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True FOE Computed FOE Recovering the observer’s rotation Velocity component due to observer’s translation Velocity component due to observer’s rotation.

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Presentation on theme: "True FOE Computed FOE Recovering the observer’s rotation Velocity component due to observer’s translation Velocity component due to observer’s rotation."— Presentation transcript:

1 True FOE Computed FOE Recovering the observer’s rotation Velocity component due to observer’s translation Velocity component due to observer’s rotation Final velocity at each location Velocity perpendicular to field lines must be due to observer’s rotation! Find (R x, R y, R z ) that best explains the motion perpendicular to the field lines Computed FOE  translational field lines

2 Finally, recovering 3D layout Now, how can we compute the relative depth of surfaces in the scene? Given (R x, R y, R z ), compute image motions due to rotation… … then subtract motions due to rotation, to obtain the image motions due to the observer’s translation What are we assuming about objects in the scene? When is this assumption violated?

3 Detecting moving obje cts Noisy velocity field, computed from a scene of rectangular objects at different depths Locations with large velocity changes in the neighborhood – around object boundaries, where depth changes occur Directions of velocity differences, with the “best FOE location” and moving objects

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