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I am trying to study how to use Kalman filter in tracking an object (ball) moving in a video sequence by myself so please explain it to me as I am a child.

  • By some algorithms (color analysis, optical flow...), I am able to get a binary image of each video frame in which there is the tracking object ( white pixels) and background (black pixels) -> I know the object size, object centroid, object position -> Just simple draw a bounding box around the object --> Finish. Why the hell do I need to use Kalman filter here?

  • Ok, somebody told me that because I can not detect the object in each video frame because of noise, I need to use Kalman filter to estimate the position of the object. Ok, fine. But as I know, I need to provide the input to Kalman filter. They are previous state and measurement.

    • previous state ( so I think it is the position, the velocity, acceleration...of the object in the previous frame) -> Ok, this is fine to me.
    • measurement of current state: Here is what I can not understand. What the hell can measurement be? - The position of the object in the current frame? It is funny because if I know the position of the object, all I need is just to draw a simple boundingbox (rectangular) around the object. Why the hell I need Kalman filter here anymore? Therefore, it is impossible to take the position of the object in the current frame as measurement value. - "Kalman Filter Based Tracking in an Video Surveillance System" article says

      The main role of the Kalman filtering block is to assign a tracking filter to each of the measurements entering the system from the optical flow analysis block.

      If you read the full paper, you will see that the author takes the maximum number of blob and the minimum size of the blob as an input to the Kalman filter. How the hell can those parameters be used as measurement?

I think I am in a loop now. I want to use Kalman filter to track the position of an object, but I need to know the position of that object as an input of Kalman filter. What the hell here?

And 1 more question, I dont understand the term "number of Kalman filter". In a video sequence, if there are 2 objects need to track -> need to use 2 Kalman filter? Is that what it means?

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John, it seems you're into Image Processing - could you assist us open this dedicated group: area51.stackexchange.com/proposals/66531/computer-vision/72084 Just vote to questions with less than 10 up votes. Thanks. –  Drazick Mar 1 at 17:53

5 Answers 5

You don't use the Kalman filter to give you an initial estimate of something; you use it to give you an improved estimate based on a series of noisy estimates.

To make this easier to understand, imagine you're measuring something that is not dynamic, like the height of an adult. You measure once, but you're not sure of the accuracy of the result, so you measure again for 10 consecutive days, and each measurement is slightly different, say a few millimeters apart. So which measurement should you choose as the best value? I think it's easy to see that taking the average will give you a better estimate of the person's true height than using any single measurement.

OK, but what has that to do with the Kalman filter?

The Kalman filter is essentially taking an average of a series of measurements, as above, but for dynamic systems. For instance, let's say you're measuring the position of a marathon runner along a race track, using information provided by a GPS + transmitter unit attached to the runner. The GPS gives you one reading per minute. But those readings are inaccurate, and you want to improve your knowledge of the runner's current position. You can do that in the following way:

Step 1) Using the last few readings, you can estimate the runner's velocity and estimate where he will be at any time in the future (this is the prediction part of the Kalman filter).

Step 2) Whenever you receive a new GPS reading, do a weighted average of the reading and of your estimate obtained in step 1 (this is the update part of the Kalman filter). The result of the weighted average is a new estimate that lies in between the predicted and measured position, and is more accurate than either by itself.

Note that you must specify the model you want the Kalman filter to use in the prediction part. In the marathon runner example you could use a constant velocity model.

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Thanks for a nice example. But what i do not understand is about the Measurement equation of Kalman filter when taking about a specific problem ( tracking the location of an object in video sequence). I would appreciate if you could explain it. Thanks –  John Jan 20 '11 at 17:27
    
very nicely explained by @carnieri –  user2396315 May 17 '14 at 10:36

The purpose of the Kalman filter is to mitigate the noise and other inaccuracies in your measurements. In your case, the measurement is the x,y position of the object that has been segmented out of the frame. If you can perfectly segmement out the ball and only the ball from the background for every frame, there is no need for the Kalman filter since your measurements in effect contain no noise.

