JP6526134B2 - Image forming apparatus, control method therefor, and computer program - Google Patents

Description

  The present invention relates to a color image processing apparatus for correcting the color of an image output from a printer, its control method, and a program for generating image processing parameters.

  In recent years, with the improvement of the performance of the electrophotographic apparatus, machines have come into play that have realized image quality equivalent to that of a printing press. However, due to the instability unique to electrophotography, it remains as a problem that the amount of color variation is larger than that of a printing press. Therefore, various calibration techniques are installed in the conventional electrophotographic apparatus.

  Therefore, in the conventional electrophotographic apparatus, calibration for creating a one-dimensional gradation correction LUT (Look Up Table) corresponding to each of cyan, magenta, yellow, and black toners to correct primary colors is performed. Technology is installed. The LUT is a table indicating output data corresponding to input data divided at specific intervals, and can express non-linear characteristics which can not be represented by arithmetic expressions. When this “monochrome” calibration (hereinafter referred to as “monochrome calibration”) is used to indicate a color represented using a single toner of C, M, Y, K, the reproduction characteristics of single colors such as maximum density and gradation are obtained. It is corrected.

  Further, in recent years, a technique for performing “mixed color” calibration using a four-dimensional LUT has been proposed by Patent Document 1. Here, “mixed color” is a color using a plurality of toners such as red, green, blue, and CMY using two of C, M, and Y, such as gray. In particular, in electrophotography, even when the gradation characteristics of a single color are corrected with a one-dimensional LUT, when “mixed color” is expressed using a plurality of toners, non-linear differences often occur. Here, when the color mixture calibration is performed, the color reproduction characteristics of the color mixture represented by a combination (such as superposition) of toners of a plurality of colors are corrected.

  The flow of calibration including "color mixing" will be described. First, a patch image is printed out on a recording medium such as a sheet of paper using chart data composed of a single color in order to perform “monochrome” calibration. This patch image is an image for measurement having a predetermined area at a single density. A plurality of patch images are generated with different colors, and those generated by printing the patch images on a recording medium are called pattern images. A recording medium such as a sheet of paper on which the pattern image is printed is read by a scanner or a sensor, and the patch image is read. Data obtained by reading the patch image is compared with a preset target value to create a one-dimensional LUT for correcting the difference from the target value. Next, in order to carry out the “color mixing” calibration, a patch image is printed out on a recording medium using chart data composed of color mixing, and this patch image is read by a scanner or sensor. Data obtained by reading the patch image is compared with a preset target value to create a four-dimensional LUT for correcting the difference from the target value.

  Further, in general, in consideration of the reproducibility of the color outputted from the electrophotographic apparatus, it is essential to take into consideration the influence of the difference in the image processing method which is a method for expressing the pseudo gradation. The image processing method mainly has two types of patterns of error diffusion and dither to perform pseudo gradation processing. Since the tone characteristic differs between the error diffusion and the dither in the image processing method, and the color reproducibility differs if the image processing method is different, a correction LUT is required for each image processing method. That is, it is necessary to perform calibration on all image processing methods. However, performing calibration for all image processing methods is not only time-consuming and time-consuming, but also consumes a large amount of consumables such as paper and toner. Therefore, a method for performing single-color calibration as simply as possible has also been proposed. In Patent Document 2, the single-color calibration is executed only for one type of image processing method, and the correction LUTs for the other image processing methods are conversion tables between the image processing methods created in advance by experiment. Making using is disclosed. Thereby, the LUT can be created without bothering the user.

JP 2011-254350 JP 2000-101836

  However, in the prior art, the single-color calibration, which should be originally performed for each image processing method, is simplified while maintaining the accuracy as much as possible. Therefore, in the method disclosed in the prior art, there is a problem that the reproduction characteristics of the color mixture can not be guaranteed at all.

In order to solve the above problems, an image forming apparatus according to the present invention includes an image forming unit capable of forming an image using a plurality of types of recording agents, and one type of the recording agent by the image forming unit. A single-color pattern image forming means for forming a single-color pattern image including a plurality of single-color patch images of different densities, which is a single-color patch image formed; colorimetry of the single-color pattern image formed by the single-color pattern image forming means An image forming apparatus comprising: monochromatic correction data generating means for generating monochromatic correction data for correcting the color of the image formed by the image forming means to a target color using the result of A color mixture patch formed by performing image processing using the single color correction data generated by the generation unit, and formed with two or more types of the recording agents. A mixed-color pattern image forming unit that forms a mixed-color pattern image including a plurality of mixed-color patch images having different colors, which is an image, and a result of measuring the mixed-color pattern image formed by the mixed color pattern image forming unit , possess a color mixture correction data generating means for generating a color mixture correction data for correcting the color to the target color of the image formed by the image forming unit, the image forming apparatus, the gradation by the image forming means The single-color pattern image forming means can execute, for each type of the image processing, the single-color pattern image formed using the image processing. Forming the single-color correction data generation unit using the single-color pattern image formed using the image processing for each type of the image processing; Generating color correction data, the mixed pattern image forming means, among said plurality of types of image processing, and forming the mixed pattern image using a single image processing.

