Discretized fast–slow systems near pitchfork singularities

Luca Arcidiacono; Maximilian Engel; Christian Kuehn

doi:10.1080/10236198.2019.1647185

Discretized fast–slow systems near pitchfork singularities

Luca Arcidiacono
, Maximilian Engel
, Christian Kuehn

Chair of Multiscale and Stochastic Dynamics

Technical University of Munich

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

6 Scopus citations

Abstract

Motivated by the normal form of a fast–slow ordinary differential equation exhibiting a pitchfork singularity we consider the discrete-time dynamical system that is obtained by an application of the explicit Euler method. Tracking trajectories in the vicinity of the singularity we show, how the slow manifold extends beyond the singular point and give an estimate on the contraction rate of a transition mapping. The proof relies on the blow-up method suitably adapted to the discrete setting where precise estimates for a cubic map in the central rescaling chart make a key technical contribution.

Original language	English
Pages (from-to)	1024-1051
Number of pages	28
Journal	Journal of Difference Equations and Applications
Volume	25
Issue number	7
DOIs	https://doi.org/10.1080/10236198.2019.1647185
State	Published - 2019

Keywords

Pitchfork bifurcation
blow-up method
discretization
invariant manifolds
loss of normal hyperbolicity
slow manifolds

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10.1080/10236198.2019.1647185

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title = "Discretized fast–slow systems near pitchfork singularities",

abstract = "Motivated by the normal form of a fast–slow ordinary differential equation exhibiting a pitchfork singularity we consider the discrete-time dynamical system that is obtained by an application of the explicit Euler method. Tracking trajectories in the vicinity of the singularity we show, how the slow manifold extends beyond the singular point and give an estimate on the contraction rate of a transition mapping. The proof relies on the blow-up method suitably adapted to the discrete setting where precise estimates for a cubic map in the central rescaling chart make a key technical contribution.",

keywords = "Pitchfork bifurcation, blow-up method, discretization, invariant manifolds, loss of normal hyperbolicity, slow manifolds",

author = "Luca Arcidiacono and Maximilian Engel and Christian Kuehn",

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T1 - Discretized fast–slow systems near pitchfork singularities

AU - Arcidiacono, Luca

AU - Engel, Maximilian

AU - Kuehn, Christian

PY - 2019

Y1 - 2019

N2 - Motivated by the normal form of a fast–slow ordinary differential equation exhibiting a pitchfork singularity we consider the discrete-time dynamical system that is obtained by an application of the explicit Euler method. Tracking trajectories in the vicinity of the singularity we show, how the slow manifold extends beyond the singular point and give an estimate on the contraction rate of a transition mapping. The proof relies on the blow-up method suitably adapted to the discrete setting where precise estimates for a cubic map in the central rescaling chart make a key technical contribution.

AB - Motivated by the normal form of a fast–slow ordinary differential equation exhibiting a pitchfork singularity we consider the discrete-time dynamical system that is obtained by an application of the explicit Euler method. Tracking trajectories in the vicinity of the singularity we show, how the slow manifold extends beyond the singular point and give an estimate on the contraction rate of a transition mapping. The proof relies on the blow-up method suitably adapted to the discrete setting where precise estimates for a cubic map in the central rescaling chart make a key technical contribution.

KW - Pitchfork bifurcation

KW - blow-up method

KW - discretization

KW - invariant manifolds

KW - loss of normal hyperbolicity

KW - slow manifolds

UR - https://www.scopus.com/pages/publications/85070466194

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EP - 1051

JO - Journal of Difference Equations and Applications

JF - Journal of Difference Equations and Applications

IS - 7

ER -

Discretized fast–slow systems near pitchfork singularities

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