JPH07312677A - Image recording method - Google Patents

Abstract

PURPOSE:To effectively suppress color moire by forming an arranging pattern provided with desired resolution in a sub scanning direction by varying a dot arranging period in the sub scanning direction by a desired magnification. CONSTITUTION:The arranging pattern in which the dot arranging period in the main scanning direction of dots Y and C provided with prescribed dot arranging period in the sub scanning direction is doubled and the resolution in the main scanning direction is reduced to 1/2 is used. In such a way, a pattern for each color is superimposed. A moire period can be dispersed by combining the arranging pattern in which the resolution in the main scanning direction is reduced, thereby, striping moire can be avoided. Also, such arranging pattern can be employed for one, two or three colors out of four colors. Also, the resolution in the main scanning direction is reduced to 1/2, and also, is set at dot unit as 1/3 or 1/4, which displays respective effect. Such conditions can be set by recording images.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image recording method capable of displaying multi-color multi-gradation by changing dot period.

[0002]

2. Description of the Related Art As means for obtaining multi-color and multi-gradation recording, for example, halftone dot gradation expression in which each halftone dot area is changed according to gradation to express a desired gradation can be mentioned. In this case, halftone dots of each color having the same shape are overlapped and recorded in order to support multicolor recording. However, if there is a misregistration between records,
This causes color moire.

In order to avoid the above color moire, it is possible to deal with it by improving the mechanical accuracy, but since technical difficulties are involved, in the field of offset printing and the like, by changing the halftone dot angle for each color. , Avoiding color moire. That is, while the dots are regularly arranged in a grid pattern, the arrangement angle of the dots with respect to the main scanning direction is, for example,
It is changed to 15 °, 30 °, 45 ° or 75 °.

Further, by adopting so-called FM screening in which halftone dots of a predetermined size are randomly arranged according to gradation,
There is also a means for suppressing color moire with random halftone dots that do not have directionality for each color. When the resolutions in the main scanning direction and the sub-scanning direction can be set smaller than the unit pixel, each of the above means can effectively suppress the occurrence of color moire.
However, in a line head such as a thermal head, a liquid crystal head, an LED (light emitting diode) head, or an EL (electroluminescence) head, in which the resolution in the main scanning direction is defined by the size of the recording element and set to approximately unit pixels, The degree of freedom in changing the dot arrangement is limited to the sub-scanning direction. Therefore, moire fringes cannot be effectively suppressed.

In order to solve the above situation, Japanese Patent Laid-Open No. 5-1
A color image recording method disclosed in Japanese Patent No. 5507 has been proposed. That is, the pixels of the three primary colors are shifted in the sub-scanning direction by about 1/2 pitch so that they are not aligned in the main scanning direction, and for one of the three primary colors, the pixel density in the sub-scanning direction is 1 / 2, the color patterns in two adjacent columns are kept in a complementary color relationship even if a registration shift occurs. Therefore, the color tone does not change as a whole, and the color unevenness can be made inconspicuous.

[0006]

As described above, various means have been proposed in order to avoid color moire during multi-color multi-gradation recording. However, even when the arrangement angle of halftone dots is changed to express multiple colors and multiple gradations, it is not possible to avoid the occurrence of color moire called a rosette pattern, which causes roughness.

Further, according to the color image recording method disclosed in Japanese Patent Laid-Open No. 15507/1993, color moire can be effectively suppressed in the case of three colors even when the resolution in the main scanning direction is limited. Although it is possible, it is impossible to avoid color moire that occurs when recording multi-color and multi-gradation by the four-color separation that is widely used in printing. So this invention
The present invention has been made in view of the above circumstances, and an object thereof is to provide an image recording method capable of effectively suppressing color moire even when the resolution in the main scanning direction is structurally fixed.

