KR0152736B1 - Monocome image generation method - Google Patents

Abstract

The present invention relates to a monochrome image realization system, and in particular, to improve the method of realizing the degree of shading of monochrome images, such as halftone, to obtain a high resolution even at an output device having a relatively low output resolution as well as to work at the same resolution. The present invention relates to a monochrome image realization method for increasing efficiency.

The present invention allows continuous output by giving an upper space and a lower space to an area occupied by one pixel, averaging a certain number of lines to be output to one line, and closing the closed curve with the correlation and mathematical information of the pixels of the output line. By approximating, the output efficiency can be improved, and when multiple output lines are represented by two lines, the resolution can be increased by inverting the second line instead of two separate lines and combining the first line into one line. .

Description

How to implement monochrome image

1 is an exemplary view for explaining a conventional method of implementing a monochrome image.

2 is a flowchart of a monochrome image implementation process for explaining FIG.

Figure 3 is another embodiment for explaining a conventional monochrome image implementation method.

4 is a block diagram of a monochrome image system to which the present invention is applied.

Figure 5 is a first embodiment for explaining a method of implementing a monochrome image of the present invention.

Figure 6 is a second embodiment for explaining a method of implementing a monochrome image of the present invention.

7 is a third embodiment for explaining a method of implementing a monochromatic image of the present invention.

8 is a fourth embodiment for explaining a method of implementing a monochromatic image of the present invention.

9 is a flowchart illustrating a process of implementing a monochrome image to explain FIG. 5.

10 is a flowchart illustrating a process of implementing a monochrome image for explaining FIG. 6.

11 is a flowchart illustrating a process of implementing a monochrome image for explaining FIG. 7.

12 is a flowchart illustrating a process of implementing a monochrome image for explaining FIG. 8.

13 is a pattern diagram of a monochrome image according to the present invention.

14 is a flowchart for explaining FIG.

15 is a work flow chart for image emphasis and special effects according to the present invention.

* Explanation of symbols for main parts of the drawings

2: Image input unit 3: Image processing unit

4 image output unit 5 output member

The present invention relates to a monochrome image realization system, and in particular, to improve the method of realizing the degree of shading of monochrome images, such as halftone, to obtain a high resolution even at an output device having a relatively low output resolution as well as to work at the same resolution. The present invention relates to a monochrome image realization method for increasing efficiency.

Normally, a monochrome image, such as a black and white photograph, is a set of pixels having a shade level (abbreviated as GL hereinafter) to complete a picture.

At this time, the digitalized monochrome bitmap image input to the computer is not a problem in the output device having a relatively high output resolution such as a laser printer, but a cutting plotter or a computer controlled automatic control device having a relatively low output resolution, In engraving robots that process plastic plates, stone, and glass, resolution and work efficiency are raised depending on how they are implemented.

The brightness level of the pixel of the monochrome image is stored inside the computer as one of N predefined shade levels when input to the computer.

When these pixels are output from a monochromatic output device, their shades are the ratio of white to black on the area (typically square or circle) occupied by one pixel on the output surface (paper, plastic, stone, etc.).

FIG. 1 illustrates a conventional monochrome image implementation process for implementing a monochrome image. As shown in (a), the GL (x, y) of the pixel at the (x, y) position is 0 (maximum black). Color) to 10 (maximum white) (N = 11), if the shadow degree is 4, then outputting white on a black background produces an area ratio of white to black within the area of one pixel. Is 40%.

At this time, the area corresponding to the white color at the time of output may be formed as one or several figures such as a rectangle, a strip, a circle, and a polygon as shown in (b) to (i) of FIG. 1.

Conversely, the method of implementation is the same when outputting in black on a white background.

FIG. 2 is a process for implementing a monochrome image with one or several figures as described above. First, the stored image information is selected.

Thereafter, when the stored image information is selected, parameters related to the output are input.

That is, the parameters related to the output include the size of the screen to be output, the type of the output device, the size and variable of the split output in the split output, the output method, the selection of the continuous reference line for the horizontal / vertical and the curve, the output target color and the output color. And so on.

When the input of the parameters related to the output is completed as described above, the output preparation operation is performed to the next step.

