JP2015092220A - Image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image forming apparatus that improves image reproducibility of a multi-order color focusing on primary colors and multi-order colors in an image formed according to an instruction by a user.SOLUTION: An image forming apparatus includes a main scanning correction unit 406k that calculates a coefficient of correction corresponding to density gradation information for primary colors constituting a multi-order color formed according to an instruction by a user, corrects a measurement color for a multi-order color on the basis of the difference between a result of colorimetry and a result of the acquisition of the density gradation information on the primary colors constituting the multi-order color, and corrects a gradation reproduction curve, which is an image forming processing parameter, on the basis of information on the corrected measurement color.

Description

  The present invention relates to an image forming apparatus, and more particularly to an image density control method for improving multi-color reproducibility.

In copiers, printers, and printing presses that use electrophotography, if the environment such as temperature and humidity changes, or if continuous printing operations are performed over a long period of time, the amount of toner adhered to the toner image per unit area will increase. It may change and change the image density.
In a color image forming apparatus that forms a color image, if the toner adhesion amount varies for each of a plurality of primary colors, the color tone of the multi-order color (for example, L * value and a * value in the L * a * b * color system). And b * value) are disturbed.
Specifically, colors reproduced by the color image forming apparatus are roughly classified into primary colors and multi-order colors. Of these, the primary color is a color expressed by only one type of toner.
For example, in a configuration using four types of toners of yellow (Y), magenta (M), cyan (C), and black (K), it is expressed by only one of Y, M, C, and K toners. The color to be performed is the primary color. In contrast, a multi-order color is a color expressed using two or more types of toner. Multi-order colors are reproduced by superimposing a plurality of primary color toner images. However, if the amount of toner attached to each primary color toner image fluctuates, the color tone of the multi-order color toner image is determined by the superposition of these primary color toner images. Will be disturbed.

Therefore, in a color marking device used for color adjustment calibration, a test pattern of multi-order colors and multi-tones is output on test print paper, and the image processing conditions relating to image density etc. are estimated by analogizing the density from the reflectance data. It is known to control (for example, Patent Documents 1 and 2).
That is, in the control method disclosed in the patent document, a calibration for determining image processing conditions, specifically, a gradation reproduction curve, on a test print paper separately from the print paper on which an image based on a user instruction is output. A plurality of test patterns are formed.
Then, the color reference L * value, a * value, and b * value of each test pattern are detected, and the gradation reproduction curve is corrected according to each result. Thereafter, a multi-color and multi-tone toner image is formed based on the corrected tone reproduction curve. As a result, even when the state of the image forming process changes, it is possible to suppress a change in the color output on the paper surface and obtain a stable image quality.

By the way, in recent years, color production printers have been developed that realize color-on-demand printing that outputs a large amount of color documents such as leaflets, catalogs, reports, and invoices at high speed.
Such a color production printer is used when, for example, invoices and receipts for tens of millions of telephone charges are issued with an issue deadline of about one week. Continuously prints in day and night.
In other words, hundreds of high-speed prints per minute are continuously operated in units of tens of hours.
Under such circumstances, the high-speed type color production printer has a characteristic that the apparatus cannot be stopped during continuous operation.
This is because stopping the device may cause the issue deadline for a huge number of copies to be missed.

In this respect, a high-speed type color production printer is technically different from a printer (MFP: Multifunction Peripheral) installed in an office.
Therefore, in the control of the set value representing the gradation reproduction curve of the image processing parameter as described above, the test print paper outputting the above test pattern is discharged separately from the print paper outputting the image based on the user's command. As a result, the user is forced to sort them.
Since such a sorting operation is very laborious, it is not practical to employ a configuration that outputs a test toner pattern.
For this reason, the control of the set value representing the gradation reproduction curve as described above cannot be performed frequently.
In particular, when high-speed printing of several hundred sheets per minute is performed continuously in units of several tens of hours as in the high-speed type color production printer as described above, the printing operation is performed once every few minutes. The control of the set value representing the gradation reproduction curve is executed by stopping.
This is contrary to the characteristics of a high-speed color production printer that must never be stopped during continuous operation as described above.
In addition, if a continuous operation is performed without executing the control of the set value representing the gradation reproduction curve, the process state changes greatly, and the image quality deteriorates. That is, for a high-speed type color production printer, a new configuration is required that can control the set value that represents the gradation reproduction curve in real time without stopping the printing operation. .

Therefore, as a configuration that can control the set value that represents the gradation reproduction curve in real time at all times, a method of measuring colors from image information based on user instructions without using a test print that created a test pattern is proposed. (For example, Patent Document 3).
Patent Document 3 discloses the following method.
Each measurement color and each density for each image information, which is a result of searching a colorimetric adaptation area of the searched multi-order color toner image by searching a region suitable for colorimetry with respect to a user image output based on a user command And the difference between the reference color and the current setting value representing the gradation reproduction curve. Then, the correction amount of the setting value representing the gradation reproduction curve is determined so as to make this difference smaller, and the setting value representing the gradation reproduction curve is corrected based on the determined correction amount.
As a result, by appropriately correcting the setting value representing the gradation reproduction curve without forming a test pattern, the color can be accurately reproduced without forcing the user to sort the test print paper on which the test image is output. be able to.

However, unlike the test pattern, the color density distribution in the image information output by the user's command is often biased. In other words, the test pattern includes even colors from high to low colors, but the color density distribution in the image information output by the user's command does not always include the colors uniformly. Also, color density distributions are often different in a plurality of pieces of image information output in accordance with user instructions.
Therefore, each density and each measured color of the color measurement results are averaged to smooth the unevenness of the color density distribution in each image information, so that even if the image information in which the color density distribution is biased is corrected. The smoothness of the tone reproduction curve is not lost, and the effects of in-plane color fluctuations and measurement errors due to the eccentricity of the photoconductor drum are averaged. There is already known a method of performing correction corresponding to the image density variation due to continuous printing operation with time.

On the other hand, in addition to the correction target using the above-described method, it is necessary to consider the fact that a mechanical accuracy error such as the eccentricity of the photoconductor used for image formation affects the density fluctuation. This mechanical accuracy error causes the color to not be accurately reproduced.
In other words, when the colorimetric measurement is performed with the user image color measurement place biased to a place where the image density fluctuation is small, the average fluctuation amount is small. On the other hand, if the color measurement is performed with a bias toward a location where the image density fluctuation is large, the fluctuation amount may increase.
When the image density is corrected by the tone reproduction curve created based on such a colorimetric result, the image density fluctuation due to the eccentricity of the photosensitive drum or other rotational drive is superimposed on the output image. Will be. As a result, there is a possibility that the color cannot be accurately reproduced.
For this reason, in order to accurately reproduce the color, a new configuration is required that suppresses the influence of fluctuations in image density due to the photosensitive drum and other eccentricity of rotational drive.

