JP2011211392A - Method for creating rgb-cmy correspondence relation table - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve accuracy and a gradation property of colors whose high accuracy is requested in an output of a color image while suppressing an increase in colorimetry points.SOLUTION: Lattice points of respective lattices obtained by equally dividing a CMY three-dimensional cubic lattice space are set as colorimetry points, lattice points of respective lattices obtained by dividing respective lattices from a straight line up to a fixed distance, in which CMY output amounts are equal, into four sections are set as colorimetry points (S210), and lattice points of respective lattices obtained by dividing lattices belonging to a beige area including beige in a center into four sections are set as colorimetry points (S220). Namely, colorimetry points are set so that densities of a gray area and the beige area may be increased. Consequently, as compared with a method for equally arranging the same number of colorimetry points, accuracy can be improved in conversion to CMY output amounts of respective colors of RGB=(x, y, z) in the gray area and the beige area which may be distinguished by human eyes even in a slight color difference or gradation difference.

Description

  The present invention relates to a method for creating an RGB-CMY correspondence table, and more particularly, to a method for creating an RGB-CMY correspondence table showing a correspondence from RGB to CMY output amounts in an output device.

  Conventionally, as an RGB-CMY correspondence table creation method of this type, Lab color value space using grid points evenly arranged in a three-dimensional cubic grid space of CMY (cyan, magenta, yellow) in an output device as colorimetric points. The color gamut of the output device is defined by measuring the color values at, and grid points that are evenly arranged in the three-dimensional cubic grid space of RGB (red, green, blue) are applied to this color gamut. A method for calculating the output amount of CMY for each of RGB grid points has been proposed (for example, see Patent Document 1). In this method, for example, n × n × n lattice points that are uniformly arranged in a three-dimensional cubic lattice space by CMY are measured as colorimetric points, and are composed of n × n × n in a Lab color value space. A color gamut is defined, and m × m × m lattice points that are evenly arranged in the three-dimensional cubic lattice space of RGB are plotted in this color gamut, and n × n × n pieces constituting the color gamut By calculating the CMY output amount of the plotted point with weights applied to the color values of the colorimetric points in the vicinity of the plotted point among the colorimetric points, the RGB grid points are converted into the CMY output amount. A table is created as a correspondence relationship.

Japanese Patent No. 2895086

  However, in the above-described method, since the grid points arranged uniformly in the three-dimensional cubic grid space by CMY are used as the colorimetric points, an unnecessarily large number of colors are required in order to improve color accuracy and gradation. Color measurement must be performed. If grid points that are evenly arranged in a three-dimensional cubic lattice space by CMY are used as colorimetric points, colorimetry for colors that do not require very high accuracy in color image output also requires high accuracy in color image output. Color measurement of colors (for example, gray and skin color) is also performed uniformly. For this reason, color measurement that requires high accuracy requires a large number of color measurement points in order to achieve good color accuracy and gradation, so color measurement of colors that do not require very high accuracy in color image output As a result, the number of colorimetric measurements will be larger than necessary.

  The RGB-CMY correspondence table creation method of the present invention is intended to improve the color accuracy and gradation required for high accuracy in color image output while suppressing an increase in colorimetric points. And

  The RGB-CMY correspondence table creation method of the present invention employs the following means in order to achieve the main object described above.

The RGB-CMY correspondence table creation method of the present invention is as follows.
A color value in a predetermined color value space is measured using a plurality of reproduced colors output by adjusting the output amount of CMY by an output device that outputs a color image by adjusting the output amount of CMY. Thus, the color gamut of the output device is defined, and the RGB reference point, which is the reference point in the RGB color space, is applied to the defined color gamut to change the output amount of CMY from the RGB reference point to the output device. An RGB-CMY correspondence table creation method for creating an RGB-CMY correspondence table showing the correspondence relationship of
The plurality of colorimetric points are set so that the density in the central region is higher than the density in the outer region of the three-dimensional cubic lattice space when the three-dimensional cubic lattice space is formed by CMY.
It is characterized by that.

