JP2012228855A - Image processor, inkjet recording device, and image processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce concentration irregularity generated in a band where recording is completed by a plurality of number of times of scanning when a mask having an uneven recording ratio is used, in an inkjet recording device.SOLUTION: Which of a color separation table A and a color separation table B is used is determined in accordance with the location of a nozzle used for recording input image data. First, which of the upper half and the lower half of each of nozzle groups 201a-201d is used is determined in accordance with a pixel position of the input image data. That is to say, the lower half of each nozzle group corresponds to a lower pattern in each region of a mask, and the upper half thereof corresponds to an upper pattern in each region of the mask. When the pixel position of the input image data is determined to use the lower half of each nozzle group, the color separation table A is set to be used. When the pixel position of the input image data is determined to use the upper half of each nozzle group, the color separation table B is set to be used.

Description

  The present invention relates to an image processing apparatus, an ink jet recording apparatus, and an image processing method, and more particularly to image processing for generating recording data using a mask for so-called multipass recording.

  So-called multi-pass printing is a printing method in which printing of a unit area is completed by a plurality of scans of the print head, and print data used for each of the plurality of scans is generally generated using a mask. Specifically, the recording data to be recorded in the unit area is distributed to the recording data for each scan using a mask composed of a plurality of mutually complementary mask patterns corresponding to a plurality of scans. The mask pattern takes various forms for the purpose of realizing desired recording characteristics and preventing deterioration of recording quality. For example, Patent Document 1 describes a mask pattern for the purpose of reducing streaking, which is a type of density unevenness that may occur at the boundary of the unit region completed by a plurality of scans. This mask pattern is a mask pattern in which the recording ratio is higher in the nozzles located in the center of the nozzle arrangement, and the recording ratio is lower in the nozzles located in the end part, which is known as a so-called gradation mask. Yes. By using such a gradation mask, the recording ratio of the nozzles at the end of the nozzle row becomes low, and the streak that may occur at the boundary of the area where the recording is completed can be made inconspicuous.

  In the above description, “recording ratio” means the ratio of mask data that outputs the recording data of the corresponding pixel in the mask pattern as it is. In other words, it means the ratio of mask elements that allow printing of the recording data when the recording data of the corresponding pixel is data indicating that dots of ink are recorded on the pixel among the mask elements constituting the mask pattern. To do. This recording ratio has a reciprocal relationship with the thinning rate that masks data indicating that dots are to be printed by the mask, that is, the thinning rate that indicates the thinning ratio.

JP 2002-96455 A

  However, if a mask having a mask pattern with a nonuniform distribution of nozzle ratios such as the gradation mask described above is used, the density within a unit area (hereinafter also referred to as a band) in which printing is completed by a plurality of scans is used. There is a problem of causing unevenness or color unevenness.

  FIGS. 1A and 1B are diagrams for explaining this problem. As an example, the above-described gradation mask pattern used in multi-pass printing in which printing is completed by four scans (four passes) is shown. Specifically, FIG. 1A shows the distribution of mask elements (black dots) that allow printing, and FIG. 1B shows the ratio of mask elements that allow the printing corresponding to the nozzle rows of the print head 201 ( Recording ratio).

  In these figures, the band that completes recording has the width of each nozzle group obtained by dividing the nozzle array of the recording head 201 into four (strictly speaking, the number of nozzles in the divided array × the length of the nozzle array pitch). It is. In addition, the recording medium is transported to the recording head 201 by the width for each scanning, and the nozzle groups 201a to 201d are respectively moved by the first (first pass) to the fourth (fourth pass) scanning. Use in sequence to complete the recording of the band of the above width. At this time, a mask pattern corresponding to the nozzle group 201a is used in the first pass scanning, and a mask pattern corresponding to the nozzle group 201b is used in the second pass scanning. Further, print data for the scan is generated using the mask pattern corresponding to the nozzle group 201c in the scan of the third pass and the mask pattern corresponding to the nozzle group 201d in the scan of the fourth pass.