At this time, since the monochrome image to be implemented is the same as the first diagram, the shape of the figure (circle, ellipse, polygon, etc.) to express the degree of shading is selected, the number of figures to be output is selected, and the position pattern of the figure. Will be selected.

As described above, when the output preparation is completed, the pixels on the I-th line are read from the pre-stored image information with the line number I to be output set to 1.

Subsequently, an area is calculated to express the degree of shadow for each pixel from the read image, and the calculated degree of shadow expression lines are output to the output device to implement a monochrome image.

After that, the line number to be output is increased by 1 (I = I + 1) to realize the degree of shading of the next line, and as described above, the pixels of the I + 1th line are read from the stored image information, After calculating the area for implementation, it outputs to the output device to implement a monochrome image.

In this way, when the output of all lines to be output while the monochrome image is implemented is completed, the process of implementing the monochrome image is terminated.

As such, in the related art, as illustrated in (a) to (c) of FIG. 3, pixels arranged in a straight line or a curve having horizontal, vertical, or any angle are outputted pixel by pixel without considering correlation. Was used.

That is, as shown in (a) of FIG. 3, when the image has a shadow degree of 0,1,2,3,1,0,0,1,3,2,1,1, and the like, a single rectangle is formed. If this is expressed using a pattern like (b).

At this time, the line that is actually cut or carved is the same as (c).

However, in the case of outputting the shadow degree independently of the low resolution and low speed output device as described above, the output speed is slowed when printing the entire image, and thus there is a problem that the work efficiency is greatly reduced.

In addition, when the degree of shading of the pixel is 10 or 0, the degree of shading is impossible, and thus, continuous operation is impossible. In addition, the low resolution output device has a problem that is difficult to implement.

Therefore, the present invention is to solve the above problems of the prior art, an object of the present invention is to improve the shading degree of the monochrome image, such as the conventional halftone (halftone) output device having a relatively low output resolution In addition to providing a high resolution as well as to provide a monochrome image implementation method to increase the work efficiency at the same resolution.

Another object of the present invention is to increase the output speed and increase the working efficiency by continuously outputting pixels lined up in a straight line or a curve having horizontal, vertical or any angle in consideration of the correlation. The present invention provides a method for implementing a monochrome image.

Hereinafter, described in detail with reference to the accompanying drawings of the present invention.

4 is a block diagram of a monochrome image system to which the present invention is applied. The image unit 1 provides an image for realizing a color image or a monochrome image, and the image provided from the image unit 1 includes an image processor 3. 2) an image input unit 2 for inputting the image, an image processor 3 for outputting a high resolution image by processing an image input from the image input unit 2, and an image obtained by the image processor 3 to the outside. It consists of an image output unit 4 for output and an output member 5 processed by the image information output from the image output unit 4.

Referring to the attached monochromatic image system to which the present invention configured as described above is applied, the monochromatic image implementation process of the present invention will be described with reference to FIGS. 5 to 15 as follows.

First, if the pixels lined up as shown in (a) of FIG. 3 are represented by continuous rectangles, a pattern as shown in (a) of FIG. 5 can be obtained according to the degree of shading. As shown in (b), a continuous monochrome image is implemented.

The process of realizing such a continuous monochrome image is shown in FIG.

As shown in the drawing, stored image information is selected and parameters related to output are input.

Here, the parameters related to the output include the size of the screen to be output, the type of output device, the size and variable of the split output in the split output, the output method, the selection of the continuous reference line for the horizontal / vertical and curve, the output target color, and the output color designation. Becomes

When the input of the parameters related to the output is completed as described above, the output preparation operation is performed to the next step.

At this time, the output preparation work selects the top and bottom line shape of the area for expressing the degree of shading (straight line, curve), and selects the reference line (bottom line, center line, and top line) of the output area.

The line number I to be output is set to 1, and the shadow information of the pixels on the I-th line is read from the pre-stored image information.

Subsequently, the pixels are searched for disconnection points in the lined pixels, and one closed curve to be output in association with successive pixels is output to the output device.

Thereafter, the number of lines to be output is increased by 1 (I = I + 1) to implement the degree of shading of the next line, and as described above, the degree of shading of the pixels on the I + 1th line is read from the previously stored image information. .

