Charles-Edouard Bréhier, David Cohen, Giuseppe Giordano
Published 2022-07-21Version 1
We design and study splitting integrators for the temporal discretization of the stochastic FitzHugh--Nagumo system. This system is a model for signal propagation in nerve cells where the voltage variable is solution of a one-dimensional parabolic PDE with a cubic nonlinearity driven by additive space-time white noise. We first show that the numerical solutions have finite moments. We then prove that the splitting schemes have, at least, the strong rate of convergence $1/4$. Finally, numerical experiments illustrating the performance of the splitting schemes are provided.
Numerical approximation of Cahn-Hilliard type nonlinear SPDEs with additive space-time white noise
Weak convergence rates of splitting schemes for the stochastic Allen-Cahn equation
Splitting Schemes for Non-Stationary Problems with a Rational Approximation for Fractional Powers of the Operator
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