# Is there an algorithm for color mixing that works like mixing real colors?

The common mixing of RGB colors is very different from mixing colors for paintings, it's mixing of light instead mixing of pigments.

For example:

``````Blue (0,0,255) + Yellow (255,255,0) = Grey (128,128,128)
``````

(It should be Blue + Yellow = Green)

Is there any known algorithm for color mixing that works like mixing real colors?

I've already tried following:

Converting both colors to HSV and mixing hues (multiplied by coefficient computed from saturation), and simple average for saturation and value channels. Then I computed average luminance from both colors (using Rec. 709 luma coefficients) and adjusted the result color to match this luminance. This worked quite well, but the hue mixing was sometimes wrong, e. g.:

``````Red (Hue 0°) + Blue (Hue 240°) = Green (Hue 120°)
``````

I've figured out that sometimes I need to shift the hue value by 360° (when the difference between hues is greater than 180°).

``````Red (Hue 360°) + Blue (Hue 240°) = Magenta/fuchsia (Hue 300°)
``````

But this shifting wasn't very good too, e.g.:

``````Cyan (Hue 179°) + Red (Hue 0°) = Hue 89.5°
Cyan (Hue 181°) + Red (Hue 0°) --> shifting is performed (difference is greater than 180°)
Cyan (Hue 181°) + Red (Hue 360°) = Hue 270.5°
``````

(Hue 179 + Red) and (Hue 181 + Red) results in two COMPLETELY different colors.

Then I tried CIE LAB color space (like in Photoshop), which is supposed to have realistic colors for human (or something like that). I used just simple average for each corresponding two channels, but the results weren't satisfying, for example I got pink (64, 26, -9.5) out of blue (98, -16, 93) and yellow (30, 68, -112). These coefficients were taken from Photoshop. Maybe if I used some different operation than average, it could work, but I don't know what.

CMYK didn't work too, results are just like in RGB or LAB.

There is piece of working software: http://commit-digest.org/issues/2007-08-12/ (Krita). They say it is the first public application that implements special technology using Kubelka and Munk equations that describe the behavior of pigments.

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A dupe i think: stackoverflow.com/questions/726549/… –  Ólafur Waage Aug 29 '09 at 13:29

The correct answer is NO, because there is no correct working model of how "color mixing in the real world" really works. It is FAR too complex and conditional and not really at all like the simple Red-Blue-Yellow stuff that we learned in school (it in fact requires all of Chemistry and a lot of Physics and Biology to resolve).

However, the simplistic answer is: YES, use subtractive mixing rather than Additive mixing.

The color-mixing that we learned in grade school is based on pigment combinations which are a form of subtractive color mixing (very simplistically). That is the more colors that we add together, the darker it becomes because each pigment subtracts a little bit more light.

On the other hand, almost all computer color-schemes are additive in that they are based on combining light waves (very simplistically), so they get brighter, because each color adds a little bit more light.

The RGB+ scheme is somewhat, the additive complement to the subtractive scheme that we learned in most US elementary schools (which is RBY-). However, they do not match up exactly and it can be difficult to convert between them (researching now ...)

OK, if you just want to switch from additive combinations in RGB to subtractive ones, you can use the following reverse-bayesan type formula to combine two colors:

``````NewColor.R = (Color1.R * Color2.R)/255
NewColor.G = (Color1.G * Color2.G)/255
NewColor.B = (Color1.B * Color2.B)/255
``````

Adjusting for the difference in the chromatic poles (G to Y, then back to G) is a lot harder ...

It has been pointed out that this produces Black for the example problem, and technically this is correct for a true subtractive system, however, if you want more diluting/subtractive system, you could try this instead:

``````NewColor.R = 255 - SQRT(((255-Color1.R)^2 + (255-Color2.R)^2)/2)
NewColor.G = 255 - SQRT(((255-Color1.G)^2 + (255-Color2.G)^2)/2)
NewColor.B = 255 - SQRT(((255-Color1.B)^2 + (255-Color2.B)^2)/2)
``````

This produces a dark grey instead of Black. But to get Yellow or anything close, you still have to fix the color-scheme's pole-alignment problem.

