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A displacement-based finite element formulation for solving elastic wave problems in coupled fluid-solid media on a GPU

A displacement-based finite element formulation for solving elastic wave problems in coupled fluid-solid media on a GPU
A displacement-based finite element formulation for solving elastic wave problems in coupled fluid-solid media on a GPU
Ultrasonic wave propagation and scattering involving both solids and fluids underpins many key configurations in non-destructive testing and underwater acoustics. The resulting interactions are highly dependent on both material parameters and geometries and are difficult and expensive to investigate experimentally. Modelling capabilities are often used to overcome this, but these are also complex and computationally expensive due to the complexity of the fluid-solid interactions. We introduce a novel explicit time-domain finite element method for simulating ultrasonic waves interacting with fluid-solid interfaces. The method is displacement-based, and relies on classical hourglassing control, in addition to a modified time-stepping scheme to damping out shear motion in an inviscid fluid. One of the key benefits of the displacement-based approach is that nodes in the fluid have the same number of degrees of freedom as those in the solid. Therefore defining a fluid-solid model is as easy as defining an all-fluid or all-solid model, avoiding the need for any special treatments at the interfaces. It is thus compatible with typical elastodynamic finite element formulations and ready for implementation on a graphical processing unit. We verified the method across a range of problems involving millions of degrees of freedom in fields such as non-destructive testing and underwater acoustics.
Finite element method (FE), Fluid-structure interaction, Graphical processing units (GPU), Non-destructive testing (NDT), Ultrasound, Underwater acoustics
0045-7949
Simillides, Yiannis
3ba44ee4-1fd4-4813-8b01-3e08a2656d92
Huthwaite, Peter
97bcb7c8-ddec-40cb-bea5-5a12efc1f1c2
Kalkowski, Michał K.
6f0d01ef-7f44-459c-82a2-03f9e1275eda
Lowe, Michael J.S.
ea054a45-8b1d-498f-bdf8-995973f76ed7
Simillides, Yiannis
3ba44ee4-1fd4-4813-8b01-3e08a2656d92
Huthwaite, Peter
97bcb7c8-ddec-40cb-bea5-5a12efc1f1c2
Kalkowski, Michał K.
6f0d01ef-7f44-459c-82a2-03f9e1275eda
Lowe, Michael J.S.
ea054a45-8b1d-498f-bdf8-995973f76ed7

Simillides, Yiannis, Huthwaite, Peter, Kalkowski, Michał K. and Lowe, Michael J.S. (2024) A displacement-based finite element formulation for solving elastic wave problems in coupled fluid-solid media on a GPU. Computers and Structures, 299, [107369]. (doi:10.1016/j.compstruc.2024.107369).

Record type: Article

Abstract

Ultrasonic wave propagation and scattering involving both solids and fluids underpins many key configurations in non-destructive testing and underwater acoustics. The resulting interactions are highly dependent on both material parameters and geometries and are difficult and expensive to investigate experimentally. Modelling capabilities are often used to overcome this, but these are also complex and computationally expensive due to the complexity of the fluid-solid interactions. We introduce a novel explicit time-domain finite element method for simulating ultrasonic waves interacting with fluid-solid interfaces. The method is displacement-based, and relies on classical hourglassing control, in addition to a modified time-stepping scheme to damping out shear motion in an inviscid fluid. One of the key benefits of the displacement-based approach is that nodes in the fluid have the same number of degrees of freedom as those in the solid. Therefore defining a fluid-solid model is as easy as defining an all-fluid or all-solid model, avoiding the need for any special treatments at the interfaces. It is thus compatible with typical elastodynamic finite element formulations and ready for implementation on a graphical processing unit. We verified the method across a range of problems involving millions of degrees of freedom in fields such as non-destructive testing and underwater acoustics.

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Published date: 1 August 2024
Additional Information: Publisher Copyright: © 2024 The Author(s)
Keywords: Finite element method (FE), Fluid-structure interaction, Graphical processing units (GPU), Non-destructive testing (NDT), Ultrasound, Underwater acoustics

Identifiers

Local EPrints ID: 507100
URI: http://eprints.soton.ac.uk/id/eprint/507100
DOI: doi:10.1016/j.compstruc.2024.107369
ISSN: 0045-7949
PURE UUID: 2c7a1246-4e69-472b-962f-529dd9fe6939

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Date deposited: 26 Nov 2025 17:52
Last modified: 26 Nov 2025 17:53

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Contributors

Author: Yiannis Simillides
Author: Peter Huthwaite
Author: Michał K. Kalkowski
Author: Michael J.S. Lowe

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