  If a mask having a mask pattern with a nonuniform distribution as described above is used, the recording ratio may not be uniform even within the mask pattern for each pass. In the example shown in FIG. 1B, when the mask pattern for each pass is divided into two, for example, the mask pattern for the first pass is divided into a pattern 601-1 and a pattern 601-2, and a pattern 601-1 is obtained. Is lower than that of the pattern 601-2. Similarly, in the mask pattern of the second pass, the recording ratio of the lower pattern in the figure is lower. On the contrary, the recording ratio of the upper pattern of the two divided patterns is lower in the third pass, and the same applies to the fourth pass. In this case, when the recording is completed in four passes, the recording data is generated in the lower area where the band is divided into two using the patterns 601-1, 602-1, 603-1 and 604-1, Recorded in this order. On the other hand, in the upper area, recording data is generated using patterns 601-2, 602-2, 603-2, and 604-2, and is recorded in this order. Here, in the example shown in FIG. 1B, if the recording ratio for each pattern is p1, p2, p3, p4 in ascending order, the patterns 601-1, 602-1, 603-1, and 604-1 are as follows. P1, p3, p4, and p2 respectively. The patterns 601-2, 602-2, 603-2, and 604-2 are p2, p4, p3, and p1, respectively. The recording ratio of these patterns serves as an index of the amount of ink ejected to the corresponding area. That is, the lower area of the band where the recording is completed is recorded in order with the ink amounts of p1, p3, p4, and p2, while the upper area is sequentially with the ink amounts of p2, p4, p3, and p1. Recording will be performed. As described above, when the amount of ink applied to the recording medium is different with respect to the order in which the recording is performed, for example, the amount of the ink applied in the preceding and following passes permeates the recording medium is different. The resulting recording density may be different. As a result, density unevenness or color unevenness occurs in a band where recording is completed by a plurality of scans, and the recording quality is lowered.

  The present invention solves the above-described problems and can reduce density unevenness that can occur in a band where printing is completed by a plurality of scans when a mask with a non-uniform printing ratio is used, An object is to provide an ink jet recording apparatus and an image processing method.

  Therefore, in the present invention, a plurality of nozzles obtained by dividing the nozzle array by using a recording head in which a plurality of nozzles for ejecting ink are arranged and performing a plurality of scans on the recording medium of the recording head. An image processing apparatus for generating recording data used for recording for completing an image of a unit area on a recording medium corresponding to one nozzle arrangement length of a group, wherein recording is allowed for each of the plurality of nozzle groups A recording ratio pattern, which is a ratio of mask elements to be generated, is defined, and recording data for each of the plurality of scans is generated using a mask with the recording ratio pattern being different between the plurality of nozzle groups, and the generated recording A conversion table created based on the measurement result of the recorded patch image by performing a plurality of scans based on the data to record the patch image, The measurement result of the patch image by the pattern of the recording ratio of the plurality of masks corresponding to the nozzle or the nozzle group that records the same region in the unit region by a plurality of scans, and the unit region by the plurality of scans Each conversion parameter is determined to be the same as the measurement result of the patch image by the pattern of the recording ratio of the plurality of masks corresponding to other nozzles or nozzle groups that record the other same region. Means for generating recording data of the unit area using the conversion table for the same area.

  According to the above configuration, it is possible to reduce density unevenness that can occur in a band in which printing is completed by a plurality of scans when a mask with a non-uniform printing ratio is used.

(A) And (b) is a figure explaining the gradation mask used for the printing data generation of multipass printing. 1 is a perspective view showing an ink jet recording apparatus according to an embodiment of the present invention. FIG. 3 is a block diagram illustrating a control configuration of a recording system according to the present embodiment including the recording apparatus illustrated in FIG. 2 and a host device that performs recording control thereof. 4 is a flowchart mainly showing recording data generation processing performed in the host device shown in FIG. 3 and processing related to recording data used in the recording apparatus. It is a figure explaining the dot arrangement pattern of the embodiment of the present invention. It is a figure which shows a color separation table typically. 5 is a flowchart showing print data generation processing by the printer driver shown in FIG. It is a figure which shows the mask of the 2nd Embodiment of this invention. (A) And (b) is a figure which shows the mask used in the 3rd Embodiment of this invention.