In response to this requirement, the image density fluctuation caused by the periodic fluctuations in a plurality of drive mechanisms including the image carrier is measured, and the image density information for each periodic component and the color measurement in the corresponding color measurement adaptive area are performed. The applicant has proposed a method of correcting based on the difference from the result (for example, Reference 1).
In this method, the image density difference for each pixel position in the main scanning direction is converted into image density difference information for each pixel position with respect to the main scanning direction obtained from a dedicated chart of multiple colors (C, M, Y, K). Based on this, the main scanning correction coefficient is calculated in advance.
Then, by correcting the colorimetric adaptation area of the user image formed based on the user command based on the main scanning correction coefficient, the image density difference with respect to the main scanning direction can be measured in any area. Measurement results with reduced can be obtained. Based on this result, the tone reproduction curve is corrected according to the difference between the colorimetric result obtained by correcting the image density difference in the main scanning direction and the image density variation information.

As described above, the colorimetric result obtained by measuring the color of the image area formed with the measurement color with the gradation reproduction curve corrected according to the difference between the image density difference and the image density fluctuation information. Can be corrected based on a main scanning correction coefficient acquired in advance.
However, in the image forming apparatus, apart from performing correction by the colorimetric result for the primary color within the colorimetric region, a countermeasure when a multi-color is formed is also a highly accurate density reproduction. It becomes important.
In other words, when the main scanning correction is performed from the color measurement result when the color measurement adaptive area of the user image formed with multi-order colors is measured, the correction may be performed using the main scanning correction coefficient of which image density of which color. It may not be clear. For example, if correction is performed using main scanning correction coefficients for all primary colors related to the formed multi-order color, multiple correction is performed, and a correct color measurement result cannot be obtained. It may not be possible to reproduce with high accuracy.

  An object of the present invention is to provide an image forming apparatus capable of accurately reproducing multi-order colors when using the color measurement results for multi-order colors in the color measurement measurement region.

In order to achieve this object, the present invention comprises an area search means for searching for an area to be measured from images formed on a plurality of image carriers, respectively.
A density colorimetric means for measuring color density fluctuations caused by periodic fluctuations in a plurality of drive units including an image carrier;
Periodic component acquisition means for acquiring periodic components in a plurality of drive units including the plurality of image carriers;
Image density information for each periodic component acquired by the periodic component acquisition means, holding means for holding pixel position information corresponding to the image density information, the pixel position information held in the holding means, and the image A main body control unit that corrects the image processing parameter with the measurement color corrected based on a difference from the color measurement result measured in the color measurement adaptation region corresponding to the density information, and the main body control unit includes: A main scanning correction unit that corrects a density variation amount according to the colorimetric adaptation region, and the main scanning correction unit calculates a correction coefficient from a color arrangement of the image density of the image information according to the colorimetry adaptation region. The colorimetric result measured by the colorimetric means for measuring the image density is measured based on the measured color corrected by the correction coefficient and the measured image information in the colorimetric adaptation region. Complement color An image forming apparatus that corrects an image processing parameter based on a difference between a synthesis period of periodic components extracted from a result of colorimetry of a colorimetric adaptive region and a periodic component of master information synthesized in the same cycle It is in.

  According to the present invention, when color measurement is performed on an area in which the image density of the color measurement adaptation area for performing color measurement is a multi-order color, the color density (RGB) of each primary color constituting the multi-order color. Value) are compared, and correction is performed using the main scanning correction coefficient in the color density gradation range of the primary color having the minimum value for each primary color. As a result, the tone reproduction curve is corrected based on the corrected colorimetric result, and therefore, even in the colorimetric adaptation region composed of multi-order colors, the density difference of the pixel position with respect to the main scanning direction included in the colorimetric result. Can be corrected correctly, and multi-order colors can be accurately reproduced.

1 is a schematic diagram for explaining an example of a configuration of an image forming apparatus according to an embodiment for carrying out the present invention. FIG. 2 is a schematic diagram for explaining a configuration of an image forming unit used in the image forming apparatus shown in FIG. 1. FIG. 2 is a block diagram for explaining a configuration of a control unit used in the image forming apparatus shown in FIG. 1. It is a block diagram for demonstrating the structure of the principal part of the control part shown in FIG. It is a figure which shows the density difference in the main scanning direction for every density | concentration gradation. It is a figure which shows the exclusive pattern in which the image pattern of a different density gradation divided | segmented by the predetermined pixel number range in the subscanning direction was formed. It is a table | surface figure which shows the relationship with the correction coefficient data for every density gradation which makes object for 1 color. It is a figure which shows the main scanning density difference confirmed in the multi-order color pattern. It is a figure which shows the relationship between the tendency of the main scanning density | concentration difference shown in FIG. 6, and the RGB value of image density. It is a flowchart for demonstrating the procedure which calculates | requires the density | concentration correction coefficient by the exclusive pattern formation for 1 color object. It is a flowchart for demonstrating the procedure for correct | amending the density difference of the primary color and multi-color of the image formed by the user command.

Hereinafter, embodiments for carrying out the present invention will be described with reference to illustrated embodiments.
FIG. 1 is a diagram showing an overall configuration of an image forming apparatus according to an embodiment of the present invention, and the image forming apparatus shown in FIG. 1 is a color production printer capable of high-speed printing.
In FIG. 1, in the configuration of the color production printer 100 (hereinafter simply referred to as the printer 100), the configuration for executing exposure, charging, development, transfer, and fixing in the image forming process is shown. Preface that you are.

In addition to the components shown in FIG. 1, the printer 100 includes a paper feeding device that supplies the recording paper 115 as a recording material, a manual tray for manually feeding the recording paper 115, and an image-formed recording. A paper discharge tray or the like (none of which is shown) for discharging the paper 115 is provided.
The printer 100 is provided with an endless belt-like intermediate transfer belt 105 that is an intermediate transfer member.
The intermediate transfer belt 105 is endlessly moved in the counterclockwise direction in the figure by the rotational drive of the support roller 112 having a function as a drive roller while being stretched around the four support rollers 112, 113, 114, and 119. .
Four image forming units 103Y, 103C, M, and K for each color of yellow (Y), cyan (C), magenta (M), and black (K) are disposed on the stretched portion of the intermediate transfer belt 105. ing.
The image forming units 103Y, 103C, 103M, and 103K have substantially the same configuration except that the toner colors used are different.
Note that the subscripts Y, C, M, and K added to the end of the reference numerals indicate members and devices for Y, C, M, and K.

