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Scenario :

I am trying to track two different colored objects. At the beginning, user is prompted to hold the first colored object (say, may be a RED) at a particular position in front of camera (marked on screen by a rectangle) and press any key, then my program takes that portion of frame (ROI) and analyze the color in it, to find what color to track. Similarly for second object also. Then as usual, use cv.inRange function in HSV color plane and track the object.

What is done :

I took the ROI of object to be tracked, converted it to HSV and checked the Hue histogram. I got two cases as below :

enter image description here enter image description here

( here there is only one major central peak. But in some cases, I get two such peaks, One a bigger peak with some pixel cluster around it, and second peak, smaller than first one, but significant size with small cluster around it also. I don't have an sample image of it now. But it almost look like below (created in paint))

enter image description here

Question :

How can I get best range of hue values from these histograms?

By best range I mean, may be around 80-90% of the pixels in ROI lie in that range.

Or is there any better method than this to track different colored objects ?

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Have you tried to normalize color (for example using equalizeHist) before calculating histogram? – ArtemStorozhuk Oct 28 '12 at 18:24
No, I didn't. What is benefit of it? – Abid Rahman K Oct 28 '12 at 18:24
It will improve the contrast of your image and (maybe) there won't be such two peaks - only one. – ArtemStorozhuk Oct 28 '12 at 18:27
Have you considered using a statistical model such as a Bayes classifier? If you have two classes of objects, it will tell you the relative likelihood of a unknown third object to belong to each class. You could then improve it by making it multivariate (for instance using not only hue but also value) you can also add classes to describe background... – Quentin Geissmann Oct 28 '12 at 18:30
@AbidRahmanK Bayes classifier is very simple: from your pixel distribution you could simply calculate the mean and sd. With these two, you can fit a Normal distribution. Then, it is possible to calculate the likelihood of any pixel value to be part of your distributions. You can implement it yourself, but opencv has an implementation. This is interesting because you catch variation (you do not only work on means). Of course, if you have multi-modal histograms, you can fit mixture of Gaussians instead of Gaussians... – Quentin Geissmann Oct 28 '12 at 18:55

If I understand right, the only thing you need here is to find a maximum in a graph, where the maximum is not necessarily the highest peak, but the area with largest density.

Here's a very simple not too scientific but fast O(n) approach. Run the histogram trough a low pass filter. E.g. a moving average. The length of your average can be let's say 20. In that case the 10th value of your new modified histogram would be:

mh10 = (h1 + h2 + ... + h20) / 20

where h1, h2... are values from your histogram. The next value:

mh11 = (h2 + h3 + ... + h21) / 20

which can be calculated much easier using the previously calculated mh10, by dropping it's first component and adding a new one to the end:

mh11 = mh10 - h1/20 + h21/20

Your only problem is how you handle numbers at the edge of your histogram. You could shrink your moving average's length to the length available, or you could add values before and after what you already have. But either way, you couldn't handle peaks right at the edge.

And finally, when you have this modified histogram, just get the maximum. This works, because now every value in your histogram contains not only himself but it's neighbors as well.

A more sophisticated approach is to weight your average for example with a Gaussian curve. But that's not linear any more. It would be O(k*n), where k is the length of your average which is also the length of the Gaussian.

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