I am working on motion detection with non-static camera using opencv. I am using a pretty basic background subtraction and thresholding approach to get a broad sense of all that's moving in a sample video. After thresholding, I enlist all separable "patches" of white pixels, store them as independent components and color them randomly with red, green or blue. The image below shows this for a football video where all such components are visible. Moving segments

I create rectangles over these detected components and I get this image:

Original Image

So I can see the challenge here. I want to cluster all the "similar" and close-by components into a single entity so that the rectangles in the output image show a player moving as a whole (and not his independent limbs). I tried doing K-means clustering but since ideally I would not know the number of moving entities, I could not make any progress.

Please guide me on how I can do this. Thanks

  • You may be able to estimate k for clustering by counting blobs in a downsampled version of your segmented image. Mean-shift may be another approach. May 24, 2014 at 8:51
  • @RogerRowland How would downsampling the image to smaller number of bits help? May 24, 2014 at 9:06
  • 2
    – berak
    May 24, 2014 at 9:32
  • Downsampling helps because the small blobs in your image above will coalesce into larger, single blobs - so you get something more like one blob per footballer (or other moving object). Then you count the blobs for a rough estimate of k for clustering and then do the clustering on the full size image. May 25, 2014 at 6:19

4 Answers 4


this problem can be almost perfectly solved by dbscan clustering algorithm. Below, I provide the implementation and result image. Gray blob means outlier or noise according to dbscan. I simply used boxes as input data. Initially, box centers were used for distance function. However for boxes, it is insufficient to correctly characterize distance. So, the current distance function use the minimum distance of all 8 corners of two boxes.

#include "opencv2/opencv.hpp"
using namespace cv;
#include <map>
#include <sstream>

template <class T>
inline std::string to_string (const T& t)
    std::stringstream ss;
    ss << t;
    return ss.str();

class DbScan
    std::map<int, int> labels;
    vector<Rect>& data;
    int C;
    double eps;
    int mnpts;
    double* dp;
    //memoization table in case of complex dist functions
#define DP(i,j) dp[(data.size()*i)+j]
    DbScan(vector<Rect>& _data,double _eps,int _mnpts):data(_data)
        for(int i=0;i<data.size();i++)
    void run()
        dp = new double[data.size()*data.size()];
        for(int i=0;i<data.size();i++)
            for(int j=0;j<data.size();j++)
        for(int i=0;i<data.size();i++)
                vector<int> neighbours = regionQuery(i);
        delete [] dp;
    void expandCluster(int p,vector<int> neighbours)
        for(int i=0;i<neighbours.size();i++)
                vector<int> neighbours_p = regionQuery(neighbours[i]);
                if (neighbours_p.size() >= mnpts)

    bool isVisited(int i)
        return labels[i]!=-99;

    vector<int> regionQuery(int p)
        vector<int> res;
        for(int i=0;i<data.size();i++)
        return res;

    double dist2d(Point2d a,Point2d b)
        return sqrt(pow(a.x-b.x,2) + pow(a.y-b.y,2));

    double distanceFunc(int ai,int bi)
            return DP(ai,bi);
        Rect a = data[ai];
        Rect b = data[bi];
        Point2d cena= Point2d(a.x+a.width/2,
        Point2d cenb = Point2d(b.x+b.width/2,
        double dist = sqrt(pow(cena.x-cenb.x,2) + pow(cena.y-cenb.y,2));
        Point2d tla =Point2d(a.x,a.y);
        Point2d tra =Point2d(a.x+a.width,a.y);
        Point2d bla =Point2d(a.x,a.y+a.height);
        Point2d bra =Point2d(a.x+a.width,a.y+a.height);

        Point2d tlb =Point2d(b.x,b.y);
        Point2d trb =Point2d(b.x+b.width,b.y);
        Point2d blb =Point2d(b.x,b.y+b.height);
        Point2d brb =Point2d(b.x+b.width,b.y+b.height);

        double minDist = 9999999;

        minDist = min(minDist,dist2d(tla,tlb));
        minDist = min(minDist,dist2d(tla,trb));
        minDist = min(minDist,dist2d(tla,blb));
        minDist = min(minDist,dist2d(tla,brb));

        minDist = min(minDist,dist2d(tra,tlb));
        minDist = min(minDist,dist2d(tra,trb));
        minDist = min(minDist,dist2d(tra,blb));
        minDist = min(minDist,dist2d(tra,brb));

        minDist = min(minDist,dist2d(bla,tlb));
        minDist = min(minDist,dist2d(bla,trb));
        minDist = min(minDist,dist2d(bla,blb));
        minDist = min(minDist,dist2d(bla,brb));

        minDist = min(minDist,dist2d(bra,tlb));
        minDist = min(minDist,dist2d(bra,trb));
        minDist = min(minDist,dist2d(bra,blb));
        minDist = min(minDist,dist2d(bra,brb));
        return DP(ai,bi);

    vector<vector<Rect> > getGroups()
        vector<vector<Rect> > ret;
        for(int i=0;i<=C;i++)
            for(int j=0;j<data.size();j++)
        return ret;

cv::Scalar HSVtoRGBcvScalar(int H, int S, int V) {

    int bH = H; // H component
    int bS = S; // S component
    int bV = V; // V component
    double fH, fS, fV;
    double fR, fG, fB;
    const double double_TO_BYTE = 255.0f;
    const double BYTE_TO_double = 1.0f / double_TO_BYTE;