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

  In the present specification, “recording” is not limited to forming significant information such as characters and figures, and whether or not it is manifested so that humans can perceive it visually. In addition, a case where an image or the like is widely formed on a recording medium or a medium is processed is also expressed. “Recording medium” refers not only to paper used in general recording apparatuses but also widely to cloth, plastic film, metal plate, glass, ceramics, wood, leather, and the like that can accept ink. Shall. Furthermore, “ink” refers to the formation of images, patterns, patterns, etc., processing of the recording medium, or processing of the ink (for example, the colorant in the ink applied to the recording medium) by being applied on the recording medium. It shall represent a liquid that can be subjected to solidification or insolubilization.

(First embodiment)
<Schematic configuration of the device>
FIG. 2 is a perspective view showing an ink jet recording apparatus according to an embodiment of the present invention. In FIG. 2, the carriage 200 can be moved by the driving force of the carriage motor 210, whereby the recording head can scan the recording medium. On the bottom of the carriage 200, a recording head (not shown) that discharges yellow (Y), magenta (M), cyan (C), and black (K) inks is mounted. The carriage 200 is detachably mounted with ink tanks 202Y, 202M, 202C, and 202K that store the Y, M, C, and K inks.

  FIG. 3 is a block diagram showing a control configuration of the recording system according to the present embodiment having the recording apparatus shown in FIG. 2 and a host device for controlling the recording. In the recording system of this embodiment, an external device such as a digital camera can be connected to the host device, and the captured image data can be recorded in the recording device.

  As shown in FIG. 3, the recording apparatus includes a main control unit 701 that includes an MPU, a ROM, a RAM, and the like and controls the entire recording apparatus. The recording buffer 702 stores recording data to be transferred to the recording head 201 (representing each recording head that discharges Y, M, C, and K inks) in a raster format. The stored recording data is generated by processing described later with reference to the drawings after FIG. A motor control unit 704 controls a motor for driving a carriage, feeding a recording medium, and discharging a recording medium. The data buffer 706 temporarily stores recording data received from the host device via the interface (I / F) unit 705. In addition, the system bus 707 performs data connection between the main control unit 701 and each unit described above. On the other hand, a host device such as a PC that transmits control data and recording data to the ink jet recording apparatus includes a main control unit 708 that includes an MPU, a ROM, a RAM, and the like and controls generation of image data and main operations. Further, the host device includes an interface (I / F) unit 709 for communicating with the recording device, a main memory 710, an external I / F unit 711 for communicating with a connected external device, and a main control unit 708. And a system bus 712 for data connection between the respective units. The interface between the inkjet recording apparatus and the host device and the interface between the host device and the external device can be used in various specifications regardless of wired or wireless. Typical specifications include the Centronics interface, USB (60 and 2.0), IEEE 1394, IrDA, Bluetooth, various wired and wireless LAN standards, etc., which are appropriate according to the usage and device configuration. Selected.

  Image data input to the host device from an external device, image data created by an application of the host device, various conversion tables downloaded via the network (table for performing later processing), and the like are stored in the main memory 710. Stored in When the application instructs to record image data, the printer driver is activated, and the image data stored in the main memory 710 is subjected to image processing described later with reference to FIG. Generate recorded data.

<Image processing procedure>
FIG. 4 is a flowchart mainly showing recording data generation processing performed in the host device shown in FIG. 3 and processing relating to recording data used in the recording apparatus. As described above, the ink jet recording apparatus applied in the present embodiment performs recording using four colors of inks of C, M, Y, and K, and for this purpose, a recording head that discharges these four colors of ink. Is prepared. As shown in FIG. 4, each process shown here is performed by a recording device and a personal computer (PC) as a host device.