  An object of the present invention is to perform correction of color reproduction characteristics of mixed colors expressed by a combination of toners of a plurality of colors by using the mixed color calibration formed using the result of single color calibration.

It is a block diagram of a system. It is a figure showing the flow of image processing. It is a figure showing the flow of single color calibration. It is a figure showing the flow of mixed color calibration. It is a figure showing a chart image used for single color calibration and mixed color calibration. 5 is a flowchart of a processing procedure in Embodiment 1. 10 is a flowchart of a processing procedure in Embodiment 2. 10 is a flowchart of a processing procedure in Embodiment 2. It is a figure which shows an example of a dither matrix. It is a figure showing a single color calibration and a mixed color calibration execution screen.

Example 1
First, mixed color calibration, which is a feature of the present embodiment, will be described in comparison with single color calibration. As described above, when performing color mixture calibration, it is premised that the single color calibration is completed and the gradation of the single color is corrected. Since the reproduction characteristics of a single color are easily affected by the image processing method, the single color calibration needs to be performed for each type of image processing method. Furthermore, since the color reproducibility of the highlight is unstable, it is required to, for example, increase the patch image of the highlight region.

  On the other hand, in the case of mixed colors, the color plates of C, M, Y and K overlap, so the influence on transfer and fixing at the time of printing greatly contributes to the color.

  That is, since the mixed color patch images formed at the time of mixed color calibration overlap color plates overlap and the dot ratio is high (10 to 15% or more), the color difference generated according to the difference in the image processing method is a single color patch. Less than at the time of image formation.

  From the above, unlike single-color calibration in which differences due to image processing methods are corrected and gradation characteristics are corrected, mixed-color calibration can be said to be processing for correcting deviations in reproduction characteristics caused by changes in engine conditions.

  Further, in contrast to the case where only a single color is used in the single color calibration, correction is performed using a color in which C, M, Y and K are mixed in the mixed color calibration.

  Therefore, the amount of toner used when printing a chart image used when performing mixed color calibration is easily greater than the amount of toner when printing a chart image used when performing single color calibration. Conceivable.

  In addition, when the single-color calibration and the mixed-color calibration are respectively performed for each image processing method, it is easily considered that the number of sheets on which the chart image to be output is printed is also increased.

  In view of the above, this embodiment is characterized in that single color calibration is performed for all image processing methods, and mixed color calibration is performed using only one type of image processing method. By this, the accuracy of mixed color calibration is maintained, and an efficient calibration flow in which consumption of paper and toner is suppressed as much as possible is proposed.

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

  FIG. 1 is a block diagram of a system in the present embodiment. The MFP (Multi Function Printer) 101 of the color image processing apparatus that uses each toner of cyan, magenta, yellow, and black (hereinafter, C, M, Y, K) is connected to another network compatible device via the network 123. There is. The PC 124 is connected to the MFP 101 via the network 123. A printer driver 125 in the PC 124 transmits print data to the MFP 101.

  The MFP 101 will be described in detail. A network I / F 122 receives print data and the like. The controller 102 includes a CPU 103, a renderer 112, and an image processing unit 114. The interpreter 104 of the CPU 103 interprets the PDL (page description language) portion of the received print data and generates intermediate language data 105.

  The CMS 106 performs color conversion using the source profile 107 and the destination profile 108 to generate intermediate language data (after CMS) 111. Here, CMS is an abbreviation of Color Management System, and performs color conversion using profile information described later. In addition, the source profile 107 is a device-independent color space such as L * a * b * (hereinafter, Lab) or XYZ defined by the CIE (International Lighting Commission), depending on the device-dependent color space such as RGB or CMYK. It is a profile for conversion. XYZ is a device-independent color space like Lab, and expresses colors with three types of stimulus values. The destination profile 108 is a profile for converting a device independent color space into a device (printer 115) dependent CMYK color space.

  On the other hand, in CMS 109, color conversion is performed using device link profile 110, and intermediate language data (after CMS) 111 is generated. Here, the device link profile 110 is a profile for directly converting a device dependent color space such as RGB or CMYK into a CMYK color space depending on the device (printer 115). Which CMS is selected from CMS 106 and CMS 109 depends on the setting in the printer driver 125.

