Presentation is loading. Please wait.

Presentation is loading. Please wait.

Abstraction of Man-Made Shapes Ravish Mehra 1,2, Qingnan Zhou 1, Jeremy Long 4, Alla Sheffer 1, Amy Gooch 4, Niloy J. Mitra 2,3 1 Univ. of British Columbia.

Published byBernadette Goodwin Modified over 9 years ago

Similar presentations

Presentation on theme: "Abstraction of Man-Made Shapes Ravish Mehra 1,2, Qingnan Zhou 1, Jeremy Long 4, Alla Sheffer 1, Amy Gooch 4, Niloy J. Mitra 2,3 1 Univ. of British Columbia."— Presentation transcript:

1 Abstraction of Man-Made Shapes Ravish Mehra 1,2, Qingnan Zhou 1, Jeremy Long 4, Alla Sheffer 1, Amy Gooch 4, Niloy J. Mitra 2,3 1 Univ. of British Columbia 2 IIT Delhi 3 KAUST 4 Univ. of Victoria Abstraction of Man-Made Shapes

2 Human Perception

3 Abstraction of Man-Made Shapes Observation © Succession Picasso

4 Abstraction of Man-Made Shapes Observation o Man-Made objects dominated by flat/smooth faces. o Sharp creases define the shape. Cole et al. 2008

5 Abstraction of Man-Made Shapes Abstract Representation o Abstraction algorithm - curves as building blocks o Extract sparse network of curves + normals o Abstract shape - union of smooth patches

6 Abstraction of Man-Made Shapes o Curve based NPR Suggestive contours [DeCarlo et al. 2003] Apparent ridges [Judd et al. 2007] o Curve based surface modeling Wires [Singh et al. 1998] Fiber Mesh [Nealen et al. 2007] iWires [Gal et al. 2009] o Vector representation Diffusion Curves [Orzan et al. 2008] Related Works

7 Abstraction of Man-Made Shapes Abstraction Pipeline 1. Original model 2. Envelope3. Curve Network 4. Reconstruction result ReconstructionVectorization Envelope generation

8 Abstraction of Man-Made Shapes Challenge o Input contains multiple self-intersecting components. o Can even be a polygon soup.

9 Abstraction of Man-Made Shapes Envelope Generation o Envelope: A tight closed manifold approximation of the original surface.

10 Abstraction of Man-Made Shapes Envelope Generation: Initialization o Initial envelope: A manifold surface loosely follow input’s geometry.

11 Abstraction of Man-Made Shapes Envelope Generation: Iterative Fitting Preserves local details Pulls each vertex towards its original position Pulls each vertex towards its mapped position

12 Abstraction of Man-Made Shapes Envelope Generation

13 Abstraction of Man-Made Shapes Vectorization o Purpose: extract a vector representation o Encodes shape-defining features; concise & enables reconstruction Envelope Vector Representation

14 Abstraction of Man-Made Shapes Vectorization as Mesh Segmentation o Man-made shapes - union of smooth patches. o Vectorization as mesh segmentation problem. Segmentation – collection of charts Each chart should be smooth o Vector representation = boundary of segmentation + associated normals

15 Abstraction of Man-Made Shapes Initial Segmentation o Variational Shape Approximation [Cohen- Steiner et al. 2004]. Speed and simplicity Satisfies smoothness criteria o Topological Simplification Merging small charts Straightening boundaries [ Julius et al. 2005 ]

16 Abstraction of Man-Made Shapes Iterative Improvement o Optimization for each chart Smooth surface  smoothly varying normals Approximate the original shape Smooth boundary  helps subsequent regularization phase

17 Abstraction of Man-Made Shapes Iterative Improvement o Normal solve trade-off between smoothness and original normals o Per-triangle solve vertex positions satisfying desired normals stay close to original positions o Global assembly reconcile different per-triangle vertex positions

18 Abstraction of Man-Made Shapes Iterative Improvement

19 Abstraction of Man-Made Shapes Regularization and Simplification o Regularity local : linear, circular, planar global : parallel, orthogonal, symmetric o Hierarchical simplification higher levels of abstraction simplify network regularize again

20 Abstraction of Man-Made Shapes Curve Extraction Vector representation of 3D Shapes

21 Abstraction of Man-Made Shapes Reconstruction o Reconstruct the abstract model Embed each boundary loop into a plane [Kruskal and Wish 1978] Triangulate the planar loops [Shewchuk 1996] Deform the planar patches using curve’s position and normal as constraints [Popa et al. 2006]

22 Abstraction of Man-Made Shapes Results

23 Abstraction of Man-Made Shapes Eiffel tower 15.6K triangles 2417 components 85 curves140 curves

24 Abstraction of Man-Made Shapes Empire state 16K triangles 17 components 38 curves152 curves

25 Abstraction of Man-Made Shapes Arc de Triomphe 13K triangles 8 components 139 curves193 curves

26 Abstraction of Man-Made Shapes Dome of the Rock 3.8K triangles 2 components 26 curves145 curves

27 Abstraction of Man-Made Shapes Limitations and Future Work o Thin long features that affect topology o Not well-known objects

28 Abstraction of Man-Made Shapes Summary o Algorithm for generating abstractions of 3D man- made models. o Simple yet robust mechanism for approximating polygon soup by a manifold surface. o Novel vector-based representation of 3D geometry.