  There are an application and a printer driver as programs that operate in the operating system of the host device, and the application J0001 executes processing for creating image data corresponding to an image recorded by the recording device. At the time of actual recording, image data created by the application is passed to the printer driver. The printer driver of this embodiment includes a pre-stage process J0002, a post-stage process J0003, a γ correction J0004, a halftoning J0005 that is a multi-level quantization process, and a print data creation J0006. Here, the pre-stage processing J0002 performs mapping of the color gamut. For example, in the case of sRGB standard image data, data conversion is performed to map the color gamut reproduced by the sRGB standard image data R, G, B into the color gamut reproducible by the recording apparatus. Specifically, each of R, G, and B is represented by 8 bits, and the R, G, B depending on the color gamut that can be represented by the recording apparatus by using a three-dimensional lookup table (3DLUT). To 8-bit data.

The post-stage process J0003 uses the 8-bit input data R, G, and B obtained in the pre-stage process J0002 as color separation data (here, 8-bit data C) corresponding to the combination of inks that reproduce the colors represented by the RGB data. , M, Y, K). Here, RGB data is converted into CMYK data by using a color separation table (for example, a three-dimensional lookup table) in which RGB data and CMYK data corresponding to ink are associated one-to-one. Specifically, in the three-dimensional lookup table, R, G, and B values each represented by 8 bits (0 to 255) and CMYK values each represented by 8 bits (0 to 255) Are associated in advance,
From (R, G, B) = (0-255,0-255,0-255) to (C, M, Y, K) = (0-255,0-255,0-255,0-255) Conversion is performed.

  For example, if (R, G, B) = (0, 0, 0), it is converted to (C, M, Y, K) = (0, 0, 0, 255). If (R, G, B) = (255, 255, 255), (C, M, Y, K) = (0, 0, 0, 0) and (R, G, B) = If (0, 128, 0), they are converted to (C, M, Y, K) = (0, 128, 128, 0), respectively. In the case of input data indicating points (colors) other than grid points, color separation data (output data) is obtained by interpolation processing using grid point data of grid points and surrounding grid points. As this interpolation method, any known interpolation method such as tetrahedral interpolation or cubic interpolation can be used. In this embodiment, as will be described later with reference to FIG. 7, at least two types of color separation tables are provided, and the color separation tables are switched and used in accordance with predetermined conditions.

  The γ correction J0004 performs gradation value conversion for each ink color data of the color separation data obtained by the post-processing J0003. Specifically, by using a one-dimensional LUT corresponding to the gradation characteristics of each color ink of the recording apparatus, conversion is performed so that the color separation data is linearly associated with the gradation characteristics of the recording apparatus. Halftoning J0005 performs quantization by converting 8-bit color separation data Y, M, C, and K into 2-bit data. In this embodiment, multi-level error diffusion is used to convert 256-gradation 8-bit data into 3-gradation 2-bit data. This 2-bit data is data serving as an index for indicating an arrangement pattern in the dot arrangement patterning process performed in the printing apparatus. Finally, the recording data creating process J0006 creates recording data in which the recording control information is added to the recording image data containing the 2-bit index data. The host device transmits this recording data to the recording device.

  In the recording apparatus, the dot arrangement patterning process J0007 is performed on the recording data transmitted from the host device. This dot arrangement patterning process J0007 assigns a dot arrangement pattern corresponding to ternary data of levels 0 to 2 for each pixel, which is an output value from the halftone processing unit. Thus, dot on / off is defined in each of a plurality of areas in one pixel, and 1-bit ejection data of “1” or “0” is arranged in each area in one pixel.