[0008]

In the image recording method according to the present invention, a head having a plurality of recording elements arranged in the main scanning direction is moved in the sub scanning direction, and the density or area of each pixel is changed according to the image density. While changing the rate, yellow,
An image recording method for recording a multicolor image by combining each color of magenta, cyan, and black, wherein one color is recorded in a regular array pattern with a constant dot period, and the dot period in the sub-scanning direction is At least two colors are recorded with different non-integer multiple patterns. Alternatively, by moving a head in which a plurality of recording elements are arranged in the main scanning direction in the sub scanning direction, the density or area ratio of each pixel is changed according to the image density, and yellow, magenta, cyan, and black colors are changed. An image recording method for recording a multicolor image in combination, comprising:
The dot cycle ratios of magenta, cyan, and black in the sub-scanning direction are set to 1: 3/4: 3/5: 1/2 in any order. Alternatively, a head having a plurality of recording elements arranged in the main scanning direction is moved in the sub scanning direction,
An image recording method in which the density or area ratio of each pixel is changed according to the image density, and a multicolor image is recorded by combining each color of yellow, magenta, cyan, and black. The dot arrangement cycle in the main scanning direction is set in dot units in order to reduce the resolution in the main scanning direction of the required dots among the dots of each color whose dot cycle ratio in the sub-scanning direction for each color is set to a different non-integer multiple for each color. Can be changed with. Alternatively, by moving a head in which a plurality of recording elements are arranged in the main scanning direction in the sub scanning direction, the density or area ratio of each pixel is changed according to the image density, and yellow, magenta, cyan, and black colors are changed. An image recording method for recording a multicolor image in combination, in which each color is recorded in a pattern in which dot periods are randomly arranged in the sub-scanning direction. Alternatively, by moving a head in which a plurality of recording elements are arranged in the main scanning direction in the sub scanning direction, the density or area ratio of each pixel is changed according to the image density, and yellow, magenta, cyan, and black colors are changed. An image recording method for recording a multicolor image in combination,
One color is recorded in a normal arrangement pattern having a fixed dot period, and the other color is recorded in a pattern randomly arranged in the sub-scanning direction. Alternatively, by moving a head in which a plurality of recording elements are arranged in the main scanning direction in the sub scanning direction, the density or area ratio of each pixel is changed according to the image density, and yellow, magenta, cyan, and black colors are changed. An image recording method for recording a multicolor image in combination, wherein yellow is recorded in a pattern in which dot periods are randomly arranged in the sub-scanning direction, and dot periods in the sub-scanning direction are set to different non-integer multiples. It records recording of magenta, cyan and black in a pattern. Alternatively, while moving a head in which a plurality of recording elements are arranged in the main scanning direction in the sub scanning direction, the density or area ratio of each pixel is changed according to the image density,
An image recording method for recording a multicolor image by combining each color of yellow, magenta, cyan and black, wherein a dot period ratio in the main scanning direction and a dot period ratio in the sub-scanning direction of each color of yellow, magenta, cyan and black The combination of (3 / 1.5, 3/3), (3/3, 3 /
4), (3 / 1.5, 3/5), and (3/3, 3/6). By moving the head, in which multiple recording elements are arranged in the main scanning direction, in the sub scanning direction, the density or area ratio of each pixel is changed according to the image density, and yellow, magenta, cyan, and black colors are combined. An image recording method for recording a multicolor image,
The combination of the dot period ratio in the main scanning direction and the dot period ratio in the sub-scanning direction for each color of yellow, magenta, cyan, and black is (3 / 1.5, 3/3), (3 / 1.5,
3/5), (3/3, 3/4), and (3/3, 3/6). Further, a resolution conversion process for converting the combination by sub-scanning direction resolution of each color of yellow, magenta, cyan, and black having a predetermined resolution, and a mask having a predetermined pattern for each resolution-converted color. And the masking process for extracting the gradation image data of each color by setting the value of the gradation data of the pixel that overlaps the predetermined pattern among the pixels to 0 and sequentially performing the masking processing in a predetermined row cycle. is there. further,
After the resolution conversion process, the gradation process of allocating the gradation of each color pixel to the sub-matrix arranged in units of two pixels in the sub-scanning direction, and the gradation process of each pixel in one of the stages before and after the mask process. It includes a cancel process for canceling a predetermined number of lower bits of the data. Further, the number of the sub-matrices is determined according to the value of the gradation data. Further, the masking process extracts the gradation data of the maximum value for the image having the maximum value of the gradation data.

[0009]

According to the above-mentioned means according to the present invention, in image recording by a head in which a plurality of recording elements are arranged at a predetermined pitch, the dot period in the sub-scanning direction is shortened by a desired magnification, thereby An array pattern having a desired resolution is formed. As a result, the resolution in the sub-scanning direction is changed, and color moire is suppressed. As for the magnification set in the sub-scanning direction, the required magnification is set for each color, one color is recorded in the normal arrangement pattern with the magnification set to 1, and the other color is recorded.
The pattern is set to a non-integer magnification for the one color.