  Although CMSs (106 and 109) are divided according to the type of profiles (107, 108 and 110) in this embodiment, one CMS may handle multiple types of profiles. Further, the type of profile is not limited to the example described in this embodiment, and any type of profile may be used as long as the device-dependent CMYK color space of the printer 115 is used.

  The renderer 112 generates a raster image 113 from the generated intermediate language data (after CMS) 111. An image processing unit 114 performs image processing on the raster image 113 and an image read by the scanner 119. Details of the image processing unit 114 will be described later.

  A printer 115 connected to the controller 102 is a printer for forming a color image using output data on paper using colored toners such as C, M, Y, K, and the like. The printer 115 has a paper feed unit 116 for feeding paper, a paper discharge unit 117 for discharging a sheet on which an image is formed, and a measurement unit 126.

  The measurement unit 126 has a sensor 127 of a color measurement unit capable of acquiring spectral reflectance, a device-independent color space value such as Lab or XYZ, and is controlled by a CPU 129 that controls the printer 115. The measurement unit 126 measures a patch image printed out on a recording medium such as a sheet by the printer 115. This patch image is an image for measurement having a predetermined area at a single density. A plurality of patch images are generated with different colors, and those generated by printing the patch images on a recording medium are called pattern images. The pattern image is read by the sensor 127 of the measurement unit 126, and the read numerical information is transmitted to the controller 102. The controller 102 performs an operation using the numerical information, and uses the result of the operation when performing single color calibration or mixed color calibration.

  The display device 118 is a UI (user interface) for displaying an instruction to the user and the state of the MFP 101. It is used when performing single color calibration and mixed color calibration to be described later.

  The scanner 119 is a scanner including an auto document feeder. The scanner 119 irradiates a bundle of or a sheet of original image with a light source (not shown), and forms an image of the original with a lens on a solid-state imaging device such as a CCD (Charge Coupled Device) sensor. Then, a raster-like image reading signal is obtained as image data from the solid-state imaging device.

  The input device 120 is an interface for receiving an input from a user. Some input devices may be touch panels and may be integrated with the display device 118.

  The storage device 121 stores data processed by the controller 102, data received by the controller 102, and the like.

  The measuring device 128 is an external measuring device on the network or connected to the PC 124. Like the measuring unit 126, the measuring device 128 can obtain spectral reflectance and a value of the color space independent of the device such as Lab or XYZ.

  Next, the flow of the image processing unit 114 will be described with reference to FIG. FIG. 2 shows the flow of image processing performed on the raster image 113 and an image read by the scanner 119. The flow of processing in FIG. 2 is realized by execution of an application specific integrated circuit (ASIC) in the image processing unit 114.

  Image data is received in step S201. In step S 202, it is determined whether the data received is the scan data received from the scanner 119 or the raster image 113 sent from the printer driver 125.

  If it is not scan data, it is a raster image 113 which has been bit map developed by the renderer 112, and becomes a CMYK image 211 converted to CMYK depending on the printer device by CMS.

  In the case of scan data, since it is the RGB image 203, color conversion processing is performed in step S204 to generate the common RGB image 205. Here, the common RGB image 205 is defined in a device-independent RGB color space, and can be converted to a device-independent color space such as Lab by calculation.

  On the other hand, character determination processing is performed in step S206 to generate character determination data 207. Here, an edge or the like of the image is detected to generate character determination data 207.

  Next, in step S208, filtering processing is performed on the common RGB image 205 using the character determination data 207. Here, different filtering processing is performed on the character part and other parts using the character judgment data 207.

  Next, the background removal processing is performed in step S209, and the color conversion processing is performed in step S210 to generate the CMYK image 211 from which the background has been removed.

  Next, in step S212, color mixture correction processing using the 4D-LUT 217 is performed. A 4D-LUT is a four-dimensional LUT (Look Up Table) that converts combinations of signal values when outputting C, M, Y, and K toners to different combinations of C, M, Y, and K signal values. It is. The 4D-LUT 217 is generated by “mixed color calibration” described later. By using the 4D-LUT, it is possible to correct “mixed color” which is a color using a plurality of toners.

  Then, after color mixture correction is performed in step S212, the image processing unit 114 corrects the gradation characteristics of each of C, M, Y, and K single colors using the 1D-LUT 218 in step S213. The 1D-LUT is a one-dimensional LUT (Look Up Table) that corrects each color (monochrome) of C, M, Y, and K. This 1D-LUT is generated by "monochrome calibration" described later.

  Finally, in step S214, the image processing unit 114 performs halftone processing such as screen processing and error diffusion processing to create a CMYK image (binary) 215, and transmits image data to the printer 115 in step S216.

