JP2016049768A - Printing system, and management device and management method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a printing system, and a management device and a management method such that platemaking conditions and printing conditions for obtaining printed matter of high quality through flexographic printing can be easily grasped.SOLUTION: An evaluation region in which at least one of items evaluated with an evaluation image for image characteristic evaluation can be evaluated is detected from a document image. First characteristic data is obtained by measuring characteristics of the document image from the evaluation region. Second characteristic data obtained by previously measuring characteristics of the evaluation image, and a flexographic printing characteristic model showing correspondence between platemaking conditions and printing conditions of a flexographic printing plate in printing the evaluation image as a measurement source of the second characteristic data are stored. A target value of the first characteristic data is set. Platemaking conditions and printing conditions corresponding to the target value of the first characteristic data are determined by referring to the flexographic printing characteristic model. Based upon the first characteristic data obtained by measuring the document image and a result of comparison with the target value, it is determined whether at least one of the platemaking conditions and printing conditions are corrected or not.SELECTED DRAWING: Figure 12

Description

  The present invention relates to a printing system for performing flexographic printing, and a management apparatus and management method for managing plate making conditions and printing conditions for flexographic printing.

  In recent years, flexographic printing methods have attracted attention as environmentally friendly printing methods (see Patent Document 1 and Patent Document 2). In flexographic printing, printing is performed using a flexible and flexible flexographic printing plate (letter plate) and ink (water-based ink, UV (ultraviolet) ink, etc.). In this flexographic printing method, as in other printing methods, various printing conditions are usually adjusted in order to improve the image quality of printed matter.

  For example, Patent Document 3 discloses that the amount of ink in a printing device is controlled by controlling the amount of ink in a printing device based on the result of comparing color management data, which is a target value when printing a printed material, and color measurement data of the printed material. A method for appropriately adjusting color reproduction is disclosed. Thereby, the image quality of printed matter can be improved.

  Patent Document 4 discloses an inspection apparatus that inspects color misregistration by comparing photographed image data obtained by imaging a printed matter with an image sensor and reference image data of a printed matter stored in advance. It is disclosed. As a result, the printing apparatus can be adjusted in a short time, and high color reproduction without color misregistration is realized, so that the image quality of the printed matter can be improved.

JP 2014-69427 A JP 2014-69428 A JP 2004-195739 A JP 2006-130795 A

  By the way, in the flexographic printing method, the quality of the image structure (unevenness and streaks and artifacts on the flat screen, line quality) changes in addition to the color reproduction disclosed in Patent Document 3 and Patent Document 4 due to print control. For this reason, in order to achieve both the image structure and color reproduction of the printed material in flexographic printing, not only the printing conditions for performing flexographic printing, but also the plate-making conditions for making a flexographic printing plate (the shape of the flexographic printing plate, etc.) ) Also needs to be determined appropriately. In the inventions disclosed in Patent Document 3 and Patent Document 4, the plate making conditions for obtaining a high-quality printed matter and the method for determining the printing conditions are not disclosed. In flexographic printing, the plate making conditions are determined by the know-how of an expert. It is necessary to determine printing conditions.

  Here, regarding the plate making conditions and printing conditions, a method of acquiring conditions set by a manufacturer that manufactures a printing system that performs flexographic printing is also conceivable. However, although the printing system used for obtaining the conditions in the manufacturer and the customer's printing system are the same model, the print reproducibility is not completely the same due to manufacturing errors and daily fluctuations of each part. Also, when the document image to be printed changes, appropriate plate making conditions and printing conditions may also change. For this reason, even if the plate-making conditions and printing conditions provided by the manufacturer are used, it is not always possible to obtain a high-quality printed matter. As described above, it is necessary to determine the plate-making conditions and printing conditions based on the know-how of a skilled person. was there.

  The present invention has been made in view of such circumstances, and provides a printing system, a management apparatus, and a management method capable of easily grasping plate making conditions and printing conditions for obtaining a high-quality printed material in flexographic printing. The purpose is to provide.

  A printing system for achieving the object of the present invention includes a plate making unit for making a flexographic printing plate based on a document image, a printing unit for printing a document image on a printing medium using the flexographic printing plate, and a document image. An evaluation area detection unit that detects an evaluation area that can evaluate at least one of the items evaluated in the evaluation image for image characteristic evaluation, and an evaluation area detection by reading an original image printed on a printing medium by the printing unit A measurement unit for measuring the characteristics of the document image from the evaluation area detected by the unit to obtain first characteristic data, second characteristic data obtained by measuring the characteristics of the evaluation image in advance, and measurement of the second characteristic data A storage unit storing a flexographic printing characteristic model indicating a correspondence relationship between a plate making condition and a printing condition of a flexographic printing plate when printing an original evaluation image, and a target value setting for setting a target value of first characteristic data The plate making conditions and the printing conditions corresponding to the target values are determined with reference to the flexographic printing characteristic model stored in the storage unit based on the target values of the first characteristic data set by the copying unit and the target value setting unit. A characteristic for acquiring first characteristic data of an original image obtained through plate making of the plate making unit and printing of the printing unit based on the plate making conditions and printing conditions determined by the condition determining unit from the condition determining unit and the measuring unit A correction determination for determining whether or not to correct at least one of the plate making conditions and the printing conditions based on a comparison result between the data acquisition unit, the first characteristic data acquired by the characteristic data acquisition unit, and the target value A section.

  According to the present invention, as compared with the case where the platemaking conditions and the printing conditions are determined based on the experience of the operator or the like, the platemaking conditions and the printing conditions for obtaining a high-quality printed material in flexographic printing are easily grasped. be able to. Further, since the plate making conditions and the printing conditions are corrected based on the first characteristic data detected from the evaluation area of the original image, it is possible to grasp the plate making conditions and the printing conditions suitable for the original image to be printed.

  In the printing system according to another aspect of the present invention, the target value setting unit sets a target value of the first characteristic data corresponding to a predetermined item, and the correction determination unit includes a plurality of types of characteristic data acquisition units. A first characteristic data storage unit for storing first characteristic data respectively acquired from the document image, and the first characteristic data corresponding to all of the target values set by the target value setting unit is the first characteristic data storage unit; Is stored in the first characteristic data storage unit, based on the comparison result between the first characteristic data in the first characteristic data storage unit and the target value, it is determined whether or not to correct at least one of the plate making conditions and the printing conditions. Accordingly, it is possible to determine whether or not to correct the plate making conditions and the printing conditions based on the first characteristic data including all the main items or items according to the customer's request.

  In the printing system according to another aspect of the present invention, when the plurality of first characteristic data corresponding to the same item is stored in the first characteristic data storage unit, the correction determination unit averages the plurality of first characteristic data. Whether or not to correct at least one of the plate making conditions and the printing conditions is determined based on the comparison result between the weighted average value obtained by increasing the weight of the first characteristic data that is new in time and the target value. Accordingly, it is possible to determine whether or not to correct the plate making condition and the printing condition based on the average value or the weighted average value of the first characteristic data.

  In the printing system according to another aspect of the present invention, when the correction determining unit determines to correct at least one of the plate making conditions and the printing conditions, based on the comparison result, at least one of the plate making conditions and the printing conditions. A condition correcting unit for correcting Thereby, a high quality printed matter is obtained.

  In the printing system according to another aspect of the present invention, when the plate making conditions are corrected, the plate making unit makes a flexographic printing plate based on the corrected plate making conditions, and the printing unit has the printing conditions corrected. In this case, printing is performed based on the corrected printing conditions. Thereby, a high quality printed matter is obtained.

  In the printing system according to another aspect of the present invention, the condition correction unit corrects at least one of the plate making condition and the printing condition based on the difference between the target value and the first characteristic data obtained by the measurement unit. Thereby, it is possible to easily determine plate making conditions and printing conditions for obtaining a high-quality printed matter.

  In the printing system according to another aspect of the present invention, the plate-making unit and the printing unit of the same model as the plate-making unit and the printing unit print an evaluation image on the printing medium for each plate-making condition and printing condition, The measurement unit of the same model measures the characteristics of the evaluation image for each condition to obtain second characteristic data, and the flexographic printing characteristic model construction unit stores the flexographic printing characteristic model generated based on the second characteristic data for each condition Department remembers. Accordingly, it is possible to easily determine plate making conditions and printing conditions for obtaining a high-quality printed material with reference to the flexographic printing characteristic model.

  The printing system according to another aspect of the present invention includes a model acquisition unit that acquires the flexographic printing characteristic model generated by the flexographic printing characteristic model construction unit and stores it in the storage unit. Thereby, the flexographic printing characteristic model generated by the manufacturer of the printing system can be acquired.

  In the printing system according to another aspect of the present invention, the evaluation area detecting unit analyzes the image data of the document image and detects the evaluation area. Thereby, at least one item of the items evaluated by the evaluation image can be measured from the evaluation area of the document image.

  In the printing system according to another aspect of the present invention, the evaluation area detection unit detects the evaluation area by analyzing the reading result of the document image read by the measurement unit. Thereby, at least one item of the items evaluated by the evaluation image can be measured from the evaluation area of the document image.

  In the printing system according to another aspect of the present invention, the first characteristic data and the second characteristic data include image quality characteristic data indicating image quality characteristics and color characteristic data indicating color characteristics. It is possible to achieve both the image structure of printed matter and color reproduction.

  A management apparatus for achieving the object of the present invention includes a plate making condition of a plate making unit for making a flexographic printing plate based on a manuscript image, and printing of a printing unit for printing a manuscript image on a printing medium using the flexographic printing plate. In the management device for managing the conditions, the first characteristic indicating the characteristics of the evaluation area that is an evaluation area included in the document image and that can evaluate at least one of the items evaluated in the evaluation image for image characteristic evaluation A target value setting unit for setting a target value of data, second characteristic data obtained by measuring characteristics of an evaluation image in advance, and a flexographic printing plate for printing an evaluation image as a measurement source of the second characteristic data Flexographic printing stored in the storage unit based on the target value of the first characteristic data set by the storage unit storing the flexographic printing characteristic model indicating the correspondence between the plate making conditions and the printing conditions and the target value setting unit A condition determining unit that determines a plate-making condition and a printing condition corresponding to the target value with reference to the property model, and plate-making and printing of the plate-making unit based on the plate-making condition and the printing condition determined by the condition determining unit Based on the comparison result between the target data and the characteristic data acquisition unit that acquires the first characteristic data of the original image obtained through the process, the first characteristic data acquired by the characteristic data acquisition unit, and the target value A correction determining unit that determines whether to correct at least one of the conditions.

  In the management device according to another aspect of the present invention, the target value setting unit sets a target value of the first characteristic data corresponding to a predetermined item, and the correction determination unit includes a plurality of types of characteristic data acquisition units. A first characteristic data storage unit for storing first characteristic data respectively acquired from the document image, and the first characteristic data corresponding to all of the target values set by the target value setting unit is the first characteristic data storage unit; Is stored in the first characteristic data storage unit, based on the comparison result between the first characteristic data in the first characteristic data storage unit and the target value, it is determined whether or not to correct at least one of the plate making conditions and the printing conditions.

  In the management device according to another aspect of the present invention, when the correction determining unit determines to correct at least one of the plate making conditions and the printing conditions, based on the comparison result, at least one of the plate making conditions and the printing conditions A condition correcting unit for correcting

  A management method for achieving the object of the present invention includes a plate making condition for making a flexographic printing plate based on a manuscript image, and printing of a printing unit for printing a manuscript image on a printing medium using the flexographic printing plate. In the management method for managing conditions, a first characteristic indicating a characteristic of an evaluation area that is an evaluation area included in a document image and that can evaluate at least one of the items evaluated in the evaluation image for image characteristic evaluation A target value setting step for setting a target value of data, second characteristic data obtained by measuring characteristics of an evaluation image in advance, and a flexographic printing plate for printing an evaluation image as a measurement source of the second characteristic data Based on the target value of the first characteristic data set in the storage step for storing the flexographic printing characteristic model indicating the correspondence between the plate making conditions and the printing conditions in the storage unit and the target value setting step. A step of determining a plate making condition and a printing condition corresponding to a target value with reference to a flexographic printing characteristic model stored in the printing unit, and a plate making based on the plate making condition and the printing condition determined in the condition determining step The characteristic data acquisition step for acquiring the first characteristic data of the original image obtained through the plate making of the part and the printing of the printing part, the first characteristic data acquired in the characteristic data acquisition step, and the comparison result with the target value A correction determining step for determining whether or not to correct at least one of the plate making conditions and the printing conditions.

