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Finite-Time Attitude Fault Tolerant Control of Quadcopter System via Neural Networks

Ngoc Phi Nguyen, Nguyen Xuan-Mung, Ha Le Nhu Ngoc Thanh, Tuân-Tú Huỳnh, Sung Kyung Hong

2020Mathematics32 citationsDOIOpen Access PDF

Abstract

This study investigates the design of fault-tolerant control involving adaptive nonsingular fast terminal sliding mode control and neural networks. Unlike those of previous control strategies, the adaptive law of the investigated algorithm is considered in both continuous and discontinuous terms, which means that any disturbances, model uncertainties, and actuator faults can be simultaneously compensated for. First, a quadcopter model is presented under the conditions of disturbances and uncertainties. Second, normal adaptive nonsingular fast terminal sliding mode control is utilized to handle these disturbances. Thereafter, fault-tolerant control based on adaptive nonsingular fast terminal sliding mode control and neural network approximation is presented, which can handle the actuator faults, model uncertainties, and disturbances. For each controller design, the Lyapunov function is applied to validate the robustness of the investigated method. Finally, the effectiveness of the investigated control approach is presented via comparative numerical examples under different fault conditions and uncertainties.

Topics & Concepts

Control theory (sociology)QuadcopterRobustness (evolution)Artificial neural networkLyapunov functionTerminal sliding modeActuatorComputer scienceFault toleranceInvertible matrixAdaptive controlSliding mode controlControl engineeringEngineeringControl (management)MathematicsNonlinear systemArtificial intelligenceDistributed computingBiochemistryPure mathematicsChemistryQuantum mechanicsAerospace engineeringGenePhysicsAdaptive Control of Nonlinear SystemsAdaptive Dynamic Programming ControlStability and Control of Uncertain Systems