  The “monochrome calibration” for correcting the tone characteristic of a single color output from the printer 115 will be described with reference to FIG. By performing single-color calibration, single-color reproduction characteristics such as maximum density characteristics and gradation characteristics are corrected. Color reproduction characteristics corresponding to C, M, Y, K toners used in the printer 115 are corrected together at the time of calibration. That is, the process of FIG. 3 is executed at one time in accordance with each color of C, M, Y, and K.

  FIG. 3 shows the flow of processing for creating a 1D-LUT 218 for correcting the gradation characteristic of a single color. The process flow of FIG. 3 is realized by the CPU 103 executing it, and the created 1D-LUT 218 is stored in the storage device 121. Further, the display device 118 displays an instruction to the user on the UI, and the user instruction is received from the input device 120.

  The chart data (A) 302 stored in the storage device 121 in step S301 is acquired. Chart data (A) 302 is for correcting the maximum density of each single color, and is composed of signal values (for example, 255) that can obtain maximum density data of “monochrome” of C, M, Y, K.

  Next, in step S303, the image processing unit 114 executes image processing on the chart data (A) 302, and the printer 115 prints out a chart image (A) 304, which is a pattern image. An example is shown in FIG. In FIG. 5A, 501 indicates an example when the chart data (A) 302 is printed out, and patch images 502, 503, 504, and 505 are printed at the maximum density of each of C, M, Y, and K colors, respectively. It is output. Thus, the chart image (A) 304 which is a pattern image includes a plurality of patch images. Here, the image processing unit 114 performs only the halftone process in step S214, and does not perform the 1D-LUT correction process of step S213 or the 4D-LUT correction process of step S212.

  Next, in step S305, the density of the print output of the chart image (A) 304 is measured using the scanner 119 and the sensor 127 in the measurement unit 126 to obtain a measured value (A) 306. The measured value (A) 306 is the density value of each of C, M, Y, and K. Next, in step S307, correction of the maximum density of the measured values (A) 306 of each color is executed using the measured values (A) 306 and the target value (A) 308 of the preset maximum density values. Here, the device setting value of the printer 115, for example, the laser output or the developing bias is adjusted so that the maximum density approaches the target value 308 (A).

  Next, chart data (B) 310 stored in the storage device 121 in step S309 is acquired. The chart data (B) 310 is composed of signal values of C, M, Y, K "monochrome" gradation data. An example of a chart image (B) 312 which is a pattern image having a patch image printed out on a recording medium using this chart data (B) 310 is shown in FIG. Reference numeral 506 in FIG. 5B denotes an example of a print output of the chart image (B) 312 having a patch image printed out on a recording medium using the chart data (B) 310. The patch images 507, 508, 509, and 510 shown in FIG. 5B and the tone data subsequent to the right are tone data of C, M, Y, and K colors. Thus, the chart image (B) 312 which is a pattern image includes a plurality of patch images.

  Next, in step S311, the image processing unit 114 executes image processing on the chart data (B) 310, and the printer 115 prints out a chart image (B) 312. Here, only the halftone processing is performed in the image processing unit 114 and step S214, and the 1D-LUT correction processing in step S213 and the 4D-LUT correction processing in step S212 are not performed. Further, since the printer 115 performs the maximum density correction in step S307, the maximum density can be set to a value equivalent to the target value (A) 308.

  Next, in step S313, measurement is performed using the scanner 119 or the sensor 127 to obtain a measured value (B) 314. The measured value (B) 314 is a density value obtained from the gradation of each of C, M, Y, and K colors. Next, in step S315, using the measured value (B) 314 and the preset target value (B) 316, the 1D-LUT 218 for correcting the gradation of a single color is created.

  Next, “mixed color calibration” for correcting the mixed color characteristic output from the printer 115 will be described with reference to FIG. By performing the color mixture calibration, the reproduction characteristics of the color mixture expressed by a combination (such as superposition) of toners of a plurality of colors are corrected. The flow of the following processing is realized by the CPU 103 in the controller 102 executing it. The acquired 4D-LUT 217 is stored in the storage device 121. Further, the display device 118 displays an instruction to the user on the UI, and the user instruction is received from the input device 120.

  The color mixture calibration corrects the color mixture output from the printer 115 after the single color calibration is performed. Therefore, it is desirable to perform mixed color calibration immediately after performing single color calibration.

  The information of the chart data (C) 402 composed of “mixed color” stored in the storage device 121 in step S401 is acquired. Chart data (C) 402 is data for correcting color mixing, and is composed of signal values of “color mixing” which is a combination of C, M, Y, and K. An example of a chart image (C) 404 which is a pattern image having a plurality of patch images printed out on a recording medium using this chart data (C) 402 is shown in FIG. FIG. 5C shows an example 511 when the chart data (C) 402 is printed out, and all patch images printed on the patch images 512 and 511 combine C, M, Y, K. It is composed of mixed colors. Thus, the chart image (C) 404 which is a pattern image includes a plurality of patch images.

