JP2011103535A - Method and system for supporting image processing, and image forming device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method and system for supporting image processing to register an XYZ tristimulus value conversion curve so that optimum printer γ correction can be applied to each paper type by an easy operation, and to provide an image forming device. <P>SOLUTION: The method for supporting image processing includes the steps of: forming a concentration correction chart on a paper sheet by an image formation part; performing color measurement on the concentration correction chart formed on the paper sheet by a color sensor 22 to input information of a voltage value; storing the voltage value by a nonvolatile memory 1b; performing color measurement on the concentration correction chart formed on the paper sheet by a color space tristimulus value color measurement machine to input information of a color space tristimulus value; and generating a color space tristimulus value conversion curve for converting a voltage value to a color space tristimulus value by a control part 1 based on the information of the voltage value, the information of the color space tristimulus value and a predetermined algorithm to store the generated color space tristimulus value conversion curve in the nonvolatile memory 1b. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an image processing support method, an image processing support system, and an image forming apparatus.

  In image processing in the image forming apparatus, density correction is performed. Examples of density correction include printer γ correction.

  “Printer γ correction” refers to (input value) such as density and luminance of an input image input to the image forming apparatus, and density (output value) of an image actually formed on a sheet based on the input image. It means to adjust the relative relationship. By performing the printer γ correction, an image having a color faithful to the input image can be formed on the paper. For density correction, in addition to printer γ correction, screen processing and the like can be cited as influencing factors.

  In the conventional printer γ correction, density information is detected by an IDC (Image Density Control) sensor installed in advance in the image forming apparatus, and the density of the input image is adjusted based on the detected density information. An image actually formed on the sheet based on the adjusted input image ensures reproducibility close to the input image input first.

FIG. 41 shows a schematic configuration of a general image forming apparatus.
The image forming apparatus 101 includes an intermediate transfer belt 102, an IDC sensor 103, YMCK photosensitive drums 104 to 107, a control unit 108, and the like. The IDC sensor 103 is installed on the downstream side in the rotation direction of the intermediate transfer belt 102 from the photosensitive drums 104 to 107 for each color of YMCK.

  The YMCK color photosensitive drums 104 to 107 form, for example, YMCK color γ correction patches on the intermediate transfer belt 102.

  The IDC sensor 103 reads density information of γ correction patches for each color of YMCK formed by the photosensitive drums 104 to 107. The density information read here is actually a voltage value.

  The control unit 108 adjusts the density of the input image based on the read density information of the γ correction patch. The adjustment performed here is printer γ correction. The control unit 108 actually forms an image on a sheet based on the adjusted input image.

  Here, in the image forming apparatus 101, the IDC sensor 103 is installed in the vicinity of the intermediate transfer belt 102 and reads density information of a γ correction patch formed on the intermediate transfer belt 102. In other words, the IDC sensor 103 does not read the density information of the γ correction patch actually formed on the paper. Therefore, even when the density of the input image is adjusted based on the density information read by the IDC sensor 103, the image formed on the paper may not be reproducible.

  According to Japanese Patent Laid-Open No. 2004-260260, a technique for performing printer γ correction using a scanner instead of an IDC sensor is disclosed. Specifically, a γ correction patch is formed on a sheet, and the sheet on which the γ correction patch is formed is read by a scanner. The data of the first γ correction patch and the γ correction patch read by the scanner are compared to obtain density data that cancels the difference. A technique for performing printer γ correction by using this for density correction is disclosed.

JP-A-2005-303701

  However, in the technique of Patent Document 1, it is necessary to individually obtain density data that cancels the difference each time the paper used for image formation is changed. That is, after obtaining density data once, when forming an image on another sheet, it is necessary to obtain density data again. Therefore, a user's operation becomes complicated and the problem that productivity falls also arises.

  SUMMARY OF THE INVENTION An object of the present invention is to provide an image processing support method, an image processing support system, and an image forming apparatus capable of applying an optimal printer gamma correction for each type of paper actually used by a simple operation.

According to the present invention, the step of forming the density correction chart on the sheet by the image forming unit;
A step of measuring the density correction chart formed on the paper by a color sensor and inputting information on a voltage value as a color measurement result;
Storing the input voltage value by a storage medium;
A step of measuring the density correction chart formed on the paper by a color space coordinate value colorimeter and inputting information of the color space coordinate value as a color measurement result;
The control unit generates color space coordinate value conversion information for performing color space coordinate value conversion processing for converting a voltage value into a color space coordinate value based on the voltage value information and the color space coordinate value information, Storing the generated color space coordinate value conversion information in the storage medium;
An image processing support method is provided.

According to the present invention, an image forming unit that forms a density correction chart on a sheet;
A color sensor that measures the density correction chart formed on the paper and inputs voltage value information that is a color measurement result; and
A storage medium for storing the input voltage value;
A color space coordinate value colorimeter that measures the density correction chart formed on the paper and inputs information of the color space coordinate value that is the color measurement result;
Color space coordinate value conversion information for performing color space coordinate value conversion processing for converting a voltage value into a color space coordinate value based on the voltage value information and the color space coordinate value information is generated, and the generated color A control unit that stores spatial coordinate value conversion information in the storage medium;
An image processing support system is provided.

According to the present invention, an image forming unit that forms a density correction chart on a sheet;
A color sensor that measures the density correction chart formed on the paper and inputs voltage value information that is a color measurement result; and
A storage medium for storing the input voltage value;
An input unit for measuring the density correction chart formed on the paper and inputting information of color space coordinate values as a color measurement result;
Color space coordinate value conversion information for performing color space coordinate value conversion processing for converting a voltage value into a color space coordinate value based on the voltage value information and the color space coordinate value information is generated, and the generated color A control unit that stores spatial coordinate value conversion information in the storage medium;
An image forming apparatus is provided.

  According to the present invention, color space coordinate value conversion information can be stored in a storage medium for each type of paper actually used by a simple operation. Therefore, the optimum printer γ correction can be applied for each paper type.

