JPH02292963A - Converter for color picture signal - Google Patents

Abstract

PURPOSE:To reduce the color difference between an input color original and a color hard copy and to obtain a color hard copy faithful to the original by using a simple means which converts the luminance signal into a new signal. CONSTITUTION:A color original 1 is read by a color picture input device 2 and the density signals DS, DC and DR are converted into END signals ES, EC and ER respectively by an equivalent neutral density processing circuit 3. These END signals are inputted to a signal conversion circuit 4 for the correction of the parts that cannot be completely corrected by the linear arithmetic of a matrix arithmetic circuit 5 of the next stage. Thus the new signals FS, FC and FR are obtained. These new signals are converted into the density signals FY, FM and FC of the color material of a color hard copy via a matrix arithmetic circuit 5. Then these density signals are converted into the END signals EY, EM and EC of the coor material via a signal adverse conversion circuit 6 having the conversion characteristic adverse to that of the circuit 4. Furthermore these END signals are converted into the copy color material quantity signals Y, M and C via a tone reproduction curve processing circuit 7 and inputted to a picture output device 8. Thus the hard copy 9 is obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention is a color image signal converter for converting a color image signal read by a color image human-powered device into a coloring material m signal for obtaining a color hard copy or the like. This invention relates to a conversion device.

(Prior art) Conventionally, the density signal of an input color image DBI Da+Do+
is the density signal F corresponding to the color material m of the color hard copy.
v=F. Matrix calculations as shown in equation (1) have often been used for color correction for conversion to Fc. However, linear calculations such as equation (1) do not adequately describe the color reproduction system, and the color difference between the input color original and the color hard copy becomes large.

A nonlinear matrix operation as shown in equation (2) has been devised to reduce the color difference, but it is not used much because the scale of hardware increases.

In other conventional examples, the input color image signal is
A conversion device has been proposed that performs correction by matrix calculation using the Sth matrix coefficient, performs logarithmic transformation, and further performs correction by matrix calculation using the second matrix coefficient ai (Japanese Unexamined Patent Publication No. 82-72277). ). This conventional conversion device attempts to obtain a color hard copy that is faithful to the original by determining the first and second matrix coefficients SII+a to minimize the color difference between the input color original and the color hard copy. However, it has the disadvantage that it requires two matrix calculation circuits and the configuration is relatively complicated.

(Problems to be Solved by the Invention) An object of the present invention is to reduce the color difference between an input color original and a color hard copy using a simple configuration, and to obtain a color hard copy that is faithful to the original.

(Means for Solving Problem rA) The color image signal conversion device of the present invention is a conversion device that converts a color image signal obtained by reading a document into a signal corresponding to color material m for obtaining a color hard copy. In II1,
It has a matrix calculation means (5, 18 to 18) for color correction and a conversion characteristic set to be non-linear so that the color difference between the original and the color hard copy is minimized, and is arranged before the matrix calculation means. Input color density signal (FB, FO
, FR) (4.13-15)
is provided after the matrix calculation means, has a conversion characteristic set non-linearly so that the color difference between the original and the color hard copy is small, and has a color material density signal (FV.FM).
, FC) (6.19-21)
It is characterized by having the following.

In one aspect of the present invention, in the above configuration, the first and second converting means have mutually opposite conversion characteristics.

Further, in another aspect of the present invention, in the above configuration, the first
The conversion characteristic of the conversion means has a conversion characteristic curve (for example, see FIG. 4) in which the output value is concave with respect to the density value of the human color density signal.

Furthermore, in another aspect of the present invention, in the above configuration ~1,
It has a lookup table for END processing (26-27) and a lookup table for TRC processing (28-30), and the lookup table for END processing is
By multiplying the data for D processing by the conversion characteristic data of the first conversion means as lookup table data, the function of the first conversion means is combined, and the TRC
The processing lookup table has the function of the second conversion means by multiplying the TRC processing data by the conversion characteristics of the second conversion means as lookup table data.

(Function) The present invention has a configuration in which a first conversion means and a second conversion means are added to a conventional color image conversion device. The conversion characteristics of the first conversion means are determined in advance so that the color difference between the color original and the color hard copy is minimized, and the portions that cannot be corrected by the matrix calculation means are corrected. That is, so that the matrix calculation means can accurately convert the ROB signal of the input color image into the YMC signal corresponding to the color material m of the color hard copy, the first conversion means converts the density signal of the input color image into The signal is transformed into a new signal with higher linearity than the concentration signal, and then manually inputted to the matrix calculation means. Then, the second conversion means restores the deformation caused by the first conversion means.