After searching the disconnected points of the pixels in line, a closed curve to be output in association with successive pixels is calculated and output to the output device.

In this process, if the output lines are output while the monochrome image is implemented, the monochrome image implementation process is terminated.

When the monochrome image is implemented as described above, the total moving distance of the output device is shortened as compared with the conventional embodiments described above. When outputting to the adhesive sheet using the cutting plotter, the final shading degree is cut and cut for the next work. Since the sheet paper should be removed, the working efficiency can be increased.

On the other hand, in order to solve the case that the continuous shading degree is impossible when the degree of shading is 10 or 0 in the prior art as shown in FIG. / max _(min GL, GL _max) gave a margin of the above interval (d * _upper) and bottom distance (d _lower) so as not to cut off the pixels are outputted in between.

In addition, by setting the minimum and maximum degree of shadow (GL ^* _min , GL ^* _max ) at the time of output, continuous output is possible even if it is slightly different from the actual image information. Alternatively, the degree of shading of pixels lined up on the curve is continuously output.

If this is expressed as an expression, it is as follows.

If the degree of shadowing of the pixel at the (x, y) position is GL (x, y), it is within the range of GL _min ≤ GL (x, y) ≤ GL _max , but the maximum and minimum size for continuous output When limiting such as GL _min ≤ GL ^* _min , GL _max ≤ GL ^* _max , the changed shading degree GL ^* (x, y) is expressed as GL ^* _min ≤ GL ^* (x, y) ≤ GL ^* _max .

Such a reduction in the degree of shading may be implemented through a method such as reconstruction of the histogram through the limitation of the histogram of the image processing technique, but it may be calculated by the following simple equation ignoring the error.

GL ^* _min ; when GL (x, y) ≤GL ^* _min

GL ^* (x, y) = GL (x, y); when GL ^* _min GL (x, y) GL ^* _max

GL ^* _max ; when GL (x, y) ≤GL ^* _max

If the upper and lower intervals are given to the degree of shadow of the pixel, the pattern of the image to be output is as shown in (d) of FIG.

When such an image pattern is output, continuous output can be obtained as shown in FIG.

However, when the image pattern is continuously output as shown in (d), the output device performs the step-shaped movement, and the speed thereof decreases.

Therefore, by applying mathematical theory instead of staircase using the continuous P shadows and additional sub shadows, approximating a large number of curves using Bezier, Spline curves or Polynomial lnterpolation. It becomes smooth and smooth curve like g), but the points used in this approximation can be used for the approximation using any number of lighting points located between the center point, front or end point, and between one bar graph. .

In this case, the fastest output method is to connect the midpoints of the same area as a bar graph indicating the degree of shadowing of each pixel in a straight line as shown in (f).

In this case, the error can be greatly reduced by using the concept of the same area as the (h) of FIG. 6 for the starting pixel and the ending pixel.

So far, the description is based on the method of expressing the top of the baseline according to the degree of shading of one pixel in the line having a long rectangular area representing the output shading degree, based on the bottom line as the baseline. As shown in (j), the reference line may be the upper line or may be expressed up and down with the center line as the reference line, and any line (straight line or curve) in the area may be used as the reference line.

FIG. 10 illustrates a process of implementing a monochrome image to allow continuous output by giving the upper and lower intervals of the pixel as described above.

As shown therein, the stored image information is selected, and output related parameters are input.

Here, the parameters related to the output include the size of the screen to be output, the type of output device, the size and variable of the split output in the split output, the output method, the selection of a continuous reference line (horizontal, vertical, and other curves), the output target color, and the output color designation. Becomes

The next step is to enter the top and bottom spacing for continuous output, select the line shape (straight and curved) for efficient output, and enter the parameters for straight lines and curves.

In the above, the straight line and curve related parameters are the center connection, the connection line selection, the degree of the curve, and the like.

In addition, the baseline (base line, center line, upper line) will be selected.

In this process, when the preparation for output preparation is completed, the line number I to be output is set to 1, and the pixels on the I-th line are read from the previously stored image information.