The image forming units 103Y, 103C, 103M, and 103K are drum-shaped photoconductors 101Y, 101C, 101M, and 101K that can carry an image, developing devices 102Y, 102C, M, and K, a charging device that uniformly charges the photoconductor. It has.
In the loop of the intermediate transfer belt 10, primary transfer rollers 106 Y, C, M, and K are disposed at positions facing the photoconductors 101 Y, C, M, and K via the belt so that the belt is exposed to light. The body 101Y, C, M, K is pressed.
As a result, primary transfer nips for Y, C, M, and K in which the photoconductors 101Y, C, M, and K abut on the intermediate transfer belt 105 are formed.

Above the intermediate transfer belt 105, toner bottles 104Y, 104C, M, and K for storing Y, C, M, and K toners to be supplied into the developing devices 102Y, 102C, 102M, and 102K are disposed. .
The charging devices of the image forming units 103Y, 103C, 103M, and 103K uniformly charge the surfaces of the photoreceptors 101Y, 101C, 101M, and 101K as latent image carriers to the same polarity as the toner charging polarity.
In the figure, as an example of the charging device, a charging brush roller to which a charging bias is applied is shown in contact with or close to the photosensitive members 101Y, 101C, 101M, 101K, but other devices such as a scorotron charger are also shown. You may use the charging device of the structure.
A latent image writing unit 200 is provided below the image forming units 103Y, 103C, M, and K.

The latent image writing unit 200 drives a semiconductor laser (not shown) based on image information sent from an external personal computer or the like.
When the semiconductor laser is driven, writing light Lb for Y, M, C, and K is emitted, and the writing light Lb is deflected in the main scanning direction by a polygon mirror (not shown) so as to serve as a latent image carrier. 101Y, C, M, and K are optically scanned. As a result, electrostatic latent images for Y, C, M, and K are written on the surfaces of the uniformly charged photoreceptors 101Y, C, M, and K.
The light source is not limited to the semiconductor laser, and may be, for example, an LED (light emitting diode).

FIG. 2 shows the configuration of the image forming units 103Y, 103C, 103M, and 103K.
The four image forming units 103Y, 103C, 103M, and 103K have substantially the same configuration except that the colors of the toners to be used are different. In FIG. 2, only one of the four image forming units 103Y, 103C, 103M, and 103K is used. Is shown.
The suffix (Y, C, M, K) at the end of the code is omitted without limiting which color unit.
In the following description, the suffixes (Y, C, M, K) at the end of the reference numerals are omitted.

The image forming unit 103 includes a charging device 301 for charging the photosensitive member 101, a developing device 102, a photosensitive member cleaning device 311, and the like around the photosensitive member 101.
In the loop of the intermediate transfer belt 105, a primary transfer roller 106 is disposed at a position facing the photoconductor 101 through the belt.
Instead of the primary transfer roller 106, a conductive brush shape or a non-contact corona charger may be employed.

The charging device 301 is of a contact charging type employing a charging roller, and uniformly charges the surface of the photoconductor 101 by applying a voltage in contact with the photoconductor 101.
As the charging device 301, a non-contact charging type using a non-contact scorotron charger or the like can also be used.

The developing device 102 contains a developer (not shown) containing a magnetic carrier and a nonmagnetic toner. As the developer, a one-component developer may be used.
The developing device 102 can be broadly divided into a stirring unit 303 and a developing unit 304 provided in the developing case.
In the agitation unit 303, a two-component developer (hereinafter simply referred to as “developer”) is conveyed while being agitated and supplied onto a developing sleeve 305 as a developer carrier.
The stirring unit 303 is provided with two parallel screws 306.
Between these two screws 306, a partition plate 309 is provided for partitioning so that both ends communicate with each other.
Further, a toner density sensor 418 for detecting the toner density of the developer in the developing device 102 is attached to the developing case 308 that houses the developing sleeve 305, the two screws 306, and the like.

On the other hand, in the developing unit 304, the toner in the developer attached to the developing sleeve 305 is transferred to the photoreceptor 101.
The developing unit 304 is provided with a developing sleeve 305 that faces the photoreceptor 101 through the opening of the developing case, and a magnet (not shown) is fixedly disposed in the developing sleeve 305. A doctor blade 307 is provided so that the tip approaches the developing sleeve 305.
In the configuration shown in the figure, the distance at the closest portion between the doctor blade 307 and the developing sleeve 305 is set to 0.9 [mm].
In the developing device 102, the developer is conveyed and circulated while being stirred by two screws 306, and is supplied to the developing sleeve 305.

The developer supplied to the developing sleeve 305 is drawn up and held by a magnet.
The developer pumped up by the developing sleeve 305 is conveyed as the developing sleeve 305 rotates, and is regulated to an appropriate amount by the doctor blade 307. The regulated developer is returned to the stirring unit 303.
The developer thus transported to the developing area facing the photoconductor 101 is brought into a spiked state by a magnet and forms a magnetic brush.
In the developing region, a developing electric field for moving the toner in the developer to the electrostatic latent image portion on the photoreceptor 101 is formed by the developing bias applied to the developing sleeve 305.
As a result, the toner in the developer is transferred to the electrostatic latent image portion on the photosensitive member 101, and the electrostatic latent image on the photosensitive member 101 is visualized to form a toner image.
The developer that has passed through the developing region is transported to a portion where the magnetic force of the magnet is weak, thereby leaving the developing sleeve 305 and being returned to the stirring unit 303.

When the toner concentration in the stirring unit 303 becomes light by repeating such operations, the toner concentration sensor 418 detects this, and toner is supplied to the stirring unit 303 based on the detection result.
The photoconductor cleaning device 311 includes a cleaning blade 312 made of polyurethane rubber, for example, which is disposed so that the tip of the cleaning blade 312 can be pressed against the photoconductor 101.
In this embodiment, in order to improve the cleaning performance, a conductive fur brush 310 that contacts the photoconductor 101 is also used.
A bias is applied to the fur brush 310 from a metal electric field roller (not shown), and the tip of a scraper (not shown) is pressed against the electric field roller.
The toner removed from the photoconductor 101 by the cleaning blade 312 and the fur brush 310 is accommodated in the photoconductor cleaning device 311 and collected by a waste toner collecting device (not shown).

