JPH0614678B2 - Image recording method - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image recording method for recording an image with a dot matrix pattern.

Structure of Conventional Example and Problems Thereof In general, images and videos have relatively low density areas.
However, when copying this, the printer cannot express the low-density region as it is because the dot size of the recording dot is as large as 100 to 200 μm. Therefore, the number of dots is sprinkled to reduce the apparent density. One of the methods is a density pattern method by a dither method using a dot matrix. FIG. 1 shows an expression density range when a dot matrix is used. As can be seen from FIG. 1, the matrix sizes are 4 × 4 matrix 4 to 6 × 6 matrix 3 and 8 × 8.
The larger the matrix 2, the closer the density representation to the original image (image, video) 1 can be made. However, increasing the matrix size lowers the resolution. FIG. 2 shows the resolution for each matrix size. (The dither method shows the minimum resolution for each matrix size.) If the matrix size is reduced to improve the resolution, the low density area cannot be reproduced, and white "blank" appears in the low density area. Further, if the gradation characteristic is improved and the low density area can be reproduced, the resolution is lowered and the image becomes blurred. Because I cannot satisfy both of these at the same time,
Currently, the matrix size (4 x
Image processing is performed using one of 4 to 8 × 8).

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,
The present invention provides an image recording method with good gradation characteristics that enables recording in a low-density area without reducing resolution.

According to the present invention, there is provided a process of preparing an original image on which an image is drawn, and a plurality of elements each of which forms a matrix from a plurality of elements, and the matrix size increases as the density gradation becomes lower. A step of preparing a dither matrix pattern, a step of dividing the image into each pixel, and an element of the first row and first column of a predetermined number matrix of each of the plurality of dither matrix patterns are at the same predetermined pixel position. And a plurality of dither matrix patterns are arranged so as to be repeatedly arranged in both the row and column directions, while making each element of each dither matrix pattern correspond to each pixel of the original image. Applying each element of the pattern to the image, measuring the density of each pixel of the image, and measuring each pixel A suitable one of the plurality of dither matrix patterns is selected for each pixel, corresponding to the density of
The step of directly comparing the density of each pixel measured for each pixel and the size of each element of the dither matrix pattern corresponding to each pixel giving the density using only the selected dither matrix; 1 according to the result
Alternatively, the image recording method includes the step of recording either 0 or 0 for each pixel.

Description of Embodiments Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

According to the experiments conducted by the present inventors, it has been found that the human eye has a property that it is difficult to recognize the decrease in the amount of information in the low density region even if the information amount is slightly decreased, that is, the resolution is slightly decreased. Therefore, consider a case where medium and high densities are reproduced with a 4 × 4 dither matrix and low density regions are reproduced with 6 × 6 and 8 × 8 dither matrices.

FIGS. 3 (a), (b), and (c) are the dither matrix called the spiral type among the dot concentration type in the systematic dither method, and (a), (b), and (c) are They are 4 × 4, 6 × 6, and 8 × 8 dither matrices, respectively.

Since the number of gradations that can be expressed by the 4 × 4 dither matrix is 16, as shown in FIG. 4, the density region of the 4 × 4 dither matrix is divided into 16 equal parts and each region is given a reference numeral of 4 to 19.
If the 16-divided length is extended to the lower density and extended to the lowest density point of the 8 × 8 dither matrix and divided into 16 equal-divided lengths, as shown in FIG. , 3 and 8 × 8 dither matrix can express 1 gradation of the area 1, and a total of 20 gradations with a white background. Figure 5
It becomes like (a), (b), (c). That is, in the 8 × 8 dither matrix (FIG. 5 (c)), the elements [4, 4] ₈ are 1, 6
In the x6 dither matrix (Fig. 5 (b)), the elements [3,
3] ₆ is 2, element [3, 4] ₆ is 3, and in the 4 × 4 dither matrix (FIG. 5 (a)), element [2, 2] ₄ is 4 and element [2, 3] ₄ is 5 , ... Element [4, 1] ₄ becomes 19.

Next, set the value of [(highest density)-(lowest density)] of the original image to 1
Divide into 9 equal parts and number them from 1 to 19 in order from the lowest concentration. This is an A / D converter for the original image signal from the scanner,
This can be easily realized by digitizing each input level.