1 is a schematic configuration diagram of an image forming apparatus. It is a schematic block diagram of a color sensor. It is a schematic block diagram of an image processing support system. 2 is a functional block diagram of the image forming apparatus. FIG. This is the size specification of the γ correction chart. It is an example of the chart for γ correction. It is a registration screen of an XYZ tristimulus value conversion curve. It is a figure which shows the structure of a paper category. It is an individual setting change screen. It is a figure which shows the structure of a tray paper profile. It is a paper condition registration screen. It is a figure which shows the structure of a paper profile. FIG. 6 is a diagram illustrating a correlation between a paper category, a tray paper profile, and a paper profile. It is a flowchart which shows the registration process of an XYZ tristimulus value conversion curve. This is the startup screen. It is a setting screen of an adjustment menu. It is a setting screen for output paper density adjustment. It is a list selection screen of a paper category. It is a paper category name input screen. This is the print standby screen. This is the printing screen. It is a list selection screen of a paper category. It is a connection request screen. It is a file selection screen of a color measurement result. It is a list selection screen of a paper category. This is a screen when an XYZ tristimulus value conversion curve cannot be registered. It is a flowchart which shows a link cancellation | release process. FIG. 10 is a flowchart showing a paper profile link setting process. This is the startup screen. It is a paper setting screen. It is an individual setting change screen. It is a paper category selection screen. It is an individual setting change screen. FIG. 10 is a flowchart illustrating a paper profile registration process. It is a setting menu screen. It is a paper feed tray setting screen. It is a paper profile registration screen. It is a paper condition registration screen. It is a paper category selection screen. It is a paper condition registration screen. 1 is a schematic configuration diagram of a general image forming apparatus.

  The configuration and operation of the image forming apparatus in this embodiment will be described in detail with reference to the drawings. In the present embodiment, a color image forming apparatus will be described as an example. However, the present invention is not limited to this, and the present invention can be realized by, for example, a monochrome image forming apparatus.

FIG. 1 shows a schematic configuration of the image forming apparatus 10.
The image forming apparatus 10 includes an image forming unit 11 and a relay unit (hereinafter “RU”) 21.

  The image forming unit 11 is an electrophotographic digital printer, and includes a control unit 1, a display unit 2, a paper feeding unit 12, YMCK photosensitive drums 13 to 16, an intermediate transfer belt 17, a transfer roller 18, a fixing unit. The apparatus 19 is provided. In addition, although it is configured to include an automatic document feeder, a scanner unit, and the like, description thereof is omitted here. Further, similarly to the general configuration, the IDC sensor 103 may be installed on the downstream side in the rotation direction of the intermediate transfer belt 17 (see FIG. 41).

  The control unit 1 includes a CPU, a RAM, a ROM, and the like. The control unit 1 develops various programs stored in the ROM or the non-volatile memory 1b (see FIG. 4) in the RAM, and performs centralized control of the operation of each unit of the image forming apparatus 10 in cooperation with the developed various programs. To do.

  The display unit 2 includes an LCD (Liquid Crystal Display), a touch panel, and the like, and displays various setting screens. The display unit 2 generates a pressing signal when various buttons are pressed by the user, and outputs the generated pressing signal to the control unit 1.

  The paper feed unit 12 includes a plurality of trays, stores paper for each paper type, feeds the stored paper through a predetermined transport path, and feeds the paper.

  The YMCK color photosensitive drums 13 to 16 form and carry YMCK color toner images on the photosensitive drum, respectively, and transfer them onto the intermediate transfer belt 17 (primary transfer).

The intermediate transfer belt 17 rotates while carrying the transferred toner image.
The transfer roller 18 transfers the YMCK color toner images carried on the intermediate transfer belt 17 to a sheet (secondary transfer).

  The fixing device 19 heats or pressurizes each of the YMCK toner images transferred and formed on the paper, and fixes the toner image on the paper. The paper on which the toner image is fixed is then conveyed to the RU 21.

  The RU 21 includes a color sensor 22. In addition to the color sensor 22, the RU 21 has a function of synchronizing with the conveyance speed of the sheet conveyed from the image forming unit 11. Further, the RU 21 may have a function capable of performing each process such as a punch process, a folding process, a glue application process, and a cutting process, that is, a so-called finisher function.

FIG. 2 shows a schematic configuration and conditions of the color sensor 22.
The color sensor 22 is a reflective sensor that includes an LED light source 221, a light receiving element 222, a lens 223, a lens holder 224, and the like.
The color sensor 22 measures a chart formed by fixing on a sheet (in this embodiment, a γ correction chart (see FIG. 6)), and outputs a voltage value calculated by the color measurement to the control unit 1. .

FIG. 3 shows a schematic configuration of the image processing support system 10A.
The image processing support system 10 </ b> A includes an image forming apparatus 10 including an image forming unit 11 and an RU 21, an XYZ tristimulus colorimeter 31, an external PC 41, and a USB memory 51.

  The image forming apparatus 10 forms an image of the γ correction chart on the paper on which the optimum printer γ correction is to be performed. At this time, the RU 21 reads the γ correction chart by the color sensor 22 and outputs information of the read voltage value to the control unit 1.

  The XYZ tristimulus colorimeter 31 includes a spectrophotometer and is connected to the external PC 41 via USB. The XYZ tristimulus colorimeter 31 reads the γ correction chart formed on the paper, and converts the read γ correction chart into XYZ tristimulus values. In addition, the XYZ tristimulus colorimeter 31 outputs the converted XYZ tristimulus value information to the external PC 41. In the present embodiment, the XYZ color system is adopted and the XYZ tristimulus colorimeter 31 acquires the XYZ tristimulus values. However, the present invention is not limited to this. Other color systems may be employed, and other color space coordinate values may be acquired by a color space coordinate value colorimeter.

  The external PC 41 inputs the output XYZ tristimulus value information and stores the input XYZ tristimulus value information in the USB memory 51.

