Numerical Analysis of a Stable Finite Volume Scheme for a Generalized Thermistor Model
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Mustapha Ghilani
und
Mohamed Rhoudaf
Abstract
A generalized thermistor model is discretized thanks to a fully implicit vertex-centered finite volume scheme on simplicial meshes. An assumption on the stiffness coefficients is mandatory to prove a discrete maximum principle on the electric potential. This property is fundamental to handle the stability issues related to the Joule heating term. Then the convergence to a weak solution is established. Finally, numerical results are presented to show the efficiency of the methodology and to illustrate the behavior of the temperature together with the electric potential within the medium.
Acknowledgements
The authors acknowledge the anonymous referees for their comments that helped improve the presentation of this paper.
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© 2021 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Frontmatter
- A Differentiable Mapping of Mesh Cells Based on Finite Elements on Quadrilateral and Hexahedral Meshes
- Block-Adaptive Cross Approximation of Discrete Integral Operators
- Local Discontinuous Galerkin Method for Time-Dependent Singularly Perturbed Semilinear Reaction-Diffusion Problems
- Weighted Estimates of the Cayley Transform Method for Abstract Differential Equations
- Numerical Analysis of a Stable Finite Volume Scheme for a Generalized Thermistor Model
- Partial Relaxation of 𝐶0 Vertex Continuity of Stresses of Conforming Mixed Finite Elements for the Elasticity Problem
- Instance-Optimal Goal-Oriented Adaptivity
- A Semi-Uniform Multigrid Algorithm for Solving Elliptic Interface Problems
- A Priori Analysis of an Anisotropic Finite Element Method for Elliptic Equations in Polyhedral Domains
- Error Analysis of Nitsche’s and Discontinuous Galerkin Methods of a Reduced Landau–de Gennes Problem
- Fast Bilinear Algorithms for Symmetric Tensor Contractions
- Morley FEM for a Distributed Optimal Control Problem Governed by the von Kármán Equations
Artikel in diesem Heft
- Frontmatter
- A Differentiable Mapping of Mesh Cells Based on Finite Elements on Quadrilateral and Hexahedral Meshes
- Block-Adaptive Cross Approximation of Discrete Integral Operators
- Local Discontinuous Galerkin Method for Time-Dependent Singularly Perturbed Semilinear Reaction-Diffusion Problems
- Weighted Estimates of the Cayley Transform Method for Abstract Differential Equations
- Numerical Analysis of a Stable Finite Volume Scheme for a Generalized Thermistor Model
- Partial Relaxation of 𝐶0 Vertex Continuity of Stresses of Conforming Mixed Finite Elements for the Elasticity Problem
- Instance-Optimal Goal-Oriented Adaptivity
- A Semi-Uniform Multigrid Algorithm for Solving Elliptic Interface Problems
- A Priori Analysis of an Anisotropic Finite Element Method for Elliptic Equations in Polyhedral Domains
- Error Analysis of Nitsche’s and Discontinuous Galerkin Methods of a Reduced Landau–de Gennes Problem
- Fast Bilinear Algorithms for Symmetric Tensor Contractions
- Morley FEM for a Distributed Optimal Control Problem Governed by the von Kármán Equations
