JP2004205844A - System of creating color proof and creation method for color proof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system of creating a color proof and a creation method for a color proof by which a color proof having sufficient approximation of colors is created by adjusting the density of a solid color in accordance with differences in the output conditions such as the lot of a photosensitive material, the state of a developer solution, the output environmental temperature or the like, and by which difference in the density of a solid color in a finish print can be prevented. <P>SOLUTION: The solid density of each color (C, M, Y) in a color chart outputted from an output device responding to the finish print is measured with a densitometer, and the obtained densities (Dc, Dm, Dy) are inputted by a first setting means. A combination of measured values (R, G, B) most approximate to the above densities (Dc, Dm, Dy) is extracted and the corresponding light quantity is calculated by a light quantity arithmetic processing means 13a by referring to a preliminarily determined measurement table 17a. A color channel color correction LUT (color channel table) 17b is created by a controlling part 19 based on the calculated light quantity. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
According to the present invention, a color proof is created by exposing a photosensitive material with a plurality of light sources having different wavelengths based on halftone image data processed in a raster image processor (RIP) or an image processing apparatus. The present invention relates to a proof creation system and a color proof creation method.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, when producing a color print, color calibration is performed at the stage of a document film. In such a case, for example, a proof (color proof) is prepared by using each color separation screen original film separated into Y (yellow), M (magenta), C (cyan) and BK (black) plates. Before making a production printing plate, make sure that the layout of the original film is correct, that there are no color errors, that there are no errors in the characters, etc., and that the printed matter is checked in advance. I have to.
[0003]
By the way, such a color proof is often produced by a DDCP (Direct Digital Color Proof) method. As one of the methods, for example, a photosensitive material is prepared based on halftone image data of each color separation halftone document. , R, G, B, etc., by exposing a light spot composed of a combination of a plurality of light beams having different wavelengths, to form the Y, M, C, and BK dots.
[0004]
On the other hand, with the spread of DTP (Desk Top Publishing) and the like, the work of image editing and page imposition of images input from a scanner on computer software has become common, and full digital editing is not uncommon. Is coming.
[0005]
In such a process, in order to further improve efficiency, an image setter output for directly outputting image data after page editing on a film, a CTP (Computer To Plate) output for directly recording an image on a printing plate, and a printing method (Computer) that records images directly on the printing plate wound on the cylinder of the machine
To Cylinder).
[0006]
However, in such a case, outputting the film or the printing plate only once for the purpose of confirming the proof, and performing print proofing or proofreading with other proofing materials is a waste or unnecessary work of the film and printing plate. The problem that the number increases.
[0007]
Therefore, in particular, in a process of creating and editing a full digital image by such a computer, a system for directly outputting a color image called DDCP or DCP (Digital Color Proof) has been required.
[0008]
Such DDCP is used to record digital image data processed on a computer on a plate making film using an image setter or the like, perform a final printing operation for directly creating a printing plate using CTP, or use a CTC for a printing machine. Before recording an image directly on a printing plate wound on a cylinder, create a color proof that reproduces the output target indicated by the digital image processed on the computer, and then create a pattern, color tone, text, etc. Is to confirm.
[0009]
In such a proofing process in the printing process,
1) Confirmation of mistakes inside the work site,
2) Outside schools submitted to the orderer and designer to confirm the finish,
3) A print sample provided to the captain of the printing press as a sample of the final printed matter;
Color proofs have been created and used primarily for three applications.
[0010]
By the way, for internal confirmation and some outside school applications, due to needs such as shortened delivery time and cost reduction, calibration materials that can not reproduce halftone images, that is, calibration by sublimation transfer method, inkjet, electrophotography, etc. In some cases, the output material is used mainly as a proofreading for the appearance confirmation.
[0011]
However, in many cases, the printing halftones are still faithfully used for reproducibility of highlights, confirmation of fine details, and confirmation of improper interference fringes of a halftone image called moiré during printing. At present, it is strongly desired that a color proof to be reproduced is created.
[0012]
Therefore, in recent years, for example, using a high-power heat mode laser, image exposure is performed on a sublimation transfer recording material or a heat-sensitive recording material, and a color proof that faithfully reproduces a printing halftone dot is created by transferring the image onto a printing paper. DDCP and the like have begun to spread.
[0013]
However, these systems generally have high laser head costs, expensive equipment, expensive materials to utilize a large number of color imaging sheets, and the process of exposing and transferring images after exposure. There is a problem that it takes a long time only for the number of colors, and it is difficult to apply it to various tasks and create many copies like conventional print proofing from the viewpoint of cost and time. It is in.
[0014]
On the other hand, in recent years, an exposure head that emits light having different wavelengths such as R, G, and B is configured using a plurality of LDs (laser diodes) and LED lamps, and further, a plurality of suction holes are provided. A drum having an outer peripheral surface, and a driving mechanism for driving the drum to rotate. The photosensitive material is held on the outer peripheral surface of the drum, and while the photosensitive material is rotated by the driving mechanism, light is emitted from the exposure head of each color. An image recording apparatus for recording a halftone image by emitting light, exposing the light, and forming Y, M, C, and BK color dots on a photosensitive material has been proposed.
[0015]
In such an image recording apparatus, the cost of the exposure head can be kept low because the LED lamp is low in cost, and the photosensitive material is low in cost because a silver halide color photosensitive material is used. Since there is no process of transfer, it is not necessary to take a long time, and it is possible to apply it to various tasks and create a large number of copies like a conventional print proof.
[0016]
By the way, in such an image recording apparatus, when performing halftone color adjustment, the amount of light emitted from the exposure head for each color is adjusted. Specifically, in the image recording apparatus, a table in which the color density of the photosensitive material corresponding to each gradation and the light amount of light emitted from the exposure head of each color are held in advance, and this table is stored. Since the light amount value of light emitted from the exposure head of each color is controlled according to the following, after outputting a test chart including a chart corresponding to each halftone of the halftone from the image recording apparatus and measuring the density thereof By correcting the table based on the measured values, the light amount value of the light emitted from the exposure head of each color is adjusted (for example, see Patent Document 1).
[0017]
By the way, in such an image recording apparatus, since the light amount value of light emitted from the exposure head of each color changes with time due to the characteristics of the exposure head, the development of developing the photosensitive material after exposure is also difficult. Since the state of the liquid changes during the development process, and furthermore, the photosensitive characteristics of the photosensitive material change each time the lot is switched, or because of the environmental temperature. In the situation where the density of the halftone image formed on the photosensitive material is not stable, such a halftone color adjustment is performed in order to calibrate the fluctuation of the density of the halftone image caused by the difference in these output conditions. It is performed every time a lot of material is switched, or every time a predetermined period elapses.
[0018]
[Patent Document 1]
JP 2000-33732 A
(Paragraphs [0030]-[0061], FIGS. 1-12)
[0019]
[Problems to be solved by the invention]
On the other hand, in such an image recording apparatus, when a solid color is exposed, the light amount value of light emitted from the exposure head of each color is set to a maximum value, and the set value is fixed. It is impossible to adjust the solid color density.
[0020]
However, as described above, the density of the halftone image formed on the photosensitive material fluctuates due to the difference in the output conditions, and the density of solid colors is not stable. In order to correct such a change in the solid color density, attempts have been made to perform halftone color adjustment.
[0021]
However, the present situation is that sufficient color approximation cannot be obtained by such halftone color adjustment.
[0022]
The present invention has been made in view of the above circumstances, and an object of the present invention is to adjust the density of a solid color according to differences in output conditions such as a lot of photosensitive material, a state of a developer, and an output environmental temperature. To provide a color proof with sufficient color approximation and a color proof creation system and a color proof creation method capable of preventing a difference in solid density of the final printed matter. Is to do.
[0023]
[Means for Solving the Problems]
In order to solve the above problem, the invention according to claim 1 is an image processing apparatus that creates halftone image data of each color by performing color separation on image data composed of a plurality of colors, An output device that outputs a halftone image based on the halftone image data of each color as a color proof by emitting light of different wavelengths from a plurality of light sources and exposing the photosensitive material at a predetermined light amount value. A color proof creating system, wherein the image processing apparatus includes a density value of each color component of each color when at least 100% of the halftone dots constituting the halftone image of each color are 100%. Density / light quantity table storage means for storing a density / light quantity table in which light quantity values of light to be emitted from each of the plurality of light sources corresponding to density values of each color component of each color are associated; By referring to the density / light amount table, each of the plurality of light sources should be emitted from the output device when outputting at least a portion of the halftone dot image of each color in which the ratio of the halftone dot is 100% in the output device. A density / light value calculating means for determining a light amount value of light and outputting the light amount value as the predetermined light amount value; and at least one of halftone dots constituting a halftone image of each color of a color chart output by the output device. Density value input means for inputting the density value of each color component obtained by measuring the density of the portion where the ratio of halftone dots is 100%, based on the density value of each color component input by the density value input means; The density value of each color component of each color constituting the density / light amount table, and the light quantity of light to be emitted from each of the plurality of light sources corresponding to the density value of each color component of each color When, characterized in that and a concentration / amount table updating means for updating the.
[0024]
According to a second aspect of the present invention, in the color proof creating system according to the first aspect, the density / light amount table updating unit is configured to execute a process based on a density value of each color component input by the density value input unit. By interpolating the density value of each color component of each color constituting the density / light quantity table and the light quantity value of light to be emitted from each of the plurality of light sources corresponding to the density value of each color component of each color. Calculating a light amount value of light to be emitted from each of the plurality of light sources corresponding to a density value of each color component input by the density value input means.
[0025]
According to a third aspect of the present invention, there is provided the color proof creating system according to the first or second aspect, wherein the density / light amount table storage means further comprises a halftone image data of each of the colors. A density / light quantity in which a density value of each color component of each color in a portion where the percentage of points is not 100% is associated with a light quantity value of light to be emitted from each of the plurality of light sources corresponding to the density value of each color component of each color. The density / light amount calculating means further stores a table in which the ratio of the halftone dots is not 100% in the halftone image of each color by referring to the density / light amount table. Determining the light amount value of the light to be emitted from each of the plurality of light sources at the time of output, outputting the light amount value as the predetermined light amount value; Means for inputting the density value of each color component obtained by measuring the density of a portion where the ratio of the halftone dots constituting the halftone image of each color constituting the dot is not 100%; A table updating unit configured to store, based on the density value of each color component input by the density value input unit, a density value of each color component of each color constituting the density / light amount table and a density value of each color component of each color; A light amount value of light to be emitted from each of the plurality of corresponding light sources is updated.
