Does anyone know of any formula for converting a light frequency to an RGB value?

2Very technical questions in terms of physics and programming +1. – whatnick Sep 24 '09 at 15:49

1check this out approximation of real spectral colors – Spektre Oct 27 '15 at 8:49
Here's a detailed explanation of the entire conversion process: http://www.fourmilab.ch/documents/specrend/. Source code included!

2

4And the Fourmilab article makes the important point that some colours are not representable in RGB (bright oranges being a good example) because you cannot "make" arbitrary colours of light by adding three primary colours together, whatever our physics teachers may have told us (well mine did). Too bad, but in practice not usually fatal. – Francis Davey May 29 '10 at 22:58

1In addition to it: en.wikipedia.org/wiki/Srgb The article was written before sRGB standard was widely adopted. Also note the "Calculations assume the 2° standard colorimetric observer" phrase, which means CIE 1931 table found in accompanying source to the paper should be used and not CIE 1964. – GrayFace Feb 10 '14 at 7:45

It would be nice to provide some example how to use the code. It requires function as an argument, uses temperature to calculate colors and such things. One would be happy to know what to delete and change to get it to work. – Tomáš Zato Mar 13 '14 at 16:34

It is worth noting that only a small subset of all possible visible wavelengths can be exactly represented in the RGB color space. The conversion process is quite intricate and ambiguous. See physics.stackexchange.com/a/94446/5089 and physics.stackexchange.com/a/419628/5089 – Violet Giraffe Dec 30 '18 at 19:39
For lazy guys (like me), here is an implementation in java of the code found in @user151323 's answer (that is, just a simple translation from pascal code found in Spectra Lab Report):
static private double Gamma = 0.80;
static private double IntensityMax = 255;
/** Taken from Earl F. Glynn's web page:
* <a href="http://www.efg2.com/Lab/ScienceAndEngineering/Spectra.htm">Spectra Lab Report</a>
* */
public static int[] waveLengthToRGB(double Wavelength){
double factor;
double Red,Green,Blue;
if((Wavelength >= 380) && (Wavelength<440)){
Red = (Wavelength  440) / (440  380);
Green = 0.0;
Blue = 1.0;
}else if((Wavelength >= 440) && (Wavelength<490)){
Red = 0.0;
Green = (Wavelength  440) / (490  440);
Blue = 1.0;
}else if((Wavelength >= 490) && (Wavelength<510)){
Red = 0.0;
Green = 1.0;
Blue = (Wavelength  510) / (510  490);
}else if((Wavelength >= 510) && (Wavelength<580)){
Red = (Wavelength  510) / (580  510);
Green = 1.0;
Blue = 0.0;
}else if((Wavelength >= 580) && (Wavelength<645)){
Red = 1.0;
Green = (Wavelength  645) / (645  580);
Blue = 0.0;
}else if((Wavelength >= 645) && (Wavelength<781)){
Red = 1.0;
Green = 0.0;
Blue = 0.0;
}else{
Red = 0.0;
Green = 0.0;
Blue = 0.0;
};
// Let the intensity fall off near the vision limits
if((Wavelength >= 380) && (Wavelength<420)){
factor = 0.3 + 0.7*(Wavelength  380) / (420  380);
}else if((Wavelength >= 420) && (Wavelength<701)){
factor = 1.0;
}else if((Wavelength >= 701) && (Wavelength<781)){
factor = 0.3 + 0.7*(780  Wavelength) / (780  700);
}else{
factor = 0.0;
};
int[] rgb = new int[3];
// Don't want 0^x = 1 for x <> 0
rgb[0] = Red==0.0 ? 0 : (int) Math.round(IntensityMax * Math.pow(Red * factor, Gamma));
rgb[1] = Green==0.0 ? 0 : (int) Math.round(IntensityMax * Math.pow(Green * factor, Gamma));
rgb[2] = Blue==0.0 ? 0 : (int) Math.round(IntensityMax * Math.pow(Blue * factor, Gamma));
return rgb;
}
By the way, this works fine for me.

