Attitude and Altitude Tracking Controller for Quadcopter Dynamical Systems
Abstract
Controlling a quadcopter is a challenging task because of the inherent high nonlinearity of a quadcopter system. In this paper, a new quaternion based nonlinear feedback controller for attitude and altitude regulation of a quadcopter is proposed. The dynamic model of the quadcopter is derived using Newton and Euler equations. The proposed controller is established based on a feedback linearization technique to control and regulate the quadcopter. Global asymptotic stability of the designed controller is verified using Lyapunov stability criterion. A comparison of the proposed controller performance and that of the state-of-the-art quadcopter controllers is performed to ensure the effectiveness of the proposed model. The efficiency of the proposed controller is clearly shown when the quadcopter is in or near a corner pose. Simulations are performed to assess the transient and steady state performance. Steady State Error ( Ess ) and Max Error ( EM ) are used as evaluation metrics of the proposed model performancePublisher
IEEEJournal title
IEEE Accessae974a485f413a2113503eed53cd6c53
10.1109/ACCESS.2022.3173739
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