In the image forming unit 103, the surface of the rotationally driven photoconductor 101 is uniformly charged by the charging device 301.
Then, based on image information from the print controller 410 (see FIG. 3), the latent image writing unit 200 performs optical scanning with the writing light Lb to write an electrostatic latent image on the surface of the photoconductor 101.
The electrostatic latent image is developed by the developing device 102 to become a primary color toner image having a primary color of Y, M, C, or K.
This primary color toner image is primarily transferred from the surface of the photoreceptor 101 to the surface of the intermediate transfer belt 105 in the primary transfer nip.
The transfer residual toner adhering to the surface of the photoconductor 101 after passing through the primary transfer nip is removed by the photoconductor cleaning device 311.
In FIG. 1 described above, the image forming units 103Y, 103C, 103M, and 103K form Y, C, M, and K toner images on the surfaces of the photoconductors 101Y, 101C, M, and K by the process described above. To do.

These Y, C, M, and K toner images are primarily transferred while being superimposed on the front surface of the intermediate transfer belt 105 at the primary transfer nip for Y, M, C, and K.
As a result, a four-color superimposed toner image is formed on the front surface of the intermediate transfer belt 105.
Outside the loop of the intermediate transfer belt 105, a secondary transfer roller 108 that is in contact with a place where the intermediate transfer belt 105 is wound around the support roller 112 and forms a secondary transfer nip is formed. It is arranged.
A secondary transfer bias having a polarity opposite to the charging polarity of the toner is applied to the secondary transfer roller 108.

A pair of registration rollers is disposed below the secondary transfer nip, which feeds the recording paper 115 toward the secondary transfer nip at a timing synchronized with the four-color superimposed toner image of the intermediate transfer belt 105. .
A four-color superimposed toner image on the intermediate transfer belt 105 is secondarily transferred onto the recording paper by the action of the secondary transfer bias and the nip pressure on the recording paper that has entered the secondary transfer nip.
The four-color superimposed toner image is combined with the white color of the recording paper 115 to become a full-color toner image.

A scorotron charger or the like may be used instead of the secondary transfer roller 108.
Above the secondary transfer roller 108 in the figure, a fixing device 111 is provided for fixing the full color toner image transferred onto the recording paper 115 to the recording paper 115.
The fixing device 111 has a configuration in which a pressure roller 118 is pressed against a heating roller 117. The fixing device 111 is a color measuring unit that performs color measurement using a full-color toner image formed on the recording paper P after passing through the fixing nip formed by the contact between the heating roller 117 and the pressure roller 118 as a test target. The spectrometer 109 is provided.
Examples of the spectrometer 109 include those disclosed in Japanese Patent Application Laid-Open No. 2005-315883.
A belt cleaning device 110 is disposed outside the belt loop.
The belt cleaning device 110 is in contact with a portion where the intermediate transfer belt 105 is wound around the support roller 113 in the circumferential direction.
Then, the toner adhering to the intermediate transfer belt 105 after passing through the secondary transfer nip is removed.

On the other hand, the photosensitive member 101 uses a drum so that its rotational position can be detected. The rotational position information obtained by detecting the rotational position is used as information for gradation reproduction control in the main body control unit 406 described later.
Although the rotational position of the photoconductor 101 is not shown, an encoder or a feeler provided in a driving mechanism of the photoconductor and a sensor capable of detecting the movement thereof are used.

In the above configuration, as a premise of the present invention, for each image position in the main scanning direction with respect to the color measurement result of the color measurement adaptive region formed with multi-order colors for the image region configured based on the user command. The density difference is corrected.
The configuration used for this correction is shown in FIG.
FIG. 3 is a block diagram illustrating a control configuration of the printer 100 as one of the image forming apparatuses. In FIG. 3, a main body control unit 406 is used as a control structure.
The main body control unit 406 performs image forming operation using an electrophotographic process by driving and controlling each unit in the printer 100, and also corrects image processing parameters that affect gradation reproduction according to various types of information to be described later. It is also used as a determination means.

The main body control unit 406 is connected to the following device via a bus line 409 to a CPU (Central Processing Unit) 402 that executes various calculations and drive control of each unit.
That is, a ROM (Read Only Memory) 405 that holds and stores fixed data such as a computer program in advance, and a RAM (Random Access Memory) 403 as data holding means that functions as a work area that stores various data in a rewritable manner. . The ROM 405 stores in advance model values of output colors for mixed colors composed of Y, M, C, and K having various area ratios. The RAM 403 is used to hold image density information for each periodic component, which will be described later, and pixel position information corresponding to the image density information.
Further, on the input side of the main body control unit 406, a toner density sensor 418, a temperature / humidity sensor 417 used for the spectrometer 109 and density color measurement means, and a sensor 501 as a rotation position detection means for detecting the rotation position of the photosensitive drum. An A / D conversion circuit 401 is also provided for converting information from the digital data into digital data. The A / D conversion circuit 401 is connected to the CPU 402 via the bus line 409. As will be described later, the toner density sensor 418 used as the density colorimetric means can measure the image density fluctuation caused by the periodic fluctuation in the driving unit.

Connected to the main body control unit 406 is a print controller 410 that processes image data sent from a PC (Personal Computer) 411, a scanner 412, a FAX (Facsimile) 413, etc., converts it into exposure data, and performs image formation processing. ing.
On the other hand, a drive circuit 414 for driving a motor and a clutch 415 is connected to the output side of the main body control unit 406.
Further, on the output side of the main body control unit 406, a voltage necessary for image formation is generated in the image forming unit (image forming unit 103, primary transfer roller 106, latent image writing unit 200, secondary transfer roller 108, etc.). A high pressure generator 416 is also connected.

The main body control unit 406 is connected to a parameter setting unit 404 in addition to the information input related and drive member related to the output control signal described above.
The parameter setting unit 404 is a part for changing image forming processing parameters such as the intensity of the writing light, the charging application voltage, and the developing bias based on the result calculated by the CPU 402 based on the information measured by the spectrometer 109. . For the spectrometer in this case, for example, a configuration as disclosed in JP-A-2005-315883 is used.
When printing is performed by the printer 100 according to information from the PC 411, print information including image data is transmitted from the PC 411 using a printer driver installed in the PC 411.
A print controller 410 corresponding to image processing means receives print information including image data transmitted from the PC 411, processes the image data, converts it into exposure data, and outputs a print command to the main body control unit 406.

When main body control unit 406 reads, from RAM 403, density fluctuation information of a photosensitive drum cycle acquired in advance, which will be described later, correction is performed based on the difference from the color measurement result in the color measurement adaptive area corresponding to the image density information. A process for correcting the image processing parameter according to the measurement color is performed.
In other words, the result of colorimetry of the colorimetric adaptation area of the image formed by the user's command is corrected by the main scanning correction coefficient corresponding to the colorimetric color image information, and the image is formed based on the corrected colorimetry result. The gradation reproduction curve with respect to the main scanning direction in the region is corrected.