  In the management method according to another aspect of the present invention, the target value setting step sets a target value of the first characteristic data corresponding to a predetermined item, and the correction determination step includes a plurality of types of correction data in the characteristic data acquisition step. First characteristic data acquired from each original image is stored in the first characteristic data storage unit, and first characteristic data corresponding to all the target values set in the target value setting step is stored in the first characteristic data storage unit. If it is determined, whether or not to correct at least one of the plate making conditions and the printing conditions is determined based on the comparison result between the first characteristic data in the first characteristic data storage unit and the target value.

  In the management method according to another aspect of the present invention, when it is determined in the correction determination step that at least one of the plate making conditions and the printing conditions is to be corrected, based on the comparison result, at least one of the plate making conditions and the printing conditions. A condition correcting step for correcting the condition;

  The printing system, management apparatus, and management method of the present invention can easily grasp plate making conditions and printing conditions for obtaining a high-quality printed material in flexographic printing.

1 is a schematic diagram of a printing system. It is the schematic which showed an example of the flexographic plate-making apparatus. It is the schematic of the CTP (Computer To Plate) drawing part of a flexographic plate-making apparatus. It is explanatory drawing for demonstrating an example of platemaking conditions. It is explanatory drawing for demonstrating "convex shape" of platemaking conditions. It is explanatory drawing for demonstrating "concave shape" of platemaking conditions. 1 is a schematic view of an example of a flexographic printing apparatus. It is description for demonstrating an example of printing conditions. It is explanatory drawing for demonstrating an example of an analysis chart. FIG. 10 is an enlarged view of a part of the analysis chart shown in FIG. 9. It is explanatory drawing for demonstrating 2nd characteristic data. It is a functional block diagram of the measuring apparatus and management apparatus of a printing system. It is explanatory drawing for demonstrating an example of the evaluation area | region in a document image. It is a flowchart which shows the flow of the detection process of each evaluation area | region by an evaluation area | region detection part. It is a flowchart which shows the flow of the production | generation process of the flexographic printing characteristic model by a model construction system. It is a flowchart which shows the flow of the platemaking conditions in the printing system, and the correction process of printing conditions. It is explanatory drawing for demonstrating the correction process of platemaking conditions and printing conditions. It is a functional block diagram of the management apparatus which comprises the printing system of another embodiment. It is explanatory drawing for demonstrating the correction process of the initial platemaking conditions and printing conditions by the condition correction part of another embodiment. It is a flowchart which shows the flow of the plate-making conditions in the printing system of another embodiment, and the correction process of printing conditions. It is explanatory drawing for demonstrating the process of the condition correction part when the several 1st characteristic data corresponding to the same evaluation item are memorize | stored in the 1st characteristic data storage part.

[Configuration of printing system]
FIG. 1 is a schematic diagram of a printing system 10. As shown in FIG. 1, the printing system 10 performs flexographic printing in which an image is printed on a printing medium 13 (see FIG. 7) using a flexographic printing plate 12 (letter plate) and ink, whereby a printed material 14 is printed. Generate. The printing system 10 is roughly divided into a flexographic plate making apparatus 20 corresponding to the plate making section of the present invention, a flexographic printing apparatus 30 corresponding to the printing section of the present invention, and a measuring apparatus 40 corresponding to the measuring section of the present invention. The management apparatus 50 is comprised.

  The flexographic plate making apparatus 20 forms a relief 19 (see FIG. 3) corresponding to the original image 16 on the flexographic plate material F (see FIG. 3) based on the image data of the original image 16, thereby making the plate making of the flexographic printing plate 12. I do.

  FIG. 2 is a schematic view showing an example of the flexographic plate making apparatus 20. As shown in FIG. 2, the flexographic plate making apparatus 20 broadly includes a RIP (Raster Image Processor) processing unit 21 and a CTP (Computer To Plate) drawing unit 22 that performs laser engraving. Note that the configuration of the flexographic plate making apparatus 20 is not limited to the configuration shown in FIG. 2 as long as the flexographic printing plate 12 is made based on image data.

  The RIP processing unit 21 develops image data of the original image 16 into raster image data, screening processing for generating binary image data from the raster image data, and exposure for converting the binary image data into exposure amount data. A quantity data generation process is performed.

  Specifically, the RIP processing unit 21 is a page description language (Page) such as PDF (Portable Document Format) data or PS (PostScript) data that represents a vector image of the original image 16 edited using a computer or the like. A decompression process for decompressing (Description Language) data into raster image data is performed.

  Next, the RIP processing unit 21 screens the raster image data under conditions such as halftone dots [AM (Amplitude Modulation) halftone dots, FM (Frequency Modulation) halftone dots, etc.], angles, and screen line numbers. Then, it is converted into binary image data.

  Then, the RIP processing unit 21 generates relief pattern data indicating the relief 19 to be formed on the flexographic printing plate 12 based on the binary image data, and the exposure amount corresponding to the exposure light quantity with respect to the flexographic printing material F. Convert to data. The RIP processing unit 21 outputs the exposure amount data to the CTP drawing unit 22.

  FIG. 3 is a schematic diagram of the CTP drawing unit 22. As shown in FIG. 3, the CTP drawing unit 22 performs laser engraving processing on the flexographic printing material F made of an elastic material such as synthetic resin or rubber based on the exposure amount data input from the RIP processing unit 21. To make the flexographic printing plate 12.

  The CTP drawing unit 22 includes a drum 62 and an exposure head 68 for performing exposure engraving on the flexographic printing material F held on the drum 62, and functions as a so-called laser engraving machine. The exposure head 68 is mounted on a stage 70 and can be moved by a focus position changing mechanism 72 and an intermittent feed mechanism 78.

  The focus position changing mechanism 72 includes a motor 74 and a ball screw 76 for moving the exposure head 68 back and forth with respect to the drum 62 to which the flexographic printing material F is attached. The movement of the exposure head 68 in the main scanning direction is controlled by the motor 74 and the ball screw 76, and the focus position of the exposure engraving process is adjusted.

  The intermittent feed mechanism 78 includes a ball screw 80 and a sub-scanning motor 82 that rotates the ball screw 80. The movement of the exposure head 68 (stage 70) in the sub-scanning direction is controlled by the ball screw 80 and the sub-scanning motor 82, and the exposure head 68 is intermittently fed in the direction of the axis 64 (sub-scanning direction) of the drum 62. The flexographic printing material F on the drum 62 is chucked by the chuck member 66 and the holding position on the drum 62 is fixed. The position where the flexographic printing material F is chucked by the chuck member 66 is an area where exposure by the exposure head 68 is not performed.

  A desired relief 19 is formed on the surface of the flexographic printing material F by irradiating the flexographic printing material F with a laser beam from the exposure head 68 while rotating the drum 62. When the chuck member 66 passes in front of the exposure head 68 by the rotation of the drum 62, the exposure head 68 (stage 70) is intermittently fed in the sub-scanning direction, and then laser engraving of the next line is performed.

  The exposure scanning position is controlled by combining such “feeding of the flexographic printing plate F in the main scanning direction by rotation of the drum 62” and “intermittent feeding of the exposure head 68 in the sub-scanning direction”. Further, by controlling the intensity and on / off of the laser beam based on the exposure amount data (depth data) for each exposure scanning position, the relief 19 having a desired shape is laser engraved on the flexographic printing material F and used for flexographic printing. A flexographic printing plate 12 is formed.

  The flexographic plate making apparatus 20 having the above-described configuration can adjust the plate making conditions 25 (see FIGS. 1 and 4) when the flexographic printing plate 12 is made. By adjusting the plate-making conditions 25, the shape of the flexographic printing plate 12 is controlled, and as a result, image quality characteristics such as image structure quality and line quality of an image printed on the printed matter 14 can be appropriately adjusted.

  FIG. 4 is an explanatory diagram for explaining an example of the plate making conditions 25. As shown in FIG. 4, the platemaking conditions 25 include, for example, conditions of “net shape”, “number of mesh lines”, “net angle series”, “convex shape”, and “concave shape”. Note that “C / M / Y / K” in each condition represents the ink color [cyan (C), magenta (M), yellow (Y), black (K)].

  The “net shape” is the shape of the halftone dots of the flexographic printing plate 12. “Number of mesh lines” is the number of mesh lines per unit length in a flat network formed by regularly arranging a plurality of halftone dots. The “halftone angle series” is a halftone angle, and is set by changing the angle for each color (C / M / Y / K) in order to prevent the occurrence of moire in, for example, four-color printing.

  FIG. 5 is an explanatory diagram for explaining the “convex shape” of the platemaking condition 25, and FIG. 6 is an explanatory diagram for explaining the “concave shape” of the platemaking condition 25. As shown in FIG. 5, the “convex shape” represents the shape of the convex portion of the flexographic printing plate 12 that is a relief plate. The shape of this convex part is represented by the height of the cap layer (indicated by CAP in the figure) constituting the tip of the convex part and the inclination angle θ1 of the base end part of the convex part.

  As shown in FIG. 6, the “concave shape” represents the shape of the concave portion located between the convex portions of the flexographic printing plate 12. The shape of the concave portion is represented by the depth of the concave portion (indicated by D in the figure) and the inclination angle θ2 of the bottom portion of the concave portion.

  The flexo plate making apparatus 20 performs the plate making of the flexographic printing plate 12 in accordance with each of the plate making conditions 25 described above.

  FIG. 7 is a schematic diagram illustrating an example of the flexographic printing apparatus 30. As shown in FIG. 7, the flexographic printing apparatus 30 uses the flexographic printing plate 12 made by the flexographic plate making apparatus 20 to print an image on a printing medium 13 to generate a printed matter 14. The flexographic printing apparatus 30 is roughly divided into a flexographic printing plate 12, a plate cylinder 34 to which the flexographic printing plate 12 is attached via a cushion tape 32 such as a double-sided tape, and an anilox roller 38 to which ink is supplied by a doctor chamber 36. And an impression cylinder 39 installed so as to face the plate cylinder 34.

  Ink is transferred from the anilox roller 38 to the top (printing surface) of the relief 19 of the flexographic printing plate 12 attached to the plate cylinder 34. Then, when the printing medium 13 passes between the plate cylinder 34 to which the flexographic printing plate 12 is attached and the impression cylinder 39, the flexographic printing plate 12 (the top of the relief 19) is pressed against the printing medium 13. As a result, the ink adhering to the top of the relief of the flexographic printing plate 12 is transferred to the printing medium 13. As a result, a desired image is printed and formed on the printing medium 13, and a printed matter 14 is generated.

  The flexographic printing apparatus 30 having the above configuration can adjust the printing condition 27 (see FIGS. 1 and 8) when printing an image on the printing medium 13. By adjusting the printing condition 27, the printed matter 14 can be adjusted. Color characteristics such as gradation and color reproducibility of a printed image can be adjusted appropriately.

  FIG. 8 is an explanatory diagram for explaining an example of the printing condition 27. The printing conditions 27 include, for example, “ink type”, “ink viscosity”, “cushion tape”, “printing pressure”, “ani pressure”, “printing speed”, “number of anilox roller lines”, and “anilox roller cell capacity”. "And" Anilox Roller Cell Shape "are included. As in the plate making condition 25 described above, “C / M / Y / K” represents the ink color under the corresponding condition.

