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Adaptive interval type-2 fuzzy control for multi-legged underwater robot with input saturation and full-state constraints

Yanchao Sun, Xinyan Chen, Ziwei Wang, Hongde Qin, Ruijie Jing

Year
2021
Citations
24

Abstract

In this paper, a trajectory tracking control strategy is proposed for multi-legged underwater robot in the presence of input saturation and full-state constraints. An anti-windup compensator is introduced to solve the input saturation problem, which can compensate for the saturation difference directly. Besides, the state constrains are addressed by a new state saturation function and the external unknown disturbances are solved by interval type-2 fuzzy neural network approximator. The dynamic surface control method combines with backstepping method is utilised to construct Lyapunov function. The control law and signals of the closed-loop system can be guaranteed to achieve semi-global uniform boundedness. Numerical simulations are presented to show the effectiveness of the proposed algorithm.

Keywords

Control theory (sociology)BacksteppingInterval (graph theory)Lyapunov functionArtificial neural networkSaturation (graph theory)Fuzzy control systemFuzzy logicMathematicsComputer science

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