Receiving the print command, the CPU 402 of the main body control unit 406 executes image formation control processing using an electrophotographic process by following the computer program stored in the ROM 405.
More specifically, the CPU 402 of the main body control unit 406 drives the motor and the clutch 415 via the drive circuit 414, and the support roller 112 is rotationally driven, so that the intermediate transfer belt 105 is rotationally driven.
The CPU 402 of the main body control unit 406 drives a device used for image formation based on an electrophotographic process via a drive circuit 414, a high voltage generator 416, and a parameter setting unit 404 connected to the output side. As an apparatus used for image formation in this case, the image forming unit 103, the primary transfer roller 106, the latent image writing unit 200, the secondary transfer roller 108, and the like shown in FIGS.
The main body control unit 406 drives the motor and the clutch 415 via the drive circuit 414 in accordance with the timing at which the four-color superimposed toner image formed on the intermediate transfer belt 105 enters the secondary transfer nip, thereby feeding the sheet. (Not shown) is controlled to supply the recording paper 115.

On the other hand, the recording paper 115 supplied from the paper feeder is sent between the intermediate transfer belt 105 and the secondary transfer roller 108, and the secondary transfer roller 108 causes the composite toner image on the intermediate transfer belt 105 to be recorded on the recording paper. Secondary transfer is performed on 115.
Thereafter, the recording paper 115 is conveyed to the fixing device 111 while being attracted to the secondary transfer roller 108, and heat and pressure are applied by the fixing device 111 to perform a toner image fixing process.
The recording paper 115 that has passed through the fixing device 111 is discharged and stacked on a paper discharge tray (not shown). The transfer residual toner remaining on the intermediate transfer belt 105 after the secondary transfer is removed by the belt cleaning device 110.

FIG. 4 is a block diagram showing the main body control unit 406 and related members shown in FIG.
In the figure, the main body control unit 406 includes the following members.
A measurement value acquisition unit 406a that also targets a multi-color toner image, a correction amount determination unit 406b that is used as a parameter correction unit, an algorithm calculation unit 406c, and a region search unit, which are formed on a photoconductor as a plurality of image carriers. There are an area search unit 406d and a parameter setting unit 406e that search for an area to be colorimetrically measured. In addition, an RGB / L ^* a ^* b ^* conversion unit 406f, a sampling color database 406g, and a main scanning correction unit 406k. Each of these units is not configured by hardware, but by a program stored in the data storage unit of the main body control unit 406.

The measurement value acquisition unit 406a acquires the measurement value (RGB value): M (t) at the position corresponding to the colorimetry adaptive region measured from the paper output of the user image, and transmits the measurement value to the main scanning correction unit 406k. To do.
In the area search unit 406d, image information of image data to be output in response to a user command is transmitted to the print controller 410, and which area is the colorimetric object in the entire area of the image formed on the hand image carrier according to the image information. It is searched whether it is a colorimetric adaptation region of Specifically, from the image information converted into pixel values representing the brightness of monochromatic components of R, G, B (hereinafter referred to as RGB values) for each pixel unit constituting the image information based on the user command, Search for the colorimetry target area at.
After this search, the recording paper on which the image has been formed is conveyed into the fixing device, and colorimetry in the colorimetric adaptation region is performed by the spectrometer 109 (see FIG. 3). The color measurement result is stored in the measurement value acquisition unit 406a of the main body control unit 406.

In the sampling color database 406g, in the output image of a plurality of pages t, the sampling position of the colorimetric adaptive region searched by the region search unit 406d: color: S (t), L ^* , a ^* , b ^* target value: R ( t), the output image measurement value: M (t) is stored.
In the algorithm calculation unit 406c, L ^* , a ^* , b ^* target values of the sampling position S (t) of the current colorimetric adaptive region searched by the region search unit 406d from the output image data (RGB values): R (t) is calculated and stored in the sampling color database 406g.
The correction amount determination unit 406b performs correction amount determination processing based on the colorimetric data stored in the sampling database 406g, and sets the correction amount for the set value representing the gradation reproduction curve TRC for Y, M, C, and K. decide.
The parameter setting unit 406e performs control parameter correction processing based on the correction amount determined by the correction amount determination unit 406b and the setting value representing the gradation reproduction curve TRC, and corrects the setting value representing the gradation reproduction curve TRC. To do.
The RGB / L ^* a ^* b ^* conversion unit 406f refers to the sampling position recorded in T from the original image data (RGB), and the reference color R = {(L _i , a _i , b _i ) : I = 1, 2,..., N}. Here, (L _i , a _i , b _i ) is an L ^* a ^* b ^* reference color that is an original color obtained by converting RGB values at the i-th sampling position (x _i , y _i ). It is.

In the main scanning correction unit 406k, when the measured color image information of the measurement color is a primary color, the main scanning correction coefficient corresponding to the range to which the density gradation of the primary color belongs is calculated to correct the color measurement result. At the same time, if it is a multi-order color, the following processing is executed.
Main scanning correction corresponding to the primary color having the smallest value when the RGB information of each primary color constituting the multi-order color is referred to by the area search unit 406d and the RGB information of each primary color is compared. The coefficient is calculated and the colorimetric result of the multi-color is corrected. Therefore, the main scanning correction unit 406k determines a color arrangement having an image density based on the image information corresponding to the color measurement adaptive region, that is, a correction coefficient for correcting the correction variation from the primary color or the multi-color. Can do.

When the color measurement result of the user image acquired by the measurement value acquisition unit 406a is the primary color when the image information of the measurement color measured based on the color measurement adaptive region by the main scanning correction unit 406k is the first color The color measurement result is corrected based on the main scanning correction coefficient corresponding to the range to which the density gradation of the next color belongs.
When the image information of the measurement color is a multi-order color, as described above, the area search unit 406d refers to the RGB information of each primary color that constitutes the multi-order color. Then, the colorimetric result of the primary color is corrected based on the main scanning correction coefficient corresponding to the one having the smallest value when comparing the RGB information of each primary color, that is, the dark primary color. The corrected colorimetric result is converted into L ^* a ^* b ^* by the RGB / L ^* a ^* b ^* conversion unit 406f, sent to the sampling color database 406g, and stored.
Note that the colorimetric adaptive region search method, colorimetric processing, and arithmetic processing in each unit described above can be exemplified by those disclosed in Japanese Patent Application Laid-Open No. 2012-165296, which is the prior application of the present applicant. Detailed description is omitted.