[0026]
In order to solve the above-mentioned problem, the invention according to claim 4 is an image processing apparatus that creates halftone image data of each color by performing color separation of image data composed of a plurality of colors, and transmits the halftone image data from the image processing apparatus. An output device that outputs a halftone image based on the halftone image data of each color as a color proof by emitting light of different wavelengths from a plurality of light sources and exposing the photosensitive material at a predetermined light amount value. A color proof creating system, wherein the image processing apparatus includes identification information of each color and each color component when at least 100% of the halftone dots constituting the halftone image of each color are 100% And a color / light quantity table storing a color / light quantity table in which the density values of the colors are associated with the light quantity values of light to be emitted from each of the plurality of light sources corresponding to the density values of the respective color components of the respective colors. By referring to the step and the color / light amount table, each of the plurality of light sources is output when the output device outputs, at the output device, at least a portion of the halftone dot image of each color in which the ratio of the halftone dots is 100%. A color / light amount calculating means for determining a light amount value of light to be emitted from the device and outputting the light amount value as the predetermined light amount value; and a halftone dot forming a halftone image of each color of a color chart output by the output device. Density value input means for inputting the density value of each color component obtained by measuring the density of at least a portion where the ratio of the halftone dots is 100%; and density of each color component input by the density value input means. Based on the values, the density value of each color component of each color constituting the color / light amount table and the light of light to be emitted from each of the plurality of light sources corresponding to the density value of each color component of each color Characterized by comprising a color / light quantity table updating means for updating the value, a, a.
[0027]
According to a fifth aspect of the present invention, in the color proof creating system according to the fourth aspect, the color / light amount table updating unit is configured to execute the color / light amount table updating unit based on a density value of each color component input by the density value input unit. By interpolating the density value of each color component of each color constituting the color / light quantity table and the light quantity value of light to be emitted from each of the plurality of light sources corresponding to the density value of each color component of each color. Calculating a light amount value of light to be emitted from each of the plurality of light sources corresponding to a density value of each color component input by the density value input means.
[0028]
According to a sixth aspect of the present invention, there is provided the color proof creating system according to the fourth or fifth aspect, wherein the color / light amount table storage means further comprises a halftone image data of each color. A color / light quantity in which a density value of each color component of each color in a portion where the percentage of points is not 100% is associated with a light quantity value of light to be emitted from each of the plurality of light sources corresponding to the density value of each color component of each color. The color / light amount calculation means further stores a table, and refers to the color / light amount table to determine a portion of the halftone image of each color where the halftone dot ratio is not 100% by the output device. When outputting at, the light amount value of the light to be emitted from each of the plurality of light sources is determined, and the light amount value is output as the predetermined light amount value. Means for inputting the density value of each color component obtained by measuring the density of a portion where the ratio of halftone dots constituting the halftone image of each color is not 100%, and wherein said color / light amount table updating means is provided. Is based on the density value of each color component input by the density value input means, the density value of each color component of each color constituting the color / light amount table, and the density value of each color component of each color. It is characterized in that the light amount value of light to be emitted from each of the plurality of light sources is updated.
[0029]
In order to solve the above-mentioned problem, an image processing apparatus according to a seventh aspect of the present invention generates halftone image data of each color by color-separating image data of a plurality of colors, and creates halftone image data of each color. A density / light quantity that associates a density value of each color component according to a ratio of a halftone dot forming an image with a light quantity value of light to be emitted from each of the plurality of light sources of the output device corresponding to the density value of each color component. Referring to the table, when outputting the dot image of each color in the output device, determine the light amount value of light to be emitted from each of the plurality of light sources, and, in the output device, the dot image of each color A halftone image based on the data is emitted as a color proof by emitting light of a different wavelength from each of the plurality of light sources and exposing the photosensitive material according to the light intensity value of the light to be emitted from each of the plurality of light sources. A color proof creation method for outputting, wherein the image processing apparatus measures the density of at least a portion where the ratio of the halftone dots is 100% in the halftone image of each color of the color chart output by the output device. Inputting the density value of each color component obtained by performing the above, and in the image processing device, the density / light amount table held in the image processing device is stored based on the input density value of each color component. Constituting, among the halftone dots constituting the halftone image of each color, when at least the ratio of the halftone dots is 100%, the density value of each color component of each color and the density value of each color component of each color Updating the light quantity value of the light to be emitted from each of the corresponding light sources.
[0030]
The invention according to claim 8 is the color proof creating method according to claim 7, wherein the step of updating the density / light amount table includes the step of updating the density / light amount table of each color component input to the image processing apparatus. Based on the density / light quantity table, the density value of each color component of each color and the light quantity value of light to be emitted from each of the plurality of light sources corresponding to the density value of each color component of each color are calculated by interpolation. This is a step of calculating a light amount value of light to be emitted from each of the plurality of light sources corresponding to a density value of each color component input by the density value input means.
[0031]
In order to solve the above-mentioned problem, an image processing apparatus according to a ninth aspect of the present invention generates color image data of each color by color-separating image data composed of a plurality of colors, and generates a halftone image data of each color. The identification information of each color and the density value of each color component according to the ratio of the halftone dots forming the image, and the light amount value of light to be emitted from each of the plurality of light sources of the output device corresponding to the density value of each color component With reference to the associated color / light amount table, when outputting the halftone image of each color in the output device, the light amount value of light to be emitted from each of the plurality of light sources is determined, and in the output device, The halftone image based on the halftone image data of each color, according to the light amount value of the light to be emitted from each of the plurality of light sources, by emitting light of different wavelengths from each of the plurality of light sources to expose the photosensitive material. A color proof creating method for outputting as a color proof, wherein in the image processing device, at least a portion of a halftone dot image of each color of a color chart output by the output device is 100%. Inputting the density value of each color component obtained by measuring the density, and, in the image processing apparatus, configuring the color / light amount table based on the input density value of each color component. Of the halftone dots constituting the halftone image, the density value of each color component of each color and the plurality of density values corresponding to the density values of each color component of each color when at least the ratio of the halftone dots is 100%. Updating the light amount value of light to be emitted from each of the light sources.
[0032]
According to a tenth aspect of the present invention, in the color proof creating method according to the ninth aspect, the step of updating the color / light amount table comprises the step of updating the color / light amount table with a density value of each color component of each color input to the image processing apparatus. The interpolation calculation of the density value of each color component of each color constituting the color / light quantity table and the light quantity value of light to be emitted from each of the plurality of light sources corresponding to the density value of each color component of each color based on This is a step of calculating a light amount value of light to be emitted from each of the plurality of light sources corresponding to a density value of each color component input by the density value input means.
[0033]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an example of a preferred embodiment of a color proof creation system and a color proof creation method according to the present invention will be specifically described with reference to the drawings.
[0034]
[Schematic configuration of color proof creation system]
First, a schematic configuration and a schematic operation of a color proof creation system according to the present invention, more specifically, a color proof creation system in the desktop publishing field will be described.
[0035]
(Overall configuration of the system)
FIG. 1 shows an overall configuration of a color proof creation system according to the present embodiment. As shown in FIG. 1, the color proof creating system 1 includes an upstream terminal device 2A having an image editing function of generating a plurality of, for example, three image data connected to a network 3 configured by a LAN or the like. 2B, 2C, a plurality of image processing apparatuses 10 (10A, 10B) having the same image output control function, and a plurality of image processing apparatuses 10 (10A, 10B) respectively connected to the network 3; , For example, two output devices 20 (20A, 20B). The image processing device 10 is preferably configured by a computer such as a server, and the output device 20 (20A, 20B) is configured by a DCP (digital color proof) creating device.
[0036]
In this embodiment, it is assumed that a density-light quantity correlation table described later is provided in the image processing apparatus 10. However, it is assumed that the density-light quantity correlation table is provided in the output device 20 alone. Alternatively, it may be provided in each of the image processing device 10 and the output device 20. At this time, for example, when a plurality of output devices 20 of different models are connected to one image processing device 10, one density-light quantity correlation table corresponding to each output device 20 is stored in one unit. It is needless to say that the image processing apparatus 10 may be provided with the image processing apparatus 10.
[0037]
Each of the upstream terminal devices 2A, 2B, and 2C operates as a computer terminal device. Specifically, a computer body having a CPU, a ROM, a RAM, and the like, and a display such as a CRT and a mouse connected thereto are provided. , A keyboard, a digitizer, an FDD device, and a hard disk, and an input device for generating an image such as an image scanner. Note that the upstream terminal devices 2A, 2B, and 2C can employ various hardware configurations according to the system configuration.
[0038]
As shown in FIG. 1, the image processing device 10 transmits image data of an image editing file edited by the upstream terminal 2 through a network 3 or an external input / output device such as an FDD to a RIP (Raster Image Processor). In addition to rasterizing the data into raster data, the color separation data (halftone image data) is generated, and the halftone image data is transferred to the output device 20 to output an image. I have.
[0039]
The image processing apparatus 10 (10A, 10B) also includes input devices such as a computer main body, a display unit, and a keyboard, accepts image data, outputs a job to the output device 20 (20A, 20B), and processes a job when a failure occurs. An operation program for performing such operations is incorporated. Further, the image processing apparatus 10 may be connected to a color scanner for reading an image original, a mount input device for reading information on a mount, and a galley printer for performing galley printing of relatively low image quality, if necessary.
[0040]
The output device 20 forms an image on a photosensitive material based on the halftone image data transferred from the image processing device 10 and develops the image to create a color proof. Note that the output device 20 can be constituted by an image forming device such as a color proofer using a laser exposure method or the like.
[0041]
That is, the image data is transferred from the image processing device 10 to the output device 20 through the network 3, and the output device 20 sequentially draws the image data of each color on a photosensitive material and develops the data to create a color proof. be able to.
[0042]
Here, the image processing apparatus 10 is equipped with software including various tables for controlling the solid density adjustment of the basic colors and the like, and the difference in output conditions such as the lot of photosensitive material, the state of the developing solution, and the output environmental temperature. By setting a combination of the light amount values of different wavelengths according to the above, it is possible to create a color proof having a correct color tone. It should be noted that such solid density adjustment processing of the basic color is a characteristic part of the present invention, and details thereof will be described later.
[0043]
(Configuration of image processing device)
FIG. 2 shows an example showing a specific control configuration of the image processing apparatus 10. As shown in FIG. 2, the image processing device 10 functions as a controller that controls the output device 20, and an input unit 11 which is an input interface to which image data of an image editing file edited from the outside is input, and an input unit. A halftone image data creating unit 12 for expanding the image data input at 11 into raster image data and performing separation and color separation data to generate halftone image data, and the like; Based on a storage unit 17 such as a hard disk for storing setting conditions and the like, halftone image data from the halftone image data creation unit 12, and a measurement table (density-light amount correlation table) 17a in the storage unit 17, An adjustment operation processing unit 13 that calculates a combination of values to perform solid adjustment; a light amount value in the adjustment operation processing unit 13; The halftone image data from the creation unit 12 is output in the order of planes, for example, special 1, C, M, Y, K, and the like. An operation unit 16 for inputting setting operations such as setting conditions, a display unit 15 including a CRT or a liquid crystal panel for displaying a screen for setting various setting parameters such as various LUTs, and an external input / output device 18 such as an FDD; A control unit 19 including a CPU for controlling each of the halftone image data creating unit 12, the adjustment operation processing unit 13, the transfer control unit 14, the operation unit 16, the storage unit 17, the display unit 15, and the external input / output device 18. And is comprised.