  In this RGB-CMY correspondence table creation method of the present invention, when a three-dimensional cubic lattice space is formed by CMY, colorimetry is performed so that the density in the central region is higher than the density in the outer region of the three-dimensional cubic lattice space. Set a point. The outer area of the three-dimensional cubic lattice space by CMY is generally a color region that does not require much accuracy in the output of a color image, and the central region of the three-dimensional cubic lattice space by CMY is generally high in the output of a color image. Since this is a color area where accuracy is required, the density in the color area where high accuracy is required for color image output will be higher than the density in the color area where accuracy is not so required for color image output. The colorimetric point is set to. As a result, when the number of colorimetric points is the same, higher accuracy is required in the output of a color image compared to a colorimetric point having grid points evenly arranged in a three-dimensional cubic lattice space by CMY. The color accuracy and gradation can be improved. In other words, it is possible to improve the color accuracy and gradation that require high accuracy in the output of a color image while suppressing an increase in colorimetric points. Note that “CMY” includes not only three colors (CMY) of cyan, magenta, and yellow, but also four colors (CMYK) of cyan, magenta, yellow, and black.

  In such an RGB-CMY correspondence table creation method of the present invention, when the plurality of colorimetric points are set to a three-dimensional cubic lattice space by CMY, the density in an equal area including straight lines in which CMY is equal is more preferable. It is characterized in that the density is set to be higher than the density outside the equivalence region, or when the predetermined color value space is the Lab space, the plurality of colorimetric points are (a, b) = ( The density in a region including a straight line of (0, 0) may be set to be higher than the density outside the region. Since the straight line in which CMY is equal and the straight line of (a, b) = (0, 0) in Lab space are gray straight lines connecting white and black, the gray gradation can be obtained by adopting the above-described embodiment. The property can be improved.

  Further, in the RGB-CMY correspondence table creation method of the present invention, when the plurality of colorimetric points are in a three-dimensional cubic lattice space by CMY, the density in the region on the MY plane side from the center is higher from the center to the MY plane. It can also be characterized by being set to be higher than the density in the region on the opposite side. Since the skin color is in the region on the MY plane side from the center when it is a three-dimensional cubic lattice space by CMY, the above-described aspect makes it possible to suppress the increase in colorimetric points and suppress the accuracy and scale of the color near the skin color. The tonality can be improved.

  Alternatively, in the RGB-CMY correspondence table creation method of the present invention, the plurality of colorimetric points are set such that the density in the skin color area including the skin color is higher than the density outside the skin color area. It can also be a feature. By so doing, it is possible to improve the color accuracy and gradation of the skin color region while suppressing an increase in colorimetric points.

The flowchart which shows an example of a LUT creation process. 6 is a flowchart illustrating an example of color measurement point setting processing. The flowchart which shows an example of a RGB-CMY conversion process. Explanatory drawing which set the colorimetric point by dividing CMY cubic lattice into 27 equal parts. Explanatory drawing which shows a mode when a colorimetric point is added to the CMY equivalence straight line vicinity. Explanatory drawing which shows a mode when a colorimetric point is added to the skin color area | region. Explanatory drawing when calculating the CMY output amount of an RGB point from four colorimetric points. Explanatory drawing which shows an example of LUT.

  Next, the form for implementing this invention is demonstrated. As an embodiment of the present invention, three primary colors of a subtractive color method such as ink used by an inkjet printer using an image source based on RGB (red, green, blue), which is the three primary colors of the additive color method, and toner used by a color laser printer A look-up table used as a correspondence relationship between CMY output amounts (CMY output amounts) of the output device with respect to each color of RGB = (x, y, z) when output by CMY (cyan, magenta, yellow) A method of creating (Look Up Table, LUT) (RGB-CMY correspondence table creation method) will be described.

