JPS58220566A - Operating device for color correction - Google Patents

Abstract

PURPOSE:To realize an operation of high accuracy and high speed, by constituting so that a condition for various color correct-processings can be set and read out optionally by an external computer, and executing all the color correct- processing by a digital operation. CONSTITUTION:A titled device is provided with a data separating circuit 103 for separating a data to each separate color from a color separating signal obtained by color-separating a color picture, a tone correcting circuit 105 for executing the conversion of a tone characteristic of each separated color signal, correction of brightness of a highlight/shadow part, etc., a base color eliminating and ink printing generating circuit 108 for generating an ink printing signal, also subtracting a grey component from a trichromatic signal and converting it to a four color printing signal, a color correcting circuit 117 for executing a non- linear correction for a chromaticity reproduction, and a parameter controlling circuit 102 for executing the write and read-out of a parameter for a desired processing condition to and from said each processing circuit. Also, a color correcting condition is set optionally from an external computer by constituting so that a parameter controlling circuit is controlled freely by the external computer connected through an interface 101.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides three primary color input signals (hereinafter C, M) obtained by color separation of a color image original.
, Y) for obtaining color-corrected color image data.

Generally, when a color image is reproduced from three primary color input signals obtained by color-separating a color image original, the reproduced image, especially the tone, is often different from the color image original.

For example, this tendency is strong when printing is performed by producing separated plates for each color from color separation signals, or when a color image is directly reproduced on recording paper as in an inkjet recording apparatus.

In general color printing, a color image original is color-separated to create four-color separation plates of C, M, Y, and black (hereinafter referred to as B), and then a practical version is created, and the practical version is sent to the printing machine. Color printing is carried out by overprinting as many times as there are practical versions. .

As mentioned above, when color separation signals are obtained from a color image original and printed in color without correction or processing, the color tone is poor and unsatisfactory, so it is necessary to obtain a reproduced image with color correction. In addition, work is carried out to correct the four-color separation plate before final printing. In addition, although color correction processing has recently begun to be performed electronically, there is still an analog data processing part, which poses problems in terms of stability, accuracy, and color correction processing time due to temperature changes, etc. have.

The present invention has been made in view of the above drawbacks, and allows conditions for various color correction processes to be arbitrarily set and read by an external computer, and all color correction processes are performed using digital calculations to achieve high precision, This is to achieve high speed. Furthermore, each processing section has a feature that it can be selectively processed by an external computer.

Embodiments of the present invention will be described below with reference to the drawings.

First, before processing, the interface 1 is
The selection of processing conditions f±, ', l', and %I operation in each processing circuit and the parameters of the control code are transferred to the parameter sterilization circuit 102 via 01. The parameter control circuit 102 decodes the type of parameter from the control code, sets it in a predetermined processing section, or reads the parameter from the processing section. Next, explanation will be given along with the flow of actual image data.

A series of image data sent from an external computer via an interface 101 is sent to a data separation circuit 103 for each pixel, and is then processed for each picture element by subtractive color mixture or additive color mixture three primary color signals or four color printing signals (B, C, M).

Separate Y) into each color. As for the format of the input image data, either a three-color signal mode or a four-color signal mode is set in advance on the control line 104 via the parameter control circuit 102 described above. When the input image data format is a three-color signal mode, the data separation circuit 103 separates and outputs each color of C, M, Y (or R, G, B), and inputs it to the tone correction circuit 105. Tone correction circuit 105
Converts the gradation characteristics of the color signal and corrects the brightness of the light/shadow areas for each color independently (However, if the input signals are R, G, and B, reflectance/density conversion is performed at the same time.) ). The tone correction curve is set in advance in a random access memory independent of each color from the parameter read/set line 106 through the parameter control circuit 102, and the tone correction process is performed using a table reference method, using the three color input values as address information. Reading and correction output are obtained.

However, the input signal is the three primary color signals 3G and B in additive color mixture.
In this case, the tone correction curve is set as a curve that simultaneously performs reflectance/density conversion, that is, log conversion characteristics. Further, control as to whether or not to perform tone correction processing is specified by the parameter control circuit 102 using a control line 107. Next, the three-color output signals after tone correction are input to the undercolor removal/black plate generation circuit 1o8, and the three-color signals (C, M, Y) are converted into four-color print signals (B, C, M, Y). Convert to In general printing, it is used to compensate for insufficient gradation and density from midtones to shadow areas (dark areas), or to prevent problems such as poor ink trussoping caused by poor ink overlapping during high-speed multicolor printing. Therefore, undercolor removal processing is performed to reduce the amount corresponding to the gray component from the three-color version and replace the gray component amount with the black version. In the embodiment of the present invention, the threshold value required for the undercolor removal process and the black plate gain to be multiplied to compensate for the lack of density of the black plate ink are obtained from an external computer through the parameter reading/setting line 109.
It has a configuration that can be set/read arbitrarily. The operation of the under color removal/black plate generation circuit 108 is to first extract the minimum value from the input three color signals (C, M, Y), generate a black plate only when the value is equal to or higher than the above-mentioned threshold value, and generate a black plate for the three colors. Subtract the black plate amount from the input value and output.

