JP3478474B2 - Halftone screen making method and printed matter - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used in the printing field where banknotes, passports, securities, cards, valuable printed matter, etc. are required to have forgery prevention and tampering prevention functions.

[0002]

2. Description of the Related Art Currently, there are methods for preventing counterfeiting of securities, such as a method using fine lines such as a tint block, a color pattern, and a relief pattern, and a method using fine constituent elements such as minute characters. Basically, a pattern is composed of a set of curved strokes having a constant stroke width, or an arrangement of minute characters. The patterns can be counterfeited or altered in consideration of design characteristics such as securities design, and it is difficult to create the same pattern by complicating the patterns, and the pattern is extracted by a photoengraving device or extracted. The role of anti-counterfeiting measures has been enhanced by using colors that are difficult to reproduce in a copying machine, or by making complicated curved lines to generate moire for scanning input / output of a copying machine and a scanner. Further, the patterns are widely used worldwide as securities designs, and at the same time, they have been used as patterns of printed matters having monetary value such as banknotes, stock certificates, bonds, etc. for a long time. It was an important pattern as a design that impresses with luxury.

However, in recent years, the image quality of color copying machines has been improved,
With the computerization of color plate-making technology, the means for counterfeiting banknotes and securities tend to diversify. In particular, the resolution of image input / output devices used in the field of printing industry has improved remarkably, and it has become easy to extract fine line images used for securities. This suggests the possibility of more full-scale forgery that uses a lot of special color plates, rather than just the forgery by the general commercial printing method consisting of a four-color halftone dot structure.

In view of the above points, the present invention provides a counterfeiting prevention measure to a continuous tone image, makes it difficult to extract a line drawing with the current photoengraving apparatus, and has a function of recognizing a specific original such as machine reading. The present invention provides a prevention gradation reproduction method.

Relatedly, in the field of printing industry,
In addition to black and white binary on printing paper, halftone dots, that is, continuous tone images are always required to represent halftone dots, and these halftone dots must be identified by light and shade by human vision, and a set of fine dots can be used as one floor. It depends on the nature of recognizing as a key. Since the technology for halftoning the continuous tone image has been led by a major plate-making manufacturer, it has been impossible for the user to freely create halftone dots. However, in the platemaking and printing industry of recent years, color printed matter in which characters and images are integrated is relatively available due to the development of PostScript language which is one of computer page description languages and the spread of commercially available application software based on the developed technology. With the ease of creation and the widespread use of Postscript languages, users are able to embark on the development area of halftone screens.

In the halftone dot creating method based on the Postscript language, a digital film recorder is used. In this device, character, image or illustration data created by application software is created as page description data of Postscript language, and RIP (Raster Imag
It is developed into pixels on a scanning line by a device called e Processor) and converted into a set of black and white dots (bitmap) image, which is output to a photosensitive material by a high-density laser beam of 2000 to 5000 pixels per inch. It is a thing. As used herein, the term "pixel" refers to an "image element" in which the smallest part of a continuous tone image is minutely divided and expressed in black and white.

According to the halftone dot producing method using the digital film recorder, for example, the amplitude modulation method is based on regularly arranging pixels whose size changes in proportion to the tone value of the original. . The characteristics are determined by how the number of lines, the halftone dot angle, the halftone dot shape, or the shape of the pixel that increases as the tone value increases.

FIG. 2 shows a halftone dot generation pattern of a general commercial print based on the Postscript language.
For example, when expressing a screen frequency of 60 lines / inch with a low-resolution output device of 300 pixels per inch, 300
/ 60 = 5 pixels, that is, 5 × 5 + arranged in a regular geometric grid of 5 × 5 pixels.
1 = 26 gradation expression.

The halftone dot shape is managed by a mathematical function. In FIG. 3, the central axis of one halftone dot of vertical and horizontal 5 × 5 pixels is set to (0, 0), and the address of each grid is represented by a numerical value from -1 to 1. Receiving the values of these coordinates, the mathematical function calculates values from -1 to 1. This value becomes the priority for filling pixels, and each grid in FIG. 3 has, for example, the mathematical function 1- (X ² + Y ² ), in which the addresses X and Y of the individual grids are set to the X of the mathematical function. , Y
It becomes the numerical value of each pixel of (a), as shown in FIG. 4 (b), the center 1 is filled first, then 0.75, and then
The colors are filled in order from 0.5, ... It should be noted that numerical values other than the central one are the same, but the order among these numerical values depends on the computer built in the machine.

