“Rounding” colour values to the nearest of a small set of colours

Preamble

As a part of a project I'm working on I am trying to provide a convenient way to search for images in our system. We currently provide searching by various types of user added metadata (e.g. title, description, keywords) and by various metadata which we extract (e.g. EXIF, IPTC, XMP, etc). I would also like to add a "colour search" similar to what you can see in google's image search.

The project uses PHP and we can use the Imagemagick extension to segment and quantize the image and extract the most "significant" colours from the image; I'm not entirely certain of the results I'm getting here, but they seem reasonably accurate and certainly better than nothing.

The Problem

The bit that I'm having difficulty on is converting these significant colours into a set of representative colours, e.g. when you look at Google's image search there is a set of 12 colours there. I'd like to mathematically "round" my colour value to the nearest representative colour, so that I can index the image with the colours that I detect and then facet my search results that way.

Any suggestions?

• Are you looking to round to those specific 12 colors in Google image search, or was that just an example of color rounding? If the latter, how many colors would you ideally like to end up with? – jwheron Dec 4 '10 at 23:41
• Those 12 would be fine, but I'm not fixed on them. I think that an appropriate approach should work regardless of the values I'm rounding to, so I don't think the actual values are important. – El Yobo Dec 5 '10 at 0:15

The first step would be to define the colors you want to compare to.

The second step is to find the smallest distance from your color to one of the colors you chose in the previous step. In order to be able to measure that distance you need an Euclidian space in which to model colors.

Of course the simple choice would be the RGB space

And the distance between two colors C1(r1, g1, b1) and C2(r2, g2, b2) would be

sqrt( (r1 - r2)2 + (g1 - g2)2 + (b1 - b2)2 ).

But if you need more precision it would be better to use the Hue-Chroma-Lightness bicone space, a derivative of the HSL cylinder.

In the RGB space things were straight forward as R, G and B where each on a separate axis. In HCL we need to compute the coordinates on each of the axis.

First of all we compute the chroma (which is a bit different from saturation) as:

Chroma = max(Red, Green, Blue) - min(Red, Green, Blue)

Then we normalize our H, C and L value so that H goes from 0 to 2 (to cover a circle if we multiply by PI and take radians as the unit), C goes from 0 to 1 (the radius of the trigonometric circle) and L goes from -1 (Black) to 1 (White).

Next we take z = L without any transformations as it is clear from the image that it goes along the vertical axis.

We can easily observe that for a color, Chroma is the distance from the z axis and Hue is the angle. So we get

x = C * cos(H*PI) and
y = C * sin(H*PI)

At this point x, y and z will all be in [-1, 1] and the distance between two colors will be, using the same formula as above,

sqrt( (x1 - x2)2 + (y1 - y2)2 + (z1 - z2)2 ).

To get even more precision and find the closest color according to human color perception you could use the CIE-L*ab modeling space and compute the distance with one of these algorithms. The principles are the same as for the two cases presented above, only the algorithms are more complex.

Update (7 years later)

Finally xkcd featured a comic that I can use in this post!

https://xkcd.com/1882/

• Alin, this definitely sounds interesting, but this is still a little too abstract for me; I have already implemented functions to convert RGB->HSL for other reasons (based on easyrgb.com/index.php?X=MATH&H=18#text18), but I don't see an algorithm for converting to HCL there and I'm not clear from your post what I would do with it once the conversion was done. – El Yobo Dec 5 '10 at 0:19
• @El Yobo I added some instructions on how to compute the distance in HCL. As for what to do with it once the conversion is done, the purpose is to be able to find as precise as possible "the closest color". For that you need to be able to compute "the distance" between colors. The RGB and HCL spaces I proposed give you a suitable medium in which to compute those distances. – Alin Purcaru Dec 5 '10 at 1:01
• @El Yobo Also I'm sorry if I explained if to abstractly. The main thing you need to understand is that you need a good way to spread the colors in space (a modeling space) so that similar colors are as close to each other as possible and that all colors are equally represented. And then check to see to which of your chosen colors a certain color is closest to. – Alin Purcaru Dec 5 '10 at 1:08
• That's a nice descriptive answer. Respect for the effort! – naugtur Dec 6 '10 at 9:54
• Compute the square of the distance in colourspace, rather than the distance. Same "closest" color results, no square root calculation. – Emilio M Bumachar Dec 29 '10 at 12:11

This is a rough idea only - you will need to tweak it to your own needs.

Basically, I thought that, as colors are recorded as RGB, either as a Hex string "#000000" to "#ffffff", or as an RGB set "rgb(0,0,0)" to "rgb(255,255,255)", and these are interchangeable/translateable, this is a simple mathematical rounding issue.

In the full range of colors there would be (16*16)*(16*16)*(16*16) = 256*256*256 = 16,777,216 possible colors.

