JP4336807B2 - Printed halftone dot and printing method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is used for printed matter that requires anti-counterfeit and tamper-proof functions including banknotes, passports, securities, cards, and valuable printed matter.
[0002]
[Prior art]
Forgery prevention technology for securities includes a method using fine lines such as a background pattern, a color pattern, a relief pattern, and a method using a fine component such as a minute character. Basically, a pattern is constituted by a set of curved lines having a fixed line width, and minute characters are arranged. The patterns can be protected against counterfeiting and alteration in consideration of design such as securities design, and it is difficult to duplicate the same pattern by making the pattern complicated. Also, as a counterfeit prevention measure, colors that make extraction difficult by a photoengraving device or reproduction by a copying machine are used, or moiré is generated with respect to scanning input / output of a copying machine or scanner by making a complicated curved line. Has increased its role. In addition, these patterns have been widely used as securities designs, and at the same time have been used for a long time as patterns of printed matter having monetary values including banknotes, stock certificates, bonds, etc. It is an important design as an impressive design.
[0003]
[Problems to be solved by the invention]
However, in recent years, with the increase in image quality of color copiers and computerization of color platemaking techniques, counterfeiting means for banknotes and securities tend to be diversified. In particular, the resolution of image input / output devices used in the printing industry has significantly improved, and it has become easier to extract fine lines and minute characters used in securities. This suggests the possibility of more serious counterfeiting not only by counterfeiting by the general commercial printing method consisting of a halftone dot configuration of four colors but also by using many special color plates.
[0004]
Therefore, the present invention provides a continuous tone using halftone dots obtained by image processing of a predetermined input image, which is difficult to reproduce with a photoengraving apparatus and can be machine-readable. It is intended to prevent forgery of printed matter by printing an image.
[0005]
[Means for Solving the Problems]
When the halftone dot printed matter of the present invention prints a halftone dot for expressing a continuous tone image, the halftone region for printing the halftone dot is m × m pixels (m ≧ 2, m is an integer). Two halftone areas of a halftone area and n × n pixels (1 ≦ n <m, where n is an integer) are arranged without overlapping the two halftone areas, Four m × m pixel halftone regions in independent regions surround one n × n pixel halftone region without any gap, and four n × n pixels in independent regions The two types of halftone areas are configured so that the halftone areas are arranged at equal intervals along the outer periphery of one m × m pixel halftone area. It is characterized in that the dot using both types of half-tone region of the tone area is printed.
[0006]
Further, the halftone dot printed matter of the present invention is a predetermined continuous region composed of the two types of halftone regions, and uses one type of continuous tone image using both types of halftone regions. A halftone dot for printing is printed, and one continuous tone image is printed in the predetermined area.
[0007]
Also, the halftone dot printed matter of the present invention provides one continuous tone image for each halftone area of each of the two types of halftone areas in the predetermined area composed of the two types of halftone areas. A halftone dot for expression is printed, and two continuous tone images are printed in the predetermined area.
[0008]
In addition, the halftone dot printed matter of the present invention can be used to print the continuous tone image using one of two types of inks that appear to be the same color with the naked eye under normal light but have different optical characteristics. Printing a halftone dot for expression, printing an area excluding the halftone dot for expressing the continuous tone image using the other ink of the two types of ink, and under the predetermined viewing conditions The continuous tone image can be visually recognized, and the predetermined region is printed so as to appear to be the same color as a whole by the naked eye under normal light.
[0009]
The halftone dot printed matter of the present invention uses either one of two types of inks that appear to be the same color with the naked eye under normal light but have different optical characteristics in the predetermined area. A halftone dot for expressing one of the two continuous tone images is printed, and the other of the two continuous tone images is printed using the other of the two types of ink. Prints halftone dots to express a gradation image, and the ink has different optical characteristics from either of the two types of ink but appears to be the same color as the two types of ink with the naked eye under normal light. Use this to print the area excluding the halftone dots for expressing the two continuous tone images, and to view one of the two continuous tone images under a predetermined viewing condition. And a predetermined different from the predetermined viewing condition The other continuous tone image of the two continuous tone images can be visually recognized under recognition conditions, and the predetermined region is printed with the naked eye under normal light so that it appears to be the same color as a whole. It is characterized by having.
[0010]
Further, the halftone dot printed matter of the present invention may be printed on any one of the two types of halftone areas to represent the continuous tone image. It is characterized in that it is a halftone dot obtained by internally blurring the inside of a contour of a predetermined input image corresponding to a type of halftone region.
[0011]
Further, in the halftone dot printed matter of the present invention, the halftone dot printed on any one of the two types of halftone areas in order to represent the continuous tone image has either one of the above halftone areas. It is characterized in that it is a halftone dot obtained by external blurring processing or external density dispersion processing on the outside of a predetermined input image corresponding to a type of halftone region.
[0012]
Further, in the halftone dot printed matter of the present invention, the halftone dot printed on any one of the two types of halftone areas in order to represent the continuous tone image has either one of the above halftone areas. A halftone dot obtained by internally blurring the inside of a contour of a predetermined input image corresponding to a type of halftone region, and internally sharpening the intersection of the lines of the predetermined input image. It is said.
[0013]
Further, in the halftone dot printed matter of the present invention, the halftone dot printed on any one of the two types of halftone areas in order to represent the continuous tone image has either one of the above halftone areas. It is a halftone dot obtained by internally blurring the inside of the outline of a predetermined input image corresponding to the type of halftone area and externally blurring or external density dispersing the outside of the outline of the predetermined input image. It is a feature.
[0014]
Further, in the halftone dot printed matter of the present invention, the halftone dot printed on any one of the two types of halftone areas in order to represent the continuous tone image has either one of the above halftone areas. The inside of the outline of the predetermined input image corresponding to the type of halftone region is internally blurred, the internal sharpening process is performed on the intersection of the lines of the predetermined input image, and the outside of the outline of the predetermined input image is externally applied. A halftone dot obtained by blurring processing or external density dispersion processing is characterized.
[0015]
Further, in the halftone dot printed matter of the present invention, the halftone dot printed on any one of the two types of halftone areas in order to represent the continuous tone image has either one of the above halftone areas. A halftone dot obtained by externally blurring or external density dispersion processing the outline of a predetermined input image corresponding to a halftone area of various types, and assigning a density zero area of several pixels to the outline area of the predetermined input image It is characterized by being.
[0016]
Further, in the halftone dot printed matter of the present invention, the halftone dot printed on any one of the two types of halftone areas in order to represent the continuous tone image has either one of the above halftone areas. The inside of the outline of the predetermined input image corresponding to the type of halftone area is internally blurred, the outside of the predetermined input image is externally blurred or the external density is dispersed, and the number of the outline area of the predetermined input image It is characterized by being halftone dots obtained by assigning a pixel density zero region.
[0017]
Further, in the halftone dot printed matter of the present invention, the halftone dot printed on any one of the two types of halftone areas in order to represent the continuous tone image has either one of the above halftone areas. The inside of the outline of the predetermined input image corresponding to the type of halftone area is internally blurred, the internal sharpening process is performed on the intersection of the lines of the predetermined input image, and the outside of the predetermined input image is externally blurred This is a halftone dot obtained by performing processing or external density dispersion processing and assigning a density zero area of several pixels to the contour area of the predetermined input image.
[0018]
The halftone dot printed matter of the present invention is a halftone region used for expressing the continuous tone image, and is printed on the other type of halftone region excluding the one type of halftone region. The halftone dot to be processed is a halftone dot obtained by subjecting the inside of the outline of a predetermined input image corresponding to the other type of halftone region to an internal blurring process.
[0019]
The halftone dot printed matter of the present invention is a halftone region used for expressing the continuous tone image, and is printed on the other type of halftone region excluding the one type of halftone region. The halftone dot is a halftone dot obtained by external blurring processing or external density dispersion processing on the outside of a predetermined input image corresponding to the other type of halftone region.
[0020]
The halftone dot printed matter of the present invention is a halftone region used for expressing the continuous tone image, and is printed on the other type of halftone region excluding the one type of halftone region. The halftone dot to be obtained is obtained by internally blurring the inside of the contour of the predetermined input image corresponding to the other type of halftone region and by sharpening the interior at the intersection of the lines of the predetermined input image. It is characterized by being a halftone dot.