[0010]

The conventional technique described in detail above is capable of creating a more complicated halftone dot shape by using a mathematical function, and is effective as a tone reproduction method for forgery prevention. . However, this method requires familiarity with mathematical functions and the postscript language that is the basis of the technology, such as trademarks, family crests, symbol marks, characters, etc.
There is a limit to creating an arbitrary shape that has a meaning in itself and has a design property using only mathematical functions.

Therefore, according to the present invention, for example, the input image having the design shown in FIG. 1 is converted into a continuous tone image composed of halftone screens (halftone screens) and given to paper money or securities. To create a printed matter that is difficult to copy with a copier or the like, prevent forgery from occurring, and have a function to determine whether a given halftone dot is true or false by machine reading (machine reading will be described later). It is a thing.

[0012]

According to the present invention, the gradation of a continuous gradation image is directly applied to each grid (grid) by computer image processing without using the above-mentioned mathematical function to generate a halftone dot. It provides flexibility to the pattern.

In FIG. 5, one pixel of an arbitrary continuous tone image has 26 pixels.
FIG. 6 is a diagram for explaining a halftone creating method used in the present invention, taking as an example the case where there are 14 gradations in gradations. In order to obtain the same halftone dot generation pattern as in FIG. 4 described above by a method that does not use a mathematical function, the number of gradations of the continuous gradation image shown in FIG. 6, that is, the value of 26 gradations is assigned. By directly applying 26 gradations to each grid, in order to express 14 gradations out of the 26 gradations of FIG. 5 with halftone dots, as shown in FIG. 6, the center 1 is first filled. , Then 2, then 3 ,. ． ． ． ． ． , 12, and so on, starting from the lowest numerical value, the value 13 smaller than 14 gradations is filled.

As described above, the gradation number of a continuous gradation image is directly applied to each grid of 5 × 5 pixels in the vertical and horizontal directions,
If the numerical value is smaller than the number of gradations on each pixel of the continuous gradation image, filling is executed and halftone dots are created.

According to the method, it is possible to freely create halftone dots in FIG. When the generation pattern that is painted from the center to the outside as shown in FIG. 6 is changed to have 6 gradations of brightness, for example, halftone dots on the face showing both eyes and mouth appear. .

By applying the above principle, in the present invention, the line width of an arbitrary shape is modulated by blurring the inside of the outline of the line of 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 obtained by blurring the inside of the contour of the image line of the image is enlarged. In this case, the drawing line gradually becomes thicker from the center of the line toward the outside.

Further, as shown by the broken line in FIG. 24, the area intersecting within the halftone image is blurred to form an acute angle, and as shown in FIG. 26Z1, the image of the intersection area of the lines which is likely to occur during printing is displayed. Prevents line collapse and improves readability and dot quality.

In the outside of the halftone dot image, not the blurring process from the center of the grid to the peripheral direction, but the density outside the outline of the image line of the image as shown in FIG. There is also a method of improving the gradation reproducibility over time.

Further, as shown in FIG. 26Z3, by assigning a zero density (FF) area of several pixels to the outline area of the halftone dot, and giving an unfilled gap inside and outside,
Halftone dots can be recognized in the entire area from the bright area to the dark area of the continuous tone image, improving readability.

Here, if the halftone dot creating method according to the present invention is shown as a flow chart, FIG. 9 corresponding to claims 1, 9 and 17, FIG. 10, claim 3 corresponding to claims 2, 10 and 18, 1
FIG. 11 corresponding to 1, 19 and FIG. 1 corresponding to claims 4, 12, and 20.
2, FIG. 13 corresponding to claims 5, 13, and 21, claims 6, 14, and 2
FIG. 14 corresponding to 2, FIG. 15 corresponding to claims 7, 15, and 23,
Shown as FIG. 16 corresponding to claims 8, 16 and 24.

Further, in these flowcharts,
If an image processing unit for inverting the input image is provided as necessary, a series of processes can be started from the input image corresponding to the highlight part, or a series of processes can be started from the input image corresponding to the shadow part. You can also start Further, it is possible to provide an image processing unit for inverting the gradation of the image data obtained through all the processing.

