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I'm currently working on a project that deals with the reconstruction based on a set of images, in a multi-view stereo approach. As such I need to know the several images pose in space. I find matching features using surf, and from the correspondences I find the essential matrix.

Now comes the problem: It is possible to decompose the essential matrix with SVD, but this can lead to 4 different results, as I read in a book. How can I obtain the correct one, assuming this is possible?

What other algorithms can I use for this?

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2 Answers

Wikipedia says:

It turns out, however, that only one of the four classes of solutions can be realized in practice. Given a pair of corresponding image coordinates, three of the solutions will always produce a 3D point which lies behind at least one of the two cameras and therefore cannot be seen. Only one of the four classes will consistently produce 3D points which are in front of both cameras. This must then be the correct solution.

If you have the extrinsic calibration parameters for the camera in the first frame, or if you assume that it lies at a default calibration, say translation of (0,0,0) and rotation of (0,0,0), then you can determine which of the decompositions is the valid one.

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My idea now is to project the image corners of the reference and of each solution into a plane in front of the reference image. If there is overlapping, then it must be a correct solution. Could this work? –  zync Apr 13 '13 at 21:13
    
If I've understood right, this will only work when the camera is not translating -- rotations can be handled by projecting points on to a plane. –  Zaphod Apr 14 '13 at 13:32
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up vote 1 down vote accepted

Thanks to Zaphod answer I was able to solve my problem. Here's what I did:

First I calculated the Essential Matrix (E) from a set of point correspondences in both images.

Using SVD, decomposed it into 2 solutions. Using the negated Essential Matrix -E (which also satisfies the same constraints) I arrived at 2 more solutions for a total of 4 possible camera positions and orientations.

Then, for all solutions I triangulated the point correspondences and determined which intersected in front of both cameras, by taking the dot product of the point coordinate and each of the cameras viewing direction. I both are positive, then that intersection is in front of both cameras.

In the end the solution that delivers the most intersections in front of the cameras is the chosen one.

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