Nonlinear Adaptive Stabilization of a Class of Planar Slow-Fast Systems at a Non-Hyperbolic Point

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Abstract

Non-hyperbolic points of slow-fast systems (also known as singularly perturbed ordinary differential equations) are responsible for many interesting behavior such as relaxation oscillations, canards, mixed-mode oscillations, etc. Recently, the authors have proposed a control strategy to stabilize non-hyperbolic points of planar slow-fast systems. Such strategy is based on geometric desingularization, which is a well suited technique to analyze the dynamics of slow-fast systems near non-hyperbolic points. This technique transforms the singular perturbation problem to an equivalent regular perturbation problem. This papers treats the nonlinear adaptive stabilization problem of slow-fast systems. The novelty is that the point to be stabilized is non-hyperbolic. The controller is designed by combining geometric desingularization and Lyapunov based techniques. Through the action of the controller, we basically inject a normally hyperbolic behavior to the fast variable. Our results are exemplified on the van der Pol oscillator.
Original languageEnglish
Title of host publicationProceedings of the American Control Conference 2017
PublisherIEEEXplore
Pages2441-2446
ISBN (Print)978-1-5090-5992-8
DOIs
Publication statusPublished - 3-Jul-2017
Event2017 American Control Conference - Sheraton Seattle Hotel, Seattle, United States
Duration: 24-May-201726-May-2017
http://acc2017.a2c2.org/

Conference

Conference2017 American Control Conference
Abbreviated titleACC 2017
Country/TerritoryUnited States
CitySeattle
Period24/05/201726/05/2017
Internet address

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