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Enhancing synchronization criteria for fractional-order chaotic neural networks via intermittent control: an extended dissipativity approach

S. Saravanan, R. Vadivel, S. Sabarathinam, Porpattama Hammachukiattikul, Nallappan Gunasekaran

2025Mathematical Modelling and Control17 citationsDOIOpen Access PDF

Abstract

In this paper, a recurrent intermittent control (RIC) for the synchronization of fractional-order chaotic neural networks (FOCNNs) is proposed in view of the extended dissipativity-based approach. Successively, standard linear matrix inequalites (LMIs)-based extended dissipative criteria are derived through differential inclusions and inequality mechanisms. Several sufficient conditions are obtained to ensure the synchronization of FOCNNs. Furthermore, RIC is generated to solve the synchronization problem for the considered FOCNNs. Based on the piecewise Lyapunov functional, this paper derives a exponentially stable criterion in connection with linear matrix inequalities using the Matlab toolbox. Extended dissipativity can be employed to precisely define $ L_2 $–$ L_{\infty} $, $ H_{\infty} $, passivity, and $ (Q, S, R) $-$ \vartheta $ dissipative performance. This is achieved by modifying the weighting matrices to achieve the desired performance level. The successful application of the stability criterion that was planned is demonstrated by the outcomes of the simulation.

Topics & Concepts

Intermittent controlSynchronization (alternating current)Control theory (sociology)Artificial neural networkChaotic systemsChaoticOrder (exchange)Control (management)Computer scienceSynchronization of chaosMathematicsTopology (electrical circuits)Control engineeringArtificial intelligenceEngineeringEconomicsCombinatoricsFinanceNeural Networks Stability and SynchronizationChaos control and synchronizationNeural Networks and Applications
Enhancing synchronization criteria for fractional-order chaotic neural networks via intermittent control: an extended dissipativity approach | Litcius