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Dror Givon, Raz Kupferman Andrew M. Stuart

Extracting macroscopic dynamics: model problems and algorithms

In many applications, the primary objective of numerical simulation of time- evolving systems is the prediction of coarse-grained, or macroscopic, quantities. The purpose of this review is twofold: firstly to describe a number of simple model systems where the coarse-grained or macroscopic behaviour of a system can be explicitly determined from the full, or microscopic description; and secondly to overview some of the emerging algorithmic approaches that have been introduced to extract effective, lower-dimensional, macroscopic dynamics. The model problems we describe may be either stochastic or deterministic in both their microscopic or macroscopic behaviour, leading to four possibilities in the transition from microscopic to macroscopic descriptions. Model problems are given which illustrate all four situations, and mathematical tools for their study are introduced. These model problems are useful in the evaluation of algorithms. We use specific instances of the model problems to illustrate these algorithms. As the subject of algorithm development and analysis is, in many cases, in its infancy, the primary purpose here is to attempt to unify some of the emerging ideas so that individuals new to the field have structured access to the literature. Furthermore, by discussing the algorithms in the context of the model problems, a platform for understanding existing algorithms, and developing new ones, is built.

 Bibliographical note: Nonlinearity, 17(2004), p55--127