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I want to design a program that can help me assess between 5 pre-defined colors which one is more similar to a variable color, and with what percentage. The thing is that I don't know how to do that manually step by step. So it is even more difficult to think of a program.

More details: The colors are from photographs of tubes with gel that as different colors. I have 5 tubes with different colors were each is representative of 1 of 5 levels. I want to take photographs of other samples and on the computer assess to which level that sample belongs by comparing colors, and I want to know that with a percentage of approximation too. I would like a program that does something like this: http://www.colortools.net/color_matcher.html

If you can tell me what steps to take, even if they are things for me to think and do manually. It would be very helpful.

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I made a minor change to the text, changing a Portuguese word to what I think is the correct English equivalent...change it back if I erred. –  Beska Jan 26 '12 at 12:30
5  
There is a wikipedia article about color difference: en.wikipedia.org/wiki/Color_difference –  Ocaso Protal Jan 26 '12 at 12:32
2  
This should be interesting: stevehanov.ca/blog/index.php?id=116 It explores computing the difference in three different color models. –  Vlad Jan 26 '12 at 12:37
    
Hey @OcasoProtal, that's a great link thanks for sharing. And to the OP, interesting question. –  Perception Jan 26 '12 at 12:42
    
Try to minimize any potential photographic variablity as well...more detail in answer below. –  Beska Jan 26 '12 at 16:37

9 Answers 9

See Wikipedia's article on Color Difference for the right leads. Basically, you want to compute a distance metric in some multidimensional colorspace. But RGB is not "perceptually uniform", so your Euclidean RGB distance metric suggested by Vadim will not match the human-perceived distance between colors. For a start, L*a*b* is intended to be a perceptually uniform colorspace, and the deltaE metric is commonly used. But there are more refined colorspaces and more refined deltaE formulas that get closer to matching human perception.

You'll have to learn more about colorspaces and illuminants to do the conversions. But for a quick formula that is better than the Euclidean RGB metric, just do this: assume that your RGB values are in the sRGB colorspace, find the sRGB to L*a*b* conversion formulas, convert your sRGB colors to L*a*b*, and compute deltaE between your two L*a*b* values. It's not computationally expensive, it's just some nonlinear formulas and some multiplies and adds.

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4  
+1 for "deltaE", that's the most standardized comparison method and there are adaptations of deltaE formula for different use cases. –  Martin Jan 31 '12 at 13:02
    
+1. LUV* gives also very good results –  pnezis Feb 3 '12 at 20:18
1  
You can find the conversion formulas here: brucelindbloom.com/index.html?Equations.html –  Guillermo Gutiérrez Nov 14 '13 at 19:36

Just an idea that first came to my mind (sorry if stupid). Three components of colors can be assumed 3D coordinates of points and then you could calculate distance between points.

F.E.

Point1 has R1 G1 B1
Point2 has R2 G2 B2

Distance between colors is

d=sqrt((r2-r1)^2+(g2-g1)^2+(b2-b1)^2)

Percentage is

p=d/sqrt((255)^2+(255)^2+(255)^2)
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11  
If we're using the RGB colorspace the difference between 2 colors isn't the same as how humans perceive the difference though. But yes the basic idea is the same everywhere - we'd just have to map it into another color space (lab I'd think) –  Voo Jan 26 '12 at 12:49
5  
@Voo: I agree, HSV/HSL/LAB would be significantly better colour spaces than (s)RGB for distance-based similarity matching. –  Jon Purdy Jan 26 '12 at 13:11
2  
This is a good way of telling you how different two colors ARE, but does a poor job of telling you how different they will be PERCEIVED. Human eyes are far from perfect: we're more sensitive to green than red or blue, our brightness perception is logrithmic, etc. OP never specified which s/he wants; but see here for an algorithm specially-tailored for human sight. –  BlueRaja - Danny Pflughoeft Jan 26 '12 at 17:57

A color value has more than one dimension, so there is no intrinsic way to compare two colors. You have to determine for your use case the meaning of the colors and thereby how to best compare them.

Most likely you want to compare the hue, saturation and/or lightness properties of the colors as oppposed to the red/green/blue components. If you are having trouble figuring out how you want to compare them, take some pairs of sample colors and compare them mentally, then try to justify/explain to yourself why they are similar/different.

Once you know which properties/components of the colors you want to compare, then you need to figure out how to extract that information from a color.

Most likely you will just need to convert the color from the common RedGreenBlue representation to HueSaturationLightness, and then calculate something like

avghue = (color1.hue + color2.hue)/2
distance = abs(color1.hue-avghue)

This example would give you a simple scalar value indicating how far the gradient/hue of the colors are from each other.

See HSL and HSV at Wikipedia.

