JP3777414B2 - Hybrid halftone screen generation method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a hybrid halftone screen generation method that combines an amplitude modulation method and a frequency modulation method in order to obtain a fine and precise high-definition printed material using a frequency modulation screening method.
[0002]
[Prior art]
In the printing industry field, halftones are always required to represent halftone, that is, continuous tone images, in addition to black and white binary values on printing paper. However, it depends on the property of recognizing a collection of fine points as one gradation. As a method for halftoning the continuous tone image, an amplitude modulation screening method and a frequency modulation screening method are known. Further, since the conventional halftone dot generation technology has been led by a major plate making manufacturer, it has been impossible for the user to generate halftone dots freely. However, in the recent plate making and printing industry, the development of a postscript language, which is one of computer page description languages, and the spread of commercially available application software based on the development technology have led to the development of color prints that integrate characters and images. It can be created relatively easily, and with the widespread use of PostScript languages, users can start to develop halftone screens.
[0003]
In the screening 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 generated as page description data in Postscript language, and is developed into pixels on a scanning line by a device called RIP (Raster Image Processor), and is converted into a monochrome bit. It is converted into a map 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.
[0004]
According to the screening method using the digital film recorder, for example, the amplitude modulation screening method is based on regularly arranging pixels whose sizes change in a balanced manner with respect to the tone value of the original. The characteristics of the screening method are determined by how the shape of the pixel increases as the number of lines, dot angle, dot shape, or tone value increases.
[0005]
FIG. 1 shows a halftone dot generation pattern of a general commercial print based on the Postscript language. For example, when expressing a screen line of 60 lines / inch with a low resolution output device of 300 pixels per inch, 300/60 = 5 pixels, that is, a 5 × 5 pixel array of regular lines. (Grid), 5 × 5 + 1 = 26 gradation representation.
[0006]
The halftone dot shape is managed by a mathematical function. In FIG. 2, the center 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 numerical values from −1 to 1. In response to these coordinate values, the mathematical function returns a value between -1 and 1. This value is the priority for filling the pixels, and each grid in FIG. 2 becomes the numerical value of each pixel in FIG. 3A by the mathematical function 1- (X ² + Y ² ). As shown in the figure, the center 1 is filled first, then 0.75, 0.5, ..., -1 and so on, starting from the highest numerical value. The order between these numbers depends on the computer built into the machine.
[0007]
Amplitude modulation screening of such simple circular halftone dot shape makes it easy to screen an image at high speed by digital processing, and uses a halftone dot larger than one pixel, so that print reproducibility is high. Although the image becomes rougher than the frequency modulation screening method, in a high-resolution output system, the halftone dot itself is very small, so the image roughness is not a concern. However, a significant drawback of the amplitude modulation method is that unwanted moiré and rosette patterns are produced in the halftoned image.
[0008]
On the other hand, the frequency modulation screening method does not have a line number, a halftone dot angle, or a halftone dot shape, and is determined by modulating the distance between halftone dots, not how the pixel shape changes. That is, all the halftone dots have the same size, but the number per surface area varies according to the tone value to be reproduced, and the spatial arrangement thereof is randomized.
[0009]
Further, frequency modulation screening methods are provided to alleviate the problems of moire and rosette patterns generated by the amplitude modulation method described above, and some of them have been disclosed. Since the shape of the pixel is not recognized, reproduction close to continuous gradation is possible, and a fine and dense high-definition printed matter can be obtained. Further, since there is no coupling at the halftone dot corners as seen in the amplitude modulation screening method, the tone fluctuations are moderate, and since there is no halftone angle, multicolor printing is possible.
[0010]
However, the frequency modulation screening method distributes and arranges using the minimum dots of 10 to 20 microns per pixel, so particularly with regard to the highlight dot, when printing from the photographic film output by the digital film recorder to the printing plate. The highlight portion disappears due to the influence of the degree of printing, the resolution of the printing plate, or the printing durability, resulting in image unevenness and particle roughness.
[0011]
[Problems to be solved by the invention]
The simplest solution to the prior art described in detail above is that the highlight area of the continuous tone image is the amplitude modulation screening, and the image in the shadow area from the middle part is subjected to multiple exposure by the frequency modulation screening method, and the combined screening is performed. That is.
[0012]
However, with this method, multiple exposure cannot always be performed at the same position, which causes a problem in position accuracy. In addition, exposing a continuous tone image at least twice requires a corresponding amount of capacity and time, and tone correction is difficult. Furthermore, the technique is limited to positive (positive).