  In step S403, the image processing unit 114 executes image processing on the chart data (C) 402, and the printer 115 prints out a chart image (C) 404. Since the color mixture calibration corrects the color mixture characteristics of the device after the single color calibration is performed, the 1D-LUT 218 created at the time of the single color calibration is used to execute the image processing in the image processing unit 114.

  Next, in step S405, the color mixture of the print output of the chart image (C) 404 is measured using the scanner 119 and the sensor 127 in the measurement unit 126, and a measurement value (C) 406 is obtained. The measured value (C) 406 indicates the color mixing characteristics of the printer 115 after the single color calibration. Also, the measured value (C) 406 is a value in a device-independent color space, which is Lab in this embodiment. When the scanner 119 is used, RGB values are converted into Lab values using a 3D-LUT (not shown) or the like.

  Next, in step S 407, the Lab → CMY 3D-LUT 409 stored in the storage device 121 is acquired, and the difference between the measured value 406 (C) and the preset target value (C) 408 is reflected to the Lab. The CMY 3D-LUT (after correction) 410 is created. Here, the Lab → CMY 3D-LUT is a three-dimensional LUT that outputs a CMY value corresponding to the input Lab value.

  The specific creation method is shown below. The difference between the measured value 406 (C) and the preset target value (C) 408 is added to the Lab value on the input side of the 3D-LUT 409 of Lab → CMY, and the Lab value for which the difference is reflected Lab An interpolation operation is performed using the 3D-LUT 409 of CMY. As a result, a Lab → CMY 3D-LUT (after correction) 410 is created.

  Next, in step S 411, the CMY → Lab 3D-LUT 412 stored in the storage device 121 is acquired, and calculation is performed using the Lab → CMY 3D-LUT (after correction) 410. Thus, the CMYK → CMYK 4D-LUT 217 is created. Here, the 3D-LUT of CMY → Lab is a three-dimensional LUT that outputs Lab values corresponding to the input CMY values.

  The specific creation method of the CMYK → CMYK 4D-LUT 217 is shown below. A CMY → CMY 3D-LUT is created from the CMY → Lab 3D-LUT 412 and the Lab → CMY 3D-LUT (after correction) 410. Next, a CMYK → CMYK 4D-LUT 217 is created so that the input value and output value of K become identical. Here, the CMY → CMY 3D-LUT is a three-dimensional LUT that outputs a corrected CMY value corresponding to the input CMY value.

  An example of UI display when selectively performing single color calibration and mixed color calibration is shown in FIG. The UI screen 1001 of FIG. 10 is displayed on the display device 118. A button 1002 receives the start of single-color calibration, and a button 1003 receives a start of mixed-color calibration. Reference numeral 1004 denotes a button for accepting the start of calibration for executing mixed color calibration after execution of single color calibration.

  When the button 1004 is selected, single-color calibration is started and performed, and then mixed-color calibration is started.

  Specifically, after the completion of the single color calibration, the mixed color calibration is started by printing out the chart image (C) 404 for mixed color calibration. Alternatively, a button for starting mixed color calibration may be displayed on the UI screen for the user, and the mixed color calibration may be started after the button is pressed by the user.

  On the other hand, when the button 1002 is selected, only single color calibration is performed. Similarly, when the button 1003 is selected, only mixed color calibration is performed.

  The reason why the button is divided into single color calibration and mixed color calibration will be described. When the chart image (C) 404 used at the time of mixed color calibration is printed out, the 1D-LUT 218 created by single color calibration is used. Therefore, it is desirable that the color mixture calibration be performed immediately after the single color calibration and the color reproduction characteristics be corrected to correct the color reproduction characteristics. However, if both types of calibration are performed, the user spends much processing time for calibration.

  Therefore, in order to shorten the processing time, either the single color calibration or the mixed color calibration is performed according to the use environment of the user. Then, a situation occurs in which the execution frequency of both calibrations is different. For example, a user who frequently performs single-color printing has a low frequency of performing mixed-color calibration. In addition, users who frequently perform mixed color printing such as photography have a high frequency of performing mixed color calibration.

  Also, the timing at which this color correction menu can be selected may be controlled.

  In general, image processing apparatuses often turn off the power at night and turn on the power in the morning. Therefore, when the main power switch of the MFP 101 is turned on and the power is turned on, only the button 1004 can be selected. Alternatively, when both calibrations are not performed within a predetermined time, only the button 1004 may be selected. Alternatively, when printing is performed using a predetermined number of sheets, only the button 1004 may be selected if both calibrations are not performed.