  FIG. 1 is a flowchart illustrating an example of a look-up table creation process indicating a correspondence relationship between CMY output amounts of an output device for each color of RGB = (x, y, z). As shown in the figure, the lookup table sets discrete colorimetric points for the entire range of CMY output amounts that can be output from the output device (step S100), and performs colorimetry of the set colorimetric points. A color gamut of the output device in the color value space (for example, Lab space) is set (step S110), and each color of RGB = (x, y, z) is plotted in the color gamut of the set output device, It is created by performing RGB-CMY conversion (step S120) for calculating the CMY output amount of each color of RGB = (x, y, z) from the colorimetric point. The created lookup table is incorporated in the driver of the output device, and is used when an RGB image source is output as an output image by CMY. Here, in the embodiment, the colorimetric point setting process in step S100 is performed by the colorimetric point setting process exemplified in FIG. 2, and the RGB-CMY conversion process in step S120 is the RGB-CMY conversion exemplified in FIG. It is done by processing. Hereinafter, it demonstrates in order.

  In the setting of the colorimetric points of the embodiment, first, the grid points of each grid obtained by equally dividing the CMY three-dimensional cubic grid space into n × n × n are set as the colorimetric points (step S200). For ease of explanation, FIG. 4 shows a state in which lattice points of each lattice obtained by equally dividing the CMY three-dimensional cubic lattice space into 3 × 3 × 3 pieces are set as colorimetric points. . In the figure, “C” on the vertical axis indicates the cyan axis, “M” on the horizontal axis indicates the magenta axis, “Y” on the depth axis indicates the yellow axis, and white circles indicate the colorimetric points set in the CMY three-dimensional cubic lattice. Of these, the color measurement points set on three surfaces (the front surface, the right surface, and the upper surface in FIG. 4) are shown. Color measurement points are set on three surfaces other than the above three surfaces (the back surface, the left surface, and the bottom surface in FIG. 4) and the inside of the CMY three-dimensional cubic lattice space, but other than the above three surface color measurement points. When the colorimetric points are illustrated, it is not clear which colorimetric points are arranged in which grid, and therefore the illustration is omitted. As shown in the figure, in the process of step S200, 4 × 4 × 4 colorimetric points are set. The actual colorimetric points are, for example, 32 × 32 × 32, 64 × 64 × 64, or 128 × 128 × 128.

  Subsequently, straight lines in which the output amounts of CMY colors are equal, that is, (C, M, Y) = (0, 0, 0) and (C, M, Y) = (1, 1, 1) Each grid from the straight line connecting the two to a certain distance is divided into four, and the grid points located at the outermost contour of the CMY three-dimensional cubic grid are set as colorimetric points among the grid points of the four divided grids (step S210). ). FIG. 5 shows a state when the process of step S210 is applied to the CMY three-dimensional cubic lattice of FIG. In FIG. 5, the colorimetric points are set such that three grids on a straight line with equal CMY output amounts correspond to each grid from a straight line with equal CMY output amounts to a certain distance. The white circles of the three target grids indicate the colorimetric points set on the three surfaces (front, right side, and upper surface in FIG. 5) in the process of step S200, and the black circles of the three target grids. Indicates the colorimetric points set on the three surfaces (front, right side, and top surface in FIG. 5) of the colorimetric points added in step S210. Here, the colors on the straight line where the CMY output amounts are equal are “C”, “M”, “Y” = (0, 0, 0) “white” and (C, M, Y) = (1, 1, 1) A color connecting “black”, that is, a gray region. Since gray can be distinguished by a slight gradation difference to human eyes, increasing the number of colorimetric points in this gray area increases the accuracy of conversion of the gray area in RGB to CMY. To do. The reason why the lattice points located at the outermost contour of the CMY three-dimensional cubic lattice are excluded is that the outermost region in the CMY three-dimensional cubic lattice space is a color region that does not require much accuracy when outputting a color image. .

