small. In the secondary colors of R, G, and B, the amount of ink in a pure color (sub-density = 0) is larger than that in the primary colors such as C, M, and Y. Therefore, even if the sub-density limit is set smaller. good.
[0061]
The maximum value limiting section 24 constitutes the maximum value limiting means of the present invention, and this processing constitutes the maximum value limiting step of the present invention.
[0062]
The total amount restriction calculation unit 25 calculates the C′M′Y ′ based on the total amount of the K data input from the K generation unit 22 and the C′M′Y ′ data input from the maximum value restriction unit 24. The data is adjusted to generate C "M" Y "K" data (output CMYK data). That is, when the limit value of the total amount of ink is limited based on the K data and the C'M'Y 'data, the CMYK data is obtained by the following equation.
[0063]
C ″ = C ′ * (limit−K) / (C ′ + M ′ + Y ′)
M ″ = M ′ * (limit−K) / (C ′ + M ′ + Y ′)
Y ″ = Y ′ * (limit−K) / (C ′ + M ′ + Y ′)
[0064]
However, if the result obtained by the above equation is larger than the original values C ′, M ′, Y ′, the original value is used for the corresponding color.
[0065]
The total amount limit calculation unit 25 constitutes the total amount adjusting means of the present invention, and this processing constitutes the total amount adjusting step of the present invention.
[0066]
FIG. 5 shows color separation curves from white (W) to red (Red) to black (K) when the present invention is applied. The total ink amount limit was set to 250%. FIG. 6 shows a conventional ink amount limitation for comparison. Here, the horizontal axis indicates a gradation step, the right end is white (R = G = B = 255), the center is a pure red color (R = 255, G = B = 0), and the left end is black (R = G = B = 255). B = 0) input, and the vertical axis indicates the corresponding CMYK output (decomposed value).
[0067]
As can be seen from the comparison, it is possible to moderate the decrease in the C and M outputs, which are the main densities, in the range of gradation steps 0 to 20 which are dark areas. It should be noted that with respect to the point of R = G = B = 0, consistency is obtained from all hue directions.
[0068]
When the amount of ink is limited, when the main density is reduced, the color gamut is sharply reduced in a dark part, causing a sharp decrease in saturation. For this reason, giving priority to the main density component of the dark part as in the present method is effective in securing the color gamut and gradation of the dark part.
[0069]
As described above, the color separation from the original RGB data to the CMYK data is performed by the color separation process described above. It is preferable to use a three-dimensional LUT (look-up table) as a dimension table because color separation from original RGB data to CMYK data is performed at high speed.
[0070]
Further, by forming a three-dimensional LUT, an effect that the conversion relation can be made smoother is also produced. Specifically, for example, the conversion relationship in a table format is
LUT (r, g, b, col)
r, g, b: each input color
col: output color
And when
LUT ′ (r, g, b, col) = 1 / 27ΣΣΣLUT (r + kk, g + jj, b + ii, col)
kk, jj, ii = -1,0,1
To obtain a smoothing LUT. This smoothing process may be repeated, and the smoothness increases as the process is repeated. The color separation curve is as shown in FIG. 7, which improves the continuity of color and gradation.
[0071]
(Second embodiment)
FIG. 8 is a configuration block diagram illustrating a second embodiment of the color separation unit in the image processing apparatus according to the present invention. As shown in the drawing, this embodiment has a configuration in which a gray amount calculation unit 26 and a CMY restriction unit 27 are added to the configuration block diagram shown in FIG.
[0072]
Also, in the figure, the hue determination and tint calculation section 23 outputs a parameter indicating the degree of gray: gray to the CMY restriction section 27 based on the CMY data input from the CMY generation section 21. .
[0073]
More specifically, using the dB to dC parameters in the hue determination and tint calculation unit 23 calculated in the first embodiment described above,
gray = 1-max (dB, dG, dR, dY, dM, dC) / 255
And
[0074]
The hue determination and tint calculation unit 23 constitutes the gray degree calculation means of the present invention, and this processing constitutes the gray degree calculation step of the present invention.
[0075]
The gray amount calculation unit 26 calculates the minimum value of C′M′Y ′ input from the maximum value restriction unit 24 as the gray amount: gray_amt. That is,
gray_amt = min (C ′, M ′, Y ′) / 255
, And outputs the result to the CMY restriction unit 27.
[0076]
Here, max () and min () are equal to the maximum value and the minimum value in the parameters in parentheses, respectively.