  FIG. 5 is a diagram illustrating a dot arrangement pattern according to the present embodiment. As shown in the figure, the dot arrangement pattern corresponds to each of input levels 0 to 2, and “record” (“1”) or “non-record” (“0”) of dots in 2 vertical pixels × 1 horizontal pixel. ) Data. This pattern has a resolution of 1200 dpi in the vertical direction and 600 dpi in the horizontal direction, corresponding to one pixel of 600 dpi in both the vertical and horizontal directions output by the halftone process. In the recording apparatus according to the present embodiment, a predetermined density is obtained by recording one ink droplet of a predetermined amount for one pixel represented by about 20 μm in length and about 40 μm in width corresponding to the above resolution. It is designed like this. In the case of the input level 1, two types of patterns are prepared. Thus, the presence of a plurality of patterns capable of expressing the same density level can suppress the occurrence of texture and pseudo contour in the recorded image.

  Referring to FIG. 4 again, the binary data of each color that has been subjected to the dot arrangement patterning process is subjected to a mask process by a mask process J0008, and print data used in each scan of 4-pass printing is generated. That is, in the multi-pass recording mode, recording of a band having a width that is ¼ of the nozzle arrangement length is completed. For this reason, in this embodiment, the gradation mask described above with reference to FIGS. 1A and 1B is used to distribute the recording data obtained by the dot arrangement patterning process to the recording data for each of the four scans. In one embodiment of the present invention, as will be described later, the contents of the color separation table used in the post-stage processing J0003 are determined according to a form in which the recording ratio is not uniform, such as this gradation mask. Here, the “recording ratio” means the ratio of mask data that outputs the recording data of the corresponding pixel as it is in the mask pattern, as described above. Note that in a mode in which printing is completed in one pass, which is not the multipass printing mode, mask processing is not performed, and print data obtained by dot arrangement patterning processing is sent to the head drive circuit as it is.

  When 1-bit binary print data is input to the drive circuit J0009, the drive circuit J0009 drives the print head of each ink color at a predetermined timing accompanying the scan of the print head based on this print data. Is done.

<Create color separation table>
A plurality of color separation tables (conversion tables) according to an embodiment of the present invention are created in advance according to the mask used in the mask processing J0008 and stored in a predetermined memory of the host device.

  FIG. 6 is a diagram schematically illustrating a color separation table. As shown in the figure, when a predetermined position (color) in the cube defined by the input data R, G, and B is represented by a grid point, the color separation table outputs data (color separation) corresponding to the grid point. Data; conversion parameters) Y, M, C, K are defined. In creating this table, first, a series of processes after the γ correction processing is performed based on the combination of ink color data Y, M, C, and K corresponding to the lattice points defined on the grid points and the lines connecting the lattice points. Recording data is generated through processing. Then, each print image is recorded by 4-pass printing by using this print data as 4-pass print data by mask processing J0008. Then, the patches recorded as described above are color-measured, and the relationship between the output data Y, M, C, and K with respect to the input data R, G, B is desired based on the colorimetric values that are the respective measurement results. The data Y, M, C, and K of each lattice point are determined so that the relationship is established. That is, in the present embodiment, the color separation table is created so that density unevenness or color unevenness does not occur in a unit area completed by 4-pass printing.

  Specifically, as described above with reference to FIGS. 1A and 1B, each band is divided into two areas, and there is a difference in density or color between the two areas in a band where recording is completed in four passes. Two color separation tables are prepared so as to correspond to the two areas. Hereinafter, these two types of color separation tables are referred to as a color separation table A and a color separation table B. The two types of color separation tables are determined as follows.