  “Ink type” represents the type of ink used for flexographic printing. “Ink viscosity” represents the recommended viscosity of ink used for flexographic printing. “Cushion tape” represents the type (soft, semi-soft, etc.) of the cushion tape 32. “Printing pressure” represents the amount of compression (biting-in amount) of the flexographic printing plate 12 by the printing pressure applied to the flexographic printing plate 12. “Ani pressure” represents the amount of compression (biting amount) of the anilox roller 38 by the ani pressure, which is the pressure between the anilox roller 38 and the flexographic printing plate 12.

  “Anilox roller line number”, “Anilox roller cell capacity”, and “Anilox roller cell shape” represent the number of lines of the anilox roller 38, the capacity of the cell of the anilox roller 38, and the shape of the cell of the anilox roller 38, respectively. .

  In accordance with each of the printing conditions 27, the flexographic printing apparatus 30 performs flexographic printing and generates a printed matter 14.

  Returning to FIG. 1, the measuring device 40 uses the printed matter 14 on which the original image 16 is printed by the flexographic plate making device 20 and the flexographic printing device 30 as a measurement target. As will be described in detail later, the measuring device 40 measures the characteristics of the document image 16 printed on the printed matter 14 to obtain first characteristic data 42, and outputs the first characteristic data 42 to the management apparatus 50.

  As will be described in detail later, the management device 50 refers to the flexographic printing property model 92 generated by the model construction system 90 based on the first property data 42 input from the measuring device 40 and Manage (correct) printing conditions 27.

[Model construction system configuration]
The model construction system 90 is installed at a manufacturer that manufactures the printing system 10, and generates a flexographic printing characteristic model 92 that is used in the customer's printing system 10. The model construction system 90 includes the flexographic plate making apparatus 20, the flexographic printing apparatus 30, and the measurement apparatus 40 described above, the flexographic plate making apparatus 20 A, the flexographic printing apparatus 30 A, the measurement apparatus 40 A, and the model construction unit 93. ing. Here, the “same model” is not limited to the completely same model, but includes a model that has been subjected to minor improvements that are basically not different in print reproducibility.

  The flexographic plate making apparatus 20A forms a relief 19 corresponding to the analysis chart 95 on the flexographic plate material F under a predetermined plate making condition 25 based on image data of an analysis chart 95 (see FIG. 9) to be described later. The printing plate 12A is made. Since the specific plate making method is the same as that of the flexographic plate making apparatus 20 (see FIGS. 2 and 3), a specific description is omitted here.

  The flexographic printing apparatus 30A prints the analysis chart 95 on the printing medium 13 with the flexographic printing plate 12A made by the flexographic plate making apparatus 20A under a predetermined printing condition 27 to generate a printed matter 14A. Since a specific printing method is the same as that of the flexographic printing apparatus 30 (see FIG. 7), a specific description is omitted here.

  The measuring device 40A reads the analysis chart 95 printed on the printed material 14A through the flexographic plate making apparatus 20A and the flexographic printing apparatus 30A, and measures the characteristics of the analysis chart 95 to obtain second characteristic data 97.

  FIG. 9 is an explanatory diagram for explaining an example of an analysis chart 95 corresponding to an evaluation image for image characteristic evaluation of the present invention. FIG. 10 is an enlarged view of a part of the analysis chart 95 shown in FIG. The second characteristic data 97 is obtained by reading the analysis chart 95 with the measuring device 40A.

  As shown in FIGS. 9 and 10, the analysis chart 95 is analyzed by an image analysis algorithm corresponding to the analysis chart 95, whereby image quality characteristic data 98 (see FIG. 11) indicating the image quality characteristic of the analysis chart 95 is obtained. .

  For example, by analyzing the read result of the image structure area 95A of the analysis chart 95 [a color chart in which the mesh shape and the number of mesh lines are changed in stages for a plurality of colors (cyan, pink, gray, etc.)] by an image analysis algorithm. As the image quality characteristics, “granularity”, “banding”, and “straightness” indicating the image structure can be calculated. Further, the image analysis algorithm is used to read the reading result of the gradation region 95B of the analysis chart 95 [color chart in which the density of a plurality of colors (yellow, magenta, cyan, red, green, blue, gray, black, etc.) is changed stepwise]. Thus, “moire” indicating the image structure can be calculated as the image quality characteristic. Further, by analyzing the read result of the CTF (Contrast Transfer Function) area 95C [chart of vertical stripes and horizontal stripes] of the analysis chart 95 by the image analysis algorithm, “CTF” indicating the image structure is calculated as the image quality characteristic. Can do.

  Further, by analyzing the read result of the line quality region 95D [chart composed of a plurality of lines having different line widths] of the analysis chart 95 by using an image analysis algorithm, “line width” and “raditness” indicating line quality are shown as image quality characteristics. "And" Linear density "can be calculated.

  On the other hand, the color characteristic data 99 (see FIG. 11) is obtained by reading the analysis chart 95 with the measuring device 40A and measuring the color. For example, “gradation” indicating gradation can be obtained by measuring the above-described gradation region 95B. In addition, the tone jump area 95E of the analysis chart 95 [color chart in which the density of a plurality of colors (black, red, green, magenta, cyan, blue, etc.) is linearly changed] is measured, and the “tone” Jump "is obtained. Further, by measuring the color reproduction area 95F of the analysis chart 95 [a color chart of multiple colors whose color reproduction can be evaluated], a “color reproduction area depth”, “maximum density”, and “minimum density” indicating color reproduction are displayed. Is obtained.

  In FIG. 9, an image structure area 95A, a gradation area 95B, a tone jump area 95E, and a color reproduction area 95F are displayed in monochrome, but are actually multicolor color areas.

  FIG. 11 is an explanatory diagram for explaining the second characteristic data 97 obtained by the measuring apparatus 40A. As shown in FIG. 11, the measurement apparatus 40A reads and analyzes the image structure region 95A, the gradation region 95B, the CTF region 95C, and the line quality region 95D of the analysis chart 95, thereby analyzing the image structure (“granularity”). , “Banding”, “straight line”, “moire”, “CTF”) and line quality (“line width”, “raditness”, “line density”).

  The measuring device 40A measures the gradation (“gradation”, “tone jump”) and the color by measuring the gradation region 95B, the tone jump region 95E, and the color reproduction region 95F of the analysis chart 95. Color characteristic data 99 indicating reproduction (“color reproduction area depth”, “maximum density”, “minimum density”) is obtained. As a result, second characteristic data 97 including image quality characteristic data 98 and color characteristic data 99 is obtained. The measuring device 40A outputs the second characteristic data 97 to the model construction unit 93.

  Returning to FIG. 1, in the model construction system 90, the plate making of the flexographic printing plate 12A by the flexographic plate making device 20A, the printing of the analysis chart 95 by the flexographic printing device 30A, and the measuring device are performed while changing the plate making conditions 25 and the printing conditions 27. The measurement of the second characteristic data 97 (image quality characteristic data 98 and color characteristic data 99) by 40A is repeatedly executed.

<Generation processing of flexographic printing characteristic model>
The model construction unit 93 corresponds to the flexographic printing characteristic model construction unit of the present invention. The model construction unit 93 includes a flexographic printing characteristic model 92 that indicates the correspondence between the second characteristic data 97 and the plate-making conditions 25 and the printing conditions 27 when the analysis chart 95 of the measurement source of the second characteristic data 97 is printed. Is generated.

  The model construction unit 93 associates the plurality of plate making conditions 25 and printing conditions 27 with the second characteristic data 97 for each condition, for example, modeling by a known modeling method (multivariate analysis model, machine learning, neuron model). Thus, the flexographic printing characteristic model 92 is generated. By performing such modeling, it is not necessary to measure the second characteristic data 97 for all the plate making conditions 25 and printing conditions 27, and the second characteristic data 97 is measured under a limited number of conditions. Thus, the flexographic printing characteristic model 92 can be generated.

  Hereinafter, an example of generation of the flexographic printing characteristic model 92 by the model construction unit 93 will be described in detail.

  When the flexographic printing characteristic model 92 is generated, the items of the plate making condition 25 and the printing condition 27 are “explanatory variables”, and the image quality characteristic data 98 and the color characteristic data 99 of the second characteristic data 97 are “target variables”. Using the multiple regression analysis method, each coefficient of the multiple regression equation for predicting the value of the objective variable is obtained from the information of the explanatory variable. The plate making conditions 25 and the printing conditions 27 are handled as qualitative data as follows.

  In the plate making condition 25 and the printing condition 27 (see FIGS. 4 and 8), a nominal scale is used for the net shape, the net angle series, the convex shape, the concave shape, the ink type, and the anilox roller cell shape. In addition, an order scale is used for the number of mesh lines, ink viscosity, printing pressure, ani pressure, printing speed, number of anilox roller lines, and anilox roller cell capacity.

Using a quantification type 1 of multivariate analysis, digitize using a dummy variable. For the objective variables y1, y2, y3,... Corresponding to the granularity, moire, banding, etc. of the objective variables,
・ Y1 = a11 * x1 + a12 * x2 + a13 * x3 +…
・ Y2 = a21 * x1 + a22 * x2 + a23 * x3 +…
・ Y3 = a31 * x1 + a32 * x2 + a33 * x3 +…
・ ...
Each coefficient (a11, a12, a13,...) Of the prediction formula represented by Here, the variables x1, x2, x3,... Correspond to explanatory variables (network shape, mesh angle series, convex shape,...) That are digitized using an ordinal scale or a nominal scale.

  By determining the coefficients a11, a12, a13,... By the multivariate analysis method described above, the polynomial that predicts the image quality characteristic data 98 and the color characteristic data 99 from the plate making conditions 25 and the printing conditions 27 is converted into a flexographic printing characteristic model 92. As required. As a result, it is possible to generate the flexographic printing characteristic model 92 indicating the correspondence between the plate making conditions 25 and the printing conditions 27 and the second characteristic data 97 (image quality characteristic data 98 and color characteristic data 99). By referring to the flexographic printing characteristic model 92, the plate making condition 25 and the printing condition 27 can be determined with respect to the input of the image quality characteristic data 98 and the color characteristic data 99, as will be described in detail later. The flexographic printing characteristic model 92 generated by the model construction unit 93 is input to the management device 50 of the printing system 10.

[Measurement process of measuring device of printing system]
FIG. 12 is a functional block diagram of the measuring device 40 and the management device 50 of the printing system 10. As shown in FIG. 12, the measuring device 40 reads the document image 16 recorded on the printed material 14, and measures the evaluation items (see FIGS. 9 and 11) evaluated by the analysis chart 95. First characteristic data 42 indicating 16 characteristics is obtained.

  The measurement device 40 is provided with an evaluation region detection unit 45. Image data of the document image 16 is input to the evaluation area detection unit 45 before measurement by the measuring device 40 (before plate making and printing based on the document image 16). The evaluation area detection unit 45 is configured to evaluate an evaluation area 18 (see FIG. 13) in which at least one of the evaluation items evaluated by the analysis chart 95 can be evaluated from the document image 16 based on the image data of the document image 16. To detect.

<Evaluation area detection>
FIG. 13 is an explanatory diagram for explaining an example of the evaluation area 18 in the document image 16. As shown in FIG. 13, the evaluation area detection unit 45 uses, for example, an evaluation area 18 as an evaluation area 18, a maximum density evaluation area 18 B, and a color reproduction area 18 C from the illustrated document image 16. A minimum density evaluation area 18D and a line density evaluation area 18E are detected. In addition, the name of the evaluation item which can be evaluated is described in the rectangular frame corresponding to each evaluation area 18 in the figure.

  The graininess evaluation area 18 </ b> A is an area (for example, a background) having a uniform image density in the document image 16. Based on the image signal in the graininess evaluation area 18A, among the evaluation items that can be evaluated in the analysis chart 95, “graininess, banding, and streak” can be evaluated.