That is, when forming a four-color separated image,
For example, Y is recorded in a regular array pattern, and M, C and K are recorded.
Are recorded with different non-integer multiple patterns with respect to Y. In this case, the magnification ratio of each color is Y: M: C: K = 1: s: t: u (s, t , U; non-integer). Even if at least one color is recorded in a pattern randomly arranged in the sub-scanning direction, color moire is suppressed.

Further, even if one color is recorded in a normal arrangement pattern and the remaining other colors are recorded in a random arrangement pattern, color moire is suppressed. Here, each of the one color and the other color may be composed of a single color or a plurality of colors. In particular, when yellow is recorded in a randomly arranged pattern and magenta, cyan, and black are recorded in different non-integer multiple patterns, color moire can be effectively suppressed.

The optimum ratio in the sub-scanning direction of each color dot cycle that can suppress color moire is Y: M: C: K = 1: 3/4: 3.
/ 5: 1/2. When the horizontal scanning moiré occurs due to specific image recording when the dot cycle in the sub-scanning direction is set to the optimum ratio, the dot cycle in the main-scanning direction for each color is further changed in dot units to The resolution in the scanning direction is reduced. As a result, the occurrence of moiré is dispersed without being synchronized, and the occurrence of horizontal moire is avoided. Further, preferably, the combination of the period ratio in the main scanning direction and the period ratio in the sub-scanning direction of each color dot is (3 / 1.5,
3/3), (3/3, 3/4), (3 / 1.5, 3 /
5), set to (3/3, 3/6). This combination is obtained by resolution conversion and mask processing.
The pattern process executed after the resolution conversion process and the cancel process executed in either of the stage before and after the mask process are executed. Pattern processing and cancellation processing are
The information amount of the gradation data of the image is reduced, and the load on the recording apparatus is reduced. In the pattern processing, the number of submatrix to which the gradation of each pixel is assigned can be determined according to the value of the gradation data.
Further, in the mask processing, the value of the gradation data is the maximum value,
That is, when the maximum density is represented, the gradation data can be extracted. This is to faithfully reproduce the contours of characters and the like.

[0013]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a first embodiment of the present invention, in which multi-color multi-gradation is recorded by four-color separation of yellow (Y), magenta (M), cyan (C) and black (K). The recording pattern used for each color in the case is shown.

That is, FIG. 1A shows a comparative example.
1B shows a normal array pattern in which dots are regularly arranged, and FIG. 1B shows a random array pattern in which dots are randomly arranged in the sub-scanning direction.
(C) shows that the dot arrangement period in the sub-scanning direction is 2 /
FIG. 1D shows a 2/3 arrangement pattern in which halftone dots that are three times shorter are regularly arranged. In FIG. 1D, the dot arrangement period in the sub-scanning direction is shortened to half. A half array pattern in which each halftone dot is regularly arrayed is shown.

Further, similarly to FIGS. 1C and 1D, by changing the dot arrangement period in the sub-scanning direction by a desired magnification, an arrangement pattern having a desired resolution in the sub-scanning direction can be formed. is there. The array patterns shown in FIGS. 1A to 1D are adopted for each color of Y, M, C, and K, and the main scanning is 300 dpi and the scanning direction length is 70.
A line thermal head having a heater size of .mu.m and a length of 55 .mu.m in the sub-scanning direction is used, and the resolution in the main scanning direction is 30.
0 dpi, sub-scanning direction resolution 6000 dpi (3.7 μ
The following are visual evaluations of color moire and roughness when a gray solid image having a recording area ratio of 50% is recorded.

In the evaluation, misregistration between the respective colors was made to occur so that the color moire was recorded so that it was easy to see. The recording material used is Japanese Patent Application No. 5-26369.
The respective color materials (Y, M, C and K) used in the heat-sensitive transfer recording material disclosed in No. 5 specification. That is,
For 10 g of four types of dispersion liquids containing the following coloring materials A to D,
0.24 g of stearic acid amide and 60 g of n-PrOH were used as coating solutions, and dry thin films A to D were 0.36 μm and 0.38 μm, respectively, on a polyester film (manufactured by Teijin Ltd.) having a thickness of 5 μm which was peeled on the back surface. , 0.42
It is a heat-sensitive transfer material prepared by coating so as to have a thickness of μm and 0.40 μm.

