Geometric Desingularization of a Cusp Singularity in Slow–Fast Systems with Applications to Zeeman’s Examples

Broer, Hendrik; Kaper, Tasso J.; Krupa, Martin

doi:10.1007/s10884-013-9322-5

Cited by 34 publications

(47 citation statements)

References 19 publications

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“…which serves as the phase space of the CDE (3) and as the set of equilibrium points of the layer equation (4). In the latter context, it is useful to recall the concept of Normally Hyperbolic Invariant Manifold (NHIM).…”

Section: Introductionmentioning

confidence: 99%

Analysis of a slow–fast system near a cusp singularity

Jardón-Kojakhmetov

Broer

Roussarie

2016

Journal of Differential Equations

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International audienceThis paper studies a slow fast system whose principal characteristic is that the slow manifold is given by the critical set of the cusp catastrophe. Our analysis consists of two main parts: first, we recall a formal normal form suitable for systems as the one studied here; afterwards, taking advantage of this normal form, we investigate the transition near the cusp singularity by means of the blow up technique. Our contribution relies heavily in the usage of normal form theory, allowing us to refine previous results. (C) 2015 Elsevier Inc. All rights reserved

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Section: Introductionmentioning

confidence: 99%

Analysis of a slow–fast system near a cusp singularity

Jardón-Kojakhmetov

Broer

Roussarie

2016

Journal of Differential Equations

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“…The scenario depicted in Figure 5(d) shows that the singular orbits are close to the curve of cusps (since Γ F (0,δ) is so short), and consequently, the full system trajectories exhibit slow passage effects associated with a cusp. Currently, cusp singularities in slow/fast systems have been treated only for the case of a single cusp point [7], whereas our system presents a whole curve of them. Numerically, we observe that small perturbations to C change the geometry of the trajectory significantly (as highlighted by Figures 5(d) and (f)), but the precise details are unknown and left to future work.…”

Section: In Figures 5(c) and (D) We Find That The Folded Node Of Thementioning

confidence: 99%

Multiple Geometric Viewpoints of Mixed Mode Dynamics Associated with Pseudo-plateau Bursting

Vo¹,

Bertram²,

Wechselberger³

2013

SIAM J. Appl. Dyn. Syst.

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Abstract. Pseudo-plateau bursting is a type of oscillatory waveform associated with mixed mode dynamics in slow/fast systems and commonly found in neural bursting models. In a recent model for the electrical activity and calcium signaling in a pituitary lactotroph, two types of pseudo-plateau bursts were discovered: one in which the calcium drives the bursts and another in which the calcium simply follows them. Multiple methods from dynamical systems theory have been used to understand the bursting. The classic 2-timescale approach treats the calcium concentration as a slowly varying parameter and considers a parametrized family of fast subsystems. A more novel and successful 2-timescale approach divides the system so that there is only one fast variable and shows that the bursting arises from canard dynamics. Both methods can be effective analytic tools, but there has been little justification for one approach over the other. In this work, we use the lactotroph model to demonstrate that the two analysis techniques are different unfoldings of a 3-timescale system. We show that elementary applications of geometric singular perturbation theory in the 2-timescale and 3-timescale methods provide us with substantial predictive power. We use that predictive power to explain the transient and long-term dynamics of the pituitary lactotroph model.

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“…For ε = 0, we can define a new time parameter τ by t = ετ . With this new time τ , we can write (1) as x = ε f (x, z, ε) z = g(x, z, ε), (2) where the prime denotes the derivative with respect to τ . An important geometric object in the study of SFSs is the slow manifold, which is defined by …”

Section: Introductionmentioning

confidence: 99%

“…In the rest of the document, we prefer to work with an SFS written as (2). Furthermore, to avoid working with an ε-parameter family of vector fields as in (2), we extend (2) by adding the trivial equation ε = 0.…”

Section: Introductionmentioning

confidence: 99%

“…In this case, the blow-up technique [4,9] can be applied to desingularize the SFS. This methodology has been successfully used in many cases, e.g., [2,7,10,11,15,16], where many of these deal with an A k -SFS with fixed k = 2 or k = 3. Briefly speaking, the blow-up technique consists in an appropriate change of coordinates under which the induced vector field is regular or has simpler singularities (hyperbolic or partially hyperbolic).…”

Section: Introductionmentioning

confidence: 99%

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Formal normal form of Ak slow–fast systems

Jardón-Kojakhmetov

2015

Comptes Rendus. Mathématique

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Presented by the Editorial BoardAn A k slow-fast system is a particular type of singularly perturbed ODE. The corresponding slow manifold is defined by the critical points of a universal unfolding of an A k singularity. In this note we propose a formal normal form of A k slow-fast systems.© 2015 Académie des sciences. Published by Elsevier Masson SAS. All rights reserved. r é s u m éUn système lent-rapide de type A k est une équation différentielle ordinaire singulièrement perturbée avec une structure particulière. La varieté lente correspondante est définie par les points critiques d'un déploiment universel d'une singularité de type A k . Dans cette note, nous proposons une forme normale formelle des systèmes lents-rapides de type A k .

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Geometric Desingularization of a Cusp Singularity in Slow–Fast Systems with Applications to Zeeman’s Examples

Cited by 34 publications

References 19 publications

Analysis of a slow–fast system near a cusp singularity

Analysis of a slow–fast system near a cusp singularity

Multiple Geometric Viewpoints of Mixed Mode Dynamics Associated with Pseudo-plateau Bursting

Formal normal form of Ak slow–fast systems

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