Litcius/Paper detail

Poincaré maps for detecting chaos in fractional-order systems with hidden attractors for its Kaplan-Yorke dimension optimization

Daniel Clemente-López, Esteban Tlelo‐Cuautle, Luis-Gerardo de la Fraga, Jose Rangel‐Magdaleno, Jesús M. Muñoz‐Pacheco, Facultad de Ciencias de la Electrónica, Benemérita Universidad Autónoma de Puebla, Ciudad Universitaria, 18 Sur y Avenida San Claudio San Manuel, Puebla 72592, Mexico

2022AIMS Mathematics17 citationsDOIOpen Access PDF

Abstract

<abstract><p>The optimization of fractional-order (FO) chaotic systems is challenging when simulating a considerable number of cases for long times, where the primary problem is verifying if the given parameter values will generate chaotic behavior. In this manner, we introduce a methodology for detecting chaotic behavior in FO systems through the analysis of Poincaré maps. The optimization process is performed applying differential evolution (DE) and accelerated particle swarm optimization (APSO) algorithms for maximizing the Kaplan-Yorke dimension ($ D_{KY} $) of two case studies: a 3D and a 4D FO chaotic systems with hidden attractors. These FO chaotic systems are solved applying the Grünwald-Letnikov method, and the Numba just-in-time (jit) compiler is used to improve the optimization process's time execution in Python programming language. The optimization results show that the proposed method efficiently optimizes FO chaotic systems with hidden attractors while saving execution time.</p></abstract>

Topics & Concepts

AttractorChaoticParticle swarm optimizationMathematicsCompilerComputer scienceOptimization problemMathematical optimizationApplied mathematicsAlgorithmArtificial intelligenceMathematical analysisProgramming languageChaos control and synchronizationFractional Differential Equations SolutionsFractal and DNA sequence analysis