Next, as shown in FIG. 6 (a), the original image is divided into pixels and the density of each pixel is examined. Pixel I of the original image in FIG. 6 (a)
If the density of (i, j) is, for example, 10, the 4 × 4 dither matrix is applied, and therefore the point I (i, j) corresponds to [3,1] ₄ . On the other hand, [3,1] ₄ = 8 in the 4 × 4 dither matrix of FIG. When the density of the dither matrix element value of FIG. 5 ≦ I (i, j), the original image I
P (i, j of the recording paper of FIG. 6 (b) corresponding to (i, j)
j) The point is 1, that is, if dots are recorded,
In this case, since 8 <10, the P (i, j) point is 1. On the other hand, if the concentration of I (i, j) is 7, [3,1] ₄ =
Since 8> 7, the P (i, j) point becomes 0.

Further, when the density of I (i, j) is 2, the 6 × 6 dither matrix is applied, and the I (i, j) point corresponds to [3,1] ₆ , so 6 × in FIG. 6 dither matrix [3
1] ₆ = 19, 19> 2, and the P (i, j) point becomes 0. When the concentration of I (i, j) is 1, 8 × 8
A dither matrix is applied and I (i, j) points are [7,
5] _8, which corresponds to [7, 5] ₈ = 19 in the 8 × 8 dither matrix shown in FIG. 5, so that 19> 1 and P (i,
j) The point becomes 0.

Now, referring to FIG. 6, pixels I (3,4), I of the original image
Assuming that the densities of (3,5), I (4,4) and I (4,5) are 15,3,1 and 14, respectively, points P (3,4) and P (corresponding to the original image on the recording paper are shown. 3,5) P (4,4), P
(4,5) are 1,0,1,0 respectively according to the above method.
Becomes

By this method, the image information of the original image is recorded on the recording paper as 1 or 0.
That is, the original image can be reproduced by the operation of whether or not to print the dots.

As described above, according to the present invention, a plurality of dither matrix patterns whose matrix size is increased as the density becomes lower is prepared for each density gradation, and each dither matrix pattern is extracted based on the density information extracted for each pixel from the original image. An image recording method in which the density is determined for each pixel and an image is recorded by a dither method using a dither matrix pattern corresponding to the density has the following effects.

(1) It is possible to reproduce the low density area of the original image without lowering the apparent resolution as compared with the current dither method.

(2) Since the image can be processed by almost the same method as the current dither method, the circuit does not become complicated.

[Brief description of drawings]

FIG. 1 is a diagram showing an optical density range of a dot matrix,
FIG. 2 is a graph showing the resolution for each matrix size, FIG. 3 is a view showing a spiral dither matrix of the dot concentration type in the systematic dither method, and FIG. 4 is 4 × 4.
FIG. 5 is a diagram showing a density range obtained by a 6 × 6, 8 × 8 dither matrix, FIG. 5 is a diagram showing a dither matrix in one embodiment of the present invention, and FIGS. 6 (a) and 6 (b) are 3A and 3B are plan views of an original image and a recorded image for explaining the image recording method in the embodiment of the invention.

Claims (1)

[Claims] 1. A process of preparing an original image on which an image is drawn, and a plurality of dither matrices each of which forms a matrix from a plurality of elements and whose matrix size increases as the density gradation becomes lower. A step of preparing a pattern; a step of dividing the image into pixels; an element of a first row and a first column of a predetermined number matrix of each of the plurality of dither matrix patterns is arranged at a predetermined same pixel position; In addition, each element of each dither matrix pattern is made to correspond to each pixel of the original image so that the plurality of dither matrix patterns are repeatedly arranged in both the row and column directions. Applying each element to the image; measuring the density of each pixel of the image; Corresponding to, a step of selecting an appropriate one of the plurality of dither matrix patterns for each pixel, and using only the selected dither matrix, the density of each measured pixel for each pixel, An image recording method comprising a step of directly comparing the size of each element of the dither matrix pattern corresponding to each pixel giving the density and a step of recording either 1 or 0 for each pixel according to the comparison result. .