[0021]
The halftone dot printed matter of the present invention is a halftone region used for expressing the continuous tone image, and is printed on the other type of halftone region excluding the one type of halftone region. The halftone dot is subjected to internal blurring processing inside the contour of the predetermined input image corresponding to the other type of halftone region, and external blurring processing or external density dispersion processing is performed outside the contour of the predetermined input image. It is characterized by the obtained halftone dot.
[0022]
The halftone dot printed matter of the present invention is a halftone region used for expressing the continuous tone image, and is printed on the other type of halftone region excluding the one type of halftone region. The halftone dot is internally blurred inside the outline of the predetermined input image corresponding to the other type of halftone region, and the internal sharp blurring process is performed on the intersection of the lines of the predetermined input image, A halftone dot obtained by external blurring processing or external density dispersion processing outside the contour of a predetermined input image is characterized.
[0023]
The halftone dot printed matter of the present invention is a halftone region used for expressing the continuous tone image, and is printed on the other type of halftone region excluding the one type of halftone region. The halftone dot is subjected to external blurring processing or external density dispersion processing on the outside of the contour of the predetermined input image corresponding to the other type of halftone region, and a density of several pixels is zero in the contour region of the predetermined input image. It is characterized by halftone dots obtained by assigning areas.
[0024]
The halftone dot printed matter of the present invention is a halftone region used for expressing the continuous tone image, and is printed on the other type of halftone region excluding the one type of halftone region. The halftone dot to be subjected to the internal blur processing inside the outline of the predetermined input image corresponding to the other type of halftone region, the external blur processing or external density dispersion processing outside the predetermined input image, The halftone dot is obtained by assigning a zero-density area of several pixels to the contour area of a predetermined input image.
[0025]
The halftone dot printed matter of the present invention is a halftone region used for expressing the continuous tone image, and is printed on the other type of halftone region excluding the one type of halftone region. The halftone dot is internally blurred inside the outline of the predetermined input image corresponding to the other type of halftone region, and the internal sharp blurring process is performed on the intersection of the lines of the predetermined input image, It is characterized in that it is a halftone dot obtained by performing external blurring processing or external density dispersion processing on the outside of a predetermined input image and assigning a density zero area of several pixels to the outline area of the predetermined input image.
[0026]
In the halftone dot printed matter of the present invention, the predetermined input image is at least one of a meaningful image including any of a trademark, a family crest, a logo mark, and a character, and an image including any of a circle, an ellipse, and a polygon. It is characterized by being composed of such images.
[0027]
Further, according to the printing method of a halftone print of the present invention, when printing a halftone dot for expressing a continuous tone image, m × m pixels (m ≧ 2) as a halftone region for printing the halftone dot. , M are integers) and a halftone area of n × n pixels (1 ≦ n <m, n is an integer) are provided, and the two halftone areas are connected to each other. The four m × m pixel halftone regions that are arranged without overlapping each other and surround the one n × n pixel halftone region without any gap and are in independent regions. The two types of halftone areas are configured so that the four n × n pixel halftone areas are arranged at equal intervals along the outer periphery of the one m × m pixel halftone area. It is characterized by printing the dot using both types of half-tone region of the two half-tone region.
[0028]
In the printing method of a halftone printed matter according to the present invention, in a predetermined region constituted by the two types of halftone regions, one continuous using both types of halftone regions of the two types of halftone regions. A halftone dot for expressing a gradation image is printed, and one continuous gradation image is printed in the predetermined area.
[0029]
The halftone print product printing method according to the present invention is a predetermined area composed of the two types of halftone areas, wherein one continuous level is provided for each type of halftone area of the two types of halftone areas. A halftone dot for expressing a tone image is printed, and two continuous tone images are printed in the predetermined area.
[0030]
The halftone dot printed matter printing method of the present invention is arranged such that circular dots corresponding to the m × m pixel halftone region are arranged in all the m × m pixel halftone regions, and the n × n pixels. A black-and-white binary halftone image in which circular dots corresponding to the halftone area are arranged in all the n × n pixel halftone areas, and a circular dot corresponding to the m × m pixel halftone area. Black and white inverted circular dots are arranged in all the m × m pixel halftone areas, and the circular dots corresponding to the n × n pixel halftone areas are all the n × n pixel halftones. Only the continuous black region is selected from the images obtained by performing the image calculation processing on the black and white binary halftone image arranged in the region, and the m × m pixel is selected. A mask matching the halftone area of the cell is produced, and the mask is overlaid on the predetermined area so as to match the halftone area of the m × m pixels, so that the n × n from the predetermined area. A halftone region of a pixel is extracted, and a mask obtained by inverting the black and white of the mask is overlaid on the predetermined region so as to coincide with the halftone region of the n × n pixels, so that the predetermined region is After extracting the m × m pixel halftone region, the predetermined region is divided into two types of halftone regions, the m × m pixel halftone region and the n × n pixel halftone region. , Assign each type of halftone area to the corresponding continuous tone image, one for each type of halftone area. It is characterized by printing a dot to represent a continuous tone image.
[0031]
Further, the printing method of the halftone print of the present invention is the ink of either one of the two types of inks that appear to be the same color with the naked eye under normal light but have different optical characteristics in the predetermined area. Printing a halftone dot for expressing the continuous tone image using the above, and printing a region excluding the halftone dot for expressing the continuous tone image using the other of the two types of ink, The continuous tone image can be visually recognized under a predetermined viewing condition, and the predetermined region is printed so as to appear as a uniform color as a whole with the naked eye under normal light.
[0032]
Further, the printing method of the halftone print of the present invention is the ink of either one of the two types of inks that appear to be the same color with the naked eye under normal light but have different optical characteristics in the predetermined area. Is used to print a halftone dot for expressing one of the two continuous tone images, and the other of the two types of inks is used to print the two continuous tone images. The other halftone dot is printed to represent the continuous tone image, and the optical properties are different from any of the two types of ink, but it is the same color as the two types of ink by the naked eye under normal light. A region excluding halftone dots for expressing the two continuous tone images using visible ink is printed, and one of the two continuous tone images is printed under a predetermined viewing condition. Can be visually recognized and differ from the predetermined viewing conditions. The other continuous tone image of the two continuous tone images can be viewed under a predetermined viewing condition, and the predetermined region as a whole appears to be the same color with the naked eye under normal light. It is characterized by printing.
[0033]
In the printing method of halftone dot printed matter of the present invention, the halftone dot printed in any one of the two types of halftone areas to express the continuous tone image is any of the above halftone areas. A halftone dot obtained by internally blurring the inside of a contour of a predetermined input image corresponding to one of the halftone areas is characterized.
[0034]
In the printing method of halftone dot printed matter of the present invention, the halftone dot printed in any one of the two types of halftone areas to express the continuous tone image is any of the above halftone areas. It is characterized in that it is a halftone dot obtained by external blurring processing or external density dispersion processing on the outside of the outline of a predetermined input image corresponding to one type of halftone area.
[0035]
In the printing method of halftone dot printed matter of the present invention, the halftone dot printed in any one of the two types of halftone areas to express the continuous tone image is any of the above halftone areas. This is a halftone dot obtained by internally blurring the inside of the outline of a predetermined input image corresponding to one of the halftone areas and sharpening the interior at the intersection of the lines of the predetermined input image. It is characterized by that.
[0036]
In the printing method of halftone dot printed matter of the present invention, the halftone dot printed in any one of the two types of halftone areas to express the continuous tone image is any of the above halftone areas. A halftone dot obtained by internally blurring the inside of the contour of a predetermined input image corresponding to one of the halftone areas, and by performing external blurring processing or external density dispersion processing on the outside of the contour of the predetermined input image. It is characterized by being.
[0037]
In the printing method of halftone dot printed matter of the present invention, the halftone dot printed in any one of the two types of halftone areas to express the continuous tone image is any of the above halftone areas. The inside of the outline of the predetermined input image corresponding to the halftone area of either type is internally blurred, the internal sharpening process is performed on the intersection of the lines of the predetermined input image, and the outline of the predetermined input image is processed. It is characterized in that it is a halftone dot obtained by external blurring processing or external density dispersion processing on the outside.
