Nonlinear Sciences – Adaptation and Self-Organizing Systems
Scientific paper
2001-11-23
Nonlinear Sciences
Adaptation and Self-Organizing Systems
14 pages, 2 figure
Scientific paper
We present a systematic computational approach to the study of self-similar dynamics. The approach, through the use of what can be thought of as a ``dynamic pinning condition" factors out self-similarity, and yields a transformed, non-local evolution equation. The approach, which is capable of treating both first and second kind self-similar solutions, yields as a byproduct the self-similarity exponents of the original dynamics. We illustrate the approach through the porous medium equation, showing how both the Barenblatt (first kind) and the Graveleau (second kind) self-similar solutions arise in this framework. We also discuss certain implications of the dynamics of the transformed equation (which we will name "MN-dynamics"); in particular we discuss the discrete-time implementation of the approach, and connections with time-stepper based methods for the "coarse" integration/bifurcation analysis of microscopic simulators.
Aronson D. G.
Betelu S. I.
Kevrekidis Ioannis G.
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