[0077]
The gray amount calculating section 26 constitutes a gray amount calculating means of the present invention, and this processing constitutes a gray amount calculating step of the present invention.
[0078]
The CMY limiting unit 27 includes a gray degree: gray input from the hue determination / tone calculation unit 23, C′M′Y ′ data input from the maximum value limiting unit 24, and the gray amount calculating unit 26. , Calculate new C "M" Y "data (third CMY data) in which the CMY values are reduced in the following manner based on the gray amount input from Output to the limit calculation unit 25.
[0079]
C ″ = C′−constant * f2 (gray) * f1 (gray_amt)
M ″ = M′−constant * f2 (gray) * f1 (gray_amt)
Y ″ = Y′−constant * f2 (gray) * f1 (gray_amt)
[0080]
Here, the functions f1 and f2 are experimentally determined as shown in FIGS. 9 and 10, respectively. However, the CMY limiting unit 27 reduces the CMY value as the saturation is closer to gray and the CMY amount is larger. Any conversion is sufficient.
[0081]
The CMY restriction unit 27 constitutes the gray amount adjusting means of the present invention, and this processing constitutes the gray amount adjusting step of the present invention.
[0082]
Then, in the total amount limit calculation unit 25, based on the total amount of the C "M" Y "data input from the CMY restriction unit 27 and the K data input from the K generation unit 22, the C" The M ″ Y ″ data is adjusted to obtain C ″ ′ M ′ ″ Y ′ ″ K data (output CMYK data).
[0083]
At this time, the color separation curves from white (W) to red (Red) to black (K) are hardly affected by the addition of new processing as shown in FIG. The color separation curves from gray to gray (K) are different as shown in FIG. C2 in FIG. 12 is the C component on the gray axis in the configuration of the second embodiment, and C1 is the C component in the configuration of the first embodiment. The same applies to M. That is, by adding the processing of the second embodiment, the ratio of K to CMY can be changed only in the gray axis and its periphery. It should be noted that although the smoothing process is performed in each case, the same tendency remains even if the smoothing process is not performed.
[0084]
In this way, the high-saturation color is not changed, and the Y, M, and C inks can be reduced from the low-saturation, high-Y, M, and C portions. In other words, the Y, M, and C values corresponding to the K value can be reduced in the ink configuration near gray.
[0085]
For this reason, when C, M, and K are composed of two or more types of inks having different densities, when the light K ink is recorded in the same amount per unit area, the lightness of the light C ink is lower than that of the light C and M inks, , M ink, it is possible to set the medium density in the vicinity of gray to appear in the light color K dots prior to the dark color C, M dots. Deterioration of roughness due to color dots can be avoided. Of course, if the amounts of K and Y, M, and C are changed, the lightness (density) of the gray generated by the combination will be different, but this will not be a problem because it will be corrected at the time of color matching described later. Here, the effect of optimizing the setting of the combination of Y, M, C, and K forming gray is important.
[0086]
As a first modification of the second embodiment, a configuration in which the order of the CMY restriction unit 27 and the total amount restriction calculation unit 25 shown in FIG. FIG. 13 shows a block diagram of this configuration.
[0087]
That is, the hue determination / tone calculation unit 23 outputs a parameter indicating the degree of gray: gray to the CMY restriction unit 27 in the same manner as described above, based on the CMY data input from the CMY generation unit 21. .
[0088]
Further, the total amount limit calculating unit 25 calculates the C′M′Y ′ data based on the total amount of the C′M′Y ′ data generated by the maximum value limiting unit 24 and the K data generated by the K generating unit 22. Is adjusted to generate C ″ M ″ Y ″ K data (fourth CMYK data) and output it to the gray amount calculation unit 26 and the CMY restriction unit 27.
[0089]
The gray amount calculator 26 calculates the minimum value of the C "M" Y "data input from the total amount limit calculator 25 as a gray amount: gray_amt. That is,
gray_amt = min (C ″, M ″, Y ″) / 255
, And outputs the result to the CMY restriction unit 27.