[0013]
Several methods using the above-described mixed amplitude and frequency halftone screen method are disclosed (for example, Japanese Patent Publication No. 62-44744). However, these methods require a pre-process for analyzing image highlights, middle portions, and shadow portions in advance using an image processing system, or dividing an image region by any method.
[0014]
The present invention does not require any intermediate process for dividing the image area as described above, and uses a method for generating an arbitrary mixed halftone screen for all gradation image areas, and is a drawback of the conventional frequency modulation method. It is an object of the present invention to provide a method for improving the roughening of grain in the highlight part of a gradation image and further improving the printing durability.
[0015]
[Means for Solving the Problems]
In order to solve the above problems, in the hybrid halftone screen generation method of the present invention, the amplitude modulation method is used for the highlight portion, and the intermediate portion, which is a region where precise and precise expression is required, is used. A frequency modulation method is used for the shadow portion, and at this time, the first variable is given to make the position where the amplitude modulation screen is mixed in the frequency modulation screen and the dot diameter variable.
[0016]
Further, by giving the second variable, it is characterized in that the priority for filling the pixels on the amplitude and frequency modulation screen is given priority on the amplitude modulation screen side.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
In the present invention, (a) an amplitude modulation method is provided in the highlight portion, and an algorithm for mixing the frequency modulation method in the middle portion to the shadow portion is provided. (B) Generate a halftone of any configuration by providing a second variable that gives priority to the amplitude modulation screen on the amplitude modulation screen side. However, you can also set it yourself using application software such as Adobe Photoshop ^TM or a Postscript Printer Definition File (PPD).
[0018]
【Example】
The present invention will be described more specifically with reference to the drawings by way of examples, but the present invention is not limited thereto.
[0019]
(Embodiment 1) FIG. 4 (a) uses the mathematical function shown in FIG. 3 and is 16 × 16 pixels × 256 gradations in length and breadth. A halftone dot of about 2% is shown in terms of gradation and halftone dot area ratio. For example, the XY address value of the grid assigned to the arithmetic register is displayed within the bold frame shown in FIG. 4 (b). The amplitude modulation screen method is used until X = 0.125 and Y = 0.125, and from outside the frame exceeding 0.125. It shall be arranged with a frequency modulation screen. In this case, each grid other than the amplitude modulation screen painted in FIG. 4C is painted randomly as a frequency modulation screen.
[0020]
FIG. 5 is a flowchart showing the mixed screen state of the present invention. When a halftone dot is generated by a digital film recorder based on the Postscript language, the X and Y address values of one grid are stored in the arithmetic register, and a mathematical function that determines the halftone dot shape is −1 to 1 The values up to are given as priorities for filling the grid, and the same calculation processing is sequentially performed for all the grids.
[0021]
In the present invention, with respect to the X and Y address values of one grid stored in the arithmetic register, the amplitude modulation screen is branched to the highlight portion of the image, and the frequency modulation screen is branched from the middle of the image to the shadow portion. It is necessary to process some operation for this in the arithmetic register.
[0022]
FIG. 6 shows the internal structure of the arithmetic register. In the Postscript language, this structure is called an operand stack, and takes a fixed data structure for temporarily storing data, and each data is stored in a stacked form on other data. The stack has a data structure of “last-in first-out method”. For example, when three elements are placed on the stack, the third element is placed on the top, so the third element is taken out first. Thus, most of the programming in the Postscript language consists of the operation of the stack. Also in this embodiment, a function for generating a halftone dot is defined by using the stack as efficiently as possible.
[0023]
In accordance with the above principle, the internal structure of the operand stack shown in FIG. 6 will be described with reference to the flowchart of FIG. 5, taking FIG. 4 as an example. First, in FIG. 4C, attention is paid to, for example, (X, Y) = (0.25, −0.125) as the address value of the grid when the amplitude modulation screen is switched to the frequency modulation screen. According to the flowchart of FIG. 5, first, the address value of X (here, 0.25) is stored (a), and then the address value of Y (−0.125) is stored (b). Take absolute value (c). Next, the storage order of the upper two elements existing in the operand stack is exchanged to obtain the absolute value of X (d). Further, the absolute value of the upper stack X is taken (e). The above operation is stored in the lower part of the operand stack as the X and Y address values of the grid necessary for arithmetic processing of the mathematical function that determines the halftone dot shape later. On the other hand, the subsequent processing newly copies two elements from the top of the operand stack as values necessary for branching to either the amplitude or frequency modulation screen (f). Here, the sum of the highest level (first operand) and the lower level (second operand) is obtained, and the value of the obtained sum enters the stack (g). Here, the sum of the X and Y address values (here, 0.125 + 0.125 = 0.25, which is the first variable), which is the limit point of the amplitude modulation screen, is placed on the stack (h), and the first operand If is less than or equal to the second operand, the logical value true is stored, otherwise a logical instruction is provided to store false. Therefore, the logical value true or false is stored in the upper stack (i). On top of the stack is further placed a mathematical function defining the dot shape of the amplitude modulation screen (j), further placing a mathematical function defining the dot shape of the frequency modulation screen (k), and finally A branch instruction is performed at this stage. All the top three operands are removed from the operand stack, and if the logic value of (i) is true, the amplitude modulation screen is executed, and if it is false, the frequency modulation screen is executed. In this embodiment, since the first operand 0.375 is larger than the second operand 0.25, it becomes false and the frequency modulation screen is selected.