[0038]
In the printing method of halftone dot printed matter of the present invention, the halftone dot printed in any one of the two types of halftone areas to express the continuous tone image is any of the above halftone areas. It is obtained by performing external blurring or external density dispersion processing on the outside of the outline of a predetermined input image corresponding to one type of halftone area, and assigning a density zero area of several pixels to the outline area of the predetermined input image. It is characterized by having a halftone dot.
[0039]
In the printing method of halftone dot printed matter of the present invention, the halftone dot printed in any one of the two types of halftone areas to express the continuous tone image is any of the above halftone areas. The inside of the contour of the predetermined input image corresponding to the halftone area of either type is internally blurred, the outside of the predetermined input image is subjected to external blurring or external density dispersion processing, and the contour of the predetermined input image A halftone dot obtained by assigning a zero-density area of several pixels to the area is characterized.
[0040]
In the printing method of halftone dot printed matter of the present invention, the halftone dot printed in any one of the two types of halftone areas to express the continuous tone image is any of the above halftone areas. The inside of the outline of the predetermined input image corresponding to the halftone area of either type is internally blurred, the internal sharpening process is performed on the intersection of the lines of the predetermined input image, and the outside of the predetermined input image Is a halftone dot obtained by external blurring processing or external density dispersion processing and assigning a density zero area of several pixels to the outline area of the predetermined input image.
[0041]
Also, the printing method of a halftone print of the present invention is a halftone region used for expressing the continuous tone image, the halftone region of the other type excluding the one type of halftone region. The halftone dot printed in the area is a halftone dot obtained by internally blurring the inside of the outline of a predetermined input image corresponding to the other type of halftone area.
[0042]
Also, the printing method of a halftone print of the present invention is a halftone region used for expressing the continuous tone image, the halftone region of the other type excluding the one type of halftone region. A halftone dot printed in a region is a halftone dot obtained by external blurring processing or external density dispersion processing on the outside of a predetermined input image corresponding to the other type of halftone region. Yes.
[0043]
Also, the printing method of a halftone print of the present invention is a halftone region used for expressing the continuous tone image, the halftone region of the other type excluding the one type of halftone region. The halftone dot printed in the area internally blurs the inside of the outline of the predetermined input image corresponding to the other type of halftone area, and the internal sharpness blurring process at the intersection of the lines of the predetermined input image It is characterized by being a halftone dot obtained.
[0044]
Also, the printing method of a halftone print of the present invention is a halftone region used for expressing the continuous tone image, the halftone region of the other type excluding the one type of halftone region. A halftone dot printed in the area internally blurs the inside of a predetermined input image corresponding to the other type of halftone area, and externally blurring or external density dispersion outside the outline of the predetermined input image. It is characterized by being halftone dots obtained by processing.
[0045]
Also, the printing method of a halftone print of the present invention is a halftone region used for expressing the continuous tone image, the halftone region of the other type excluding the one type of halftone region. The halftone dot printed in the area internally blurs the inside of the outline of the predetermined input image corresponding to the other type of halftone area, and the internal sharpness blurring process at the intersection of the lines of the predetermined input image The contour outside the predetermined input image is a halftone dot obtained by external blurring processing or external density dispersion processing.
[0046]
Also, the printing method of a halftone print of the present invention is a halftone region used for expressing the continuous tone image, the halftone region of the other type excluding the one type of halftone region. A halftone dot printed in the area performs external blurring processing or external density dispersion processing on the outside of the contour of the predetermined input image corresponding to the other type of halftone region, and several pixels are added to the contour region of the predetermined input image. It is characterized by being halftone dots obtained by assigning a zero density region.
[0047]
Also, the printing method of a halftone print of the present invention is a halftone region used for expressing the continuous tone image, the halftone region of the other type excluding the one type of halftone region. A halftone dot printed in the area internally blurs the inside of the contour of the predetermined input image corresponding to the other type of halftone area, and external blurring processing or external density dispersion processing outside the predetermined input image The halftone dot is obtained by assigning a zero-density area of several pixels to the contour area of the predetermined input image.
[0048]
Also, the printing method of a halftone print of the present invention is a halftone region used for expressing the continuous tone image, the halftone region of the other type excluding the one type of halftone region. The halftone dot printed in the area internally blurs the inside of the outline of the predetermined input image corresponding to the other type of halftone area, and the internal sharpness blurring process at the intersection of the lines of the predetermined input image The halftone dot is obtained by performing external blurring processing or external density dispersion processing on the outside of the predetermined input image, and assigning a density zero area of several pixels to the outline area of the predetermined input image. .
[0049]
Further, in the printing method of halftone dot printed matter of the present invention, the predetermined input image includes a meaningful image including any one of a trademark, a family crest, a logo mark, and a character, and an image including any one of a circle, an ellipse, and a polygon. It is characterized by comprising at least one of the images.
[0050]
DETAILED DESCRIPTION OF THE INVENTION
In the printing industry field, halftone dots are always required to represent halftone, that is, continuous tone images, in addition to black and white binary values on printing paper. This depends on the property that a human recognizes a collection of fine points as one gradation when visually distinguishing shades. Since the technology for halftoning the continuous tone image has been led by major plate makers, it was impossible for the user to create halftone dots freely. However, in the recent plate making and printing industry, the development of Postscript language, one of the computer page description languages, and the spread of commercial application software based on Postscript language have made it relatively difficult to produce color prints that integrate characters and images. It can be created easily, and further, with the spread of Postscript language, users can start creating halftone dots.
[0051]
In the halftone dot creation method based on the Postscript language, a digital film recorder is used. In this digital film recorder, character, image, or illustration data created with application software is created as page description data in Postscript language, and a set of black and white dots is created using a device called RIP (Raster Image Processor) or software RIP. A (bitmap) image is converted into an image and output to a photosensitive material with a high-density laser beam of 2000 to 5000 pixels per inch. As used herein, “pixel” refers to an “image element” in which a minimum portion obtained by finely dividing a continuous tone image is represented by a binary value.
[0052]
According to the halftone dot creation method using the digital film recorder or software RIP, for example, the amplitude modulation method regularly arranges pixels whose size changes in a balanced manner with respect to the tone value of the original. The arrangement of halftone dots created by this amplitude modulation method is determined by how the shape of the pixel increases as the number of lines, halftone angle, halftone shape, or tone value increases.
[0053]
FIG. 2 shows a halftone dot generation pattern of a general commercial print based on the Postscript language. For example, a halftone area representing a screen line of 60 lines / inch on a low-resolution output device of 300 pixels per inch has a regular geometry of 300/60 = 5 pixels, that is, 5 × 5 pixels vertically and horizontally. It is arranged in a geometrical grid, and 5 × 5 + 1 = 26 gradation representation.
[0054]
The halftone dot shape is managed by a mathematical function. In FIG. 3, the central axis of one halftone dot of 5 × 5 pixels in the vertical and horizontal directions is (0, 0), and the address of each grid is expressed by a numerical value from −1 to 1. In response to the values of these coordinates, the mathematical function calculates values from −1 to 1. This value is a priority in which pixels are filled, and each grid in FIG. 3 has, for example, a mathematical function 1- (X ² + Y ² ), If the addresses X and Y of the respective grids are substituted into the mathematical functions X and Y, as shown in FIG. 4, the center 1 is filled first, then 0.75 and then 0.5. ,. . . . . . , -1 and the numerical values are filled in ascending order. In addition, although the same numerical value is arrange | positioned in several places as numerical values other than center 1, the order between these numerical values is dependent on the computer incorporated in the machine. If a mathematical function is used, it is possible to create a more complicated halftone dot shape, which is effective as a gradation reproduction method for preventing forgery. However, this method requires mastery of mathematical functions and postscript languages. For example, trademarks, family crests, symbol marks, characters, etc., can be used to create arbitrary shapes with design that are meaningful by themselves. There was a limit to the creation.
