Litcius/Paper detail

Multiobjective Design of 2D Hyperchaotic System Using Leader Pareto Grey Wolf Optimizer

Abdurrahim Toktaş, Uğur Erkan, Deniz Üstün, Qiang Lai

2024IEEE Transactions on Systems Man and Cybernetics Systems58 citationsDOI

Abstract

A chaotic system is a mathematical model exhibiting random and unpredictable behavior. However, existing chaotic systems suffer from suboptimal parameters regarding chaotic indicators. In this study, a novel leader Pareto grey wolf optimizer (LP-GWO) is proposed for multiobjective (MO) design of 2D parametric hyperchaotic system (2D-PHS). The MO capability of LP-GWO is improved by integrating a LP solution within the Pareto optimal set. The effectiveness of LP-GWO is corroborated through a comparison with regular MO versions of grey wolf optimizer (GWO), artificial bee colony, particle swarm optimization, and differential evolution. Additionally, the validation extends to the exploration of LP-GWO’s performance across four variants of the 2D-PHS optimized by the compared algorithms. A 2D-PHS model with eight parameters is conceived and then optimized using LP-GWO by ensuring tradeoff between two objectives: Lyapunov exponent (LE) and Kolmogorov entropy (KE). A globally optimal design is chosen for freely improving the two objectives. The chaotic performance of 2D-PHS significantly outperforms existing systems in terms of precise chaos indicators. Therefore, the 2D-PHS has the best ergodicity and erraticity due to optimal parameters provided by LP-GWO.

Topics & Concepts

ChaoticMathematical optimizationErgodicityParticle swarm optimizationPareto principleMathematicsParametric statisticsPareto optimalLyapunov exponentMulti-objective optimizationComputer scienceControl theory (sociology)StatisticsArtificial intelligenceControl (management)Chaos control and synchronizationMetaheuristic Optimization Algorithms ResearchNeural Networks and Applications