The halftone dot created by the halftone screen creating method of the present invention is machine-readable in any area from the highlight part to the shadow part, regardless of the halftone screen created by any of the creating methods. (Mechanical reading will be described later).

In this way, according to the present invention, the designer designs a halftone dot according to the customer's order using a generally used personal computer and image processing software without using a special system. The feature is that it is possible.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiment 2 of FIG. 25, which will be described later, is a method of creating a halftone screen (continuous tone halftone dot) according to the present invention.
In correspondence with the reference mark of (1) trademark, family crest, logo mark, symbol mark, character, company name, slogan, warning sentence, etc.
An image input unit is provided for reading an image having a design that has its own meaning. (2) An outline extraction processing unit for the input image is provided. An image processing unit for converting the image lines into a plurality of gradations is provided by providing an image processing unit (3 ′) for blurring an acute angle with respect to the intersection area of the image lines, and (4 ′) performing density dispersion processing on the outside of the outline of the image lines. And (5) assigning a zero density area of several pixels to the contour area, and (6) providing a portion for converting the obtained image data into a Postscript command that can be read by an output device,
(7) A processing unit for giving an instruction to the halftone dot generator is provided.

Hereinafter, the present invention will be described more specifically by way of examples with reference to the drawings, but the present invention is not limited thereto. As a first embodiment, an example will be described in which, in the logo mark shown in FIG. 1 having a design characteristic, the Japanese text "I" is halftone-dotted and the line thickness is modulated to reproduce a continuous tone image.
The print quality of the present invention is as high as 80
It has a resolution of ~ 175 lines / inch and can be reproduced in a small area. Although FIG. 1 shows an arbitrary logo mark or the like adopted in the present invention, it is not limited to this example.

First, the Japanese text "I" shown in FIG. 18 is converted into black and white gradation image data by using an image input device. Figure 19 (a)
As shown in (4), the black area inside the outline of the image is blurred to 256 gradations. At this point, the image density outside the area is zero (FF in 8-bit hexadecimal notation) as shown in FIG. 19B.

Next, as shown in FIG. 20A, a white area outside the image outline area of the image is subjected to a circular blurring process from the center of the grid to the outside to obtain 256 gradations. Figure 20
From (b), it can be seen that 256 gradation data is added to the entire area. The image density is 8 bits 16 for the brightest part.
It is FF in hexadecimal notation, and the darkest part is 00 in 8-bit hexadecimal notation.

To adjust the stroke thickness of the Japanese typeface "Ichi", 256 gradation data can be arbitrarily changed as shown in FIG. 21 (b), or commercially available image processing software can be used. Figure
If the image of 21 (a) is directly corrected, a rectangular array with optimum 256 gradation density can be obtained.

The rectangular array data of 256 gradation densities (00 to FF in 8-bit hexadecimal notation) obtained in FIG. 21 (b) is converted into data readable by a halftone dot generator, and film output is performed. . The 256-gradation density rectangular array data is a critical value for judging ON / OFF (black, white) in each grid of halftone dots, 0 means black and FF means white, and the continuous gradation to be applied. If the density of the image is darker (smaller) than the numerical value for judging on / off (black, white) in each grid shown in FIG. 21 (b),
The grid of dots is turned on.

As a second embodiment, FIG. 26 is an improvement of the first embodiment. In the character portion Z ₁ of the character portion in FIG. 26, in the blurring process inside the image outline of the image of the first embodiment, the uneven density distribution as shown in FIG. 21Z results. Therefore, when synthesizing the images of both with the example of FIGS. 22 and 23, as shown by the broken line in FIG. 24, blurring processing is performed in an acute angle to prevent the image lines in the intersecting area that are likely to occur during printing from being crushed. , Improve readability and halftone dot quality.

An improvement of Example 1 is shown in FIG. 26 Z ₂ .
By dispersing the density outside the character area, the gradation from the middle to the bright part is reproduced more smoothly.

Further, in FIG. 26 Z ₃ , the outline region of the character is assigned a zero density (FF) region of several pixels. By providing a non-filled gap between the inside and the outside of the character, it becomes possible to observe the character information having a fine structure from the bright portion to the dark portion.

FIG. 27 is a printed matter p obtained in this example. While the thickness of the strokes of the Japanese typeface "Ichi" gradually increases,
Moreover, the characters can be observed even in the dark area.

