Lyapunov methods; Neuroscience; Nonlinear systems; Qualitative methods; Singular perturbation; Singularity theory; Transition detection; Qualitative method; Singular perturbations; Control and Systems Engineering; Electrical and Electronic Engineering
Abstract :
[en] Motivated by neuroscience applications, we introduce the concept of qualitative detection, that is, the problem of determining on-line the current qualitative dynamical behavior (e.g., resting, oscillating, bursting, spiking etc.) of a nonlinear system. The approach is thought for systems characterized by i) large parameter variability and redundancy, ii) a small number of possible robust, qualitatively different dynamical behaviors and, iii) the presence of sharply different characteristic timescales. These properties are omnipresent in neurosciences and hamper quantitative modeling and fitting of experimental data. As a result, novel control theoretical strategies are needed to face neuroscience challenges like on-line epileptic seizure detection. The proposed approach aims at detecting the current dynamical behavior of the system and whether a qualitative change is likely to occur without quantitatively fitting any model nor asymptotically estimating any parameter. We talk of qualitative detection. We rely on the qualitative properties of the system dynamics, extracted via singularity and singular perturbation theories, to design low dimensional qualitative detectors. We introduce this concept on a general class of singularly perturbed systems and then solve the problem for an analytically tractable class of two-dimensional systems with a single unknown sigmoidal nonlinearity and two sharply separated timescales. Numerical results are provided to show the performance of the designed qualitative detector.
Disciplines :
Engineering, computing & technology: Multidisciplinary, general & others
Author, co-author :
Tang, Ying; CRIStAL CNRS UMR 9189, Université de Lille, France
Franci, Alessio ; Université de Liège - ULiège > Département d'électricité, électronique et informatique (Institut Montefiore) > Brain-Inspired Computing ; Department of Mathematics, Universidad National Autónoma de México, Mexico
Postoyan, Romain; Université de Lorraine, CNRS, CRAN, Nancy, France
Language :
English
Title :
On-line detection of qualitative dynamical changes in nonlinear systems: The resting-oscillation case
ANR - Agence Nationale de la Recherche [FR] Région Grand Est UNAM - National Autonomous University of Mexico [MX]
Funding text :
This work was supported by the ANR under the grant SEPICOT (ANR 12 JS03 004 01), by the French “Région Grand Est ” through a fellowship grant 2016–2017, and by DGAPA-UNAM under the grant PAPIIT RA105518. The material in this paper was presented at the 20th World Congress of the International Federation of Automatic Control, July 9–14, 2017, Toulouse, France (Tang, Franci, & Postoyan, 2017b). This paper was recommended for publication in revised form by Associate Editor Warren E. Dixon under the direction of Editor Daniel Liberzon.
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