A: Cyan pigment (CI, P.B. 15: 4) 12 g --- B: Magenta pigment (CI, P.R. 57: 1) -12 g-C: Yellow pigment (CI, P.Y. 14) -12 g D: Carbon (Mitsubishi Chemical Co., Ltd. MA-100) 12 g Butyral resin (Sekisui Chemical Co., Ltd. S-REC FPD-1 softening point 70 ° C, average degree of polymerization 300 or less) 12.0 g Solvent n -Propyl alcohol (n-PrOH) 110.4 g Dispersion aid Solspers S-20000 (manufactured by ICI Japan Co., Ltd.) 0.8 g

[0018]

[Table 1]

As shown in Table 1, when the dot arrangement period in the sub-scanning direction is set to a non-integer multiple of another color (1: non-integer), color moire is reduced, and especially K is a non-integer multiple of another color. When set to, color moire is further reduced (Examples 1 and 2).
reference). Further, when a random array pattern is adopted, color moire is reduced, but the graininess is increased (see Example 4). Here, when a random array is adopted for Y, which is not easily noticeable in texture, color moire and graininess are reduced (see Example 6).

In the third embodiment, the sub-scanning dot array periods of Y, M, C and K are sin 30 ° and sin, respectively.
The halftone dot angles of the conventional printed matter set to 60 °, sin 90 °, and sin 10 ° are shown. From the above evaluations, in the case of three-color separation recording, a substantially satisfactory evaluation can be obtained in any of the examples. However, in the case of four-color separation recording, in addition to Example 6 in which a random arrangement is adopted, the arrangement patterns of Y, M, C, and K are a normal arrangement pattern, a 3/4 arrangement pattern, a 3/5 arrangement pattern, and a 1 / Satisfactory evaluations were obtained in Example 8 set in a two array pattern.

That is, when the dot arrangement period in the sub-scanning direction set in Embodiment 8 which does not adopt the random arrangement pattern is analyzed among Embodiments 6 and 8 in which the satisfactory evaluation is obtained, Y, M and C are analyzed. And the dot arrangement period ratio of K in the sub-scanning direction is 20: 15: 12: 10 (1: 3/4:
3/5: 1/2). The ratio represents the ratio of the dot arrangement period in the sub-scanning direction that is the minimum period. As described above, Y is set to 1 and other colors are set to the above ratio based on this. In Example 8, a satisfactory evaluation was obtained.

Although the eighth embodiment shows a ratio capable of suppressing color moire to the minimum, depending on the image, as shown in FIG. 2, horizontal line moire a occurs due to coincidence of moire cycles. There are cases. Therefore, as shown in FIG. 3, the dot arrangement period in the main scanning direction of the Y and C dots having the dot arrangement period in the sub scanning direction set as in the eighth embodiment is set to be double to set the main scanning direction. Resolution of 1 /
The arrangement pattern reduced to 2 is adopted. That is,
The dot arrangement cycle ratio of Y, M, C, and K in the sub-scanning direction is
20: 15: 12: 10 (1: 3/4: 3/5: 1 /
In addition to 2), the dot arrangement cycle ratio in the main scanning direction is further set to 1: 2: 1: 2 (1/2: 1: 1/2: 1). Considering the relative ratio of the dot arrangement cycle ratio in each scanning direction, the combination of the dot arrangement cycle ratios of Y, M, C, and K in the main scanning direction and the sub scanning direction is (3/1.
5,3 / 3), (3 / 3,3 / 4), (3 / 1.5,3)
/ 5) and (3/3, 3/6). When set as above, the resolution of each color in the main scanning direction and the sub scanning direction is
(75 dpi, 150 dpi), (150 dpi, 20
0 dpi), (75 dpi, 250 dpi), (150
dpi, 300 dpi).