  The USB memory 51 is extracted from the external PC 41 and connected to the image forming apparatus 10, and outputs XYZ tristimulus value information to the image forming apparatus 10. Note that the XYZ tristimulus colorimeter 31, the external PC 41, and the image forming apparatus 10 may be always connected via a LAN cable or the like so that data communication is possible.

  The image forming apparatus 10 inputs information on the XYZ tristimulus values output from the USB memory 51, and based on the voltage value read by the color sensor 22, the information on the input XYZ tristimulus values, and a predetermined algorithm. Thus, a voltage density conversion table (hereinafter, XYZ tristimulus value conversion curve) is created. The image forming apparatus 10 stores the created XYZ tristimulus value conversion curve in the nonvolatile memory 1b (see FIG. 4).

FIG. 4 shows a functional block diagram of the image forming apparatus 10.
The image forming apparatus 10 includes an image forming unit 11 and an RU 21. The image forming unit 11 and the external PC 41 are connected to be communicable with each other via a LAN.

  The image forming unit 11 includes a control unit 1, a display unit 2, a scanner unit 3, a printer unit 4, a printer controller 5, and the like.

  The control unit 1 includes an image control CPU 1a, a nonvolatile memory 1b, a reading processing unit 1c, a compression IC 1d, a DRAM control IC 1e, an image memory 1f, an expansion IC 1g, a writing processing unit 1h, and the like.

  The image control CPU 1a includes a CPU, a RAM, a ROM, and the like, reads various programs stored in the ROM or the non-volatile memory 1b, expands them in the RAM, and executes various processes in cooperation with the expanded various programs. .

  The nonvolatile memory 1b includes a rewritable nonvolatile memory, and stores various programs and various data.

  The reading processing unit 1c receives an analog image signal output from the CCD 3a, and performs analog processing, shading processing, A / D conversion processing, and the like on the input analog image signal to generate digital image data. The read processing unit 1c outputs the generated image data to the compression IC 1d.

  The compression IC 1d receives the image data output from the reading processing unit 1c, performs compression processing on the input image data, and then outputs the image data to the DRAM control IC 1e.

The DRAM control IC 1e compresses the image data read by the reading processing unit 1c with the compression IC 1d, and stores the compressed image data with the compression memory 11f.
Further, the DRAM control IC 1e receives the compressed image data from the compression memory 11f, expands it with the expansion IC 1g, and stores the expanded uncompressed image data with the page memory 12f. Further, the DRAM control IC 1e inputs uncompressed image data stored in the page memory 12f, and outputs the input uncompressed image data to the write processing unit 1h.

  The image memory 1f is constituted by a DRAM and includes a compression memory 11f and a page memory 12f. The compression memory 11f stores compressed image data. The page memory 12f temporarily stores uncompressed image data to be image formed before image formation.

  The decompression IC 1g performs decompression processing on the input compressed image data.

  The write processing unit 1 h generates print data for image formation based on the image data to be formed input from the DRAM control IC 1 e and outputs the print data to the printer unit 4.

The display unit 2 includes an LCD 2a and a display control unit 2b.
The LCD 2a includes a touch panel that covers the LCD 2a. The display control unit 2b receives a display signal output from the image control CPU 1a, and displays various setting screens on the LCD 2a based on the input display signal. Further, the display control unit 2b receives an operation signal generated by pressing an operation key group or a touch panel (not shown), and outputs the input operation signal to the image control CPU 1a.

  The scanner unit 3 includes a CCD 3a and a scanner control unit 3b that drives and controls the CCD 3a. The scanner unit 3 exposes and scans a document surface placed on a document table (not shown) with a light source, receives reflected light from the document surface, and photoelectrically converts the received reflected light with a CCD 3a to generate an analog image signal. To do. The scanner unit 3 outputs the generated analog image signal to the reading processing unit 1c.

  The printer unit 4 includes an LD (Laser Diode) 4a and a printer control unit 4b that controls an image forming operation of the LD 4a. The printer unit 4 performs a series of image forming processes for forming a toner image on a sheet and fixing the formed toner image.

  The printer controller 5 includes a controller control CPU 5a, a LANIF 5b, a USB 5c, a DRAM control IC 5d, and an image memory 5e.

The controller control CPU 5a comprehensively controls the operation of each unit of the printer controller 5.
The LANIF 5b is a communication interface for connecting to a LAN such as a NIC or a modem, and receives image data transmitted from an external PC via the LAN. The LANIF 5b outputs the received image data to the DRAM control IC 5d.

  The USB port 5c inputs various data stored in the USB memory, and outputs the input various data to the controller control CPU 5a.

  The DRAM control IC 5d outputs the image data to the image memory 5e, and inputs the image data from the image memory 5e. The DRAM control IC 5d is connected to the DRAM control IC 1e of the control unit 1 through a PCI bus, and outputs image data or various data to the DRAM control IC 1e.

  The image memory 5e is constituted by a DRAM and temporarily stores image data.

The RU 21 includes an RU control unit 21a, a color sensor 22, and the like.
The RU control unit 21a includes a CPU, a RAM, a ROM, and the like, reads various programs stored in the ROM, expands them in the RAM, and executes various processes in cooperation with the expanded various programs. The RU control unit 21a is connected to the control unit 1 through the printer control unit 4b so that data communication is possible.

  The color sensor 22 reads the γ correction chart formed on the sheet passing over the sensor, and outputs the read voltage value to the RU control unit 21a.

FIG. 5 shows the size specification of the γ correction chart.
The setting of the size specification of the γ correction chart is preliminarily stored in the nonvolatile memory 1b. The γ correction chart includes a plurality of γ correction patches, and the γ correction patches are formed over a plurality of sheets. The size of the γ correction patch is determined by the performance of the color sensor 22 and the like. In general, the larger the paper size, the smaller the number of sheets used in the γ correction chart, and the smaller the paper size, the more paper is required. In this example, the sheet size required for the γ correction chart is associated with a total of three paper sizes of large, medium, and small sizes. For example, when the γ correction chart is formed on a paper (A4 paper) having a length of 297.0 mm in the sub-scanning direction (paper conveyance direction), since it is “medium size”, the “number of γ correction patches” is 32. The number of “sheets” is four.

