# simple case of optical flow

General: I'm hoping that the use-case I'm about to describe is a simple case of an optical flow problem and since I don't have much knowledge on the subject, I was wondering if anyone has any suggestions on how I can approach solving my problem.

Research I've already done: I have began reading the High Accuracy Optical Flow Estimation Based on a Theory for Warping paper and am planning on looking over the Particle Video paper. I have found a MATLAB High Accuracy Optical Flow implementation of optical flow. However, the papers (and the code) seem to describe concepts that are very involved and may require a lot of time for me to dig in and understand. I am hoping that the solution to my problem may be more simple.

Problem: I have a sequence of images. The images depict a material breakage process, where the material and background are black and the cracks are white. I am interested in traversing the sequence of images in reverse in an attempt to map all of the cracks that have formed in the breakage process to the first black image. You can think of the material as a large puzzle and I am trying to put the pieces back together in the reverse order that they broke.

In each image, there can be some cracks that are just emerging and/or some cracks that have been fully formed (and thus created a fragment). Throughout the breakage process, some fragments may separate and break further. The fragments can also move farther away from one another (the change is slight between subsequent frames).

Desired Output: All of the cracks/lines in the sequence mapped to the first image in the sequence.

Additional Notes: Images are available in grayscale format (i.e. original) as well as in binary format, where the cracks have been outlined in white and the background is completely black. See below for some image examples.

The top row shows the original images and the bottom row shows the binary images. As you can see, the crack that goes down the middle grows wider and wider as the image sequence progresses. Thus, the bottom crack moves together with the lower fragment. When traversing the sequence in reverse, I hope to algorithmically realize that the middle crack comes together as one (and map it correctly to the first image), and also map the bottom crack correctly, keeping its correct correspondence (size and position) with the bottom fragment.

A sequence typically contains about 30~40 images, so I've just shown the beginning subset. Also, although these images don't show it, it is possible that a particular image only contains the beginning of the crack (i.e. its initial appearance) and in subsequent images it gets longer and longer and may join with other cracks.

Language: Although not necessary, I would like to implement the solution using MATLAB (just because most of the other code that relates to the project has been done in MATLAB). However, if OpenCV may be easier, I am flexible in my language/library usage.

Any ideas are greatly appreciated.

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Optical flow won't give you meaningful results for black&white images. Also, your problem is underspecified - what is your desired output? And as always, sample images would of course help to understand the setting. –  etarion May 26 '11 at 16:48
why the last image is not a desired output? Can fragments move increasing gaps to each other? –  Andrey May 26 '11 at 17:26
Please do provide images. In general OF algorithms require textures and are not very suitable for binary images. I would be helpful if you provided the name of the papers you've read instead of a link to a PDF. –  Adi Shavit May 26 '11 at 17:52
@Andrey: Yes, fragments generally tend to move with increasing gaps to each other throughout the sequence. @etarion: The binary images were created because I thought it might make algorithms simpler. Original grayscale images are available (see edit). @Adi: See edit. –  Myx May 26 '11 at 20:57
Your explanation of "Desired Output" is quite short - could you provide an example output dataset that you would hope to extract from these three images? –  Jonas Heidelberg Jun 4 '11 at 15:53