Analysis of a micro–macro acceleration method with minimum relative entropy moment matching

Tony Lelièvre; Giovanni Samaey; Przemysław Zieliński

doi:10.1016/j.spa.2019.10.008

Analysis of a micro–macro acceleration method with minimum relative entropy moment matching

Tony Lelièvre
, Giovanni Samaey
, Przemysław Zieliński

KU Leuven

Research output: Contribution to journal › Article › peer-review

Abstract

We analyse convergence of a micro–macro acceleration method for the simulation of stochastic differential equations with time-scale separation. The method alternates short bursts of path simulations with the extrapolation of macroscopic state variables forward in time. After extrapolation, a new microscopic state is constructed, consistent with the extrapolated macroscopic state, that minimises the perturbation caused by the extrapolation in a relative entropy sense. We study local errors and numerical stability of the method to prove its convergence to the full microscopic dynamics when the extrapolation time step tends to zero and the number of macroscopic state variables tends to infinity.

Original language	English
Pages (from-to)	3753-3801
Number of pages	49
Journal	Stochastic Processes and their Applications
Volume	130
Issue number	6
DOIs	https://doi.org/10.1016/j.spa.2019.10.008
Publication status	Published - 1 Jun 2020

Keywords

Entropy optimisation
Kullback–Leibler divergence
Micro–macro simulations
Stiff stochastic differential equations
Weak convergence

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10.1016/j.spa.2019.10.008

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title = "Analysis of a micro–macro acceleration method with minimum relative entropy moment matching",

abstract = "We analyse convergence of a micro–macro acceleration method for the simulation of stochastic differential equations with time-scale separation. The method alternates short bursts of path simulations with the extrapolation of macroscopic state variables forward in time. After extrapolation, a new microscopic state is constructed, consistent with the extrapolated macroscopic state, that minimises the perturbation caused by the extrapolation in a relative entropy sense. We study local errors and numerical stability of the method to prove its convergence to the full microscopic dynamics when the extrapolation time step tends to zero and the number of macroscopic state variables tends to infinity.",

keywords = "Entropy optimisation, Kullback–Leibler divergence, Micro–macro simulations, Stiff stochastic differential equations, Weak convergence",

author = "Tony Leli{\`e}vre and Giovanni Samaey and Przemys{\l}aw Zieli{\'n}ski",

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AU - Lelièvre, Tony

AU - Samaey, Giovanni

AU - Zieliński, Przemysław

PY - 2020/6/1

Y1 - 2020/6/1

N2 - We analyse convergence of a micro–macro acceleration method for the simulation of stochastic differential equations with time-scale separation. The method alternates short bursts of path simulations with the extrapolation of macroscopic state variables forward in time. After extrapolation, a new microscopic state is constructed, consistent with the extrapolated macroscopic state, that minimises the perturbation caused by the extrapolation in a relative entropy sense. We study local errors and numerical stability of the method to prove its convergence to the full microscopic dynamics when the extrapolation time step tends to zero and the number of macroscopic state variables tends to infinity.

AB - We analyse convergence of a micro–macro acceleration method for the simulation of stochastic differential equations with time-scale separation. The method alternates short bursts of path simulations with the extrapolation of macroscopic state variables forward in time. After extrapolation, a new microscopic state is constructed, consistent with the extrapolated macroscopic state, that minimises the perturbation caused by the extrapolation in a relative entropy sense. We study local errors and numerical stability of the method to prove its convergence to the full microscopic dynamics when the extrapolation time step tends to zero and the number of macroscopic state variables tends to infinity.

KW - Entropy optimisation

KW - Kullback–Leibler divergence

KW - Micro–macro simulations

KW - Stiff stochastic differential equations

KW - Weak convergence

UR - https://www.scopus.com/pages/publications/85074158356

U2 - 10.1016/j.spa.2019.10.008

DO - 10.1016/j.spa.2019.10.008

M3 - Article

AN - SCOPUS:85074158356

SN - 0304-4149

VL - 130

SP - 3753

EP - 3801

JO - Stochastic Processes and their Applications

JF - Stochastic Processes and their Applications

IS - 6

ER -

Analysis of a micro–macro acceleration method with minimum relative entropy moment matching

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Keywords

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