FIG. 6 shows an example of a γ correction chart.
The γ correction chart shown in FIG. 6 is a γ correction chart formed on A4 paper. YMCK γ correction patches for each color are formed over a total of four sheets A4-1 to A4-4. Eight γ correction patches are formed for one A4 sheet, and a total of 32 patches are formed for four A4 sheets. The total number of γ correction patches for each color of YMCK is 32 × 4 colors = 128. The gradation values of the γ correction patches formed in the γ correction charts A4-1 to A4-4 are evenly distributed in A4-1 to A4-4 with the gradation 255 as the maximum, as shown in FIG. By evenly distributing the density, color reproducibility can be ensured, and chart dependency can be reduced or noise can be reduced.

FIG. 7 shows an XYZ tristimulus value conversion curve registration screen G1.
The registration screen G1 is displayed by the display unit 2. In the registration screen G1, an XYZ tristimulus conversion curve can be registered in the paper category.
The “XYZ tristimulus value conversion curve” refers to a voltage density conversion table or function that converts voltage values read by the color sensor 22 into XYZ tristimulus values.

  The “paper category” refers to file data that includes an XYZ tristimulus conversion curve and is stored in the nonvolatile memory 1b. The nonvolatile memory 1b in the present embodiment secures a memory area that can store a maximum of 10 paper categories. In the registration screen G1, no. 1-No. Up to 10 paper categories up to 10 are displayed.

FIG. 8 shows the structure of the paper category.
In the non-volatile memory 1b, no. 1-No. A total of ten paper categories of 10 are stored, and each of the paper categories includes (a) paper category name, (b) registration status, (c) update date, (ii) XYZ tristimulus conversion curve (voltage) Density conversion table) and (e) patch colorimetric voltage values. For the (2) XYZ tristimulus value conversion curve, the XYZ tristimulus values of the γ correction chart read by the XYZ tristimulus colorimeter 31 with the (e) patch colorimetric voltage values registered in the paper category. Is input to the image forming apparatus 10.

FIG. 9 shows an individual setting change screen G2.
The individual setting change screen G2 is displayed by the display unit 2. On the individual setting change screen G2, a tray paper profile can be set.

  The “tray sheet profile” is setting information for each tray provided in the sheet feeding unit 12. The tray paper profile is stored in the nonvolatile memory 1b.

  In the individual setting change screen G2, the “output paper density adjustment” button is in a pressed state, and on the right side of the screen, three buttons of “default correction value”, “paper category”, and “OFF” are displayed to be pressed. .

  The “default correction value” button is a button for setting an XYZ tristimulus value conversion curve predetermined for each paper type.

  The “paper category” button is a button for using an XYZ tristimulus conversion curve (see FIG. 8) created and registered for each user.

  The “OFF” button is a button for performing printer γ correction using the conventional IDC sensor 103 (see FIG. 41) without using the XYZ tristimulus conversion curve determined for each paper type.

FIG. 10 shows the structure of the tray paper profile.
The nonvolatile memory 1b stores a total of nine tray sheet profiles with tray numbers 1 to 9. In the present embodiment, since the number of trays provided in the sheet feeding unit 12 is nine, a maximum of nine tray sheet profiles are stored.

  The tray paper profile consists of (h) paper type, (li) paper name, (nu) basis weight unit, (le) basis weight, ..., (wo) printer gamma correction mode, (wa) link to paper category database, It consists of each data.

As for the above (v) “printer γ correction mode”, any one of “default correction value”: 1, “paper category”: 2, and “OFF”: 0 is registered.
With regard to “(iii)“ Link to paper category database ”, the paper category registration number No. 1-No. 10 (see FIG. 8) is registered. By registering the number, the tray paper profile is linked with the registered paper category.

FIG. 11 shows a paper condition registration screen G3.
The paper condition registration screen G3 is displayed by the display unit 2. On the paper condition registration screen G3, a paper profile can be set.

  The “paper profile” is the same information as the “tray paper profile”. The paper profile is stored in the nonvolatile memory 1b.

FIG. 12 shows the structure of the paper profile.
In the non-volatile memory 1b, no. 1-No. A total of 500 paper profiles up to 500 are stored. Since the paper profile has the same content as the tray paper profile, description thereof is omitted here.

  FIG. 13 shows the correlation between the paper category, the tray paper profile, and the paper profile. As a premise, it is assumed that the USB memory 51 is inserted into the USB port 5 c and the information on the XYZ tristimulus values stored in the USB memory 51 is output to the control unit 1.

  When the XYZ tristimulus values stored in the USB memory 51 are output to the control unit 1, the control unit 1 creates an XYZ tristimulus value conversion curve and stores it in the nonvolatile memory 1b. Here, the created XYZ tristimulus conversion curve is registered in the “paper category” (No. 1 in FIG. 13) of the nonvolatile memory 1b.

  Paper categories can be linked to tray paper profiles and paper profiles. Here, the paper category No. 1 is linked to tray number 2 of the tray paper profile. Also, the paper category No. No. 1 is the paper profile No. Link to 3. When the paper is actually fed by the tray 2, the tray paper profile of the tray number 2 is No. 1 paper category, or No. 1 3 paper profile is loaded. Thereby, it is possible to apply the optimum printer γ correction to the fed paper and image. In particular, when a tray paper profile loads a paper profile, the tray paper profile includes not only the XYZ tristimulus conversion curve but also other attributes and control values (paper characteristics such as paper type, paper name, basis weight unit,...). Can be loaded as a set.

  In other words, when the user wants to perform optimum printer gamma correction for each actually used paper, the user can set or check any of the paper category, tray paper profile, and paper profile to perform optimum printer gamma correction. You can hang it.

The XYZ tristimulus value conversion curve registration process will be described with reference to FIG.
The control unit 1 displays a startup screen on the display unit 2 (step S1).

FIG. 15 shows a startup screen G11.
On the right side of the screen, a paper tray is displayed so that tray numbers 1 to 9 can be selected. In addition, an “adjustment” button is displayed at the bottom of the screen so that it can be pressed.