Rounding colors to their closest single character Hex value reduces that to 16*16*16 = 4,096 possible colors. Still far too many, but getting closer.

Rounding colors to a single character value, but then limiting that further to being one of 4 (0,3,7,f) reduces it to 4*4*4 = 32. Close enough for me.

So, I built a very basic PHP function to try and achieve this:

``````function coloround( \$incolor ){
\$inR = hexdec( \$incolor{0}.\$incolor{1} )+1;
\$inG = hexdec( \$incolor{2}.\$incolor{3} )+1;
\$inB = hexdec( \$incolor{4}.\$incolor{5} )+1;
# Round from 256 values to 16
\$outR = round( \$outR/16 );
\$outG = round( \$outG/16 );
\$outB = round( \$outB/16 );
# Round from 16 to 4
\$outR = round( \$outR/4 );
\$outG = round( \$outG/4 );
\$outB = round( \$outB/4 );
# Translate to Hex
\$outR = dechex( max( 0 , \$outR*4-1 ) );
\$outG = dechex( max( 0 , \$outG*4-1 ) );
\$outB = dechex( max( 0 , \$outB*4-1 ) );
# Output
echo sprintf( '<span style="background-color:#%s;padding:0 10px;"></span> &gt; <span style="background-color:#%s;padding:0 10px;"></span>%s has been rounded to %s<br>' ,
\$incolor , \$outR.\$outG.\$outB ,
\$incolor , \$outR.\$outG.\$outB );
}
``````

This function, when passed a hex string, echos a sample of the original color and a sample of the abbreviated color.

This is just a basic proof-of-concept, as I do not know the format Imagemagick is returning the colors as, but you may be able to utilise this logic to create your own.

From those 32 colors then, you could group the similar (there would probably be about 8 shades of grey in there) and name the remainder to allow your users to search by them.

``````function getSimilarColors (color) {
var base_colors=["660000","990000","cc0000","cc3333","ea4c88","993399","663399","333399","0066cc","0099cc","66cccc","77cc33","669900","336600","666600","999900","cccc33","ffff00","ffcc33","ff9900","ff6600","cc6633","996633","663300","000000","999999","cccccc","ffffff"];

//Convert to RGB, then R, G, B
var color_rgb = hex2rgb(color);
var color_r = color_rgb.split(',')[0];
var color_g = color_rgb.split(',')[1];
var color_b = color_rgb.split(',')[2];

//Create an emtyp array for the difference betwwen the colors
var differenceArray=[];

//Function to find the smallest value in an array
Array.min = function( array ){
return Math.min.apply( Math, array );
};

//Convert the HEX color in the array to RGB colors, split them up to R-G-B, then find out the difference between the "color" and the colors in the array
\$.each(base_colors, function(index, value) {
var base_color_rgb = hex2rgb(value);
var base_colors_r = base_color_rgb.split(',')[0];
var base_colors_g = base_color_rgb.split(',')[1];
var base_colors_b = base_color_rgb.split(',')[2];

//Add the difference to the differenceArray
differenceArray.push(Math.sqrt((color_r-base_colors_r)*(color_r-base_colors_r)+(color_g-base_colors_g)*(color_g-base_colors_g)+(color_b-base_colors_b)*(color_b-base_colors_b)));
});

//Get the lowest number from the differenceArray
var lowest = Array.min(differenceArray);

//Get the index for that lowest number
var index = differenceArray.indexOf(lowest);

//Function to convert HEX to RGB
function hex2rgb( colour ) {
var r,g,b;
if ( colour.charAt(0) == '#' ) {
colour = colour.substr(1);
}

r = colour.charAt(0) + colour.charAt(1);
g = colour.charAt(2) + colour.charAt(3);
b = colour.charAt(4) + colour.charAt(5);

r = parseInt( r,16 );
g = parseInt( g,16 );
b = parseInt( b ,16);
return r+','+g+','+b;
}

//Return the HEX code
return base_colors[index];
}
``````
• What does this do? Why is it good? Code-only answers rarely helpful. – Raphael Apr 1 '17 at 7:33
• This javascript function rounds the input color(which is hex) to the nearest color set in the base_colors variable. Demo: jsfiddle.net/2tc3b1z6/1 – passatgt Apr 30 '17 at 8:56
• "Rounds" how? The accepted answer shows that there are different approaches (in fact, there are infinitely many). Which is yours, and why is it better than others? – Raphael Apr 30 '17 at 8:59
• It seems you do geometric distance, which was given in answers before yours, and is not really a good solution. – Raphael Apr 30 '17 at 9:00
• Method is described into the comments of the code. – passatgt Apr 30 '17 at 9:00

Depending on the number of colors you're looking for, why not try using bitwise operators (PHP's reference here, since you mentioned it in the question) to reduce the number of significant digits? You could round the RGB values before shifting to increase accuracy as well.