Nonconforming finite element formulation for the simulation of impedance cardiography

Manfred Kaltenbacher; Vahid Badeli; Alice Reinbacher-Koestinger

doi:10.1002/jnm.3063

Nonconforming finite element formulation for the simulation of impedance cardiography

Manfred Kaltenbacher^*, Vahid Badeli, Alice Reinbacher-Koestinger

^*Corresponding author for this work

Institute of Fundamentals and Theory in Electrical Engineering (4370)

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

Abstract

We present a nonconforming Finite Element (FE) formulation for the electro-quasistatic case. The formulation allows a grid generation for each sub-domain individually. At the nonconforming interfaces, we apply a Nitsche-type mortaring, which can also be interpreted as a DG-IP (Discontinuous Galerkin-Internal Penalty) formulation. Thereby, the continuity of the electric potential and the electric flux in the discrete setting is guaranteed. The system matrix remains symmetric, and the necessary penalty factor can be chosen in a wide range without deteriorating the numerical solution. The application to impedance cardiography demonstrates the practical applicability, especially its advantage toward simplification of the grid generation.

Original language	English
Article number	e3063
Journal	International Journal of Numerical Modelling
Early online date	16 Sept 2022
DOIs	https://doi.org/10.1002/jnm.3063
Publication status	E-pub ahead of print - 16 Sept 2022

Keywords

finite elements
impedance cardiography
nonconforming grid

ASJC Scopus subject areas

Electrical and Electronic Engineering
Computer Science Applications
Modelling and Simulation

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10.1002/jnm.3063Licence: CC BY-NC 4.0

Cite this

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title = "Nonconforming finite element formulation for the simulation of impedance cardiography",

abstract = "We present a nonconforming Finite Element (FE) formulation for the electro-quasistatic case. The formulation allows a grid generation for each sub-domain individually. At the nonconforming interfaces, we apply a Nitsche-type mortaring, which can also be interpreted as a DG-IP (Discontinuous Galerkin-Internal Penalty) formulation. Thereby, the continuity of the electric potential and the electric flux in the discrete setting is guaranteed. The system matrix remains symmetric, and the necessary penalty factor can be chosen in a wide range without deteriorating the numerical solution. The application to impedance cardiography demonstrates the practical applicability, especially its advantage toward simplification of the grid generation.",

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N2 - We present a nonconforming Finite Element (FE) formulation for the electro-quasistatic case. The formulation allows a grid generation for each sub-domain individually. At the nonconforming interfaces, we apply a Nitsche-type mortaring, which can also be interpreted as a DG-IP (Discontinuous Galerkin-Internal Penalty) formulation. Thereby, the continuity of the electric potential and the electric flux in the discrete setting is guaranteed. The system matrix remains symmetric, and the necessary penalty factor can be chosen in a wide range without deteriorating the numerical solution. The application to impedance cardiography demonstrates the practical applicability, especially its advantage toward simplification of the grid generation.

AB - We present a nonconforming Finite Element (FE) formulation for the electro-quasistatic case. The formulation allows a grid generation for each sub-domain individually. At the nonconforming interfaces, we apply a Nitsche-type mortaring, which can also be interpreted as a DG-IP (Discontinuous Galerkin-Internal Penalty) formulation. Thereby, the continuity of the electric potential and the electric flux in the discrete setting is guaranteed. The system matrix remains symmetric, and the necessary penalty factor can be chosen in a wide range without deteriorating the numerical solution. The application to impedance cardiography demonstrates the practical applicability, especially its advantage toward simplification of the grid generation.

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Nonconforming finite element formulation for the simulation of impedance cardiography

Abstract

Keywords

ASJC Scopus subject areas

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