  The control unit 1 determines whether or not a press signal generated when a paper tray is selected and the “Adjust” button is pressed on the startup screen G11 is input (step S2).

When the pressing signal for the adjustment button is not input (step S2; N), the control unit 1 continuously displays the startup screen G11.
When an adjustment button pressing signal is input (step S2; Y), the control unit 1 displays an adjustment menu setting screen (step S3).

FIG. 16 shows an adjustment menu setting screen G12.
On the right side of the screen, an “output paper density adjustment” button is displayed so that it can be pressed.

  The control unit 1 determines whether or not a pressing signal generated when the “Output Paper Density Adjustment” button is pressed on the adjustment menu setting screen G12 (Step S4).

When the pressing signal of the output paper density adjustment button is not input (step S4; N), the control unit 1 continuously displays the adjustment menu setting screen G12.
When a pressing signal for the output paper density adjustment button is input (step S4; Y), the control unit 1 displays an output paper density adjustment setting screen (step S5).

FIG. 17 shows an output paper density adjustment setting screen G13.
On the left side of the screen, the state of transition from the adjustment menu setting screen G12 to the output paper density adjustment setting screen G13 is displayed.
On the right side of the screen, a “paper category registration” button is displayed so that it can be pressed.

  The control unit 1 determines whether or not a pressing signal generated when the “paper category registration” button is pressed on the output paper density adjustment setting screen G13 (step S6).

When the press signal of the paper category registration button is not input (step S6; N), the control unit 1 continuously displays the output paper density adjustment setting screen G13.
When the pressing signal of the paper category registration button is input (step S6; Y), the control unit 1 displays a paper category list selection screen (step S7).

FIG. 18 shows a paper category list selection screen G14.
In the list selection screen G14, when there is no name or name of the paper category, the blank area is No. 1-No. A total of 10 items can be selected up to 10. In addition, a “print mode” button is displayed at the bottom of the screen so that it can be pressed.

  In the list selection screen G14 for the paper category, the control unit 1 selects No. 1-No. 10 is selected, and it is determined whether or not a pressing signal generated when the “print mode” button is pressed is selected (step S8).

When the press signal of the print mode button is not input (step S8; N), the control unit 1 continuously displays the paper category list selection screen G14.
When a print mode button pressing signal is input (step S8; Y), the control unit 1 displays a paper category name input screen (step S9).

FIG. 19 shows a paper category name input screen G15.
On the paper category name input screen G15, a keyboard is displayed so that it can be pressed. At the bottom of the screen, an “OK” button is displayed so that it can be pressed.

  The control unit 1 determines whether or not a name is input on the sheet category name input screen G15 and a pressing signal generated when the “OK” button is pressed is input (step S10).

When the OK button pressing signal is not input (step S10; N), the control unit 1 displays a paper category list selection screen G14.
When an OK button pressing signal is input (step S10; Y), the control unit 1 displays a print standby screen (step S11).

FIG. 20 shows a print standby screen G16.
On the lower right side of the screen, a total of nine trays from tray 1 to tray 9 are displayed in a selectable manner. An XYZ tristimulus conversion curve is registered later in the tray paper profile of the tray selected here.

  Whether the control unit 1 has input a pressing signal generated when one of the trays 1 to 9 is selected and a print start button (not shown) is pressed on the print standby screen G16 It is determined whether or not (step S12).

When the press signal of the print start button is not input (step S12; N), the control unit 1 continuously displays the print standby screen G16.
When the press signal of the print start button is input (step S12; Y), the control unit 1 forms an image of the γ correction chart and displays a printing screen (step S13).

FIG. 21 shows a printing screen G17.
On the printing screen G17, a message such as “Copying” is displayed.
When the image formation of the γ correction chart is completed, the printing screen G17 transitions to the print standby screen G16.

  The control unit 1 changes the printing screen G17 to the print standby screen G16, and registers the color measurement value (voltage value) of the γ correction chart measured by the color sensor 22 in the paper category (step S14).

  The control unit 1 determines whether or not a pressing signal generated when the “end printing mode” button is pressed on the print standby screen G16 (step S15).

When the press signal of the print mode end button is not input (step S15; N), the control unit 1 continuously displays the print standby screen G16.
When the pressing signal for the print mode end button is input (step S15; Y), the control unit 1 displays a list selection screen for the paper category (step S16).

FIG. 22 shows a paper category list selection screen G18.
The list selection screen G18 has the same display content and configuration as the list selection screen G14. Here, since the voltage value of the γ correction chart read by the color sensor 22 is registered in the paper category, the name is displayed in the paper category list. In addition, a message such as “Ready to read colorimetric data” is displayed.
At the bottom of the screen, a “read color measurement data” button is displayed so that it can be pressed.

  The control unit 1 determines whether or not a pressing signal generated when the “colorimetric data reading” button is pressed on the list selection screen G18 is input (step S17).

When the pressing signal of the colorimetric data reading button is not input (step S17; N), the control unit 1 continuously displays the list selection screen G18.
When the pressing signal of the colorimetric data reading button is input (step S17; Y), the control unit 1 displays a connection request screen for the USB memory 51 (step PS18).

FIG. 23 shows a connection request screen G19.
On the connection request screen G19, a message such as “Please connect the USB memory and select OK” is displayed. In addition, an “OK” button is displayed to be pressed.

  When the pressing signal generated when the “OK” button is pressed is input on the connection request screen G19, the control unit 1 determines whether or not the USB memory 51 has been recognized (step S19).

If it cannot be recognized (step S19; N), the control unit 1 displays a message such as “USB memory could not be recognized” on the same configuration screen as the connection request screen G19.
If it can be recognized (step S19; Y), the control unit 1 displays a file selection screen for the colorimetry result (step S20).

FIG. 24 shows a color measurement result file selection screen G20.
On the file selection screen G20, a color measurement result file (XYZ tristimulus values) stored in the USB memory 51 is displayed in a selectable manner. At the bottom of the screen, an “OK” button is displayed so that it can be pressed.