[0024]
By adjusting the sum of the X and Y address values, which is the limit point of the amplitude modulation screen, that is, the first variable, the dot diameter of the amplitude modulation screen can be controlled, and the highlight halftone dot of the image can be controlled. It is possible to control what percentage of the area ratio is held by the amplitude modulation screen. For example, in FIG. 4, when the grid address value, the sum of (X, Y) = (0.25, 0.25), 0.5, is taken as the first variable, the dot diameter of the amplitude modulation screen increases, The amplitude modulation screen halftone dot will be kept as compared with the above example.
[0025]
As described above, with respect to the X and Y address values of one grid stored in the arithmetic register, the amplitude modulation screen is branched to the bright portion of the image and the frequency modulation screen is branched from the middle of the image to the shadow portion. The
[0026]
FIG. 7 shows a state in which the mixed state of dots on both the amplitude modulation screen and the frequency modulation screen changes. For example, in the case of (a) the first variable 2.0, only the amplitude modulation screen is used, and in the case of (b) the first variable 1.0, the halftone dot diameter of the amplitude modulation screen is constant when the intermediate portion of the continuous tone image is exceeded. Become. In addition, in the case of (c) first variable 0.25, it can be seen that the halftone dot diameter is constant from around 2 to 3% of the continuous tone image highlight portion, and the frequency modulation screen is generated around.
[0027]
FIG. 8 shows the internal structure of the arithmetic register that explains how the priorities are determined for the amplitude modulation screen. The mathematical function of the amplitude modulation screen is set to pixel fill priority = 1− (X ² + Y ² ) as in FIG. First, an X address value is stored in the operand stack (a), and then a Y address value is stored (b). Next, the top element on the operand stack is duplicated (dup) (c). Further, the product (mul) of the most significant (first operand) and the lower (second operand) is returned (d). Exchange the storage order of the upper 2 elements existing in the operand stack (e). The first element on the operand stack is duplicated (dup) again (f), and the product (mul) of the highest (first operand) and the lower (second operand) is returned (g). Returns the sum (add) of the most significant (first operand) and the lower (second operand) (h) and puts 1 on the stack (i). Finally, exchange the storage order of the upper two elements existing in the operand stack (exch) (j) and return the (sub) value subtracted from the highest (first operand) and below (second operand) (k). Thus, values from −1 to 1 are calculated, and these values are priorities in the amplitude modulation screen that fills each pixel.
[0028]
The above (dup), (mul), etc. are described in a Postscript language, and the mathematical function of the amplitude modulation screen is {dup mul exch dup mul add 1 exch sub}.
[0029]
FIG. 10 shows the internal structure of the arithmetic register explaining how the priority is determined for the frequency modulation screen. Here, the determination of the priority order will be described by paying attention to the address value of the grid shown in FIG. 9, that is, (X, Y) = (− 1, 1). First, the X address value (-1 in this case) is stored in the operand stack (a), and then the Y address value (1) is stored (b). Here, the priority order is set on the frequency modulation screen. For randomization, the X and Y address values stored in the register are removed (c to d), the register is emptied, and then a random number is generated by a random number generator inside the computer (e). In this embodiment, random numbers from 0 to 2 ^31-1 (0 to 2147483647) are generated, and a value obtained by dividing the generated random number value by the maximum value 2147483647 (f) is set as one of the priority orders (g ). In this way, priorities are randomly recorded for all the pixels in the required grid, and the XY address values of each grid in FIG. 9 are stored as numerical values from −1 to 1 as shown in FIG. Each pixel is filled in order from the highest priority.
[0030]
In general frequency modulation screens, each manufacturer's unique algorithm is adopted, so output devices are restricted, but in the present invention, any output device based on Postscript can be used, regardless of manufacturer. A hybrid halftone screen can be generated, and a high-quality frequency modulation screen can be obtained. In addition, it does not require investment of extra hardware and software, and can be created simply by determining the algorithm, contributing to cost reduction and effective use of equipment.
