DE19646821A1 - Image data detection unit for colour printer, video device and digital camera - Google Patents

Abstract

The image detection unit uses densitometric three filter measuring units in the measurement engineering determining of the individual points, in order to computer from these pseudo colour values. The spectral colour evaluation of the densitometric three filter measuring unit, distinguishes an image original from a colorimetric evaluation. The result of this, is that in the individual regions of the colour space, different colours are not adequately distinguished from each other. Individually important image points can be selected and alteration of the spectral evaluation function, to obtain a better matching to the desired colour values.

Description

The invention relates to an image data acquisition device according to the preamble of the An saying 1.

The specified image data acquisition device is intended to be an image in individual pixels (small first stored image element) describe each colorimetrically. Such applications are z. B. in the field of reproduction technology in scanners, in printing press to control the printed image, in video systems and digital cameras for the long distance re processing the data in practical testing. To image data in under to be able to process various other devices in the correct color (e.g. screen representation, color printer), you use the general description of the Color through colorimetry. Since in practice color measuring devices for image data Er Detection devices are too complex, with densitometric three-filter measuring devices worked and tried with suitable approximation methods, the densitometric Three-filter measured values as close as possible to the colorimetric measured values.  

It is known that color images are processed on many DTP systems today, that have to be output on different systems. For data out swap you select image data in a buffer that matches the color measurement values (e.g. DIN 5033 part 1-9) can be clearly and reversibly assigned. There under different output devices have certain transmission differences, you need a device-independent, absolutely calibratable database like this before output e.g. B. is given with the colorimetric measured values. The individual output devices can be configured using calibration routines such that the reproducible color space of the output device a subset of the total Color space clearly reverses the colorimetric buffer (see below) cash can be assigned. Apart from certain device errors, thus the output image data approximate the color measurement values very well or with Modify suitable color space maps in a targeted manner. So modified Color space maps can e.g. B. may be required if the output color space is smaller than the input color space. In such cases, e.g. B. the color space cut or scale. Furthermore, are common in reproductive practice Color corrections are required as the color photographic material is for industrial use Studio photography (e.g. slide) does not have sufficient color calibration.

For mapping the input data sets or measured values (e.g. scanner data) on the pseudo color readings and further on the output data sets are divided into individual NEN systems offered aids that, for. B. labeled "Color Management" have been documented. The color space mapping rules are described in so-called Color profiles (tags) defined and assigned to the input data sets. About the two The simple conversions of the very extensive data sets are simplified Mapping rules only applied to the data records in the output device. From that results in the colorimetric buffer (as mentioned above) for image data in many cases is a virtual memory in which instead of pseudo-colorimetric Data only the measured values together with the mapping instruction on the Color space are stored.

The image data acquisition devices in practical use are almost completely equipped with three filters, which allow three measurement values to be recorded in the different color ranges, which are described completely mathematically in the standard DIN 16 536 Part 1 as color density ( Fig. 2 ). With the help of calibration templates and calibration instructions, the three-dimensional space of the density values, often referred to as RGB space in the field of video technology and screen technology, is now approximately mapped onto a color space that comes close to the color measurement values. The approximate values thus obtained are referred to below as "pseudo color values".

However, it is necessary to work with density values that use completely different evaluation functions in the spectral evaluation of the original image than is done in colorimetry. By measuring a test chart, mapping specifications for the pseudo color values on the color measurement values can now be calculated for a specific template. In practice, however, images are processed with the image data acquisition device after the calibration process, in which the colors have a different, unknown spectral characteristic than the colors of the test panel for calibration. The resulting problem is very easy to see from the different evaluation integrals for the color measurement values ( Fig. 1) and the density values or RGB values ( Fig. 2): Certain colors that are assessed as different with the eye or with the color measurement technique appear identical in density assessment. Conversely, there are colors that appear different in the density evaluation and are identical in the visual evaluation. This phenomenon is known as metamerism in visual evaluation and colorimetry. Colors that are rated as identical for one type of light can appear different for another type of light. Similarly, certain colors appear identical in the densitometric evaluation under a given evaluation function, while they are very different in the visual and colorimetric evaluation. It follows that the ability to distinguish colors is very dependent on the spectral evaluation. You are dealing with a so-called "device metamerism"; Different colors, which are assessed as identical with a specific spectral evaluation function of an image data acquisition device, usually appear differently with another evaluation function. It is widely known in the printing industry that, for. B. certain wood shades of similar types of wood, which have visually and colorimetrically clear differences, in which the densitometric measured values cannot be sufficiently differentiated.

The lack of differentiability of colors could be a problem Measurement accuracy of the image data acquisition devices can be interpreted. Sadly it is no further, the measuring accuracy of the image data acquisition devices arbitrarily refine, since the image templates to be measured even in the micro range of a pixel have certain sampling inaccuracies. Since the densitometric measurements of the Pixels with a certain error arise from colors in their densitometric measured values are close to each other, by mapping on the Color space under certain circumstances big mistakes. Certain areas of the Color spaces are more critical than other areas for such errors.

The invention has for its object to enable image-oriented work. In principle, there are certain errors in image processing with image data acquisition devices ell are unavoidable, the images must be in image-important and less important image points are broken down. A pixel can be a single pixel or a surface element consisting of several pixels. Image-sensitive pixels must be exact are mapped to target color values, larger ones can be used for unimportant details Color deviations are tolerated.