  The control unit 1 determines whether or not a pressing signal generated when a file is selected on the file selection screen G20 and the “OK” button is pressed is input (step S21).

When the OK button pressing signal is not input (step S21; N), the control unit 1 continuously displays the file selection screen G20.
When an OK button pressing signal is input (step S21; Y), the control unit 1 performs XYZ three based on information on the selected file, information on the voltage value registered in the paper category, and a predetermined algorithm. A stimulus value conversion curve (voltage concentration conversion table) is created (step S22).

  The control unit 1 registers the created XYZ tristimulus value conversion curve in the paper category (step S23), and ends the registration process of the XYZ tristimulus value conversion curve.

FIG. 25 shows a paper category list selection screen G21 after the XYZ tristimulus conversion curves are registered.
The list selection screen G21 has the same configuration and contents as the list selection screen G18. Here, since the XYZ tristimulus conversion curve is registered in the paper category, a message such as “Waiting for colorimetric data reading” is deleted from the list of paper categories, and only the paper category name is displayed.

FIG. 26 shows a screen G22 when the XYZ tristimulus value conversion curve cannot be registered.
The screen G22 is a screen displayed when an “OK” button is pressed without selecting an appropriate file on the file selection screen G20. A message to reconfirm the selected file is displayed on the screen G22.

With reference to FIG. 27, the link release processing will be described.
As described with reference to FIG. 13, the tray paper profile or the paper profile is linked to the paper category. Paper category No. 1-No. When any one of the paper categories is deleted or overwritten, it is necessary to delete the tray paper profile or the link setting of the paper profile linked at the time of deletion or overwriting registration.

  The control unit 1 determines whether or not the tray paper profile is linked to the paper category that is the target of deletion or overwrite registration (step S31).

When linked (step S31; Y), the control unit 1 deletes the link setting from the tray sheet profile to the sheet category (step S32).
When not linked (step S31; N), the control unit 1 proceeds to step S33.

The control unit 1 determines whether there is another tray sheet profile that has already been registered (step S33).
If another already registered tray sheet profile exists (step S33; Y), the control unit 1 reads another registered tray sheet profile (step S34), and proceeds to step S31.
When there is no other registered tray paper profile (step S33; N), the control unit 1 proceeds to step S35.

  The control unit 1 determines whether or not the paper profile is linked to the paper category to be deleted or overwritten (step S35).

When linked (step S35; Y), the control unit 1 deletes the link setting from the paper profile to the paper category (step S36).
When not linked (step S35; N), the control unit 1 proceeds to step S37.

The control unit 1 determines whether there is any other registered paper profile (step S37).
If there is another registered paper profile (step S37; Y), the control unit 1 reads another registered paper profile (step S38), and proceeds to step S35.
When there is no other registered paper profile (step S37; N), the control unit 1 ends the link release process.

The paper profile link setting process will be described with reference to FIG.
With the link setting process, the paper category can be linked to the paper profile.
First, the control unit 1 displays a startup screen on the display unit 2 (step S41).

FIG. 29 shows a startup screen G31.
The startup screen G31 has the same configuration and contents as the startup screen G11 (see FIG. 15). In the startup screen G31, a “paper setting” button is displayed in the lower left side of the screen so as to be pressed.

  The control unit 1 determines whether or not a pressing signal generated when the paper setting button is pressed is input on the startup screen G31 (step S42).

When the press signal of the paper setting button is not input (step S42; N), the control unit 1 continuously displays the startup screen G31.
When a paper setting button pressing signal is input (step S42; Y), the control unit 1 displays a paper setting screen (step S43).

FIG. 30 shows a paper setting screen G32.
On the left side of the screen, a total of nine “tray” buttons from tray 1 to tray 9 are displayed in a selectable manner. In the lower right side of the screen, a “setting change” button is displayed so as to be pressed.

  The control unit 1 determines whether one of the trays 1 to 9 is selected on the paper setting screen G32 and a pressing signal generated when the “setting change” button is pressed is input. (Step S44).

When the pressing signal for the setting change button is not input (step S44; N), the control unit 1 continuously displays the paper setting screen G32.
When the pressing signal for the setting change button is input (step S44; Y), the control unit 1 displays an individual setting change screen (step S45).

FIG. 31 shows an individual setting change screen G33.
The individual setting change screen G33 has the same configuration and contents as the individual setting change screen G2 (see FIG. 9). On the left side of the screen, an “output paper density adjustment” button is displayed so that it can be pressed. When the “output paper density adjustment” button is pressed, a “default correction value” button, a “paper category” button, and an “OFF” button are displayed on the left side of the screen.

  The control unit 1 determines whether or not a pressing signal generated when the “paper category” button is pressed on the individual setting change screen G33 (step S46).

When the press signal of the paper category button is not input (step S46; N), the control unit 1 continuously displays the individual setting change screen G33.
When a paper category button pressing signal is input (step S46; Y), the control unit 1 displays a paper category selection screen (step S47).

FIG. 32 shows a paper category selection screen G34.
The paper category selection screen G34 has the same configuration and contents as the list selection screen G21 (see FIG. 25). In the center of the screen, a paper category is displayed so as to be selectable. In addition, an “OK” button is displayed at the bottom of the screen so that it can be pressed.

  The control unit 1 determines whether or not a press signal generated when a paper category is selected on the paper category selection screen G34 and the “OK” button is pressed is input (step S48).

When the OK button pressing signal is not input (step S48; N), the control unit 1 continuously displays the paper category selection screen G34.
When an OK button pressing signal is input (step S48; Y), the control unit 1 displays the individual setting change screen G33 again (step S49).

FIG. 33 shows the individual setting change screen G35 displayed again.
The individual setting change screen G35 displayed again has the same configuration and contents as the individual setting change screen G33 (see FIG. 31). In the individual setting change screen G35, an “output paper density adjustment” button and a “paper category” button are displayed in a pressed state. In addition, an “OK” button is displayed at the bottom of the screen so that it can be pressed.