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1  
From the stuff I remember from my lectures about these things I would convert the image into the Lab color space and not HSV/HSL though. Any reasoning for picking that one? –  Voo Jan 26 '12 at 12:55
    
Nope. RGB and HSL are the ones I'm most familiar with, so I picked HSL just to underscore the idea that the "default" RGB is not the only option -- it really depends on the application. Thanks for letting me know about the Lab color space. –  Supr Jan 26 '12 at 13:11
    
I gave you +1 anyhow because the basic principle here is the "right" answer (convert in color space that handles perceived difference uniformly then do comparison). I'm not that sure which space would be the best - all these different color spaces are confusing as hell imo ;) –  Voo Jan 26 '12 at 13:27

If you have two Color objects c1 and c2, you can just compare each RGB value from c1 with that of c2.

int diffRed   = Math.abs(c1.getRed()   - c2.getRed());
int diffGreen = Math.abs(c1.getGreen() - c2.getGreen());
int diffBlue  = Math.abs(c1.getBlue()  - c2.getBlue());

Those values you can just divide by the amount of difference saturations (255), and you will get the difference between the two.

float pctDiffRed   = (float)diffRed   / 255;
float pctDiffGreen = (float)diffGreen / 255;
float pctDiffRed   = (float)diffBlue  / 255;

After which you can just find the average color difference in percentage.

(pctDiffRed + pctDiffGreen + pctDiffBlue) / 3 * 100

Which would give you a difference in percentage between c1 and c2.

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2 more minor things: <b>1</b> pctDiffRed = diffRed / 255; is going to give you 0 unless you cast to a float somewhere. <b>2</b> You'll need to multiply by 100 somewhere to get a percentage. –  Baqueta Jan 26 '12 at 12:34
10  
This may not give the best "visible" difference, since the human eye perceives color changes differently. That being said, I'm guessing this is exactly what she's looking for, because she's probably looking for a equally quantifiable difference rather than a percieved difference. Just thought I'd this out here as something to consider in case it's relevant. –  Beska Jan 26 '12 at 12:34
    
@PeterLang, Baqueta, thank you for the feedback. I have updated my answer. –  kba Jan 26 '12 at 12:37

Just another answer, although it's similar to Supr's one - just a different color space.

The thing is: Humans perceive the difference in color not uniformly and the RGB color space is ignoring this. As a result if you use the RGB color space and just compute the euclidean distance between 2 colors you may get a difference which is mathematically absolutely correct, but wouldn't coincide with what humans would tell you.

This may not be a problem - the difference is not that large I think, but if you want to solve this "better" you should convert your RGB colors into a color space that was specifically designed to avoid the above problem. There are several ones, improvements from earlier models (since this is based on human perception we need to measure the "correct" values based on experimental data). There's the Lab colorspace which I think would be the best although a bit complicated to convert it to. Simpler would be the CIE XYZ one.

Here's a site that lists the formula's to convert between different color spaces so you can experiment a bit.

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actually I walked the same path a couple of month ago. there is no perfect answer to the question (that was asked here a couple of time) but there is one more sophisticated then the sqrt(r-r) etc answer and more easy to implent directly with RGB without moving to all kind of alternate color spaces. I found this formula here which is a low cost approximation of the quite complicated real formula (by the CIE which is the W3C of color, since this is a not finished quest, you can find older and simpler color difference equations there). good luck

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I expect you want to analyze a whole image at the end, don't you? So you could check for the smallest/highest difference to the identity color matrix.

Most math operations for processing graphics use matrices, because the possible algorithms using them are often faster than classical point by point distance and comparism calculations. (e.g. for operations using DirectX, OpenGL, ...)

So I think you should start here:

http://en.wikipedia.org/wiki/Identity_matrix

http://en.wikipedia.org/wiki/Matrix_difference_equation

... and as Beska already commented above:

This may not give the best "visible" difference...

Which means also that your algorithm depends onto your definiton of "similar to" if you are processing images.

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The best way is deltaE. DeltaE is a number that shows the difference of the colors. If deltae < 1 then the difference can't recognize by human eyes. I wrote a code in canvas and js for converting rgb to lab and then calculating delta e. On this example the code is recognising pixels which have different color with a base color that I saved as LAB1. and then if it is different makes those pixels red. You can increase or reduce the sensitivity of the color difference with increae or decrease the acceptable range of delta e. In this example I assigned 10 for deltaE in the line that I wrote (deltae <= 10):

<script>   
  var constants = {
    canvasWidth: 700, // In pixels.
    canvasHeight: 600, // In pixels.
    colorMap: new Array() 
          };



