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Finite-time adaptive optimal control of uncertain strict-feedback nonlinear systems based on fuzzy observer and reinforcement learning

Yue Sun, Ming Chen, Kaixiang Peng, Li‐Bing Wu, Cungen Liu

Year
2024
Citations
14

Abstract

This paper proposes an adaptive optimal control strategy of finite-time control for high-order uncertain strict-feedback nonlinear systems. Firstly, a reinforcement learning (RL) based an optimal control scheme is employed to design a optimal controller, to achieve global optimisation. Additionally, considering the unmeasurable states, we construct a fuzzy observer and utilise fuzzy logic systems to approximate the unknown functions. Meanwhile, the inclusion of command filtering and time-based control simplifies the controller design and enhances the system's response rapidity. Finally, the effectiveness and feasibility of the proposed approach are validated through a numerical simulation and a single link-robot system simulation.

Keywords

Control theory (sociology)Observer (physics)Nonlinear systemReinforcement learningFuzzy logicController (irrigation)Computer scienceFuzzy control systemControl engineeringOptimal control

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