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Subtractive color explains the theory of mixing paints, dyes, inks, and natural colorants to create colors which absorb some wavelengths of light and reflect others. The portions of the light's spectrum (if it includes all portions of the spectrum) that reflect back to one's eye, is the color one will perceive the sample as. Anything that is not additive color is subtractive color. No other color mixing systems are known.
Color is not an absolute, but depends on the details of human color vision, which varies between individuals. Although color can be measured by instruments, such instruments are simply emulating a particular individual's vision.
Consider a "red" apple. When viewed under a white light, it appears red. But this doesn't mean that it emits red light. If it did, you would be able to see it in the dark. Rather, it absorbs some of the white light, and the color remaining after reflection is, as viewed by most humans, red. They simply absorb the frequencies of the light shining on it but reflect back only the red. Humans perceive the apple as red because of how their eye works, and how their brain interprets information from the eye..
It takes three things to see color: a light source, a sample, and a detector (which can be an eye). In color printing, the primary inks used are cyan, magenta, and yellow. Cyan is the opposite of red, meaning that cyan acts like a filter that absorbs red. The amount of cyan applied to a paper will control how much red will show. Magenta is the opposite of green, and yellow the opposite of blue. With this knowledge an infinite number of color combinations are possible. This is how artwork reproductions are mass produced, though for various reasons a black ink is usually used as well. This mixture of cyan, magenta, yellow and black is commonly called CMYK. CMYK is therefore an example of a subtractive color space, or rather a whole range of color spaces, since inks can vary, and the effect of the inks depends on the paper used.
See also
References - Berns, Roy S. (2000). Billmeyer and Saltzman's Principles of Color Technology, 3rd edition. Wiley, New York. ISBN 0-471-19459-X.
- Stroebel, Leslie, John Compton, Ira Current, and Richard Zakia (2000). Basic Photographic Materials and Processes, 2nd edition. Focal Press, Boston. ISBN 0-240-80405-8.
- Wyszecki, Günther and W. S. Stiles (1982). Colour Science Concept and Methods, Quantitative Data and Formulae. Wiley, New York. ISBN 0-471-02106-7.
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