This object is achieved in that individual pixels for an operator can be marked on an output device (e.g. printer, monitor) by bordering, coloring, contrasting, cursor positioning or the like usual techniques. The input data (measured values) of these pixels are with the existing mapping rule on the pseudo color values and against compared to the desired colorimetric target values. In the event of deviations from the Corrected pseudo color values to the colorimetric target values is a correction achieved by changing the spectral evaluation function of the image, by changing the light color and / or the filter color in the spectral characteristic is / will be. By further checking the with the image data acquisition device detected pseudo color values and possibly still existing, smaller deviation The setpoint (s) can be iteratively approximated to the setpoint (s) can be achieved.

In order to achieve such a change in the spectral evaluation function, a software routine is implemented in the image data acquisition device, with which individual / several image points can be made selectable for an operator. This software routine is linked to an image display device in such a way that the position (s) of the image point (s) is / are displayed there. For these pixels, the colorimetric coordinates can either be calculated and output or the pixels are visually illustrated with an output device calibrated in the sense of color management. The output device, which outputs the pixels free of color errors, thus enables a visual matching with the coloring patterns. Another device is provided in the image data acquisition device, which allows an operator to change the pseudo-colorimetric coordinates, this device being constructed such that the light color S _λ and / or the filter color τ _i (λ) in the spectral Characteristic for the image data acquisition device is / are adjustable. The change in the spectral characteristics of the light color can be controlled very easily, among other things, by mixing several light colors of different colors or, in the case of thermal radiators, by changing the temperature of the radiator. Among other things, the spectral characteristics of the filter color can be changed very easily by swiveling in different filters.

The advantages that can be achieved with the invention are, in particular, that in the picture by a surgeon deliberately selected individual, particularly important image points can be selected in their pseudo-colorimetric, erroneous values in the virtual, colorimetric buffer closer to the colorimetric target values can be approximated. It can be achieved that individual colors in the image, which are initially indistinguishable for densitometric measurements were better (device metamerism) due to the changed spectral evaluation become distinguishable. The changed spectral rating may change in others Areas of the color space adversely affect what in the color differentiation but in the less important picture details i. a. is accepted. Based on these new, improved database, it is then possible to use an output device (e.g. Printing machine) the desired colors of important details better the wishes or reproduce according to the target values.

In the practice of image processing, there is often a requirement that certain Spot colors, product colors, colors for corporate identity and beyond  well-known object colors such as B. skin color with certain, tight tole color values must be reproduced. In selected pixels can with the described invention exactly the color of a template or other specified target value (e.g. staining pattern) in the virtual, colorimetric buffer achieve what with the previously known densitometric evaluation was not possible.

In applications in which image data acquisition devices are used for process control it is crucial that there is sufficient detail in the important details Color recognition differentiation achieved through suitable evaluation functions can be.

An embodiment of the invention is with an image scanner and Image processing computer equipped with an additional routine the Markie certain pixels. Another routine is determined based on the pass the device calibration, the pseudo color values for the selected pixels. With a color measuring device, the selected pixels are colorimetric in the image measured. With the help of the changeable spectral evaluation through change the light color or by changing the filter color are now the selected Pixels approximated to the previously measured color values.

Instead of a color measuring device, it is also possible to use a color atlas, so as has been common in reproduction technology and color lithography was, although at the individual color fields in the color atlas instead of the previously used area coverings must be the colorimetric measured values. Individual important colors of a template can be visually compared with the fields of the Color atlases are matched in order to obtain the required color measurement values (Color coordinates) to determine. This sampling process has so far been in the graphic industry for "best possible color matching" in both reproductions technology as well as in printing. Such a matching process based on colorimetry or based on visual matching in all image data Detection devices are made available.

Reference symbol list

X, Y, Z: standard color values
x

, y

, e.g.

: Standard spectral values (e.g. table in DIN 5033 part 2)
S _(λ)

: Illuminant with the radiation function (e.g. standard illuminant: A, D 65, C)
ϕ _(λ)

: Color stimulus function:
ϕ _(λ)

= S _λ

: for self-candlesticks,
ϕ _(λ)

= S _λ

τ (λ): for transmitted light originals,
ϕ _(λ)

= S _λ

R (λ): for body colors
R (λ): function of the spectral reflection factor (e.g. DIN 5036 part 1, 6.9)
τ (λ): spectral transmittance of the transmitted light original
D _C

, D _M

, D _Y

: Density, measured in each case in a center of gravity of the visible spectral range, e.g. B. adapted to the printing inks cyan, magenta and yellow,
β (λ): spectral reflectance of the incident light test sample or spectral transmittance of the transmitted light test sample
S _λ

: Illuminant with the radiation function (e.g. standard illuminant: A, D 65, C) or more generally: relative spectral radiation distribution
s (λ) _rel

: relative spectral sensitivity of the radiation receiver
τ _C

(λ), τ _M

(λ), τ _Y

(λ): spectral transmittance of the measuring filter for the center of gravity of the visible spectral range, e.g. B. adapted to the inks cyan, magenta and yellow, or more generally τ _i

(λ).

Claims (1)

Image data acquisition device for determining the colorimetric coordinates of pixels in top view or transmitted light originals, characterized in that a software routine is implemented with which individual / multiple pixels are made selectable for an operator and this software routine is linked to an image output device in such a way that on this the position (s) of the selected pixel (s) is / are displayed and a further device in the image data acquisition device is built such that the light color S _λ and / or the filter color τ _i (λ) of the image data acquisition device in the spectral characteristic is / are adjustable.