1. Projective 2D geometry (cont’) course 3 Multiple View Geometry Modified from Marc Pollefeys’s slides

2. Last class … Points and lines Conics and dual conics Projective transformations

3. Last week … Projective 8dof Affine 6dof Similarity 4dof Euclidean 3dof Concurrency, collinearity, order of contact (intersection, tangency, inflection, etc.), cross ratio Parallellism, ratio of areas, ratio of lengths on parallel lines (e.g midpoints), linear combinations of vectors (centroids). The line at infinity l ∞ Ratios of lengths, angles. The circular points I,J lengths, areas.

4. Projective geometry of 1D The cross ratio Invariant under projective transformations 3DOF (2x2-1)

5. Recovering metric and affine properties from images Parallelism Parallel length ratios Angles Length ratios

6. The line at infinity The line at infinity l  is a fixed line under a projective transformation H if and only if H is an affinity Note: not fixed pointwise

7. Affine properties from images projection rectification

8. Affine rectification v1v1 v2v2 l1l1 l2l2 l4l4 l3l3 l∞l∞

9. Distance ratios

10. The circular points The circular points I, J are fixed points under the projective transformation H iff H is a similarity

11. The circular points “circular points” l∞l∞ Algebraically, encodes orthogonal directions

12. Conic dual to the circular points The dual conic is fixed conic under the projective transformation H iff H is a similarity Note: has 4DOF in projective frame l ∞ is the nullvector

13. Angles Euclidean: Projective: (orthogonal) Projective invariant: We can recover Euclidean  from projective frame!

14. Length ratios

15. Metric properties from images Rectifying transformation from SVD

16. Metric from affine

17. Metric from projective

18. Pole-polar relationship The polar line l=Cx of the point x with respect to the conic C intersects the conic in two points. The two lines tangent to C at these points intersect at x

19. Correlations and conjugate points A correlation is an invertible mapping from points of P 2 to lines of P 2. It is represented by a 3x3 non-singular matrix A as l=Ax Conjugate points with respect to C (on each others polar) Conjugate lines with respect to C * (through each others pole)

20. Projective conic classification DiagonalEquationConic type (1,1,1)improper conic (1,1,-1)circle (1,1,0)single real point (1,-1,0)two lines (1,0,0)single line

21. Affine conic classification ellipseparabolahyperbola

22. Fixed points and lines (eigenvectors H =fixed points) (eigenvectors H - T =fixed lines) ( 1 = 2  pointwise fixed line)

23. Next course: Projective 3D Geometry Points, lines, planes and quadrics Transformations П ∞, ω ∞ and Ω ∞