In the third embodiment, not only the single logo mark or typeface, but also a plurality of Japanese typefaces such as company names, slogans, and warning sentences are halftone-dotted to obtain a gradation expression.
According to the embodiment, in FIG. 28, gradation is expressed while the line width of the Japanese document “printing station” gradually increases. Also,
In FIG. 29, the gradation is expressed by the Japanese text “copy prohibited”.

In Example 4, an intermediate product as a screen for screen making made of film can be prepared, and a halftone dot structure corresponding to the amount of transmitted light can be obtained by an optical method using the screen. This is a kind of blurring screen, and when the produced film is observed with a microscope, the light and shade defocus points described in the above embodiment are alternately arranged. The center of the black dot has the highest density, and the center of the white dot has the lowest density and is transparent.

An arbitrary halftone dot film can be obtained by using a focal plane of a plate making camera or a vacuum device of a photo enlarger with a vacuum plane, and exposing it in close contact with the front surface of a hard plate making film (lith film) having high resolution. . In this case, the amount of light transmitted through the screen varies depending on the lightness and darkness of the original to be used, and it is possible to optically create continuous tone halftone dots together with the amount of blackening that occurs in the lith film.

The gradation reproduction method for preventing forgery according to the present invention has been described above. Next, the film original plate and the printed matter obtained by the present invention will be described.

Using the continuous tone image shown in FIG. 30, a printing plate was prepared for the film original plate (mesh plate) obtained as a result of the above-described halftone dot creating method, and a printed matter printed using the printing plate. The enlarged photograph of the left-eye portion e reproduces a continuous tone image while modulating the drawing line thickness of the Japanese document "Ichi" as shown in FIG. 31 (a).

Since the quality of such printed matter has a resolution of 80 to 175 lines / inch, which is the same level as that of general printed matter, the printed matter is not noticed to the naked eye that it is composed of halftone dots in consideration of design. Is clear (Fig. 31 (b))
Will be described later).

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments.
Any trademark or logo mark can be applied to any continuous tone image as a halftone dot. The present invention is also applicable to bills, securities, etc.
For those requiring anti-counterfeiting, the object can be achieved only by applying the present invention to an extremely small area even if the paper surface is limited.

[0041]

As is apparent from the above description, according to the gradation reproduction method for forgery prevention by the halftone dot creating method of the present invention, the reproduction is performed by a general plate-making device as shown in FIG. 31 (b). As described above, the halftone dots of the Japanese typeface "Ichi" disappear and become unreadable.

Further, when the halftone dots are duplicated, moiré is generated for the scanning input / output, and since the duplicate can judge the authenticity at a glance due to the remarkable gradation defect, it is difficult to restore the gradation defect. It is possible to prevent counterfeiting from time to time, and it plays a major role as a counterfeit prevention measure.

Further, as an example of the above-mentioned machine reading in the present invention, for example, in a bill discriminating and reading part of an automatic vending machine or the like, a halftone dot (for example, the above-mentioned Japanese text "Ichi") of the narrow area is read by a CCD camera or the like. There is an example in which by performing image processing such as reading and pattern matching, it is possible to perform automatic and high-speed true / false determination as compared with visual true / false determination.

[Brief description of drawings]

FIG. 1 is a view for explaining that, as an example of a dot that can be given in the present invention, a dot shape itself can freely adopt a trademark, a family crest, a symbol mark, a character, or the like that has its own meaning. Fig.

FIG. 2 is a diagram for explaining an example of a 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 halftone screen of PostScript language.

FIG. 4 is a diagram illustrating an example of a mathematical function and a diagram for explaining a state in which priorities for filling are assigned.

FIG. 5 is a continuous tone image used to explain the halftone creation method of the present invention.

FIG. 6 is a diagram illustrating a method of not using a mathematical function in the halftone creation method of the Postscript language, and a diagram for explaining a state in which the priority order of filling is assigned by the number of gradations.

FIG. 7 is a diagram for explaining how to add a design property to a generated pattern by applying a method that does not use a mathematical function in the halftone creating method of the Postscript language.

FIG. 8 is a diagram for explaining blurring processing in the halftone creating method of the present invention.

FIG. 9 is a diagram for explaining a halftone dot creating method corresponding to claims 1, 9, and 17 according to the present invention with a flowchart.