In the next step, the shadows of the pixels on the I-th line are adjusted to be within the upper and lower intervals, and the mathematical information of the line to be output is obtained by considering the front and back correlations of the pixels for the continuous output of the I-th line, and approximated by one closed curve. .

Thereafter, the approximated closed curve image information is output to the output device.

In addition, the line number I to be output for the output of the next line is increased by 1 (I + 1), and as described above, the pixels on the I + 1th line are read from the previously stored image information.

The next step is to readjust the shadows of pixels on the I + 1th line to be within the top and bottom intervals, and obtain the mathematical information of the line to be output by considering the front and back correlation of the pixels for the continuous output of the I + 1th line. Approximate to closed curve.

Thereafter, the approximated closed curve image information is output to the output device.

In this process, the monochromatic image is continuously implemented, and when the output of all the lines is completed, the monochromatic image is finished.

However, this continuous output method basically implements the degree of shading of pixels on one continuous line. When a horizontal line is selected as a baseline and the above method is applied, a single line is cut or manipulated by one horizontal line of the image. Will be generated.

Therefore, assuming that the size of the output image is fixed, increasing the horizontal and vertical pixel numbers H and V, which determine the resolution of the output image, increases the number of horizontal lines to be output, thereby greatly increasing the working distance of the output device. In the case of removing sheet paper, the number of lines to be removed is also greatly increased, thereby reducing work efficiency.

In addition, the resolution of the original image is limited due to the low resolution of the output device and the limitation of the minimum unit for cutting and manipulating.

In the case of using the horizontal direction, for example, the removal of sheet paper requires that the height of at least one horizontal pixel to be output is at least twice the minimum spacing (actually, since there must be a d _lower distance from the _upper gap). Top gap + bottom gap + height for shading).

To solve this problem, the same method as in FIG. 7 is used.

For example, if you have an original image with a horizontal pixel H and a vertical pixel V, and output it, the cutting plotter will have V lines to be removed on the sheet of paper.

In this case, an example of one horizontal line is shown in Fig. 7A.

At this time, if M and V images are output in the same output size in the horizontal and vertical directions to increase the output resolution, M * V lines to be removed are formed on the sheet.

At this time, the height of each line is reduced to 1 / M as shown in (b), but since the interval for continuous output has a minimum value, the area for expressing the degree of shading and the restriction of the selection of the M value is also reduced accordingly.

However, when outputting images of M times horizontally and M times vertically (M ^{2 in} terms of area) at the same resolution as the original image, M horizontal lines are averaged in the vertical direction and considered as horizontal lines. As shown in (c) of FIG. 7, the horizontal resolution is the same as the original image, but the image is increased by M times in the vertical direction.

Since there are only M lines to be removed as in the original image, the removal work is the same as the output of the original image.

In addition, in the original image output, each line had to have a top and bottom gap, but in this case, only one top and bottom gap is required for M lines, thereby increasing the area for expressing the degree of shading.

In addition, the upper and lower intervals for the continuous cutting operation can be further reduced to facilitate the operation.

The process for implementing this is shown in FIG.

First, pre-stored image information is selected and output related parameters are input.

Here, the output-related parameters include the size of the screen to be output, the type of output device, the split output size and variable in splitting output, the output method, the selection of continuous reference lines (horizontal, vertical, and other curves), the target color and the output. It becomes color designation.

Then, input the up and down intervals for continuous output for the output preparation work, select the line shape (linear, curve) for efficient output, and input the parameters for the straight line and the curve.

In the above, the parameters related to the straight line and the curve are the center connection, the connection line selection, the degree of the curve, and the like.

Then, select the baseline (underline, centerline, and hypocrisy), and enter the M value for how many lines are averaged and expressed as a single line.

When the output preparation operation is completed by this process, the line number I to be output is set to 1, and the pixel values from the I th line to the (I + M-1) th line are read from the previously stored image information.

In the next step, the shading degree information of these M lines is averaged and set as one I-th line, and the shadow degree of pixels on the set I-th line is readjusted so as to be located within the upper and lower intervals.

Subsequently, the mathematical information of the line to be output is obtained in consideration of the front-rear relations of the pixels for continuous output of the I-th line, and then approximated to one closed curve.

