Euler–Maruyama approximations of the stochastic heat equation on the sphere
Journal article, 2024
The stochastic heat equation on the sphere driven by additive isotropic Wiener noise is approximated by a spectral method in space and forward and backward Euler–Maruyama schemes in time. The spectral approximation is based on a truncation of the series expansion with respect to the spherical harmonic functions. Optimal strong convergence rates for a given regularity of the initial condition and driving noise are derived for the Euler–Maruyama methods. Besides strong convergence, convergence of the expectation and second moment is shown, where the approximation of the second moment converges with twice the strong rate. Numerical simulations confirm the theoretical results.
Stochastic heat equation
Euler–Maruyama scheme
Spectral approximation
Strong convergence
Second moment
Stochastic evolution on surfaces
Isotropic Wiener noise
Author
Annika Lang
Chalmers, Mathematical Sciences, Applied Mathematics and Statistics
Ioanna Motschan-Armen
Chalmers, Mathematical Sciences, Applied Mathematics and Statistics
Journal of Computational Dynamics
2158-2505 (eISSN)
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Subject Categories
Computational Mathematics
Probability Theory and Statistics
Mathematical Analysis
DOI
10.3934/jcd.2023012