  As described above with reference to FIGS. 1A and 1B, each band corresponding to the nozzle arrangement of the gradation pattern mask is divided into two. Of the two divided mask patterns, patches were recorded by four-pass recording using recording data created by the portions of the patterns 601-1, 602-1, 603-1, and 604-1, and created based on the patches. The color separation table is color separation table A. Also, patches are recorded by four-pass recording based on recording data created by the portions of the patterns 601-2, 602-2, 603-2, and 604-2, and the color separation table created based on the patches is referred to as the color separation table B. To do. More specifically, the color separation data of the color separation tables A and B are stored so that the colorimetric values of the recorded patches are the same for the same combination of R, G, and B input to the post-processing J0003. Determine. That is, binary C, M, Y, and K data are obtained based on the color separation data obtained from the color separation tables A and B for the same combination of R, G, and B. The C, M, Y, and K data obtained from the color separation table A are recorded as 4-pass print data according to the gradation mask patterns 601-1, 602-1, 603-1, and 604-1. The C, M, Y, and K data obtained from the color separation table B are recorded as 4-pass print data according to the mask patterns 601-2, 602-2, 603-2, and 604-2. Based on the recording data for each of the four passes obtained in this way, the patches corresponding to the two divided areas are recorded in four passes. At this time, the patterns 601-1, 602-1, 603-1, and 604-1 and the patterns 601-2, 602-2, 603-2, and 604-2 have the recording order with respect to the recording ratio as described above. The color separation table data is determined so that the colorimetric values of the patches are the same when the density or color of the image that is completed differs in 4 passes, so that the same colorimetric values can be obtained. . For example, for the same combination of R, G, and B, when the density is higher in the upper region of the two divided regions of the band, the color separation data of the color separation table B corresponding to the upper region The values of C, M, Y, and K are set smaller than the values of the color separation data C, M, Y, and K for the same combination of R, G, and B in the color separation table A. This basically prevents the occurrence of density unevenness or color unevenness in the band.

<Color separation table switching process>
In recording, the color separation table created as described above is used by switching according to the nozzle position of the recording head.

  FIG. 7 is a flowchart showing print data generation processing by the printer driver described above with reference to FIG. In FIG. 7, first, in step S1101, 8-bit RGB image data to be recorded is input. Next, in step S1102, it is determined which one of the color separation table A and the color separation table B is used according to which position of the nozzle the input image data is recorded. Specifically, first, it is determined which of the upper half or the lower half of each of the nozzle groups 201a to 201d shown in FIG. 1B is used according to the pixel position of the input image data. That is, the lower half of each nozzle group corresponds to the mask patterns 601-1, 602-1, 603-1, and 604-1, and the upper half corresponds to the mask patterns 601-2, 602-2, 603-2, and 604. -2. When it is determined that the pixel position of the input image data uses the lower half of each nozzle group, the color separation table A is set to be used. On the other hand, when it is determined that the pixel position of the input image data uses the upper half of each nozzle group, the color separation table B is set to be used.

  After the above processing, in step S1103, image processing including post-processing J0003 performed using the color separation table (pre-processing J0002, post-processing 0003, γ correction processing J0004, halftone processing J0005, etc. described in FIG. 4). )I do. Thereby, recording data is generated, and the recording data generated in step S1104 is transmitted to the recording apparatus.

(Second Embodiment)
The second embodiment of the present invention relates to a pattern in which a band, which is a unit area that completes printing by a plurality of scans, is divided into three, and a gradation mask corresponding to the band is divided into three corresponding to the three divided areas. FIG. 8 is a view showing the mask of the present embodiment, and shows the same gradation mask as shown in FIGS. 1A and 1B according to the first embodiment. In the present embodiment, mask patterns corresponding to each band are patterns 1201-1, 1202-1, 1203-1, 1204-1, patterns 1201-2, 1202-2, 1202-2, 1204-2, The patterns 1201-3, 1202-3, 1203-3, and 1204-3 are divided into three, and a color separation table is created corresponding to these three pattern groups.

<Color separation table to be used>
That is, a color separation table created using the portions of the patterns 1201-1, 1202-1, 1203-1, 1204-1 is referred to as a color separation table A. Further, a color separation table created using the portions of the patterns 1201-2, 1202-2, 1203-2, and 1204-2 is referred to as a color separation table B. Further, a color separation table created using the portions of the patterns 1201-3, 1202-3, 1203-3, and 1204-3 is referred to as a color separation table C.