Then, the approximated closed curve image information is output to the output device, and the line number to be output for the image output of the next line is increased by 1 (I + 1), and the image of all the lines is output in the same manner as described above. It is to be made.

This method greatly improves the output resolution for the same throughput.

In order to further increase the output resolution, a monochromatic image implementation method as shown in FIG. 8 is added.

That is, if the method of using the bar graph for the M times the image information described above, for example, the output of two successive horizontal lines using the basic method is the same as in Fig. 8 (a) of Fig. 8 (b) When 2 * M lines are expressed as two lines, as shown above, if the second line is reversed and combined with the first line instead of two separate lines, the degree of shading of the two is combined.

Thus, when cutting and engraving, 2 * M lines are represented by one line instead of two, and the total number of horizontal lines is cut in half, thereby doubling the work efficiency at almost the same resolution.

In addition, the resolution of the horizontal and vertical 2 * M times using the image and, 2 * M of Creating a single output line per lines in the area concept (2 * M) using the image with a resolution of ^two times the output resolution of the Is increased by about 2 * M times.

The process of implementing this is shown in FIG.

That is, the stored image information is selected and output related parameters are input.

Here, the parameters related to the output are as described above, the size of the screen to be output, the type of output device, the size and variable of the split output in the split output, the output method, the selection of continuous reference lines (horizontal, vertical, and other curves), the target color of the output, Output color is designated.

The next step is to enter the top and bottom spacing for continuous output for output preparation and select the line type (straight, curved) for efficient output.

Then, the center connection, the connection line selection, the degree of the curve are input as parameters related to the straight line and the curve, the reference line (underline, center line, upper line) is selected, and the M value for how many lines are averaged and expressed as one line. Enter to complete the output preparation.

Thereafter, the line number I to be output is set to 1, and pixel values from the I th line to the (I + 2) * (M-1) th line are read from the image information.

Then, the average of M line shading information from I to I + (M-1) th is averaged and calculated as the shading information of one I line, and from (I + M) to (I + 2) * (M- 1) M line shading information up to the first is averaged and calculated as shading information of one (I + 1) th line.

Subsequently, the shadows of the pixels on the I-th and (I + 1) -th lines are readjusted to be within the upper and lower intervals.

Then, the mathematical information of the line to be output is obtained in consideration of the front and rear correlations of the pixels, and the shadow information of the upper part of the approximated closed curve to be finally output is calculated to set image information for continuous output of the I-th line.

Subsequently, the mathematical information of the line to be output is obtained in consideration of the front and rear correlations of the pixels for the continuous output of the (I + 1) th line, and the shadow information of the lower portion of the approximated closed curve to be finally output is calculated.

The image information corresponding to the approximated closed curve thus calculated is output to the output device to increase the resolution to realize a monochromatic image, hereinafter to the next output line (I = (I + 2) * (M-1)). Will print all lines of.

FIG. 13 is a diagram of another embodiment of the present invention, in which the above-described monochromatic image implementation methods are combined according to a special purpose and a rendering effect.

That is, a plurality of methods are mixed and outputted to output successive pixels on predetermined reference lines.

In addition, a combination of various shapes (circles, ellipses, rectangles, polygons, etc.), not horizontal and vertical lines, is outputted by a predetermined reference line arrangement pattern, thereby exhibiting an overall special effect.

As an example, when the connecting line defining the pixels connected as (a) is a circle, this is a circle connecting the 2 * 2 elements in a circle, and since this is a repeated form, the shading degree is square as shown in (b). It is approximated to enable continuous output using and output is made by using connecting line.

In addition, even when the connecting lines defining continuous pixels such as (c) and (e) are circles, squares, and polygons, the three output methods are used in combination to continuously output a special output pattern such as (d) and (f). You get

Meanwhile, as shown in (g), the last method described above (see FIG. 12) when M = 1 is applied to two a-type connecting lines, and the last method described above for one square-type closed connector (Fig. 12). ), You get an output pattern like (h).

The process for implementing this is shown in FIG.

First, stored image information is selected, and output related parameters are input.

In this case, as described above, the output-related parameters include the size of the screen to be output, the type of output device, the size and variable of the split output when splitting the output, the output method, the selection of a continuous reference line (horizontal, vertical, and other curves), the target color of the output, Output color is designated.