2There seems to be a bug in your code. If the wavelength is for example 439.5, your function returns black. The original code on the site was working with integers, I believe (I don't know pascal at all). I suggest to change
Wavelength<=439
toWavelength<440
. – Hassedev Feb 25 '13 at 15:44 
1
General idea:
 Use CEI color matching functions to convert wavelength to XYZ color.
 Convert XYZ to RGB
 Clip components to [0..1] and multiply by 255 to fit in the unsigned byte range.
Steps 1 and 2 may vary.
There are several color matching functions, available as tables or as analytic approximations (suggested by @Tarc and @Haochen Xie). Tables are best if you need a smooth preсise result.
There is no single RGB color space. Multiple transformation matrices and different kinds of gamma correction may be used.
Below is the C# code I came up with recently. It uses linear interpolation over the "CIE 1964 standard observer" table and sRGB matrix + gamma correction.
static class RgbCalculator {
const int
LEN_MIN = 380,
LEN_MAX = 780,
LEN_STEP = 5;
static readonly double[]
X = {
0.000160, 0.000662, 0.002362, 0.007242, 0.019110, 0.043400, 0.084736, 0.140638, 0.204492, 0.264737,
0.314679, 0.357719, 0.383734, 0.386726, 0.370702, 0.342957, 0.302273, 0.254085, 0.195618, 0.132349,
0.080507, 0.041072, 0.016172, 0.005132, 0.003816, 0.015444, 0.037465, 0.071358, 0.117749, 0.172953,
0.236491, 0.304213, 0.376772, 0.451584, 0.529826, 0.616053, 0.705224, 0.793832, 0.878655, 0.951162,
1.014160, 1.074300, 1.118520, 1.134300, 1.123990, 1.089100, 1.030480, 0.950740, 0.856297, 0.754930,
0.647467, 0.535110, 0.431567, 0.343690, 0.268329, 0.204300, 0.152568, 0.112210, 0.081261, 0.057930,
0.040851, 0.028623, 0.019941, 0.013842, 0.009577, 0.006605, 0.004553, 0.003145, 0.002175, 0.001506,
0.001045, 0.000727, 0.000508, 0.000356, 0.000251, 0.000178, 0.000126, 0.000090, 0.000065, 0.000046,
0.000033
},
Y = {
0.000017, 0.000072, 0.000253, 0.000769, 0.002004, 0.004509, 0.008756, 0.014456, 0.021391, 0.029497,
0.038676, 0.049602, 0.062077, 0.074704, 0.089456, 0.106256, 0.128201, 0.152761, 0.185190, 0.219940,
0.253589, 0.297665, 0.339133, 0.395379, 0.460777, 0.531360, 0.606741, 0.685660, 0.761757, 0.823330,
0.875211, 0.923810, 0.961988, 0.982200, 0.991761, 0.999110, 0.997340, 0.982380, 0.955552, 0.915175,