FIG. 10 is a diagram for explaining a halftone dot creating method corresponding to claims 2, 10, and 18 according to the present invention with a flowchart.

FIG. 11 is a diagram for explaining a halftone dot creating method corresponding to claims 3, 11, and 19 according to the present invention with a flowchart.

FIG. 12 is a diagram for explaining a halftone dot creating method corresponding to claims 4, 12, and 20 according to the present invention with a flowchart.

FIG. 13 is a diagram for explaining a halftone dot creating method corresponding to claims 5, 13, and 21 according to the present invention with a flowchart.

FIG. 14 is a view for explaining a halftone dot creating method corresponding to claims 6, 14, and 22 according to the present invention with a flowchart.

FIG. 15 is a diagram for explaining a halftone dot creating method corresponding to claims 7, 15, and 23 according to the present invention with a flowchart.

FIG. 16 is a diagram for explaining a halftone dot creating method corresponding to claims 8, 16 and 24 according to the present invention with a flowchart.

FIG. 17 is a diagram for explaining a halftone dot creating method according to the first embodiment with a flowchart.

FIG. 18 is a diagram showing an example of halftone dots added in the first embodiment, to which the Japanese text “Ichi” is applied.

FIG. 19 is a diagram for explaining that the inside of the outline of the image line of the halftone dot text document “Ichi” given in the first embodiment is blurred to 256 gradations.

FIG. 20 is a diagram for explaining that the outside of the outline of the image line of the image of the halftone dot text document “Ichi” given in the first embodiment is blurred to 256 gradations.

FIG. 21 is a diagram illustrating that correction can be made to the entire area of the halftone dot text body “Ichi” given in the first embodiment.

FIG. 22 is a diagram showing an image before forming intersections for explaining an acute-angle blurring process for the intersection regions inside the drawing lines in the second embodiment.

FIG. 23 is a diagram showing an image before forming an intersection for explaining an acute-angle blurring process with respect to the intersection area inside the image line in the second embodiment.

FIG. 24 is a diagram illustrating a state of a sharp-angled blurring process at a portion where image lines form an intersection.

FIG. 25 is a flowchart for explaining a halftone dot creating method according to the second embodiment.

FIG. 26 is a diagram (Z ₁ ) illustrating an acute-angled blurring process state for a region where image lines form an intersection with the Japanese text “I” as an example, and as a gradation expression other than the character region. , A diagram for explaining the dispersion of the densities (Z ₂ ), and a method for allocating a region without density of several pixels to the character outline portion and enabling the character recognition even in the dark gradation region Figure (Z ₃ ).

FIG. 27 is a printed matter illustrating an example of gradation reproduction obtained in Example 2.

FIG. 28 shows an example in which halftone dots are formed by using a company name, slogan, warning text, logo mark, etc. as constituent elements in the third embodiment.
Printed material with half-tone Japanese print style "Print Bureau".

FIG. 29 shows an example in which halftone dots are formed using the company name, slogan, warning text, logo mark, etc. as constituent elements in the third embodiment.
Printed material that is halftone version of the Japanese typeface "copy prohibited".

FIG. 30 is a continuous tone image used for obtaining a halftone screen having a design property in Example 2.

FIG. 31 is a partially enlarged photograph of a continuous tone image including halftone dots which is not reproduced by a copying machine or the like in consideration of the design property obtained by the present invention, and when the right eye portion of FIG. 30e is enlarged. (A) illustrating the observed halftone dot typeface "Ichi", and an enlarged photograph of a duplicate obtained after printing the printing plate obtained by processing the printed matter obtained by the present invention with a plate-making input / output device. Then, the halftone dot of the Japanese typeface "Ichi" disappears and is unreadable (b).