Therefore, by simply adding the first and second signal conversion circuits, the color difference between the input color original and the color hard copy can be reduced, and a color hard copy faithful to the original can be obtained.

Furthermore, by multiplying the data of the lookup table for END and TRC processing by the conversion characteristics as the data of those lookup tables, the first and second conversion means can be used as the lookup table for END and TRC processing. In this embodiment, the fidelity of color correction can be improved by 4 points compared to the conventional device by simply replacing the data in the look-up table of the conventional device.

(Embodiment) FIG. 1 shows a schematic configuration of an embodiment in which the present invention is applied to a digital color copying machine.

Color original 1 into color image input device 1i! ? The color image density signal obtained by reading D.2. Do, DR are equivalent neutral concentrations (Equivalent Neutral De
nslty'+hereinafter abbreviated as E'N D) E in processing circuit 3
The ND signals E a rEa and ER are converted.

END signal Ell. Eo and ER are input to the signal conversion circuit 4 according to the present invention, and the portions that cannot be corrected by the linear calculation in the matrix calculation circuit 50 at the next stage are corrected and converted into new signals Fa, FO and FR.

The conversion characteristics of the signal conversion circuit 4 are for color originals! From the spectral reflection characteristics of the coloring materials constituting the image input device 20, the spectral sensitivity characteristics of the color image input device 20, the spectral reflection characteristics of the coloring materials used to obtain the color hard copy 9, and the output characteristics of the color image output device 8, the color original and the color hard copy are determined. It is determined to minimize the color difference between the two.

The signals Fa, Fa, F+t are processed by the matrix calculation circuit 5 as the density signal FYIFM+F0 of the color material of the color hard copy.
is converted to

Thereafter, a signal inverse conversion circuit 6 having conversion characteristics opposite to that of the signal conversion circuit 4 according to the present invention outputs the END signals EY, El of the color materials of the color hard copy. l, E0. In order to accurately convert the BGR signal of the input color image into the MMC signal corresponding to the amount of color material of the color hard copy in the matrix calculation circuit 5, the signal conversion circuit 184 converts the density signal of the input color image into the density signal. The signal is transformed into a new signal with higher linearity and input to the matrix calculation circuit 5, but the signal inverse transformation circuit 6 undoes the transformation by the signal transformation circuit 4.

Color hard copy color material END signal EV. E.M., E.
c is TRC (Tone ReproduCtio
n Curve) processing circuit 7 receives color material m signals Y, M. C, and the color image output device I2
! 8 and a color hard copy 9 is obtained.

FIG. 2 is a diagram showing in more detail the 11th to 18th section of the embodiment in FIG. 1.

The END processing circuit 3 includes lookup tables for END processing (hereinafter abbreviated as END processing LUT) 10 to 12.

The signal conversion circuit 4 includes a signal conversion lookup table (
(hereinafter abbreviated as signal conversion LUT) 13 to 15, and the END signal E. ．． E. , ER to create new signals FB, FO, F
This is to obtain R. This signal conversion LUT13-16
is the input B. This is an LUT that stores data with the same conversion characteristics common to G and R signals, and its characteristics are determined in advance so that the color difference between a color original and a color hard copy is minimized.

A method for determining the conversion characteristics will be briefly explained. The signal conversion LUT 13 is preset with suitable characteristics, for example 4.
Enter the data for the 5° straight line.

If the chromaticity value of the original 1, for example the value of a◆b- in CIE1978L, is L'1a'1b'', and the chromaticity of the color hard copy 9 is Lmin+,4+b$1, then the color difference between the two ΔE= { (L-shin'-L-)"+(a"-a
Umbrella)2+(b"-b-)2}1/2 is minimized by repeatedly changing the conversion characteristics using nonlinear optimization methods such as relaxation method and simplex method, and finally obtained The characteristic value for which the color difference between the two is the smallest is set as data for the signal conversion LUT 13. Since this determination method requires many repetitions, it is desirable to determine it in advance by simulation.

The matrix calculation circuit 5 is connected to the matrix calculation circuits 16 to 16.
7, which is expressed by the formula (1) shown above.
It is composed of 1.Rix coefficient dIJ. The matrix coefficient dl1 is based on the original END signals Ea, EO, ER and the color hard copy color material END signals E, EM, EC.
A conventional value determined by multiple regression analysis can be used. The converted signal Fe. FGIFR and color material signal Fv. of color hard copy. F. , F. Multiple regression analysis or newly calculated matrix coefficient to minimize the color difference between the original and the color hard copy
If dlJ is used I1), a hard copy with less color difference and more faithful to the original can be obtained.