[0055]
Japanese Patent Laid-Open No. 11-268228, for example, copies a continuous tone image made up of halftone dots obtained by image processing of any of the images shown in FIG. It is intended to provide a function of creating a printed matter that is difficult to duplicate by a machine, preventing counterfeiting, and determining whether a given halftone dot is true or false by machine reading. According to this method, the gradation of the continuous tone image is directly applied to each grid (grid) by computer image processing without using the mathematical function, thereby providing a degree of freedom to the halftone dot generation pattern. Can do.
[0056]
FIG. 5 is a diagram for explaining the halftone dot creation method, taking as an example a case where one pixel of an arbitrary continuous tone image has 14 gradations out of 26 gradations. In order to obtain a halftone dot generation pattern similar to that shown in FIG. 4 using a method that does not use a mathematical function, as shown in FIG. Assign a number to the pixel. In order to express 14 gradations among the 26 gradations in FIG. 5 with halftone dots by directly applying 26 gradations to each grid, the center 1 is first filled as shown in FIG. Next, 2, 3,. . . . . . , 12, the pixels are filled in order from the highest numerical value of the pixels, and the pixels are filled in order until reaching the value 13 smaller than 14 gradations. As described above, the number of gradations of the continuous tone image is directly applied to the individual grid of 5 × 5 pixels in the vertical and horizontal directions, and the numerical value of the pixel is high up to the number of gradations on each pixel of the continuous tone image. Create halftone dots by filling the pixels in order. Here, FIG. 7 explains that free halftone dot creation is possible. As shown in FIG. 6 described above, when the halftone dot generation pattern in which pixels are painted outward from the center is changed to have six gradations of brightness, for example, the halftone dot of the face showing both eyes and mouth Appears.
[0057]
By applying the above principle, in Japanese Patent Laid-Open No. 11-268228, the image line width of an arbitrary shape is modulated by blurring the image as shown in FIG. In FIG. 8, the number of gradations is given to each grid of 5 × 5 pixels in the vertical and horizontal directions when a part of the cross section subjected to the blurring process is enlarged. In this case, the image line gradually increases from the center of the line toward the outside. Further, by blurring the intersecting area inside the halftone image into an acute angle as shown by the broken line in FIG. 9, the image of the intersection area of the image line that is likely to occur during printing as shown by Z1 in FIG. Prevents line collapse and improves readability and dot quality. Outside the halftone image, the gradation reproducibility from the middle of the continuous gradation to the dark part is improved by performing the density dispersion process as shown by Z2 in FIG. 10 instead of the blurring process from the center of the grid to the peripheral direction. . Further, as shown by Z3 in FIG. 10, the halftone dot contour region is assigned a zero density (FF) region of several pixels, and a gap that is not filled inside and outside is given, so that a bright portion of the continuous tone image Halftone dots can be recognized in the entire area from dark to dark, improving the halftone dot readability and enabling halftone dot machine reading. FIG. 11 shows a printed matter p obtained by using the technique disclosed in Japanese Patent Application Laid-Open No. 11-268228. Characters can be observed even in the dark area while the thickness of the stroke of the Japanese document “徐 々 に” gradually increases. As described above, according to the technique disclosed in Japanese Patent Laid-Open No. 11-268228, a designer can use a commonly used personal computer and image processing software without using a special system in response to a customer order. Halftone dots can be designed freely, and halftone dots obtained by image processing a predetermined input image using the technique disclosed in Japanese Patent Application Laid-Open No. 11-268228 can be copied with a copying machine or the like. Since it is difficult to read and machine-readable, it functions effectively when a continuous tone image of an anti-counterfeit printed matter is expressed.
[0058]
However, this method is intended to express one continuous tone image using one type of halftone region. When printing halftone dots for expressing a continuous tone image, Two kinds of halftone areas that do not overlap each other are provided as a halftone area for printing without any gap, and a predetermined area is obtained by printing halftone dots in both kinds of halftone areas of the two kinds of halftone areas. It was not possible to print one continuous tone image or two continuous tone images. Here, when a plurality of halftone dots are assigned to one halftone area, the halftone dot diameter itself becomes large and it is difficult to increase the number of lines (image density). In the printed material p ′ in FIG. 12, gradation is expressed while the thickness of the image line of the Japanese document “printing station” gradually increases. Further, in the printed matter p ″ in FIG. 13, the gradation is expressed while the thickness of the stroke of the Japanese document “copy prohibited” is gradually increased, but in both cases shown in FIG. 12 and FIG. The diameter itself increases, making it difficult to increase the number of lines (image density). In addition, when two continuous tone images are printed using one type of halftone area, if two continuous tone images are formed into latent images using functional ink, each continuous tone image is printed. As a result, the halftone dots constituting the image are merged to form a secondary pattern, resulting in a noise effect that hinders the latent image effect. For example, using one type of halftone area, a continuous tone image in which two continuous tone images, FIGS. 14A and 14B, are printed by a halftone dot dot, and both are combined. 14 (c) and FIG. 14 (c) in which the gradation of FIG. 14 (c) is reversed are printed in a predetermined area, FIG. 14 (e) is obtained. In FIG. It can be seen that secondary patterns are formed by fusing each other, and the latent image effect is significantly inhibited.
[0059]
Therefore, in the present invention, for example, when printing halftone dots obtained by performing image processing on any of the images shown in FIG. 1, m × m pixels (m ≧ 2, m is an integer.) And two types of halftone areas of n × n pixels (1 ≦ n <m, n is an integer) are provided. Are arranged so as not to overlap each other, and the four m × m pixel halftone regions in the mutually independent regions surround the one n × n pixel halftone region without any gap, and are independent from each other. The two types of halftone areas are configured so that the four halftone areas of n × n pixels in FIG. 4 are arranged at equal intervals along the outer periphery of the halftone area of one m × m pixel. In addition, halftone areas for expressing one continuous tone image using both types of halftone areas of the two types of halftone areas are printed, so that one continuous tone image is displayed in a predetermined area. Printing or assigning each type of halftone area of the two types of halftone areas to one corresponding continuous tone image, and corresponding continuous gradation for each type of halftone area A halftone dot for expressing an image is printed and two continuous tone images are printed in a predetermined area. At this time, for example, a halftone dot obtained by performing image processing on any of the images shown in FIG. 1 using the technique disclosed in Japanese Patent Laid-Open No. 11-268228 is difficult to reproduce with a copying machine or the like. It is possible to prevent counterfeiting and determine the authenticity of printed matter by mechanically reading halftone dots obtained by image processing of any of the images shown in FIG. 1 using the technique disclosed in Japanese Patent Laid-Open No. 11-268228. Is possible.
[0060]
Also, in the present invention, in a predetermined area composed of the two types of halftone areas, one continuous tone image is expressed using both types of halftone areas of the two types of halftone areas. When printing halftone dots, the one continuous tone image using either one of two types of inks that appear to be the same color with the naked eye under normal light but have different optical characteristics. Printing a halftone dot for expressing the one continuous tone image using the other ink of the two types of inks, and printing the area excluding the halftone dot for expressing the one continuous tone image. The one continuous tone image can be provided as a latent image, and the predetermined area is made to be color-matched with the naked eye under normal light without forming a secondary pattern by fusion of halftone dots. Solid printing It can be.
[0061]
Furthermore, in the present invention, in a predetermined area composed of the two types of halftone areas, one continuous tone image is represented for each type of halftone area of the two types of halftone areas. By printing halftone dots, when printing two continuous-tone images in the predetermined area, two types of ink that have different optical characteristics that appear to be the same color with the naked eye under normal light but different from each other A halftone dot for expressing one continuous tone image of the two continuous tone images is printed using any one of the two inks, and the second ink is used using the other of the two types of inks. A halftone dot is printed to represent the other continuous tone image of the two continuous tone images, and the optical characteristics are different from any of the two types of inks. Same color as ink When the area excluding the halftone dots for expressing the two continuous tone images is printed using the above-mentioned ink, the two continuous tone images can be provided as latent images in the predetermined area. The area can be solid-printed so as to be the same color with the naked eye under normal light without forming a secondary pattern by fusion of halftone dots. At this time, the four m × m pixel halftone regions in the mutually independent regions surround the one n × n pixel halftone region without gaps, and the four in the independent regions The two types of halftone areas are configured such that the n × n pixel halftone areas are arranged at equal intervals along the outer periphery of one m × m pixel halftone area. The two continuous tone images can be arranged and printed in the same area without overlapping each other.
