1. Intrinsic Parameterization for Surface Meshes Mathieu Desbrun, Mark Meyer, Pierre Alliez CS598MJG Presented by Wei-Wen Feng 2004/10/5

2. What’s Parameterization? Find a mapping between original surface and a target domain ( Planar in general )

3. What does it do? Most significant : Texture Mapping Other applications include remeshing, morphing, etc.

4. Two Directions in Research Define metric (energy) measuring distortion Minimize the energy to find mapping This paper’s main contribution

5. Two Directions in Research Using the metric, and make it work on mesh Cut mesh into patches Considering arbitrary genus

6. Outline Previous Work Intrinsic Properties DCP & DAP Boundary Control Future Work

7. Previous Work Discrete Harmonic Map (Eck. 95): Minimize Eharm[h] = ½ ΣK i,j |h(i) – h(j)| 2 K : Spring constant The same as minimize Dirichlet energy

8. Previous Work Shape Preserving Param. (Floater. 97): Represent vertex as convex combination of neigobors Trivial choice : barycenter of neighbors Ensure valid embedding

9. Previous Work Most Isometric Param. (MIPS) (K. Hormann. 99): Doesn’t need to fix boundary Conformal but need to minimize non-linear energy MIPSHarmonic Map

10. Previous Work Signal Specialized Param. (Sander. 02): Minimize signal stretch on the surface when reconstruct from parametrization

11. Intrinsic Parameterization Motivation: Find good distortion measure only depending on the intrinsic properties of mesh Develop good tools for fast parameterization design

12. Intrinsic Properties Defined at discrete suraface, restricted at 1-ring Notion:  Return the “score” of surface patch M E(M,U) : Distortion between mapping Intrinsic Properties: Rotation & Translation Invariance Continuity : Converge to continuous surface Additivity :  (A) +  (B) =  (A  B) +  (A  B)

13. Intrinsic Properties Minkowski Functional  A = Area   = Euler characteristic  P = Perimeter From Hadwiger, the only admissible intrinsic functional is :  a  A + b    + c  P

14. Discrete Conformal Param. Measure of Area (Dirichlet Energy) Conformality is attained when Dirichlet energy is minimum When fixed boundary, it is in fact discrete harmonic map

15. Discrete Authalic Param. Measure of Euler characteristic (Angle) Integral of Gaussian curvature Derived as Chi Energy

16. Comparing DCP & DAP DCP (Dirichlet Energy) Measure area extension Minimized when angles preserved DAP (Chi Energy) Measure angle excess Minimized when area preserved

17. Solving Parametrization General distortion measure : Fix the boundary, minimized the energy : Very sparse linear systems  Conjugate gradient

18. Natural Boundary Instead fixed the boundary, solve for optimal conformal mapping which yields “best” boundary. For interior points For boundary points : Constrain two points to avoid degeneracy.

19. Compare with LSCM Least Square Conformal Map (Levy. ’02) Start from Cauchy-Riemann Equation Theoretically equivalent to Natural Boundary Map Minimize conformal energy Natural Conformal Map Imposing boundary constraint for boundary points

20. Extend to non-linear func. All parametrization could be expressed as : U = U A + (1- ) U  Substitute U in a non-linear function reduces the problem into solving Ex : Could be reduced into root finding

21. Boundary Control Precompute the “impulse response” parameterization for each boundary points New parameterization could be obtained by projecting boundary parameter onto its “ impulse response ” parameterization

22. Boundary Optimization Minimized arbitrary energy with respect to boundary parameterization Using precomputed gradient to accelerate optimization

23. Summary of Contributions A linear system solution for Natural Conformal Map A new geometric metric for parameterization (DAP) Real-time boundary control for better parameterization design

24. What’s Next ? Mean Value Coordinate (Floater. 03) The same property of convex combination Approximating Harmonic Map but ensure a valid embedding TutteHarmonicShape Preserving Mean Value

25. What’s Next ? Spherical Parameterization (Praun. 03) Smooth parameterization for genus-0 model Using existing metric

26. Conclusion There seems to be less paper directly about finding metrics (or find a better way to model them) for parameterization. Now more efforts in finding globally smooth parameterization on arbitrary meshes

27. Thank You

28. References (Eck. 95) Multiresolution Analysis of Arbitrary Meshes. Proceedings of SIGGRAPH 95\ (Floater. 97) Parametrization and Smooth Approximationof Surface Triangulations. Computer Aided Geometric Design 14, 3 (1997) (K. Hormann. 99) MIPS: An Efficient Global Parametrization Method. In Curve and Surface Design: Saint-Malo 1999 (2000) (Sander. 02) Signal-Specialized Parameterization. In Eurographics Workshop on Rendering, 2002.

29. References (Floater, Hormann 03) Surface Parameterization : A Tutorial and Survey (Levy. ’02) Least Squares Conformal Maps for Automatic Texture Atlas Generation. ACM SIGGRAPH Proceedings (Floater. 03) Mean Value Coordinates. Computer Aided Geometric Design 20, 2003