This work proposes a stabilized space–time method for the monodomain equation coupled with the Rogers–McCulloch ionic model, which is widely used to simulate electrophysiological wave propagation in the cardiac tissue. By extending the Spline Upwind method and exploiting low-rank matrix approximations, as well as preconditioned solvers, we achieve both significant computational efficiency and accuracy. In particular, we develop a formulation that is both simple and highly effective, designed to minimize spurious oscillations and ensuring computational efficiency. We rigorously validate the method's performance through a series of numerical experiments, showing its robustness and reliability in diverse scenarios.
Antonietti, P., Dedè, L., Loli, G., Montardini, M., Sangalli, G., Tesini, P. (2025). Space–time Isogeometric Analysis of cardiac electrophysiology. COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING, 441(1 June 2025) [10.1016/j.cma.2025.117957].
Space–time Isogeometric Analysis of cardiac electrophysiology
Tesini, Paolo
2025
Abstract
This work proposes a stabilized space–time method for the monodomain equation coupled with the Rogers–McCulloch ionic model, which is widely used to simulate electrophysiological wave propagation in the cardiac tissue. By extending the Spline Upwind method and exploiting low-rank matrix approximations, as well as preconditioned solvers, we achieve both significant computational efficiency and accuracy. In particular, we develop a formulation that is both simple and highly effective, designed to minimize spurious oscillations and ensuring computational efficiency. We rigorously validate the method's performance through a series of numerical experiments, showing its robustness and reliability in diverse scenarios.
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