JP2543146B2 - Color correction data calculator - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color correction data calculation device for obtaining a color reproduction from a color original.

2. Description of the Related Art Conventionally, in a color correction device, a method using a table memory is often used. For example, it is described in JP-A-61-257071 or JP-A-62-1368. Various modifications can be considered for these devices depending on the purpose, but when roughly classified, one table memory is allocated for each CMYK (cyan, magenta, yellow, black) to simplify the hardware and the table memory. Is used as a part of the arithmetic circuit to form a high-precision color correction arithmetic circuit. However, all the data written in the table memory is obtained by a color masking operation.

Problems to be Solved by the Invention Since color masking is used as a method in the conventional color correction data calculation method, (1) color correction cannot sufficiently correspond to the non-linear characteristic of a color printer, and its drawbacks are Even if non-linear masking using a high-order polynomial is used to compensate, this time it is too adaptive to color samples and produces a disturbed result for inputs outside the color samples. (2) The color masking matrix has a fixed evaluation. Since it is obtained as an average optimum solution in the color sample based on the standard, there is a problem that it is not easy to deal with the improvement of the local color reproduction effect in the color space that often appears in human demand. In order to obtain a vivid color reproduction that is more saturated than the original, the data for drawing the table is converted into a color development system, for example, L ^* a ^* b ^* space by chromaticity coordinate conversion, and then the saturation is obtained. , A complex mathematical procedure such as increasing Ca ^* b and inversion is required.

In view of the above problems, the present invention is capable of exhibiting a highly accurate color correction effect flexibly corresponding to the non-linear characteristic of a color printer in the color correction data calculation method, and at the same time, achieving a local color correction effect in a color space. It makes it easy to improve. Further, the color reproduction with increased saturation can be performed by only changing a part of the above-mentioned color correction data calculation without performing complicated mathematical processing.

Means for Solving the Problems The color correction data calculation device of the present invention reads three color density signals Dr (red density), Dg (green density), and Db by a color scanner when a color original is read and a color reproduction is made. Color correction processing for generating color printer drive signals C (cyan), M (magenta), Y (yellow), and K (black) from (blue density) converts the three color density signals into the color printer drive signals. For a color correction device having four table memories and data selection means capable of selecting data in the table memory, a color patch including CMY3 color signals for calculating data in the table memory of the color correction device A data generator, a black signal generator that generates K from a set of CMY, and a set of C, M, Y, and K, and is used in a color reproduction system where the color correction device will be used. A color printer and a color scanner, an input grid point density data creation unit that creates all combinations of input grid point density data to be input to the color correction system, and a density space for each of the input grid point density data. At the minimum distance to find the color patch read signal, and create a color correction table in association with the data CMY used to draw that color; And a table memory address conversion unit that converts the color correction table in the address order of the table memory.

Action The present invention has the above-described configuration, and since the conversion from the document color densities Dr, Dg, and Db to the color printer drive signals C, M, Y, and K is not based on a polynomial such as color masking, Therefore, it can flexibly respond to the non-linear characteristics of the printer, and exhibits a highly accurate color correction effect. In addition, by measuring a large number of color samples near the color existing in a specific local area in the color space, it is easy to improve the local color correction effect in the color space of the reproduced color in the vicinity. Can provide calculations. Further, it is possible to easily obtain a color reproduction with increased saturation without complicated chromaticity coordinate conversion.

Examples Hereinafter, the concept of the present invention will be described first.

The color correction device used in the color correction data calculation device of the present invention is a combination of Dr, Dg, Db of the original colors separated into three colors by the color scanner provided in the device for obtaining the color reproduction, The color correction data C, M, Y, K, which are written in advance as address signals to the four table memories, are output from the table memories to drive the color printer.

 Next, a color correction data calculation device according to an embodiment of the present invention
I will describe. The basic color correction is the color shown in Fig. 2 (a).
In the model of Fig. 2 (b) in which the replication system is rewritten into a loop
Given. NowXDrive the color printer with the signal
Then, the recorded color chart is separated into three colors with a color scanner.
Signal , Input to the color correction systemD, Color printer
And a recording / playback system including the characteristics of the color scanner.
Let Φ be the arithmetic.X, ,DThat can be taken by the system
Figure 3 shows the set X, D created by collecting the matching number.
, Φ corresponds to the map φ = X →, and is the collection by the map φ.
It is an image of Go X. Color correction system is inverse map φ⁻= D → X is realized
To obtain this inverse mapping, the elements of D (D)
For all X elements (X) Is obtained from the actual measurement of the color chart φ
⁻By directly making a table, the color correction data is calculated.
You can get out.

As can be seen from this calculation method, the conversion from the density D (Dr, Dg, Db), which is the input to the color correction system, to X (C, M, Y, K (C, M, Y)) is like color masking. Since it is not based on a polynomial equation, it is possible to flexibly deal with the non-linear characteristic of the printer regardless of the order or the number of terms, and a rational solution can be achieved even for inputs outside the color sample without being restricted by the mathematical formula. In addition, by measuring a large number of color samples near the color existing in a specific local area in the color space, it is possible to improve the color reproduction accuracy in the vicinity as much as possible, so it is necessary to improve the local image quality in the color space. Can also handle. Also, if you measure the color sample made with the full black method and reproduce it with the full black method, it is possible to reproduce the color close to the original, but dare to reproduce the color with the skeleton black method to obtain a more vivid reproduced color. available.

