Preserving invariance properties of reaction-diffusion systems on stationary surfaces

Massimo Frittelli; Anotide Madzvamuse; Ivonne Sgura; Chandrasekhar Venkataraman

doi:10.1093/imanum/drx058

Preserving invariance properties of reaction-diffusion systems on stationary surfaces

Massimo Frittelli, Anotide Madzvamuse, Ivonne Sgura, Chandrasekhar Venkataraman

Applied Mathematics

Research output: Contribution to journal › Article › peer-review

Abstract

We propose and analyse a lumped surface finite element method for the numerical approximation of reaction–diffusion systems on stationary compact surfaces in ℝ³. The proposed method preserves the invariant regions of the continuous problem under discretization and, in the special case of scalar equations, it preserves the maximum principle. On the application of a fully discrete scheme using the implicit–explicit Euler method in time, we prove that invariant regions of the continuous problem are preserved (i) at the spatially discrete level with no restriction on the meshsize and (ii) at the fully discrete level under a timestep restriction. We further prove optimal error bounds for the semidiscrete and fully discrete methods, that is, the convergence rates are quadratic in the meshsize and linear in the timestep. Numerical experiments are provided to support the theoretical findings. We provide examples in which, in the absence of lumping, the numerical solution violates the invariant region leading to blow-up.

Original language	English
Number of pages	36
Journal	IMA Journal of Numerical Analysis
Volume	Advance articles
Early online date	27 Oct 2017
DOIs	https://doi.org/10.1093/imanum/drx058
Publication status	E-pub ahead of print - 27 Oct 2017

Keywords

Surface finite elements
Mass lumping
Invariant region
Maximum principle
Reaction-diffusion
Heat equation
Convergence
Pattern formation

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10.1093/imanum/drx058Licence: CC BY

Frittelli-2017-Preserving-invariance-IMAJNA-CC
© The authors 2017. Published by Oxford University Press on behalf of the Institute of Mathematics and its Applications. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.
Final published version, 650 KBLicence: CC BY

InCeM - Research Training Network on Integrated Component Cycling in Epithelial Cell Motility
Venkataraman, C. (CoI)
1/01/15 → 31/12/19
Project: Standard

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title = "Preserving invariance properties of reaction-diffusion systems on stationary surfaces",

abstract = "We propose and analyse a lumped surface finite element method for the numerical approximation of reaction–diffusion systems on stationary compact surfaces in ℝ3. The proposed method preserves the invariant regions of the continuous problem under discretization and, in the special case of scalar equations, it preserves the maximum principle. On the application of a fully discrete scheme using the implicit–explicit Euler method in time, we prove that invariant regions of the continuous problem are preserved (i) at the spatially discrete level with no restriction on the meshsize and (ii) at the fully discrete level under a timestep restriction. We further prove optimal error bounds for the semidiscrete and fully discrete methods, that is, the convergence rates are quadratic in the meshsize and linear in the timestep. Numerical experiments are provided to support the theoretical findings. We provide examples in which, in the absence of lumping, the numerical solution violates the invariant region leading to blow-up.",

keywords = "Surface finite elements, Mass lumping, Invariant region, Maximum principle, Reaction-diffusion, Heat equation, Convergence, Pattern formation",

author = "Massimo Frittelli and Anotide Madzvamuse and Ivonne Sgura and Chandrasekhar Venkataraman",

note = "This work (AM, CV) is partly supported by the EPSRC grant number EP/J016780/1 and the Leverhulme Trust Research Project Grant (RPG-2014-149). The authors (MF, AM, IS CV) would like to thank the Isaac Newton Institute for Mathematical Sciences for its hospitality during the programme [Coupling Geometric PDEs with Physics for Cell Morphology, Motility and Pattern Formation] supported by EPSRC Grant Number EP/K032208/1. AM acknowledges funding from the European Union Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No 642866 and was partially supported by a grant from the Simons Foundation. AM is a Royal Society Wolfson Research Merit Award Holder funded generously by the Wolfson Foundation.",

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AU - Sgura, Ivonne

AU - Venkataraman, Chandrasekhar

N1 - This work (AM, CV) is partly supported by the EPSRC grant number EP/J016780/1 and the Leverhulme Trust Research Project Grant (RPG-2014-149). The authors (MF, AM, IS CV) would like to thank the Isaac Newton Institute for Mathematical Sciences for its hospitality during the programme [Coupling Geometric PDEs with Physics for Cell Morphology, Motility and Pattern Formation] supported by EPSRC Grant Number EP/K032208/1. AM acknowledges funding from the European Union Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No 642866 and was partially supported by a grant from the Simons Foundation. AM is a Royal Society Wolfson Research Merit Award Holder funded generously by the Wolfson Foundation.

PY - 2017/10/27

Y1 - 2017/10/27

N2 - We propose and analyse a lumped surface finite element method for the numerical approximation of reaction–diffusion systems on stationary compact surfaces in ℝ3. The proposed method preserves the invariant regions of the continuous problem under discretization and, in the special case of scalar equations, it preserves the maximum principle. On the application of a fully discrete scheme using the implicit–explicit Euler method in time, we prove that invariant regions of the continuous problem are preserved (i) at the spatially discrete level with no restriction on the meshsize and (ii) at the fully discrete level under a timestep restriction. We further prove optimal error bounds for the semidiscrete and fully discrete methods, that is, the convergence rates are quadratic in the meshsize and linear in the timestep. Numerical experiments are provided to support the theoretical findings. We provide examples in which, in the absence of lumping, the numerical solution violates the invariant region leading to blow-up.

AB - We propose and analyse a lumped surface finite element method for the numerical approximation of reaction–diffusion systems on stationary compact surfaces in ℝ3. The proposed method preserves the invariant regions of the continuous problem under discretization and, in the special case of scalar equations, it preserves the maximum principle. On the application of a fully discrete scheme using the implicit–explicit Euler method in time, we prove that invariant regions of the continuous problem are preserved (i) at the spatially discrete level with no restriction on the meshsize and (ii) at the fully discrete level under a timestep restriction. We further prove optimal error bounds for the semidiscrete and fully discrete methods, that is, the convergence rates are quadratic in the meshsize and linear in the timestep. Numerical experiments are provided to support the theoretical findings. We provide examples in which, in the absence of lumping, the numerical solution violates the invariant region leading to blow-up.

KW - Surface finite elements

KW - Mass lumping

KW - Invariant region

KW - Maximum principle

KW - Reaction-diffusion

KW - Heat equation

KW - Convergence

KW - Pattern formation

U2 - 10.1093/imanum/drx058

DO - 10.1093/imanum/drx058

M3 - Article

SN - 0272-4979

VL - Advance articles

JO - IMA Journal of Numerical Analysis

JF - IMA Journal of Numerical Analysis

ER -

Preserving invariance properties of reaction-diffusion systems on stationary surfaces

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Keywords

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InCeM - Research Training Network on Integrated Component Cycling in Epithelial Cell Motility

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