# Best algorithm for matching colours.

I have an array of around 200 colours in RGB format. I want to write a program that takes any RGB colour and tries to match a colour from the array that is most "similar".

I need a good definition for "similar", which is as close as possible to human perception.

I also want to show some information about matching accuracy. For example black-white: 100% and for a similar colour with a slightly different hue: -4%.

Do I need to use neural networks? Is there an easier alternative?

• Is the question about a suggestion as to what may be a good similarity function, or is it about an algorithm to quickly find the most similar color(s) in the the array, relative to a give color ?
– mjv
Nov 5, 2009 at 5:15
• Both. If first I need some definition of similarity before I can try crating algorithm. I think "perceptually similar" is what I was looking for. Nov 5, 2009 at 5:22

Convert all of the colors to the CIE Lab color space and compute the distance in that space

``````deltaE = sqrt(deltaL^2 + deltaA^2 + deltaB^2)
``````

Colors with the lowest deltaE are the most perceptually similar to each other.

• Keep in mind you don't need to do the sqrt - sqrt is an increasing function, therefore this step is superfluous. Nov 5, 2009 at 5:18
• You're right, if you're doing nothing more than sorting, the square of the distance is as good as the distance itself. If you want to compare "how different', then leave it in. Nov 5, 2009 at 5:22
• CIE Lab is used in exactly this manner to do nearest-color calculations in all the major color management systems, such as the ones from Apple, Microsoft, and Adobe. It's a very interesting topic. Nov 6, 2009 at 5:41
• What's a good low value for deltaE from your experience? i.e. when deltaE < 14, colors are perceptually similar. Jul 21, 2014 at 21:34
• @MariusAndreiana Using the usual scaling of Lab values, a difference of about deltaE=1 is the smallest difference that people can see, and the biggest difference representable on a monitor is maybe 150-200. It's up to you to decide where "similar" ends and "not similar" starts :) Jul 21, 2014 at 22:12

No, you do not need neural networks here! Simply consider an HSL color value a vector and define a weighted modulus function for the vector like this:

``````modulus = sqrt(a*H1*H1 + b*S1*S1 + c*L1*L1);

where a,b,c are weights you should decide based on your visual definition of what
creates a bigger difference in perceived color - a 1% change in Hue or a 1%
change in Saturation
``````

I would suggest you use a = b = 0.5 and c = 1

Finally, find out the range your modulus would take and define similar colors to be those which have their moduli very close to each other (say 5%)

• That's a good simple alternative. The conversion from RGB to HSL is a lot simpler than the conversion from RGB to Lab. :) Nov 5, 2009 at 5:30
• Crimson, can you check the math on your modulus there? I don't think it's right. You want something more like `a * (H1 - H2)**2 + `..., yeah? Nov 5, 2009 at 6:21
• @hobbs - it would be better to calculate both moduli and then compare them rather than just compute the modulus of the difference vector Nov 5, 2009 at 6:38
• But you don't want to multiply the hues, etc. of the two different colors, do you? Nov 5, 2009 at 7:55
• Hi, I was wondering what you mean by "find out the range your modulus would take"? Do we just compare the two moduli of colors using abs(mod1 - mod2) or something or does "find out the range" mean something different? Jul 29, 2013 at 10:18

I'd also point out the least squares method, just as something slightly simpler. That is, you take the difference of a number, square it, then sum all these squared differences.