[0044]
Note that the control unit 19 and the adjustment calculation processing unit 13 can constitute a calculation unit. This calculating means corresponds to the "density / light quantity table updating means" or the "color / light quantity table updating means" of the present invention, and at least corresponds to a solid color (halftone) corresponding to a halftone dot of halftone image data. Based on each density value of each component (the ratio of points is 100%), an optimal combination of the respective light amount values to be emitted by a plurality of lights is calculated.
[0045]
Note that the control unit 19 and the transfer control unit 14 constitute a “density / light amount calculation unit” or a “color / light amount calculation unit” of the present invention. The measurement table (density-light quantity correlation table) 17a corresponds to the “density / light quantity table” of the present invention. The storage unit 17 corresponds to the “density / light amount table storage unit” of the present invention.
[0046]
Such an image processing apparatus 10 develops an edited image file transferred from the upstream terminal 2 into image data such as raster data, and, if not yet separated, a predetermined color based on the image data. Separation processing is performed to separate colors into Y, M, C, K and special colors, and a transfer control operation is performed on each of the separated data to the output device 20.
[0047]
The input unit 11 includes image data such as page description language (PDL) including color information of an image editing file from the editing upstream terminal 2 for comprehensively integrating and editing images such as characters and pictures. Is entered. As the image data, in addition to the data described in the page description language such as PS, EPS, and PDF, general-purpose format data such as TIFF and TIFF / IT, data handled by major manufacturers as a format dedicated to the company, In addition, various data similar thereto are also included.
[0048]
The halftone dot image data creation unit 12 uses the storage unit 17 including a spool buffer to convert input data, for example, PDL data, into predetermined image output conditions (dot shape, halftone angle, screen ruling, In accordance with the gamma characteristics of the photosensitive material, the characteristics of the developing machine, etc.), raster image data, which is binary image data, is developed, separation is performed, and halftone image data is generated.
[0049]
The transfer control unit 14 performs processing such as transferring the developed and separated image data to the output device 20. As a result, Y, M, C, and K image data in a raster image format are generated in order (plane-by-plane) for each color from the image data for electronic plate making that is the basis of the electronic plate making.
[0050]
Then, reproduction is performed from the image data for electronic plate making using a set of halftone dots having the same screen ruling as the printed matter, and the pixel gain is approximated to that of the printed matter and reproduced. As a result, the print halftone image is faithfully reproduced. Here, a halftone dot is a fine point created by screen-making that reproduces a photograph or illustration with continuous tone as a printed matter. It was used.
[0051]
The storage unit 17 outputs a specific output material 20 using a specific photosensitive material corresponding to one target which is a final print, which is necessary for adjusting the solid density of the basic color. A measurement table that defines the correlation between the density values of each of the basic color components, Dc, Dm, and Dy obtained by measuring the density of the color chart, and the combinations of the RGB light quantity values corresponding to the density values. (Density value-light amount value correlation table) 17a and a processing program for calculating a corresponding light amount from the extracted density value using the measurement table 17a are stored as files in a specific directory. I have.
[0052]
It is preferable to prepare a plurality of measurement tables 17a in accordance with output conditions such as a lot of photosensitive material, a state of a developing solution, and an output environment temperature. Associating a sensitivity index that corrects an error between each of the plurality of measurement tables according to the output condition such as the lot of photosensitive material, the state of the developing solution, and the output environmental temperature, etc. A tabulated sensitivity index table is prepared, and, for example, when the lot number of the photosensitive material, the environmental temperature, and the like are input on the display unit 15 or the operation unit 16, these are automatically used as a reference. Using a measurement table and a sensitivity index table, a measurement table corresponding to those output conditions may be created. Alternatively, a color channel (color correction) color correction LUT corresponding to those output conditions may be automatically created. The details will be described later. Further, it goes without saying that a measurement table for a special color, a processing program for calculating a light amount value, and the like may be prepared.
[0053]
The storage unit 17 also includes a work memory that temporarily stores the entire control program and font data, a control program for color separation processing (special color separation), and the progress of processing, for example. A PS file memory for storing graphic file data including color data described in a page description language (PDL data) such as PostScript (PS), and extracting and storing data of all colors from a file in the PS file memory The memory includes various memory areas such as a color table memory for performing color separation, a color separation file memory for storing color separation files for each color subjected to special color separation, and the like.
[0054]
The operation unit 16 is also used as the display unit 15 and can be set by inputting from an input key or the like as an operation input unit. For example, parameters set by pressing a save button or the like are stored in the storage unit 17. be able to.
[0055]
The display unit 15 is a display unit that displays the status of the output device 20 and various information, and also a display operation unit that inputs information for various settings and operations. The parameters set by the operation unit 16 and the display unit 15 include, for example, various LUTs.
[0056]
In the case of the image processing apparatus 10, the output setting information includes output resolution, halftone dot information, positive / negative setting, necessity of rotation, various table information for various color adjustments, and the like. Information, error logs, etc.
[0057]
The control unit 19 reads various information set and stored for the output device 20 from the storage unit 17, sets the read information in the halftone image data creation unit 12, displays the same on the display unit 15, and displays the various information. The halftone image data creating unit 12 is controlled based on the halftone image data.
[0058]
By the way, between the image processing apparatus 10 and the output apparatus 20, in addition to the transfer of the dot image data, communication of control information (instruction for transporting the photosensitive material, instruction for starting / stopping the exposure, and response thereto) is performed. May be asked. In such a case, the control information is communicated via the transfer control unit 14. It is preferable that the relay of the control information and the transfer of the dot image data are independently performed by a plurality of transfer control functions in the control transfer control unit 14, respectively.
[0059]
(Configuration of output device)
FIG. 2 shows an example of a specific control configuration of the output device 20. As shown in FIG. 2, the output device 20 outputs the number of scanning lines based on the halftone image data transferred from the image processing device 10 in the order of, for example, special 1 (special color 1), C, M, Y, and K. (1 main scan) is converted to an exposure format, and the converted halftone image data is converted into pixel data composed of all data for one color of Y, M, C, and BK by exposure for each scanning line. The exposure unit 23 performs laser exposure by reading out data in all formats simultaneously and sequentially (dot-sequentially), and develops a photosensitive material transported from the exposure unit 23 to form a photosensitive image on which a color image is formed. An output unit 24 that outputs a material as a color proof, an information temporary storage unit 21 that is a data buffer, a storage unit 25, a setting unit 26, and a control unit 22 that controls the exposure unit 23 and the output unit 24 are provided. I have.
[0060]
The control unit 22 controls the amount of exposure based on a color channel color correction LUT that defines the correspondence between the reference color for printing and the intensity composition of the light from the light source that exposes the photosensitive material. Is adjusted to control the density.
[0061]
The information temporary storage unit 21 temporarily stores, in a predetermined area, halftone image data generated by the image processing apparatus 10 and transferred for each color in a frame-sequential manner. Further, the control unit 22 temporarily stores the halftone image data converted into the exposure format for each of the number of scanning lines (for one main scan) in one predetermined area of Y, M, C, and BK in another predetermined area. Store.
[0062]
The control unit 22 reads out pixel data including all data of Y, M, C, and BK in an exposure format for each scanning line, and outputs data of all colors simultaneously (dot sequential) on the photosensitive material. Is controlled so that the image is exposed by the exposure unit 23.
[0063]
By the way, in a photosensitive material storage unit (not shown) of the output device 20, for example, a roll-shaped silver halide color photographic photosensitive material is set as the photosensitive material, and the control unit 22 pulls out the photosensitive material and cuts it into a sheet. After that, the exposure unit 23 exposes the photosensitive material with laser light according to the rearranged halftone image data.
[0064]
The output unit 24 performs a development process in a development processing unit (not shown) to create a color proof.
[0065]
In addition, it is preferable that a red laser light source, a green laser light source (HeNe), an infrared laser light source, and the like are configured in an optical unit (not shown) of the exposure unit 23. At this time, the green laser light source generates a green laser beam to sensitize the magenta coloring layer (M layer) of the photosensitive material, and the red laser light source generates a red laser beam to cause the cyan coloring layer (C layer) of the photosensitive material. ), And the infrared laser light source generates an infrared laser beam to sensitize the yellow coloring layer (Y layer) of the photosensitive material. In this photosensitive material, a normal color printing paper has a blue photosensitive yellow coloring layer (Y layer), a green photosensitive magenta coloring layer (M layer), and a red photosensitive cyan coloring layer (C layer). The blue light-sensitive layer of the blue light-sensitive layer (Y layer) is shifted to the infrared light-sensitive layer to form an infrared-sensitive yellow color-forming layer.
[0066]
Further, the number of colors in the optical system is not limited to three. For example, a blue laser diode, a red laser diode, a first infrared laser diode (oscillation wavelength of 760 to 880 nm), and a second far infrared laser diode (oscillation Four wavelengths of 900 nm or more).
[0067]
The green laser light source, the red laser light source, and the infrared laser light source are configured to modulate the light amount according to the modulation signal, and generate laser beams of three wavelengths of green G, red R, and infrared IR, respectively. The CMY layer of the photosensitive material is exposed to light.
[0068]
The LUT unit in the storage unit 25 stores reference colors for printing, that is, Y (yellow), M (magenta), C (cyan), and BK (black), and light of a light source that exposes the reference colors to the photosensitive material. That is, a color channel table 25a, which is LUT (look-up table) data that defines correspondence with the intensity composition of B (blue), R (red), and IR (infrared), is stored. Although the details of the color channel table 25a will be described later, the color channel table 25a includes an LUT corresponding to the basic color.
[0069]
The reference colors include four primary colors of Y, M, C, and BK, which are the primary colors of normal color image printing, three primary colors of the additive color mixture, Y, M, and C, and three primary colors of printing. And five or more colors obtained by adding one or more special colors to the four colors Y, M, C, and BK, but are not limited thereto. Incidentally, Y means yellow (yellow), M means magenta, C means cyan, BK means black (black), B means blue (blue), G means green (green), and R means red (red).
[0070]
In addition, depending on the printed matter, a special color ink other than Y, M, C, and K, that is, a so-called “special color” ink may be used in order to enhance color reproducibility. This special color ink plate is called a “special color plate”. As the special color ink, various kinds of inks such as gold, silver and other metallic colors are used in addition to green and orange inks. Further, the density of the special color ink may not be uniform, and a mixture of glitter and gold powder may be used. The special color plate is often used when reproducing an image component such as a logo which is designated as a special color in advance, or when it is desired to enhance color reproducibility of a color image by printing with a special color ink.
[0071]
Incidentally, the above-described color channel table 25a may be provided in the storage unit 17 of the image processing apparatus 10. However, regardless of whether the storage unit 25 is provided in the storage unit 25 of the output device 20 or the storage unit 17 of the image processing device 10, the configuration can be updated and set.
