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Adaptive Neural Indirect Inverse Control for a Class of Fractional-Order Hysteretic Nonlinear Time-Delay Systems and Its Application

Jianguo Wang, Yulin Ni, Xiuyu Zhang, Zhi Li, Chenliang Wang, Chun‐Yi Su

Year
2024
Citations
11

Abstract

Motivated by wide utilizations of the smart material actuator-based motion control systems in soft robotics, this article proposes a neural adaptive fractional-order backstepping indirect inverse control (NAFBIIC) scheme for a class of fractional-order hysteretic nonlinear time-delay systems with the following features: 1) The effective control for the fractional-order hysteretic nonlinear system without constructing the direct hysteresis inverse model is realized. Then, the hysteresis indirect inverse compensator for fractional-order hysteretic nonlinear systems is designed. This makes the construction of the direct hysteresis inverse model to be not required any more and the hysteresis in the fractional-order nonlinear systems is effectively mitigated. 2) The time-delay functions are approximated by combining the finite covering lemma with neural networks, which leads to the abandonment of the traditional Lyapunov–Krasoviskii functions when dealing with time-delay functions. 3) The fractional-order model of piezoelectric positioning stage is proposed, and the motion control experiments are implemented to show the effectiveness of the proposed fractional-order indirect inverse control scheme.

Keywords

Control theory (sociology)Nonlinear systemClass (philosophy)Adaptive controlInverseHysteresisArtificial neural networkOrder (exchange)Computer scienceControl (management)

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