On the derivation of multisymplectic variational integrators for hyperbolic PDEs using exponential functions

Odysseas Kosmas; Pieter Boom; Andrey Jivkov

doi:10.3390/app11177837

On the derivation of multisymplectic variational integrators for hyperbolic PDEs using exponential functions

Odysseas Kosmas, Pieter Boom, Andrey Jivkov

Mechanical and Aerospace Engineering

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Abstract

We investigated the derivation of numerical methods for solving partial differential equations, focusing on those that preserve physical properties of Hamiltonian systems. The formulation of these properties via symplectic forms gives rise to multisymplectic variational schemes. By using analogy with the smooth case, we defined a discrete Lagrangian density through the use of exponential functions, and derived its Hamiltonian by Legendre transform. This led to a discrete Hamiltonian system, the symplectic forms of which obey the conservation laws. The integration schemes derived in this work were tested on hyperbolic-type PDEs, such as the linear wave equations and the non-linear seismic wave equations, and were assessed for their accuracy and the effectiveness by comparing them with those of standard multisymplectic ones. Our error analysis and the convergence plots show significant improvements over the standard schemes.

Original language	English
Article number	7837
Number of pages	11
Journal	Applied Sciences
Volume	11
Issue number	17
DOIs	https://doi.org/10.3390/app11177837
Publication status	Published - 25 Aug 2021

Keywords

Conservation laws
Hamiltonian systems
Multisymplectic numerical schemes
Seismic wave equation
Symplectic forms

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Geometric Mechanics of Solids: new analysis of modern engineering materials - GEMS
Jivkov, A. (PI) & Margetts, L. (CoI)
1/11/16 → 31/10/21
Project: Research

3 Article

A geometric formulation of linear elasticity based on Discrete Exterior Calculus
Boom, P., Kosmas, O., Margetts, L. & Jivkov, A., 1 Feb 2022, In: International Journal of Solids and Structures. 236-237, 12 p., 111345.
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A guide to the finite and virtual element methods for elasticity
Berbatov, K., Lazarov, B. & Jivkov, A., Nov 2021, In: Applied Numerical Mathematics. 169, p. 351-395 45 p.
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On the geometric description of non linear elasticity via an energy approach using barycentric coordinates
Kosmas, O., Boom, P. & Jivkov, A., 19 Jul 2021, In: Mathematics. 9, 1689.
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Cite this

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title = "On the derivation of multisymplectic variational integrators for hyperbolic PDEs using exponential functions",

abstract = "We investigated the derivation of numerical methods for solving partial differential equations, focusing on those that preserve physical properties of Hamiltonian systems. The formulation of these properties via symplectic forms gives rise to multisymplectic variational schemes. By using analogy with the smooth case, we defined a discrete Lagrangian density through the use of exponential functions, and derived its Hamiltonian by Legendre transform. This led to a discrete Hamiltonian system, the symplectic forms of which obey the conservation laws. The integration schemes derived in this work were tested on hyperbolic-type PDEs, such as the linear wave equations and the non-linear seismic wave equations, and were assessed for their accuracy and the effectiveness by comparing them with those of standard multisymplectic ones. Our error analysis and the convergence plots show significant improvements over the standard schemes.",

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Y1 - 2021/8/25

N2 - We investigated the derivation of numerical methods for solving partial differential equations, focusing on those that preserve physical properties of Hamiltonian systems. The formulation of these properties via symplectic forms gives rise to multisymplectic variational schemes. By using analogy with the smooth case, we defined a discrete Lagrangian density through the use of exponential functions, and derived its Hamiltonian by Legendre transform. This led to a discrete Hamiltonian system, the symplectic forms of which obey the conservation laws. The integration schemes derived in this work were tested on hyperbolic-type PDEs, such as the linear wave equations and the non-linear seismic wave equations, and were assessed for their accuracy and the effectiveness by comparing them with those of standard multisymplectic ones. Our error analysis and the convergence plots show significant improvements over the standard schemes.

AB - We investigated the derivation of numerical methods for solving partial differential equations, focusing on those that preserve physical properties of Hamiltonian systems. The formulation of these properties via symplectic forms gives rise to multisymplectic variational schemes. By using analogy with the smooth case, we defined a discrete Lagrangian density through the use of exponential functions, and derived its Hamiltonian by Legendre transform. This led to a discrete Hamiltonian system, the symplectic forms of which obey the conservation laws. The integration schemes derived in this work were tested on hyperbolic-type PDEs, such as the linear wave equations and the non-linear seismic wave equations, and were assessed for their accuracy and the effectiveness by comparing them with those of standard multisymplectic ones. Our error analysis and the convergence plots show significant improvements over the standard schemes.

KW - Conservation laws

KW - Hamiltonian systems

KW - Multisymplectic numerical schemes

KW - Seismic wave equation

KW - Symplectic forms

U2 - 10.3390/app11177837

DO - 10.3390/app11177837

M3 - Article

SN - 2076-3417

VL - 11

JO - Applied Sciences

JF - Applied Sciences

IS - 17

M1 - 7837

ER -

On the derivation of multisymplectic variational integrators for hyperbolic PDEs using exponential functions

Abstract

Keywords

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Projects

Geometric Mechanics of Solids: new analysis of modern engineering materials - GEMS

Research output

A geometric formulation of linear elasticity based on Discrete Exterior Calculus

A guide to the finite and virtual element methods for elasticity

On the geometric description of non linear elasticity via an energy approach using barycentric coordinates

Cite this