29 Abstraction of Man-Made Shapes Acknowledgements Sponsored by Adobe Inc. MITACS NCE Microsoft Outstanding Young Faculty Fellowship NSERC Discover Program Thanks Benjamin Cecchetto Derek Bradley Karan Singh Tiberiu Popa Vladislav Kraevoy Xi Chen anonymous reviewers

30 Abstraction of Man-Made Shapes

Download ppt "Abstraction of Man-Made Shapes Ravish Mehra 1,2, Qingnan Zhou 1, Jeremy Long 4, Alla Sheffer 1, Amy Gooch 4, Niloy J. Mitra 2,3 1 Univ. of British Columbia."

Similar presentations

Multi-chart Geometry Images Pedro Sander Harvard Harvard Hugues Hoppe Microsoft Research Hugues Hoppe Microsoft Research Steven Gortler Harvard Harvard.

Multi-chart Geometry Images Pedro Sander Harvard Harvard Hugues Hoppe Microsoft Research Hugues Hoppe Microsoft Research Steven Gortler Harvard Harvard.
Image Segmentation with Level Sets Group reading 22-04-05.

Image Segmentation with Level Sets Group reading
Abstraction of Man-Made Shapes Ravish Mehra 1,2, Qingnan Zhou 1, Jeremy Long 4, Alla Sheffer 1, Amy Gooch 4, Niloy J. Mitra 2,3 1 Univ. of British Columbia.

Abstraction of Man-Made Shapes Ravish Mehra 1,2, Qingnan Zhou 1, Jeremy Long 4, Alla Sheffer 1, Amy Gooch 4, Niloy J. Mitra 2,3 1 Univ. of British Columbia.
 Over-all: Very good idea to use more than one source. Good motivation (use of graphics). Good use of simplified, loosely defined -- but intuitive --

 Over-all: Very good idea to use more than one source. Good motivation (use of graphics). Good use of simplified, loosely defined -- but intuitive --
L1 sparse reconstruction of sharp point set surfaces

L1 sparse reconstruction of sharp point set surfaces
Surface Simplification Using Quadric Error Metrics Speaker: Fengwei Zhang September 20. 2007.

Surface Simplification Using Quadric Error Metrics Speaker: Fengwei Zhang September
GRAPP, Lisbon, February 2009 University of Ioannina Skeleton-based Rigid Skinning for Character Animation Andreas Vasilakis and Ioannis Fudos Department.

GRAPP, Lisbon, February 2009 University of Ioannina Skeleton-based Rigid Skinning for Character Animation Andreas Vasilakis and Ioannis Fudos Department.
Surface Reconstruction From Unorganized Point Sets

Surface Reconstruction From Unorganized Point Sets
Least-squares Meshes Olga Sorkine and Daniel Cohen-Or Tel-Aviv University SMI 2004.

Least-squares Meshes Olga Sorkine and Daniel Cohen-Or Tel-Aviv University SMI 2004.
Consistent Mesh Parameterizations Peter Schröder Caltech Wim Sweldens Bell Labs Emil Praun Princeton.

Consistent Mesh Parameterizations Peter Schröder Caltech Wim Sweldens Bell Labs Emil Praun Princeton.
Extended Gaussian Images

Extended Gaussian Images
Developer’s Survey of Polygonal Simplification Algorithms Based on David Luebke’s IEEE CG&A survey paper.

Developer’s Survey of Polygonal Simplification Algorithms Based on David Luebke’s IEEE CG&A survey paper.
Interactive Inverse 3D Modeling James Andrews Hailin Jin Carlo Séquin.

Interactive Inverse 3D Modeling James Andrews Hailin Jin Carlo Séquin.
Fast and Extensible Building Modeling from Airborne LiDAR Data Qian-Yi Zhou Ulrich Neumann University of Southern California.

Fast and Extensible Building Modeling from Airborne LiDAR Data Qian-Yi Zhou Ulrich Neumann University of Southern California.
Xianfeng Gu, Yaling Wang, Tony Chan, Paul Thompson, Shing-Tung Yau

Xianfeng Gu, Yaling Wang, Tony Chan, Paul Thompson, Shing-Tung Yau
MATHIEU GAUTHIER PIERRE POULIN LIGUM, DEPT. I.R.O. UNIVERSITÉ DE MONTRÉAL GRAPHICS INTERFACE 2009 Preserving Sharp Edges in Geometry Images.

MATHIEU GAUTHIER PIERRE POULIN LIGUM, DEPT. I.R.O. UNIVERSITÉ DE MONTRÉAL GRAPHICS INTERFACE 2009 Preserving Sharp Edges in Geometry Images.
Computer Graphics Group Alexander Hornung Alexander Hornung and Leif Kobbelt RWTH Aachen Robust Reconstruction of Watertight 3D Models from Non-uniformly.

Computer Graphics Group Alexander Hornung Alexander Hornung and Leif Kobbelt RWTH Aachen Robust Reconstruction of Watertight 3D Models from Non-uniformly.
Computing Stable and Compact Representation of Medial Axis Wenping Wang The University of Hong Kong.

Computing Stable and Compact Representation of Medial Axis Wenping Wang The University of Hong Kong.
Dual Marching Cubes: An Overview

Dual Marching Cubes: An Overview
Shape Space Exploration of Constrained Meshes Yongliang Yang, Yijun Yang, Helmut Pottmann, Niloy J. Mitra.

Shape Space Exploration of Constrained Meshes Yongliang Yang, Yijun Yang, Helmut Pottmann, Niloy J. Mitra.

Similar presentations

Ads by Google