Hereinafter, a color correction device used in the color correction data calculation device according to a specific embodiment of the present invention will be described with reference to FIG. In FIG. 1, 1 to 3 are three color separation digital signals of the color scanner, which are converted into density signals Dr, Dg and Db by logarithmic conversion table memories 4 to 6. Up to this point, data has been processed with 8-bit signals, but only the upper 5 bits are used for input of color correction processing.
It is inputted to the color correction table memories 10 to 13. And 7
The contents of the table memories 10 to 13 are read out by the combination of the signals 9 to 9 and the color correction signals 16 to 19 are output to the color printer (not shown). Color correction table selection means 14
Allows switching of up to two types of color correction data in the color correction table memories 10 to 13, and can substantially have another side of the color correction table memory.

Next, calculation of color correction data and calculation of color correction data for performing color reproduction with increased saturation will be described with reference to FIG. In the following, "color patch" refers to a color chart.

FIG. 4 (a) is a block connection diagram of the color correction data calculation device in one embodiment of the present invention, and FIG. 4 (b) is an operation flowchart of the same device.

In FIG. 4 (a), 41 is a color patch data creation unit consisting of CMY3 color signals for calculating the data of the table memory used in the color correction apparatus of FIG. 1, and 42 is a black K from a set of CMY by a certain method. To generate a set of C, M, Y and K to generate a black signal generator, 43 and 44 are color printers and color scanners used in a color reproduction system where a color correction device is to be used, and 45 is a color printer. An input grid point density data creation unit that creates all combinations of density data to be input to the correction system, 46 searches for color patch read signals located at the minimum distance in the density space for each input grid point data. The correspondence calculation unit for associating the color CMY with the data CMY used to draw the color, 47 is a smoothing processing unit for three-dimensionally smoothing the color correction table, and 48 is a table for this color correction table. A table memory address conversion unit for converting in the order of the address of the memory, and a data storage unit 49 for storing the intermediate result and the final result in each of the above processes.

The operation of the above configuration will be described below with reference to the operation flowchart of FIG.

(A) The CMY color patch data creation unit 41 creates a file of color patch data signals that covers all the dynamic lenses of the drive signals of the color printer 43 used. Eight levels of area ratio C (cyan), M (magenta),
Data of 512 colors obtained by combining three colors of Y (yellow) is used as a basic color patch 50.

In addition to the basic color patch, the color patch 50 has a great effect when it is created for colors that are particularly important in the reproduced image. For example, it is an achromatic grayscale color patch for improving gray reproduction, or a light color patch for improving color reproduction of each hue near the highlight.

In designing the color patch 50, the colors are arranged in an orderly manner in accordance with the color number fi for the convenience of later reading. Since each color of the color in the CMY color patch data creation unit 41 patch is managed by the color number fi, previously obtained color signal values X fi from fi (C, M, Y) the calculation formula so can determine ( However, fi = 0 to fimax-1) (B) When the printer 43 reproduces three colors, the printer is driven by three color signals of C, M, and Y. However, since four color reproduction is assumed here, CMY From the values, K (black) is generated by the black generation unit 42 by the method of full black or skeleton black, and color patch data is generated as four color signals of C, M, Y and K.

(C) The created color patch data file is output to the printer 43 and the color patch 50 is drawn. Since the drawing method is included in the characteristics of each printer, any method may be used as long as it is the same at the time of color patch drawing and color reproduction.

(D) The color patch 50 is separated into three colors by using the color scanner 44 which is the original image input unit, and the RGB data is loaded into the data storage unit 49. When reading a hard copy represented by dither digitally, it is necessary to defocus the optical system in order to prevent moire.

This process can also be done indirectly by reading with a colorimeter. In that case, the relationship between the RGB value read by the color scanner and the XYZ value of the colorimeter is measured in advance and converted by matrix calculation or the like.

(E) The input grid point density data creation unit 45 converts the captured RGB data (reflectance) of the scanner 44 into Dr, Dg, Db data (density) to create a color patch read density data file. This data Express. (However, fi = 0 to fimax-1) (F) D, which is the input in the color correction table to be obtained
Create r, Dg, Db concentration data. This shows discrete grid point coordinates (input grid point data) in the three-dimensional density space, and a color correction table is constructed by associating a color correction signal with each grid point. Each input grid point has a number il and this total is equal to the total number of input combinations in the color correction table. For example, to make a color correction table for each of 32 gradations of density Dr, Dg, Db, the total number is 32 × 32 ×
32 = 32768 pieces. The resulting data D il = (Dril,
Expressed as Dgil, Dbil). (However, il = 0 to 32767) (G) For each Dil created, fi is 0 to fimax-
Scan up to 1, Let fil be fi that minimizes Bind X fil to D il via.