[0072]
The control unit 22 converts the Y, M, C, and K digital halftone dot image data of the transmitted exposure format into B, R, and G exposure intensity data using the color channel table 25a. .
[0073]
At this time, the Y, M, C, and BK halftone image data of the printed matter are converted into a combination of B, R, and G laser intensities for each pixel.
[0074]
The halftone image data of each color (Y, M, C, BK) created by the halftone image data generation unit 12 of the image processing unit 10 is temporarily stored in the information temporary storage unit 21 of the output device 20. You. Then, the control unit 22 simultaneously reads out the halftone image data of each color by a dot clock or the like while accumulating the fluctuation of the transfer speed in the information temporary storage unit 21 and sends it to the storage unit 25.
[0075]
By the way, when solid adjustment or the like is performed, adjustment processing is performed in the adjustment calculation processing unit 13 of the image processing apparatus 10, and control information such as each exposure value extracted at this time is reflected in the color channel LUT. . Then, information on the color channel LUT is sent to the storage unit 25 of the output device 20, and an update process of the exposure value and the like of the color channel table 25a is performed. Then, all-color simultaneous exposure is performed based on the color channel table 25a reflecting the solid adjustment and the like.
[0076]
At this time, the green laser light source, the red laser light source, and the infrared laser light source emit light based on the LUT data of the set color channel table, and the color of ink and / or the color of printing paper when printing a color print. The image having the color corresponding to is exposed.
[0077]
Further, at this time, the control unit 22 determines the position of the photosensitive material from the sensors (not shown) and the count value of the pulse signal from the rotary encoder that detects the rotational position of the drum (not shown). It is determined whether or not the image recording area of the photosensitive material exists at the irradiation position of the laser light emitted from the optical unit, and during the period in which the image recording area of the photosensitive material exists at the irradiation position of the laser light, Control is performed so that LUT data is set such that the exposure intensity data input to the driver for driving each laser light source is always converted to an exposure intensity data value equal to or greater than the exposure intensity data value sufficient to cause the laser diode to emit light.
[0078]
Thus, the laser diode of the laser light source constantly emits light during the period in which the image recording area of the photosensitive material is located at the laser beam irradiation position, and the responsiveness is good. In this manner, the image output of the halftone image is performed on the photosensitive material held on the drum. The configuration and operation of the other output device 20B are the same as those of the output device 20A.
[0079]
Incidentally, the image recording density of the image recorded on the photosensitive material is preferably 600 dpi or more (especially 1000 dpi or more, more preferably 1200 dpi or more) in both the main scanning direction and the sub-scanning direction from the viewpoint of reproducibility of gradation by a halftone dot image. In addition, from the viewpoint of saturation of gradation reproducibility by a halftone dot image, image recording speed, apparatus cost, and the like, both in the main scanning direction and in the sub-scanning direction are preferably 10,000 dpi or less (particularly 5000 dpi or less). The image recording densities in the main scanning direction and the sub-scanning direction are indicated in units of dpi indicating how many pixels to be image-recorded are arranged in a length of 1 inch in the main scanning direction or the sub-scanning direction.
[0080]
Further, it is preferable that one halftone dot is recorded from 100 or more (especially, 200 or more) pixels because the reproduction is close to an actual printing halftone dot. Further, it is preferable that one halftone dot is recorded from pixels of 5000 or less (especially 2000 or less) because image data can be easily handled and image data can be processed at high speed.
[0081]
Further, the number of recording pixels per second of each color of the exposure light is preferably 3,000,000 pixels / second or more (especially 10,000,000 pixels / second or more). This makes it possible to achieve both high-speed image recording and high-definition image recording. The number of recording pixels per second of each color of the exposure light is preferably 4 billion pixels or less (particularly 500 million pixels or less). Thereby, the drive circuit is stabilized, the image recording is stabilized, the exposure intensity and the exposure position are stabilized, the cost is low, and the adjustment is easy.
[0082]
Further, it is assumed that the control unit 19 of the image processing device 10 can detect the exposure amount information and the like set in the output device 20 via the transfer control unit 14 and the control unit 22 of the output device 10. Thus, the image processing apparatus 10 can also change the exposure amount information and the like of the output device 20, and the changed exposure amount information and the like are transferred from the transfer control unit 14 to the output device 20 again.
[0083]
As described above, when creating a color print, before creating image data in a raster image format from digital image data described in various formats and creating a printing plate, a dot image data creating unit of the image processing apparatus 10 is used. In step 12, image data in a raster image format is generated from the digital image data, and is rearranged into image data in a format compatible with the output device 20 using the storage unit 17, and output is performed based on the rearranged image data. By recording an image in the device 20, a color proof that simulates an image obtained by printing on a printing plate created from digital image data described in various formats is created, and an image represented by the digital image data is created. There is an error such as whether there is an error in the layout, color, text, etc. Check the, it is possible to confirm the print finish in advance.
[0084]
Note that PDL data including color information output from the editing upstream terminal 2 is already separated data of page 4 (5) consisting of C, M, Y, K, (or special 1). (Hereinafter, also referred to as separated data as necessary), the halftone image data creating unit 12 performs raster image processing as a non-separation mode (non-separation mode) and performs CMYK. It is also possible to output five special editions of raster image data.
[0085]
On the other hand, PDL data or the like including color information output from the editing upstream terminal 2 is a description of one page and is data that has not yet been separated (hereinafter, also referred to as unseparated data as necessary). In some cases, the halftone image data creation unit 12 performs raster image processing as a processing mode (separation mode) to output raster image data.
[0086]
As described above, even if the separation process for separating (decomposing) image data in which Y, M, C, and K are mixed into each data is executed by the upstream terminal 2 for editing, It may be executed by the data creation unit 12. That is, the image data is generally a single data file in which process colors (CMYK) and special colors are mixed. In some cases, each color plate is passed as separate data, or only the special color data is transferred. In some cases, the color separations are passed as separate data files. If each color plate is passed as separate data, the halftone image data creating unit 12 omits the separation processing.
[0087]
(Schematic operation of the system)
In the configuration described above, when creating a color proof, first, in the image processing apparatus 10, various designations are performed using the display unit 15 and the operation unit 16. The control unit 19 stores the designated input information in the storage unit 17.
[0088]
Next, the control unit 19 starts taking in the page description language (PDL data) including the color information from the upstream terminal 2 via the input unit 11, and determines whether or not the supply of the PDL data has been completed.
[0089]
Image data, which is multi-valued gradation data described in various page description languages and the like, which has been edited and transferred in the external upstream terminal 2, is developed and separated by the halftone image data creating unit 12, A color separation file (halftone image data) required to create one color proof is generated, and pixels of halftone image data as binary halftone dots are generated.
[0090]
That is, since the image data is data that can be reproduced by printing, the information on the color is naturally described in the color used for printing. Therefore, when the print colors are the process colors Y, M, C, and K and the special colors are special features 1 and 2, the description of the color of the image data is described only in these six colors. Has these six color information.
[0091]
Normally, in the RIP process, monochromatic raster format gradation data for each color plate is output for the number of colors, but data in a format in which color gradation values are arranged for each pixel may be used. In any of the formats, the color value of a certain pixel of the input raster image data is expressed as a vector value, such as gradation value = (C, M, Y, K, special 1, special 2). Is preferred. Each vector component is a numerical value (halftone dot%) from 0 to 100 where solid is 100 and white is 0.
[0092]
At this time, if there is no other instruction, the control unit 19 sets the halftone image data creation unit 12 to the separation processing mode as a default.
[0093]
If the transferred PDL data including color information is data that has been separated, the halftone image data creating unit 12 is set to the separation mode in advance, and raster image processing is started, and the separation is not performed. If the data is data, the halftone image data processing unit 12 is set to the non-separation mode, and the halftone image data creation unit 12 performs raster image processing in the halftone image separation process on the PDL data including color information. To do.
[0094]
By controlling in this way, if the transferred PDL data is not separated data, the halftone image data creation unit 12 is set to the separation mode, and the process is continued as it is. As a result, , Raster image data for the desired four plates is obtained.
[0095]
As a result, the separation / non-separation processing mode in the editing upstream terminal 2 and the separation / non-separation processing mode in the halftone image data processing unit are appropriately selected. The process is executed by one of the PC 2 and the halftone image data creating unit 12.
[0096]
A file written in a page description language (hereinafter, also referred to as a PS file) can uniformly handle data in which characters, photos, figures, and the like are mixed, and can handle graphic data written in such a page description language. When multicolor printing is performed, a separation file (including a special color separation) for each color is generated. Specifically, the data of all the colors used are analyzed from the PS file including the graphic data written in the page description language, and the color of the color separation file is analyzed based on the color data. Generate version data.
[0097]
Then, the transfer control unit 14 transfers the color plate data to the output device 20, and the output device 20 receives the color plate data from the image processing device 10 in a predetermined order in a frame-sequential manner.
[0098]
The color plate data generated by the image processing device 10 and transferred for each color in a frame-sequential manner, that is, halftone dot image data is converted into an exposure format for each scanning line number (for one main scan) in the output device 20. It is converted and stored in a predetermined area of the information temporary storage unit 21 of the output device 20.
[0099]
At this time, the screen-sequential halftone dot image data (data separated into Y, M, C, and BK corresponding to the printing plate) is converted into a series of data of a plurality of beams of the exposure unit 23 for one scan. .
[0100]
Then, the halftone image data converted into the exposure format for each scanning line (for one main scan) is used for one screen of all colors of Y, M, C, and BK (necessary for creating one color proof). After accumulating one dot image data for all colors, pixel data composed of all data of Y, M, C, and BK is read in an exposure format for each scanning line, and data of all colors is simultaneously (dots). Sequentially).
[0101]
The control unit 22 counts the number of halftone pixels based on image data obtained by converting the input pixel data including all the data of Y, M, C, and BK into an exposure format for each scanning line number. For example, the process is continuously performed on the pixels of the dot image data for one line or one page.
[0102]
The control unit 22 counts the number of dots in the main scanning direction and the number of dots (the number of lines) in the sub-scanning direction with respect to the halftone image data, and calculates the image size with reference to the counted value. Control is performed so that an image is exposed on the photosensitive material by the exposure unit 23.
[0103]
In the photosensitive material storage section of the output device 20, for example, a roll-shaped silver halide color photographic photosensitive material is set as the photosensitive material, and the control section 22 pulls out the sheet, cuts it into a sheet, and then exposes the sheet. The color proof is created by exposing with laser light according to the rearranged halftone image data by the unit 23 and then performing development processing by the development processing unit of the output unit 24.
[0104]
[Detailed configuration of color proof creation system]
Next, a detailed configuration and a detailed operation of the color proof creating system according to the present embodiment will be described mainly with respect to a solid color density adjustment which is a characteristic part of the present invention.
