TY - GEN
T1 - Accelerated iterative DG finite element solvers for large-scale time-harmonic acoustic problems
AU - Modave, Axel
N1 - Publisher Copyright:
© 2024 by Societe Francaise d’Acoustique. All Rights Reserved.
PY - 2024/1/1
Y1 - 2024/1/1
N2 - Finite element methods are widely used to solve time-harmonic wave propagation problems, but solving large cases can be extremely difficult even with the computational power of parallel computers. In this work, the linear system resulting from the finite element discretization is solved with iterative solution methods, which are efficient in parallel but can require a large number of iterations. In standard discontinuous Galerkin (DG) methods, the numerical solution is discontinuous at the interfaces between the elements. In hybridizable DG methods, additional unknowns are introduced at the interfaces between the finite elements, and the physical unknowns are eliminated from the global system, resulting in a hybridized system. We have recently proposed a new strategy, called CHDG, where the additional unknowns correspond to transmission variables, whereas in the standard approach they are numerical fluxes. This strategy improves the properties of the hybridized system for faster iterative solution procedures. In this talk, we present and study a 3D CHDG implementation with nodal finite element basis functions. The resulting scheme has properties amenable to efficient parallel computing. Numerical results are presented to validate the method, and preliminary 3D computational results are proposed.
AB - Finite element methods are widely used to solve time-harmonic wave propagation problems, but solving large cases can be extremely difficult even with the computational power of parallel computers. In this work, the linear system resulting from the finite element discretization is solved with iterative solution methods, which are efficient in parallel but can require a large number of iterations. In standard discontinuous Galerkin (DG) methods, the numerical solution is discontinuous at the interfaces between the elements. In hybridizable DG methods, additional unknowns are introduced at the interfaces between the finite elements, and the physical unknowns are eliminated from the global system, resulting in a hybridized system. We have recently proposed a new strategy, called CHDG, where the additional unknowns correspond to transmission variables, whereas in the standard approach they are numerical fluxes. This strategy improves the properties of the hybridized system for faster iterative solution procedures. In this talk, we present and study a 3D CHDG implementation with nodal finite element basis functions. The resulting scheme has properties amenable to efficient parallel computing. Numerical results are presented to validate the method, and preliminary 3D computational results are proposed.
UR - https://www.scopus.com/pages/publications/105015532272
U2 - 10.3397/in_2024_2877
DO - 10.3397/in_2024_2877
M3 - Conference contribution
AN - SCOPUS:105015532272
T3 - 53rd International Congress and Exposition on Noise Control Engineering, Internoise 2024
SP - 1301
EP - 1307
BT - 53rd International Congress and Exposition on Noise Control Engineering, Internoise 2024
PB - Societe Francaise d'Acoustique
T2 - 53rd International Congress and Exposition on Noise Control Engineering, Internoise 2024
Y2 - 25 August 2024 through 29 August 2024
ER -