Local theory for spatio-temporal canards and delayed bifurcations

DANIELE AVITABILE; MATHIEU DESROCHES; ROMAIN VELTZ; MARTIN WECHSELBERGER

doi:10.1137/19M1306610

Local theory for spatio-temporal canards and delayed bifurcations

DANIELE AVITABILE^*, MATHIEU DESROCHES, ROMAIN VELTZ, MARTIN WECHSELBERGER

^*Corresponding author for this work

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Abstract

We present a rigorous framework for the local analysis of canards and slow passages through bifurcations in a wide class of infinite-dimensional dynamical systems with time-scale separation. The framework is applicable to models where an infinite-dimensional dynamical system for the fast variables is coupled to a finite-dimensional dynamical system for slow variables. We prove the existence of center-manifolds for generic models of this type, and study the reduced, finite-dimensional dynamics near bifurcations of (possibly) patterned steady states in the layer problem. Theoretical results are complemented with detailed examples and numerical simulations covering systems of local and nonlocal reaction-diffusion equations, neural field models, and delay-differential equations. We provide analytical foundations for numerical observations recently reported in the literature, such as spatio-temporal canards and slow passages through Hopf bifurcations in spatially extended systems subject to slow parameter variations. We also provide a theoretical analysis of slow passage through a Turing bifurcation in local and nonlocal models.

Original language	English
Pages (from-to)	5703-5747
Number of pages	45
Journal	SIAM Journal on Mathematical Analysis
Volume	52
Issue number	6
Early online date	18 Nov 2020
DOIs	https://doi.org/10.1137/19M1306610
Publication status	Published - Dec 2020

Funding

\ast Received by the editors December 13, 2019; accepted for publication (in revised form) September 14, 2020; published electronically November 18, 2020. https://doi.org/10.1137/19M1306610 \bfF \bfu \bfn \bfd \bfi \bfn \bfg : The fourth author acknowledges funding via the grant ARC DP180103022. \dagger Corresponding author. Department of Mathematics, Vrije Universiteit Amsterdam, Amsterdam, 1081 HV The Netherlands; MathNeuro Team, Inria Sophia Antipolis Research Centre, Sophia Antipolis cedex, 06902 France ([email protected]). \ddagger MathNeuro Team, Inria Sophia Antipolis Research Centre, Sophia Antipolis cedex, 06902 France ([email protected], [email protected]). \S School of Mathematics and Statistics, University of Sydney, Sydney, NSW, NSW 2006 Australia ([email protected].).

Funders	Funder number
Australian Research Council	DP180103022

Keywords

Center manifold
Delayed bifurcations
Infinite-dimensional systems
Nonlocal equations
PDEs
Spatio-temporal canards

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Local theory for spatiotemporal canards and delayed bifurcationsFinal published version, 4.93 MBLicence: Article 25fa Dutch Copyright Act

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title = "Local theory for spatio-temporal canards and delayed bifurcations",

abstract = "We present a rigorous framework for the local analysis of canards and slow passages through bifurcations in a wide class of infinite-dimensional dynamical systems with time-scale separation. The framework is applicable to models where an infinite-dimensional dynamical system for the fast variables is coupled to a finite-dimensional dynamical system for slow variables. We prove the existence of center-manifolds for generic models of this type, and study the reduced, finite-dimensional dynamics near bifurcations of (possibly) patterned steady states in the layer problem. Theoretical results are complemented with detailed examples and numerical simulations covering systems of local and nonlocal reaction-diffusion equations, neural field models, and delay-differential equations. We provide analytical foundations for numerical observations recently reported in the literature, such as spatio-temporal canards and slow passages through Hopf bifurcations in spatially extended systems subject to slow parameter variations. We also provide a theoretical analysis of slow passage through a Turing bifurcation in local and nonlocal models. ",

keywords = "Center manifold, Delayed bifurcations, Infinite-dimensional systems, Nonlocal equations, PDEs, Spatio-temporal canards",

author = "DANIELE AVITABILE and MATHIEU DESROCHES and ROMAIN VELTZ and MARTIN WECHSELBERGER",

year = "2020",

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AU - AVITABILE, DANIELE

AU - DESROCHES, MATHIEU

AU - VELTZ, ROMAIN

AU - WECHSELBERGER, MARTIN

PY - 2020/12

Y1 - 2020/12

N2 - We present a rigorous framework for the local analysis of canards and slow passages through bifurcations in a wide class of infinite-dimensional dynamical systems with time-scale separation. The framework is applicable to models where an infinite-dimensional dynamical system for the fast variables is coupled to a finite-dimensional dynamical system for slow variables. We prove the existence of center-manifolds for generic models of this type, and study the reduced, finite-dimensional dynamics near bifurcations of (possibly) patterned steady states in the layer problem. Theoretical results are complemented with detailed examples and numerical simulations covering systems of local and nonlocal reaction-diffusion equations, neural field models, and delay-differential equations. We provide analytical foundations for numerical observations recently reported in the literature, such as spatio-temporal canards and slow passages through Hopf bifurcations in spatially extended systems subject to slow parameter variations. We also provide a theoretical analysis of slow passage through a Turing bifurcation in local and nonlocal models.

AB - We present a rigorous framework for the local analysis of canards and slow passages through bifurcations in a wide class of infinite-dimensional dynamical systems with time-scale separation. The framework is applicable to models where an infinite-dimensional dynamical system for the fast variables is coupled to a finite-dimensional dynamical system for slow variables. We prove the existence of center-manifolds for generic models of this type, and study the reduced, finite-dimensional dynamics near bifurcations of (possibly) patterned steady states in the layer problem. Theoretical results are complemented with detailed examples and numerical simulations covering systems of local and nonlocal reaction-diffusion equations, neural field models, and delay-differential equations. We provide analytical foundations for numerical observations recently reported in the literature, such as spatio-temporal canards and slow passages through Hopf bifurcations in spatially extended systems subject to slow parameter variations. We also provide a theoretical analysis of slow passage through a Turing bifurcation in local and nonlocal models.

KW - Center manifold

KW - Delayed bifurcations

KW - Infinite-dimensional systems

KW - Nonlocal equations

KW - PDEs

KW - Spatio-temporal canards

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Local theory for spatio-temporal canards and delayed bifurcations

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