[0105]
(Detailed configuration of image processing device)
FIG. 3 shows an example showing a detailed control configuration of the image processing apparatus 10. As illustrated in FIG. 3, the storage unit 17 of the image processing apparatus 10 outputs data using a specific photosensitive material corresponding to one target which is a final print beforehand when the output device 20 is shipped. The correlation between the density values (Dc, Dm, Dy) obtained by measuring the solid density values of the basic colors of the color chart with a densitometer and the light intensity values (R, G, B) at that time was defined. It is configured to include a measurement table (density (Dc, Dm, Dy) -light amount (R, G, B) correlation table) 17a.
[0106]
It is preferable that a plurality of measurement tables 17a be prepared in accordance with the output conditions such as the lot of photosensitive material, the state of the developing solution, and the output environmental temperature. For example, as shown in FIG. Some reference measurement tables (reference density tables), and those reference measurement tables (reference density tables) correspond to differences in output conditions such as lots of photosensitive materials, developer conditions, and output environmental temperatures. A sensitivity index table is prepared by associating a sensitivity index for correcting an error with each of the plurality of measurement tables, and the table is prepared. When an environmental temperature or the like is input, a measurement table (correction density table) corresponding to those output conditions may be automatically created. Alternatively, a color channel (color correction) color correction LUT corresponding to those output conditions may be automatically created. The details will be described later. Further, when the output device 20 is provided with a plurality of photosensitive material storage units (for example, magazines 1 to 8) (not shown), a correction density table is created corresponding to the photosensitive material stored in each of the storage units. It may be done. Incidentally, the reference density table, the sensitivity index table, and the correction density table shown in FIG. 4 are merely examples, and the present invention is not limited to these examples.
[0107]
Further, the storage unit 17 stores a color channel (color correction) color correction LUT 17b in which the exposure amount of each light solid-adjusted with respect to the basic color is defined for each printing reference color, and each basic color (process color: C, M). , Y, K), a dot gain correction LUT 17c for performing dot gain correction, a calibration correction LUT 17d for performing calibration correction for each basic color, and an ICC profile standardized by an ICC (International Color Consortium). It comprises an ICC profile color correction information storage unit 17e storing color correction information, and an ICC device link profile color correction information storage unit 17f storing color correction information relating to the ICC device link profile.
[0108]
The storage unit 17 corresponds to the “color / light amount table storage unit” of the present invention. The color channel (color correction) color correction LUT 17b corresponds to the “color / light amount table” of the present invention.
[0109]
The adjustment calculation processing unit 13 includes a light amount value calculation processing unit 13a that is a calculation unit that calculates a combination of light amount values for solid adjustment based on the basic color measurement table 17a, and a network based on the dot gain correction LUT 17c. A dot gain correction arithmetic processing means 13b for performing arithmetic processing of dot gain correction of the dot image data; and a calibration correction arithmetic processing means 13c for performing arithmetic processing of calibration correction of the halftone image data based on the calibration correction LUT 17d. Based on the information in the ICC profile color correction information storage means 17d, which performs the ICC profile color correction arithmetic processing based on the information in the ICC profile color correction information storage means 17e, and the information in the ICC device link profile color correction information storage means 17f, ICC device link profile A configuration including an ICC device link profile color correction calculation processing unit 13e for performing a color correction calculation process, and a calculation procedure control unit 13f for controlling only the calculation order of these correction calculations and necessary correction calculations. Have been.
[0110]
Incidentally, the adjustment calculation processing unit 13f further calculates, based on the combination of the light amount values calculated by the light amount value calculation processing unit 13a, for example, the light amount value of each reference color in the case of a solid (100% net) of the basic color. Processing means for transferring information relating to the color channel color correction LUT 17b defining the combination of the above to the output device 20, and prompting a process of replacing the LUT set by default in the output device 20 with information of the color channel color correction LUT 17b. May be included.
[0111]
At this time, the processing unit may include a determination unit that acquires information on the color channel color correction LUT 17b of the output device 20 and determines whether the image processing device 10 needs to replace the information.
[0112]
Note that the adjustment calculation means can be constituted by the dot gain correction calculation processing means 13b and the calculation procedure control means 13f. The adjustment calculating means converts the basic color into a dot area ratio corresponding to the type of printed matter based on the dot gain LUT 17c which defines the dot area ratio of the dot image data to the dot ratio of the printed dot. The adjustment is performed by calculating the combination of the light amount values while correcting the fluctuation.
[0113]
In addition, the adjustment calculation means can be configured by the calibration correction calculation processing means 13C and the calculation procedure control means 13f. The adjustment calculation unit performs the adjustment by calculating the combination of the light amount values while correcting the color of the basic color based on the calibration LUT 17d.
[0114]
The display unit 15 includes, for example, a first setting unit 15a for setting and inputting information regarding the measurement table 17a and a second setting for setting and inputting information regarding the color channel color correction LUT 17b based on the basic color (process color). Means 15b, third setting means 15c for setting and inputting information regarding the dot gain correction LUT 17c for the basic color (process color), and fourth setting for setting and inputting information regarding the calibration correction LUT 17d for the basic color. Means 15d, fifth setting means 15e for setting and inputting information relating to ICC profile color correction, and sixth setting means 15f for setting and inputting information relating to the ICC device link profile. I have.
[0115]
The first setting means 15a and the second setting means 15b each correspond to the "density value input means" of the present invention.
[0116]
In addition, the display unit 15 sets these output conditions so as to create a measurement table (correction density table) according to the difference in output conditions such as the lot of photosensitive material, the state of the developing solution, and the output environmental temperature. And a seventh setting means 15g.
[0117]
Note that the control unit 19 and the light amount value calculation processing unit 13a can constitute an extraction unit. This extracting means extracts a light amount value corresponding to the solid (100% net) measurement value of the basic color set by the first setting means 15a using the measurement table 17a. Then, a color channel color correction LUT (color channel table) 17b is created based on the light amount value.
[0118]
Here, the measurement table 17a specifically has a structure shown in FIG. 5, and is, for example, a table that defines the relationship between the light intensity value of 0 to 255 and the measured density value (CMY). Say. The measured density value is a density value when passing through the C filter density value Dc, the M filter density value Dm, and the Y filter density value Dy, and the light amount value is 5 steps in 1 step and 52 steps, for example, (R, G, B) ) To (255,0,0), then from (0,5,0) to (255,5,0), and similarly repeated until it becomes (255,255,255), and 52 × It is a value obtained by measuring all 52 × 52 = 140608 patterns.
[0119]
That is, when the output device 20 is shipped, the solid density value of the basic color of the basic color of the color chart output using a specific photosensitive material corresponding to one target which is the final printed matter is previously measured by a densitometer. A measurement table is created that defines the correlation between the density values (Dc, Dm, Dy) obtained by the measurement and the light intensity values (R, G, B) at that time. In the densitometer, the value of V (omitted), the value of Dc, the value of Dm, and the value of Dy are respectively detected. Data is input to the densitometer by connecting it to a PC or the like via the RS232C. Incidentally, at this time, the data may be input using the first setting unit 15a or the second setting unit. The input data is mounted on the storage unit 17 as a measurement table 17a.
[0120]
The color chart 30a specifically has the structure shown in FIG. 6, and includes, for example, each halftone dot of K, 3C (C, M, Y) (for example, halftone dots 20%, 40%, 60%). %, 80%) and solid of K, 3C, 4C (C, M, Y, K), C, M, Y, R (M + Y), G (C + Y), B (C + M) ) Is output. Incidentally, when creating the measurement table 17a, each solid density of K, 3C, 4C, C, M, Y, R, G, and B is measured.
[0121]
As described above, in the present embodiment, the color chart 30a is configured to output both the data of each halftone dot of each color and the solid data of each color, so that the color chart 30a is output using one color chart 30a. The adjustment of the channel color correction LUT (color channel table) and the adjustment of the solid density of the basic color can both be performed.
[0122]
Returning to the description, the light amount value calculation processing unit 13a of the extraction unit refers to the measurement table 17a and searches for a combination of the measurement values (R, G, B) that is closest to the density values (Dc, Dm, Dy). To calculate the corresponding light amount value. Then, the control unit 19 creates a color channel color correction LUT (color channel table) 17b based on the light amount value.
[0123]
In the present embodiment, as an example of the measurement table 17a, a case where the light amount value is 5 steps is described. However, this step can be further refined, and the measured value of the minimum resolution of the densitometer is used. In this case, for example, the light amount value of R is increased by one step such as 0, 1, 2,..., And a combination of R, G, and B can form a 256 × 256 × 256 pattern. As described above, it is preferable to prepare a plurality of measurement tables for each of the basic colors according to the output conditions such as the lot of the photosensitive material, the state of the developer, and the output environmental temperature. .
[0124]
Further, in the present embodiment, as examples of the color chart 30a, each halftone dot of K, 3C (C, M, Y) (for example, four halftone dots of 20%, 40%, 60%, and 80%); K, 3C, 4C (C, M, Y, K), C, M, Y, R (M + Y), G (C + Y), B (C + M) However, these combinations can be increased or decreased as necessary, and it is preferable that the combinations be appropriately selected. Also, the number of each halftone dot can be increased or decreased as necessary, and its ratio (%) can be arbitrarily selected.
[0125]
The color channel color correction LUT (color channel table) 17b specifically has a structure shown in FIG. 7, where the colors of the reference colors are Y, M, C, B, (Y + M) R, (M + C) B,... That is, in the arrangement of the halftone dots, when another halftone dot having a different angle overlaps with a certain halftone dot, there are 16 possible combinations. For each color, for example, information on the intensity of exposure from 0 to 255 is tabulated.
[0126]
As will be described later, for example, the solids of K, 3C, 4C, C, M, Y, R, G, and B of the color chart 30a measured by the densitometer are measured using the second setting unit. In order to create a corrected color channel (color correction) color correction LUT by inputting the density value of each color component obtained by performing the above, a color channel color correction LUT (color channel table) Information on the density values of Y, M, C, and B as color components is added to each of the 16 patterns of Y, M, C, B, (Y + M) R, (M + C) B,. It will be. The details will be described later.
[0127]
That is, the color channel color correction LUT (color channel table) 17b includes, for example, reference colors for printing, that is, Y (yellow), M (magenta), C (cyan), B (blue), G (green), and R. (Red), BK (black), GY (gray) and W (white), and light from a light source for exposing the reference color to the photosensitive material, that is, R (red), G (green), B (or IR) (Infrared) is stored.
[0128]
As described above, the exposure amount of the color channel color correction LUT (color channel table) 17b is automatically set by the calculation unit including the control unit 19 and the adjustment calculation processing unit 13. However, for example, the contents of the color channel color correction LUT (color channel table) 17b are displayed on the display unit 15, and the contents can be arbitrarily changed by the second setting means 15b as necessary. It does not matter.