[0090]
Then, the CMY restriction unit 27 calculates the gray degree: gray input from the hue determination / tone calculation unit 23, the C ″ M ″ Y ″ K data input from the total amount restriction calculation unit 25, Based on the gray amount: gray_amt input from the gray amount calculation unit 26, new C ′ ″ M ′ ″ Y ′ ″ K data (output CMYK data Get)
[0091]
C ′ ″ = C ″ −constant * f2 (gray) * f1 (gray_amt)
M ′ ″ = M ″ −constant * f2 (gray) * f1 (gray_amt)
Y ′ ″ = Y ″ −constant * f2 (gray) * f1 (gray_amt)
[0092]
Even with such a configuration, the same effect as described above can be obtained. In particular, this mode is suitable for a case where it is desired to further reduce the ink amount near the maximum density because the CMY restriction unit 27 reduces the ink amount near gray after the processing by the total amount restriction calculation unit 25.
[0093]
Further, as a second modified example of the second embodiment, instead of the dark and light inks, C, M, and K use two or more types of dots having different sizes, and the small dots of K are smaller than the small dots of C and M. Also, when the brightness is low and the brightness is higher than the large dots of C and M, if the values of (Y,) M and C with respect to K are reduced, the value of K decreases prior to the large dots of M and C. Since the dots can be generated, it is possible to avoid the deterioration of the roughness due to the dark C and M color dots as described above. Further, as a secondary effect, the amount of ink near the gray axis can be reduced.
[0094]
(Third embodiment)
Next, a third embodiment of the color separation processing in the image processing apparatus according to the present invention will be described.
[0095]
In a printing paper or an ink jet printer, the expressible color (color gamut) may be wider in a C to G region than in a monitor. FIG. 14 shows a comparison of the color reproduction range between a general monitor RGB space and a CMYK space of an inkjet printer. The figure shows the color gamut at L * = 50 on the Lab plane, where the alternate long and short dash line indicates the color reproduction range of the monitor, and the solid line indicates the color reproduction range of the printer. The dotted line will be described later.
[0096]
FIG. 14 shows that a vivid color that cannot be reproduced on a monitor can be reproduced by a printer depending on color matching. However, if color matching is performed so as to actually use the entire color space of the printer, the color near C may be reproduced too vividly and may look unnatural in a natural image. As a countermeasure for this, it is conceivable to specify for each hue how much to extend from the original color gamut at the time of color matching, but the process for realizing it is complicated.
[0097]
In such a case, if the image processing (color separation processing) according to the present invention is applied and the CMYK space is restricted from RGB beforehand and color matching is performed, the color gamut on the output side becomes a condition that uses the entire color space of the printer. And various processes and settings in color matching are facilitated. Here, the following condition (3) is added to the conditions (1) and (2) described in the first embodiment.
[0098]
{Circle around (3)} For the G and C hues, the maximum value of the color corresponding to the main density (= C) is limited to 80%.
[0099]
The color gamut in this case is a dotted line superimposed on FIG. 14, and it can be seen that the color gamut of G to C can be limited in the corresponding region.
[0100]
With the above restrictions, color separation from RGB data to CMYK was performed, printing was performed from the obtained CMYK data, colorimetry was performed, and a printer profile was created. Furthermore, as a result of performing color matching using the monitor RGB as the target color by the color management system, the saturation is not overemphasized as compared with the case where C is not limited, and is more vivid and appropriate than the case where the original RGB is faithfully matched. Conversion was done.
[0101]
The conversion relationship between the input data and the printer is obtained as a conversion characteristic of the preceding stage of the color separation unit 2B as a color matching unit for RGB to RGB as shown in FIG. Specifically, the color matching unit 2A can be configured by a three-dimensional LUT and a discrete operation for discrete values of input RGB data.
[0102]
At this time, if the three-dimensional LUTs including the color separation unit are combined into one as shown by reference numeral 2C as shown in FIG. 15B, color conversion from the target color can be performed at high speed.
[0103]
It should be noted that the present invention is not limited to the embodiment described above, and can be modified within the technical scope described in the claims. For example, the CMY generating unit 21 may convert the above-described conversion into gamma-converted CMY using an appropriate curve.
[0104]
The generation of K in the K generation unit 22 may be generated experimentally or set analytically as a function of C, M, and Y.
[0105]
Further, the method of determining the hue in the hue determination and tint calculation unit 23 is not limited to this, and, for example, the above equation is slightly changed.
dB = max {f (f (C−Y) − | C−M |), f (f (M−Y) − | C−M |)}
dG = max {f (f (C−M) − | C−Y |), f (f (Y−M) − | C−Y |)}
dR = max {f (f (MC)-| MY |), f (f (YC)-| MY |)}
dY = max {f (f (Y-C)-| CM-), f (f (Y-M)-| CM-)}
dM = max {f (f (M−Y) − | C−Y |), f (f (M−C) − | C−Y |)}
dC = max {f (f (CM)-| MY |), f (f (CY)-| MY |)}
An expression may be used, or the hue may be determined by directly evaluating the chromaticity indicated by the RGB space in a uniform color space.
