# Algorithm for Additive Color Mixing for RGB Values

I'm looking for an algorithm to do additive color mixing for RGB values.

Is it as simple as adding the RGB values together to a max of 256?

(r1, g1, b1) + (r2, g2, b2) =
(min(r1+r2, 256), min(g1+g2, 256), min(b1+b2, 256))
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Why do you need this? Simple addition may not always give the results you want. –  dirkgently Apr 7 '09 at 16:28
Ideally it would represent color blending as if it were colored light. I may be incorrect, but I thought that's what additive color mixing represents. Maybe I'm wrong. –  Gaidin Apr 7 '09 at 16:33
You absolutly right, it should be min. –  Gaidin Apr 7 '09 at 16:41
Typically, the color channel values range from 0 to 255, not 1 to 256. –  Mr Fooz Apr 7 '09 at 17:04
FYI, I'm working off of this, and it refers to 256: pythonware.com/library/tkinter/introduction/… –  Gaidin Apr 7 '09 at 17:20

It depends on what you want, and it can help to see what the results are of different methods.

If you want

Red + Black        = Red
Red + Green        = Yellow
Red + Green + Blue = White
Red + White        = White
Black + White      = White

then adding with a max works (e.g. min(r1 + r2, 255)) This is more like the light model you've referred to.

If you want

Red + Black        = Dark Red
Red + Green        = Dark Yellow
Red + Green + Blue = Dark Gray
Red + White        = Pink
Black + White      = Gray

then you'll need to average the values (e.g. (r1 + r2) / 2) This works better for lightening/darkening colors and creating gradients.

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Sounds more like I want the 2nd option, thanks –  Gaidin Apr 7 '09 at 16:35

To blend using alpha channels, you can use these formulas:

r = new Color();
r.A = 1 - (1 - fg.A) * (1 - bg.A);
if (r.A < 1.0e-6) return r; // Fully transparent -- R,G,B not important
r.R = fg.R * fg.A / r.A + bg.R * bg.A * (1 - fg.A) / r.A;
r.G = fg.G * fg.A / r.A + bg.G * bg.A * (1 - fg.A) / r.A;
r.B = fg.B * fg.A / r.A + bg.B * bg.A * (1 - fg.A) / r.A;

fg is the paint color. bg is the background. r is the resulting color. 1.0e-6 is just a really small number, to compensate for rounding errors.

NOTE: All variables used here are in the range [0.0, 1.0]. You have to divide or multiply by 255 if you want to use values in the range [0, 255].

For example, 50% red on top of 50% green:

// background, 50% green
var bg = new Color { R = 0.00, G = 1.00, B = 0.00, A = 0.50 };
// paint, 50% red
var fg = new Color { R = 1.00, G = 0.00, B = 0.00, A = 0.50 };
// The result
var r = new Color();
r.A = 1 - (1 - fg.A) * (1 - bg.A); // 0.75
r.R = fg.R * fg.A / r.A + bg.R * bg.A * (1 - fg.A) / r.A; // 0.67
r.G = fg.G * fg.A / r.A + bg.G * bg.A * (1 - fg.A) / r.A; // 0.33
r.B = fg.B * fg.A / r.A + bg.B * bg.A * (1 - fg.A) / r.A; // 0.00

Resulting color is: (0.67, 0.33, 0.00, 0.75), or 75% brown (or dark orange).

You could also reverse these formulas:

var bg = new Color();
if (1 - fg.A <= 1.0e-6) return null; // No result -- 'fg' is fully opaque
if (r.A - fg.A < -1.0e-6) return null; // No result -- 'fg' can't make the result more transparent
if (r.A - fg.A < 1.0e-6) return bg; // Fully transparent -- R,G,B not important
bg.A = 1 - (1 - r.A) / (1 - fg.A);
bg.R = (r.R * r.A - fg.R * fg.A) / (bg.A * (1 - fg.A));
bg.G = (r.G * r.A - fg.G * fg.A) / (bg.A * (1 - fg.A));
bg.B = (r.B * r.A - fg.B * fg.A) / (bg.A * (1 - fg.A));

or

var fg = new Color();
if (1 - bg.A <= 1.0e-6) return null; // No result -- 'bg' is fully opaque
if (r.A - bg.A < -1.0e-6) return null; // No result -- 'bg' can't make the result more transparent
if (r.A - bg.A < 1.0e-6) return bg; // Fully transparent -- R,G,B not important
fg.A = 1 - (1 - r.A) / (1 - bg.A);
fg.R = (r.R * r.A - bg.R * bg.A * (1 - fg.A)) / fg.A;
fg.G = (r.G * r.A - bg.G * bg.A * (1 - fg.A)) / fg.A;
fg.B = (r.B * r.A - bg.B * bg.A * (1 - fg.A)) / fg.A;

The formulas will calculate that background or paint color would have to be to produce the given resulting color.

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What can you do about the "division by zero" problem, if fg.A and bg.A is both 0.0? This results is f.A = 0. And then I got a division by zero problem i.e. here: r.R = fg.R * fg.A / r.A + bg.R * bg.A * (1 - fg.A) / r.A; –  nodepond yesterday
@nodepond fixed –  Markus Jarderot yesterday

Few points:

• I think you want to use min instead of max
• I think you want to use 255 instead of 256

This will give:

(r1, g1, b1) + (r2, g2, b2) = (min(r1+r2, 255), min(g1+g2, 255), min(b1+b2, 255))

However, The "natural" way of mixing colors is to use the average, and then you don't need the min:

(r1, g1, b1) + (r2, g2, b2) = ((r1+r2)/2, (g1+g2)/2, (b1+b2)/2)

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You are absolutely right... I will change my answer –  Dani van der Meer Apr 7 '09 at 16:46
Sorry. I am halucingating. min(a,b) will give the least value of a and b. min(a,constant) will constrain a below the constant. –  Markus Jarderot Apr 7 '09 at 16:50
@Markus, they are both the same! (will give the least value). –  UpTheCreek Aug 7 '12 at 8:54

## Javascript function to blend rgba colors

c1,c2 and result - JSON's like c1={r:0.5,g:1,b:0,a:0.33}

var rgbaSum = function(c1, c2){
var a = c1.a + c2.a*(1-c1.a);
return {
r: (c1.r * c1.a  + c2.r * c2.a * (1 - c1.a)) / a,
g: (c1.g * c1.a  + c2.g * c2.a * (1 - c1.a)) / a,
b: (c1.b * c1.a  + c2.b * c2.a * (1 - c1.a)) / a,
a: a
}
}
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