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Autori principali: Lemaire, Simon, Moatti, Julien
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2310.12870
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author Lemaire, Simon
Moatti, Julien
author_facet Lemaire, Simon
Moatti, Julien
contents We are interested in the high-order approximation of anisotropic, potential-driven advection-diffusion models on general polytopal partitions. We study two hybrid schemes, both built upon the Hybrid High-Order technology. The first one hinges on exponential fitting and is linear, whereas the second is nonlinear. The existence of solutions is established for both schemes. Both schemes are also shown to possess a discrete entropy structure, ensuring that the long-time behaviour of discrete solutions mimics the PDE one. For the nonlinear scheme, the positivity of discrete solutions is a built-in feature. On the contrary, we display numerical evidence indicating that the linear scheme violates positivity, whatever the order. Finally, we verify numerically that the nonlinear scheme has optimal order of convergence, expected long-time behaviour, and that raising the polynomial degree results, also in the nonlinear case, in an efficiency gain.
format Preprint
id arxiv_https___arxiv_org_abs_2310_12870
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Structure preservation in high-order hybrid discretisations of potential-driven advection-diffusion: linear and nonlinear approaches
Lemaire, Simon
Moatti, Julien
Numerical Analysis
65M60, 35K51, 35Q84, 35B40
We are interested in the high-order approximation of anisotropic, potential-driven advection-diffusion models on general polytopal partitions. We study two hybrid schemes, both built upon the Hybrid High-Order technology. The first one hinges on exponential fitting and is linear, whereas the second is nonlinear. The existence of solutions is established for both schemes. Both schemes are also shown to possess a discrete entropy structure, ensuring that the long-time behaviour of discrete solutions mimics the PDE one. For the nonlinear scheme, the positivity of discrete solutions is a built-in feature. On the contrary, we display numerical evidence indicating that the linear scheme violates positivity, whatever the order. Finally, we verify numerically that the nonlinear scheme has optimal order of convergence, expected long-time behaviour, and that raising the polynomial degree results, also in the nonlinear case, in an efficiency gain.
title Structure preservation in high-order hybrid discretisations of potential-driven advection-diffusion: linear and nonlinear approaches
topic Numerical Analysis
65M60, 35K51, 35Q84, 35B40
url https://arxiv.org/abs/2310.12870