The signal inverse conversion circuit 6 includes signal inverse conversion LUTs 19 to 21, which correspond to signal conversion LUTs 13 to 15 whose input and output characteristics are interchanged.

The TRC processing circuit 7 includes lookup tables 22 to 24 for TRC processing, and converts the density signal EvIEMIEc into signals fflY, M. Data to be converted to C is stored in the form of a lookup table.

According to this embodiment (first embodiment), by simply adding the first and second signal conversion circuits, the color difference between the input color original and the color hard copy can be reduced.
You can obtain a color hard copy that is faithful to the original.

A second embodiment of the invention is shown in FIG. In this embodiment, the data of the END processing LUTs 25 to 27 is the product of the characteristics of the END processing LUTIO to 12 of the first embodiment and the signal conversion LUTs 13 to 15, and the data of the inverse transformation LUTs 19 to 21 of the first embodiment is and TRC processing LUT 2 2~
TRC processing LUT2 is obtained by multiplying 24 characteristics.
By simply determining the data according to the present invention, a color hard copy that is more faithful to the original can be obtained than with the conventional method, without adding a new circuit to the conventional device. .

Figure 4 shows the matrix calculation times Illi5 determined to minimize the color difference between the color original and the color hard copy.
An example of the signal conversion characteristic curve of 18 to 18 is shown, and (
Equation 3) shows a specific example of matrix coefficients.

(3) In the CIE1976L"a"b medium color space, the color difference between the original and the hard copy is 16.0 at maximum and 3 on average using the conventional method.
．． According to the present invention, it has improved from 7 to 6.2 at maximum and 2.1 on average. Further, the signal conversion characteristic curve is generally concave with respect to the density, and this is thought to be due to the correction being made for the fact that the amount of coloring material of a color hard copy and the measured color density are not in a proportional relationship I11.

In the previous embodiment, a single curve LUT that does not depend on B, G, and R was used as the signal conversion LUT, but B. G. By using three characteristic curves tailored to the characteristics of each R, it is possible to obtain a color hard copy that is more faithful to the original.

(Effects of the Invention) The present invention reduces the color difference between an input color original and a color hard copy by providing a simple means for converting a density signal into a new signal, thereby obtaining a color hard copy that is faithful to the original. It is something that can be done.

[Brief explanation of drawings]

FIG. 1 is a block diagram schematically showing a digital color copying machine according to a first embodiment of the present invention. Figure 2 is a block diagram showing details of the main parts in Figure 1. It is a one ivy diagram. FIG. 3 is a block diagram showing the configuration of the second embodiment. FIG. 4 is a diagram showing a specific example of the signal conversion characteristic curve of the signal conversion LUT according to the present invention. 1...Color original, 2...Color mouth image input device, 3
...END processing circuit, 4...signal conversion circuit, 5...
・Matrix calculation circuit, 6... Signal inverse conversion circuit, 7
...TRC processing circuit, 8...color image output device,
9...Color hard copy @ya"txx-a-ce:

Claims (4)

[Claims] (1) In a conversion device that converts a color image signal obtained by reading a document into a signal corresponding to the amount of coloring material used to obtain a color hard copy, a matrix calculation means for color correction and a matrix calculation means provided before the matrix calculation means are provided. , which has conversion characteristics set non-linearly so that the color difference between the original and the color hard copy is small, and which converts the input color density signal.
A second conversion means is provided after the matrix calculation means and has a conversion characteristic set to be non-linear so as to reduce the color difference between the original and the color hard copy, and converts the density signal of the coloring material. A color image signal conversion device comprising: (2) The color image signal conversion device according to claim (1), wherein the first and second conversion means have conversion characteristics that are opposite to each other. (3) The conversion of a color image signal according to claim (1), wherein the conversion characteristic of the first conversion means has a conversion characteristic curve in which the output value is concave with respect to the density value of the input color density signal. Device. (4) Lookup table and TRC for END processing
The END processing lookup table has a processing lookup table, and the END processing lookup table multiplies the END processing data by the conversion characteristic data of the first conversion means as the data of the lookup table. The TRC processing lookup table also has the function of a conversion means, and the TRC processing data is multiplied by the conversion characteristics of the second conversion means as lookup table data. 2. The color image signal conversion device according to claim 1, wherein the color image signal conversion device has the following functions.