  The maximum density evaluation area 18B is an area (for example, a black subject area) where the image density is maximum in the document image 16. Based on the image signal in the maximum density evaluation region 18B, the “maximum density” can be evaluated among the evaluation items that can be evaluated in the analysis chart 95 described above.

  The color reproduction area 18C is an area in which the size of the color reproduction area can be detected in the document image 16 (for example, an area including at least one color of red (R), green (G), and blue (B)). Based on the image signal in the color gamut area 18C, the “color gamut area width” can be evaluated among the evaluation items that can be evaluated in the analysis chart 95 described above.

  The minimum density evaluation area 18D is an area (for example, a white subject area) in the document image 16 where the image density is minimum. Based on the image signal in the minimum density evaluation region 18D, the “minimum density” can be evaluated among the evaluation items that can be evaluated in the analysis chart 95 described above.

  The line density evaluation area 18E is an area in which the line width and line density can be detected in the document image 16 (for example, an area including lines such as characters and patterns). Based on the image signal in the line density evaluation area 18E, “line width and line density” can be evaluated among the evaluation items that can be evaluated by the analysis chart 95 described above.

  14A to 14E are flowcharts showing the flow of detection processing of each area of the evaluation area 18 by the evaluation area detection unit 45.

  As shown in FIG. 14A, the evaluation area detector 45 detects, for example, an evaluation area 18A such as a graininess, for example, a 35 mm ROI (Region of Interest: hereinafter referred to as ROI size (large)). Is set to an arbitrary position in the document image 16 (for example, any one of the four corners). Then, the evaluation region detection unit 45 analyzes the image signal within the range of the ROI size (large), and the density (pixel value) within the range of the ROI size (large) is uniform (here, the density is predetermined). Or “substantially uniform” that falls within the specified range). Thereafter, the evaluation area detection unit 45 scans the entire surface of the document image 16 while changing the position of the ROI size (large), and whether the density within the range of the ROI size (large) is uniform or not at each position. Sex determination processing is performed (step SA1).

  At this time, the evaluation area detection unit 45 determines the position of the ROI size (large) determined to have density uniformity as the evaluation area 18A for graininess etc. (YES in step SA2). Next, the evaluation area detecting unit 45 registers the position of the granularity evaluation area 18A [ROI size (large)] determined as the granularity evaluation area 18A in a memory (not shown) for each density (step SA3).

  As shown in FIG. 14B, when detecting the maximum density evaluation region 18B, the evaluation region detection unit 45 uses, for example, a 10 mm size ROI (hereinafter referred to as ROI size (medium)) in the document image 16. Set to any position. Then, the evaluation region detection unit 45 analyzes the image signal within the ROI size (medium) range and determines whether the density within the ROI size (medium) range is uniform. Thereafter, the evaluation area detection unit 45 scans the entire surface of the original image 16 while changing the position of the ROI size (medium), and determines whether the density within the range of the ROI size (medium) is uniform at each position. Uniformity determination processing is performed (step SB1).

  At this time, the evaluation region detection unit 45 selects the ROI size (medium) determined to have density uniformity among the ROI sizes (medium) at each position (YES in step SB2). Next, the evaluation area detection unit 45 determines the position of the ROI size (medium) that has the maximum density among the selected ROI sizes (medium) as the maximum density evaluation area 18B, and registers this position in the memory (step SB3). YES, step SB4).

  As shown in FIG. 14C, the evaluation area detector 45 scans the entire surface of the document image 16 while changing the position of the ROI size (medium) when detecting the color reproduction area 18C. At each position, uniformity determination processing of density within the range of the ROI size (medium) is performed (step SC1).

  At this time, the evaluation area detection unit 45 selects the ROI size (medium) determined to have density uniformity among the ROI sizes (medium) at each position (YES in step SC2). Next, the evaluation area detection unit 45, when there is an ROI size (medium) serving as a color gamut boundary, among ROI sizes (medium) having uniform density, the ROI size serving as a color gamut boundary. (Medium) is registered in the memory as the color reproduction area 18C (YES in step SC3, step SC4).

  As shown in FIG. 14D, when detecting the minimum density evaluation region 18D, the evaluation region detection unit 45 scans the entire surface of the document image 16 while changing the position of the ROI size (medium). At each position, uniformity determination processing of density within the range of the ROI size (medium) is performed (step SD1).

  At this time, the evaluation area detection unit 45 selects the ROI size (medium) determined to have density uniformity among the ROI sizes (medium) at each position (YES in step SD2). Next, the evaluation area detecting unit 45 determines the position of the ROI size (medium) that becomes the minimum density among the selected ROI sizes (medium) as the minimum density evaluation area 18D, and registers this position in the memory (step SD3). YES, step SD4).

  As shown in FIG. 14E, the evaluation area detector 45 performs line detection processing on the entire surface of the document image 16 when detecting the evaluation area 18E such as the line density (step SE1). Next, the evaluation area detection unit 45 determines an area having a line length equal to or greater than a predetermined value as a line evaluation position (YES in step SE2 and YES in step SE3). Then, the evaluation area detection unit 45 determines an area having a predetermined size including the line evaluation position as the line density evaluation area 18E, and registers this position in the memory (step SE4). Thus, the detection process of the evaluation area detection unit 45 ends.

  Each of the evaluation areas 18 described with reference to FIGS. 13 and 14 is an example of the evaluation area 18 that can be detected from the document image 16 illustrated in FIG. Therefore, by changing the type of the document image 16, it is possible to detect the evaluation area 18 in which the evaluation items (“moire”, “CTF”, “gradation”, etc.) of the analysis chart 95 other than the above can be evaluated. .

  The measuring device 40 measures the evaluation items (see FIG. 13) that can be evaluated in each area based on the detection result of the position of each area of the evaluation area 18 registered in the memory by the evaluation area detecting unit 45.

  Specifically, the measuring device 40 measures the graininess, banding, and unevenness based on the image signal in the graininess evaluation area 18A in the document image 16. As described above, since the position of the evaluation area 18A for graininess and the like is registered in the memory for each density, the graininess, banding, and unevenness are measured for each density. As a result, measurement results of “granularity”, “banding”, and “straightness” are obtained for each density value (optical density) of the image signal of the document image 16.

  The measuring device 40 also determines the maximum density, the color reproduction area width, and the minimum density based on the image signal in each of the maximum density evaluation area 18B, the color reproduction area 18C, and the minimum density evaluation area 18D in the document image 16. Measure each. Thereby, measurement results of “maximum density”, “color reproduction area width”, and “minimum density” of the document image 16 are obtained.

  Further, the measuring device 40 measures the line width (number of line width pixels) and the line density (density value) based on the image signal of the line density evaluation area 18E in the document image 16. As a result, measurement results of “line width” and “line density” of the document image 16 are obtained.

  Among the measurement results of the measurement apparatus 40 described above, “granularity”, “banding”, “straightness”, “line width”, and “line density” are included in the image quality characteristic data 98 (see FIG. 11). It is an evaluation item. Therefore, the measuring device 40 measures the image quality characteristic data 98S (see FIG. 12) constituted by these evaluation items (“granularity”, “banding”, “straightness”, “line width”, “line density”). To do. The image quality characteristic data 98S is data composed of items that can be evaluated in the document image 16 among the evaluation items of the image quality characteristic data 98 obtained by the measurement of the analysis chart 95 described above.

  In the measurement results of the measurement apparatus 40, the “maximum density”, “color reproduction area width”, and “minimum density” are evaluation items included in the color characteristic data 99 (see FIG. 11). It is. Therefore, the measuring device 40 measures the color characteristic data 99S (see FIG. 12) constituted by these evaluation items (“maximum density”, “color reproduction area width”, “minimum density”). The color characteristic data 99S is data composed of items that can be evaluated in the document image 16 among the evaluation items of the color characteristic data 99 obtained by the measurement of the analysis chart 95 described above.

  In this way, the measuring apparatus 40 measures the first characteristic data 42 (see FIG. 12) constituted by the image quality characteristic data 98S and the color characteristic data 99S from the document image 16, and the first characteristic data 42 is managed by the management apparatus. Output to 50.

[Configuration of management device]
Returning to FIG. 12, the management device 50 roughly includes a model acquisition unit 52, a storage unit 53, a target value setting unit 54, a condition determination unit 55, and a condition correction unit 56.

  The model acquisition unit 52 acquires the flexographic printing characteristic model 92 generated by the model construction unit 93 described above. For example, when the model acquisition unit 52 and the model construction unit 93 are connected via a wired or wireless network, or when the flexographic printing characteristic model 92 is stored in a server on the network, the model acquisition unit As 52, a communication interface is used. When the flexographic printing characteristic model 92 is recorded on an information recording medium such as a memory card, a reading interface that reads the flexographic printing characteristic model 92 from the information recording medium is used as the model acquisition unit 52. In addition, when the operator manually inputs the data of the flexographic printing characteristic model 92 to the management apparatus 50, an input interface such as a keyboard is used as the model acquisition unit 52. The model acquisition unit 52 stores the acquired flexographic printing characteristic model 92 in the storage unit 53.

  The storage unit 53 stores the flexographic printing characteristic model 92 input from the model acquisition unit 52. The processing from the acquisition of the flexographic printing characteristic model 92 by the model acquisition unit 52 to the storage of the flexographic printing characteristic model 92 in the storage unit 53 may be performed by the manufacturer of the printing system 10. When a new flexographic printing characteristic model 92 is generated in the manufacturer's model construction system 90, the new flexographic printing characteristic model 92 is acquired by the model acquisition unit 52 and stored in the storage unit 53. The characteristic model 92 may be overwritten.

  The target value setting unit 54 sets the target of the first characteristic data 42 (image quality characteristic data 98S and color characteristic data 99S) obtained by measuring the original image 16 with the measuring device 40 in advance before the original image 16 is printed. Set the value P. The setting of the target value P is performed, for example, according to the content of the target value setting operation input to the operation unit (not shown) based on the detection result of the evaluation area detection unit 45 described above.

  For example, when the evaluation area detecting unit 45 detects the evaluation area 18A such as the graininess, the operator separates the “graininess”, “banding”, and “straightness unevenness” according to the density value (optical density) of the image signal of the document image 16. The target value of each item is determined, and the target value setting operation for each item is performed. When the maximum density evaluation area 18B, the color reproduction area 18C, and the minimum density evaluation area 18D are detected by the evaluation area detection unit 45, the operator selects “maximum density”, “color reproduction area width”, and “minimum density reproduction area 18D”. The target value of each item of “density” is determined, and the target value setting operation for each item is performed. Further, when the evaluation area detection unit 45 detects the evaluation area 18E such as the line density, the operator selects the target value of the line width [the finished target line width (in mm) with respect to the number of line width pixels of the document image 16, and A target value [density value (optical density)] of the line density is determined, and a target value setting operation for each item is performed.

  The target value setting unit 54 determines the target value P of the first characteristic data 42 (each evaluation item of the image quality characteristic data 98S and the color characteristic data 99S) based on the above-described target value setting operation for each item, and this target value is set. The value P is output to the condition determining unit 55 and the condition correcting unit 56, respectively.

  The condition determination unit 55 refers to the flexographic printing characteristic model 92 stored in the storage unit 53 based on the target value P (image quality characteristic data 98S and color characteristic data 99S) input from the target value setting unit 54. The initial plate-making conditions 25 and printing conditions 27 (initial values) corresponding to the target value P are determined.

[Determination Processing of Plate Making Condition 25 and Printing Condition 27]
Hereinafter, an example of determination processing of the plate making condition 25 and the printing condition 27 by the condition determining unit 55 will be described.

