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Surface Reconstruction From Unorganized Point Sets

Surface Reconstruction From Unorganized Point Sets. piyush@cs. Example Reconstruction. Surface Reconstruction Algorithm. Organization of Talk. Problem Statement Some Basic Definitions Hoppe’s Algorithm : The Beginning Alpha Shapes : Generalizations of the convex hull

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Surface Reconstruction From Unorganized Point Sets

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  1. Surface Reconstruction From Unorganized Point Sets piyush@cs

  2. Example Reconstruction Surface Reconstruction Algorithm

  3. Organization of Talk • Problem Statement • Some Basic Definitions • Hoppe’s Algorithm : The Beginning • Alpha Shapes : Generalizations of the convex hull • Crust : A Narrow problem specification • New Algorithms on the Horizon • Open Problems

  4. Problem Statement • Given a set of Sample Points in three dimensions produce a simplicial surface that captures the “most reasonable shape” the points were sampled from. • Applications: CG, Medical Imaging, Cartography, Compression, Reverse Engineering, etc.

  5. Definitions Delaunay Triangulation, Voronoi Diagram[2D,3D]

  6. Hoppe et al’s Algorithm • Estimate Signed Distance Function -ve +ve • Use Iso-Surface Extraction after this step

  7. Hoppe et al’s Algorithm • Tangent Plane Estimation(PCA) • Consistent tangent plane orientation(MST) • Signed distance function • Contour tracing (Marching Cubes)

  8. Principal Component Analysis

  9. PCA

  10. Sample Output

  11. Problems with Hoppe’s Algorithm • All k-nearest neighbors might lie on a single line in some cases hence creating a problem for the normal computation. • The Sampling criterion required is uniform. Sampling ideally should be proportional to curvature in some sense. • Curless Levoy gave a modification which is one of the best results in Practice.

  12. Alpha Shapes The space generated by point pairs that can be touched by an empty disc of radius alpha.

  13. Alpha Shapes Alpha Controls the desired level of detail.

  14. Sample Outputs

  15. Problems with Alpha Shapes • Global Value of Alpha may not exist for a correct reconstruction in some cases • Experimentation is required to find the appropriate values of alpha • A Delaunay computation is done on the point set which is costly in 3D

  16. Crust: A Narrow problem Specification • Aims to reconstruct only smooth closed Manifolds in 2D and 3D Medial Axis: of surface F is the closure of points that have more than one closest point in F.

  17. Definitions Local Feature Size f(p) at a point p on F is the least distance of p to the medial axis. S is called an r-sample of F if every point has a sample within a distance rf(p). p f(p) F

  18. The Intuition behind Crust The Voronoi Cells of a dense sampling are thin and long. The Medial Axis is the extension of Voronoi Diagram for continuous surfaces in the sense that the Voronoi Diagram of S Can be defined as the set of points with more than one closest point in S. (S = Sample Point Set) The Sampling criterion of the Crust breaks down in case of non-smooth curves and surfaces.

  19. The Crust in 2D Input : P = Set of sample points in the plane Output: E = Set of edges connecting points in P The Algorithm Compute the Voronoi vertices of P = V Calculate the Delaunay of (P U V) Pick the edges (p,q) where both p,q are in P

  20. Sample Output

  21. 3D Crust: Definitions Restricted Voronoi Cells: Restricted Delaunay Triangles: A triangle is nonempty. Here S is a surface and p is a sample point. (What is a correct connection in 3D??)

  22. Medial Axis in 3D

  23. The Problem with 3D • Slivers : Even very dense sampling does not guarantee that the Voronoi Vertices approximate the Medial axis which is true in case of 2D Crust. Actually the Voronoi Vertices in 3D can be arbitrarily far from the Medial Axis.

  24. Crust in 3D • Compute the 3D Voronoi diagram of the sample points. • For each sample point s, pick the farthest vertex v of its Voronoi cell, and the farthest vertex v' such that angle vsv' exceeds 90 degrees. • Compute the Voronoi diagram of the sample points and the "poles", the Voronoi vertices chosen in the second step. • Add a triangle on each triple of sample points with neighboring cells in the second Voronoi diagram.

  25. Poles

  26. Sample Output

  27. Problems with Crust • Very Slow in 3D for large pointsets • Cannot handle Boundaries • Cannot deal with Sharp turns and Corners • Needs computation of Delaunay Twice • Theoretically requires very high density sampling in 3D (r <= .06)

  28. The Hot Solutions • Spiralling Edge (P.Crossno & E.Angel, Visualization 99)* • Interactive Approach (L.P.Kobelt and M.Botsch, EuroGraphics 2k) • Surface Reconstruction based on Lower Dimensional Localized Delaunay Triangulation (Gopi et al., Eurographics 2000) • Single Pass Crust(Amenta et al, SoCG 2k)* • Graph-Based Surface Reconstruction Using Structures in Scattered Point Sets (R. MenclandH. Müller in CGI 98)*

  29. Graph Based Reconstruction • EMST Computation • SDG Computation(in successive stages) • Fill SDG(final) with triangles

  30. Single Pass Crust Single Pole Computation Cross section of the Voronoi cell of p in 3 Dimensions If Edge e has three such supporting points, the dual triangle to e is in the crust Edge e x p Near pi/2 angle

  31. Spiralling Edge • Advancing Front Flavour: Uses Edge Rings. • Gabriel Graph Computation in k-nearest neighbours. • Starts with normal information. • Handles Boundary and Corner points as special cases. • No Theoretical Guarantees.

  32. Reviver http://reviver.homepage.com

  33. Reviver

  34. Problems with Reviver

  35. Open Problems • Provable reconstruction for Manifolds with boundary and sharp turns. • Can Provable algorithms be given using subset of Delaunay instead of global Delaunay computation? • Can Unorganised points be decimated before reconstruction?

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