0.868934, 0.825623, 0.777405, 0.720353, 0.658341, 0.593878, 0.527963, 0.461834, 0.398057, 0.339554,
0.283493, 0.228254, 0.179828, 0.140211, 0.107633, 0.081187, 0.060281, 0.044096, 0.031800, 0.022602,
0.015905, 0.011130, 0.007749, 0.005375, 0.003718, 0.002565, 0.001768, 0.001222, 0.000846, 0.000586,
0.000407, 0.000284, 0.000199, 0.000140, 0.000098, 0.000070, 0.000050, 0.000036, 0.000025, 0.000018,
0.000013
},
Z = {
0.000705, 0.002928, 0.010482, 0.032344, 0.086011, 0.197120, 0.389366, 0.656760, 0.972542, 1.282500,
1.553480, 1.798500, 1.967280, 2.027300, 1.994800, 1.900700, 1.745370, 1.554900, 1.317560, 1.030200,
0.772125, 0.570060, 0.415254, 0.302356, 0.218502, 0.159249, 0.112044, 0.082248, 0.060709, 0.043050,
0.030451, 0.020584, 0.013676, 0.007918, 0.003988, 0.001091, 0.000000, 0.000000, 0.000000, 0.000000,
0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000,
0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000,
0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000,
0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000, 0.000000,
0.000000
};
static readonly double[]
MATRIX_SRGB_D65 = {
3.2404542, 1.5371385, 0.4985314,
0.9692660, 1.8760108, 0.0415560,
0.0556434, 0.2040259, 1.0572252
};
public static byte[] Calc(double len) {
if(len < LEN_MIN  len > LEN_MAX)
return new byte[3];
len = LEN_MIN;
var index = (int)Math.Floor(len / LEN_STEP);
var offset = len  LEN_STEP * index;
var x = Interpolate(X, index, offset);
var y = Interpolate(Y, index, offset);
var z = Interpolate(Z, index, offset);
var m = MATRIX_SRGB_D65;
var r = m[0] * x + m[1] * y + m[2] * z;
var g = m[3] * x + m[4] * y + m[5] * z;
var b = m[6] * x + m[7] * y + m[8] * z;
r = Clip(GammaCorrect_sRGB(r));
g = Clip(GammaCorrect_sRGB(g));
b = Clip(GammaCorrect_sRGB(b));
return new[] {
(byte)(255 * r),
(byte)(255 * g),
(byte)(255 * b)
};
}
static double Interpolate(double[] values, int index, double offset) {
if(offset == 0)
return values[index];
var x0 = index * LEN_STEP;
var x1 = x0 + LEN_STEP;
var y0 = values[index];
var y1 = values[1 + index];
return y0 + offset * (y1  y0) / (x1  x0);
}
static double GammaCorrect_sRGB(double c) {
if(c <= 0.0031308)
return 12.92 * c;
var a = 0.055;
return (1 + a) * Math.Pow(c, 1 / 2.4)  a;
}
static double Clip(double c) {
if(c < 0)
return 0;
if(c > 1)
return 1;
return c;
}
}
Result for the 400700 nm range:

This is really interesting to me. I have an idea to use something like this to give a normal response, but use a WXYZ response to mimic the response of tetrachromats who have a fourth cone which responds to a frequency far enough from any of the other normal three types of cones. That might let me take source images and infer the differences they see. N.B. they don't see new colors, it's that lights that blend, (sum), for example, to a particular yellow seems identical to a yellow of a particular frequency for most of us, but for them, the light wouldn't blend to that yellow at all. – Patrick Nov 18 '16 at 4:34

Of course, for a particular RGB color, it could have been arrived at in a lot of ways. The green of a leaf could come from the filtering out of everything but green, or the green could have been filtered out, but nano characteristics could cause blue and yellow to reflect and look identical to the green. Given an image rather than the light, is there any way that I can differentiate? – Patrick Nov 18 '16 at 4:36
Although this is an old question and already gets a handful good answers, when I tried to implement such conversion functionality in my application I was not satisfied with the algorithms already listed here and did my own research, which gave me some good result. So I'm going to post a new answer.
After some researchs I came across this paper, Simple Analytic Approximations to the CIE XYZ Color Matching Functions, and tried to adopt the introduced multilobe piecewise Gaussian fit algorithm in my application. The paper only described the functions to convert a wavelength to the corresponding XYZ values, so I implemented a function to convert XYZ to RGB in the sRGB color space and combined them. The result is fantastic and worth sharing:
/**
* Convert a wavelength in the visible light spectrum to a RGB color value that is suitable to be displayed on a
* monitor
*
* @param wavelength wavelength in nm
* @return RGB color encoded in int. each color is represented with 8 bits and has a layout of
* 00000000RRRRRRRRGGGGGGGGBBBBBBBB where MSB is at the leftmost
*/
public static int wavelengthToRGB(double wavelength){
double[] xyz = cie1931WavelengthToXYZFit(wavelength);
double[] rgb = srgbXYZ2RGB(xyz);
int c = 0;
c = (((int) (rgb[0] * 0xFF)) & 0xFF) << 16;
c = (((int) (rgb[1] * 0xFF)) & 0xFF) << 8;
c = (((int) (rgb[2] * 0xFF)) & 0xFF) << 0;
return c;
}
/**
* Convert XYZ to RGB in the sRGB color space
* <p>
* The conversion matrix and color component transfer function is taken from http://www.color.org/srgb.pdf, which
* follows the International Electrotechnical Commission standard IEC 6196621 "Multimedia systems and equipment 
* Colour measurement and management  Part 21: Colour management  Default RGB colour space  sRGB"
*
* @param xyz XYZ values in a double array in the order of X, Y, Z. each value in the range of [0.0, 1.0]
* @return RGB values in a double array, in the order of R, G, B. each value in the range of [0.0, 1.0]
*/
public static double[] srgbXYZ2RGB(double[] xyz) {
double x = xyz[0];
double y = xyz[1];
double z = xyz[2];
double rl = 3.2406255 * x + 1.537208 * y + 0.4986286 * z;
double gl = 0.9689307 * x + 1.8757561 * y + 0.0415175 * z;
double bl = 0.0557101 * x + 0.2040211 * y + 1.0569959 * z;
return new double[] {
srgbXYZ2RGBPostprocess(rl),
srgbXYZ2RGBPostprocess(gl),
srgbXYZ2RGBPostprocess(bl)
};
}
/**
* helper function for {@link #srgbXYZ2RGB(double[])}
*/
private static double srgbXYZ2RGBPostprocess(double c) {
// clip if c is out of range
c = c > 1 ? 1 : (c < 0 ? 0 : c);
// apply the color component transfer function
c = c <= 0.0031308 ? c * 12.92 : 1.055 * Math.pow(c, 1. / 2.4)  0.055;
return c;
}
/**
* A multilobe, piecewise Gaussian fit of CIE 1931 XYZ Color Matching Functions by Wyman el al. from Nvidia. The
* code here is adopted from the Listing 1 of the paper authored by Wyman et al.
* <p>
* Reference: Chris Wyman, PeterPike Sloan, and Peter Shirley, Simple Analytic Approximations to the CIE XYZ Color
* Matching Functions, Journal of Computer Graphics Techniques (JCGT), vol. 2, no. 2, 111, 2013.
*
* @param wavelength wavelength in nm
* @return XYZ in a double array in the order of X, Y, Z. each value in the range of [0.0, 1.0]
*/
public static double[] cie1931WavelengthToXYZFit(double wavelength) {
double wave = wavelength;
double x;
{
double t1 = (wave  442.0) * ((wave < 442.0) ? 0.0624 : 0.0374);
double t2 = (wave  599.8) * ((wave < 599.8) ? 0.0264 : 0.0323);
double t3 = (wave  501.1) * ((wave < 501.1) ? 0.0490 : 0.0382);
x = 0.362 * Math.exp(0.5 * t1 * t1)
+ 1.056 * Math.exp(0.5 * t2 * t2)
 0.065 * Math.exp(0.5 * t3 * t3);
}
double y;
{
double t1 = (wave  568.8) * ((wave < 568.8) ? 0.0213 : 0.0247);
double t2 = (wave  530.9) * ((wave < 530.9) ? 0.0613 : 0.0322);
y = 0.821 * Math.exp(0.5 * t1 * t1)
+ 0.286 * Math.exp(0.5 * t2 * t2);
}
double z;
{
double t1 = (wave  437.0) * ((wave < 437.0) ? 0.0845 : 0.0278);
double t2 = (wave  459.0) * ((wave < 459.0) ? 0.0385 : 0.0725);
z = 1.217 * Math.exp(0.5 * t1 * t1)
+ 0.681 * Math.exp(0.5 * t2 * t2);
}
return new double[] { x, y, z };
}
my code is written in Java 8, but it shouldn't be hard to port it to lower versions of Java and other languages.