  The control unit 1 determines whether or not a pressing signal generated when the “OK” button is pressed is input on the individual setting change screen G35 (step S50).

When the OK button pressing signal is not input (step S50; N), the control unit 1 continuously displays the individual setting change screen G35.
When an OK button pressing signal is input (step S50; Y), the control unit 1 registers link settings in the paper profile so as to link to the paper category selected on the paper category selection screen G34 (step S51). Then, the paper profile link setting process ends.

The paper profile registration process will be described with reference to FIG.
Through the paper profile registration process, up to 500 paper profiles can be registered in advance.
First, the control unit 1 displays a setting menu screen on the display unit 2 (step S61).

FIG. 35 shows a setting menu screen G41.
On the right side of the screen, a “user setting” button is displayed so as to be pressed.

  The control unit 1 inputs a pressing signal generated when the “user setting” button is pressed on the setting menu screen G41, and subsequently presses the pressing signal in the order of the “environment setting” button and the “paper tray setting” button. Is determined (step S62).

When the last sheet feed tray setting button pressing signal is not input (step S62; N), the control unit 1 continuously displays the setting menu screen G41.
When the pressing signal of the last paper feed tray setting button is input (step S62; Y), the control unit 1 displays a paper feed tray setting screen (step S63).

FIG. 36 shows a paper feed tray setting screen G42.
On the right side of the screen, a state that starts from the setting menu, changes to the paper feed tray setting through the user setting and the environment setting is displayed. On the left side of the screen, a “paper setting” button is displayed to be pressed.

  The control unit 1 determines whether or not a pressing signal generated when the “paper setting” button is pressed on the paper feed tray setting screen G42 (step S64).

When the press signal of the paper setting button is not input (step S64; N), the control unit 1 continuously displays the paper feed tray setting screen G42.
When a paper setting button pressing signal is input (step S64; Y), the control unit 1 displays a paper profile registration screen (step S65).

FIG. 37 shows a paper profile registration screen G43.
In the center of the screen, no. 1-No. A total of 500 paper profiles up to 500 are displayed to be selectable. In addition, an “add / edit” button is displayed at the bottom of the screen so that it can be pressed.

  The control unit 1 determines whether or not a press signal generated when a paper profile is selected on the paper profile registration screen G43 and the “add / edit” button is pressed is input (step S66).

When the push signal of the add / edit button is not input (step S66; N), the control unit 1 continuously displays the paper profile registration screen G43.
When a signal for pressing the add / edit button is input (step S66; Y), the control unit 1 displays a paper condition registration screen (step S67).

FIG. 38 shows a paper condition registration screen G44.
The sheet condition registration screen G44 has the same configuration and contents as the individual setting change screen G2 (see FIG. 9). On the left side of the screen, an “output paper density adjustment” button is displayed so that it can be pressed. When the “output paper density adjustment” button is pressed, a “default correction value” button, a “paper category” button, and an “OFF” button are displayed on the left side of the screen.

  The control unit 1 determines whether or not the “output paper density adjustment” and “paper category” are selected on the paper condition registration screen G44 and a pressing signal generated when the “OK” button is pressed is input. (Step S68).

When the OK button pressing signal is not input (step S68; N), the control unit 1 continuously displays the paper condition registration screen G44.
When an OK button pressing signal is input (step S68; Y), the control unit 1 displays the paper category selection screen again (step S69).

FIG. 39 shows a paper category selection screen G45.
The paper category selection screen G45 has the same configuration and contents as the paper category selection screen G34 (see FIG. 32). In the center of the screen, a paper category is displayed so as to be selectable. The paper category displayed here is a paper category registered in advance by the user. In addition, an “OK” button is displayed at the bottom of the screen so that it can be pressed.

  The control unit 1 determines whether or not a press signal generated when the paper category is selected and the “OK” button is pressed on the paper category selection screen G45 is input (step S70).

When the OK button pressing signal is not input (step S70; N), the control unit 1 continuously displays the paper category selection screen G45.
When an OK button pressing signal is input (step S70; Y), the control unit 1 displays the paper condition registration screen G44 again (step S71).

FIG. 40 shows the sheet condition registration screen G46 displayed again.
The paper condition registration screen G46 displayed again has the same configuration and contents as the paper condition registration screen G44 (see FIG. 38). In the paper condition registration screen G46, an “output paper density adjustment” button and a “paper category” button are displayed in a pressed state. In addition, an “OK” button is displayed at the bottom of the screen so that it can be pressed.

  The control unit 1 determines whether or not a pressing signal generated when the “OK” button is pressed on the paper condition registration screen G46 is input (step S72).

When the OK button pressing signal is not input (step S72; N), the control unit 1 continuously displays the paper condition registration screen G46.
When an OK button pressing signal is input (step S72; Y), the control unit 1 registers a paper profile (step S73) and ends the paper profile registration process.

  As described above, according to the present embodiment, the color space coordinate value conversion information (XYZ tristimulus conversion curve) is stored in advance in the storage medium (nonvolatile memory 1b) for each type of paper actually used by the user. I can leave. The color space coordinate value conversion information (XYZ tristimulus value conversion curve) is measured by the voltage value information input by the color sensor 22 and the color space coordinate value colorimeter (XYZ tristimulus value colorimeter 31). It is generated based on the information of the color space coordinate values (XYZ tristimulus values). Therefore, the user can apply the optimal printer γ correction to the actually used paper with a simple operation.

  The XYZ tristimulus conversion curve can be registered in the paper category, and the paper category can be associated with the tray paper profile or the paper profile.

  Further, the tray paper profile and the paper profile can be associated with each other.

  Further, when the paper category in which the XYZ tristimulus conversion curve is registered is deleted or changed, the association between the deleted or changed paper category and the tray paper profile or the paper profile can be canceled.

  In addition, when the paper category in which the XYZ tristimulus conversion curve is registered is changed, and when the paper type used for generating the XYZ tristimulus conversion curve is different before and after the change, the changed paper category The association with the tray paper profile or the paper profile can be released.