The condition determination unit 55 uses a known optimization algorithm (genetic algorithm, simulated annealing, etc.) to determine the initial plate-making condition 25 and the printing condition 27 that give the target value P from the above prediction formulas (y1 =... y2 =..., y3 =. Here, in order to use the optimization method, the target value P is reduced to one variable by an appropriate evaluation formula. As this evaluation formula, for example,
E = (t1-t1x) ² + (t2-t2x) ² + (t3-t3x) ² +.
Is used. Here, t1, t2, t3,... Are target values P of individual items of the image quality characteristic data 98 and the color characteristic data 99, t1x, t2x, t3x,... Are evaluation targets, and E is an evaluation value. (In this example, it corresponds to an error). Note that “drop into one variable” means that when there are multiple optimization targets (for example, t1, t2, t3,...), One evaluation formula is optimal, and multiple optimization targets are optimal. It is to use an optimization technique that expresses as follows.

  Hereinafter, a case where a genetic algorithm is used as the optimization algorithm will be described as an example.

  As described above, the target values P of the image quality characteristic data 98 and the color characteristic data 99 are t1, t2, t3..., And a predetermined number of candidate groups of the plate making conditions 25 and the printing conditions 27 are s1k, s2k, s3k. (K corresponds to the number of candidates). Further, candidates corresponding to mutations are designated as s1m, s2m, s3m (m is equivalent to the number of candidates), and partial change, exchange, averaging, etc. of candidate groups, which are processes corresponding to inheritance, are performed. Processing is performed, and each evaluation value is calculated, and a predetermined number in the order in which the evaluation values are excellent is updated as a new candidate group (iteration processing).

  The end condition ends when the evaluation value satisfies a preset condition (error is within an allowable range), and in this case, candidates corresponding to the end condition are output as optimum values (initial plate-making condition 25 and printing condition 27). . If the condition is not satisfied, the iteration process is executed again. The iteration process sets an upper limit number of times, and ends when the upper limit number is reached. In that case, the best candidate at that time is the optimum value (initial plate-making condition 25 and printing condition 27).

  When simulated annealing is used as the optimization algorithm described above, a plurality of candidate groups are generated by adding a predetermined number of random numbers to the candidates (s1, s2, s3,...), And the respective evaluation values are calculated. Then, the one with the best evaluation value is selected as the next candidate.

(Iteration processing)
Control is performed so that the random number of the iteration process has a large absolute value at the start of calculation, and the absolute value of the random number decreases as the number of iteration processes increases. The end condition ends when the evaluation value satisfies a preset condition (error is equal to or less than an allowable range), and in that case, a candidate corresponding to the condition is output as an optimum value. If the condition is not satisfied, the iteration process is executed again. The iteration process sets an upper limit number of times, and ends when the upper limit number is reached.

  In this way, the condition determination unit 55 can determine the initial plate-making condition 25 and the printing condition 27 (initial value) corresponding to the target value P by calculation using the flexographic printing characteristic model 92. Then, the condition determining unit 55 outputs the determined initial plate making conditions 25 and printing conditions 27 to the flexographic plate making apparatus 20 and the flexographic printing apparatus 30, respectively. As a result, the initial plate-making conditions 25 and printing conditions 27 are set in the flexographic plate-making apparatus 20 and the flexographic printing apparatus 30, respectively.

  The condition correction unit 56 functions as a characteristic data acquisition unit, a correction determination unit, and a condition correction unit of the present invention. The condition correction unit 56 first acquires the first characteristic data 42 (image quality characteristic data 98S and color characteristic data 99S) from the measuring device 40. The first characteristic data 42 is data obtained by measuring the document image 16 obtained based on the initial plate making conditions 25 and the printing conditions 27 with the measuring device 40.

  Next, the condition correction unit 56 includes the first characteristic data 42 (image quality characteristic data 98S and color characteristic data 99S) obtained from the measuring device 40, and the target value P (image quality characteristic) input from the target value setting unit 54 described above. In comparison with the data 98S and the color characteristic data 99S), it is determined whether or not to correct the initial plate-making condition 25 and the printing condition 27 based on the comparison result.

  Specifically, the condition correction unit 56 includes first characteristic data 42 (image quality characteristic data 98S and color characteristic data 99S) that are actual measurement values obtained from the measuring device 40, and a target value P (image quality characteristic data 98S and color characteristics). An error (difference) from the data 99S) is obtained, and it is determined whether or not the error exceeds a predetermined allowable range. If the condition correcting unit 56 determines that the error exceeds the allowable range, the condition correcting unit 56 determines to correct at least one of the initial plate making condition 25 and the printing condition 27, and the correction value 100 (“target” A value obtained by adding “value P—actual value” (see FIG. 17) to the target value P is referred to as “corrected target value P”.

  Next, the condition correction unit 56 refers to the flexographic printing characteristic model 92 based on the “corrected target value P” corresponding to the comparison result described above, and determines the plate making condition 25 and the printing condition 27 described above. Calculation is performed to determine at least one of a modified plate-making condition 25a in which the initial plate-making condition 25 is modified and a modified printing condition 27a in which the initial printing condition 27 is modified. Then, when the initial plate making condition 25 is corrected, the condition correcting unit 56 outputs the corrected plate making condition 25 a after correction to the flexographic plate making apparatus 20. In addition, when correcting the initial printing condition 27, the condition correcting unit 56 outputs the corrected printing condition 27a after correction to the flexographic printing apparatus 30.

  The flexographic plate making apparatus 20 performs the plate making of the flexographic printing plate 12 based on the corrected plate making conditions 25 a input from the condition correcting unit 56. Further, the flexographic printing apparatus 30 prints the printed matter 14 (original image 16) based on the corrected printing condition 27a input from the condition correcting unit 56.

  Such correction of the plate making condition 25 and the printing condition 27 is performed when a new document image 16 is printed, when a document image 16 to be printed is changed, or when a periodic inspection (periodic maintenance) of the printing system 10 is performed. It is implemented at appropriate timing.

[Operation of printing system]
Next, the operation of the printing system 10 configured as described above, particularly the correction of the plate making conditions 25 and the printing conditions 27 will be described. First, generation processing of the flexographic printing characteristic model 92 necessary for correcting the plate making conditions 25 and the printing conditions 27 in the printing system 10 will be described.

<Generation processing of flexographic printing characteristic model>
FIG. 15 is a flowchart showing a flow of processing for generating the flexographic printing characteristic model 92 by the model construction system 90. As shown in FIG. 15, first, image data of an analysis chart 95 (see FIG. 9) is input to the flexographic plate making apparatus 20A (step S1).

  When the plate making start operation is performed after the input of the image data of the analysis chart 95, the flexographic plate making apparatus 20A applies the relief 19 corresponding to the analysis chart 95 to the flexographic plate material F under a predetermined plate making condition 25 based on the image data. To form. Thereby, the flexographic printing plate 12A corresponding to the analysis chart 95 is made (step S2). The flexographic printing plate 12A is set on the plate cylinder 34 (see FIG. 7) of the flexographic printing apparatus 30A.

  At this time, the model construction unit 93 acquires the plate making conditions 25 when the flexographic printing plate 12A is made from the flexographic plate making apparatus 20A (step S3). In FIG. 15, the plate making conditions 25 are acquired by the model construction unit 93 after plate making of the flexographic printing plate 12A. However, the timing of obtaining the plate making conditions 25 is not particularly limited. It may be before plate making or during plate making.

  When the printing start operation is performed after the flexographic printing plate 12A is set on the plate cylinder 34, the flexographic printing apparatus 30A prints the analysis chart 95 on the printing medium 13 by the flexographic printing plate 12A under a predetermined printing condition 27. The printed material 14A is generated (step S4). This printed material 14A is set in the measuring device 40A.

  At this time, the model construction unit 93 acquires the printing condition 27 when the analysis chart 95 is printed from the flexographic printing apparatus 30A (step S5). In FIG. 15, the print condition 27 is acquired by the model construction unit 93 after the analysis chart 95 is printed. However, the timing for acquiring the print condition 27 is not particularly limited, and for example, before the analysis chart 95 is printed. Or during printing.

  When the measurement start operation is performed after setting the printed material 14A on the measuring device 40A, the measuring device 40A reads the analysis chart 95 printed on the printed material 14A, measures the characteristics of the analysis chart 95, and determines the second characteristic data. 97 is obtained (step S6). The measuring device 40A outputs the second characteristic data 97 to the model construction unit 93.

  Hereinafter, while changing at least one of the plate-making conditions 25 and the printing conditions 27, acquisition of the plate-making and plate-making conditions 25 of the flexographic printing plate 12A, printing of the analysis chart 95 and acquisition of the printing conditions 27, measurement of the analysis chart 95, and The acquisition of the two characteristic data 97 is repeatedly executed (YES in any of steps S7 and S8, step S2 to step S6). The acquisition of the plate making condition 25 and the printing condition 27 may be performed only when the condition is changed.

  When the acquisition of the second characteristic data 97 under all the predetermined plate making conditions 25 and printing conditions 27 is completed (NO in both steps S7 and S8), the model construction unit 93 makes a plurality of plate making conditions 25 and printing conditions 27. And the second characteristic data 97 for each condition are modeled by the above-described known modeling method. As a result, a flexographic printing characteristic model 92 indicating the correspondence between the plate making conditions 25 and the printing conditions 27 and the second characteristic data 97 (image quality characteristic data 98 and color characteristic data 99) is generated (step S9).

  Thus, the flexographic printing characteristic model 92 generation process by the model construction system 90 is completed.

<Correction of plate making conditions and printing conditions>
FIG. 16 is a flowchart showing the flow of correction processing (corresponding to the management method of the present invention) of the plate making conditions 25 and the printing conditions 27 in the printing system 10. FIG. 17 is an explanatory diagram for explaining correction processing of the plate making conditions 25 and the printing conditions 27.

  As shown in FIGS. 16 and 17, in the printing system 10, the model acquisition unit 52 executes the acquisition of the flexographic printing characteristic model 92 generated in advance by the model construction system 90 described above. Thereby, the flexographic printing characteristic model 92 acquired by the model acquisition unit 52 is stored in the storage unit 53 (step S11, corresponding to the storage step).

  At the timing of obtaining the optimum plate making conditions 25 and printing conditions 27 for the original image 16 to be printed, such as when printing a new original image 16 or changing the original image 16 to be printed (YES in step S12), First, image data of the document image 16 is input to the measuring device 40.

  When the image data of the document image 16 is input to the measurement device 40, the evaluation area detection unit 45 is activated. Based on the image data of the document image 16, the evaluation region detection unit 45 performs a plurality (one or more) of evaluation regions from the document image 16 by the method described with reference to FIGS. 18 is detected (see FIG. 13, step S13). The detection result of the evaluation area 18 is stored in a memory or the like of the measuring device 40.

  After the evaluation area 18 is detected, the operator determines a target value of an evaluation item corresponding to each evaluation area 18 detected by the evaluation area detection unit 45, and performs a target value setting operation using an operation unit (not shown). In response to this target value setting operation, the target value setting unit 54 sets the target value of the first characteristic data 42 (image quality characteristic data 98S and color characteristic data 99S) as indicated by the parenthesized number (1) in FIG. P is set, and this target value P is output to the condition determining unit 55 and the condition correcting unit 56, respectively (step S14, target value setting step).

  The condition determining unit 55 refers to the flexographic printing characteristic model 92 in the storage unit 53 based on the target value P input from the target value setting unit 54. Then, the condition determination unit 55 performs the above-described calculation using the flexographic printing characteristic model 92, and the initial value corresponding to the target value P as shown in parenthesized numbers (2) and (3) in FIG. Plate making condition 25 and printing condition 27 (initial value) are determined (step S15, condition determining step). These initial plate making conditions 25 and printing conditions 27 are set in the flexographic plate making apparatus 20 and the flexographic printing apparatus 30, respectively.

  After the initial plate making conditions 25 and printing conditions 27 are set, the image data of the original image 16 is input to the flexographic plate making apparatus 20 (step S16).