Hereinafter, with reference to FIGS. 4 to 8, Y, M, C
And K in the main scanning direction and the sub scanning direction, the combination of the dot arrangement period ratios is (3 / 1.5, 3/3), (3/3,
3/4), (3 / 1.5, 3/5), (3/3, 3 /
The execution sequence in the case of setting 6) will be described. The variable resolution in the sub-scanning direction will be described here. First, as shown in FIG. 4, the gradation of the image is 2
In order to represent 56 gradations, the sub-scanning direction of each color gradation image represented by 8-bit data is processed at a cycle of 6 lines. If the number of lines in the sub-scanning direction of the gradation image is not a multiple of 6, a blank line is added to the final line and the number of lines in the sub-scanning direction of the gradation image is set to a multiple of 6. Next, as shown in FIG. 5, according to the position of the gradation image,
The gradation image data in the sub-scanning direction is interpolated to convert the resolution. In the illustrated example, the resolutions of Y, M, C, and K in the sub-scanning direction set to 300 dpi are 300 dpi, 400 dpi, 500 dpi, and 600, respectively.
Converted to dpi. Edges are smoothed by converting to high resolution. In Y, the resolution is fixed, but as shown in FIG. 6, an averaging process is performed in which the average value of the center and the line above it is used as the value of the center line. At this time, a weighting factor 50 is set for each of the center line and the upper line to obtain a weighted average.
This is to accurately reproduce the density even if the original image has a checkered pattern. Here, the center of the weighting coefficient may be set to 50 and the upper and lower sides may be set to 25 by averaging the upper and lower lines.

The arithmetic expressions for the resolution conversion and the averaging process are shown in equations 1 to 4. Since the same process is repeated in a cycle of three lines, the line numbers from the first line are line (0,0), line (0,1),
line (0,2), line (1,0), line
(1,1), ..., line (n, 0), line (n,
1) and line (n, 2). Further, the data of the 0th line is necessary for the processing of the 1st line, but this data value is set to 0. The data is set to 256 gradations, the data value 0 is white, and the data value 255 is full density.

[0025]

[Equation 1]

[0026]

[Equation 2]

[0027]

[Equation 3]

[0028]

[Equation 4]

Next, as shown in FIG. 7, the gradation of each pixel is assigned to the sub-matrix, and the pattern processing of adding the value of the sub-matrix to the original gradation data is executed. The sub-matrix is arranged in units of 2 dots in the sub-scanning direction, and the number of sub-matrices is set according to the gradation of the image in order to improve gradation characteristics. For example, the number of submatrices in the halftone is set to 4 and the number of submatrices in the highlight is set to 8 to improve the gradation reproducibility in the highlight. The sub-matrix may be arranged in the same order for all pixels, or may be randomly set for each pixel. In this embodiment, the case of addition is shown, but subtraction or addition / subtraction may be used in combination. The gradation image data is 25
It is represented by 8 bits to represent 6 gradations. However, when recording 256 gradations with 8-bit data, a considerable recording time is required depending on the recording device, or
It may not be possible to record 6 gradations. Therefore, a predetermined number of bits of 8-bit data is canceled according to the set number of sub-matrices. The relationship between the number of canceled bits n and the number of matrices D is defined by D = 2 ⁿ . Further, the cancel processing is executed for the lower bits of the 8-bit data. That is, when the number of matrices is 4, the number of canceled bits is 2, and
When the lower 2 bits of bit data are set to 0 and the number of matrices is 8, the number of canceled bits is 3, and the lower 3 bits of 8-bit data are set to 0. Next, as shown in FIG. 8, the mask of the illustrated pattern is superimposed on each color image, the gradation data value of the pixel corresponding to the white part is set to 0, and the gradation of the pixel corresponding to the black part is set. Extract the data value as it is. If the masking process is executed on the character area of the image, the continuity of gradation is lost. Therefore, when the gradation data value of the image having 256 gradations is 255 which corresponds to a character, the gradation data value of 255 is extracted as it is without executing the mask process. In the above embodiment, the cancellation process of the bits of the gradation data is executed before the mask process.
The cancel process may be executed after the mask process. Further, among the above processes, the pattern dither process and the cancel process are not indispensable processes, and as described above, since the gradation number and the recording speed that the recording device can process are satisfied, the burden on the recording device is increased. This is a process for reducing. Further, it may be better not to execute the special mask processing of the 255 gradation data depending on the application.

FIG. 9 shows a state in which the patterns corresponding to the respective colors shown in FIG. 3 are superposed. As shown in the drawing, the moire period is dispersed by combining the array patterns with the reduced resolution in the main scanning direction, whereby the horizontal linear moire is avoided. The arrangement pattern can be adopted for one, two, or three colors out of four colors. Further, the resolution in the main scanning direction is reduced to 1/2 and is set in dot units such as ⅓ or ¼, and each has an effect. These conditions are
It is set according to the recorded image.

When the resolution in the main scanning direction is lowered, two dots adjacent in the main scanning direction may be controlled to have independent sizes by their own data. That is, the resolution of the shape is reduced, but the resolution of the data is not reduced. Further, in this embodiment, the two adjacent dots are completely arranged in parallel in the main scanning direction, but the dots may be arranged with some offset in the sub scanning direction.