The next step is to enter the top and bottom gaps for continuous output and select the connecting line pattern to prepare the output.

Thereafter, the connecting line patterns are efficiently arranged to form a composite pattern.

Then, input M value about how many lines are averaged in the direction of connecting line and express as one line, apply complex pattern to the image, determine the number and output order of total connecting lines (output reference line), and complete the output preparation work. Done.

Thereafter, the line number I to be output is set to 1, and pixel values related to the I-th connection line are read from prestored image information.

In addition, the pixels on the connection line are processed according to the input M value to form an I-th line of increased resolution.

Then, the shadow degree of the pixels on the I-th line is readjusted so as to be within the upper and lower intervals, and the mathematical information of the line to be output is obtained in consideration of the relationship between the pixels before and after, and the shadow information of the approximated closed curve to be finally output is calculated. Image information for continuous output of the first line is set.

The image information corresponding to the approximated closed curve thus calculated is output to the output device to increase the resolution to realize a monochrome image, and to output the image of the next output line (I + 1). The pixel values are read from pre-stored image information.

In addition, the pixels on the connection line are processed according to the input M value to form an I + 1th line of increased resolution.

Then, the shadowing degree of pixels on the I + 1th line is readjusted to be within the upper and lower intervals, and the mathematical information of the line to be output is calculated in consideration of the front and rear correlations of the pixels to calculate the shadow information of the approximated closed curve to be finally output. To set the video information for the continuous output of the I + 1th line.

In this way, the image information corresponding to the approximated closed curve is output to the output device to increase the resolution to realize a monochromatic image, and to repeat the above process from the following connection line to the last connection line. It will be output as a monochromatic image.

Meanwhile, although the degree of shadowing of an image may be expressed using the above-described monochromatic image implementation method, there is a case in which the degree of shadowing of an image is weak depending on the material of an output used.

To compensate for this weakness, a work flow chart is added as shown in FIG. 15 to give a special effect to the emphasis of the image or the degree of shading of the expressed image.

That is, as shown in FIG. 14, after processing the output object 100 using the above-described monochromatic image implementation methods, the primary color material 101 having different colors for image emphasis and special effects is processed on the processed surface. Inject or spray or apply.

In addition, when the first color material 101 is injected, sprayed or applied, the second color material 103 is injected, sprayed, or coated with another color on the unprocessed surface, and the two colors are contrasted. Can make the highlight and special effects.

The use of a mask material can simplify the task depending on the type of workpiece and color material.

For example, when engraving images using tiles or stones as output objects, the contrast between the processed and unprocessed surfaces may not be clear.In the case of stones, if the water penetrates into the processed surface, the brightness contrast may be It tends to be greatly reduced.

To prevent this, print a monochrome image on an adhesive sheet (vinyl film) using a cutting plotter, remove unnecessary parts, attach it to the stone material, and process the stone by sand blasting (Sand Blasting), etc. Since the adhesive sheet paper when coloring the material 101 acts as a mask during coloring as well as a masking effect during processing, the processed surface can be easily colored.

When the adhesive sheet is removed after coloring of the primary color material 101, the unnecessary primary color material is also easily removed, and then, depending on the purpose, the secondary color material 102 is simply rolled onto the unprocessed portion of the output object. By coloring, you can get image enhancement and special effects.

As described above, the present invention can provide continuous output by giving an upper interval and a lower interval of pixels when the degree of shading is implemented, and has the effect of increasing the resolution and improving the working efficiency at the same resolution.

In addition, it is possible to implement a combination of monochromatic images, so it is possible to implement a special pattern according to the surrounding conditions such as the overall image feeling and the installation place.