  Alternatively, when a predetermined time has elapsed, printing is performed using a predetermined number of sheets, or the power is turned on, the single color calibration and the color mixture calibration are automatically performed sequentially. May be

  As described above, when the user executes calibration at a predetermined timing, only the button 1004 can be selected, and the user is urged to execute the mixed color calibration immediately after the single color calibration is performed at predetermined time intervals. .

  Therefore, as described above, it is possible to select whether to carry out both color calibration and color calibration or to carry out either color calibration or color calibration after executing the single color calibration. This makes it possible to perform a calibration suitable for the user's use.

  In addition, by controlling to be able to select to execute both calibrations at predetermined time intervals, it is possible to suppress the decrease in correction accuracy of the reproduction characteristics due to the calibration by executing only one of the calibrations. Becomes possible. In the present embodiment, when 1004 in FIG. 10 is selected and it is instructed that mixed color calibration is to be performed after the single color calibration is performed, the operation shown in FIG. 6 is performed.

  FIG. 6 is a flow showing the flow of processing in this embodiment. A control program (not shown) for realizing the present embodiment is stored in the storage device 121, loaded into a RAM (not shown), and executed by the CPU 103.

  The present method will be described along the flow of the flowchart of FIG. First, in S600, the single color calibration shown in FIG. 3 is performed. At this time, in the execution and output of the image processing of S311, the image processing unit 114 performs an arbitrary type of image processing method, and the 1D-LUT 218 is created after S315. Next, it is determined whether or not the 1D-LUT 218 has been generated by all types of image processing methods applied in S601. If the 1D-LUT 218 of all kinds of image processing methods to be applied is not updated, the process returns to S600, and the single color calibration is continued. At that time, the correction of the maximum density (S301 to S307) is not performed, and the tone correction of S309 is performed. This is because the maximum density correction result is the same regardless of which image processing method is used to update the 1D-LUT using the chart image output.

  At this time, in the execution and output of the image processing in step S311, the image processing unit 114 selects an image processing method that has not yet output a chart image for performing single-color calibration.

  There are several types of image processing methods, such as those applied when processing scan data, those applied when processing raster data such as bitmaps in PDL jobs, and those applied when processing text. . Therefore, in order to update the 1D-LUT 218 corresponding to each of the prepared image processing methods, S600 is repeated a plurality of times. Alternatively, when the calibration is started by designating the usage in advance, the calibration may be repeated using only the chart image output by the image processing method of the designated usage.

  A specific example of the image processing method will be described with reference to FIG. FIG. 9 shows an example of dither generated by pseudo gradation processing performed using dither matrices of different numbers of lines and different angles. The image processing method 1 having the smallest number of lines has high stability, and the image processing method 2 having a relatively large number of lines has less interference with the period of the input image than the image processing method 1 has. The image processing method 3 with the highest number of lines makes the character edge smooth. As described above, each image processing method has unique features, and an optimum one is used depending on the job type and object of the output image. The image processing method for the color mixture chart will be described in detail later.

  If it is determined in step S601 that the 1D-LUT 218 of all image processing methods has been updated, the process advances to step S602 to determine the image processing method of the chart image used for color mixture calibration. As described above, there are a plurality of image processing methods, but it is also possible to select one of them or to set an image processing method for color mixture correction in advance. FIG. 9 (a) shows a dither matrix used in the former case. That is, the image processing method 2 having an intermediate number of lines, which is one of the image processing methods used when creating the chart image used for single color calibration, is selected, and the chart image used for mixed color calibration is output. Used when. FIG. 9 (b) shows a dither matrix used in the latter case. That is, the image processing method at the time of outputting the chart image used for mixed color calibration is prepared separately from the image processing method used at the time of creating the chart image used for single color calibration. In this case, among the plurality of usable image processing methods, other than the first image processing method is used when outputting a chart image using for single color calibration. Then, the first image processing method is used when outputting a chart image to be used for mixed color calibration.

  Further, an image processing method to be selected when outputting a chart image to be used for mixed color calibration is usually determined in advance, and the selection may be arbitrarily switched by the user. The dither used in each image processing method is usually different for each of C, M, Y, and K. Although representative types are shown in FIG. 9 to show the features of the image processing method, in practice, the image processing methods of C, M, Y, and K of a predetermined combination are selected as a set. . Hereinafter, the image processing method refers to a set of C, M, Y, and K image processing methods.