The print controller 410 includes the following members.
That is, a 3D lookup table (hereinafter abbreviated as 3D-LUT) 410a, undercolor removal (hereinafter abbreviated as UCR) / gray component replacement (hereinafter abbreviated as GCR) 410b, and tone reproduction curve (hereinafter abbreviated as TRC). ) Are a storage unit 410c and a halftone processing unit 410d.

The main body control unit 406 determines the main scanning correction coefficient corresponding to the range to which the density gradation for one color belongs and corrects the color measurement result. The main scanning correction coefficient used in this case is shown in FIG. The explanation is as follows.
FIG. 5 is a diagram in which, for example, a density difference that occurs in the main scanning direction for each density gradation in cyan (C) is actually confirmed.
The result shown in FIG. 5 is the result of obtaining the density difference with respect to the density gradation pattern for the A4 size (210 mm × 297 mm) shown in FIG.

The density difference shown in FIG. 5 is obtained under the following conditions.
(1) Color measurement is performed on an image in which image patterns of different density gradations divided in a predetermined pixel number range in the A4 size sub-scanning direction are formed in the main scanning direction in units of pixels (200 dpi).
(2) The difference between the image density at each main scanning position obtained by averaging the color measurement results at the same main scanning position in each density gradation region in the sub-scanning direction and the average value of the color measurement results in the entire density gradation region Is obtained as a density difference generated in the main scanning direction.
(3) The density difference obtained in (2) is represented for each of R (FIG. 5 (a)), G (FIG. 5 (b)), and B (FIG. 5 (c)) values. An example of the expressed result is shown in FIG.
The density gradation pattern shown in FIG. 6 is formed with density gradations represented by 0 to 255 in a to g. The density gradations in FIG. 6 are a = 100%, b = 80%, c = 70%, d = 60%, e = 40%, f = 20%, and g = 10%. g is the density difference obtained from the colorimetric results in the image areas indicated by reference signs a to g in FIG.
As shown in FIG. 3, when the image density difference (hereinafter referred to as main scanning density difference) occurring in the main scanning direction is 80% and 100%, 60% and 70%, and 20% and 40%, the tendency of the main scanning density difference Can be confirmed to be almost the same.
As described above, it can be experimentally confirmed that the change tendency of the main scanning density difference is the same in the vicinity range of 0 to 255 density gradations, and the tendency of the main scanning density difference changes every certain range. Yes. Therefore, for example, a range obtained by dividing the range of 0 to 255 into six parts, that is, in an easy-to-understand manner, when the density gradation range of 0 to 255 is expressed as a percentage, the range is as follows.
0-10%, 11% -20%, 21-40%, 41-60%, 61-80%, 81-100%, and the median of each range (5%, 15%, 30%, 50% , 70%, 90%), the correction coefficient may be acquired based on the density gradation pattern. In this case, as the correction coefficient data for one color, the map shown in FIG. 7 is created for four colors (C, M, Y, K), and stored and managed in the main scanning correction unit 406k.

The color measurement is performed by the spectrometer 109 (see FIG. 3), and the measurement value acquisition unit 406a described above performs color measurement along the center portion of each image pattern.
Incidentally, when considering density variation due to periodic variation in the drive system, the image pattern interval for color measurement may be acquired at a periodic pitch smaller than the photosensitive drum cycle. For example, when the photosensitive drum diameter is φ60 mm, the length of one drum circumference is 188.4 mm. Therefore, the density fluctuation along the drum cycle can be confirmed by obtaining at 1/4 pitch or less, but if it is obtained more accurately and accurately, 1/24 pitch (about 8 mm as shown in the figure) is obtained. ) It is desirable to acquire at intervals of about.

In the above configuration, the density variation correction that is the premise of the present invention will be described as follows. This procedure includes a case where density variation due to periodic variation of the drive system is taken into consideration as a correction target, and is a procedure disclosed in Japanese Patent Application No. 2013-207000 which is a prior application of the present applicant. .
That is, the main body control unit 406 corrects the color measurement result by determining the main scanning correction coefficient corresponding to the range to which the density gradation belongs, from the color measurement result by the dedicated chart for the primary color. In addition to this, image processing based on the difference between the synthesis period of the periodic component extracted from the result of colorimetry of the colorimetric adaptation region of the image formed based on the user command and the periodic component of the master information synthesized in the same period The tone reproduction curve TRC used for the parameters is corrected.

Specifically, the following procedure is used.
(1) The image density difference for each pixel position in the main scanning direction obtained for each color (C, M, Y, K) and a plurality of density dedicated charts for the image density difference for each pixel position in the main scanning direction in the image forming area. A main scanning correction coefficient is calculated in advance based on the difference information.
(2) The result of colorimetry of the colorimetric adaptive region of the user image formed based on the user command is corrected based on the main scanning correction coefficient.
By using the above procedure, it is possible to obtain a measurement result in which the image density difference in the main scanning direction is reduced regardless of the color measurement in any region, and the color measurement result in which the image density difference in the main scanning direction is corrected, and the image The gradation reproduction curve TRC is corrected according to the difference from the density variation information.

In this case, when correcting the color measurement result when the image area formed with the primary color is measured, the correction can be performed based on the main scanning correction coefficient acquired in advance.
However, when performing the main scanning correction from the colorimetric result when the colorimetric adaptive region of the user image formed with multi-order colors is measured, it is only necessary to correct using the main scanning correction coefficient of which image density of which color. Or not clear. For this reason, for example, when correction is performed using the main scanning correction coefficient for each primary color related to the formed multi-order color, multiple correction is performed, and a correct color measurement result cannot be obtained. As a result, there is a possibility that multi-order colors cannot be reproduced with high accuracy.

In the present embodiment, by using the measurement color obtained by correcting the main scanning density difference between the primary color and the multi-order color with respect to the result of measuring the colorimetric adaptation region of the image formed based on the user command. It is characterized by further improving reproducibility for multi-order colors. The configuration and procedure for this will be described below.
As a configuration for obtaining this feature, a main scanning correction unit 406k provided in the main body control unit 406 is used.
The main scanning correction unit 406k creates a dedicated chart having the density gradation pattern shown in FIG. 6 as correction coefficient data for one color (primary color). As described above, the density gradation of the pattern arranged on the chart is the median value (5%, 15%, 30%, 50%, 70%, 90%) of the range in which the tendency of the main scanning density difference changes. Density gradation pattern charts are created for four colors (C, M, Y, K), and the main scanning density difference is calculated from the result of color measurement in the same manner. A value obtained by the approximate expression calculated based on the main scanning density difference data is stored as a correction coefficient.
The number of divisions in the density gradation range described above is an example, and when there is a margin in the memory capacity for storing the main scanning correction coefficient, the correction coefficient based on the fine division range may be acquired by increasing the number of divisions. good.
Note that the pattern of FIG. 6 is also an example, and the pattern may be formed for each density gradation type on the entire sheet. However, when the amount of toner consumption and the number of printed sheets are taken into consideration, the sub-scan as shown in FIG. A method of performing colorimetry by creating a pattern chart in which the density gradation range is equally divided in the direction is most desirable.
In this way, the main scanning density difference for each pixel in the main scanning direction can be calculated, and the correction coefficient can be obtained from this main scanning density difference, so that accurate colorimetric results can be corrected while reducing the main scanning density difference. Become.