[Explanation of symbols]

1 Image input unit for reading an image having a design property that has meaning by itself, such as a trademark, a family crest, a symbol mark, and a character 2 A contour extraction processing unit 3 of an input image 3 A gradation process is performed by blurring the inside of the contour. Image processing unit 3 ′ Image processing unit 4 for blurring processing in an area where intersections of drawing lines form an acute angle in a sharp angle image processing unit 4 ′ for blurring processing for the outside of the contour to obtain multiple gradations Performing density distribution processing for the outside of the contour Image processing unit 5 for multi-gradation Image processing unit 6 for assigning a zero density region of several pixels to the contour region 6 Processing unit 7 for converting the obtained image data into a Postscript command readable by an output device by blurring during processing unit Z print providing instructions to uneven concentration distribution (streak collapse) intersection region Z ₁ acute-angled likely character part generating, collapse of uneven concentration distribution (streaking By distributing the intersection area Z ₂ character area outside of the concentration of the character portion which prevented the,
Area Z that smoothly reproduces the gradation from the middle to the bright part Z ₃ Outline of characters to which a density zero (FF) area of several pixels is assigned p Extract the contour of the input image with design and blur the inside of the contour of the image line. The halftone dot is processed, and the intersection area of the image lines is blurred in an acute angle, the outside of the contour is density-dispersed, and a zero density (FF) area of several pixels is assigned to the contour area and output. Printed matter p ′ A net obtained by blurring the inside of the contour line of the input image having the design property, blurring the intersection area of the contour lines in an acute angle shape, and performing density distribution processing on the outside of the contour line of the input image.
Printed matter consisting of dots e The outline of the input image having design characteristics is extracted, the inside of the image line outline is blurred, the intersection region of the image line is blurred in an acute angle, the outside of the image line outline is subjected to density dispersion processing, and the outline is extracted. Network output by assigning a zero density (FF) area of several pixels to the area
The left-eye part of the printed matter consisting of dots .

Claims (34)