  If the image processing method is determined in step S602, the process advances to step S603 to execute mixed color calibration. The details of the color mixture calibration performed in step S603 are as shown in FIG. 4. When the image processing is performed in step S403, the image processing to which the color mixture image processing method determined in step S602 is applied is performed. The change in color mixture reflects the change in engine condition more than the difference in image processing methods. Therefore, the effect of the color mixture calibration can be obtained by correcting each color with only one type of image processing method. Further, the image processing method may be not only the dither method shown in FIG. 9 but also a plurality of types such as an error diffusion method or an FM screen method.

  As described above, in the present embodiment, in the color mixture calibration, a chart output by one selected image processing method is not used to perform correction using a plurality of chart images output by all image processing methods. Make corrections using only the image. As a result, it is possible to suppress an increase in the amount of paper and toner to be used while obtaining the effect of correction, and to correct the reproduction characteristics of color mixture without increasing the time and effort required for the user.

  Furthermore, in the present case, when performing single-color calibration, the single-color reproduction characteristics are corrected using the results of measurement using chart images created using all image processing methods.

  Therefore, since the reproduction characteristics of the single color can be corrected with high accuracy, it is possible to maintain the accuracy of correction by the mixed color calibration on the premise that the single color calibration is properly performed.

(Example 2)
Here, only differences from the first embodiment will be described. In the present embodiment, the usage condition of the user is analyzed, and mixed color calibration is performed using a chart image output by the image processing method most frequently used. It can be said that the reproduction characteristics of the color mixture are hardly affected by the difference in the image processing method. However, as a matter of course, the image processing method used when the chart image for calibration is output can be most accurately corrected. Therefore, by outputting a chart image for mixed color calibration using an image processing method frequently used by the user, it is possible to carry out mixed color calibration that is most effective for the user.

  FIG. 7 is a flow showing the flow of processing in this embodiment. The difference from the first embodiment is that the usage condition of the user is analyzed in step S701 before the color mixture calibration. The analysis S701 of the use status of the user will be described in detail with reference to FIG.

  FIG. 8 is a flow of data collection for performing an analysis S 701 of the use status of the user. A program for performing the analysis S 701 of the user's usage status is stored in the storage device 121, loaded into a RAM (not shown), and executed by the CPU 103. The case of printing the raster image 113 sent from the printer driver 125 will be described as an example. First, in step S801, whether there is a plurality of image processing methods used when printing one page of image data, that is, whether there is a switch of the image processing method when forming image data of one page to be printed Determine Since switching of the image processing method is generally performed based on the image area data of the input image, it is determined whether there is a switch of the image processing method by referring to the image area data. Alternatively, if it is possible to determine whether or not there is a switch in the image processing method from other output settings, it may be used. If it is determined in S801 that the image processing method has not been switched in the page, the processing proceeds to S804. Then, in S804, only one type of image processing method used at the time of output is counted. The count result is stored in the storage device 121. On the other hand, if it is determined in S801 that the image processing method is switched in the page, the process proceeds to S802.

  Then, in S802, the usage rates (in-page usage rates) of various image processing methods in the page are acquired.

  The in-page usage rate indicates the rate at which each of the image processing methods was used when printing one page.

  If the in-page usage rate of each image processing method acquired in S802 is equal to or higher than the threshold value for any image processing method, the process advances to S803. In step S803, all image processing methods used are counted. On the other hand, if only the in-page usage rate of the specific image processing method among the in-page usage rates of the respective image processing methods acquired in S802 is equal to or more than the threshold value, the process proceeds to S804. Then, in S804, only a specific image processing method having a high in-page usage rate is counted. A threshold for determining whether the in-page usage rate is high is set in advance. For example, when the setting is 30%, an image processing method with an in-page usage rate of 30% or more is determined to be an image processing method with a high in-page usage rate, and an image processing method with an in-page usage rate of 30% or less is a page It is determined that the image processing method has a low internal usage rate.

  Referring back to the flow of FIG. 7, in S702, the image processing method most frequently used in the data collection period is determined from the data collected in S701.

  The overall usage rate of the image processing method is obtained by calculating the number of times each image processing method has been used (count number) with respect to the number of times all types of image processing methods have been used (total count number). The utilization of the method is obtained. Also, the period to be counted (period for collecting data) may be from the previous mixed color calibration execution until the analysis of the user's usage status in S701, for example, every predetermined period such as one month. May be. When the number of persons sharing the electrophotographic apparatus is small, it may be effective to adopt the number of counts acquired in a short period of time.

  Next, in step S703, mixed color calibration is performed. Although the details are as shown in FIG. 4, when the image processing is performed in S403, the image processing method determined in S702 is applied.