Claims (8)

Selecting pre-stored image information and retrieving the presence or absence of input of each parameter for continuous output when output related parameters are input; Setting a line number to be output when each parameter for continuous output is inputted as a result of the search; A third step of reading a pixel corresponding to the set output line from previously stored image information and readjusting the shadow of the output line pixel to be within an upper and lower intervals; A fourth process of approximating the pixels of the line to be output to one closed curve in consideration of front and rear correlations between the pixels of the output line; Output the approximated closed curve image information to the output device, and repeat the third process and the fourth process to realize the monochrome image of the next line, and output the image information of all the output lines to the output device to realize the monochrome image. Monochromatic image implementation method comprising the fifth step. The method of claim 1, wherein the first process comprises: a first step of searching for presence or absence of input of up and down intervals for continuous output when an output related parameter is inputted; A second step of searching for a selection of a straight line or a curved line for efficient output of the image information; A third step of searching for the presence or absence of input of straight line and curve related parameters; And a fourth step of searching for a selection of a reference line. 3. The method of claim 2, wherein the linear and curve related parameters of the third step are center connection, association line selection, and curve order. Selecting pre-stored image information and retrieving the presence or absence of input of each parameter for continuous output when output related parameters are input; Setting a line number to be output when each parameter for continuous output is inputted as a result of the search; A third step of reading pixels of the last output line for representing one line from the pixels corresponding to the set output lines from previously stored image information; A fourth process of averaging the shaded information of the read pixels and calculating the degree of shading of the first output line; A fifth step of adjusting the shadow degree of the pixel of the output line so as to be positioned within an upper and lower interval; A sixth process of approximating the pixels of the line to be output to one closed curve in consideration of the front and rear correlations of the pixels of the output line; The output device outputs the calculated image information of the closed curve, reads the pixel of the next output line and the pixel of the last output line for the expression of one line from the stored image information. And a seventh process of repeatedly outputting image information of all output lines to an output device to implement a monochrome image. The method of claim 4, wherein the first process comprises: a first step of searching for an input of an up / down interval for continuous output when an output related parameter is input; A second step of searching for a selection of a straight line or a curved line for efficient output of the image information; A third step of searching for the presence or absence of input of straight line and curve related parameters; A fourth step of searching for whether a baseline is selected; And a fifth step of searching for an input of an average line value (M) to determine how many lines are averaged into one line. Selecting pre-stored image information and retrieving the presence or absence of input of each parameter for continuous output when output related parameters are input; Setting a line number to be output when each parameter for continuous output is inputted as a result of the search; A third step of reading pixels of the last output line for representing one line from the pixels corresponding to the set output lines from previously stored image information; Average the shaded degree information of the read pixel of the set output line to set the shaded degree of the first output line, and averages the shaded degree information of the pixel of the last output line for the representation of one line from the pixel of the second output line A fourth step of setting the shadow degree of the second output line by using the second step; A fifth step of adjusting the shadow degree of the pixel of the output line so as to be positioned within an upper and lower interval; A sixth process of approximating the upper part with one closed curve in consideration of the front-rear relations of the pixels of the first output line; A seventh process of approximating the lower part of one closed curve in consideration of the front and rear correlations of the pixels of the second output line; Outputting the image information of the closed curve approximated up and down as one line of image information, and reading the pixel of the next output line and the pixel of the last output line for the representation of one line from the prestored image information, And an eighth process of repeating the fourth and seventh processes to output image information of all output lines to an output device to implement a monochrome image. Selecting pre-stored image information and retrieving the presence or absence of input of each parameter for continuous output when output related parameters are input; Setting a line number to be output when each parameter for continuous output is inputted as a result of the search; Reading pixel values on the connection line of the set line from previously stored image information; A fourth step of processing the pixels on the connection line according to a line average value and setting the set line to an increased resolution; A fifth step of adjusting the shadow degree of the pixels on the set line so as to be positioned within an upper and lower interval for continuous output; A sixth step of extracting the image information of the closed curve to be finally output in consideration of front and rear correlations between the pixels of the setting line and outputting the extracted image information to the output device; And setting a next output line and repeating the third to sixth processes to output image information of all lines to be output to an output device. 8. The method of claim 7, wherein the first process comprises: a first step of searching for presence or absence of input of up and down intervals for continuous output when an output related parameter is inputted; A second step of searching whether a connection line pattern is selected for efficient output of image information; A third step of rearranging the connection line patterns to form a composite pattern; A fourth step of searching for the presence or absence of input of an average line value (M) to determine how many lines are averaged and made into one line; And a fifth step of applying a complex pattern to the image and searching for the total number of connection lines as the output reference line and whether the output order is input.