[0129]
In such a case, it is preferable that, for example, a screen including the color channel color correction LUT data of one channel, for example, channel 1 and the numeric keypad be displayed on the display unit 15 as the color correction setting screen. The numerical values of the color channel color correction LUT data are standard values in a default state. On this screen, the user selects a specific output condition, whether solid adjustment is possible, or the like, and displays a desired channel. Further, in the channel, desired reference colors Y to W or other reference colors may be selected, and the intensity composition values of the lasers R, G, and IR corresponding thereto may be adjusted and changed.
[0130]
By the way, since the color tone of Y, M, C, K of the target, which is the final printed matter, differs depending on the type of ink and paper used for printing, the intensity composition of lasers R, G, IR corresponding to the reference colors Y to W. Is preferably set according to the type of ink or paper used for printing. Therefore, as in the case of responding to the difference in the output conditions described above, there are several reference measurement tables (reference density tables), the reference measurement tables (reference density tables), and the ink and paper used for printing. A sensitivity index table prepared by associating a sensitivity index for correcting an error with each of the plurality of measurement tables corresponding to the type and the like is prepared, and, for example, a seventh setting unit 15g of the display unit 15, Alternatively, by inputting the type of ink or paper used for printing in the operation unit 16, automatically using the reference measurement table and sensitivity index table to correspond to those printing conditions. It is preferable to configure so that a measurement table (correction density table) is created. Alternatively, it is preferable that a color channel (color correction) color correction LUT corresponding to those printing conditions is automatically created. This eliminates the need for detailed settings.
[0131]
Similarly, when the ground color of the printing paper is different from the ground color of the photosensitive material, the intensity compositions of the lasers R, G, and IR corresponding to the reference colors Y to W are preferably set accordingly.
[0132]
By making such settings, when creating a color proof, a color channel color correction LUT corresponding to the type of ink or paper used for printing is used. It is possible to create a color proof adapted to the ground color and the like.
[0133]
In a printing machine, a so-called dot gain occurs in which printed dots are larger than halftone dots. This dot gain also depends on the type of ink and printing paper. Therefore, it is preferable that the setting to modify the dot image data and to apply the dot gain corresponding to the dot gain at the time of printing is automatically performed according to the type of the photosensitive material.
[0134]
Further, a table is provided in which numbers having different values are sequentially assigned based on the ratio of halftone dots of each color (hereinafter referred to as halftone%), and the information of this table is correlated with the setting parameter to which the dot gain is given. It is preferable that the screen% is set automatically by the setting. According to the color code and the dot% information of this table, a color proof in which a desired dot is formed for each corresponding color separation plate is created. By easily changing the angle of the halftone dots, the number of halftone lines, and the shape of the halftone dots generated in the colored area of the color proof, the tone of the original can be reproduced well or the tone of the original can be different. Such changes can be made or even partially emphasized.
[0135]
That is, the calculation procedure control unit 13f performs the light amount value calculation processing unit 13a according to the above-described procedure of performing the calculation of the light amount value, the dot gain correction, the calibration correction, and the color correction based on the ICC profile or the ICC device link profile. It controls each part of the dot gain correction calculation processing means 13b, the calibration correction calculation processing means 13c, the ICC profile correction calculation processing means 13d, and the ICC device link profile correction calculation processing means 13e. Of course, when any of the corrections is set by the setting units 15a to 15g, the control is performed so that only the set correction is performed.
[0136]
For example, the light amount value calculation processing unit 13a calculates the light amount corresponding to the density while referring to the measurement table 17a. As described above, this light amount value is calculated based on the measured value by measuring the density of a color chart output using a specific photosensitive material corresponding to one target which is a final print. Inevitably, the density adjustment according to the form of the one target is necessarily reflected. In other words, by exposing with the light amount using the measurement table 17a, it is possible to output in a state where the deviation of the halftone dot density has been corrected corresponding to the one target.
[0137]
However, since the measurement table 17a is a table for solid adjustment corresponding to one target (for example, art paper) that is a final print, other coated paper and high-quality paper, as well as other lots, It is preferable that a plurality of measurement tables be prepared according to printing conditions such as when a target (for example, art paper) is used, when a certain type of ink is used, and when another type of ink is used. At this time, a measurement table (reference density table) serving as several references, a measurement table (reference density table) serving as those references, and printing conditions such as a type of printing paper, a lot, and a type of ink are taken into account. A sensitivity index table prepared by associating a sensitivity index for correcting an error with each of the plurality of measurement tables and preparing a table is prepared, and, for example, “coated paper, ink A” or the like is set by the seventh setting unit 15g. Is set, a corresponding sensitivity index is selected, and a corrected measurement table (corrected density table) is created using the sensitivity index and a reference measurement table (reference density table). You may comprise. Alternatively, the configuration may be such that a corresponding color channel (color correction) color correction LUT is automatically created. As a result, a halftone dot suitable for the target is output.
[0138]
Returning to FIG. 3, for example, the light quantity value calculation processing unit 13a stores the combination of each exposure amount corresponding to the halftone dot of the halftone image data of each color plane in the measurement table 17a based on the measured value of the density. The color channel LUT 17b is generated based on the exposure amount, and the exposure amount is calculated with respect to the dot image data in consideration of the solid adjustment.
[0139]
By the way, it is assumed that the state of these color channel LUTs 17b can be confirmed from the display unit 15, for example. Then, the setting can be performed by the second setting means 15b as necessary. That is, instead of creating the above-described measurement table (correction density table), each of the basic color components, Dc, Dm, and Dy obtained by measuring the density of a color chart using a specific photosensitive material. By inputting the density value using the second setting means 15b, the color channel LUT 17b corresponding to those output conditions is automatically created. For example, the extraction unit including the control unit 19 and the light amount value calculation processing unit 13a outputs the density values of the basic color components, Dc, Dm, and Dy input by the second setting unit 15a, and the color values of the colors of the color channel LUT 17b. The error is extracted by comparing with the density value of each basic color component, and the light amount value (R, G, B) corresponding to the density value of each basic color component of each color of the color channel LUT 17b based on the error. Is performed to generate a corrected color channel LUT 17b. Note that the extraction unit including the control unit 19 and the light amount calculation unit 13a corresponds to the “color / light amount table updating unit” of the present invention.
[0140]
Then, by a predetermined operation, control information relating to the exposure amount, that is, information relating to the color channel LUT 17b is transferred to the output device 20 via the transfer control unit 14, and the output device 20 is controlled based on the information relating to the color channel LUT 17b. The exposure information in the color channel table 25a of the storage unit 25 is updated.
[0141]
When performing dot gain correction, the dot gain correction arithmetic processing means 13b performs dot gain correction on the halftone image data or the light amount value. This is to correct the variation of the halftone dot area ratio according to the type of printed matter by the dot gain correction LUT 17c which defines the area ratio of halftone dots to the area ratio of printed dots. Note that, specifically, in the present embodiment, the dot gain correction LUT 17c is, for example, each of the halftone dots of K, 3C (C, M, Y) of the color chart 30a shown in FIG. %, 60% and 80%) based on the calculation result of the dot area ratio for each color of CMYK obtained by measuring the density.
[0142]
Thus, in the halftone type color proof printer, the color of each color material of CMYK is close to the printing ink color, so that the correction of the difference in the halftone dot (dot gain curve correction) is performed according to the type of printing press and the individual difference. It becomes possible.
[0143]
When performing the calibration correction, the calibration correction operation processing unit 13c performs the calibration correction on the halftone image data or the light amount value. In this method, color correction is performed by a calibration correction LUT 17d that defines a change in the color of a halftone dot according to the model of the output device.
[0144]
Further, when performing color correction based on the ICC profile, the ICC profile color correction calculation processing means 13d performs color correction on the halftone image data or the light amount value.
[0145]
On the other hand, when performing color correction using the ICC device link profile included in the CMS, the ICC device link profile color correction calculation processing unit 13d performs color correction on halftone image data or light amount values.
[0146]
Here, the profile is a conversion parameter for converting a color of a specific device (for example, a printing machine, a printer, or the like) into the above-described standard color space (L * a * b *). The profile format is being internationally standardized by an organization called ICC (International Color Consortium). The color space (L * a * b *) is a chromaticity diagram called CIELAB recommended by CIE, L * represents lightness, a * represents the degree of red or green, b * represents yellow or Represents the degree of blue.
[0147]
In addition, a color management system (hereinafter, also referred to as “CMS”) refers to a printer, such as a scanner, a printing machine, or a digital printer, which includes a plurality of printing devices (collectively referred to as “devices”). This is a function for realizing output color matching. Normally, when the same image data (for example, CMYK color data) is output by different devices (for example, printing and electrostatic copying), the colors of actually obtained output products are different. This is because the CMYK color description does not directly describe the color represented by human senses, but only describes the output signal of the device. CMYK and RGB are, so to speak, "device dependent." Color. " On the other hand, absolutely "color expressed as a human sense" is described in a standard color space (XYZ or L * a * b *) specified by the CIE (International Commission on Illumination) regardless of the device. can do. The function of the CMS is to describe in advance which colors, such as CMYK and RGB, of each device correspond to in a standard color space, by using a description data called a profile in advance (a conversion parameter used when performing color conversion. This is to obtain an output of the same color even with different devices by performing color conversion on the image while referring to the profile.
[0148]
In a color management system composed of a scanner, a printer, a personal computer, a display device, and the like, a basic ICC profile (equipment of a device) that incorporates the individual characteristics of the scanner, printer, and display device at the time of shipment from the factory. Information containing characteristics is stored in the image processing apparatus, and color matching processing is performed for the entire system.
[0149]
At this time, the calculation unit including the control unit 19 and the adjustment operation processing unit 13 is a color system corresponding to the combination of the basic colors of the output device in the color management system standardized by the ICC (International Color Consortium). Using a profile in which the values are stored, the color of a specific printing apparatus is converted into a standard color space and color adjustment is performed, and a combination of light amount values is calculated and adjusted.
[0150]
The device link profile is used as an output value for an input value of a combination of four or three basic colors for a printing machine as a color matching target so that an output device suitable for the printing machine can be obtained by an output device. One of the first profiles that defines the color system values, and the output device that reproduces the target color uses the values of the four or three basic colors as the output values for the input values of the combination of the color system values. Four colors or three as an output value with respect to an input value of a combination of four or three basic colors for output on a printing machine created based on the other defined first profile or two first profiles. This defines the value of the combination of basic colors.
[0151]
Then, the calculation unit including the control unit 19 and the adjustment calculation processing unit 13 performs adjustment by calculating a combination of light amount values while performing color adjustment based on the device link profile.
[0152]
When these various corrections are performed or the solid adjustment is performed by the light amount calculation processing unit 13a, information on the combination of light amount values is transferred to the storage unit 25 of the output device 20 via the transfer control unit 14. . Then, a color channel color correction LUT, which is a new color channel, is generated based on the information on (the combination of) the light amount values, and a process for replacing the color channel table (LUT) set by default is performed. Then, based on the new color channel table, the exposure unit 23 performs an exposure process, and thereafter performs a development process and the like to output a color proof.
