Momentum‐preserving inversion alleviation for elastic material simulation

This paper proposes a novel method that enhances the optimization‐based elastic body solver. The proposed method tackles the element inversion problem, which is prevalent in the prediction‐projection approach for numerical simulation of elastic bodies. At the prediction stage, our method alleviates...

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Bibliographic Details
Published in:Computer animation and virtual worlds 2024-05, Vol.35 (3), p.n/a
Main Authors: Jeong, Heejo, Kim, Seung‐wook, Lee, JaeHyun, Um, Kiwon, Kee, Min Hyung, Han, JungHyun
Format: Article
Language:English
Subjects:
Computer Science
Elastic bodies
elasticity
Graphics
inversion
Inversions
optimization
physically‐based simulation
Solvers
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Summary:This paper proposes a novel method that enhances the optimization‐based elastic body solver. The proposed method tackles the element inversion problem, which is prevalent in the prediction‐projection approach for numerical simulation of elastic bodies. At the prediction stage, our method alleviates inversions such that the subsequent projection solver can benefit in stability and efficiency. To prevent excessive suppression of predicted inertial motion when alleviating, we introduce a velocity decomposition method and adapt only the non‐rigid motion while preserving the rigid motion, that is, linear and angular momenta. Thanks to the respected inertial motion in the prediction stage, our method produces lively motions while keeping the entire simulation more stable. The experiments demonstrate that our alleviation method successfully stabilizes the simulation and improves the efficiency particularly when large deformations hamper the solver. In this paper, we propose a novel method that enhances the prediction‐projection approach involved in the optimization‐based elastic body solver. At the prediction stage, our method alleviates inversions, allowing the subsequent projection solver to benefit from improved stability and efficiency.
ISSN:1546-4261
1546-427X
DOI:10.1002/cav.2249