  // -----------------------------------------------------------------------------------------------------

  function fillcolormap(imageObj1) {


    function rgbtoxyz(red1,green1,blue1){ // a converter for converting rgb model to xyz model
 var red2 = red1/255;
 var green2 = green1/255;
 var blue2 = blue1/255;
 if(red2>0.04045){
      red2 = (red2+0.055)/1.055;
      red2 = Math.pow(red2,2.4);
 }
 else{
      red2 = red2/12.92;
 }
 if(green2>0.04045){
      green2 = (green2+0.055)/1.055;
      green2 = Math.pow(green2,2.4);    
 }
 else{
      green2 = green2/12.92;
 }
 if(blue2>0.04045){
      blue2 = (blue2+0.055)/1.055;
      blue2 = Math.pow(blue2,2.4);    
 }
 else{
      blue2 = blue2/12.92;
 }
 red2 = (red2*100);
 green2 = (green2*100);
 blue2 = (blue2*100);
 var x = (red2 * 0.4124) + (green2 * 0.3576) + (blue2 * 0.1805);
 var y = (red2 * 0.2126) + (green2 * 0.7152) + (blue2 * 0.0722);
 var z = (red2 * 0.0193) + (green2 * 0.1192) + (blue2 * 0.9505);
 var xyzresult = new Array();
 xyzresult[0] = x;
 xyzresult[1] = y;
 xyzresult[2] = z;
 return(xyzresult);
} //end of rgb_to_xyz function
function xyztolab(xyz){ //a convertor from xyz to lab model
 var x = xyz[0];
 var y = xyz[1];
 var z = xyz[2];
 var x2 = x/95.047;
 var y2 = y/100;
 var z2 = z/108.883;
 if(x2>0.008856){
      x2 = Math.pow(x2,1/3);
 }
 else{
      x2 = (7.787*x2) + (16/116);
 }
 if(y2>0.008856){
      y2 = Math.pow(y2,1/3);
 }
 else{
      y2 = (7.787*y2) + (16/116);
 }
 if(z2>0.008856){
      z2 = Math.pow(z2,1/3);
 }
 else{
      z2 = (7.787*z2) + (16/116);
 }
 var l= 116*y2 - 16;
 var a= 500*(x2-y2);
 var b= 200*(y2-z2);
 var labresult = new Array();
 labresult[0] = l;
 labresult[1] = a;
 labresult[2] = b;
 return(labresult);

}

    var canvas = document.getElementById('myCanvas');
    var context = canvas.getContext('2d');
    var imageX = 0;
    var imageY = 0;

    context.drawImage(imageObj1, imageX, imageY, 240, 140);
    var imageData = context.getImageData(0, 0, 240, 140);
    var data = imageData.data;
    var n = data.length;
   // iterate over all pixels

    var m = 0;
    for (var i = 0; i < n; i += 4) {
      var red = data[i];
      var green = data[i + 1];
      var blue = data[i + 2];
    var xyzcolor = new Array();
    xyzcolor = rgbtoxyz(red,green,blue);
    var lab = new Array();
    lab = xyztolab(xyzcolor);
    constants.colorMap.push(lab); //fill up the colormap array with lab colors.         
      } 

  }

// -----------------------------------------------------------------------------------------------------

    function colorize(pixqty) {

         function deltae94(lab1,lab2){    //calculating Delta E 1994

         var c1 = Math.sqrt((lab1[1]*lab1[1])+(lab1[2]*lab1[2]));
         var c2 =  Math.sqrt((lab2[1]*lab2[1])+(lab2[2]*lab2[2]));
         var dc = c1-c2;
         var dl = lab1[0]-lab2[0];
         var da = lab1[1]-lab2[1];
         var db = lab1[2]-lab2[2];
         var dh = Math.sqrt((da*da)+(db*db)-(dc*dc));
         var first = dl;
         var second = dc/(1+(0.045*c1));
         var third = dh/(1+(0.015*c1));
         var deresult = Math.sqrt((first*first)+(second*second)+(third*third));
         return(deresult);
          } // end of deltae94 function
    var lab11 =  new Array("80","-4","21");
    var lab12 = new Array();
    var k2=0;
    var canvas = document.getElementById('myCanvas');
                                        var context = canvas.getContext('2d');
                                        var imageData = context.getImageData(0, 0, 240, 140);
                                        var data = imageData.data;

    for (var i=0; i<pixqty; i++) {

    lab12 = constants.colorMap[i];

    var deltae = deltae94(lab11,lab12);     
                                        if (deltae <= 10) {

                                        data[i*4] = 255;
                                        data[(i*4)+1] = 0;
                                        data[(i*4)+2] = 0;  
                                        k2++;
                                        } // end of if 
                                } //end of for loop
    context.clearRect(0,0,240,140);
    alert(k2);
    context.putImageData(imageData,0,0);
} 
// -----------------------------------------------------------------------------------------------------

$(window).load(function () {    
  var imageObj = new Image();
  imageObj.onload = function() {
  fillcolormap(imageObj);    
  }
  imageObj.src = './mixcolor.png';
});

// ---------------------------------------------------------------------------------------------------
 var pixno2 = 240*140; 
 </script>
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You'll need to convert any RGB colors into the Lab color space to be able to compare them in the way that humans see them. Otherwise you'll be getting RGB colors that 'match' in some very strange ways.

The wikipedia link on Color Differences gives you an intro into the various Lab color space difference algorithms that have been defined over the years. The simplest that just checks the Euclidian distance of two lab colours, works but has a few flaws.

Conveniently there's a Java implementation of the more sophisticated CIEDE2000 algorithm in the OpenIMAJ project. Provide it your two sets of Lab colours and it'll give you back single distance value.

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