[0062]
Printing method of halftone dot printed matter according to the present invention, that is, two halftone areas that do not overlap each other as halftone areas for printing halftone dots are provided without gaps, and then the two types of halftone areas FIG. 15 shows a halftone print product printing method for printing halftone dots for expressing one continuous tone image using both types of halftone areas and printing one continuous tone image in a predetermined area. (1) A first threshold data generation unit is provided in two types of halftone areas, and (2) a second threshold having a pixel density lower than that of the first threshold data in the two types of halftone areas. A data creation unit is provided, and (3) a post-script that can be decoded by an output device or software RIP for image data obtained in association with one continuous tone image. A command conversion unit for converting into halftone dot generation method HalftoneType16, and (4) a unit for storing halftone dot data corresponding to one continuous tone image. A raster processor for giving instructions to the point generator or software RIP is provided, and (6) a black and white binary halftone image of TIFF is generated.
[0063]
Furthermore, the method for printing halftone prints according to the present invention, that is, two halftone areas that do not overlap each other as halftone areas for printing halftone dots are provided without gaps, and the two types of halftone areas are formed. Assign halftone areas of each type of tone area to one corresponding continuous tone image, and print halftone dots to express the corresponding continuous tone image for each type of halftone area. A halftone print product printing method for printing two continuous tone images in a predetermined area will be described with reference to FIG. 16. (1) The first half-tone area is composed of circular dots. (2) a second threshold composed of circular dots having a lower pixel density than the first threshold data in two types of halftone areas; A threshold data creation unit is provided, and (3) image data obtained by the first threshold data creation unit by arranging circular dots and circular dots having a low pixel density are obtained by the second threshold data creation unit. A command conversion unit for converting each image data of the image data into a command conforming to HalftoneType16 of Postscript halftone generation method is provided, and (4) corresponds to both the first threshold data generation unit and the second threshold data generation unit. A section for storing halftone data is provided, (5) a raster processing section for giving instructions for generating halftone dots, and (6) a black and white binary halftone image 1 of TIFF is generated. Next, (1 ′) a first threshold data creating unit is formed which is composed of inverted circular dots obtained by inverting black and white in two types of halftone areas, and (2 ′) from the first threshold data in two types of halftone areas. A second threshold data creation unit composed of circular dots having a low pixel density is provided, and (3 ′) image data obtained by the first threshold data creation unit and circular dots are arranged by arranging inverted circular dots. A command conversion unit for converting each image data of the image data obtained by the second threshold data generation unit into a command according to HalftoneType16 of the Postscript halftone generation method, and (4 ') the first threshold data generation unit And a second threshold data creation unit for storing halftone dot data corresponding to both (5 ' Raster processor providing instructions to the halftone dot generator provided, (6 ') halftone image 2 black and white binary TIFF is generated. And (7) an image calculation processing unit for the generated TIFF monochrome binary halftone images 1 and 2; (8) a generation unit for the mask 1 in which m × m pixels are painted black; and (9) An inversion portion of the mask 1 is provided, and (10) a generation portion of the mask 2 in which n × n pixels are painted black is provided. The halftone area is divided into a halftone area of m × m pixels and a halftone area of n × n pixels by using the mask 1 and the mask 2 thus obtained, and one continuous tone image is provided for each type of halftone area. Can be assigned.
[0064]
Here, a mask generation method necessary for assigning one continuous tone image to each of the two types of halftone areas will be described in detail in correspondence with the reference numerals in FIG. To do. In the following, a mask generation method when 58% gray level is assigned to FIG. 17 (a ′) and 50% gray level is assigned to FIG. 17 (b ′) will be described. In the m × m pixel halftone region in FIG. 17B ″, inverted circular dots obtained by inverting the black and white of the circular dots in the m × m pixel halftone region in FIG. 17A ″ are used. FIG. 17A shows a circular dot in the m × m pixel halftone region shown in FIG. 16A, and the bitmap data thereof is the first threshold data. On the other hand, FIG. 17B shows a circular dot in an n × n pixel halftone region having a smaller number of vertical and horizontal pixels than that in FIG. 17A, and the bitmap data thereof becomes the second threshold data. The first threshold data and the second threshold data are converted into commands according to Halftone Type 16 of the Postscript halftone generation method in FIG. 16 (3) and stored as halftone data in FIG. 16 (4). For the halftone dot data, a postscript halftone generation method HalftoneType16 instruction is given to the halftone dot generator or software RIP for raster processing, and the TIFF monochrome binary half shown in FIG. A tone image 1 is obtained, and the same processing is performed from (1 ') to (6') in Fig. 16 to obtain a TIFF monochrome binary halftone image 2 shown in Fig. 17 (b ").
[0065]
Next, in FIG. 16 (7), the image calculation processing of the TIFF monochrome binary halftone image 1 (FIG. 17 (a ″)) and the TIFF monochrome binary halftone image 2 (FIG. 17 (b ″)). FIG. 17C is generated by performing. At this time, the relationship of m> n always holds between the halftone area of m × m pixels that is entirely painted black and the halftone area of n × n pixels in which circular dots are painted black on a white background. The four corners of the m × m pixel halftone area filled in black are continuous with a slight bit shift. The commercially available image processing software has a function of selecting a part of an image using an approximate color of adjacent pixels, so that all half-tone regions of all m × m pixels continuous with each other painted in black can be obtained. If selected in a lump, the mask 1 shown in FIG. 17 (d) can be generated. Further, by reversing the black and white of the mask 1 shown in FIG. 17D, it is possible to generate the mask 2 in which the halftone regions of all n × n pixels are painted black.
[0066]
【Example】
Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the embodiment of the present invention is not limited to the following embodiments, and within the scope of the technical matters described in the claims. If necessary, the embodiment of the invention can be modified as appropriate.
[0067]
(Embodiment 1) As Embodiment 1, in FIG. 18, when printing halftone dots in each of the two types of halftone areas, as shown in FIG. In the halftone area, the input image is “5” in the Japanese document “50,000” Fill the pixel of the position that becomes the shape of “5” within m × m pixel, In the halftone area of n × n pixels that forms a halftone dot (FIG. 18A), “10,000” in “50,000” is used as an input image. Fill the pixel of the position of “ten thousand” shape in n × n pixels, (FIG. 18B) was formed, and the continuous tone (FIG. 18C) was expressed by modulating the image line thickness for each type of halftone region. The quality of this printed matter has a resolution of 80 to 175 lines / inch, which is the same level as a general printed matter, and can express continuous tone even in a narrow area. Further, these halftone dots (FIGS. 18A and 18B) are excellent in readability in the entire region from the bright part to the dark part of the continuous tone, and the halftone dots can be mechanically read. there were. Furthermore, if these halftone dots (FIGS. 18A and 18B) are duplicated by a copying machine, the readability of the halftone dots is significantly impaired, and a forgery prevention function can be imparted to the printed matter. It was. At this time, a continuous tone is obtained by image processing a predetermined input image. To express , "5" that is the input image in a halftone area of m × m pixels, As shown in FIG. 8, the image line width of an arbitrary shape is modulated by performing the blurring process. In this case, the image line gradually increases from the center of the line toward the outside. Further, as shown by a broken line in FIG. 9, the area intersecting inside the halftone image is subjected to blurring processing at an acute angle, thereby preventing the collapse of the image line in the intersection area of the image line that is likely to occur during printing. Improve point quality. Outside the halftone image, gradation reproducibility from the middle of the continuous gradation to the dark portion is improved by performing density dispersion processing instead of blurring processing from the center of the grid to the peripheral direction. Furthermore, the halftone dot outline area can be recognized in all areas from the bright part to the dark part of the continuous tone image by assigning a zero-density (FF) area of several pixels and providing a gap that is not filled inside and outside. . these The input image “10,000” with halftone area of n × n pixels and halftone area that has been image processed using any of the technologies As shown in FIG. 8, the image line width of an arbitrary shape is modulated by performing the blurring process. In this case, the image line gradually increases from the center of the line toward the outside. Further, as shown by a broken line in FIG. 9, the area intersecting inside the halftone image is subjected to blurring processing at an acute angle, thereby preventing the collapse of the image line in the intersection area of the image line that is likely to occur during printing. Improve point quality. Outside the halftone image, gradation reproducibility from the middle of the continuous gradation to the dark portion is improved by performing density dispersion processing instead of blurring processing from the center of the grid to the peripheral direction. Furthermore, the halftone dot outline area can be recognized in all areas from the bright part to the dark part of the continuous tone image by assigning a zero-density (FF) area of several pixels and providing a gap that is not filled inside and outside. . these Halftone dots obtained by image processing using any one of the technologies are halftone dots that can be read mechanically in a region from a bright part to a dark part of a continuous tone, and cannot be reproduced by a photolithography machine. Since it is a halftone dot, a method of generating a halftone dot by image processing of an input image of “five” in an m × m pixel halftone region and an input image of “ten thousand” in an n × n pixel halftone region The method of generating halftone dots by processing is as follows: Mentioned above Any one of the halftone dot generation methods, whether they are the same method or different methods, makes it possible to machine-read halftone dots while expressing continuous tone, and to forge printed matter. I was able to prevent it. Further, in the first embodiment, halftone dots are formed using “5” as an input image in a halftone area of m × m pixels, and halftone dots are formed using “10,000” as an input image in a halftone area of n × n pixels. However, the input image to each type of halftone area is not limited to “five” and “ten thousand”, and each type of halftone area is input to each type of halftone area. As a predetermined input image constituted by at least one of a meaningful image including any of a trademark, a family crest, a logo mark, and a character and an image including any of a circle, an ellipse, and a polygon, In addition to representing continuous tone, it was possible to read halftone dots and prevent counterfeiting of printed matter.