(57) [Claims] 1. A trademark, a family crest, a logo mark, a symbol mark, a character and the like are used as an input image corresponding to one halftone dot pixel,
A halftone screen creating method, characterized by comprising halftone dots obtained by performing a blurring process inside a contour of an image line of the input image. 2. A trademark, a family crest, a logo mark, a symbol mark, a character and the like are used as an input image corresponding to one halftone dot pixel,
It is obtained by blurring outside the contour of the stroke of the input image.
A halftone screen producing method, characterized by comprising halftone dots . 3. A trademark, a family crest, a logo mark, a symbol mark, a character or the like is used as an input image corresponding to one halftone dot pixel,
A halftone screen creating method, characterized in that it is constituted by halftone dots obtained by performing a blurring process inside a contour of an image line of the input image and performing an acute-angle blurring process on an intersection point of the image lines of the input image. 4. A trademark, a family crest, a logo mark, a symbol mark, a character and the like are used as an input image corresponding to one halftone dot pixel,
Halftone dots obtained by performing a blurring process on the inside of the contour of the image of the input image and a blurring process on the outside of the contour of the line of the input image
A halftone screen creating method characterized by being configured by . 5. A trademark, a family crest, a logo mark, a symbol mark, a character and the like are used as an input image corresponding to one halftone dot pixel,
A net obtained by performing blurring processing on the inside of the contour of the image of the input image, blurring at the intersection point of the lines of the input image in an acute angle, and blurring outside the contour of the drawing of the input image.
A method of making a halftone screen, characterized by being composed of dots . 6. A trademark, a family crest, a logo mark, a symbol mark, a character and the like are used as an input image corresponding to one halftone dot pixel,
The contour area of the input image is extracted, and the drawing line of the input image is extracted.
The outline of the input image is blurred and the halftone dot obtained by assigning a zero density area of several pixels to the outline area of the input image
Therefore , a halftone screen making method characterized by comprising. 7. A trademark, a family crest, a logo mark, a symbol mark, a character and the like are used as an input image corresponding to one halftone dot pixel,
Extracting a contour region of the input image, and blurring the inner contour of the field lines of the input image, the outline of streaked of the input image
And blurring the outside, by resulting halftone dots obtained by assigning zero concentration region of several pixels in the contour region of the input image
A method for creating a halftone screen, which is characterized by comprising: 8. A trademark, a family crest, a logo mark, a symbol mark, a character and the like are used as an input image corresponding to one halftone dot pixel,
Extracting a contour region of the input image, and the blur processing inside the image lines of the input image, and blurring in an acute angle at the intersection portion of the image line of the input image, the contour outside streaked of the input image
The input image is subjected to a blurring process, and the outline region of the input image is assigned a zero density region of several pixels to construct a halftone dot.
A method of creating a halftone screen, characterized by comprising: 9. A halftone dot is an n × n block in which n lines of a company name, slogan, warning text, logo mark, etc. consisting of n characters repeated in the horizontal direction are shifted in the horizontal direction by one character each in a fixed direction. An input image corresponding to a pixel, and n × obtained by performing blurring processing on the inside of the contour of the image line of the input image
A halftone screen creating method characterized by comprising n blocks of halftone dots . 10. A halftone dot is an n × n block in which a company name, slogan, warning text, logo mark, etc. consisting of n characters repeated in the horizontal direction are shifted in the horizontal direction by one character and n rows are arranged. An input image corresponding to a pixel, and n obtained by performing a blurring process on the outside of the contour of the image line of the input image.
A halftone screen producing method, characterized in that it is constituted by halftone dots of × n blocks. 11. A halftone dot is an n × n block in which a company name, slogan, warning text, logo mark, etc. consisting of n characters repeated in the horizontal direction are arranged in n rows by shifting one character in the horizontal direction in a fixed direction. An input image corresponding to a pixel is subjected to blurring processing inside the contours of the image lines of the input image, and the intersection point of the image lines of the input image is subjected to the blurring processing in an acute angle by the halftone dots of n × n blocks . A method for creating a halftone screen, which is characterized by comprising: 12. A halftone dot is an n × n block in which a company name, slogan, warning text, logo mark, etc. consisting of n characters repeated in the horizontal direction are arranged in n rows by shifting one character in the horizontal direction in a fixed direction. An input image corresponding to a pixel, and is composed of halftone dots of n × n blocks obtained by performing a blurring process inside a contour of an image line of the input image and performing a blurring process outside the contour of an image line of the input image. A halftone screen creation method characterized by. 13. A halftone dot is an n × n block in which n company characters, slogans, warnings, logo marks, etc., each consisting of n characters repeated in the horizontal direction, are arranged in n rows while shifting each character in the horizontal direction in a fixed direction. As an input image corresponding to a pixel, blur processing is performed inside the contour of the image line of the input image, blurring processing is performed at an intersection point of the image lines of the input image in an acute angle shape, and blurring is performed outside the contour of the image line of the input image. N × n obtained by processing
A method of making a halftone screen, characterized by comprising halftone dots of blocks. 14. A halftone dot is an n × n block in which a company name, slogan, warning text, logo mark, etc. consisting of n characters repeated in the horizontal direction are arranged in n rows by shifting one character in the horizontal direction in a fixed direction. As an input image corresponding to pixels, the contour area of the input image is extracted, and the circle of the drawing line of the input image is extracted.
A halftone screen producing method, characterized in that it is constituted by halftone dots of n × n blocks obtained by performing blurring processing on the outside of the contour and assigning a zero density area of several pixels to the contour area of the input image. 15. A halftone dot is an n × n block in which n company characters, slogans, warnings, logo marks, etc., each consisting of n characters repeated in the horizontal direction, are arranged in n rows while shifting one character in the horizontal direction in a fixed direction. As an input image corresponding to a pixel, a contour area of the input image is extracted, blurring processing is performed inside the contour of an image line of the input image, and the contour outline of the image line of the input image is external.
