An exponential map free implicit midpoint method for stochastic Lie-Poisson systems
Preprint, 2024
An integrator for a class of stochastic Lie-Poisson systems driven by Stratonovich noise is developed. The integrator is suited for Lie-Poisson systems that also admit an isospectral formulation, which enables scalability to high-dimensional systems. Its derivation follows from discrete Lie-Poisson reduction of the symplectic midpoint scheme for stochastic Hamiltonian systems. We prove almost sure preservation of Casimir functions and coadjoint orbits under the numerical flow and provide strong and weak convergence rates of the proposed method. The scalability, structure-conservation, and convergence rates are illustrated numerically for the (generalized) rigid body, point vortex dynamics, and the two-dimensional Euler equations on the sphere.
weak convergence
stochastic Lie–Poisson system
Stratonovich noise
structure-conservation
Casimir functions
symplectic midpoint scheme
strong convergence
Author
Sagy Ephrati
Chalmers, Mathematical Sciences, Applied Mathematics and Statistics
University of Gothenburg
Erik Jansson
Chalmers, Mathematical Sciences, Applied Mathematics and Statistics
Annika Lang
Chalmers, Mathematical Sciences, Applied Mathematics and Statistics
Erwin Luesink
University of Amsterdam
Time-Evolving Stochastic Manifolds (StochMan)
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Subject Categories (SSIF 2011)
Mathematics
Computational Mathematics
Geometry
Probability Theory and Statistics
Infrastructure
C3SE (-2020, Chalmers Centre for Computational Science and Engineering)
Chalmers e-Commons (incl. C3SE, 2020-)
DOI
10.48550/arXiv.2408.16701