Description
1. (Stereo- 30 points ) Estimate the accuracy of the simple stereo system (Z = f B/d, Figure 3
in the lecture notes of stereo vision) assuming that the only source of noise is the localization of
corresponding points in the two images, which means the error in estimating d. Please derive
(10 points) and discuss (20 points) the dependence of the error in depth estimation of a 3D point
as a function of (1) the baseline width B, (2) the focal length f, (3) stereo matching error,
and (4) the depth of the 3D point, Z.
Hint: Take the partial derivatives of Z with respect to d, assuming that both B and f and constant
parameters.
2. (Motion- 40 points) Could you obtain 3D information of a scene by viewing the scene by a
camera rotating around its optical center (10 points)? Discuss why or why not(10 points). What
about translating the camera along the direction of its optical axis (10 points)? Explain. (10
points)
3. (Motion- 10 points) Explain that the aperture problem can be solved if a corner is visible
through the aperture.
4. (Stereo Programming – 20 points + 20 bonus points ) Use the image pair ( Image 1, Image
2) for the following exercises.
(1). Fundamental Matrix (20 points). – Design and implement a program that, given a stereo
pair, determines at least eight point matches, then recovers the fundamental matrix (10 points )
and the location of the epipoles (5 points) . Check the accuracy of the result by measuring the
distance between the estimated epipolar lines and image points not used by the matrix
estimation (5 points). Also, overlay the epipolar lines of control points and test points on one of
the images (say Image 1- I already did this in the starting code below). Control points are the
correspondences (matches) used in computing the fundamental matrix, and test points are
those used to check the accuracy of the computation.
Hint: As a first step, you can pick up the matches of both the control points and the test points
manually. You may use my matlab code (FmatGUI.m) as a starting point – where I provided an
interface to pick up point matches by mouse clicks. The epipolar lines should be (almost)
parallel in this stereo pair. If not, something is wrong either with your code or the point matches.
*(2). Feature-based matching (10 bonus points). – Design a stereo vision system to do
“feature-based matching” and explain your algorithm in writing – what the feature is, how effect it
is, and what are the problems. The system should have a user interface that allows a user to
select a point on the first image, say by a mouse click. The system should then find and
highlight the corresponding point on the second image, say using a cross hair points). Try to use
the epipolar geometry derived from (1) in searching correspondences along epipolar lines.
Hint : You may use a similar interface as I did for question (1). You may use the point match
searching algorithm in (1) (if you have done so), but this time you need to constrain your search
windows along the epipolar lines.
*(3) Discussions (10 bonus points). Show your results on points with different properties like
those in corners, edges, smooth regions, textured regions, and occluded regions that are visible
only in one of the images. Discuss for each case, why your vision system succeeds or fails in
finding the correct matches. Compare the performance of your system against a human user
(e.g. yourself) who marks the corresponding matches on the second image by a mouse click.
Computer Science – The City College of New York