<Color separation table switching process>
The color separation table switching process is performed in the print data generation process by the printer driver shown in FIG. 7, as in the first embodiment. That is, as described above, in step S1102 of FIG. 7, an appropriate color separation table corresponding to the nozzle position is selected from the three types of color separation tables.

  In the first and second embodiments described above, examples using two or three types of color separation tables have been described. However, although there are restrictions such as hardware processing, the number of mask divisions, that is, the number of color separation tables. The number may be further increased.

(Third embodiment)
The third embodiment of the present invention relates to a mode in which a color separation table or color separation data is defined for each nozzle.

<Color separation table to be used>
FIGS. 9A and 9B are diagrams showing a mask used in the present embodiment. In other words, the present embodiment uses two masks and creates two color separation tables accordingly. The mask A shown in FIG. 9A is a mask in which the recording ratios at the lower ends of the areas corresponding to the bands of the gradation masks according to the first and second embodiments are set to a constant ratio in the area. A mask B shown in FIG. 9B is a mask in which the recording ratio at the upper end of the area corresponding to each band of the gradation mask is set to a constant ratio in the area. The color separation table A is created using the mask A, and the color separation table B is created using the mask B.

<Color separation table switching process>
The process of step S1102 of FIG. 7 is performed as follows. When the number of nozzles arranged in each print head is m, when performing N-pass printing, the nozzles used in the first pass are from the first nozzle to the m / N-th nozzle. In the second pass, m nozzles after the (m / N + 1) th nozzle are used. Therefore, the color separation table A is created using patterns corresponding to the first nozzle, the (m / N + 1) th nozzle, the (2m / N + 1) th nozzle,. Further, among the patterns of the mask B, a color separation table B is created using patterns corresponding to the (m / N) th nozzle, the (2m / N) th nozzle, the (3m / N) th nozzle, and so on. . Further, for example, color separation data corresponding to nozzles other than the above-mentioned nozzles between the first and m / Nth corresponding to a certain band is obtained as follows. The color separation data of the color separation table A corresponding to the first nozzle is (C1, M1, Y1, K1), and the color separation data of the color separation table B corresponding to the m / Nth nozzle is (C2, M2, Y2 and K2), the color separation data (Cd, Md, Yd, Kd) of the d (1 <d <m / N) th nozzle is obtained by the following equation using the internal division ratio.

(Other embodiments)
In the embodiment described above, the gradation mask and the mask having a different recording ratio for each mask area corresponding to the band for which recording is completed have been described as an example. However, the application of the present invention is not limited to such a mask. It is. It is clear from the above description that the present invention can be applied to any mask as long as the recording ratio corresponding to the nozzle row is not uniform among the nozzle groups. Further, the sum of the recording ratios of the masks corresponding to a plurality of scans may not be 100% as in the above-described example. For example, a mask may be used in which mask elements that allow printing are overlapped between mask areas corresponding to each nozzle group so that the printing ratio is greater than 100%.

  In the first and second embodiments described above, the number of divisions of the mask area corresponding to the band is 2 or 3. However, the present invention is not limited to this example. This number of divisions can be determined, for example, according to density unevenness or color unevenness to be eliminated, and according to processing load.

(Still another embodiment)
In the embodiment described above, the host device performs the color separation process using the color separation table created according to the mask pattern. However, the present invention is not limited to this form. For example, in an ink jet recording apparatus, color separation processing may be performed using a color separation table. In this specification, an apparatus that performs color separation processing using a color separation table in this way, including a host device and an inkjet recording apparatus, is referred to as an image processing apparatus.

