# RGB values of visible spectrum

I need an algorithm or function to map each wavelength of visible range of spectrum to its equivalent RGB values. Is there any structural relation between the RGB System and wavelength of a light? like this image: sorry if this was irrelevant :-]

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This question may give you some insight. stackoverflow.com/questions/1472514/… –  GWW Aug 4 '10 at 17:15
Spectral Colors and RGB colors have a inf-to-1 relation, so there is no unique relation. One RGB colour maps to infinitely many spectral colours. –  phresnel Apr 4 '13 at 5:40
look here: stackoverflow.com/a/22149027/2521214 and yes this can be used only to wavelength -> RGB conversion not the other way around ... (wavelength has color but color is not wavelength ...) –  Spektre Mar 4 at 8:25

There is a relationship between frequency and what is known as Hue, but for complicated reasons of perception, monitor gamut, and calibration, the best you can achieve outside of expensive lab equipment is a gross approximation.

See http://en.wikipedia.org/wiki/HSL_and_HSV for the math, and note that you'll have to come up with your best guess for the Hue ⇔ Frequency mapping. I expect this empirical mapping to be anything but linear.

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the whole math for Hue -> RGB mapping is approximation (linear). Hue -> freq can be mapped as wavelength 390 to 750 nm maps to hue [0, 1]. freq = c / wavelength –  Andrey Aug 4 '10 at 17:33
Note my use of the word "empirical" and then try it for yourself whilst remembering that our perception is trichromat and distinctly non-linear and that monitors are a different trichromatic and are also extremely non-linear. There is an entire calibration industry built around these effects. –  msw Aug 4 '10 at 17:46

I think the answers fail to address a problem with the actual question.

RGB values are generally derived from the XYZ color space which is the combination of a standard human observer function, an illuminate and the relative power of the sample at each wavelength over the range of ~360-830.

I'm not sure of what you are trying to achieve here but it would be possible to calculate a relatively "accurate" RGB value for a sample where each discrete band of the spectrum @ say 10nm was fully saturated. The transform looks like this Spectrum `->XYZ->RGB`. Check out Bruce Lindbloom's site for the math. From the XYZ you can also easily calculate `hue`, `chroma` or `colorimetric` values such as `L*a*b*`.

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This is most of what color profiles deal with. Basically, for a given device (scanner, camera, monitor, printer, etc.) a color profile tells what actual colors of light will be produced by a specific set of inputs.

Also note that for most real devices, you only deal with a few discrete wavelengths of light, and intermediate colors are produced not by producing that wavelength directly, but by mixing varying amounts of the two neighboring wavelengths that are available. Given that we perceive color in the same way, that's not really a problem, but depending on why you care, it may be worth knowing anyway.

Without a color profile (or equivalent information) you lack the information necessary to map RGB value to colors. An RGB value of pure red will normally map to the reddest color that device is capable of producing/sensing (and likewise, pure blue to the bluest color) -- but that "reddest" or "bluest" can and will vary (widely) based on the device.

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Partial "Approximate RGB values for Visible Wavelengths"

Credit: Dan Bruton - Color Science

Original FORTRAN code @ (http://www.physics.sfasu.edu/astro/color/spectra.html)

Will return smooth(continuous) spectrum, heavy on the red side.

w - wavelength, R, G and B - color components

Ignoring gamma and intensity simple leaves:

``````if w >= 380 and w < 440:
R = -(w - 440.) / (440. - 380.)
G = 0.0
B = 1.0
elif w >= 440 and w < 490:
R = 0.0
G = (w - 440.) / (490. - 440.)
B = 1.0
elif w >= 490 and w < 510:
R = 0.0
G = 1.0
B = -(w - 510.) / (510. - 490.)
elif w >= 510 and w < 580:
R = (w - 510.) / (580. - 510.)
G = 1.0
B = 0.0
elif w >= 580 and w < 645:
R = 1.0
G = -(w - 645.) / (645. - 580.)
B = 0.0
elif w >= 645 and w <= 780:
R = 1.0
G = 0.0
B = 0.0
else:
R = 0.0
G = 0.0
B = 0.0
``````
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This would give 6 discrete RGB values. Anything for the in-between colours? –  FrustratedWithFormsDesigner Aug 4 '10 at 17:13
@FrustratedWithFormsDesigner no, it is gradient. w is inside the expressions, so they are f(w) –  Andrey Aug 4 '10 at 17:15
Aren't the `R=-(w - 440.) / (440. - 350.)` bits for the in-between values? R,G,B are floating-point here, not ints. –  Rup Aug 4 '10 at 17:15
What's the source of the algorithm - your own from frequency tables for some colours or is this a standard computation? –  Rup Aug 4 '10 at 17:16
@FrustratedWithFormsDesigner: there is not just five discrete values. (w stands for the wavelenght.) it sounds to work. i'll try it. –  sorush-r Aug 4 '10 at 17:17

If you want an exact match then the only solution is to perform a convolution of the x,y,z color matching functions with your spectral values so you finally get a (device-independent) XYZ color representation that you can later convert into (device-dependent) RGB.

This is described here: http://www.cs.rit.edu/~ncs/color/t_spectr.html

You can find the x,y,z color matching function for convolution here: http://cvrl.ioo.ucl.ac.uk/cmfs.htm

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