[0106]
Further, the numerical value of the maximum value restricting unit 24 is not limited to the value described above, and may be appropriately set in consideration of the color of the corresponding color material, restrictions on the amount of ink, and the like.
[0107]
【The invention's effect】
According to the present invention, it is possible to provide an image processing method and an image processing apparatus that can maintain saturation, reduce roughness, and obtain a smooth gradation while reducing the total amount of ink for each hue by a simple calculation. it can.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration example of an image processing system using an image processing apparatus according to the present invention.
FIG. 2 is a configuration block diagram illustrating a first embodiment of an image processing apparatus according to the present invention;
FIG. 3 shows an example of a K data generation table.
FIG. 4 is a graph showing chromaticity of B with and without limiting the maximum values of M and C.
FIG. 5 is a graph showing a color separation curve from white to red to black when the present invention is applied.
FIG. 6 is a graph showing a conventional ink amount limitation.
FIG. 7 is a graph showing a color separation curve when a smoothing process is performed;
FIG. 8 is a configuration block diagram illustrating a second embodiment of the image processing apparatus according to the present invention.
FIG. 9 is a graph showing a function f1.
FIG. 10 is a graph showing a function f2.
FIG. 11 is a graph showing a color separation curve from white to red to black.
FIG. 12 is a graph showing a color separation curve from white to gray to black.
FIG. 13 is a configuration block diagram illustrating a first modification of the second embodiment of the image processing apparatus according to the present invention;
FIG. 14 is a graph showing a comparison of a color gamut between a general monitor RGB space and a CMYK space of an inkjet printer.
FIGS. 15A and 15B are block diagrams showing a conversion relationship between RGB data and CMYK data, respectively.
[Explanation of symbols]
1: Image input device
2: Image processing device
3: Image output device
21: CMY generation unit
22: K generation unit
23: Hue judgment / color calculation unit
24: Maximum value limit section
25: Total amount calculation unit
26: Gray amount calculation unit
27: CMY restriction unit
2A: Color matching section
2B: color separation unit

Claims (14)

An image processing method of inputting original RGB data, separating the color into CMYK data, and outputting the separated data.
An initial value setting step of setting first CMYK data corresponding to a combination of original RGB data;
A hue determining step of determining which hue of the first CMY data belongs to R, G, B, C, M, or Y;
A maximum value limiting step of limiting the first CMY data to a maximum value of each color set in advance for each hue to obtain second CMY data based on a result of the hue determination step;
A total amount adjusting step of adjusting the second CMY data based on the total amount of the second CMY data and the first K data to obtain CMYK data for output;
An image processing method comprising: An image processing method of inputting original RGB data, separating the color into CMYK data, and outputting the separated data.
An initial value setting step of setting first CMYK data corresponding to a combination of original RGB data;
A hue determining step of determining which hue of the first CMY data belongs to R, G, B, C, M, or Y;
A maximum value limiting step of limiting the first CMY data to a maximum value of each color set in advance for each hue to obtain second CMY data based on a result of the hue determination step;
A gray level calculating step of calculating a gray level from the first CMY data;
A gray amount calculating step of calculating a gray amount from the second CMY data;
A gray amount adjusting step of reducing CMY data from the second CMY data using the gray degree and the gray amount to obtain third CMY data;
A total amount adjusting step of adjusting the third CMY data based on the total amount of the third CMY data and the first K data to obtain output CMYK data;
An image processing method comprising: An image processing method of inputting original RGB data, separating the color into CMYK data, and outputting the separated data.
