CHAOS Meeting!

1. CHAOS Meeting! Bill White will present an overview of three papers that were presented at this year’s SIGGRAPH. These papers were selected as being expected to have the greatest overall impact on computer graphics and interactive techniques. “A Morphable Model for the Synthesis of 3D Faces” by Volker Blanz and Thomas Vetter, Max-Planck-Institut für Biologische Kybernetik Wednesday September 8, 1999 4:30 - 5:30 PM Peck Hall 2304 “Teddy: A Sketching Interface for 3D Freeform Design” by Takeo Igarashi and Hidehiko Tanaka, University of Tokyo, and Satoshi Matsuoka, Tokyo Institute of Technology “Graphical Modeling and Animation of Brittle Fracture” by James F. O’Brien and Jessica K. Hodgins, Georgia Institute of Technology

2. “Graphical Modeling and Animation of Brittle Fracture” James F. O’Brien and Jessica K. Hodgins Georgia Institute of Technology

3. Previous work in modeling breaking objects either: • simulated material deformations , generating a fracture whenever the distance between originally close nodes exceeded a certain size, or • used virtual springs to connect masses together until the springs were pulled too far apart. • The two main drawbacks to these techniques: • the exact location and orientation of the fractures is unknown, and • the fracture surfaces are limited to the boundaries of the original mesh structure.

4. This work remedies these two problems by structuring the breakable objects as a 3-D mesh of tetrahedra, each of which can be split into multiple tetrahedra after being fractured. An adobe wall struck by a wrecking ball. The wall is attached to the ground. The same adobe wall struck by a wrecking ball with 50 times the original wrecking ball’s mass.

5. (a) The initial mesh used to generate the face of the adobe wall that is struck by the wrecking ball. (b) The (reassembled) mesh after being struck by the wrecking ball. (c) Same as (b), with cracks emphasized. (d) Internal fractures shown as a wireframe.

6. A simple object and its tetrahedron mesh. The force modes that could make the object open further. Opening Mode In-Plane Shear Mode Out-Of-Plane Shear Mode

7. Splitting a Tetrahedral Element with a Fracture Plane (a) The original tetrahedral element. (b) The splitting node and fracture plane. (c) The element is split into polyhedra that are decomposed into tetrahedra.

8. Comparison of a Real-World Event and a Simulation A physical ceramic bowl dropped from one meter onto a hard surface. A simulation matching the initial conditions of the physical bowl.

10. “A Morphable Model for the Synthesis of 3D Faces” Volker Blanz and Thomas Vetter Max-Planck-Institut für Biologische Kybernetik

11. A data set of prototypical of 3D facial scans is used... …that can be manipulated to have a new orientation, expression, etc. …along with a 2D image of a face... …to produce a parameterization of the 2D face as a linear combination of the faces in the database...

12. Making New Faces from Old Ones Halfway between the average and the prototype The “Anti-Face” - As far from the average as the prototype, but in the opposite way!

13. The 3D Reconstruction The Original Reorientations The 3D Model The Color Map

14. “Teddy: A Sketching Interface for 3D Freeform Design” Takeo Igarashi & Hidehiko Tanaka, University of Tokyo Satoshi Matsuoka, Tokyo Institute of Technology

15. Creating a 3D object with a 2D input stroke. Painting on the surface of the 3D object with a 2D input stroke. Creating an extrusion from the 3D object with a closed stroke, followed by a rotation, and then an extrusion stroke.

16. Cutting off part of the 3D object with a 2D input stroke. Adding an extrusion after cutting the object. Scribbling to erase a feature. Scribbling to smooth off a surface.

17. Spines are elevated, quarter ovals are generated, and then triangulated as a 3D mesh. Creating the 3D Object Original Polygon Triangulation into Terminal, Sleeve, and Junction Triangles Chordal Axis Retriangulation into Fans Spine Final Retriangulation