The recording means capable of avoiding the horizontal linear moire is
Regardless of recording based on the heat-sensitive transfer material disclosed in Japanese Patent Application No. 5-263695, well-known melt heat transfer, sublimation-type heat transfer, color heat-sensitive (Thermoautochrome paper FJX-TV P manufactured by Fuji Photo Film Co., Ltd.) -20), ink jet recording, electrophotographic recording, color offset printing, lith film for printing, and other multicolor image recording, and particularly suitable for area gradation recording.

Even if a sublimation type transfer material is used and density gradation is applied to each color, color moire and graininess are reduced, but bleeding of black characters is confirmed, which is not preferable (comparison See Example 6). Furthermore, only 1 for K
When the / 2 array pattern was applied, the outline of black characters was sharpened as compared with Comparative Example 6 (see Example 9). The sublimation type thermal transfer material used is ink sublimation type 4 color A3 super ink sheet CH-791 manufactured by Seiko Denshi KK, and used paper is sublimation type A3 plain paper CH-89 manufactured by Seiko Denshi KK
It is 5.

Further, when recording is carried out according to the above-described embodiment, since there are few roughness factors such as the rosette pattern observed at the time of printing, particularly in a gray solid image or the like, an image similar to a photograph with less roughness feeling can be obtained. The above examples are applicable to direct color thermal recording, melt transfer thermal recording and sublimation transfer thermal recording, which are recorded by a thermal head, respectively. Further, it can be applied to electrophotography, silver salt photography, and photopolymer multicolor light-sensitive material recorded by a liquid crystal array line head. Further, it is applicable to electrophotography and silver halide photography recorded by an LED line head or an EL line head. In laser recording capable of high-resolution recording in the main scanning direction, when an image is recorded based on high-resolution image data, there is a problem related to the present invention, and based on low-resolution image data. Even when an image is recorded, a gradation image can be obtained by changing the resolution, so that it can be applied to laser recording.

The present invention can also be applied to the case of recording on an intermediate medium other than direct multicolor printing, for example, to an output device having a lith film and a printing plate. Although the above-described embodiment describes the image recording, it can be applied to the case of image reading using a line image sensor, for example. In the embodiment described above, the two-dimensional recording in which the one-dimensional array direction of the recording elements is defined as the main scanning direction and the direction orthogonal to the main scanning direction is defined as the sub-scanning direction has been described. However, it goes without saying that the one-dimensional array direction of the recording elements may be defined as the sub-scanning direction and the direction orthogonal to the sub-scanning direction may be defined as the main scanning direction.

According to the invention described above, an array pattern having a desired resolution in the sub-scanning direction is formed by changing the dot array period in the sub-scanning direction at a desired magnification. Therefore, the resolution in the sub-scanning direction is changed, and thus color moire can be effectively suppressed. Furthermore, by varying the resolution in the sub-scanning direction and the resolution in the main-scanning direction, it is possible to avoid linear moire that occurs during recording of a specific image.

[Brief description of drawings]

FIG. 1 is a pattern diagram showing a first embodiment of the present invention.

FIG. 2 is a pattern diagram showing a horizontal linear moire.

FIG. 3 is a pattern diagram for avoiding the horizontal linear moire shown in FIG.

FIG. 4 is a diagram showing a process for obtaining an array pattern of the present invention.

FIG. 5 is a diagram showing a process for obtaining an array pattern of the present invention.

FIG. 6 is a diagram showing a process for obtaining an array pattern of the present invention.

FIG. 7 is a diagram showing a process for obtaining an array pattern of the present invention.

FIG. 8 is a diagram showing a process for obtaining an array pattern of the present invention.

FIG. 9 is a pattern diagram when the color patterns shown in FIG. 3 are overlapped.

