Differential Flatness of Quadrotor Dynamics Subject to Rotor Drag for Accurate Tracking of High-Speed Trajectories

12/06/2017

∙

In this paper, we prove that the dynamical model of a quadrotor subject to linear rotor drag effects is differentially flat in its position and heading. We use this property to compute feed-forward control terms directly from a reference trajectory to be tracked. The obtained feed-forward terms are then used in a cascaded, nonlinear feedback control law that enables accurate agile flight with quadrotors. Compared to state-of-the-art control methods, which treat the rotor drag as an unknown disturbance, our method reduces the trajectory tracking error significantly. Finally, we present a method based on a gradient-free optimization to identify the rotor drag coefficients, which are required to compute the feed-forward control terms. The new theoretical results are thoroughly validated trough extensive comparative experiments.

READ FULL TEXT

Differential Flatness of Quadrotor Dynamics Subject to Rotor Drag for Accurate Tracking of High-Speed Trajectories

Keep soft robots soft -- a data-driven based trade-off between feed-forward and feedback control

Differential Flatness of Lifting-Wing Quadcopters Subject to Drag and Lift for Accurate Tracking

Robust tracking of an unknown trajectory with a multi-rotor UAV: A high-gain observer approach

Extending Flat Motion Planning to Non-flat Systems. Experiments on Aircraft Models Using Maple

Flatness Based Control of an Industrial Robot Joint Using Secondary Encoders

Flexible-Joint Manipulator Trajectory Tracking with Learned Two-Stage Model employing One-Step Future Prediction

Physics-Inspired Temporal Learning of Quadrotor Dynamics for Accurate Model Predictive Trajectory Tracking

Differential Flatness of Quadrotor Dynamics Subject to Rotor Drag for Accurate Tracking of High-Speed Trajectories

Related Research

Keep soft robots soft -- a data-driven based trade-off between feed-forward and feedback control

Differential Flatness of Lifting-Wing Quadcopters Subject to Drag and Lift for Accurate Tracking

Robust tracking of an unknown trajectory with a multi-rotor UAV: A high-gain observer approach

Extending Flat Motion Planning to Non-flat Systems. Experiments on Aircraft Models Using Maple

Flatness Based Control of an Industrial Robot Joint Using Secondary Encoders

Flexible-Joint Manipulator Trajectory Tracking with Learned Two-Stage Model employing One-Step Future Prediction

Physics-Inspired Temporal Learning of Quadrotor Dynamics for Accurate Model Predictive Trajectory Tracking