Observer-based adaptive control for slung payload stabilization with a fully-actuated multirotor UAV.

This article presents an observer-based adaptive sliding mode controller for a fully-actuated hexacopter unmanned aerial vehicle, designed for trajectory tracking in a perturbed environment while carrying a cable-suspended payload. Based on the unavailability of a payload swing sensor, an extended high-gain observer is designed to provide full-state and disturbance estimation including payload motion. Such disturbances are compensated into the control loop to dampen the oscillations, thus improving the flight performance of the hexacopter driven by the adaptive control, providing robustness against bounded perturbations and chattering reduction. The stability analysis of the observer-based controller is guaranteed through Lyapunov theory. Simulations using a multibody emulator demonstrate time reduction in payload dampening while controlling the aircraft trajectory, compared to a feedback regulation-based adaptive controller. • An observer-based adaptive control is designed for UAV payload swing reduction. • The observer provides swing estimation without using additional sensor. • The control scheme provides robustness to disturbances and finite-time convergence. • The closed-loop stability of the observer-based control is proven by Lyapunov theory. • Simulations show the performance of the proposal for UAV tracking and swing damping. [ABSTRACT FROM AUTHOR]