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical indication location B41J 2/36 2/325 2/44 2/45 2/455 B41J 3/04 101 A 3/20 115 D 117 C 3/21 L

Claims (12)

[Claims] 1. A head in which a plurality of recording elements are arranged in the main scanning direction is moved in the sub scanning direction to change the density or area ratio of each pixel according to the image density, and yellow, magenta, cyan and black. An image recording method for recording a multicolor image by combining the respective colors, wherein one color is recorded in a regular array pattern with a constant dot period, and the dot period in the sub-scanning direction is different from the one color by a different non-integer multiple. An image recording method characterized by recording at least two colors in a set pattern. 2. A head in which a plurality of recording elements are arranged in the main scanning direction is moved in the sub scanning direction to change the density or area ratio of each pixel according to the image density, and yellow, magenta, cyan and black. An image recording method for recording a multicolor image by combining the respective colors of, wherein the dot cycle ratios of the respective colors of yellow, magenta, cyan, and black in the sub-scanning direction are in random order 1: 3/4: 3/5:
An image recording method characterized by setting to 1/2. 3. A head in which a plurality of recording elements are arranged in the main scanning direction is moved in the sub scanning direction to change the density or area ratio of each pixel according to the image density, and yellow, magenta, cyan and black. An image recording method for recording a multicolor image by combining the respective colors of, wherein the dot period ratios of the colors of yellow, magenta, cyan, and black in the sub-scanning direction are set to different non-integer multiples for each color. Among the dots, an image recording method characterized in that a dot arrangement cycle in the main scanning direction is changed in dot units in order to reduce the resolution of required dots in the main scanning direction. 4. A head in which a plurality of recording elements are arranged in the main scanning direction is moved in the sub scanning direction to change the density or area ratio of each pixel according to the image density, and yellow, magenta, cyan and black. An image recording method for recording a multicolor image by combining the respective colors, wherein each color is recorded in a pattern in which dot periods are randomly arranged in the sub-scanning direction. 5. A head in which a plurality of recording elements are arranged in the main scanning direction is moved in the sub scanning direction to change the density or area ratio of each pixel according to the image density, and yellow, magenta, cyan and black. An image recording method for recording a multi-color image by combining the respective colors, characterized in that one color is recorded in a regular array pattern with a constant dot period and the other color is recorded in a pattern randomly arranged in the sub-scanning direction. Image recording method. 6. A head in which a plurality of recording elements are arranged in the main scanning direction is moved in the sub scanning direction to change the density or area ratio of each pixel in accordance with the image density, and yellow, magenta, cyan and black. Is an image recording method for recording a multicolor image by combining the respective colors of, wherein yellow is recorded in a pattern in which the dot cycle is randomly arranged in the sub-scanning direction, and the dot cycle in the sub-scanning direction is different from each other by a non-integer multiple. An image recording method characterized by recording recording of magenta, cyan and black with a set pattern. 7. A head in which a plurality of recording elements are arranged in the main scanning direction is moved in the sub scanning direction to change the density or area ratio of each pixel according to the image density, and yellow, magenta, cyan and black. An image recording method for recording a multicolor image by combining the respective colors of (3), wherein a combination of the dot period ratio in the main scanning direction and the dot period ratio in the sub-scanning direction of each color of yellow, magenta, cyan, and black is (3 / 1.5, 3/3), (3/3, 3 /
4), (3 / 1.5, 3/5), and (3/3, 3/6) are set. 8. A head in which a plurality of recording elements are arranged in the main scanning direction is moved in the sub scanning direction to change the density or area ratio of each pixel in accordance with the image density, and yellow, magenta, cyan and black. An image recording method for recording a multicolor image by combining the respective colors of (3), wherein a combination of the dot period ratio in the main scanning direction and the dot period ratio in the sub-scanning direction of each color of yellow, magenta, cyan, and black is (3 / 1.5, 3/3), (3 / 1.5,
(3/5), (3/3, 3/4), (3/3, 3/6). 9. A resolution conversion process for converting the combination by sub-scanning direction resolution of each color of yellow, magenta, cyan and black having a predetermined resolution, and a predetermined pattern for each resolution-converted color. And a mask process for extracting the gradation image data of each color by setting the value of the gradation data of the pixel which overlaps the predetermined pattern among the pixels to 0 and sequentially executing the mask processing in a predetermined row cycle. The image recording method according to claim 8, which is obtained. 10. After the resolution conversion process, in one of a pattern process of allocating the gradation of each color pixel to a sub-matrix arrayed in units of two pixels in the sub-scanning direction, and one of a stage before and after the mask process, The image recording method according to claim 9, further comprising a canceling process of canceling a predetermined number of lower bits of the gradation data of each pixel. 11. The image recording method according to claim 10, wherein the number of sub-matrices is determined according to the value of gradation data. 12. The image recording method according to claim 9, wherein the masking process extracts the gradation data of the maximum value for the image having the maximum value of the gradation data.