On the other hand, in order to correct the density of the black ink, the generated black plate amount is multiplied by the black plate weight and output. Further, the configuration is such that a control line 110 can be used to select whether or not to perform undercolor removal processing, and a control line 111 can be used to select whether or not to brighten the black plate signal. Furthermore, if the series of image data format sent from the outside is in a four-color print signal (B, C, M, Y) mode, the data separation circuit 103 separates the image data into data for each color, and The plate signal B is passed through the signal line 112.
2 selection circuit 113. Black version signal is selection circuit 1
13, the black plate signal from the data separation circuit 103 and the black plate signal 11 generated by the undercolor removal/black plate generation circuit 108
4 is selected and output by the control line 11φ and the control line 116. Simultaneously undercolor removal/black plate generation circuit 10
The C, M, and Y three color signals from 8 are input to a color correction circuit 117, where unnecessary components (cloudiness) of the printing ink are removed and nonlinearity correction on chromaticity reproduction in mixed recording is performed. The color correction circuit 117 performs independent multiplication for each color, and reads out the conversion value set in advance as a conversion coefficient from the outside from the memory using a table reference method, while reading out the color correction coefficient multiplied by each function from another memory, and performs cumulative multiplication. Polynomial operations are realized in time series. Function values and color correction coefficients are calculated by an external computer using interface 1.
01. It is possible to arbitrarily read/set the parameters from the parameter read/set line 118 via the parameter control circuit 102. Also, whether or not to perform color correction processing is determined in advance by a control line.

119. C, M mentioned by MfJ.

111 What is the color correction output signal for Y3 colors? Together with the black plate output signal from the 1' selection circuit 113, it is used as an independent line pant for each color, and arbitrary color data can be read from the memory for each color. The output data format from the line buffer circuit 120 is a pixel sequential mode in which B, C, M, and Y are continuously transferred per pixel, which is the same format as the four-color input signal in the data separation circuit 103, and a designated color only mode. It is configured so that it can be used by selecting from two types of color sequential modes in which images are transferred continuously. Well, the color correction output result is written from an arbitrary address of the RAM that constitutes the line buffer circuit 120,
Further, it is configured to read and output image data from an arbitrary address. The starting address of image data input/output in the line buffer circuit 120 can be arbitrarily read and set by an external computer via the interface 101, the parameter control circuit 102, and the parameter read/set line 121. Furthermore, the above-mentioned output data format is the control line 1,,l! 2 specifies the data structure, and the number of bits for each color of the output cicada image data is specified by the control line 123.

The color correction calculation in the embodiment of the present invention described above is performed by, for example, the formula (
1) to (3).

(tone correction) (Undercolor removal/black plate generation) However, δ indicates the amount of undercolor removal, and δ≧0.

(Color correction) However, i21-3. j21~10゜glnif(Ci), g2=f(Mi), g
32f(Yi), g4=,? ”(Ci-M
i), gs2f(Mi-Yi), g6=J(Yi
”Ci), g7=f(Ci2),,!/8=f('M
i2), ¥9-f(Yl), g1o=1.

Note that Ci, Mi, and Yi are the three color input values of the color image,
(cyan, magenta, yellow, respectively) and Bi,
(5i, Mi, Yi indicate the four-color printing input value number (Bi is the black plate input signal). α indicates the threshold value for undercolor removal, β indicates the black plate gain, and ff ij is the color A correction coefficient matrix is shown. f (, z) shows a function value of the input signal X.

Bo, Co, Mo, and Yo are four-color print output signals (
Black version, cyan, magenta, yellow) are shown respectively.

In equation (3), setting ai4 to ailO=O corrects the purity of the color separation signals of the original image and converts the primary color system.

It is also possible to use it as primary masking processing to perform color tone conversion and the like.

As is clear from the above explanation, in the present invention, all the various color correction conditions can be read out and set by a computer, and even if the printing ink, recording paper, or other recording material is changed, the color correction parameters can be changed. This can be handled by setting . It also has the feature that special effects on images can be realized by arbitrarily setting parameters for color correction. Furthermore, all color correction operations are performed on the D of color image data.
In parallel with MA transfer, rear! It is also possible to process in real time, achieving high precision and high speed digital calculations.