  In the description of the present embodiment, as shown in FIG. 8, the method of counting the image processing method by determining the presence or absence of the switching of the image processing method when printing one page was described, but the image processing method is used If there is another effective method that can extract the frequency of occurrence, it may be used. For example, when the image processing method is different between the copy job and the PDL job, a method of counting the switching of the image processing method for each job type is also effective. As described above, by analyzing the use situation of the user and performing mixed color calibration using the chart image created by the most frequently used image processing method, the image of the feature that the user frequently sees Correction of color mixture reproduction characteristics most suitable for

(Other embodiments)
The present invention is also realized by performing the following processing. That is, software (program) for realizing the functions of the above-described embodiment is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU or the like) of the system or apparatus reads the program. It is a process to execute.

  The above embodiments have been described using an electrophotographic apparatus as an example, but an inkjet printer, a thermal printer, etc. may be used, and the gist of the present invention is not limited to the type of printer. Also, although the toner in the electrophotographic printing has been described as an example of the recording agent, the recording agent used for printing is not limited to the toner but may be another recording agent such as ink, and the main subject of the present invention is the type of recording agent It is not limited to

Claims (7)

An image forming unit capable of forming an image using a plurality of types of recording agents;
It is a single color patch image formed of one type of the recording material by the image forming unit,
Monochrome pattern image forming means for forming a monochrome pattern image including a plurality of the monochrome patch images of different densities;
Using the result of colorimetry of the single-color pattern image formed by the single-color pattern image forming means, a single-color correction data for correcting the color of the image formed by the image forming means to a target color Correction data generation means;
In an image forming apparatus having
A mixed-color patch image formed by performing image processing using the single-color correction data generated by the single-color correction data generation unit, and formed of two or more types of recording agents, wherein the mixed-color patch is different in color Mixed-color pattern image forming means for forming a mixed-color pattern image including a plurality of images;
Color mixing to generate color mixing correction data for correcting the color of the image formed by the image forming means to a target color using the result of colorimetry of the color mixture pattern image formed by the color mixing pattern image forming means have a correction data generation means,
The image forming apparatus can execute a plurality of types of image processing for artificially expressing gradations by the image forming means.
The single-color pattern image forming means forms the single-color pattern image formed using the image processing for each type of the image processing,
The single color correction data generation unit generates the single color correction data using the single color pattern image formed using the image processing for each type of the image processing.
The image forming apparatus is characterized in that the mixed color pattern image forming unit forms the mixed color pattern image using one image processing among the plurality of types of image processing . 2. The image forming apparatus according to claim 1 , wherein the mixed color pattern image forming unit forms the mixed color pattern image after the single color correction data is generated by the single color correction data generating unit. At least an instruction to generate the single color correction data by the single color correction data generation unit, and an instruction to generate both the single color correction data by the single color correction data generation unit and the color mixture correction data by the color mixture correction data generation unit. the image forming apparatus according to claim 1 or 2, and accepting means for accepting from a user, characterized by having a a. It further has an input means for inputting image data,
The image forming means uses the color mixture correction data generated by the color mixture correction data generation means and the image data input through the input means using the single color correction data generated by the single color correction data generation means. The image forming apparatus according to any one of claims 1 to 3 , wherein the color of the image is corrected. The image forming means corrects the color of the image data input through the input means using the color mixture correction data, and then corrects the color of the image data using the single color correction data. The image forming apparatus according to claim 4 , wherein A control method of an image forming apparatus having an image forming unit capable of forming an image using a plurality of types of recording agents, comprising:
A single-color pattern image forming step of forming a single-color pattern image including a plurality of single-color patch images having different densities, which is a single-color patch image formed of one of the plurality of types of recording agents;
In the single-color pattern image forming step, a single-color correction data for correcting the color of the image formed by the image forming means to a target color using the result of colorimetry of the formed single-color pattern image A control data generation step of controlling the image forming apparatus;
A mixed-color patch image formed by performing image processing using the single-color correction data generated in the single-color correction data generation step, and formed of two or more types of the recording material, wherein the mixed-color patch is different in color A color mixture pattern image forming step of forming a color mixture pattern image including a plurality of images;
Color mixing to generate color mixing correction data for correcting the color of the image formed by the image forming means to a target color using the result of measuring the color mixing pattern image formed by the color mixing pattern image forming step have a correction data generating step,
It has a plurality of image processing steps of executing image processing for artificially expressing gradations in the image formed by the image forming means,
The single-color pattern image and the mixed-color pattern image are formed by image processing in the image processing step,
The image forming apparatus can execute a plurality of types of image processing for artificially expressing gradations by the image forming means.
In the single color pattern image forming step, the plurality of types of image processing are executed to form a single color pattern image corresponding to each of the image processing,
A control method of an image forming apparatus, wherein in the mixed color pattern image forming step, one of the plurality of image processings is performed to form a mixed color pattern image . A computer program for causing a computer to realize the control method of an image forming apparatus according to claim 6 .

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