Abstract

This paper investigates the fractional order chaotic systems synchronization with input delay. To reduce the utilization of communication resources and achieve system synchronization, an adaptive neural network backstepping sliding mode controller is proposed based on event-triggered scheme without Zeno behavior. To avoid “explosion of complexity” and obtain fractional derivatives for virtual control functions continuously, the fractional order dynamic surface control (DSC) technology is introduced into the controller. The sliding term is introduced to enhance robustness. The Pade delay approximation method is used to handle the input delay, which can reduce the analysis complexity of fractional order chaotic systems with input delay. The unknown nonlinear functions and uncertain disturbances are approximated by the RBF neural network. An observer is used for state estimation of the fractional order system. By applying the Lyapunov stability theory, we can prove that the all closed-loop signals are bounded. Examples and simulations prove the feasibility of the proposed control method.

Highlights

  • Most coupled dynamic systems have complex dynamics

  • The fractional order dynamic systems can more truly reflect the situation of the system itself and present the physical phenomena reflected by the system, so the use of fractional calculus can more accurately describe the chaotic phenomenon [5], [6]

  • Compared with the current research, this work has the following contributions: 1) Aiming at the fractional order chaotic systems synchronization, an event-triggered adaptive neural network backstepping sliding controller is proposed for the first time

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Summary

Introduction

Most coupled dynamic systems have complex dynamics. The dynamical systems have the chaotic dynamics characteristics whenever its evolution sensitively depends on the initial conditions. INDEX TERMS Fractional order chaotic systems synchronization, event-triggered, dynamic surface control, neural network, observer, input delay. In [17], a fractional order adaptive synchronization controller was proposed for a new four-scroll chaotic systems.

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