Computing slow manifolds of saddle type*

John Guckenheimer; Christian Kuehn

doi:10.1137/080741999

Computing slow manifolds of saddle type*

John Guckenheimer, Christian Kuehn

Cornell University

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

52 Scopus citations

Abstract

Slow manifolds are important geometric structures in the state spaces of dynamical systems with multiple time scales. This paper introduces an algorithm for computing trajectories on slow manifolds that are normally hyperbolic with both stable and unstable fast manifolds. We present two examples of bifurcation problems where these manifolds play a key role and a third example in which saddle-type slow manifolds are part of a traveling wave profile of a partial differential equation.Initial value solvers are incapable of computing trajectories on saddle-type slow manifolds, so the slow manifold of saddle type (SMST) algorithm presented here is formulated as a boundary value method. We take an empirical approach here to assessing the accuracy and effectiveness of the algorithm.

Original language	English
Pages (from-to)	854-879
Number of pages	26
Journal	SIAM Journal on Applied Dynamical Systems
Volume	8
Issue number	3
DOIs	https://doi.org/10.1137/080741999
State	Published - 2009
Externally published	Yes

Keywords

Canard
Collocation method
Invariant slow manifold
Singular perturbaton

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10.1137/080741999

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AB - Slow manifolds are important geometric structures in the state spaces of dynamical systems with multiple time scales. This paper introduces an algorithm for computing trajectories on slow manifolds that are normally hyperbolic with both stable and unstable fast manifolds. We present two examples of bifurcation problems where these manifolds play a key role and a third example in which saddle-type slow manifolds are part of a traveling wave profile of a partial differential equation.Initial value solvers are incapable of computing trajectories on saddle-type slow manifolds, so the slow manifold of saddle type (SMST) algorithm presented here is formulated as a boundary value method. We take an empirical approach here to assessing the accuracy and effectiveness of the algorithm.

KW - Canard

KW - Collocation method

KW - Invariant slow manifold

KW - Singular perturbaton

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Computing slow manifolds of saddle type*

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Keywords

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