    // Convert from 8-bit integers to doubles
    fH = (double)bH * BYTE_TO_double;
    fS = (double)bS * BYTE_TO_double;
    fV = (double)bV * BYTE_TO_double;

    // Convert from HSV to RGB, using double ranges 0.0 to 1.0
    int iI;
    double fI, fF, p, q, t;

    if( bS == 0 ) {
        // achromatic (grey)
        fR = fG = fB = fV;
    else {
        // If Hue == 1.0, then wrap it around the circle to 0.0
        if (fH>= 1.0f)
            fH = 0.0f;

        fH *= 6.0; // sector 0 to 5
        fI = floor( fH ); // integer part of h (0,1,2,3,4,5 or 6)
        iI = (int) fH; // " " " "
        fF = fH - fI; // factorial part of h (0 to 1)

        p = fV * ( 1.0f - fS );
        q = fV * ( 1.0f - fS * fF );
        t = fV * ( 1.0f - fS * ( 1.0f - fF ) );

        switch( iI ) {
        case 0:
            fR = fV;
            fG = t;
            fB = p;
        case 1:
            fR = q;
            fG = fV;
            fB = p;
        case 2:
            fR = p;
            fG = fV;
            fB = t;
        case 3:
            fR = p;
            fG = q;
            fB = fV;
        case 4:
            fR = t;
            fG = p;
            fB = fV;
        default: // case 5 (or 6):
            fR = fV;
            fG = p;
            fB = q;

    // Convert from doubles to 8-bit integers
    int bR = (int)(fR * double_TO_BYTE);
    int bG = (int)(fG * double_TO_BYTE);
    int bB = (int)(fB * double_TO_BYTE);

    // Clip the values to make sure it fits within the 8bits.
    if (bR > 255)
        bR = 255;
    if (bR < 0)
        bR = 0;
    if (bG >255)
        bG = 255;
    if (bG < 0)
        bG = 0;
    if (bB > 255)
        bB = 255;
    if (bB < 0)
        bB = 0;

    // Set the RGB cvScalar with G B R, you can use this values as you want too..
    return cv::Scalar(bB,bG,bR); // R component

int main(int argc,char** argv )
    Mat im = imread("c:/data/football.png",0);
    std::vector<std::vector<cv::Point> > contours;
    std::vector<cv::Vec4i> hierarchy;
    findContours(im.clone(), contours, hierarchy, CV_RETR_LIST, CV_CHAIN_APPROX_SIMPLE);

    vector<Rect> boxes;
    for(size_t i = 0; i < contours.size(); i++)
        Rect r = boundingRect(contours[i]);
    DbScan dbscan(boxes,20,2);
    //done, perform display

    Mat grouped = Mat::zeros(im.size(),CV_8UC3);
    vector<Scalar> colors;
    RNG rng(3);
    for(int i=0;i<=dbscan.C;i++)
    for(int i=0;i<dbscan.data.size();i++)
        Scalar color;
            int label=dbscan.labels[i];
        putText(grouped,to_string(dbscan.labels[i]),dbscan.data[i].tl(),    FONT_HERSHEY_COMPLEX,.5,color,1);




I agree with Sebastian Schmitz: you probably shouldn't be looking for clustering.

Don't expect an uninformed method such as k-means to work magic for you. In particular one that is as crude a heuristic as k-means, and which lives in an idealized mathematical world, not in messy, real data.

You have a good understanding of what you want. Try to put this intuition into code. In your case, you seem to be looking for connected components.

Consider downsampling your image to a lower resolution, then rerunning the same process! Or running it on the lower resolution right away (to reduce compression artifacts, and improve performance). Or adding filters, such as blurring.

I'd expect best and fastest results by looking at connected components in the downsampled/filtered image.

  • "crude a heuristic as k-means": That is a bit negative in my opinion. Example: If you want to cluster images into 10 Colour Buckets and you make a bit of preprocessing (for example delete outlier) it works reasonably well. I haven't seen k-means in Computer Vision though. May 24, 2014 at 11:51
  • Yes, for vector quantization in a clearly linear domain such as RGB space, with limited outliers (due to a finite domain), k-means works reasonably well. Once you don't know k, have nonlinear attributes, missing values, binary values, categorial attributes, attributes with different scale, etc., k-means often yields as-good-as-random results. May 25, 2014 at 15:26
  • 1
    @Anony-Mousse The different pieces in the image do not completely coalesce into one another on downsampling. So it does not give an idea about the number of blobs. Moreover, how shall I generate connected components when I do not know where should I stop connecting the nodes? May 26, 2014 at 6:31
  • Have you considered defining a merge threshold, say 5 pixels, and using that for merging then? Still makes more sense than k-means. May 26, 2014 at 7:34

I am not entirely sure if you are really looking for clustering (in the Data Mining sense).

Clustering is used to group similar objects according to a distance function. In your case the distance function would only use the spatial qualities. Besides, in k-means clustering you have to specify a k, that you probably don't know beforehand.

It seems to me you just want to merge all rectangles whose borders are closer together than some predetermined threshold. So as a first idea try to merge all rectangles that are touching or that are closer together than half a players height.

You probably want to include a size check to minimize the risk of merging two players into one.

Edit: If you really want to use a clustering algorithm use one that estimates the number of clusters for you.


I guess you can improve your original attempt by using morphological transformations. Take a look at http://docs.opencv.org/master/d9/d61/tutorial_py_morphological_ops.html#gsc.tab=0. Probably you can deal with a closed set for each entity after that, specially with separate players as you got in your original image.

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