  Further, when the paper type of the tray paper profile or the paper profile is changed, the association between the changed tray paper profile or the paper profile and the paper category can be canceled.

DESCRIPTION OF SYMBOLS 10 Image forming apparatus 11 Image forming part 12 Paper feed parts 13-16 Photosensitive drum 17 Intermediate transfer belt 18 Transfer roller 19 Fixing device 21 Relay unit 22 Color sensor 1 Control part 2 Display part 3 Scanner part 4 Printer part 5 Printer controller

Claims (18)

A step of forming a density correction chart on a sheet by the image forming unit;
A step of measuring the density correction chart formed on the paper by a color sensor and inputting information on a voltage value as a color measurement result;
Storing the input voltage value by a storage medium;
A step of measuring the density correction chart formed on the paper by a color space coordinate value colorimeter and inputting information of the color space coordinate value as a color measurement result;
The control unit generates color space coordinate value conversion information for performing color space coordinate value conversion processing for converting a voltage value into a color space coordinate value based on the voltage value information and the color space coordinate value information, Storing the generated color space coordinate value conversion information in the storage medium;
An image processing support method including: Storing at least a tray paper profile or a paper profile for managing a paper type by the storage medium;
Associating the color space coordinate value conversion information with a tray paper profile or a paper profile for managing the same paper type as the paper type used to generate the color space coordinate value conversion information by the control unit;
The image processing support method according to claim 1, comprising: Associating the tray paper profile associated with the color space coordinate value conversion information with the paper profile associated with the color space coordinate value conversion information by the control unit;
The image processing support method according to claim 2, comprising: When the control unit changes or deletes the color space coordinate value conversion information stored in the storage medium, the association between the changed or deleted color space coordinate value conversion information and the tray paper profile or the paper profile The step of releasing
4. The image processing support method according to claim 2, further comprising: When the color space coordinate value conversion information stored in the storage medium is changed by the control unit, and the paper type used for generating the color space coordinate value conversion information is different before and after the change, the change is made. Releasing the association between the color space coordinate value conversion information and the tray paper profile or the paper profile;
The image processing support method according to any one of claims 2 to 4, further comprising: When the control unit changes the tray paper profile or the paper type managed by the paper profile, releasing the association between the changed tray paper profile or paper profile and the color space coordinate value conversion information;
The image processing support method according to any one of claims 2 to 5, further comprising: An image forming unit for forming a density correction chart on paper;
A color sensor that measures the density correction chart formed on the paper and inputs voltage value information that is a color measurement result; and
A storage medium for storing the input voltage value;
A color space coordinate value colorimeter that measures the density correction chart formed on the paper and inputs information of the color space coordinate value that is the color measurement result;
Color space coordinate value conversion information for performing color space coordinate value conversion processing for converting a voltage value into a color space coordinate value based on the voltage value information and the color space coordinate value information is generated, and the generated color A control unit that stores spatial coordinate value conversion information in the storage medium;
Image processing support system. The storage medium stores at least a tray paper profile or a paper profile for managing paper types,
8. The control unit according to claim 7, wherein the control unit associates the color space coordinate value conversion information with a tray paper profile or a paper profile that manages the same paper type as the paper type used to generate the color space coordinate value conversion information. Image processing support system.   The image processing support system according to claim 8, wherein the control unit associates a tray sheet profile associated with the color space coordinate value conversion information with a sheet profile associated with the color space coordinate value conversion information.   When the color space coordinate value conversion information stored in the storage medium is changed or deleted, the control unit associates the changed or deleted color space coordinate value conversion information with the tray paper profile or the paper profile. The image processing support system according to claim 8, wherein the image processing support system is canceled.   When the color space coordinate value conversion information stored in the storage medium is changed and the paper type used for generating the color space coordinate value conversion information is different before and after the change, the control unit changes the color space coordinate value conversion information. The image processing support system according to any one of claims 8 to 10, wherein the association between the color space coordinate value conversion information and the tray sheet profile or the sheet profile is canceled.   9. The control unit cancels the association between the changed tray paper profile or paper profile and the color space coordinate value conversion information when the paper type managed by the tray paper profile or paper profile is changed. The image processing assistance system as described in any one of -11. An image forming unit for forming a density correction chart on paper;
A color sensor that measures the density correction chart formed on the paper and inputs voltage value information that is a color measurement result; and
A storage medium for storing the input voltage value;
An input unit for measuring the density correction chart formed on the paper and inputting information of color space coordinate values as a color measurement result;
Color space coordinate value conversion information for performing color space coordinate value conversion processing for converting a voltage value into a color space coordinate value based on the voltage value information and the color space coordinate value information is generated, and the generated color A control unit that stores spatial coordinate value conversion information in the storage medium;
An image forming apparatus. The storage medium stores at least a tray paper profile or a paper profile for managing paper types,
14. The control unit according to claim 13, wherein the control unit associates the color space coordinate value conversion information with a tray paper profile or a paper profile that manages the same paper type as the paper type used to generate the color space coordinate value conversion information. Image forming apparatus.   The image forming apparatus according to claim 14, wherein the control unit associates a tray sheet profile associated with the color space coordinate value conversion information with a sheet profile associated with the color space coordinate value conversion information.   When the color space coordinate value conversion information stored in the storage medium is changed or deleted, the control unit associates the changed or deleted color space coordinate value conversion information with the tray paper profile or the paper profile. The image forming apparatus according to claim 14, wherein the image forming apparatus cancels the image.   When the color space coordinate value conversion information stored in the storage medium is changed and the paper type used for generating the color space coordinate value conversion information is different before and after the change, the control unit changes the color space coordinate value conversion information. The image forming apparatus according to claim 14, wherein the association between the color space coordinate value conversion information and the tray sheet profile or the sheet profile is canceled.   15. The control unit cancels the association between the changed tray paper profile or paper profile and the color space coordinate value conversion information when the paper type managed by the tray paper profile or the paper profile is changed. The image forming apparatus according to any one of -16.

Images