  Next, among the n × n × n grids in step S200, the grid belonging to a predetermined skin color area centered on the skin color is divided into four, and the grid points of each of the four divided grids are set as colorimetric points. (Step S220), the colorimetric point setting process is terminated. FIG. 6 shows a state when the process of step S220 is applied to the CMY three-dimensional cubic lattice of FIG. In FIG. 6, the color measurement point is set assuming that the grid located below the central grid corresponds to the grid belonging to the skin color region. In the drawing, an ellipse indicated by a broken line indicates a skin color region, and a black circle is set on three surfaces (front surface, right side surface, and upper surface in FIG. 5) of the colorimetric points added by the processing of Step S210 and Step S220. The colorimetric point is shown. Here, the skin color is discernable even by a slight color difference or gradation difference to human eyes. Therefore, by increasing the colorimetric points in this skin color area, the CMY of the skin color area in RGB The accuracy of conversion to is increased. In the subtractive color method, the skin color is a mixed region of Y (yellow) and M (magenta) and has a small amount of C (cyan). Therefore, as shown in the CMY three-dimensional cubic lattice space in FIG. This is the side area.

  The colorimetric points set in this way have higher densities in the area from the straight line where the CMY output amount is equal to a certain distance and the skin color area, compared to other areas. The region from the straight line where the CMY output amount is equal to a certain distance is a region including a straight line of (a, b) = (0, 0) in the color value space (Lab space). In other words, the density in the region including the straight line (a, b) = (0, 0) in the color value space (Lab space) and the density in the skin color region are higher than those in the other regions. Further, since the skin color region is a region on the MY plane side from the center in the CMY three-dimensional cubic lattice space, the colorimetric point of the embodiment is the density of the region on the MY plane side from the center in the CMY three-dimensional cubic lattice space. Can be said to be higher than the region on the opposite side of the MY plane from the center in the CMY three-dimensional cubic lattice space. Further, in step S210, a grid point located at the outermost contour of the CMY three-dimensional cubic grid is set as a colorimetric point in a region from a straight line having a constant CMY output amount to a certain distance, or skin color is set in step S220. Since grid points are set in the region, it can be said that the colorimetric point of the embodiment has a higher density in the central region than in the outer region of the CMY three-dimensional cubic lattice space.

  As described above, when a colorimetric point is set, the colorimetric range of the output device in the color value space (for example, Lab space) is set by performing colorimetry of the set colorimetric point, and the color reproduction of the set output device is performed. By performing RGB-CMY conversion processing for plotting each color of RGB = (x, y, z) in the area and calculating the CMY output amount of each color of RGB = (x, y, z) from the neighboring colorimetric points Create a lookup table. Next, the RGB-CMY conversion process will be described with reference to the flowchart of FIG.

  In the RGB-CMY conversion process, first, RGB = (x, y, z) is plotted in a color value space (for example, Lab space) (step S300), and the colorimetric point of the color gamut that sets the color gamut of the output device is set. Four points are extracted from the points closest to the plotted points (RGB points) (step S310), and it is determined whether the RGB points are inside or outside the tetrahedron formed by the extracted four points. (Step S320). When the RGB point is outside the tetrahedron, out of the colorimetric points for which the color gamut of the output device has been set, the point closest to the four points extracted as the RGB point is extracted (step S330) and extracted before. Four points consisting of three of the four points and the newly extracted point are extracted (step S340), and the RGB points are inside or outside the tetrahedron formed by the four extracted points. (Step S340). When the RGB point is outside the tetrahedron, the RGB point is moved forward until all combinations of the three points of the previously extracted four points and the newly extracted point are finished. It is determined whether it is inside or outside a tetrahedron formed by four points including three points of different combinations from the four extracted points and a newly extracted point (steps S340 to S360). When the RGB point is outside the tetrahedron of any of the four points by all combinations, the next closest point to the RGB point is extracted from the colorimetric points that set the color gamut of the output device and extracted before Processing for determining whether there are RGB points inside or outside the tetrahedron formed by the four points formed by three points out of the four points and the newly extracted points (step S330) To S360).