On the other hand, in the case of multi-order colors, it has been confirmed through experiments that the main scanning density difference has the following characteristics.
In FIG. 8, the density differences between the primary color and the multi-order color at a predetermined density gradation are R value (FIG. 6A), G value (FIG. 6B), B value (FIG. 6 (FIG. 6). c)).
In this case, the predetermined density gradation is set to 60% (Y60: dotted line) for yellow and 60% (M60: fine line) for magenta density for the primary color. The difference is sought.
In the case of a multi-order color, the density difference in the case of using a so-called multi-order color image pattern in which the density gradation of each of yellow and magenta is 60% (MY 60: thick line), that is, a so-called multi-order color image pattern is obtained. Yes.
As shown in FIG. 8, it can be seen that in the R value and the G value, the change tendency (thick line) of the main scanning density difference of MY60 coincides with the change tendency (thin line) of the main scanning density difference of M60.
On the other hand, in the B value, the change tendency of the main scanning density difference of MY60 is almost the same as the change tendency (dotted line) of the main scanning density difference of Y60.
FIG. 9 shows the RGB values of the image densities of Y60 and M60 from the tendency shown in FIG.
FIG. 9 represents the RGB values of the image densities of Y60 and M60 with 0 to 255 density gradations.
As is apparent from FIGS. 9 and 8, it can be seen that the changing tendency of MY60 depends on the RGB value of the primary color that constitutes the multi-order color is smaller, that is, the darker one.
This is not limited to the density gradation of 60%, but the same tendency is observed at 30% and 100%, and it has been confirmed that the same tendency is observed in other multi-color configurations.
Therefore, when correcting the main scanning density difference in the colorimetric result of the multi-order color, the RGB value of the density tone of the primary color constituting the multi-order color acquired by the area search unit 406d (see FIG. 2). Are compared. Based on the correction coefficient of the primary color having the smaller value in the comparison result, the main scanning density difference of each of the RGB values of the multi-order color is corrected. This makes it possible to obtain a color measurement result in which the main scanning density difference of the multi-order color is reduced.

Using the configuration described above, the image density difference for each pixel position in the main scanning direction is obtained for each color (C, M, Y, K), and the image density for each pixel position with respect to the main scanning direction obtained from the multiple density dedicated chart. The procedure for obtaining the difference information will be described with reference to the flowchart of FIG.
First, when the process is started, a counter cnt representing the number of printed sheets is initialized to 0 (step S101).
Next, printing of density images of a plurality of gradations that are specified in advance and divided equally with respect to the image density range of one color of the dedicated chart described in FIG. 6 is performed in four colors of C, M, Y, and K. Done for minutes.
For example, when 10 sheets of this dedicated chart are printed for one color and one gradation density, the prescribed number is 10 sheets × 4 colors × multiple gradation densities. Therefore, the process ends when the specified number of sheets have been printed (step S102; YES), and if the specified number of sheets has not been printed, the print sheet counter cnt is incremented by +1 (step S102; NO, step S103).

Printing processing is executed for the new dedicated chart of cnt (step S104), and in the case of the dedicated chart, since the position and area for color measurement are known, the color measurement adaptive area set in advance is measured ( Step S105).
Examples of the color measurement processing (step S105) in the color measurement adaptive region include those disclosed in JP2012-165296A.
If it is determined in step S106 that the printing process for the dedicated chart has reached the specified number, the process proceeds to step S107. If the specified number has not been reached, the process returns to step S103 and the printing process for the dedicated chart is continued.
Based on the colorimetric data acquired in step S107, a correction coefficient for each RGB is determined based on the density gradation range shown in FIG. 7 (step S108).
The determined correction coefficient is stored in the main scanning correction unit 406k (step S109).
The processing from step S107 to step S109 is repeated until the processing for four colors × multiple gradation densities is completed (step S110), and the process is terminated.
Although not shown, when the amount of density variation due to the periodic component of the drive system is taken into account, the colorimetric data acquired in step S107 is the colorimetric data in the main scanning direction for each pixel position of the same sub-scan. Averaging processing is performed, and FFT processing is performed on the colorimetric data subjected to the averaging processing. After extracting the periodic component from the result, a process of obtaining the pixel position (phase) information and the image density variation (amplitude) information of the individual periodic component by applying inverse FFT processing to the individual periodic component specified in advance. Done. This procedure is disclosed in Japanese Patent Application No. 2013-207000 mentioned above. FIG. 3 shows that the periodic component acquisition means for acquiring the periodic component in the drive unit is composed of a rotational position detection sensor (indicated by reference numeral 501 for reference).
Furthermore, when performing colorimetry using a user image, there may be a region where an image density color of the same gradation does not exist in all sub-scanning directions depending on the user image. In such a case, the same area can be obtained by complementing a part of the area where the image density color to be measured of the same gradation does not exist with a polynomial curve based on the area where the image density color of the same gradation exists. It is possible to compensate for an area where no gradation image density color exists. As another example of complementing, there is a portion between sheets, that is, a so-called gap between sheets or a non-image forming area (margin, etc.). . In addition, in the main body control unit 406, when considering the periodic component in the driving unit, as disclosed in the above-mentioned reference, the result of color measurement and the pixel position in the color measurement adaptive region corresponding to the image density information The image density variation is determined from the difference from the information. It is also possible to correct the measurement color with respect to the sub-scanning direction of the image forming area.

A method for correcting the main scanning density difference between the primary color and the multi-order color with respect to the result of the color measurement of the colorimetric adaptation region of the image formed based on the user command is as shown in the flowchart of FIG.
First, a user image is printed by a user command (step S201).
Next, a colorimetric adaptive area is searched from the user image (step S202), and colorimetry is performed on the searched area (step S203).
Examples of the colorimetric adaptive region search method and the colorimetric processing disclosed in JP 2012-165296 A can be exemplified.
Next, based on the image information of the color measurement region, it is determined whether the measurement color is a primary color or a multi-color (step S204).
In the case of a primary color, information on the color and density gradation is acquired from the image information, a main scanning correction coefficient in a range including the acquired color and density gradation is acquired (step S205), and the acquired correction coefficient The color measurement result is corrected based on (Step S209).

