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Main Authors: Munir, Taj, Chamakuri, Nagaiah, Warnecke, Gerald
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.19003
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author Munir, Taj
Chamakuri, Nagaiah
Warnecke, Gerald
author_facet Munir, Taj
Chamakuri, Nagaiah
Warnecke, Gerald
contents This paper introduces improved numerical techniques for addressing numerical boundary and interface coupling conditions in the context of diffusion equations in cellular biophysics or heat conduction problems in fluid-structure interactions. Our primary focus is on two critical numerical aspects related to coupling conditions: the preservation of the conservation property and ensuring stability. Notably, a key oversight in some existing literature on coupling methods is the neglect of upholding the conservation property within the overall scheme. This oversight forms the central theme of the initial part of our research. As a first step, we limited ourselves to explicit schemes on uniform grids. Implicit schemes and the consideration of varying mesh sizes at the interface will be reserved for a subsequent paper \cite{CMW3}. Another paper \cite{CMW2} will address the issue of stability. We examine these schemes from the perspective of finite differences, including finite elements, following the application of a nodal quadrature rule. Additionally, we explore a finite volume-based scheme involving cells and flux considerations. Our analysis reveals that discrete boundary and flux coupling conditions uphold the conservation property in distinct ways in nodal-based and cell-based schemes. The coupling conditions under investigation encompass well-known approaches such as Dirichlet-Neumann coupling, heat flux coupling, and specific channel and pumping flux conditions drawn from the field of biophysics. The theoretical findings pertaining to the conservation property are corroborated through computations across a range of test cases.
format Preprint
id arxiv_https___arxiv_org_abs_2502_19003
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle On conservative, stable boundary and coupling conditions for diffusion equations I -- The conservation property for explicit schemes
Munir, Taj
Chamakuri, Nagaiah
Warnecke, Gerald
Numerical Analysis
65N06, 65N08
This paper introduces improved numerical techniques for addressing numerical boundary and interface coupling conditions in the context of diffusion equations in cellular biophysics or heat conduction problems in fluid-structure interactions. Our primary focus is on two critical numerical aspects related to coupling conditions: the preservation of the conservation property and ensuring stability. Notably, a key oversight in some existing literature on coupling methods is the neglect of upholding the conservation property within the overall scheme. This oversight forms the central theme of the initial part of our research. As a first step, we limited ourselves to explicit schemes on uniform grids. Implicit schemes and the consideration of varying mesh sizes at the interface will be reserved for a subsequent paper \cite{CMW3}. Another paper \cite{CMW2} will address the issue of stability. We examine these schemes from the perspective of finite differences, including finite elements, following the application of a nodal quadrature rule. Additionally, we explore a finite volume-based scheme involving cells and flux considerations. Our analysis reveals that discrete boundary and flux coupling conditions uphold the conservation property in distinct ways in nodal-based and cell-based schemes. The coupling conditions under investigation encompass well-known approaches such as Dirichlet-Neumann coupling, heat flux coupling, and specific channel and pumping flux conditions drawn from the field of biophysics. The theoretical findings pertaining to the conservation property are corroborated through computations across a range of test cases.
title On conservative, stable boundary and coupling conditions for diffusion equations I -- The conservation property for explicit schemes
topic Numerical Analysis
65N06, 65N08
url https://arxiv.org/abs/2502.19003