201 Recording Head 701 Main Control Unit 702 Recording Buffer 706 Data Buffer 708 Main Control Unit 710 Main Memory

Claims (5)

One nozzle array of a plurality of nozzle groups obtained by dividing the nozzle array by performing a plurality of scans on the recording medium of the recording head using a recording head in which a plurality of nozzles for ejecting ink are arrayed An image processing device for generating recording data corresponding to a length and used for recording for completing an image of a unit area in a recording medium,
For each of the plurality of nozzle groups, a pattern of a printing ratio that is a ratio of mask elements that allow printing is determined, and each of the plurality of scans is performed using a mask in which the pattern of the printing ratio is different among the plurality of nozzle groups A conversion table created on the basis of the measurement result of the recorded patch image, wherein a plurality of scans are performed based on the generated recording data to record a patch image. A patch image measurement result with a plurality of mask recording ratio patterns corresponding to nozzles or nozzle groups that record the same area in the unit area by a plurality of scans, and the other in the unit area by the plurality of scans. Patch image measurement results using a plurality of mask recording ratio patterns corresponding to other nozzles or nozzle groups that record the same area of the mask. Each transformation parameters so as to have been established, using the conversion table for each different the same region, means for generating recording data of the unit area,
An image processing apparatus comprising:   The means determines a nozzle group that records a pixel for conversion or a nozzle group to which a nozzle that records a pixel for conversion belongs, and converts the determined nozzle or the conversion table corresponding to the same area to be recorded by the nozzle group. The image processing apparatus according to claim 1, wherein the image processing apparatus is used.   The image processing apparatus according to claim 1, wherein the recording ratio pattern forms a gradation pattern between the plurality of nozzle groups. One nozzle array of a plurality of nozzle groups obtained by dividing the nozzle array by performing a plurality of scans on the recording medium of the recording head using a recording head in which a plurality of nozzles for ejecting ink are arrayed An inkjet recording apparatus that completes an image of a unit area in a recording medium corresponding to a length,
For each of the plurality of nozzle groups, a pattern of a printing ratio that is a ratio of mask elements that allow printing is determined, and each of the plurality of scans is performed using a mask in which the pattern of the printing ratio is different among the plurality of nozzle groups. Masking means for generating recording data of
With
The mask means is created based on the measurement result of the recorded patch image by performing a plurality of scans based on the recording data generated using the mask in the ink jet recording apparatus. A patch image measurement result based on a plurality of mask recording ratio patterns corresponding to nozzles or nozzle groups that record the same region in the unit region in the plurality of scans, and the plurality of times. Each of the conversions is performed so that the patch image measurement results corresponding to the recording ratio patterns of the plurality of masks corresponding to other nozzles or nozzle groups that record other same areas in the unit area in the scanning of the same are the same. The recording data of the unit area, which is generated using the conversion table for each different same area where parameters are defined An ink jet recording apparatus characterized by the use of a mask, to generate the recording data of each of the plurality of scans for. One nozzle array of a plurality of nozzle groups obtained by dividing the nozzle array by performing a plurality of scans on the recording medium of the recording head using a recording head in which a plurality of nozzles for ejecting ink are arrayed An image processing method for generating recording data corresponding to a length and used for recording to complete an image of a unit area in a recording medium,
A pattern of a printing ratio that is a ratio of mask elements that allow printing is determined for each of the plurality of nozzle groups, and the pattern of the printing ratio is different for each of the plurality of scans using a mask that is different among the plurality of nozzle groups. A conversion table generated based on the measurement result of the recorded patch image, wherein the recording data is generated, a patch image is recorded by performing a plurality of scans based on the generated recording data, The patch image measurement result by the pattern of the recording ratio of the plurality of masks corresponding to the nozzle or the nozzle group that records the same area in the unit area in the scan of the second time, and the other result in the unit area in the scan of the plurality of times The patch image measurement results corresponding to the recording ratio patterns of the plurality of masks corresponding to other nozzles or nozzle groups that record the same area are the same. Each transformation parameters such that has been determined, using the conversion table for each different the same region, the step of generating recording data of the unit area,
An image processing method characterized by comprising:

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