Mahesh Kumar Mulimani, Sebastian Echeverria-Alar, Michael Reiss, Wouter-Jan Rappel
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Prediction of excitable wave dynamics using machine learning
Excitable systems, including cardiac tissue, can exhibit a variety of
dynamics with different complexity, ranging from a single, stable spiral to
spiral defect chaos (SDC), during which spiral waves are continuously formed
and destroyed. Cardiac models typically involve a large number of variables and
can be time-consuming to simulate. Here we trained a deep-learning (DL) model
using snapshots from a single variable, obtained by simulating a single
quasi-periodic spiral wave and spiral defect chaos (SDC) using a generic
cardiac model. Using the trained DL model, we predicted the dynamics in both
cases, using timesteps that are much larger than required for the simulations
of the underlying equations. We show that the DL model is able to predict the
trajectory of a quasi-periodic spiral wave and that the SDC activaton patterns
can be predicted for approximately one Lyapunov time. Furthermore, we show that
the DL model accurately captures the statistics of termination events in SDC,
including the mean termination time. Finally, we show that a DL model trained
using a specific domain size is able to replicate termination statistics on
larger domains, resulting in significant computational savings.
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