Open AccessImproving multilevel Monte Carlo for stochastic differential equations with application to the Langevin equation
Author(s) -
Eike H. Müller,
Robert Scheichl,
Tony Shardlow
Publication year - 2015
Publication title -
proceedings of the royal society a mathematical physical and engineering sciences
Language(s) - English
Resource type - Journals
eISSN - 1471-2946
pISSN - 1364-5021
DOI - 10.1098/rspa.2014.0679
Subject(s) - stochastic differential equation , monte carlo method , integrator , mathematics , extrapolation , differential equation , gaussian , operator (biology) , statistical physics , computer science , mathematical analysis , physics , statistics , computer network , bandwidth (computing) , quantum mechanics , biochemistry , chemistry , repressor , transcription factor , gene
This paper applies several well-known tricks from the numerical treatment of deterministic differential equations to improve the efficiency of the multilevel Monte Carlo (MLMC) method for stochastic diffe- rential equations (SDEs) and especially the Langevin equation. We use modified equations analysis as an alternative to strong-approximation theory for the integrator, and we apply this to introduce MLMC for Langevin-type equations with integrators based on operator splitting. We combine this with extrapolation and investigate the use of discrete random variables in place of the Gaussian increments, which is a well-known technique for the weak approximation of SDEs. We show that, for small-noise problems, discrete random variables can lead to an increase in efficiency of almost two orders of magnitude for practical levels of accuracy
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