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Autori principali: Makrakis, G., Makridakis, C., Mitsoudis, D., Plexousakis, M., Pryer, T.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2511.13217
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author Makrakis, G.
Makridakis, C.
Mitsoudis, D.
Plexousakis, M.
Pryer, T.
author_facet Makrakis, G.
Makridakis, C.
Mitsoudis, D.
Plexousakis, M.
Pryer, T.
contents In this paper, we investigate whether Variational Principles can be associated with the Helmholtz equation subject to impedance (absorbing) boundary conditions. This model has been extensively studied in the literature from both mathematical and computational perspectives. It is classical with wide applications, yet accurate approximation at high wavenumbers remains challenging. We address the question of whether there exist energy functionals with a clear physical interpretation whose stationary points, the zeros of their first variation, correspond to solutions of the Helmholtz problem. Starting from Hamilton's principle for the wave equation, we derive time-harmonic energies. The resulting functionals are generally indefinite. As a next step, we construct strongly coercive augmentations of these indefinite functionals that preserve their physical interpretation. Finally, we show how these variational principles lead to practical numerical methods based on finite element spaces and neural network architectures.
format Preprint
id arxiv_https___arxiv_org_abs_2511_13217
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Variational Principles for the Helmholtz equation: application to Finite Element and Neural Network approximations
Makrakis, G.
Makridakis, C.
Mitsoudis, D.
Plexousakis, M.
Pryer, T.
Numerical Analysis
In this paper, we investigate whether Variational Principles can be associated with the Helmholtz equation subject to impedance (absorbing) boundary conditions. This model has been extensively studied in the literature from both mathematical and computational perspectives. It is classical with wide applications, yet accurate approximation at high wavenumbers remains challenging. We address the question of whether there exist energy functionals with a clear physical interpretation whose stationary points, the zeros of their first variation, correspond to solutions of the Helmholtz problem. Starting from Hamilton's principle for the wave equation, we derive time-harmonic energies. The resulting functionals are generally indefinite. As a next step, we construct strongly coercive augmentations of these indefinite functionals that preserve their physical interpretation. Finally, we show how these variational principles lead to practical numerical methods based on finite element spaces and neural network architectures.
title Variational Principles for the Helmholtz equation: application to Finite Element and Neural Network approximations
topic Numerical Analysis
url https://arxiv.org/abs/2511.13217