 This operation is called "association".

The groups of are distributed roughly and non-uniformly in the density space by being limited by the number of color charts. Therefore, it is unlikely that the input grid points will be spatially regular and uniform, and the matching based on the minimum distance was adopted.

Also At the same time is a very limited area in the density space due to the gamut of the printer ink. Of course, it is also necessary to properly associate input grid points outside the reproduction area, but at this time the minimum distance algorithm above works effectively, and the position on the surface of the reproduction area is located as the point at the minimum distance in the density space. The color to be selected is selected. This is rational in that it reproduces at the limit of the printer reproduction color for input outside the printer reproduction range.

(H) The color correction table obtained as a result of correspondence has output colors (a subset of Xfi) of at most (512) colors of the color patch 50, and the input colors and the output colors are many-to-one. Become.
This is a state where the reproduced color is "degenerated" due to the limitation of the number of color patches. The phenomenon is that there is no color continuity and the gradation is discontinuous.

Since this cannot be used for color correction of a natural image, the smoothing processing unit 47 interpolates by smoothing the table to realize smooth gradation. In this smoothing, averaging is performed in a 3 × 3 × 3 region near the input grid point in the density space,
Performed for each component of the printer drive signal C, M, Y. For example, for C, And

(However, 0 ≦ Dr ≦ 31, 0 ≦ Dg ≦ 31, 0 ≦ Db ≦ 31) The above processing completes the color correction table.

(1) At this point, the color correction table is processed as described above (E).
Since the (C, M, Y) signal is attached to the input grid point data Dil of, the K signal is generated by the same method as that adopted in (1), and the (C, M, Y) signal is generated again. , K (C, M, Y)) color correction table.

In some cases, it may be preferable for human beings to perform color reproduction with slightly increased saturation without intentionally performing correct color reproduction. As a simple realization method, the K generation amount performed here is made smaller than the K generation amount used in the processing (B). For example, the full black method may be adopted in (B) and the skeleton black method may be adopted in (I).

(J) Combining another color correction table etc. that fits in the other side in the table memory together, add addresses and add each C, M, Y,
Create complete data for programming K table memory.

(K) The color correction table memory is completed by programming the data created for each C, M, Y, K table memory.

In the above embodiment, the number of input bits of the table memory, the number of input grid points to the color correction table, the number of color patch colors, etc., are not deterministic.

EFFECTS OF THE INVENTION As described above, according to the present invention, it is possible to flexibly deal with the linearity characteristic of a color printer and to exhibit a highly accurate color correction effect, and at the same time improve a local color correction effect in a color space of reproduced colors. It is possible to provide an easy color correction data calculation, and it is possible to easily obtain a color reproduction with increased saturation without complicated chromaticity coordinate exchange.

[Brief description of drawings]

FIG. 1 is a block connection diagram of a color correction device used in a color correction data calculation device in one embodiment of the present invention, FIG. 2 is a conceptual diagram showing a basic concept of color correction, and FIG. 3 is a principle of the present invention. FIG. 4 (a) and FIG. 4 (b) are a block connection diagram and an operation flowchart of the color correction data calculation device in one embodiment of the present invention. 1 to 3 ... 3 color separation digital signals output from the color scanner, 4 to 6 ... logarithmic conversion table for density conversion,
7 to 9 ... upper 5 bit density signal, 10 to 13 ... color correction table memory, 14 ... color correction table selection means, 15 ...
Color correction table selection signal, 16 to 19 ... Color correction signal.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Hidehiko Kawakami, 3-10-10 Higashisanda, Tama-ku, Kawasaki City, Kanagawa Prefecture Matsushita Giken Co., Ltd. Matsushita Giken Co., Ltd. (56) References JP-A-61-257071 (JP, A) JP-A-62-47273 (JP, A) JP-A-63-254864 (JP, A)

Claims (2)

(57) [Claims] 1. A color printer drive signal C (cyan) from three color density signals Dr (red density), Dg (green density), Db (blue density) by a color scanner when a color original is read to make a color reproduction. ), M (magenta), Y (yellow), and K (black).
Converting the color density signal into the color printer drive signal 4
Color patch data composed of CMY3 color signals for calculating the data in the table memory of the color correction device, for a color correction device having a number of table memories and data selection means capable of selecting data in the table memory A color printer used in a color reproduction system in which the color correction device is to be used, and a black signal generation unit that generates a K, C, M, Y, K set from a CMY set and a creation unit. And a color scanner, an input grid point density data creation unit for creating all combinations of input grid point density data to be input to the color correction system, and a minimum in the density space for each of the input grid point density data. A correspondence calculation unit that finds a color patch read signal located at a distance and creates a color correction table in association with the data CMY used to draw that color; A smoothing unit for smoothing the positive table in three dimensions, color correction data calculation apparatus comprising a table memory address translation unit for converting the color correction table in the address order of the table memory. 2. The color correction data calculation device according to claim 1, wherein the generation amount of the black signal when creating the table memory is smaller than the generation amount of the black signal when creating the color chart.