In most applications, perfect measurements cannot be guaranteed for a number of reasons (change in lighting, change in background, other moving objects, etc.) so there needs to be a way of filtering the measurements to produce the best estimate of the true track.

What the Kalman Filter does is use a model to predict what the next position should be assuming the model holds true, and then compares that estimate to the actual measurement you pass in. The actual measurement is used in conjunction with the prediction and noise characteristics to form the final position estimate and update a characterization of the noise (measure of how much the measurements are differing from the model).

The model could be anything that models the system you are trying to track. A common model is a constant velocity model which just assumes that the object will continue to move with the same velocity as in the previous estimate. This is not to say that this model will not track something with a changing velocity since the measurements will reflect the change in velocity and affect the estimate.

There are a number of ways you can attack the problem of tracking multiple objects at once. The simplest way is to use an independent Kalman filter for each track. This is where the Kalman filter really starts to pay off because if you are using the simple approach of just using the centroid of a bounding box, what happens if the two objects cross one another? Can you again differentiate which object is which after they separate? With the Kalman filter, you have the model and prediction that will help keep the track correct when other objects are interfering.

There are also more advanced ways of tracking multiple objects jointly like a JPDAF.

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Hello, thanks for explanation. Could you please explain the part "MEASUREMENT of current state....." in my posted question. –  John Jan 20 '11 at 16:56

Jason has given a good start on what Kalman filter is. In regard to your question as to how the paper can use the maximum number of blobs and the minimum size of the blob, this is exactly the power of Kalman filter.

A measurement needs not be a position, a velocity or an acceleration. A measurement can be any quantity that you can observe at a time instance. If you can define a model that predict your measurement in the next time instance given the current measurement, Kalman filter can help you mitigate the noise.

I would suggest you look into more introductory materials on Image Processing and Computer Vision. These materials will almost always cover Kalman filter.

Here is a SIGGRAPH course on trackers. It is not introductory but should give you a more in-depth look at the topic. http://www.cs.unc.edu/~tracker/media/pdf/SIGGRAPH2001_CoursePack_08.pdf

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Hello, thanks for explanation. I am interested in your answer. If the state equation is x(k) = A.x(k-1) + B.u(k-1) + noise; and measure equation is y(k) = B.u(k) + noise. And if measurement is the number of blob, can you give a simple example of measure equation? (supposed that state of the system is position, velocity, acceleration). Thank you very much. –  John Jan 20 '11 at 17:20

In the case that you can find the ball exactly in every frame, you don't need a Kalman filter. Just because you find some blog which is likely the ball, it doesn't mean that the center of that blob will be the perfect center of the ball. Think of that as your measurement error. Also, if you happen to pick out the wrong blog, using a Kalman filter would help prevent you from trusting that one wrong measurement. Like you said before, if you can't find the ball in a frame, you can also use the filter to estimate where it is likely to be.

Here are some of the matrices you will need, and my guess at what they would be for you. Since the x and y position of the ball is independent, I think it is easier to have two filters, one for each. Both would look kinda like this:

x = [position ; velocity] //This is the output of the filter P = [1, 0 ; 0 ,1] //This is the uncertainty of the estimation, I am not quite sure what you should have to start, but it will converge once the filter is running. F = [ 1,dt ; 0,1] when you do x*F this will predict the next location of the ball. Notice that this assumes the ball keeps moving with the same velocity as before, and just updates the position. Q = [ 0,0 ; 0,vSigma^2] This is the "process noise". This one of the matrices you tune to make the filter preform well. In your system, velocity can change at any time, but position will never change without the velocity being what changed it. This is confusing. The value should be the standard deviation of what those velocity changes might be. z = [position in x or y] This is your measurement H = [1,0 ; 0,0] This is how your measurement gets applied to your current state. Since you are only measuring position, you only have a 1 in the first row. R = [?] I think you will only need a scalar for R, which is the error in your measurement.

With those matrices you should be able to plug them into the formulas that are everywhere for Kalman filters.

Some good things to read: Kalman filtering demo Another great into, read the page linked to in the third paragraph

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In vision application , it is common to use your results at each frame as measurement, for example location of ball in each frame is good measurement.

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