1@Baddack, you're right: it's just a fancy way to make some further transformation on the calculated values. I cannot remember exactly, but I think it first applies a gamma correction, then cuts off out of range values. Maybe I should have it done in a separate method, but I wasn't actually thinking about sharing the code while writing it, and it was a toy project in which I needed this conversion. – Haochen Xie Jun 24 '16 at 18:39

1@Baddack I've dug out the project that I needed this conversion, and rewrote this part without using java 8 lambda so the code is more clear. I actually remembered incorrectly about what the
transfer
DoubleUnaryOperator was doing (thus the explanation in my previous comment are not correct), so please check the new code. – Haochen Xie Jun 25 '16 at 15:09 
1@Baddack i'm glad that the code helps you. and if you don't mind, could you please upvote it so it may potentially help more people? – Haochen Xie Jun 27 '16 at 2:30

1@Baddack Math.pow(c, 1. / 2.4) = c^(1/2.4), i.e. raise c to the power of 1/2.4;
1.
is just 1 but the type will bedouble
instead ofint
– Haochen Xie Jun 29 '16 at 21:36 
3@Ruslan since this algorithm is a analytical fit of the CIE standard observer (which could be considered to be the "precise" model), there are errors. But from the paper, if you look at the Figure 1 on page 7 (compare (d) with (f)), this method provides quite a close approximation. Especially if you look at (f), you could see that there is also a bluish line even in the standard model. Also, color perception of pure light source varies personally, so this level of error is probably negligible. – Haochen Xie Sep 8 '16 at 12:56
You're talking about converting from wave length to an RGB value.
Look here, will probably answer your question. Thy have an utility for doing this with the source code as well as some explanation.

1Just reading the same page "There is no unique onetoone mapping between wavelength and RGB values"  so well you are stuck with a lookup table and heuristics. As a first cut I would look at HSV to RGB conversions since the "Hue" ranges from blue to red. With possibly a slight shift since in RGB domain red+blue = violet and violet has the shortest visible wavelength. – whatnick Sep 24 '09 at 15:49

3

1


8@ Joseph Gordon  Strongly disagree. Consider a greenish ray 400nm emitted in air hit the water surface and then propagates in water. Refraction coefficient of water is, say, 1.33, so a ray wavelength in water is now 300nm, which obviously doesn't change it's color. The matter that "colorizes" the rays is frequency, not wavelength. In the same substance (vacuum, air, water) frequencies (colors) map to same wavelengths. In different media  not. – mbaitoff Jan 16 '11 at 7:44
I guess I might as well follow up my comment with a formal answer. The best option is to use the HSV colour space  though the hue represents the wavelength it is not a onetoone comparison.