[0068]
(Example 2)
As Example 2, in FIG. 19, a general circular dot is adopted for two types of halftone areas, that is, a halftone area of m × m pixels and a halftone area of n × n pixels. An example in which the two continuous tone images shown in FIG. 19B are formed into a latent image without generating a secondary pattern due to the fusion of halftone dots will be described.
[0069]
FIG. 19 (a ′) shows a halftone process of the continuous tone image shown in FIG. 19 (a) by a method according to HalftoneType16 of the Postscript halftone generation method. FIG. 19 (b ′) The continuous tone image shown in FIG. 19B is halftone processed by a method according to HalftoneType16 of the Postscript halftone generation method. A mask having a pixel density equivalent to that in FIG. 19 (a ′) is created by a method according to FIG. 16, and a mask having a pixel density equivalent to that in FIG. 19 (b ′) is created by a method according to FIG. FIG. 19 (m1) shows a partially enlarged view of a mask having a pixel density equivalent to that of FIG. 19 (a ′), and FIG. 19 (m2) shows a partially enlarged view of a mask having a pixel density equivalent to that of FIG. 19 (b ′). Show. In FIG. 20, when the image calculation processing of FIG. 20 (a ″) showing a halftone image halftoned by a method according to HalftoneType16 of the Postscript halftone generation method and the image calculation processing of FIG. 20 (m1) showing a mask are performed. FIG. 20 (d), which is a dot image, is generated, and FIG. 20 (b ″) showing a halftone image halftoned by a method according to HalftoneType16 of the Postscript halftone generation method and FIG. 20 (m2) showing a mask 20 (d ′), which is a halftone image, is generated. FIG. 20D, which is a halftone image, and FIG. 20D, which is a halftone image, are arranged equally in a predetermined area without overlapping each other, and without causing fusion of halftone dots. It is printed. At this time, the halftone image of FIG. 20 (a ′) shows the same halftone image as that of FIG. 19 (a ′), and the halftone image of FIG. 20 (b ′) is the same as that of FIG. The same halftone dot image as that in FIG.
[0070]
In this way, it is possible to print the two types of halftone dot images of FIG. 20D and FIG. 20D ′, which are halftone images that do not overlap with each other, but FIG. 20D and FIG. It is necessary to fill the region excluding the two types of halftone dot images with ink that looks the same color as the two types of halftone dot images of FIGS. 20D and 20D ′ with the naked eye under normal light. As shown in FIG. 21, the image calculation processing of FIG. 21 (d) and FIG. 21 (d ′), which are halftone images, is performed to generate FIG. 21 (e), and the gradation of FIG. By inversion, FIG. 21 (g) is generated. At this time, the halftone image of FIG. 21 (d) shows the same halftone image as that of FIG. 20 (d), and the halftone image of FIG. 21 (d ′) is the same as that of FIG. 20 (d ′). The same halftone dot image as the halftone dot image is shown. FIGS. 22A, 22B, and 22C show printing plates produced by the above method. Here, the printing plate of FIG. 22 (a) is a printing plate for printing the halftone image of FIG. 20 (d), and the printing plate of FIG. 22 (b) is the halftone image of FIG. 20 (d '). 22 (c) is a printing plate for printing the area excluding the halftone image of FIG. 20 (d) and the halftone image of FIG. 20 (d ′). is there. When each of these three printing plates is used for offset printing so that they appear to be the same color with the naked eye under normal light, as shown in FIG. As a whole, the same color solid printing without the subsequent pattern was obtained. At this time, the four m × m pixel halftone regions in the mutually independent regions surround the one n × n pixel halftone region without gaps, and the four in the independent regions Since the two types of halftone areas are configured so that the n × n pixel halftone areas are arranged at equal intervals along the outer periphery of one m × m pixel halftone area, they overlap each other. The two types of halftone dot images of FIG. 20 (d) and FIG. 20 (d ′), which are not halftone images, can be printed with the same arrangement in a predetermined area.
[0071]
(Example 3)
As Example 3, in a predetermined area composed of two types of halftone areas, an m × m pixel halftone area and an n × n pixel halftone area, the color appears to be the same color with the naked eye under normal light. Print halftone dots for expressing one continuous tone image of two continuous tone images using any one of two types of inks having different optical characteristics. A halftone dot for printing the other continuous tone image of the two continuous tone images is printed using the other ink of the two types of ink, and the optical characteristics are different from any of the two types of ink. Prints the area excluding the halftone dots for expressing the two continuous tone images using the ink that appears to be the same color as the two types of ink under normal light, and has a predetermined viewing condition. And the two consecutive One of the gradation images can be visually recognized, and the other continuous gradation image of the two continuous gradation images can be visually recognized under a predetermined viewing condition different from the predetermined viewing condition. In addition, an example will be described in which the predetermined region is printed so as to appear to be the same color as a whole with the naked eye under normal light. In FIG. 23, general circular dots are adopted for two types of halftone areas, that is, an m × m pixel halftone area and an n × n pixel halftone area, and FIGS. The two continuous tone images shown in FIG. 2) are formed into latent images using functional ink or the like without generating a secondary pattern due to the fusion of halftone dots. Hereinafter, the blending ratio of the ink used in Example 3 is shown, but the ink that can be used in the present invention is not limited to the ink having the following blending ratio.
