Controlling Canard Cycles

Hildeberto Jardón-Kojakhmetov; Christian Kuehn

doi:10.1007/s10883-021-09553-2

Controlling Canard Cycles

Hildeberto Jardón-Kojakhmetov^*, Christian Kuehn

^*Corresponding author voor dit werk

Dynamical Systems, Geometry and Mathematical Physi

Onderzoeksoutput › Academic › peer review

2 Citaten (Scopus)

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Canard cycles are periodic orbits that appear as special solutions of fast-slow systems (or singularly perturbed ordinary differential equations). It is well known that canard cycles are difficult to detect, hard to reproduce numerically, and that they are sensible to exponentially small changes in parameters. In this paper, we combine techniques from geometric singular perturbation theory, the blow-up method, and control theory, to design controllers that stabilize canard cycles of planar fast-slow systems with a folded critical manifold. As an application, we propose a controller that produces stable mixed-mode oscillations in the van der Pol oscillator.

Originele taal-2	English
Pagina's (van-tot)	517–544
Aantal pagina's	28
Tijdschrift	Journal of Dynamical and Control Systems
Volume	28
Vroegere onlinedatum	24-jun.-2021
DOI's	https://doi.org/10.1007/s10883-021-09553-2
Status	Published - 2022

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title = "Controlling Canard Cycles",

abstract = "Canard cycles are periodic orbits that appear as special solutions of fast-slow systems (or singularly perturbed ordinary differential equations). It is well known that canard cycles are difficult to detect, hard to reproduce numerically, and that they are sensible to exponentially small changes in parameters. In this paper, we combine techniques from geometric singular perturbation theory, the blow-up method, and control theory, to design controllers that stabilize canard cycles of planar fast-slow systems with a folded critical manifold. As an application, we propose a controller that produces stable mixed-mode oscillations in the van der Pol oscillator.",

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AU - Jardón-Kojakhmetov, Hildeberto

AU - Kuehn, Christian

PY - 2022

Y1 - 2022

N2 - Canard cycles are periodic orbits that appear as special solutions of fast-slow systems (or singularly perturbed ordinary differential equations). It is well known that canard cycles are difficult to detect, hard to reproduce numerically, and that they are sensible to exponentially small changes in parameters. In this paper, we combine techniques from geometric singular perturbation theory, the blow-up method, and control theory, to design controllers that stabilize canard cycles of planar fast-slow systems with a folded critical manifold. As an application, we propose a controller that produces stable mixed-mode oscillations in the van der Pol oscillator.

AB - Canard cycles are periodic orbits that appear as special solutions of fast-slow systems (or singularly perturbed ordinary differential equations). It is well known that canard cycles are difficult to detect, hard to reproduce numerically, and that they are sensible to exponentially small changes in parameters. In this paper, we combine techniques from geometric singular perturbation theory, the blow-up method, and control theory, to design controllers that stabilize canard cycles of planar fast-slow systems with a folded critical manifold. As an application, we propose a controller that produces stable mixed-mode oscillations in the van der Pol oscillator.

UR - https://doi.org/10.1007/s10883-021-09553-2

U2 - 10.1007/s10883-021-09553-2

DO - 10.1007/s10883-021-09553-2

M3 - Article

SN - 1079-2724

VL - 28

SP - 517

EP - 544

JO - Journal of Dynamical and Control Systems

JF - Journal of Dynamical and Control Systems

ER -

Controlling Canard Cycles

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