Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I am currently implementing an algorithm for identifying the axis of minimum inertia of a colored mass (provided by the second moments). In order to do so, I need to acquire the centre of mass, as given by the first moments.

The weighted averaging function works well, but due to outlier pixels, I am receiving undesired results.

Here is the averaging function:

(e.g. x's weighted average)

for (i = 0, i < rows, i++) {
    for (j = 0, j < cols, j++) {
        if (colorAt(i,j).isForeground()) {
    x_ += i*tempSumX;
    tempSumX = 0;
x_ /= totalForeground; //where x_ represents the x coordinate of the weighted center of mass.

Incorrect Center of Mass

Given an image such as this, which is represented by exclusively two colors (background and foreground), how can I remove outlying pixels? Note: Outlying pixels refers to anything not part of the big color-mass. The white dot is the calculated center of mass, which is incorrect.

Much appreciated.

share|improve this question
Have you looked at morphological filters? – mathematician1975 Jul 13 '12 at 13:53
I considered them, but I'm not sure how well they will work in my case. Just not too well-informed. I was also looking at graph theory to identify connections. – JT Cho Jul 13 '12 at 13:55
It does not look like an average, or do you have any outliers not visible in the image? What exactly do you weigh when calculating the weighted average? – TaZ Jul 13 '12 at 17:45
"due to outlier pixels, I am receiving undesired results." On images where there are no smaller, separate pixels as in the one I show, the weighted center of mass is correct. Or perhaps not. Allow me to look at my program again.. – JT Cho Jul 13 '12 at 19:43
The current algorithm I'm using for weighted average is in the post above now. – JT Cho Jul 13 '12 at 19:52
up vote 1 down vote accepted

There are a lot of flood fill algorithms that would identify all the connected pixels given a starting point.

Alternatively a common way to remove small outliars like these that come from noise is to erode the image, then dilate it to return to the same size - although if you are purely doing CoG you don't necessarily need the dilate step

share|improve this answer
I was looking at morphological filters on mathematician1975's recommendation, but I became confused on what Structuring Element I would use. The general principle makes sense, but I wasn't quite sure about the SE stuff. If I were to use flood fill, would I simply use it multiple times to identify which shape is the largest? That is, how would I know where to begin searching? – JT Cho Jul 13 '12 at 14:18
FloodFill seems to be a good approach to me. Even if you use connected component labeling you'll have to decide which blob to use. There's an OpenCV example here:…. You can then get OpenCV to calculate the moments for you:… – beaker Jul 16 '12 at 18:37
Thanks for your help! I ended up using a connected component labeling algorithm since it's better suited for what I need, however. Thanks for the OpenCV API link, beaker... although I already wrote all the code for the moments myself beforehand. Whoops. – JT Cho Jul 17 '12 at 16:15

I believe your algorithm is incorrect. m10 (sorry, I couldn't figure out how to do subscripts) in a binary image is the summation of the x-coordinates of the foreground pixels, so your code should be something like:

for (i = 0, i < rows, i++) {
    for (j = 0, j < cols, j++) {
        if (colorAt(i,j).isForeground()) {
            tempSumX += i;
x_ = tempSumX/totalForeground; //where x_ represents the x coordinate of the weighted center of mass.

Assuming this is related to your previous post Algorithm for Finding Longest Stretch of a Value at any Angle in a 2D Matrix, you should compute the other first and second order moments in the same loop:

m01 += j;
m20 += i*i;
m02 += j*j;
m11 += i*j;

(tempSumX in your algorithm is just m10 and totalForeground is m00)

Give this a try and if you're still having trouble with the outliers you can use Connected Component Labeling to find the largest mass. (Available in matlab using bwlabel or bwconncomp.)

share|improve this answer
That's effectively what I'm doing, except you've simplified it by removing the multiplication aspect. tempSumX++ in the loop, with tempSumX*i outside is exactly the same thing as tempSumX + i in the loop. The problem with the image is that I swapped the x and y coordinates for the Point in the image. The weighting algorithm works properly. I did try a connected-component labeling algorithm after I asked the question, but I had problems finding a good union-find implementation in C++. Any recommendations? – JT Cho Jul 13 '12 at 22:11
So you are. I guess I got confused by the max x-dimension being rows and the max y-dimension being cols. Sorry, I don't happen to have a good union-find implementation that I can point you to. – beaker Jul 13 '12 at 22:26
Are you sure your colorAt(i,j) function takes y (row) as the first argument and x (column) as the second? Perhaps the mistake lies there. Because you report correct results when you swap the coordinates. I'd suggest using y and x instead of i and j for clarity. EDIT: Meh, now I got confused too. The suggestion to rename your variables still stand. – TaZ Jul 14 '12 at 0:32
I used a colorAt function for simplification. I'm using OpenCV, and Matrix data is stored in an array of uchars. So the data accessing is correct, as I've used it for numerous other color calculations before. I concur on the name-changes, I will probably do that simply to make my life easier. Turns out most of my problems are now based on my k-means not being precise enough... – JT Cho Jul 14 '12 at 2:33

How about, in pseudo code:

for( y = 0; y < rows; y++ )
   for ( x = 0; x < cols; x++ )
       if ( pixel( x, y ).isColor() )
          int sum = 0;
          // forgetting about edge cases for clarity...
          if ( !pixel( x-1, y-1 ).isColor() ) sum++;
          if ( !pixel( x,   y-1 ).isColor() ) sum++;
          if ( !pixel( x+1, y-1 ).isColor() ) sum++;
          if ( !pixel( x-1, y   ).isColor() ) sum++;
          if ( !pixel( x+1, y   ).isColor() ) sum++;
          if ( !pixel( x-1, y+1 ).isColor() ) sum++;
          if ( !pixel( x,   y+1 ).isColor() ) sum++;
          if ( !pixel( x+1, y+1 ).isColor() ) sum++;
          if ( sum >= 7 )
             pixel( x, y ).setBackground();
             x -= 1;
             y -= 1;

That is remove any pixel surrounded by 7 background pixels. If you change the color of a pixel back up to the earliest pixel which may now be affected.

Your measure of "outlier" could change - e.g. you could count diagonal pixels as being worth 1/2 as much. E.g. pixels directly above, below, left and right count for 2. And then use a different number for the sum.

You can increase accuracy by increasing the size of the filter - like to a 5x5 instead of a 3x3. In that case pixels 2 away should count for even less.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.