1
I did a linear fit of known hue values and frequencies (dropping out red and violet because they extend so far in frequency values that they skew things a bit) and I got a rough conversion equation.
It goes like
frequency (in THz)=474+(3/4)(Hue Angle (in degrees))
I've tried to look around and see if anyone has come up with this equation, but I haven't found anything as of May 2010.
Method 1
This is bit cleaned up and tested C++11 version of @haochenxie. I also added a function that converts value 0 to 1 to a wavelength in visible spectrum that is usable with this method. You can just put below in one header file and use it without any dependencies. This version will be maintained here.
#ifndef common_utils_OnlineStats_hpp
#define common_utils_OnlineStats_hpp
namespace common_utils {
class ColorUtils {
public:
static void valToRGB(double val0To1, unsigned char& r, unsigned char& g, unsigned char& b)
{
//actual visible spectrum is 375 to 725 but outside of 400700 things become too dark
wavelengthToRGB(val0To1 * (700  400) + 400, r, g, b);
}
/**
* Convert a wavelength in the visible light spectrum to a RGB color value that is suitable to be displayed on a
* monitor
*
* @param wavelength wavelength in nm
* @return RGB color encoded in int. each color is represented with 8 bits and has a layout of
* 00000000RRRRRRRRGGGGGGGGBBBBBBBB where MSB is at the leftmost
*/
static void wavelengthToRGB(double wavelength, unsigned char& r, unsigned char& g, unsigned char& b) {
double x, y, z;
cie1931WavelengthToXYZFit(wavelength, x, y, z);
double dr, dg, db;
srgbXYZ2RGB(x, y, z, dr, dg, db);
r = static_cast<unsigned char>(static_cast<int>(dr * 0xFF) & 0xFF);
g = static_cast<unsigned char>(static_cast<int>(dg * 0xFF) & 0xFF);
b = static_cast<unsigned char>(static_cast<int>(db * 0xFF) & 0xFF);
}
/**
* Convert XYZ to RGB in the sRGB color space
* <p>
* The conversion matrix and color component transfer function is taken from http://www.color.org/srgb.pdf, which
* follows the International Electrotechnical Commission standard IEC 6196621 "Multimedia systems and equipment 
* Colour measurement and management  Part 21: Colour management  Default RGB colour space  sRGB"
*
* @param xyz XYZ values in a double array in the order of X, Y, Z. each value in the range of [0.0, 1.0]
* @return RGB values in a double array, in the order of R, G, B. each value in the range of [0.0, 1.0]
*/
static void srgbXYZ2RGB(double x, double y, double z, double& r, double& g, double& b) {
double rl = 3.2406255 * x + 1.537208 * y + 0.4986286 * z;
double gl = 0.9689307 * x + 1.8757561 * y + 0.0415175 * z;
double bl = 0.0557101 * x + 0.2040211 * y + 1.0569959 * z;
r = srgbXYZ2RGBPostprocess(rl);
g = srgbXYZ2RGBPostprocess(gl);
b = srgbXYZ2RGBPostprocess(bl);
}
/**
* helper function for {@link #srgbXYZ2RGB(double[])}
*/
static double srgbXYZ2RGBPostprocess(double c) {
// clip if c is out of range
c = c > 1 ? 1 : (c < 0 ? 0 : c);
// apply the color component transfer function
c = c <= 0.0031308 ? c * 12.92 : 1.055 * std::pow(c, 1. / 2.4)  0.055;
return c;
}
/**
* A multilobe, piecewise Gaussian fit of CIE 1931 XYZ Color Matching Functions by Wyman el al. from Nvidia. The
* code here is adopted from the Listing 1 of the paper authored by Wyman et al.
* <p>
* Reference: Chris Wyman, PeterPike Sloan, and Peter Shirley, Simple Analytic Approximations to the CIE XYZ Color
* Matching Functions, Journal of Computer Graphics Techniques (JCGT), vol. 2, no. 2, 111, 2013.
*
* @param wavelength wavelength in nm
* @return XYZ in a double array in the order of X, Y, Z. each value in the range of [0.0, 1.0]