[0153]
Alternatively, when the solid adjustment is performed by the light amount calculation processing unit 13a, a color channel color correction LUT 17b that is a color channel table corresponding to the reference color and that takes the solid adjustment into consideration is generated based on the information on the combination of light amounts. .
[0154]
Here, dot gain correction, calibration correction, and the like may be performed on the color channel color correction LUT 17b.
[0155]
Next, information on the color channel color correction LUT 17b is transferred to the storage unit 25 of the output device 20 via the transfer control unit 14, and is replaced with the color channel color correction LUT set by default.
[0156]
Then, based on the replaced new color channel color correction LUT 17b, the exposure unit 23 performs exposure, performs development processing and the like, and outputs a color proof.
[0157]
The settings of the various LUTs for performing the various corrections described above can be changed by the first to seventh setting units 15a to 15g. For example, with respect to the dot gain correction LUT, a dot gain curve or the like is displayed on the display unit 15. When there are a plurality of the dot gain correction LUTs, one of the curves is selected, or the curve is freely changed by selecting the curve with a mouse or the like. It is configured to enable setting of change operation such as performing. The same applies to other corrections. The display mode at this time is not particularly limited.
[0158]
(Detailed operation of the system)
An example of the overall processing procedure when adjusting the solid density in such a color proof creation system will be described with reference to FIG.
[0159]
First, in order to perform color correction of a color proof, a solid adjustment calculation process is performed (S01). In this step, a combination of each exposure value (R, G, B) corresponding to the gradation density of each basic color component of the halftone dot is extracted.
[0160]
Specifically, the color output by a specific output device 20 using a specific photosensitive material corresponding to one target which is a final print, which is necessary for the process of adjusting the solid density of the basic color. Measure the density of the chart. This color chart is specifically as shown in FIG.
[0161]
As described above, in the storage unit 17 of the image processing apparatus 10, in advance, for example, when the output device 20 is shipped, the output is performed using a specific photosensitive material corresponding to one target which is a final print. A measurement table (density) that defines a correlation between density values (Dc, Dm, Dy) and light intensity values (R, G, B) obtained by measuring solid density values of the basic colors of the color chart with a densitometer. (Dc, Dm, Dy) -light amount (R, G, B) correlation table) (reference density table) 17a is stored. In the present embodiment, K, 3C, 4C, C, Comparing the density values of the respective color components obtained by measuring the solid colors of M, Y, R, G, and B with the density values of the respective basic color components, Dc, Dm, and Dy in the measurement table 17a. Then, extract the error, and By performing a process of shifting the light amount values (R, G, B) corresponding to the density values of the respective basic color components, Dc, Dm, and Dy of the measurement table 17a based on the difference, the corrected measurement table (corrected density) Table).
[0162]
Specifically, for example, the light amount values (R, G, B) of the output device 20 are set in two stages of “H” and “L” (where H> L), and two types of color charts are output. I do. Then, the light amount values (R, G, B) corresponding to the density values of the respective basic color components, Dc, Dm, and Dy, of the measurement table 17a are expressed in a density-light amount curve as shown in FIG. For example, the measured density value D of the basic color component Dc _H1 , D _L1 (= Density value D of basic color component Dc in measurement table 17a) _HO , D _LO Error) G _H = D _HO -D _H1 , G _L = D _LO -D _L1 Is calculated. Further, at this time, the ratio of each error, that is, G _H [%] = D _HO -D _H1 / D _HO , G _L [%] = D _LO -D _L1 / D _LO Is calculated. As a result, the ratio of each error can be represented on a graph for calculating a correction value as shown in FIG. Here, in the graph shown in FIG. 10, the error G [%] from the density-light amount curve at each light amount value corresponds to the shift amount at each light amount value of the density-light amount curve shown in FIG. The sign of G [%] corresponds to each shift direction. Therefore, in this example, the shift amount of the density-light amount curve shown in FIG. 9 is calculated by calculating the average value of the error G [%] from the density-light amount curve at each light amount value in the graph shown in FIG. And the shift direction is determined, and the correction is performed. As a result, the density-light amount curve shown in FIG. 9 is shifted as a whole as shown in FIG. Incidentally, the density-light amount curve shown by the dotted line in FIG. 11 indicates the curve before shifting, that is, before performing the correction. Such a correction is performed for each of the basic color components Dc, Dm, and Dy in the measurement table 17a.
[0163]
Note that the number of color charts output to create the corrected measurement table and the method of shifting the density-light amount curve are not limited to these, and other methods may be used. good.
[0164]
Further, as described above, the density values of the respective color components obtained by measuring the solids of K, 3C, 4C, C, M, Y, R, G, and B of the color chart, respectively, and the color channel LUT 17b The error is extracted by comparing the density value of each basic color component of each color with the density value of each color, and the light amount value (R, G, B) corresponding to the density value of the color channel LUT 17b is shifted based on the error. When the corrected color channel LUT 17b is created, the correction is performed using the above-described method of shifting the density-light amount curve only by changing the target from the measurement table 17a to the color channel LUT 17b. It becomes.
[0165]
As described above, since the measurement table 17a is a solid adjustment table corresponding to one target (art paper, for example) which is the final printed matter, other coated papers and high quality papers are further required. A plurality of measurement tables are prepared according to printing conditions such as when using a target of another lot (for example, art paper), when using a certain type of ink, when using another type of ink, and the like. Is preferred. At this time, as described above, a measurement table (reference density table) serving as several references, a measurement table (reference density table) serving as the references, and printing conditions such as a type of printing paper, a lot, and a type of ink. And a sensitivity index table prepared by associating a sensitivity index for correcting an error with each of the plurality of measurement tables corresponding to the difference, and preparing a table, for example, by the seventh setting unit 15g. By setting paper, ink A, etc., a corresponding sensitivity index is selected, and a corrected measurement table (corrected density table) is obtained using the sensitivity index and a reference measurement table (reference density table). A configuration that is created may be used.
[0166]
Then, a color correction color correction LUT 17b, which is a new color channel table, is generated based on the combination of each light amount value in the corrected measurement table (corrected density table) created in this way (S02).
[0167]
Next, if the setting for performing dot gain correction has been made by the third setting means, the above-described calculation processing of dot gain correction is performed (S03). Further, when the calculation processing of the dot gain correction is completed and the setting for performing the color correction based on the ICC profile is made by the fifth setting means, the calculation processing of the color correction based on the ICC profile described above is performed. Become. Further, when the calculation processing of the color correction based on the ICC profile is completed and the setting for performing the color correction based on the ICC device link profile is performed by the sixth setting unit, the color correction based on the ICC device link profile described above is performed. Calculation processing will be performed. Then, when the calculation processing of the color correction based on the ICC device link profile ends, the calculation result by these corrections, that is, the updated color correction color correction LUT 17b is output as the target value (S04).
[0168]
Then, the updated color correction color correction LUT 17b is transferred to the output device 20, and the output device 20 performs a process for outputting a color chart (S05).
[0169]
In response, the output device 20 outputs a color chart for confirmation (S06). Then, the solid density of each color of the color chart is measured again using the densitometer (S07). At this time, in the image processing apparatus 10, a solid density value of each color is input by a PC connected to the densitometer via the RS232C or the first setting unit 15a. Then, the control unit 19 generates an error between the measured solid density of each color of the color chart and the target value of the color correction color correction LUT 17b after color correction corresponding to the color set in S04. It is determined whether or not there is (S08). Here, if an error occurs and the error is in the non-adjustable range (S08, non-adjustable NG), the control unit 19 determines that this is an abnormality of the output device 20, and performs a maintenance call. The replacement / replenishment of the developer is performed by the maintenance man, and at this time, the setting accompanying the replacement / replenishment is performed (S09). If an error occurs and the error is within the adjustable range (S08, adjustable NG), the density calibration correction is performed again (S10). Specifically, a color chart for adjusting the sensitivity index is output (S11), and the solid density of each color is measured (S12). Then, based on the density value, the above-described sensitivity index for correction is generated (S13), and the sensitivity index is updated (S14). Then, the confirmation color chart is output again (S06). Thereafter, the process proceeds to S07.
[0170]
If the solid density value of each color matches the target value in S08, the process shifts to dot gain correction (S16). As described above, the dot gain correction is to correct the variation of the area ratio of the halftone dots to be printed. Specifically, for example, each of the halftone dots K and 3C in the color chart shown in FIG. By measuring the density of a dot (for example, 20%, 40%, 60%, 80%) with a densitometer, the area ratio of the halftone dot is calculated. Here, when the area ratio of the halftone dots is within the allowable range, that is, when the dot gain determination is OK, the process proceeds to S05 without performing the density calibration correction. Here, if the area ratio of the halftone dot is out of the allowable range, that is, if the determination of the dot gain is NG, a color chart is output for LUT adjustment (S17), and further, The halftone dot density of the color chart for LUT adjustment is measured (S18), and the color correction color correction LUT is updated based on the density value (S19).
[0171]
When the photosensitive material is replaced in S05 and the lot is switched (S20), the process proceeds to S10, and the density calibration correction is performed again (S10). Thereafter, the process continues to S11.
[0172]
As described above, in the color proof creation system according to the present embodiment, even when a solid color (halftone 100%) is expressed, a color chart is output and its density is measured to measure the color chart. Since the light amount value in the table 17a and the color correction color correction LUT 17b can be corrected and calibrated, it is possible to output a color proof with a color closest to the color reproduction range of the color proof creation system, The accuracy of color matching with the target, which is the final printed matter, can be dramatically improved.
[0173]
Further, in the color proof creation system according to the present embodiment, color correction using various LUTs, such as CMS (color management system) correction, dot gain correction, and density calibration correction, can be performed. Since the density of a solid color can be adjusted according to a difference in output conditions such as a lot, a state of a developer, and an output environmental temperature, a color proof more faithful to a target can be output. Accordingly, it is possible to prevent a difference in the solid density of the final printed matter, thereby preventing an error in the proofreading operation.
[0174]
【The invention's effect】
As described above, according to the color proof creation system and the color proof creation method according to the present invention, even when a solid color (halftone 100%) is expressed, a color chart is output and the color chart is output. By measuring the density, the light amount value in the measurement table or the color correction color correction LUT can be corrected, and the density can be adjusted, so that the color proof can be made with the color closest to the color reproduction range of the color proof creation system. Can be output, and the accuracy of color matching with the target, which is the final printed matter, can be dramatically improved.
[0175]
According to the color proof creation system and the color proof creation method of the present invention, color correction using various LUTs such as CMS (color management system) correction, dot gain correction, and density calibration correction is added. It is possible to adjust the solid color density according to the output conditions such as the lot of photosensitive material, the state of the developer, the output environment temperature, etc., so that the color matching accuracy with the target which is the final printed matter can be improved. It can be dramatically improved. Accordingly, it is possible to prevent a difference in the solid density of the final printed matter, thereby preventing an error in the proofreading operation.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing an overall configuration in an embodiment of a color proof creating system according to the present invention.