[0031]
(Embodiment 2) In the first embodiment, since the priority is assigned to the frequency modulation screen area other than the amplitude modulation screen by random number generation, a value having a higher priority than the amplitude modulation screen may be returned. For example, the thick frame in FIG. 12A shows an amplitude modulation screen, and the outside of the frame shows a frequency modulation screen. In the frequency modulation screen area (X, Y) = (-0.375, -0.375), depending on random number generation, a higher priority (0.99875) than the priority obtained in the amplitude modulation screen area (here 0.96875) And is painted before the amplitude modulation screen as shown in FIG. As a result, undesired noise is generated in the highlight portion, resulting in deterioration of halftone dot quality. Therefore, as shown in FIG. 13 (a), a second variable (for example, 0.2) is added to the priority order (maximum value 1) of the frequency modulation screen, and both are subtracted to give priority to the amplitude modulation screen. Assign a lower value (0.79875) than the rank. By adding the second variable, a priority order is surely assigned from the center of the grid so that an amplitude modulation screen is formed in the highlight portion of the image, and a mechanism in which no fill is generated around is taken. Thus, without generating undesirable noise in the highlight portion, as shown in FIG. 13B, an amplitude modulation screen is generated in the highlight portion of the continuous tone image, and a frequency modulation screen is generated in the shadow portion from the middle. , The quality of the printed matter can be further improved.
[0032]
【The invention's effect】
As described above in detail, in the present invention, the amplitude modulation screen is adopted as a method of eliminating the particle roughness in the highlight portion peculiar to the frequency modulation screen, while the frequency modulation screen is used for fine and precise line drawing expression. By adopting it, high-quality printed matter with printing durability can be achieved. In addition, since this imparting method is defined as a mathematical function and filed, no pre-processing such as image processing is required, so that rapid plate-making processing is possible. In addition, no new capital investment is required, and it can be easily created just by determining the algorithm. Therefore, if it is an output machine that supports PostScript, it can stably supply the same quality regardless of the manufacturer. Can contribute to cost reduction and effective use of equipment. In addition, since the optimum value can be selected according to the printing conditions of the company by changing the variable value, it is very versatile.
[Brief description of the drawings]
FIG. 1 is a diagram showing a halftone dot generation form of an amplitude modulation screen.
FIG. 2 shows an example in which an XY address value is defined for each grid of one halftone dot.
FIG. 3 is a diagram illustrating a state in which a mathematical function is assigned to an amplitude modulation screen and is painted in descending order of priority.
FIG. 4A is a diagram showing an address of an XY grid in 16 × 16 pixels and 256 gradations.
FIG. 4B is a diagram showing the priorities of mathematical functions having an amplitude modulation screen in vertical and horizontal 4 × 4 pixels at the center of FIG.
FIG. 4 (c) is a diagram showing halftone dots of 4 gradations in a vertical and horizontal 16 × 16 pixels, 256 gradations, and a printing dot area ratio of about 2%.
FIG. 5 is a flowchart showing a screen mixing state when the first and second variables are assigned.
FIG. 6 shows a state of an operand stack in an arithmetic register for a method of branching an amplitude modulation screen to a bright portion of an image and branching from a middle portion of the image to a frequency modulation screen in a shadow portion.
FIG. 7 is a diagram showing a state of mixing screens when the first variable is changed.
FIG. 8 is a diagram for explaining an algorithm of an amplitude modulation screen, and shows a state of an operand stack in an operation register for an address of a certain grid.
FIG. 9 shows an example in which addresses are defined for each grid of one halftone dot.
FIG. 10 is a diagram for explaining an algorithm of a frequency modulation screen, and shows a state of an operand stack in an arithmetic register for an address of a certain grid.
FIG. 11 is a diagram showing an example of filling a frequency modulation screen.
FIG. 12 is a diagram for explaining that noise is generated in a highlight portion with only the first variable, resulting in deterioration of halftone dot quality.
FIG. 13 is a diagram illustrating a manner in which noise generation in a highlight portion is removed by adding a second variable.

Claims (2)

Amplitude and frequency modulation when generating continuous-tone images using the Postscript halftone screen generation method, using the amplitude modulation method for bright areas of the image and using the frequency modulation method for the middle to shadow areas. A halftone screen generation characterized in that a value for branching to one of the screens is a first variable, and a halftone dot of an amplitude modulation screen is mixed in the frequency modulation screen by adjusting the first variable Law. A value for giving an advantage to the amplitude modulation screen side is set as a second variable with respect to the priority for filling pixels on the amplitude and frequency modulation screen, and the priority is assigned by adjusting the second variable. The hybrid halftone screen generation method according to claim 1.

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