Locking-Proof Tetrahedra

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Standard

Locking-Proof Tetrahedra. / Francu, Mihail; Ásgeirsson, Árni Gunnar; Erleben, Kenny; Rønnow, Mads J. L. .

I: A C M Transactions on Graphics, Bind 40, Nr. 2, 12, 2021, s. 1-17.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Francu, M, Ásgeirsson, ÁG, Erleben, K & Rønnow, MJL 2021, 'Locking-Proof Tetrahedra', A C M Transactions on Graphics, bind 40, nr. 2, 12, s. 1-17. https://doi.org/10.1145/3444949

APA

Francu, M., Ásgeirsson, Á. G., Erleben, K., & Rønnow, M. J. L. (2021). Locking-Proof Tetrahedra. A C M Transactions on Graphics, 40(2), 1-17. [12]. https://doi.org/10.1145/3444949

Vancouver

Francu M, Ásgeirsson ÁG, Erleben K, Rønnow MJL. Locking-Proof Tetrahedra. A C M Transactions on Graphics. 2021;40(2):1-17. 12. https://doi.org/10.1145/3444949

Author

Francu, Mihail ; Ásgeirsson, Árni Gunnar ; Erleben, Kenny ; Rønnow, Mads J. L. . / Locking-Proof Tetrahedra. I: A C M Transactions on Graphics. 2021 ; Bind 40, Nr. 2. s. 1-17.

Bibtex

@article{3a0e86b99dcf4ae2922ca7f19f5e7aa5,
title = "Locking-Proof Tetrahedra",
abstract = "The simulation of incompressible materials suffers from locking when using the standard finite element method (FEM) and coarse linear tetrahedral meshes. Locking increases as the Poisson ratio gets close to 0.5 and often lower Poisson ratio values are used to reduce locking, affecting volume preservation. We propose a novel mixed FEM approach to simulating incompressible solids that alleviates the locking problem for tetrahedra. Our method uses linear shape functions for both displacements and pressure, and adds one scalar per node. It can accommodate nonlinear isotropic materials described by a Young{\textquoteright}s modulus and any Poisson ratio value by enforcing a volumetric constitutive law. The most realistic such material is Neo-Hookean, and we focus on adapting it to our method. For , we can obtain full volume preservation up to any desired numerical accuracy. We show that standard Neo-Hookean simulations using tetrahedra are often locking, which, in turn, affects accuracy. We show that our method gives better results and that our Newton solver is more robust. As an alternative, we propose a dual ascent solver that is simple and has a good convergence rate. We validate these results using numerical experiments and quantitative analysis.",
author = "Mihail Francu and {\'A}sgeirsson, {{\'A}rni Gunnar} and Kenny Erleben and R{\o}nnow, {Mads J. L.}",
year = "2021",
doi = "10.1145/3444949",
language = "Dansk",
volume = "40",
pages = "1--17",
journal = "ACM Transactions on Graphics",
issn = "0730-0301",
publisher = "Association for Computing Machinery, Inc.",
number = "2",

}

RIS

TY - JOUR

T1 - Locking-Proof Tetrahedra

AU - Francu, Mihail

AU - Ásgeirsson, Árni Gunnar

AU - Erleben, Kenny

AU - Rønnow, Mads J. L.

PY - 2021

Y1 - 2021

N2 - The simulation of incompressible materials suffers from locking when using the standard finite element method (FEM) and coarse linear tetrahedral meshes. Locking increases as the Poisson ratio gets close to 0.5 and often lower Poisson ratio values are used to reduce locking, affecting volume preservation. We propose a novel mixed FEM approach to simulating incompressible solids that alleviates the locking problem for tetrahedra. Our method uses linear shape functions for both displacements and pressure, and adds one scalar per node. It can accommodate nonlinear isotropic materials described by a Young’s modulus and any Poisson ratio value by enforcing a volumetric constitutive law. The most realistic such material is Neo-Hookean, and we focus on adapting it to our method. For , we can obtain full volume preservation up to any desired numerical accuracy. We show that standard Neo-Hookean simulations using tetrahedra are often locking, which, in turn, affects accuracy. We show that our method gives better results and that our Newton solver is more robust. As an alternative, we propose a dual ascent solver that is simple and has a good convergence rate. We validate these results using numerical experiments and quantitative analysis.

AB - The simulation of incompressible materials suffers from locking when using the standard finite element method (FEM) and coarse linear tetrahedral meshes. Locking increases as the Poisson ratio gets close to 0.5 and often lower Poisson ratio values are used to reduce locking, affecting volume preservation. We propose a novel mixed FEM approach to simulating incompressible solids that alleviates the locking problem for tetrahedra. Our method uses linear shape functions for both displacements and pressure, and adds one scalar per node. It can accommodate nonlinear isotropic materials described by a Young’s modulus and any Poisson ratio value by enforcing a volumetric constitutive law. The most realistic such material is Neo-Hookean, and we focus on adapting it to our method. For , we can obtain full volume preservation up to any desired numerical accuracy. We show that standard Neo-Hookean simulations using tetrahedra are often locking, which, in turn, affects accuracy. We show that our method gives better results and that our Newton solver is more robust. As an alternative, we propose a dual ascent solver that is simple and has a good convergence rate. We validate these results using numerical experiments and quantitative analysis.

U2 - 10.1145/3444949

DO - 10.1145/3444949

M3 - Tidsskriftartikel

VL - 40

SP - 1

EP - 17

JO - ACM Transactions on Graphics

JF - ACM Transactions on Graphics

SN - 0730-0301

IS - 2

M1 - 12

ER -

ID: 256671824