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Fast viscoelastic behavior with thin features

Published: 01 August 2008 Publication History

Abstract

We introduce a method for efficiently animating a wide range of deformable materials. We combine a high resolution surface mesh with a tetrahedral finite element simulator that makes use of frequent re-meshing. This combination allows for fast and detailed simulations of complex elastic and plastic behavior. We significantly expand the range of physical parameters that can be simulated with a single technique, and the results are free from common artifacts such as volume-loss, smoothing, popping, and the absence of thin features like strands and sheets. Our decision to couple a high resolution surface with low-resolution physics leads to efficient simulation and detailed surface features, and our approach to creating the tetrahedral mesh leads to an order-of-magnitude speedup over previous techniques in the time spent re-meshing. We compute masses, collisions, and surface tension forces on the scale of the fine mesh, which helps avoid visual artifacts due to the differing mesh resolutions. The result is a method that can simulate a large array of different material behaviors with high resolution features in a short amount of time.

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Published In

cover image ACM Transactions on Graphics
ACM Transactions on Graphics  Volume 27, Issue 3
August 2008
844 pages
ISSN:0730-0301
EISSN:1557-7368
DOI:10.1145/1360612
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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 01 August 2008
Published in TOG Volume 27, Issue 3

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Author Tags

  1. computational fluid dynamics
  2. deformable models
  3. explicit surface
  4. finite element method
  5. free-form deformation
  6. viscoelastic behavior

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