  When a plate making start operation is performed after the image data of the original image 16 is input, the flexographic plate making apparatus 20 forms a relief 19 corresponding to the original image 16 on the flexographic plate material F under the initial plate making conditions 25 based on the image data. To do. Thereby, the flexographic printing plate 12 corresponding to the document image 16 is made (step S17). The flexographic printing plate 12 is set on the plate cylinder 34 (see FIG. 7) of the flexographic printing apparatus 30.

  When a printing start operation is performed after the flexographic printing plate 12 is set on the plate cylinder 34, the flexographic printing apparatus 30 prints the original image 16 on the printing medium 13 by the flexographic printing plate 12 under the initial printing conditions 27. The printed matter 14 is generated (step S18). This printed matter 14 is set in the measuring device 40.

  When a measurement start operation is performed after setting the printed material 14 on the measuring device 40, the measuring device 40 causes the original image 16 printed on the printed material 14 to be based on the detection result of each evaluation area 18 previously stored in the memory. The position of each evaluation area 18 is determined. Next, the measuring device 40 measures the evaluation items (see FIG. 13) that can be evaluated in each area for each evaluation area 18 in the document image 16 printed on the printed material 14. As a result, first characteristic data 42 (image quality characteristic data 98S and color characteristic data 99S) indicating the characteristics of the document image 16 is obtained (step S19).

  The first characteristic data 42 measured by the measuring device 40 is output from the measuring device 40 to the condition correcting unit 56 as indicated by the parenthesized number (4) in FIG. Thereby, the condition correction part 56 acquires the 1st characteristic data 42 from the measuring apparatus 40 (equivalent to the characteristic data acquisition step of this invention).

  Next, the condition correction unit 56 includes first characteristic data 42 (image quality characteristic data 98S and color characteristic data 99S) that are actual measurement values obtained from the measuring device 40, and a target value P (image quality characteristic data 98S and color characteristic data 99S). ) (Step S20). Then, the condition correction unit 56 determines whether or not to correct at least one of the initial plate making condition 25 and the printing condition 27 based on the result of determining whether or not the error exceeds a predetermined allowable range. Determine (step S21, corresponding to the correction determination step of the present invention). If the condition correction unit 56 determines that the error is within the allowable range, the initial plate making condition 25 and the printing condition 27 are not corrected (NO in step S21).

  On the other hand, when the condition correcting unit 56 determines that the above-described error exceeds the allowable range, that is, when it is determined to correct at least one of the initial plate-making condition 25 and the printing condition 27 (step YES in S21), the above-described correction value 100 is obtained as indicated by the parenthesized number (5) in FIG. Then, the condition correction unit 56 sets a value obtained by adding the correction value 100 to the target value P as a “corrected target value P”. Next, the condition correction unit 56 performs the above-described calculation with reference to the flexographic printing characteristic model 92 based on the “corrected target value P”. As a result, as shown by the parenthesized number (6) in FIG. 17, at least one of the initial plate-making conditions 25 and the printing conditions 27 (both corrections are performed in the present embodiment) is corrected plate-making conditions 25a. And the corrected printing condition 27a is determined (step S22, condition correcting step).

  The modified plate making conditions 25a and the modified printing conditions 27a determined by the condition modifying unit 56 are set in the flexographic plate making apparatus 20 and the flexographic printing apparatus 30, respectively, as shown in parenthesized numerals (7) and (8) in FIG. (Step S23).

  Thus, the correction process of the plate making condition 25 and the printing condition 27 in the printing system 10 is completed. Note that the processing from step S14 to step S23 may be repeatedly executed a plurality of times while changing the target value P (at least one of the image quality characteristic data 98S and the color characteristic data 99S).

  When the original image 16 is printed after the correction processing of the plate making conditions 25 and the printing conditions 27, the flexographic plate making apparatus 20 performs the plate making of the flexographic printing plate 12 under the corrected plate making conditions 25a based on the image data of the original image 16. . Then, the flexographic printing apparatus 30 prints the original image 16 using the flexographic printing plate 12 of the original image 16 under the corrected printing condition 27a (step S24).

  Thereafter, when printing a new document image 16 or when changing the document image 16 to be printed, the above-described processes (step S12 to step S23) are repeatedly executed, and a new modified plate making condition 25a and modified printing are performed. The document image 16 can be printed based on the condition 27a.

[Effect of this embodiment]
As described above, in the printing system 10 according to the present embodiment, it is possible to determine whether or not to correct the plate making condition 25 and the printing condition 27 with reference to the flexographic printing characteristic model 92 generated in advance. Compared to the case where correction is performed based on the experience of the operator without referring to the model 92, plate making conditions and printing conditions for obtaining a high-quality printed material in flexographic printing (corrected plate making conditions 25a, corrected printing conditions 27a) Can be easily grasped. Further, since the plate making conditions 25 and the printing conditions 27 are corrected based on the first characteristic data 42 detected from the evaluation area 18 of the original image 16, the plate making conditions 25 and the printing conditions 27 suitable for the original image 16 to be printed are grasped. be able to. Thereby, the high-quality printed matter 14 is obtained in flexographic printing.

  Furthermore, since the printing system 10 can correct not only the printing conditions as described in the above prior art document but also the plate making conditions, it is possible to achieve both the image structure and color reproduction of the printed matter in flexographic printing. And a high-quality printed matter 14 is obtained.

[Print System of Another Embodiment]
In the above embodiment, it is determined whether or not to correct the plate making condition 25 and the printing condition 27 based on the first characteristic data 42 detected from the evaluation area 18 of one document image 16. At this time, since the original image 16 is an image that the customer desires to print, the evaluation items (necessary for evaluating the print reproduction such as the image structure and color reproduction of the printed matter 14 in one original image 16). Hereinafter, the evaluation area 18 including the main evaluation items) does not always exist. Therefore, in the printing system of another embodiment, the first characteristic data 42 detected from the evaluation area 18 of the plurality of document images 16 is stored, and the first characteristic data 42 corresponding to all the preset evaluation items is stored. If it is obtained, it is determined whether or not the plate making condition 25 and the printing condition 27 are to be corrected.

  FIG. 18 is a functional block diagram of the management apparatus 120 configuring the printing system according to another embodiment. Note that the printing system of another embodiment is basically the same as the printing system 10 of the above embodiment, except that the configuration of the management apparatus 120 is partially different from the configuration of the management apparatus 50 of the above embodiment. For this reason, the same reference numerals are given to the same functions and configurations as those of the above-described embodiment, and the description thereof is omitted.

  The management device 120 includes a target value setting unit 122, a condition determination unit 123, and a condition correction unit 124, in addition to the model acquisition unit 52 and the storage unit 53 similar to the management device 50 of the above embodiment. Yes.

  The target value setting unit 122 sets the target value P1 of the first characteristic data 42 corresponding to, for example, main evaluation items or evaluation items according to customer demands among the evaluation items shown in FIG. That is, the target value setting unit 122 is not the evaluation item included in the evaluation region 18 detected in advance by the evaluation region detection unit 45 as in the above embodiment, but the first characteristic corresponding to the evaluation item predetermined on the customer side. A target value P1 of data 42 is set. The setting of the target value P1 is performed according to the content of the target value setting operation input to the operation unit (not shown) by the customer operator, similarly to the setting of the target value P1 in the above embodiment.

  The condition determining unit 123 refers to the flexographic printing characteristic model 92 based on the target value P1 input from the target value setting unit 122, and determines the initial plate making condition 25 and the printing condition 27 corresponding to the target value P1, respectively. . Then, the condition determining unit 123 outputs the determined plate making condition 25 to the flexographic plate making apparatus 20 and outputs the determined printing condition 27 to the flexographic printing apparatus 30. Note that the specific method for determining the initial plate-making conditions 25 and the printing conditions 27 corresponding to the target value P1 is the same as that in the above-described embodiment, and a specific description thereof will be omitted here.

  In the flexographic plate making apparatus 20 of another embodiment, image data of a plurality of types of document images 16 are input at arbitrary timings. The flexographic plate making apparatus 20 is set with the initial plate making conditions 25 determined by the condition determining unit 123 before the image data of the document image 16 is input. The flexographic plate making apparatus 20 forms the flexographic printing plate 12 with the above-described initial plate making conditions 25 for each of image data of a plurality of types of document images 16. In the figure, as a plurality of types of document images 16, three types of document images 16 including a document image 16 (1), a document image 16 (2), and a document image 16 (3) will be described as an example. However, the number of types of document images 16 is not particularly limited.

  In the flexographic printing apparatus 30 of another embodiment, the flexographic printing plates 12 for each of a plurality of types of document images 16 formed by the flexographic plate making apparatus 20 are set at arbitrary timings. The flexographic plate making apparatus 20 is set with the initial printing conditions 27 determined by the condition determining unit 123 before the flexographic printing plate 12 is set. The flexographic printing apparatus 30 uses the flexographic printing plate 12 for each of a plurality of types of document images 16 to print a plurality of types of document images 16 on the printing medium 13 under the above-described initial printing conditions 27, so that the plurality of types of document images 16 are printed. The printed matter 14 of the original image 16 is generated.

  For example, when the flexographic printing plate 12 corresponding to the original image 16 (1) is set, the flexographic printing apparatus 30 generates the printed matter 14 (1) of the original image 16 (1) under the above-described initial printing conditions 27. To do. Similarly, when the flexographic printing plate 12 corresponding to the original image 16 (2) is set, the flexographic printing apparatus 30 generates a printed matter 14 (2) of the original image 16 (2), and the original image 16 ( When the flexographic printing plate 12 corresponding to 3) is set, a printed matter 14 (3) of the original image 16 (3) is generated.

  In the measurement apparatus 40 of another embodiment, the printed matter 14 for each of a plurality of types of document images 16 generated by the flexographic printing apparatus 30 is set at an arbitrary timing. The measuring device 40 measures the characteristics of each of the plurality of types of document images 16 from each printed matter 14 to obtain first property data 42, and the condition correction unit 124 uses the first property data 42 for each of the plurality of types of document images 16. Output to.

  In addition, the image data of the plurality of types of document images 16 is input in advance to the evaluation region detection unit 45 of the measurement apparatus 40 of another embodiment before the printed matter 14 for each of the plurality of types of document images 16 is set. . As a result, the evaluation area detection unit 45 analyzes the image data of the plurality of types of document images 16 and uses the method described with reference to FIGS. From each, the evaluation area 18 is detected. The detection results of the evaluation area 18 are stored in a memory or the like of the measuring device 40.

  For example, when the printed material 14 (1) is set, the measuring device 40 evaluates the document image 16 (1) based on the detection result of the evaluation region 18 in the document image 16 (1) stored in the memory. The position of the region 18 is obtained. Next, the measuring device 40 performs measurement on the evaluation item (see FIG. 13) corresponding to the evaluation area 18 in the document image 16 (1). Thereby, the first characteristic data 42 (1) indicating the characteristics of the document image 16 (1) is obtained. Similarly, the measurement device 40 obtains first characteristic data 42 (2) indicating the characteristics of the original image 16 (2) when the printed material 14 (2) is set. Further, when the printed material 14 (3) is set, the measuring device 40 obtains first characteristic data 42 (3) indicating the characteristics of the document image 16 (3). Then, the measuring device 40 outputs the first characteristic data 42 for each of the plural types of document images 16 to the condition correction unit 124.

  FIG. 19 is an explanatory diagram for explaining correction processing of the initial plate making condition 25 and the printing condition 27 by the condition correction unit 124 according to another embodiment. As shown in FIG. 19, when the condition correction unit 124 acquires the first characteristic data 42 corresponding to all the target values P1 for each evaluation item set by the target value setting unit 122, the initial plate making condition 25 is obtained. And whether or not to correct the printing condition 27 is determined. The condition correction unit 124 includes an evaluation item information storage unit 127 and a first characteristic data storage unit 128.