[0072]
First, it is produced using about 3% of orange pigment sren orange GR, about 7% of azo yellow FG of yellow pigment, and about 90% of offset varnish as a visible excitation visible light emitter ink excited at 546 nm and emitting at 620 nm. did. FIG. 24 is a diagram showing a fluorescence spectrum of the visible excitation visible light emitter ink. Next, as an ultraviolet-excited visible luminescent ink that excites at 360 nm and emits light at 570 nm, the orange pigment Pigment Orange is approximately 2%, the yellow pigment Pigment Yellow G is approximately 6%, the UV-excited offset ink is approximately 15%, and the offset varnish. Approximately 77% was used for production. FIG. 25 is a diagram showing a fluorescence spectrum of ultraviolet-excited visible luminescent ink. Furthermore, as a normal ink having no light emitting characteristics, an orange pigment Pigment Orange of about 3%, a yellow pigment of Pigment Yellow G of about 7%, and an offset varnish of about 90% were prepared. FIG. 26 is a diagram showing a fluorescence spectrum of a normal ink having no light emission characteristics. The three types of inks were in the same color relationship with each other under a white fluorescent lamp. Here, the visible excitation visible light emitter ink is printed using the printing plate of FIG. 22B, the ultraviolet excitation visible light emitter ink is printed using the printing plate of FIG. 22A, and FIG. A normal ink having no light emission characteristics was printed using the above printing plate, and offset printing was carried out on a paper that had been creased so that the three types of ink did not overlap each other. A pattern printed with three types of ink is shown in the center (elliptical portion) of FIG. In the central part of FIG. 23A, no image can be recognized in the reflected light state of the visible light region, but the watermark image (FIG. 23B) in the transmitted light state of the visible light region, and UV-excited visible light emission under ultraviolet light. The reflected light image of FIG. 23C was recognized by the body ink, and the visible light image of FIG. 23D was recognized by the visible excitation visible light ink under the visible light of 620 nm. At this time, if the visible excitation visible light ink is an infrared excitation visible light ink, no image can be recognized in the reflected light state of the visible light region in the central part of FIG. It was possible to recognize the watermark image of FIG. 23B in the light state, the reflected light image of FIG. 23C under the ultraviolet light, and the reflected light image of FIG. 23D under the infrared light. If this method is used on the front and back of the printed matter, a total of five types of continuous tone images can be printed as latent images.
[0073]
In addition, as the functional ink, a fluorescent light emitting material having a characteristic of emitting light having a wavelength in the visible region, ultraviolet region, or infrared region can be used, but it emits light having a wavelength in the visible region. Examples of fluorescent light-emitting materials include zinc sulfide-based compounds, zinc oxide-based compounds, zinc silicate-based compounds, and yttrium-based compounds. Examples of fluorescent light-emitting materials that emit light having a wavelength in the ultraviolet region include, for example, BaSi. ₂ O _Five : Pb, SrB _Four O ₇ F: Eu, Ca _Three (PO _Four ): There are Ti and the like, and fluorescent light emitting materials that emit light having a wavelength in the infrared region include, for example, LiAlO ₂ : Fe, (Zn ・ Cd) S: Cu, YVO _Four : Nd etc. Furthermore, as functional inks, ultraviolet absorbing materials, for example, inorganic materials such as titanium dioxide, zinc sulfide, zinc silicate, organic materials such as oxazine thiazole, diaminodiphenyl, and indium compounds that are infrared absorbing materials. Anthraquinone compounds or the like may be used, or phosphorescent materials or thermochromic materials may be used. In the present invention, regardless of which type of functional ink is used, the latent image is visually recognized under a predetermined viewing condition corresponding to the optical characteristics of the functional ink used for printing the latent image. I was able to. Also, when printing two latent images in a predetermined area, one of two types of functional inks that appear to be the same color with the naked eye under normal light but have different optical properties from each other. One of the two latent images is printed using the functional ink, and the other latent image of the two latent images is printed using the other type of functional ink of the two types of functional ink. By doing so, one of the two latent images can be visually recognized under a predetermined viewing condition corresponding to one of the two types of functional ink, and two types of functions can be used. The other latent image of the two latent images could be visually recognized under a predetermined viewing condition corresponding to the other type of functional ink.
[0074]
(Example 4)
As Example 4, in FIG. 27 (a), after adopting a general circular dot for two types of halftone areas, an m × m pixel halftone area and an n × n pixel halftone area, An example will be described in which two face images are provided as latent images so that the halftone dots are not fused using functional ink on the right part of the face photograph of the identification card. In the right part of the face photo of the identification card in FIG. 27 (a), no image can be recognized in the reflected light state in the visible light region, but the reflection of the face photo turned upside down as shown in FIG. 27 (b) under ultraviolet light. Under the light image and infrared, a reflected light image equivalent to a face photograph could be recognized as shown in FIG.
[0075]
【The invention's effect】
According to the present invention, forgery and alteration of printed matter can be prevented by printing a continuous tone image using halftone dots that are difficult to reproduce with a general plate-making device and can be machine-readable. Can be planned. In addition, according to the present invention, one continuous tone image can be printed in a predetermined region, and two continuous tone images can be printed in a predetermined region without overlapping each other. Continuous tone images can be arranged and printed equally without causing dot fusion. At this time, a continuous tone image is printed in a predetermined area using a functional ink so as to become a latent image, and the continuous ink is printed using a normal ink that appears to be the same color as the functional ink with the naked eye under normal light. If the area excluding the tone image is printed, the predetermined area on which the latent image is printed can be solid-printed so as to have the same color as a whole.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining that a dot, a family crest, a logo mark, a character, or the like having its own meaning can be freely adopted as a halftone dot shape used in the present invention.
FIG. 2 is a diagram for explaining an example of a halftone dot generation pattern of a general commercial print.
FIG. 3 is a diagram for explaining vertical and horizontal address values of a grid managed by a mathematical function in a postscript language halftone screen;
FIG. 4 is a diagram for illustrating an example of a mathematical function and explaining a state in which priorities for filling are assigned.
FIG. 5 is a continuous tone image used for explaining the halftone print and the printing method of the present invention.
FIG. 6 is a diagram illustrating a method in which a mathematical function is not used in a halftone creation method of a Postscript language, and illustrates a state in which priorities for filling are assigned by the number of gradations.
FIG. 7 is a diagram for explaining how to apply design to a generated pattern by applying a method that does not use a mathematical function in a halftone creation method of a Postscript language.
FIG. 8 is a diagram for explaining blurring processing in the halftone creation method of the present invention;
FIG. 9 is a diagram for explaining a state of sharpening blurring at a portion where image lines form intersections;
FIG. 10 is a diagram (Z1) illustrating a sharp blurring state with respect to a region where the image lines form an intersection with the Japanese document “以外” as an example; A diagram explaining the distribution of density (Z2) and a diagram explaining a technique for assigning an area without density of several pixels to the character outline portion and enabling character recognition even in a dark gradation area. (Z3).
FIG. 11 is a printed matter expressing gradation using the technique disclosed in Japanese Patent Laid-Open No. 11-268228.
FIG. 12 is a diagram illustrating a printed matter in which the Japanese document “printing station” is halftone, and the halftone dot diameter itself increases, making it difficult to increase the number of lines (image density).
FIG. 13 is a diagram illustrating a printed matter in which a Japanese document “copy prohibited” is halftone, and the halftone dot diameter itself increases, making it difficult to increase the number of lines (image density).
FIG. 14 shows a case where a plurality of continuous tone images are formed into a latent image using functional ink or the like, and halftone dots are fused to form a secondary pattern, which inhibits the latent image effect and has a noise effect. The figure explaining how it exerts.
FIG. 15 is a diagram illustrating a halftone dot generation method according to the present invention in the case where one continuous tone image is expressed using both types of halftone regions of two types of halftone regions.
FIG. 16 shows a halftone dot generation method and mask generation according to the present invention when two continuous tone images are expressed by assigning one continuous tone image to each of the two types of halftone regions. The figure explaining the law.
FIG. 17 is a diagram illustrating a method for creating a mask necessary for assigning two types of halftone areas.
FIG. 18 shows halftone dots of Japanese document “50,000” in a halftone area of m × m pixels in Example 1, and Japanese document “5” in a halftone area of n × n pixels. The figure explaining expressing a continuous tone by making halftone dots of “ten thousand”.
FIG. 19 is a diagram illustrating the correspondence between two types of halftone images formed by a method according to HalftoneType16 of the Postscript halftone generation method and a mask in Example 2.
FIG. 20 shows that when two types of halftone images formed by a method according to HalftoneType16 of the Postscript halftone generation method and the mask are subjected to image processing in Example 2, the two types of halftone images overlap each other. The figure explaining having been produced without.
FIG. 21 is a diagram illustrating a method for creating an area excluding two types of halftone images that do not overlap each other in the second embodiment.
FIG. 22 shows solid printing that does not overlap with each other when offset printing is performed on each type of ink of three types of color matching inks using the corresponding printing plates according to the present invention. The figure explaining that it is possible.