An initial value setting step of setting first CMYK data corresponding to a combination of original RGB data;
A hue determining step of determining which hue of the first CMY data belongs to R, G, B, C, M, or Y;
A maximum value limiting step of limiting the first CMY data to a maximum value of each color set in advance for each hue to obtain second CMY data based on a result of the hue determination step;
A total amount adjusting step of adjusting the second CMY data based on the total amount of the second CMY data and the first K data to obtain fourth CMYK data;
A gray level calculating step of calculating a gray level from the first CMY data;
A gray amount calculating step of calculating a gray amount from the fourth CMY data;
A gray amount adjusting step of reducing CMY data from the fourth CMY data using the gray degree and the gray amount to obtain output CMYK data;
An image processing method comprising: 4. The method according to claim 1, wherein the correspondence between the generated original RGB data and the CMYK data is held as a three-dimensional table, and the color separation from the original RGB data to the CMYK data is performed using the three-dimensional table. Image processing method. 5. The image processing method according to claim 4, wherein a smoothing process is performed on the data stored in the three-dimensional table. At least C, M, and K are composed of two or more types of dots having different densities per unit area, and a light K dot has a lower brightness than a light C and M dot when printed in the same amount per unit area, and a dark C dot. 6. The image processing method according to claim 1, wherein the output is a color separation output to an output device having dots higher than M dots. Based on the color separation relationship, CMYK data corresponding to the original RGB data is output, printing is performed based on the values, and the reproduction characteristics of the output device are obtained from the colorimetric data. After performing color matching between the input data and the output data and creating color correction data between input and output, the data is combined with the color separation to form a relationship between the input data and the final CMYK output into one multidimensional table. The image processing method according to claim 1. An image processing apparatus for inputting original RGB data, color-separating the same into CMYK data and outputting the same,
Initial value setting means for setting first CMYK data corresponding to a combination of original RGB data;
Hue determination means for determining which of the R, G, B, C, M, and Y colors the first CMY data belongs to;
A maximum value limiting unit that limits the first CMY data to a maximum value of each color set in advance for each hue and obtains second CMY data based on a determination result by the hue determining unit;
Total amount adjusting means for adjusting the second CMY data based on the total amount of the second CMY data and the first K data to obtain output CMYK data;
An image processing apparatus comprising: An image processing apparatus for inputting original RGB data, color-separating the same into CMYK data and outputting the same,
Initial value setting means for setting first CMYK data corresponding to a combination of original RGB data;
Hue determination means for determining which of the R, G, B, C, M, and Y colors the first CMY data belongs to;
A maximum value limiting unit that limits the first CMY data to a maximum value of each color set in advance for each hue to obtain second CMY data based on a determination result of the hue determining unit;
A gray level calculating means for calculating a gray level from the first CMY data;
Gray amount calculating means for calculating the amount of gray from the second CMY data;
Gray amount adjusting means for reducing CMY data from the second CMY data using the gray degree and the gray amount to obtain third CMY data;
Total amount adjusting means for adjusting the third CMY data to obtain output CMYK data based on the total amount of the third CMY data and the first K data;
An image processing apparatus comprising: An image processing apparatus for inputting original RGB data, color-separating the same into CMYK data and outputting the same,
Initial value setting means for setting first CMYK data corresponding to a combination of original RGB data;
Hue determination means for determining which of the R, G, B, C, M, and Y colors the first CMY data belongs to;
Maximum value limiting means for limiting the first DMY data to a maximum value of each color set in advance for each hue and obtaining second CMY data based on a determination result of the hue determining means;
Total amount adjusting means for adjusting the second CMY data to obtain fourth CMYK data based on the total amount of the second CMY data and the first K data;
A gray level calculating means for calculating a gray level from the first CMY data;
Gray amount calculating means for calculating the amount of gray from the fourth CMY data;
Gray amount adjusting means for reducing CMY data from the fourth CMY data using the gray degree and the gray amount to obtain output CMYK data;
An image processing apparatus comprising: 10. A storage device for holding a correspondence from the generated original RGB data to CMYK data as a three-dimensional table, and performing color separation from the original RGB data to CMYK data using the three-dimensional table. Or the image processing apparatus according to 10. The image processing apparatus according to claim 11, further comprising a smoothing processing unit that performs a smoothing process on the data stored in the three-dimensional table. At least C, M, and K are composed of two or more types of dots having different densities per unit area, and a light K dot has a lower brightness than a light C and M dot when printed in the same amount per unit area, and a dark C dot. The image processing apparatus according to any one of claims 8 to 12, wherein the output is color separation output to an output device having a dot higher than M dots. Based on the color separation relationship, CMYK data corresponding to the original RGB data is output, printing is performed based on the values, and the reproduction characteristics of the output device are obtained from the colorimetric data. After performing color matching between the input data and the output data and creating color correction data between input and output, the data is combined with the color separation to form a relationship between the input data and the final CMYK output into one multidimensional table. The image processing device according to claim 8.

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