In the case of a multi-order color, density gradation information (RGB values) of the primary color constituting the multi-order color obtained from the area search unit 406d (see FIG. 4) is obtained (step S206). The obtained density gradation information is compared (step S207), and the correction coefficient of the primary color having the smaller value among the RGB values shown in FIG. 7 is employed (step S208). By correcting the main scanning density difference of the multi-order color based on the adopted correction coefficient, it becomes possible to reduce the main scanning density difference and to reproduce the multi-order color with high accuracy (step S209). .
If correction of all measurement data has been completed, the process ends. If not, the process proceeds to step S203 to repeat the process (step S210).
When all the main scanning density difference correction processes are completed, the colorimetric data is sent to RGB / L ^* a ^* b ^* : conversion unit 406f. The converted value is converted into RGB / L ^* a ^* b ^* data, the TRC correction value is determined by the correction value determination unit 406b via the sampling color database 406g, the TRC is corrected, and the process is terminated. As a calculation method of the correction amount for correcting the TRC, the one disclosed in JP2012-165296A can be exemplified.

  As described above, according to the present embodiment, the main scanning included in the result of the color measurement of the colorimetric adaptive region in the multi-order color of the image formed based on the user command by the main body control unit 406 serving as the control device. The density difference for each pixel position with respect to the direction is corrected. Then, by correcting the gradation reproduction curve TRC based on the corrected colorimetric result, it is possible to reproduce the multi-order color with higher accuracy.

As mentioned above, although preferable embodiment of this invention was described, this invention is not limited to this specific embodiment, Unless it is specifically limited by the above-mentioned description, this invention described in the claim is described. Various modifications and changes are possible within the scope of the gist of the invention.
The effects described in the embodiments of the present invention are only the most preferable effects resulting from the present invention, and the effects of the present invention are limited to those described in the embodiments of the present invention. is not.

100 Printer 101 Photosensitive drum 109 Spectrometer 402 CPU
403 RAM
406 Main body control unit 406b Correction amount determination unit 406d Area search means 406e Parameter setting unit 406h Periodic component acquisition unit 406k Main scanning correction unit

JP 2002-033935 A JP 2004-229294 A JP 2012-165296 A

Claims (8)

Area search means for searching for an area to be measured from an image formed by image information on each of a plurality of image carriers;
A density colorimetric means for measuring color density fluctuations caused by periodic fluctuations in a plurality of drive units including an image carrier;
Periodic component acquisition means for acquiring periodic components in a plurality of drive units including the plurality of image carriers;
Image density information for each periodic component acquired by the periodic component acquisition means, and holding means for holding pixel position information corresponding to the image density information;
The image processing parameter is determined by the measurement color corrected based on the difference between the pixel position information held in the holding unit and the colorimetry result measured in the colorimetry adaptive region corresponding to the image density information. A main body control unit for correcting
The main body control unit is provided with a main scanning correction unit that corrects a density variation amount according to the colorimetric adaptation region,
The main scanning correction unit determines a correction coefficient from the color density configuration of the image density of the image information corresponding to the color measurement adaptation region, and displays the color measurement result measured by the color measurement unit that measures the image density. The measurement color corrected by the correction coefficient, the measurement color is corrected based on the measured color measurement image information in the color measurement adaptive region, and the synthesis period of the periodic components extracted from the result of color measurement of the color measurement adaptive region, An image forming apparatus, wherein an image processing parameter is corrected based on a difference from a periodic component of master information synthesized at the same period. The image forming apparatus according to claim 1.
The main body control unit is configured to measure an image density variation caused by a periodic variation in the plurality of driving units, the color measurement result obtained by measuring the pixel position information and the color measurement adaptive region corresponding to the image density information. An image forming apparatus that corrects the measurement color with respect to the sub-scanning direction of the image forming area from the difference between the two. The image forming apparatus according to claim 1.
The main body control unit corrects the measurement color with respect to the main scanning direction of the image forming area from the pixel position information and the color measurement result measured in the color measurement adaptive area corresponding to the image density information. An image forming apparatus. The image forming apparatus according to claim 1.
The periodic component acquisition means extracts a plurality of periodic components having a large influence of image density variation from the colorimetric results measured in the colorimetric adaptation region, and individually extracts the plurality of periodic components for the extracted periodic components. An image forming apparatus that acquires pixel position information and the image density information. The image forming apparatus according to claim 1.
The density colorimetric means complements a non-existing region from a region where the measurement target color exists when there is a region where the specified measurement target color does not exist for the region in the sub-scanning direction in which the measurement is performed. An image forming apparatus. The image forming apparatus according to claim 1.
The parameter correction means corrects the image processing parameter from the color measurement result of only the measurement target color when there is no measurement target color in the image indicated by the image information. An image forming apparatus. The image forming apparatus according to any one of claims 1 to 6,
The main body control unit performs printing by correcting the image density of the image information based on image density information obtained by combining a plurality of periodic components acquired by the periodic component acquisition unit for each pixel position. Image forming apparatus. Area search means for searching for a colorimetric adaptation area suitable for colorimetry from images formed by image information on a plurality of image carriers, respectively, and density for colorimetry density information on the image carrier An output color stored in advance for each of a plurality of multi-color toner images formed by the image forming unit after the area search process and a set value of an image processing parameter of the image information processing unit; An algorithm representing a relationship, a difference between a measurement color that is a color measurement result obtained by measuring the color measurement adaptation region of a multi-color toner image formed based on the image information and a reference color that is an original color; Based on an area ratio of each primary color toner image in the multi-color toner image in the color measurement adaptive region and a set value of the image processing parameter, the image processing parameter for reducing the difference is set. Correction amount A constant correcting amount determining means, and the parameter correcting means for correcting the image processing parameters based on the determined the correction amount, the image forming apparatus including the main controller,
The density colorimetric means performs colorimetry on image density information generated by periodic fluctuation of the drive mechanism,
The main body control unit includes a periodic component acquisition unit that acquires periodic components in the plurality of driving units, image density information for each periodic component acquired by the periodic component acquisition unit, and pixels corresponding to the image density information Holding means for holding position information, and
The main body control unit determines a correction coefficient in the main scanning correction unit from the color density configuration of the image information according to the color measurement adaptation region, and performs color measurement by the color measurement unit that measures the image density. The measured color is corrected based on the measured color corrected by the correction coefficient and the image information corresponding to the measured colorimetric adaptation region, and the image is calculated based on the corrected measured color. An image forming apparatus that corrects a processing parameter.

Images