FIG. 2 is a functional block diagram showing a configuration of an image processing device and an output device in the color proof creating system shown in FIG.
FIG. 3 is a functional block diagram illustrating a detailed configuration of the image processing apparatus illustrated in FIG. 2;
FIG. 4 is an explanatory diagram showing a process in which a measurement table (correction density table) corresponding to a color print is created using a reference measurement table (reference density table) and a sensitivity index table.
FIG. 5 is an explanatory diagram showing an example of a structure of a measurement table.
FIG. 6 is an explanatory diagram illustrating an example of a configuration of a color chart.
FIG. 7 is an explanatory diagram showing an example of the structure of a color channel table.
FIG. 8 is a flowchart illustrating an example of a solid density adjustment processing procedure in the color proof creating system illustrated in FIG. 1;
FIG. 9 is a diagram showing a density-light amount curve in which the relationship between the density value of each basic color component and the light amount value in the measurement table is represented by a curve.
10 is an explanatory diagram for explaining a process of calculating a shift amount for correcting the density-light amount curve shown in FIG.
11 is a diagram showing a density-light amount curve after correcting the density-light amount curve shown in FIG. 9;
[Explanation of symbols]
10 Image processing device
13 Adjustment calculation processing unit
13a Light amount calculation processing means
13b Dot gain correction arithmetic processing means
13c Calibration correction calculation processing means
13d ICC profile color correction calculation processing means
13e ICC device link profile color correction calculation processing means
13f operation procedure control means
15 Display
15a First setting means
15b Second setting means
15c Third setting means
15d Fourth setting means
15e Fifth setting means
15f sixth setting means
15g Seventh setting means
17 Memory
17a Measurement table (density-light quantity correlation table)
17b Color channel color correction LUT
17c Dot gain correction LUT
17d Calibration correction LUT
17e ICC profile color correction information storage means
17f ICC device link profile color correction information storage means
19 Control part

Claims (10)

An image processing apparatus that creates halftone image data of each color by performing color separation on image data composed of a plurality of colors;
A halftone image based on the halftone image data of each color transmitted from the image processing apparatus, by emitting light of different wavelengths from a plurality of light sources and exposing the photosensitive material at a predetermined light amount, as a color proof An output device for outputting, a color proof creation system including:
The image processing device includes:
Of the halftone dots constituting the halftone image of each color, the density values of the respective color components of the respective colors when at least the ratio of the halftone dots is 100%, and the plurality of halftone images corresponding to the density values of the respective color components of the respective colors. Density / light quantity table storage means for storing a density / light quantity table in which light quantity values of light to be emitted from each of the light sources are associated with each other;
By referring to the density / light amount table, each of the plurality of light sources should emit light when outputting at least a portion of the halftone dot image of each color having a halftone dot ratio of 100% in the output device. Density / light value calculating means for determining a light amount value of light and outputting the predetermined light amount value;
The density value of each color component obtained by measuring the density of at least a portion where the ratio of the halftone dots is 100% among the halftone dots constituting the halftone image of each color of the color chart output by the output device. Density value input means for inputting
Based on the density value of each color component input by the density value input means, the density value of each color component of each color constituting the density / light amount table, and the plurality of color values corresponding to the density values of each color component of each color. A color proof creating system, comprising: a density / light amount table updating unit that updates a light amount value of light to be emitted from each of the light sources. The density / light amount table updating means includes a density value of each color component of each color constituting the density / light amount table and a color component of each color based on the density value of each color component inputted by the density value input means. By interpolating the light amount value of the light to be emitted from each of the plurality of light sources corresponding to the respective density values, each of the plurality of light sources corresponding to the density values of the respective color components input by the density value input means. The color proof creating system according to claim 1, wherein a light amount value of light to be emitted from the color proof is calculated. The density / light amount table storage means further stores a density value of each color component of each color in a portion where the ratio of halftone dots constituting the halftone image data of each color is not 100%, and a density value of each color component of each color. Storing a density / light quantity table in which light quantity values of light to be emitted from each of the plurality of light sources are associated;
The density / light amount calculation unit may further refer to the density / light amount table to output a portion of the halftone dot image of each color that is not 100% in the output device. Determine a light amount value of light to be emitted from each of the plurality of light sources, output as the predetermined light amount value,
The density value input unit further inputs a density value of each color component obtained by measuring a density of a portion where the ratio of the halftone dots constituting the halftone image of each color constituting the color chart is not 100%. Means to
The density / light amount table updating means includes a density value of each color component of each color constituting the density / light amount table and a color component of each color based on the density value of each color component inputted by the density value input means. 3. The color proof creating system according to claim 1, wherein a light amount value of light to be emitted from each of the plurality of light sources corresponding to the density value is updated. An image processing apparatus that creates halftone image data of each color by performing color separation on image data composed of a plurality of colors;
A halftone image based on the halftone image data of each color transmitted from the image processing apparatus, by emitting light of different wavelengths from a plurality of light sources and exposing the photosensitive material at a predetermined light amount, as a color proof An output device for outputting, a color proof creation system including:
The image processing device includes:
Corresponds to the identification information of each color and the density value of each color component, and the density value of each color component of each color when at least 100% of the halftone dots constituting the halftone image of each color are 100%. Color / light quantity table storage means for storing a color / light quantity table in which light quantity values of light to be emitted from each of the plurality of light sources are associated with each other;
By referring to the color / light amount table, each of the plurality of light sources should emit light when the output device outputs at least a portion of the halftone dot image of each color having a halftone dot ratio of 100% in the output device. Color / light amount calculating means for determining a light amount value of light and outputting the light amount value as the predetermined light amount value;
The density value of each color component obtained by measuring the density of at least a portion where the ratio of the halftone dots is 100% among the halftone dots constituting the halftone image of each color of the color chart output by the output device. Density value input means for inputting
Based on the density values of the respective color components input by the density value input means, the density values of the respective color components of the respective colors constituting the color / light amount table and the plurality of the plurality of color values corresponding to the respective density values of the respective color components of the respective colors are included. A color proof creating system comprising: a color / light amount table updating unit that updates a light amount value of light to be emitted from each of the light sources. The color / light quantity table updating means includes a density value of each color component of each color constituting the color / light quantity table and a color component of each color based on the density value of each color component inputted by the density value input means. By interpolating the light amount value of the light to be emitted from each of the plurality of light sources corresponding to the respective density values, each of the plurality of light sources corresponding to the density values of the respective color components input by the density value input means. 5. The color proof creating system according to claim 4, wherein a light amount value of light to be emitted from the color proof is calculated. The color / light amount table storage means further stores a density value of each color component of each color in a portion where the ratio of halftone dots constituting the halftone image data of each color is not 100%, and a density value of each color component of each color. Storing a color / light quantity table in which light quantity values of light to be emitted from each of the plurality of light sources are associated;
The color / light amount calculation unit may further refer to the color / light amount table to output a portion of the halftone dot image of each color where the halftone dot ratio is not 100% in the output device. Determine a light amount value of light to be emitted from each of the plurality of light sources, output as the predetermined light amount value,
The density value input unit further inputs a density value of each color component obtained by measuring a density of a portion where the ratio of the halftone dots constituting the halftone image of each color constituting the color chart is not 100%. Means to
The color / light quantity table updating means includes a density value of each color component of each color constituting the color / light quantity table and a color component of each color based on the density value of each color component inputted by the density value input means. 6. The color proof creating system according to claim 4, wherein a light amount value of light to be emitted from each of the plurality of light sources corresponding to the density value is updated. In the image processing apparatus, by performing color separation on image data composed of a plurality of colors, halftone image data of each color is created, and density values of each color component according to a ratio of halftone dots forming the halftone image of each color. A halftone image of each color by referring to a density / light quantity table in which the light quantity values of light to be emitted from each of the plurality of light sources of the output apparatus corresponding to the density values of the color components are referred to. When determining the light amount value of light to be emitted from each of the plurality of light sources when outputting at,
In the output device, a halftone image based on the halftone image data of each color emits light of different wavelengths from each of the plurality of light sources according to a light amount value of light to be emitted from each of the plurality of light sources. A color proof creating method of outputting as a color proof by exposing
In the image processing device, the density of each color component obtained by measuring the density of at least a portion where the ratio of the halftone dots is 100% in the halftone image of each color of the color chart output by the output device. Entering a value;
In the image processing apparatus, based on the input density values of the respective color components, the density / light amount table held in the image processing apparatus is configured. Of the halftone dots forming the halftone image of each color, The density value of each color component of each color and the light amount value of light to be emitted from each of the plurality of light sources corresponding to the density value of each color component of each color when at least the ratio of the halftone dots is 100%. Updating the color proof. The step of updating the density / light amount table includes, based on the density value of each color component of each color input to the image processing apparatus, the density value of each color component of each color constituting the density / light amount table, By performing an interpolation calculation of the light amount values of the light to be emitted from each of the plurality of light sources corresponding to the density values of the respective color components, the plurality of light sources corresponding to the density values of the respective color components input by the density value input means are obtained. The method according to claim 7, further comprising calculating a light amount value of light to be emitted from each of the light sources. In the image processing device, by separating the image data of a plurality of colors, halftone image data of each color is created, and identification information of each color according to a ratio of halftone dots constituting the halftone image of each color. And a color / light quantity table in which the density value of each color component is associated with the light quantity value of light to be emitted from each of the plurality of light sources of the output device corresponding to the density value of each color component, with reference to the color / light quantity table. When the point image is output from the output device, the light amount value of light to be emitted from each of the plurality of light sources is determined,
In the output device, a halftone image based on the halftone image data of each color emits light of different wavelengths from each of the plurality of light sources according to a light amount value of light to be emitted from each of the plurality of light sources. A color proof creating method of outputting as a color proof by exposing
In the image processing device, the density of each color component obtained by measuring the density of at least a portion where the ratio of the halftone dots is 100% in the halftone image of each color of the color chart output by the output device. Entering a value;
In the image processing apparatus, based on the input density values of the respective color components, at least the ratio of the halftone dots among the halftone dots constituting the halftone image of each color constituting the color / light amount table is 100. Updating the density value of each color component of each color, and the light amount value of light to be emitted from each of the plurality of light sources corresponding to the density value of each color component of each color, when the percentage is a percentage. A color proof creation method characterized by the following. The step of updating the color / light amount table includes, based on a density value of each color component of each color input to the image processing apparatus, a density value of each color component of each color constituting the color / light amount table, By performing an interpolation calculation of the light amount values of the light to be emitted from each of the plurality of light sources corresponding to the density values of the respective color components, the plurality of light sources corresponding to the density values of the respective color components input by the density value input means are obtained. The method according to claim 9, further comprising calculating a light amount value of light to be emitted from each of the light sources.

Images