I faced the same problem recently, and compared various algorithms I found online. At first I was hesitant to use CIELAB color space due to its complexity, but it's really not as bad as it looks at first. Here's all the code you'll need to compare two RGB values.

``````struct CIELAB {
float L, a, b;
};

float gammaCorrect( float v )
{
return 100.0f * (v <= 0.04045f ? v / 12.92f : powf( (v + 0.055f) / 1.055f, 2.4f ));
}

float nonlinearToLinear( float v )
{
return v > 0.008856f ? cbrtf( v ) : 7.787f * v + 16.0f / 116.0f;
}

CIELAB RGBToCIELAB( int R, int G, int B )
{
float red = gammaCorrect( R / 255.0f );
float green = gammaCorrect( G / 255.0f );
float blue = gammaCorrect( B / 255.0f );

float xr = nonlinearToLinear( (red * 0.4124564f + green * 0.3575761f + blue * 0.1804375f) / 95.047f );
float yr = nonlinearToLinear( (red * 0.2126729f + green * 0.7151522f + blue * 0.0721750f) / 100.000f );
float zr = nonlinearToLinear( (red * 0.0193339f + green * 0.1191920f + blue * 0.9503041f) / 108.883f );

return { 116.0f * yr - 16.0f, 500.0f * (xr - yr), 200.0f * (yr - zr) };
}

float similarity( int R0, int G0, int B0, int R1, int G1, int B1 )
{
CIELAB lab0 = RGBToCIELAB( R0, G0, B0 );
CIELAB lab1 = RGBToCIELAB( R1, G1, B1 );
float dL = lab0.L - lab1.L;
float da = lab0.a - lab1.a;
float db = lab0.b - lab1.b;
return dL*dL + da*da + db*db;
}
``````

For the similarity() function, the lower the result the better the match. For improved efficiency, pre-convert your RGB color list into CIELAB space.

If a simpler algorithm is desired, Wikipedia's Color difference page has an algorithm that works pretty well. You can implement it using integer arithmetic, and if only comparing similarities you can skip the square-root computation.

``````int similarity( int R0, int G0, int B0, int R1, int G1, int B1 )
{
int dr = R0 - R1;
int dg = G0 - G1;
int db = B0 - B1;
int redsum = R0 + R1;
return (1024 + redsum) * dr*dr + 2048 * dg*dg + (1534 - redsum) * db*db;
}
``````

The computation will not exceed 32-bit signed integers.

I found this matching to be noticeably inferior to matching in CIELAB space, but the computation is trivial.

I also tried matching in HSV color space but did not get good results for some color pairs. For example, pure white and pure black (which are as different as can be) can have the same hue and saturation, so might match better than you'd like.

I was looking for the thing but having not found a lot answers around I decided to create this little library.

https://github.com/sebastienjouhans/c-sharp-colour-utilities

• Please be very careful when posting answers that promote your own work. Make sure that you actually answer the question here and only use your blog/source as backup and reference. At the moment this is likely to be flagged as spam.
– ChrisF
Apr 8, 2013 at 22:10

The fastest way I've achieved this is to add the colors to an octree and then, just as with quantization, you use each bit to guide you to the deepest child node. Once you can go no deeper, either you're at the deepest level (the lowest bit), in which case you've hit the exact color, or the next child node you need doesn't exist--at which point you just need the child with the bit that's closest to the bit you're searching for and that's your closest color. It's a heck of a lot faster than converting everything to HSL and back, or calculating every single Euclidean distance.

Here's my code on CodeProject: https://www.codeproject.com/tips/1046574/octtree-based-nearest-color-search

Here is the complete code Python for finding the name of a colour given an arbitrary value in RGB.

``````import matplotlib.colors as mc
import numpy as np
from scipy.spatial import KDTree
import cv2

class ColorNamer:
def __init__(self):
self.clut = {}
self.clut_list = []
self.clut_tree = None

for name in mc.XKCD_COLORS:
rgb = mc.to_rgb(mc.XKCD_COLORS[name])
lab = cv2.cvtColor(np.single([[rgb]]), cv2.COLOR_RGB2Lab)
self.clut[tuple(lab)] = name[5:]
self.clut_list = list(self.clut.keys())
self.clut_tree = KDTree(self.clut_list)

def name(self, rgb):
lab = tuple(cv2.cvtColor(np.single([[rgb]]), cv2.COLOR_RGB2Lab))
dist, point = self.clut_tree.query(lab, 1)
idx = int(point)
key = self.clut_list[idx]
return self.clut[key]

if __name__ == '__main__':
cn = ColorNamer()
print(cn.name((.3211, .543, .633)))
``````