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This formula would give black in the situation mentioned, wouldn't it? –  Dolphin Aug 31 '09 at 15:49
Hmmm, yeah, pretty close. Let me find something better then... –  RBarryYoung Aug 31 '09 at 17:54
So have you found something better? –  tomp Sep 11 '09 at 10:42
No, it's pretty hard not to come up with Black in any subtractive approach because all three poles are maxed out in the source. The only solutions that I can see require re-mapping to a different scheme which I've been trying to avoid for a "simple" solution. Hmmm, ... give me a couple of hours this morning though, I may have a "simple" re-mapping to fix it... –  RBarryYoung Sep 11 '09 at 13:01
Dye mixing is subtractive, but many dyes don't actually operate on primary colors. Paint mixing is not subtractive but may be, depending upon the paint, an arbitrary combination of additive, subtractive, and weird-and-wacky. –  supercat Jun 11 '12 at 22:34
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there are two different possibilities combining colors:

1. additive mixing (like RGB)

2. subtractive mixing (like CMYK)

So in subtractive color mixing the result is what you expected, but there is no blue, instead there is cyan:

Yellow + cyan = green

In general subtractive color mixing is just "taking away" (filtering) from white while additive color mixing is adding up from black. (base colors of subtractive are inverse from additive: red ->cyan; green->magenta; blue->yellow)

So if you start with white screen applying filters:

min( white (255,255,255), yellow (255,255,0), cyan (0,255,255)) = green (0,255,0)

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What if I try blue as Cyan+Magenta (100%, 100%, 0, 0). When I mix this with yellow, it doesn't seem very realistic and natural. –  tomp Aug 29 '09 at 13:39
The "rule "yellow+blue=green" is a misconception. You have to mix cyan with yellow to get blue(on subtractive colors). –  Peter Parker Aug 29 '09 at 13:49
CMYK isn't "right" either. It's an approximation model, just like RBY-. You could perhaps argue that it is "more" right than RBY-. –  RBarryYoung Aug 29 '09 at 13:58
@RBarryYoung: CMYK is only an accurate model when applied to inks or dyes which are deliberately formulated so as to make it reasonably accurate. RGB additive synthesis, by contrast, is relatively accurate regardless of whether colors are "pure" or not. –  supercat Jun 11 '12 at 22:35

There is code to mix colors in a realistic way in krita: https://projects.kde.org/projects/calligra/repository/revisions/master/show/krita/plugins/extensions/painterlyframework.

Note that the code including the illuminants file is GPLv2+. It can convert from RGB to wavelengths, do composition and convert back.

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Thank you for the link. I've mentioned Krita in my question, I just couldn't find the related source code. But is it really the light wavelength that drives the algorithm? Blue light has wavelength about 475 nm, red light about 650 nm. How are the wavelengths combined to get violet light? It must be working with something more difficult than just light wavelength. I'm sure that the algorithm itself is very complicated and I'm still looking for its, at least brief, explanation. –  tomp Apr 22 '12 at 17:04
You will need to go back to version 2.4.x, it seems that code was removed because it was not maintained. –  Ben Holland Feb 12 '13 at 19:25

I think your problem with combining hues is that you are doing it by adding together the two angles and dividing by two. As you've noticed, the result often makes no sense. I think you'd be better off converting the angles to Cartesian coordinates on the unit circle, averaging those, and finding the angle of the resulting point (ignoring the magnitude).

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That gives: Cyan (Hue 179°) + Red (Hue 0°) = 89.5° and Cyan (Hue 181°) + Red (Hue 0°) = -89.5° = 270.5° –  tomp Dec 22 '11 at 7:47