  When it is determined in step S320 that the RGB point is inside the tetrahedron, or when it is determined in step S350 that the RGB point is inside the tetrahedron while the processes in steps S330 to S360 are repeated, the RGB point and the tetrahedron are determined. The CMY output amount at the RGB point is calculated by the complementary calculation with the weight according to the distance from the four points (colorimetric points) forming the body (step S370), and the CMY output calculated as RGB = (x, y, z) is obtained. The competence is stored (step S380). An example of how the CMY output amount of RGB points is calculated from the four colorimetric points forming the tetrahedron is shown in FIG. In the figure, point A is an RGB point, and points P1 to P4 are four colorimetric points forming a tetrahedron. The processes in steps S300 to S380 are performed for all of RGB = (x, y, z) (step S390), and the RGB-CMY conversion process is terminated. FIG. 8 shows an example of a look-up table listing the relationships between stored RGB = (x, y, z) and CMY output amounts.

  According to the method for creating the look-up table of the present embodiment described above, each grid from a straight line having a constant CMY output amount to a certain distance is divided into four, and the CMY cubic among the grid points of each grid divided into four. By setting the colorimetric points excluding the grid points located at the outermost contour of the original cubic lattice, the number of colorimetric points in the gray area that can be distinguished even by a slight gradation difference in the human eye is increased. It is possible to increase the accuracy of conversion of the gray area in x, y, z) into the CMY output amount. In other words, by increasing the density of the colorimetric points in the straight line from the straight line where the CMY output amount is equal to a certain distance, that is, the gray area, the gray color that can be discerned even by a slight gradation difference in the human eye. By increasing the number of colorimetric points in the region, it is possible to increase the accuracy of conversion to the CMY output amount of the gray region in RGB = (x, y, z). In addition, by dividing the grid belonging to the skin color area centered on the skin color into 4 and setting the grid points of each of the 4 grids as colorimetric points, even a slight color difference or gradation difference can be obtained in human eyes. By increasing the number of colorimetric points in the distinguishable skin color area, the accuracy of conversion into the CMY output amount of the skin color area in RGB = (x, y, z) can be increased. In other words, by increasing the density of the colorimetric points in the skin color region, the colorimetric points in the skin color region that can be distinguished even by slight color differences or gradation differences in the human eye are increased, and RGB = (x, It is possible to increase the accuracy of conversion of the skin color area into the CMY output amount in y, z). In addition, since the lattice points of each lattice obtained by equally dividing the CMY three-dimensional cubic lattice space into n × n × n are set as colorimetric points, each color in RGB = (x, y, z) is set to CMY. It can be accurately converted into an output amount. Since the setting of the colorimetric point in the embodiment can be considered to be performed such that the density in the central region is higher than the density in the outer region of the CMY three-dimensional cubic lattice space, the colorimetric point is determined as the CMY three-dimensional cubic lattice. By setting the density in the center area to be higher than the density in the outer area of the space, a slight color difference or gradation in the human eye compared to the case where the same number of colorimetric points are evenly arranged. It can be said that by increasing the density of colorimetric points in a region that can be distinguished even by a difference, the accuracy of conversion into the CMY output amount of that region in RGB = (x, y, z) can be increased. As described above, according to the method for creating the lookup table of this embodiment, the color accuracy and gradation that require high accuracy in the output of the color image while suppressing the increase in the colorimetric points are excellent. It can also be said that.

  In the colorimetric point setting process in the lookup table creation method of the above-described embodiment, each grid from a straight line to a certain distance from which the CMY output amount is equal is divided into four and the grid points of each grid divided into four are set. Of these, the colorimetric points are set except for the grid points located at the outermost contour of the CMY 3D cubic grid. However, the density of the colorimetric points in the range from the straight line where the CMY output amount is equal to a certain distance is set. Since it is only necessary to increase the colorimetric point, the colorimetric points may be set at random using random numbers in a range from a straight line where the CMY output amount is equal to a certain distance. Similarly, for a skin color area centered on the skin color, the grid belonging to this area is divided into four, and the grid points of each of the four grids are not set as colorimetric points, but are randomized using random numbers. It is good also as what sets a colorimetric point to.