*/
static void cie1931WavelengthToXYZFit(double wavelength, double& x, double& y, double& z) {
double wave = wavelength;
{
double t1 = (wave  442.0) * ((wave < 442.0) ? 0.0624 : 0.0374);
double t2 = (wave  599.8) * ((wave < 599.8) ? 0.0264 : 0.0323);
double t3 = (wave  501.1) * ((wave < 501.1) ? 0.0490 : 0.0382);
x = 0.362 * std::exp(0.5 * t1 * t1)
+ 1.056 * std::exp(0.5 * t2 * t2)
 0.065 * std::exp(0.5 * t3 * t3);
}
{
double t1 = (wave  568.8) * ((wave < 568.8) ? 0.0213 : 0.0247);
double t2 = (wave  530.9) * ((wave < 530.9) ? 0.0613 : 0.0322);
y = 0.821 * std::exp(0.5 * t1 * t1)
+ 0.286 * std::exp(0.5 * t2 * t2);
}
{
double t1 = (wave  437.0) * ((wave < 437.0) ? 0.0845 : 0.0278);
double t2 = (wave  459.0) * ((wave < 459.0) ? 0.0385 : 0.0725);
z = 1.217 * std::exp(0.5 * t1 * t1)
+ 0.681 * std::exp(0.5 * t2 * t2);
}
}
};
} //namespace
#endif
The plot of colors from 375nm to 725nm looks like below:
One issue with this method is the fact that it works only between 400700nm and outside of that it sharply falls down to black. Another issue is narrower blue.
For comparison, below is the colors from Vision FAQ at maxmax.com:
I used this to visualize depth map where each pixel represents depth value in meters and this looks like below:
Method 2
This is implemented as part of bitmap_image single file headeronly library by Aeash Partow:
inline rgb_t convert_wave_length_nm_to_rgb(const double wave_length_nm)
{
// Credits: Dan Bruton http://www.physics.sfasu.edu/astro/color.html
double red = 0.0;
double green = 0.0;
double blue = 0.0;
if ((380.0 <= wave_length_nm) && (wave_length_nm <= 439.0))
{
red = (wave_length_nm  440.0) / (440.0  380.0);
green = 0.0;
blue = 1.0;
}
else if ((440.0 <= wave_length_nm) && (wave_length_nm <= 489.0))
{
red = 0.0;
green = (wave_length_nm  440.0) / (490.0  440.0);
blue = 1.0;
}
else if ((490.0 <= wave_length_nm) && (wave_length_nm <= 509.0))
{
red = 0.0;
green = 1.0;
blue = (wave_length_nm  510.0) / (510.0  490.0);
}
else if ((510.0 <= wave_length_nm) && (wave_length_nm <= 579.0))
{
red = (wave_length_nm  510.0) / (580.0  510.0);
green = 1.0;
blue = 0.0;
}
else if ((580.0 <= wave_length_nm) && (wave_length_nm <= 644.0))
{
red = 1.0;
green = (wave_length_nm  645.0) / (645.0  580.0);
blue = 0.0;
}
else if ((645.0 <= wave_length_nm) && (wave_length_nm <= 780.0))
{
red = 1.0;
green = 0.0;
blue = 0.0;
}
double factor = 0.0;
if ((380.0 <= wave_length_nm) && (wave_length_nm <= 419.0))
factor = 0.3 + 0.7 * (wave_length_nm  380.0) / (420.0  380.0);
else if ((420.0 <= wave_length_nm) && (wave_length_nm <= 700.0))
factor = 1.0;
else if ((701.0 <= wave_length_nm) && (wave_length_nm <= 780.0))
factor = 0.3 + 0.7 * (780.0  wave_length_nm) / (780.0  700.0);
else
factor = 0.0;
rgb_t result;
const double gamma = 0.8;
const double intensity_max = 255.0;
#define round(d) std::floor(d + 0.5)
result.red = static_cast<unsigned char>((red == 0.0) ? red : round(intensity_max * std::pow(red * factor, gamma)));
result.green = static_cast<unsigned char>((green == 0.0) ? green : round(intensity_max * std::pow(green * factor, gamma)));
result.blue = static_cast<unsigned char>((blue == 0.0) ? blue : round(intensity_max * std::pow(blue * factor, gamma)));
#undef round
return result;
}
Plot of wavelength from 375725nm looks like below:
So this is more usable in 400725nm. When I visualize same depth map as in method 1, I get below. There is an obvious issue of those black lines which I think indicates minor bug in this code which I haven't looked more deeply. Also violets are bit narrower in this method which causes less contrast for far away objects.