  In the evaluation item information storage unit 127, information related to the evaluation item of the target value P1 set by the target value setting unit 122 is stored. For example, when the target value setting unit 122 sets the target value P1 of the first characteristic data 42 corresponding to the evaluation items of “granularity”, “banding”, “maximum density”, and “color reproduction area width”, Information regarding these evaluation items is stored in the evaluation item information storage unit 127.

  The first characteristic data storage unit 128 stores first characteristic data 42 for each of a plurality of types of document images 16 input from the measuring device 40. Here, the evaluation items included in the first characteristic data 42 (1) of the document image 16 (1) are “graininess” and “color reproduction area width”, and the first characteristic data of the document image 16 (2). The evaluation item included in 42 (2) is “banding”, and the evaluation item included in the first characteristic data 42 (3) of the document image 16 (3) is “maximum density”.

  When the first characteristic data 42 (1) is stored in the first characteristic data storage unit 128, the condition correction unit 124 stores the evaluation items included in the first characteristic data 42 (1) and the evaluation item information storage unit 127. It is determined whether or not the first characteristic data 42 corresponding to all the evaluation items in the evaluation item information storage unit 127 has been acquired by comparing with the stored evaluation items. Here, since the first characteristic data 42 corresponding to the evaluation items of “banding” and “maximum density” has not been acquired, the condition correction unit 124 determines whether or not to correct the initial plate making condition 25 and the printing condition 27. No decision is made.

  Next, the condition correction unit 124, when the first characteristic data 42 (2) is stored in the first characteristic data storage unit 128, the evaluation items included in the first characteristic data 42 (1) and 42 (2), The evaluation item stored in the evaluation item information storage unit 127 is compared to determine whether or not the first characteristic data 42 corresponding to all of the evaluation items in the evaluation item information storage unit 127 has been acquired. Since the first characteristic data 42 corresponding to the evaluation item “maximum density” has not yet been acquired, the condition correction unit 124 determines whether or not the initial plate-making condition 25 and the printing condition 27 are to be corrected. Absent.

  When the first characteristic data 42 (3) is stored in the first characteristic data storage unit 128, the condition correction unit 124 is included in the first characteristic data 42 (1), 42 (2), 42 (3). Whether or not the first characteristic data 42 corresponding to all of the evaluation items in the evaluation item information storage unit 127 is acquired by comparing the evaluation items to be evaluated with the evaluation items stored in the evaluation item information storage unit 127 Determine. The first characteristic data 42 corresponding to all of the evaluation items in the evaluation item information storage unit 127, that is, the first characteristic data 42 corresponding to all of the target values P1 for each evaluation item set by the target value setting unit 122. Is acquired, the condition correction unit 124 determines whether or not to correct the initial plate-making conditions 25 and the printing conditions 27.

  The condition correction unit 124 detects an error between the first characteristic data 42 [first characteristic data 42 (1), 42 (2), 42 (3)], which is an actual measurement value obtained from the measuring device 40, and the target value P1. (Difference) is obtained, and it is determined whether or not the error exceeds a predetermined allowable range.

  Next, when the condition correction unit 124 determines that the error exceeds the allowable range, the condition correction unit 124 determines to correct at least one of the initial plate-making condition 25 and the printing condition 27, and the correction value 100 (here, A value obtained by adding “target value P1—actually measured value”) to target value P1 is referred to as “corrected target value P1”. Then, the condition correcting unit 124 refers to the flexographic printing characteristic model 92 based on the “corrected target value P1”, and corrects the corrected plate making conditions 25a and the initial printing conditions 27 that have corrected the initial plate making conditions 25. At least one of the printing conditions 27a is determined. Since the subsequent processing is the same as that in the above embodiment, a specific description is omitted.

[Operation of Printing System of Another Embodiment]
Next, the operation of the printing system according to another embodiment having the above-described configuration, in particular, the correction of the plate making conditions 25 and the printing conditions 27 will be described with reference to FIG. FIG. 20 is a flowchart showing the flow of correction processing (corresponding to the management method of the present invention) of the plate making conditions 25 and the printing conditions 27 in the printing system of another embodiment.

  As shown in FIG. 20, the processing from step S11 to step S12 is the same as that in the above-described embodiment, and a specific description is omitted here. When obtaining the optimum plate-making conditions 25 and printing conditions 27 for the document image 16 (YES in step S12), the customer operator selects the main evaluation items and customer requests among the evaluation items shown in FIG. The target value P1 of the first characteristic data 42 corresponding to the evaluation item corresponding to is determined.

  Next, the operator performs a target value setting operation using an operation unit (not shown). In response to this target value setting operation, the target value P1 of the first characteristic data 42 is set, and this target value P1 is output to the condition determining unit 123 and the condition correcting unit 124, respectively (step S14A, target value of the present invention) Equivalent to setting step). The condition correction unit 124 causes the evaluation item information storage unit 127 to store information related to the evaluation item of the target value P1.

  The condition determining unit 123 refers to the flexographic printing characteristic model 92 in the storage unit 53 based on the target value P1 input from the target value setting unit 54, and sets the initial plate making conditions 25 and printing conditions corresponding to the target value P1. 27 (initial value) is determined (step S15A, corresponding to the condition determining step of the present invention). The initial plate making conditions 25 are set in the flexographic plate making apparatus 20, and the initial printing conditions 27 are set in the flexographic printing apparatus 30.

  After the initial plate making conditions 25 and printing conditions 27 are set, the image data of the original image 16 (1) is input to the flexographic plate making apparatus 20 (step S16A). Further, the image data of the document image 16 (1) is input to the evaluation area detection unit 45 of the measuring device 40. Based on the image data of the document image 16 (1), the evaluation region detection unit 45 extracts the evaluation region 18 from the document image 16 (1) by the method described with reference to FIGS. 14A to 14E. To detect. The detection result of the evaluation area 18 is stored in a memory or the like of the measuring device 40.

  When the plate making start operation is performed after the image data of the original image 16 (1) is input, the flexographic plate making apparatus 20 performs flexo printing corresponding to the original image 16 (1) under the initial plate making conditions 25 as in the above embodiment. The plate 12 is made (step S17A). Next, the flexographic printing apparatus 30 prints the original image 16 (1) on the printing medium 13 using the flexographic printing plate 12 under the initial printing condition 27 to generate the printed matter 14 (1) (step S18A). This printed matter 14 (1) is set in the measuring device 40.

  When a measurement start operation is performed after setting the printed material 14 (1) to the measuring device 40, the measuring device 40 prints on the printed material 14 (1) based on the detection result of the evaluation area 18 previously stored in the memory. The position of the evaluation area 18 in the original document image 16 (1) is obtained. Next, the measuring device 40 performs measurement on evaluation items (see FIG. 13) that can be evaluated in the evaluation area 18 in the document image 16 (1). Thereby, the first characteristic data 42 (1) indicating the characteristics of the document image 16 (1) is obtained (step S19A). The first characteristic data 42 (1) is input from the measuring device 40 to the condition correction unit 124 and then stored in the first characteristic data storage unit 128.

  When the first characteristic data 42 (1) is stored in the first characteristic data storage unit 128, the condition correction unit 124 stores the evaluation items included in the first characteristic data 42 (1) and the evaluation item information storage unit 127. The stored evaluation items are compared to determine whether or not the first characteristic data 42 corresponding to all the evaluation items in the evaluation item information storage unit 127 has been acquired (step S19B). If the condition correction unit 124 determines that the initial plate making condition 25 and the printing condition 27 are to be corrected when it is determined that they have not been acquired (NO in step S19B), the new first characteristic data 42 is determined. Is stored in the first characteristic data storage unit 128 (step S19C).

  Next, when image data of the document image 16 (2) is input to the flexographic plate making apparatus 20 at an arbitrary timing (step S16A), the processing from the above-described step S17A to step S19A is repeatedly executed, and the document image 16 (2 ) Is stored in the first characteristic data storage unit 128.

  When the first characteristic data 42 (2) is stored in the first characteristic data storage unit 128, the condition correction unit 124 includes an evaluation item included in the first characteristic data 42 (1) and (2), and evaluation item information. It is determined again whether or not the first characteristic data 42 corresponding to all the evaluation items in the evaluation item information storage unit 127 has been acquired by comparing with the evaluation items stored in the storage unit 127 (step S19B). . If it is determined that the condition correction unit 124 has not yet acquired, the condition correction unit 124 does not determine whether or not to correct the initial plate making condition 25 and the printing condition 27, and the new first characteristic data 42 is the first characteristic data. It waits again until it memorize | stores in the memory | storage part 128 (it is NO at step S19B, step S19C).

  Hereinafter, until the condition correction unit 124 determines that the first characteristic data 42 corresponding to all the evaluation items in the evaluation item information storage unit 127 has been acquired, the processing from the above-described step S19C and steps S16A to S19B is performed. Repeatedly executed.

  The condition correction unit 124 corresponds to the first characteristic data 42 corresponding to all the evaluation items in the evaluation item information storage unit 127, that is, all the target values P1 for each evaluation item set by the target value setting unit 122. When the first characteristic data 42 to be acquired is acquired, it is determined whether or not the initial plate making condition 25 and the printing condition 27 are to be corrected (YES in step S19B).

  The subsequent processing is basically the same as the processing from step S20 to step S24 described in the above embodiment, and a specific description is omitted here.

[Effect of another embodiment]
As described above, in the printing system according to another embodiment, when the first characteristic data 42 corresponding to all the target values P1 of the first characteristic data 42 set by the target value setting unit 122 is acquired, the plate making conditions 25 and In order to determine whether or not to correct the printing condition 27, the plate making condition 25 and the printing condition 27 are corrected based on the first characteristic data 42 including all the main evaluation items or the evaluation items according to the customer's request. It can be decided whether or not to do so. Further, the same effects as those described in the above embodiment can be obtained.

[Modification of another embodiment]
In the another embodiment, until the condition correction unit 124 acquires the first characteristic data 42 corresponding to all the evaluation items (all the target values P1) in the evaluation item information storage unit 127, the new document image 16 is supported. The storage of the first characteristic data 42 to the first characteristic data storage unit 128 is repeatedly executed. For this reason, a plurality of first characteristic data 42 corresponding to the same evaluation item may be stored in the first characteristic data storage unit 128.

  FIGS. 21A and 21B illustrate the processing of the condition correction unit 124 when a plurality of first characteristic data 42 corresponding to the same evaluation item is stored in the first characteristic data storage unit 128. It is explanatory drawing for. As shown in FIG. 21A, the condition correction unit 124 stores, for example, the first characteristic data 42 (1) and (2) including the evaluation item “maximum density” in the first characteristic data storage unit 128. In this case, a first characteristic data average value 42 (A) that is an average value of the first characteristic data 42 (1) and (2) is obtained. In this case, the condition correction unit 124 compares the evaluation items included in the first characteristic data average value 42 (A) with the evaluation items stored in the evaluation item information storage unit 127.

  As described above, when a plurality of pieces of the first characteristic data 42 corresponding to the same evaluation item are stored in the first characteristic data storage unit 128, the condition correction unit 124 is a first value that is an average value of the first characteristic data 42. The characteristic data average value 42 (A) is obtained. Then, the condition correction unit 124 uses the first characteristic data average value 42 (A) for comparison with the evaluation items stored in the evaluation item information storage unit 127. When there are a plurality of types of the same evaluation item, the first characteristic data average value 42 (A) may be obtained for each type of evaluation item. Thereby, when there are a plurality of first characteristic data 42 corresponding to the same evaluation item, it is possible to determine whether or not to correct the plate making condition 25 and the printing condition 27 based on the average value.