  In the colorimetric point setting process in the lookup table creation method of the above-described embodiment, each grid from a straight line to a certain distance from which the CMY output amount is equal is divided into four and the grid points of each grid divided into four are set. Out of the CMY three-dimensional cubic grids, the grid points that are located at the outermost contour are set as colorimetric points, and the grids belonging to the skin color area centered on the skin color are divided into 4 and the grid points of each of the 4 grids are measured. Although it is set as the color point, the colorimetric point is set so that the density of the colorimetric point within the range from the straight line where the CMY output amount is equal to a certain distance is increased, but the measurement in the skin color region is performed. The colorimetric points may not be set so as to increase the density of the color points. Conversely, the colorimetric points are set so that the density of the colorimetric points in the skin color area is increased, but the CMY output is not performed. From a straight line where the ability is equal May not performed setting Hakairoten is to be higher for the density of the color measurement points in the range of up to a constant distance.

  In the RGB-CMY conversion process in the lookup table creation method of the above-described embodiment, the RGB points are composed of four points that are sequentially obtained from among the colorimetric points used when setting the color gamut of the output device. The CMY output amount corresponding to the RGB point is calculated using the four points that form the tetrahedron when inside the tetrahedron, but the output device outputs the CMY output amount corresponding to the RGB point. Any method may be used as long as the calculation is performed based on the colorimetric points used when setting the color reproduction range.

  As mentioned above, although the form for implementing this invention was demonstrated, this invention is not limited to such embodiment at all, and it can implement with a various form in the range which does not deviate from the summary of this invention. Of course.

  The present invention is applicable to an output device using a look-up table, such as a printer manufacturing industry.

Claims (5)

A color value in a predetermined color value space is measured using a plurality of reproduced colors output by adjusting the output amount of CMY by an output device that outputs a color image by adjusting the output amount of CMY. Thus, the color gamut of the output device is defined, and the RGB reference point, which is the reference point in the RGB color space, is applied to the defined color gamut to change the output amount of CMY from the RGB reference point to the output device. An RGB-CMY correspondence table creation method for creating an RGB-CMY correspondence table showing the correspondence relationship of
The plurality of colorimetric points are set so that the density in the central region is higher than the density in the outer region of the three-dimensional cubic lattice space when the three-dimensional cubic lattice space is formed by CMY.
An RGB-CMY correspondence table creation method characterized by the above. The RGB-CMY correspondence table creation method according to claim 1,
The plurality of colorimetric points are set so that the density in an equivalence region including a straight line in which CMY is equal when the three-dimensional cubic lattice space is formed by CMY is higher than the density outside the equivalence region. Become,
An RGB-CMY correspondence table creation method characterized by the above. The RGB-CMY correspondence table creation method according to claim 1,
When the predetermined color value space is a Lab space, the density of the plurality of colorimetric points is higher in the area including the straight line of (a, b) = (0, 0) than in the area outside the area. Will be set as
An RGB-CMY correspondence table creation method characterized by the above. An RGB-CMY correspondence table creation method according to any one of claims 1 to 3,
The plurality of colorimetric points are set so that the density in the region on the MY plane side from the center is higher than the density in the region on the opposite side of the MY plane from the center when a three-dimensional cubic lattice space is formed by CMY. Become,
An RGB-CMY correspondence table creation method characterized by the above. An RGB-CMY correspondence table creation method according to any one of claims 1 to 3,
The plurality of colorimetric points are set such that the density in the skin color area including the skin color is higher than the density outside the skin color area.
An RGB-CMY correspondence table creation method characterized by the above.

Images