Of the n × n block obtained by assigning a zero density area of several pixels to the contour area of the input image.
A halftone screen making method characterized by being composed of halftone dots . 16. A halftone dot is an n × n block in which a company name, slogan, warning text, logo mark, etc., which consists of n characters repeated in the horizontal direction, are arranged in n rows by shifting one character in the horizontal direction in a fixed direction. As an input image corresponding to a pixel, the contour area of the input image is extracted, and the blurring process is performed inside the contour of the image line of the input image, and the blurring process is performed at the intersection point of the image lines of the input image in an acute angle shape, Outside the outline of the input image lines
A halftone screen creating method, characterized in that it is constituted by halftone dots of n × n blocks obtained by assigning a zero density area of several pixels to a contour area of the input image by blurring the area. 17. A halftone dot is an n × n block in which n company characters, slogans, warnings, logo marks, etc. consisting of n characters repeated in the vertical direction are arranged in n rows while shifting one character in the vertical direction in a fixed direction. An input image corresponding to a pixel is obtained, and n is obtained by blurring the inside of the outline of the image line of the input image.
A halftone screen producing method, characterized in that it is constituted by halftone dots of × n blocks. 18. A halftone dot is an n × n block in which n company characters, slogans, warnings, logo marks, etc. consisting of n characters repeated in the vertical direction are arranged in n rows while shifting by one character in the vertical direction. An input image corresponding to a pixel, and n obtained by performing a blurring process on the outside of the contour of the image line of the input image.
A halftone screen producing method, characterized in that it is constituted by halftone dots of × n blocks. 19. A halftone dot is an n × n block in which a company name, a slogan, a warning sentence, a logo mark, etc. consisting of n characters repeated in the vertical direction are arranged in n rows while shifting one character in the vertical direction in a fixed direction. An input image corresponding to a pixel is subjected to blurring processing inside the contours of the image lines of the input image, and the intersection point of the image lines of the input image is subjected to the blurring processing in an acute angle by the halftone dots of n × n blocks . A method for creating a halftone screen, which is characterized by comprising: 20. One halftone dot is an n × n block in which n company characters, slogans, warnings, logo marks, etc. consisting of n characters repeated in the vertical direction are arranged in n rows while shifting in the constant direction by one character in the vertical direction. An input image corresponding to a pixel, and is composed of halftone dots of n × n blocks obtained by performing a blurring process inside a contour of an image line of the input image and performing a blurring process outside the contour of an image line of the input image. A halftone screen creation method characterized by. 21. One halftone dot is an n × n block in which n company characters, slogans, warnings, logo marks, etc. consisting of n characters repeated in the vertical direction are arranged in n rows while shifting in the constant direction by one character in the vertical direction. As an input image corresponding to a pixel, blur processing is performed inside the contour of the image line of the input image, blurring processing is performed at an intersection point of the image lines of the input image in an acute angle shape, and blurring is performed outside the contour of the image line of the input image. N × n obtained by processing
A method of making a halftone screen, characterized by comprising halftone dots of blocks. 22. One halftone dot is an n × n block in which n company characters, slogans, warnings, logo marks, etc., each consisting of n characters repeated in the vertical direction, are arranged in n rows while shifting by one character in the vertical direction. an input image corresponding to the pixel to extract a contour region of the input image, wheel streaked of the input image
A halftone screen producing method, characterized in that it is constituted by halftone dots of n × n blocks obtained by performing blurring processing on the outside of the contour and assigning a zero density area of several pixels to the contour area of the input image. 23. One halftone dot is an n × n block in which a company name, a slogan, a warning sentence, a logo mark, etc. consisting of n characters repeated in the vertical direction are arranged in n rows while shifting one character in the vertical direction in a fixed direction. As an input image corresponding to a pixel, a contour area of the input image is extracted, blurring processing is performed inside the contour of an image line of the input image, and the contour outline of the image line of the input image is external.
Of the n × n block obtained by assigning a zero density area of several pixels to the contour area of the input image.
A halftone screen making method characterized by being composed of halftone dots . 24. One halftone dot is an n × n block in which n columns of company names, slogans, warnings, logo marks, etc. consisting of n characters repeated in the vertical direction are arranged in a fixed direction by shifting one character in the vertical direction. As an input image corresponding to a pixel, the contour area of the input image is extracted, and the blurring process is performed inside the contour of the image line of the input image, and the blurring process is performed at the intersection point of the image lines of the input image in an acute angle shape, Outside the contour in the stroke of the input image
A halftone screen creating method, characterized in that it is constituted by halftone dots of n × n blocks obtained by assigning a zero density area of several pixels to a contour area of the input image by blurring the area. 25. The method for producing a halftone screen according to claim 1, wherein an image processing unit for inverting the input image is provided and the input image is configured by halftone dots . 26. The method according to any one of claims 1 to 25, wherein an image processing unit for inverting the gradation of the image data obtained through all the processing is provided, and the image processing unit is configured by halftone dots.
A method of creating a halftone screen, characterized by comprising: 27. A contact screen film for plate-making produced by the method for producing a halftone screen according to any one of claims 1 to 26. 28. A film original plate for plate making produced by the method for producing a halftone screen according to claim 1. 29. A plate-making film original made from the plate-making contact screen film according to claim 27. 30. A printing plate produced by the method for producing a halftone screen according to claim 1. 31. A printing plate for printing made of the contact screen film for plate making according to claim 27. 32. A printing plate made of the film-making plate precursor according to claim 28. 33. A printing method for printing special halftone dots using the printing plate for printing according to claim 30. 34. A printed matter having special halftone dots created by the printing method according to claim 33.