GitHub - zhangjingling/Vision-Motion: Computer vision course: optical flow and moving object tracker

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Computer vision course: optical flow and moving object tracker

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Name		Name	Last commit message	Last commit date
Latest commit History 11 Commits
basketball		basketball
basketball_result		basketball_result
flow_result		flow_result
rolling_ball		rolling_ball
rolling_ball_result		rolling_ball_result
walking_person		walking_person
walking_person_result		walking_person_result
CS4731_Homework5.pdf		CS4731_Homework5.pdf
README.txt		README.txt
chooseTarget.m		chooseTarget.m
computeFlow.m		computeFlow.m
drawBox.m		drawBox.m
flow1.png		flow1.png
flow2.png		flow2.png
flow3.png		flow3.png
flow4.png		flow4.png
flow5.png		flow5.png
flow6.png		flow6.png
result1_2.png		result1_2.png
result2_3.png		result2_3.png
result3_4.png		result3_4.png
result4_5.png		result4_5.png
result5_6.png		result5_6.png
runHw5.m		runHw5.m
runTests.m		runTests.m
saveAnnotatedImg.m		saveAnnotatedImg.m
signAcademicHonestyPolicy.m		signAcademicHonestyPolicy.m
simple1.png		simple1.png
simple2.png		simple2.png
simpleresult.png		simpleresult.png
trackingTester.m		trackingTester.m

Repository files navigation

Linxi Fan

All the scripts run successfully in Matlab. 

=============== Challenge 1 ===============
I use the function normxcorr2() to do the template matching. This can be
much faster than a double for-loop with corr2().

It is very tricky to match the template close to the image boundary. My
algorithm takes special care of these cases. 

On top of the brute-force search, I impose a few filtering rules to make the
optical flow more robust.
For example, any flow vector that has length greater than a certain
(variable) threshold will be ruled out. 

This is why you see less noise (random arrows) in the area where there's very 
few texture (e.g. the black region at the bottom right). 
In this way, the annotated image looks much better.

I experimented with a very dense field and saved the results to
the folder "flow_result". The flow field looks highly smooth and robust. 
The screenshots are taken manually for better resolution. 

The script saves the annotated screen with the function 'saveAnnotatedImg'
we used before. The output file names are "result_<i>_<i+1>.png".

The actual grid density I set in runHw5.m is lowered for speed. It takes
around 30 seconds to render 5 annotated images on my laptop. 

- Debug1a
Parameters: 
search_half_window_size = 10;
template_half_window_size = 4;
grid_MN = [32, 24];

- Challenge1a
search_half_window_size = 10;
template_half_window_size = 15;
grid_MN = [32, 24]; 


=============== Challenge 2 ===============
The object tracker works really well on all three data sets.

The annotated image sequences are saved to "*_result" folders.

I modified the trackingTester() signature slightly. Now it takes a third
boolean argument. If true, it uses imshow() to display the annotated image
stack. If false, it silently saves the results to disk. 

The best number of histogram bins is found to be around 16 to 24. 

Note that the box I use is smaller than the bounding box that wraps the
entire object. This makes the tracking much more robust. 
In the "basketball" data set, the tracer does not lose its target when the two
green players overlap (frame 177).