  Further, instead of obtaining the average value of the first characteristic data 42 corresponding to the same evaluation item, the weighted average value of the first characteristic data 42 obtained by increasing the weight of the new first characteristic data 42 in terms of time may be obtained. Good. That is, when a plurality of pieces of first characteristic data 42 corresponding to the same evaluation item are stored in the first characteristic data storage unit 128, the condition correction unit 124 increases the weighting factor for the first characteristic data 42 that is new in time. The weighted average of each first characteristic data 42 is set. Thereby, it is possible to determine whether or not to correct the plate making condition 25 and the printing condition 27 based on the weighted average value of the first characteristic data 42 in which the weight of the first characteristic data 42 that is new in time is increased.

[Others]
The evaluation area detection unit 45 (see FIG. 12) of the above embodiment analyzes the image data of the document image 16 input to the printing system 10 and detects each evaluation area 18. Each evaluation region 18 may be detected by analyzing a reading result obtained by reading the printed document image 16 by the measuring device 40. The same applies to the other embodiments described above.

  In the above embodiment, an example of the plate making condition 25 is shown in FIG. 4 and an example of the printing condition 27 is shown in FIG. 8, but the individual conditions of the plate making condition 25 and the printing condition 27 are illustrated in FIGS. It is not limited to what is mentioned, You may include other well-known conditions. 11 shows an example of the image quality characteristic data 98 and the color characteristic data 99, but the items of the image quality characteristic data 98 and the color characteristic data 99 are not limited to those illustrated in FIG. It may contain items. The same applies to the other embodiments described above.

  In the above embodiment, the flexographic printing characteristic model 92 is generated by performing modeling using a known modeling method in the model construction system 90. However, the plate making conditions 25 and the printing conditions 27 correspond to the second characteristic data 97. The method is not limited to modeling as long as the attached flexographic printing characteristic model 92 can be generated. The same applies to the other embodiments described above.

  In the above embodiment, the printing system 10 is configured by five different apparatuses, namely the flexographic plate making apparatus 20, the flexographic printing apparatus 30, the measuring apparatus 40, and the management apparatus 50, but at least two of these five different apparatuses are integrated. For example, the management device 50 may be integrated with another device. Further, the above-described evaluation area detection unit 45 (see FIG. 12) may be provided in the management device 50. The same applies to the other embodiments described above.

  In the above embodiment, the case where one management device 50 includes the model acquisition unit 52, the storage unit 53, the target value setting unit 54, the condition determination unit 55, and the condition correction unit 56 has been described. You may distribute and provide in the some management apparatus 50. FIG. The same applies to the other embodiments described above.

  In the above embodiment, one original image printed according to the initial plate making conditions and printing conditions is measured, and the first plate making conditions and printing conditions are determined using the first characteristic data and the target value obtained by this measurement. It is determined whether or not to make corrections, and each condition is corrected. In contrast to this, for example, a plurality of original images (identical or non-identical original images) are printed according to initial plate making conditions and printing conditions, and a plurality of first characteristic data and targets obtained by measuring each printed matter, respectively. The values may be comprehensively determined to determine whether or not to correct the initial plate-making conditions and printing conditions, and to correct each condition. The same applies to the other embodiments described above.

  Furthermore, it goes without saying that the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.

  DESCRIPTION OF SYMBOLS 10 ... Printing system, 12 ... Flexographic printing plate, 12A ... Flexographic printing plate, 14 ... Printed matter, 14A ... Printed matter, 16 ... Original image, 20 ... Flexographic plate making apparatus, 20A ... Flexographic plate making apparatus, 25 ... Plate making conditions, 27 ... Printing Conditions: 30 ... Flexographic printing device, 30A ... Flexographic printing device, 40 ... Measuring device, 40A ... Measuring device, 42 ... First characteristic data, 45 ... Evaluation area detection unit, 50 ... Management device, 52 ... Model acquisition unit, 53 DESCRIPTION OF SYMBOLS ... Memory | storage part, 55 ... Condition determination part, 56 ... Condition correction part, 90 ... Model construction system, 93 ... Model construction part, 95 ... Analysis chart, 97 ... 2nd characteristic data, 120 ... Management apparatus, 122 ... Target value setting Part, 123 ... condition determining part, 124 ... condition correcting part

Claims (17)

A plate making section for making a flexographic printing plate based on an original image;
A printing unit that prints the original image on a printing medium using the flexographic printing plate;
An evaluation area detecting unit that detects an evaluation area that can evaluate at least one of the items evaluated in the evaluation image for image characteristic evaluation from the document image;
A measurement unit that reads the document image printed on the print medium by the printing unit, measures the characteristics of the document image from the evaluation region detected by the evaluation region detection unit, and obtains first characteristic data;
Correspondence relationship between the second characteristic data obtained by measuring the characteristics of the evaluation image in advance, and the plate making conditions and printing conditions of the flexographic printing plate when the evaluation image of the measurement source of the second characteristic data is printed A storage unit storing a flexographic printing characteristic model indicating
A target value setting unit for setting a target value of the first characteristic data;
Based on the target value of the first characteristic data set by the target value setting unit, referring to the flexographic printing characteristic model stored in the storage unit, the plate making conditions and the printing corresponding to the target value A condition determining unit for determining a condition;
The first characteristic data of the original image obtained through the plate making of the plate making unit and the printing of the printing unit based on the plate making conditions and the printing conditions determined by the condition determining unit from the measurement unit. A characteristic data acquisition unit to acquire;
A correction determination for determining whether to correct at least one of the plate making conditions and the printing conditions based on a comparison result between the first characteristic data acquired by the characteristic data acquisition unit and the target value. And
A printing system comprising: The target value setting unit sets the target value of the first characteristic data corresponding to the predetermined item,
The correction determination unit includes a first characteristic data storage unit that stores the first characteristic data respectively acquired from the plurality of types of document images by the characteristic data acquisition unit, and is set by the target value setting unit When the first characteristic data corresponding to all of the target values is stored in the first characteristic data storage unit, the comparison result between the first characteristic data in the first characteristic data storage unit and the target value The printing system according to claim 1, wherein it is determined whether to correct at least one of the plate making conditions and the printing conditions based on the conditions.   When a plurality of pieces of the first characteristic data corresponding to the same item are stored in the first characteristic data storage unit, the correction determination unit is configured to calculate an average value of the plurality of first characteristic data, or 3. The method according to claim 2, wherein whether or not to correct at least one of the plate making conditions and the printing conditions is determined based on a comparison result between the weighted average value obtained by increasing the weight of the first characteristic data and the target value. Printing system.   A condition correction unit that corrects at least one of the plate making conditions and the printing conditions based on the comparison result when the correction determining unit decides to correct at least one of the plate making conditions and the printing conditions. A printing system according to any one of claims 1 to 3.   The plate making unit makes the flexographic printing plate based on the corrected plate making conditions when the plate making conditions are corrected, and the printing unit performs correction after the printing conditions are corrected. The printing system according to claim 4, wherein printing is performed based on the printing conditions.   The said condition correction part correct | amends at least one of the said platemaking conditions and the said printing conditions based on the difference of the said target value and the said 1st characteristic data obtained by the said measurement part. Printing system.   The plate making unit and the printing unit of the same model as the plate making unit and the printing unit print the evaluation image on the printing medium for each of the plate making conditions and the printing conditions, and the measuring unit of the same model as the measuring unit. Measuring the characteristic of the evaluation image for each of the conditions to obtain the second characteristic data, and the flexographic printing characteristic model generated by the flexographic printing characteristic model construction unit based on the second characteristic data for each of the conditions, The printing system according to claim 1, wherein the storage unit stores the information.   The printing system according to claim 7, further comprising a model acquisition unit that acquires the flexographic printing characteristic model generated by the flexographic printing characteristic model construction unit and stores the acquired flexographic printing characteristic model in the storage unit.   The printing system according to claim 1, wherein the evaluation area detection unit detects the evaluation area by analyzing image data of the document image.   The printing system according to claim 1, wherein the evaluation area detection unit detects the evaluation area by analyzing a reading result of the original image read by the measurement unit.   The printing system according to any one of claims 1 to 10, wherein the first characteristic data and the second characteristic data include image quality characteristic data indicating image quality characteristics and color characteristic data indicating color characteristics. In a management device that manages plate making conditions of a plate making unit that makes a flexographic printing plate based on a document image and printing conditions of a printing unit that prints the document image on a printing medium using the flexographic printing plate,
A target value of first characteristic data indicating the characteristics of the evaluation area that can evaluate at least one of the evaluation areas included in the document image and evaluated in the evaluation image for image characteristic evaluation is set. A target value setting unit;
Correspondence relationship between the second characteristic data obtained by measuring the characteristics of the evaluation image in advance, and the plate making conditions and printing conditions of the flexographic printing plate when the evaluation image of the measurement source of the second characteristic data is printed A storage unit storing a flexographic printing characteristic model indicating
Based on the target value of the first characteristic data set by the target value setting unit, referring to the flexographic printing characteristic model stored in the storage unit, the plate making conditions and the printing corresponding to the target value A condition determining unit for determining a condition;
Characteristic data acquisition for acquiring the first characteristic data of the original image obtained through plate making of the plate making unit and printing of the printing unit based on the plate making conditions and the printing conditions determined by the condition determining unit And
A correction determining unit that determines whether or not to correct at least one of the plate making conditions and the printing conditions based on a comparison result between the first characteristic data acquired by the characteristic data acquiring unit and the target value. When,
A management device comprising: The target value setting unit sets the target value of the first characteristic data corresponding to the predetermined item,
The correction determination unit includes a first characteristic data storage unit that stores the first characteristic data respectively acquired from the plurality of types of document images by the characteristic data acquisition unit, and is set by the target value setting unit When the first characteristic data corresponding to all of the target values is stored in the first characteristic data storage unit, the comparison result between the first characteristic data in the first characteristic data storage unit and the target value 13. The management apparatus according to claim 12, wherein it is determined whether to correct at least one of the plate making conditions and the printing conditions based on the conditions.   A condition correction unit that corrects at least one of the plate making conditions and the printing conditions based on the comparison result when the correction determining unit decides to correct at least one of the plate making conditions and the printing conditions. The management apparatus according to claim 12 or 13, comprising: In a management method for managing a plate making condition of a plate making unit for making a flexographic printing plate based on a document image and a printing condition of a printing unit for printing the document image on a printing medium using the flexographic printing plate,
A target value of first characteristic data indicating the characteristics of the evaluation area that can evaluate at least one of the evaluation areas included in the document image and evaluated in the evaluation image for image characteristic evaluation is set. A target value setting step;
Correspondence relationship between the second characteristic data obtained by measuring the characteristics of the evaluation image in advance, and the plate making conditions and printing conditions of the flexographic printing plate when the evaluation image of the measurement source of the second characteristic data is printed A storage step of storing a flexographic printing characteristic model indicating
Based on the target value of the first characteristic data set in the target value setting step, referring to the flexographic printing characteristic model stored in the storage unit, the plate making conditions and the printing corresponding to the target value A condition determination step for determining a condition;
Characteristic data acquisition for acquiring the first characteristic data of the original image obtained through plate making of the plate making unit and printing of the printing unit based on the plate making conditions and the printing conditions determined in the condition determining step Steps,
A correction determining step for determining whether to correct at least one of the plate making conditions and the printing conditions based on a comparison result between the first characteristic data acquired in the characteristic data acquiring step and the target value; ,
Management method. In the target value setting step, the target value of the first characteristic data corresponding to the predetermined item is set,
In the correction determination step, the first characteristic data acquired from the plurality of types of document images in the characteristic data acquisition step is stored in a first characteristic data storage unit, and the target set in the target value setting step is stored. When the first characteristic data corresponding to all of the values is stored in the first characteristic data storage unit, based on a comparison result between the first characteristic data in the first characteristic data storage unit and the target value, The management method according to claim 15, wherein it is determined whether to correct at least one of the plate making conditions and the printing conditions.   Condition correction for correcting at least one of the plate making conditions and the printing conditions based on the comparison result when it is decided to modify at least one of the plate making conditions and the printing conditions in the correction determining step. The management method according to claim 15 or 16, further comprising steps.