Further, the various color correction processing circuits are connected in a pipeline, and each processing section can be selected and used according to the operation mode (selection of operation for each processing) specified by an external computer. Therefore, it goes without saying that similar processing results can be obtained even if the connection order of each processing circuit is changed arbitrarily.

As described above, according to the present invention, it is possible to selectively process large amounts of color image data under arbitrary color correction conditions and arbitrary color correction processing regardless of connection conditions.
It is possible to realize a color correction arithmetic device that can be executed with high accuracy and high speed.

FIG. 2 shows an example in which the color correction arithmetic device described in FIGS.

First, a drum 202 loaded with a color image original 201 rotates, and a color image is read by a one-color separation head 203 and converted into an analog/digital image.

After passing through a reflectance/density conversion circuit 204, the signal is input to a computer 208 via an interface 206.

The computer 208 stores the original data of the color image in the magnetic tisf device 209 .

The original data is also displayed on a color display device 212 via an interface 211 . Next, the process moves on to image color correction processing necessary for color image duplication. The computer 208 reads out the original data stored in the magnetic disk 209 and uses the color correction arithmetic unit 21 described in FIG.
3, and the color correction processing result is transferred to the line buffer circuit 12.
0 through the interface 101. The color correction processing results are stored in the edited magnetic disk device 210 after being subjected to compositing processing with other images. Most, 1:1
Finally, the image data after color correction processing is read from the edited magnetic disk device 210 and transferred to the inkjet recording device 223. The transferred color image data is
An electric circuit 226 consisting of a line buffer circuit, a dot conversion circuit, a digital/analog conversion circuit, an inkjet head drive circuit, etc. is connected via the interface 224.
The ink is applied to the inkjet head 226 for each color, and in accordance with the signal, each color ink is ejected and sent to the drum 227.
A high-quality color print is reproduced on the recording paper 228 wound on the recording paper 228. In FIG. 2, a tablet 229 is used when editing image data. - 230 is a floppy disk device, 231 is a magnetic tape device, 232.
233 are a console display device and a console keyboard, respectively. This device separates color image originals, corrects the tone of color images reproduced by inkjet recording devices, expands the reproduction density of images, sharpens images, and significantly improves the reproduction of real colors. A corrective effect can be obtained.

As described above, the present invention provides a data separation circuit that separates data for each color from color separation signals obtained by color separation of a color image, conversion of gradation characteristics of each separated color signal, and conversion of highlight/shadow parts. A tone correction circuit that performs brightness correction, etc., an undercolor removal and black plate generation circuit that generates a black plate signal, subtracts gray components from the three color signals and converts them into four color printing signals, and a black plate generation circuit that performs chromaticity reproduction. A color correction circuit that performs nonlinearity correction and a parameter control circuit that writes and reads parameters for desired processing conditions in each of the processing circuits are provided, and the parameter control circuit is freely controlled by an external computer. With the color correction calculation device, color correction conditions can be arbitrarily set from an external computer, and color correction can be performed at high speed and with high precision.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of a color correction arithmetic device according to the present invention, and FIG. 2 is a block diagram showing an embodiment of an inkjet color image duplicating device to which the color correction arithmetic device according to the present invention is applied. 101...Interface, 1o2...
... Parameter control circuit, 103 ... Color image data separation circuit, 106 ... Tone correction circuit, 1o8 ... Color fastness removal/black plate generation circuit, 11
3...Selection circuit. 117...Color correction circuit, 12o...Mark/line buffer circuit, 201...Color image original, 2
o2...Drum, 203...Color separation head, 204...Analog/digital conversion 1 reflectance/density conversion circuit, 205-=--Interface, 2o7... ...Color image M, taking device, 20
8... Benicom computer (calculator) 209, 21
0...Magnetic disk device, 211...
Interface, 212. Old... Color display device, 213... Calculation device for color correction, 223.
...Inkjet recording device, 224...
- Interface, 226... Inkjet head drive circuit, 226... Inkjet head, 227... Drum, 228...
Recording paper, 229...Taglet, 23o...
... Floppy disk device, 231 ... Magnetic tape device, 232-233 ... Console display device and console keyboard. ,
i, ::

Claims (2)

[Claims] (1) A data separation circuit that separates data for each color from the color separation signals obtained by color separation of a color image, a tone correction circuit that corrects the gradation characteristics and brightness of each separated color signal, and a An undercolor removal and black generation circuit that generates a black signal and removes the undercolor; a color correction circuit that corrects nonlinearity in chromaticity reproduction; the data separation circuit, the tone correction circuit, and the undercolor 1. A color correction arithmetic device comprising a parameter control circuit for writing and reading parameters for controlling a removal, black plate generation circuit, and color correction circuit. (2) The one-color correction arithmetic device according to claim 1, wherein writing and reading of parameters of the parameter control circuit is controlled by an external computer.