FIG. 23 shows that in Example 3, a general circular dot is used for two types of halftone areas, and two continuous tone images are formed using functional ink without merging halftone dots. The figure explaining the example made into a latent image.
FIG. 24 is a diagram for explaining the fluorescence spectrum of the visible excitation visible light emitter ink used in Example 3.
FIG. 25 is a diagram for explaining the fluorescence spectrum of the ultraviolet-excited visible luminescent ink used in Example 3.
FIG. 26 is a diagram illustrating a fluorescence spectrum of normal ink having no light emission characteristics used in Example 3.
27 is a diagram for explaining an example in which the present invention is applied to an identification card in Embodiment 4. FIG.
[Explanation of symbols]
Z1 Intersection area of character parts that prevents uneven density distribution (crushing of image lines) by blurring sharply
Z2 An area where the gradation from the middle to the bright part is smoothly reproduced by dispersing the density outside the character area.
Z3 Character contour assigned a zero density (FF) area of several pixels
p Extracts the contour of a given input image, blurs the inside of the contour, sharpens the inner sharpness at the intersection area of the image, disperses the external density outside the contour, and has a density of several pixels in the contour area (FF) Printed material consisting of components (halftone dots) output by assigning areas
p ′ Printed matter composed of components (halftone dots) that are subjected to internal blurring processing within a predetermined input image, subjected to internal sharpening processing at the intersection of image lines, and subjected to external density dispersion processing outside the input image.
p ″ Printed matter composed of components (halftone dots) that are subjected to internal blurring processing inside a predetermined input image, subjected to internal sharpening processing at the intersection area of the image lines, and external density dispersion processing performed on the outside of the input image.
1 First threshold data generator for two types of halftone areas
2 Second threshold data creation unit having a pixel density smaller than that of the first threshold data
3 A unit that converts the obtained image data into a command that conforms to Halftone Type 16 of the Postscript halftone generation method that can be decoded by the output device or software RIP
4 Section to save the obtained halftone data
5 Raster processor that gives instructions to halftone dot generator and software RIP
6 TIFF monochrome binary dot image generation unit
First threshold data creation unit composed of inverted circular dots in 1'2 types of halftone areas
2 'second threshold data creation unit composed of circular dots having a lower pixel density than the first threshold data
3 'A part that converts the obtained image data into a command conforming to HalftoneType16 of Postscript halftone generation method that can be decoded by output device and software RIP
4 'Saves the obtained dot data
Raster processor that gives instructions to 5 'halftone dot generator and software RIP
6'TIFF black and white binary dot image generator
7 Image calculation processing unit for the generated TIFF monochrome binary dot image
8 m × m pixel halftone area with black mask generator
9 Mask reversal part
10 n × n pixel halftone area with black mask generator

Claims (6)

When printing halftone dots to represent continuous tone images,
A halftone area of m × m pixels (m ≧ 2, m is an integer) and an n × n pixel (1 ≦ n <m, n is an integer) halftone as a halftone area for printing the halftone dots. A predetermined area is formed by two types of halftone areas.
The two types of halftone areas are arranged so as not to overlap each other, and the four m × m pixel halftone areas that are independent of each other have no gap around the one n × n pixel halftone area. Go,
The two types of halftone areas are arranged such that four n × n pixel halftone areas in mutually independent areas are arranged at equal intervals along the outer periphery of one m × m pixel halftone area. Once configured,
Printing halftone dots for expressing one continuous tone image for each type of halftone area of the two types of halftone areas in a predetermined area composed of the two types of halftone areas. 2. A halftone printed matter, wherein two continuous tone images are printed in the predetermined area. Printing halftone dots for expressing one continuous tone image for each type of halftone area of the two types of halftone areas in a predetermined area composed of the two types of halftone areas. Then, when two continuous tone images are printed in the predetermined area,
Continuous tone image of either one of the two continuous tone images using one of two types of inks that appear to be of the same color with the naked eye under normal light but have different optical properties Printing a halftone dot for expressing the other continuous tone image of the two continuous tone images using the other ink of the two types of inks, and A halftone dot for expressing the two continuous tone images using an ink that has different optical characteristics from any of the two types of ink but appears to be the same color as the two types of ink with the naked eye under normal light Print the area except
One continuous tone image of the two continuous tone images can be visually recognized under a predetermined viewing condition, and the two continuous tone images under a predetermined viewing condition different from the predetermined viewing condition While making the other continuous tone image of the image visible,
The halftone dot printed matter according to claim 1, wherein the halftone dot printed matter is printed so that the predetermined region looks as a uniform color as a whole with the naked eye under normal light.   The halftone dots for expressing the continuous tone image are at least one of a meaningful image including any of a trademark, a family crest, a logo mark, and a character, and an image including any of a circle, an ellipse, and a polygon. The halftone dot printed matter according to claim 1 or 2, characterized by comprising: When printing halftone dots to represent continuous tone images,
A halftone area of m × m pixels (m ≧ 2, m is an integer) and an n × n pixel (1 ≦ n <m, n is an integer) halftone as a halftone area for printing the halftone dots. A predetermined area is formed by two types of halftone areas.
The two types of halftone areas are arranged so as not to overlap each other, and the four m × m pixel halftone areas that are independent of each other have no gap around the one n × n pixel halftone area. The two types of half-tone regions are arranged so as to be arranged at equal intervals along the outer periphery of the one half-tone region of the m × m pixels. After configuring the tone area,
Printing halftone dots for expressing one continuous tone image for each type of halftone area of the two types of halftone areas in a predetermined area composed of the two types of halftone areas. A printing method for halftone prints in which two continuous tone images are printed in the predetermined area,
In the two types of halftone areas, circular dots corresponding to the halftone areas of the m × m pixels are arranged in all the halftone areas of the m × m pixels, and the halftone areas of the n × n pixels A black-and-white binary halftone image in which circular dots corresponding to are arranged in all the n × n pixel halftone regions;
Inverted circular dots obtained by inverting the black and white of the circular dots corresponding to the m × m pixel halftone region are arranged in all the m × m pixel halftone regions, and in the n × n pixel halftone region. By selecting only a continuous black region from images obtained by performing image calculation processing on a black and white binary halftone image in which the corresponding circular dots are arranged in all the n × n pixel halftone regions. Making a mask that matches the half-tone area of the m × m pixel,
Extracting the m × m pixel halftone region from the predetermined region by overlapping the mask with the predetermined region to match the m × m pixel halftone region;
By overlapping the predetermined area of the mask obtained by reversing the black and white of the mask so as to coincide with the halftone area of the n × n pixels, the halftone area of the m × m pixel is formed from the predetermined area. By extracting
The predetermined region is divided into two types of halftone regions, the m × m pixel halftone region and the n × n pixel halftone region,
A halftone area of each type is assigned to the corresponding continuous tone image, and a halftone dot for printing one continuous tone image is printed for each halftone area of each type. Printing method for halftone prints. Printing halftone dots for expressing one continuous tone image for each type of halftone area of the two types of halftone areas in a predetermined area composed of the two types of halftone areas. A printing method for halftone prints in which two continuous tone images are printed in the predetermined area,
Continuous tone image of either one of the two continuous tone images using one of two types of inks that appear to be of the same color with the naked eye under normal light but have different optical properties Printing a halftone dot for expressing the other continuous tone image of the two continuous tone images using the other ink of the two types of inks, and A halftone dot for expressing the two continuous tone images using an ink that has different optical characteristics from any of the two types of ink but appears to be the same color as the two types of ink with the naked eye under normal light Print the area except
One continuous tone image of the two continuous tone images can be visually recognized under a predetermined viewing condition, and the two continuous tone images under a predetermined viewing condition different from the predetermined viewing condition While making the other continuous tone image of the image visible,
5. A method for printing a halftone dot printed material according to claim 4, wherein printing is performed so that the predetermined area appears to be of the same color as a whole with the naked eye under normal light.   The halftone dots for expressing the continuous tone image are at least one of a meaningful image including any of a trademark, a family crest, a logo mark, and a character, and an image including any of a circle, an ellipse, and a polygon. 6. A method for printing a halftone print according to claim 4 or 5, characterized in that the image is processed.

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