High-Precision Trajectory Tracking in Changing Environments Through $\mathcal{L}_1$ Adaptive Feedback and Iterative Learning

As robots and other automated systems are introduced to unknown and dynamic environments, robust and adaptive control strategies are required to cope with disturbances, unmodeled dynamics and parametric uncertainties. In this paper, we propose and provide theoretical proofs of a combined $\mathcal{L}_1$ adaptive feedback and iterative learning control (ILC) framework to improve trajectory tracking of a system subject to unknown and changing disturbances. The $\mathcal{L}_1$ adaptive controller forces the system to behave in a repeatable, predefined way, even in the presence of unknown and changing disturbances; however, this does not imply that perfect trajectory tracking is achieved. ILC improves the tracking performance based on experience from previous executions. The performance of ILC is limited by the robustness and repeatability of the underlying system, which, in this approach, is handled by the $\mathcal{L}_1$ adaptive controller. In particular, we are able to generalize learned trajectories across different system configurations because the $\mathcal{L}_1$ adaptive controller handles the underlying changes in the system. We demonstrate the improved trajectory tracking performance and generalization capabilities of the combined method compared to pure ILC in experiments with a quadrotor subject to unknown, dynamic disturbances. This is the first work to show $\mathcal{L}_1$ adaptive control combined with ILC in experiment.

[1]  Raffaello D'Andrea,et al.  Optimization-based iterative learning for precise quadrocopter trajectory tracking , 2012, Autonomous Robots.

[2]  Angela P. Schoellig,et al.  Design of norm-optimal iterative learning controllers: The effect of an iteration-domain Kalman filter for disturbance estimation , 2014, 53rd IEEE Conference on Decision and Control.

[3]  Jay H. Lee,et al.  Model-based iterative learning control with a quadratic criterion for time-varying linear systems , 2000, Autom..

[4]  Raffaello D'Andrea,et al.  Optimization-based iterative learning control for trajectory tracking , 2009, 2009 European Control Conference (ECC).

[5]  Naira Hovakimyan,et al.  L1 Adaptive Control Theory - Guaranteed Robustness with Fast Adaptation , 2010, Advances in design and control.

[6]  Jay H. Lee,et al.  Model predictive control: past, present and future , 1999 .

[7]  Jonathan P. How,et al.  L 1 Adaptive Control for Indoor Autonomous Vehicles: Design Process and Flight Testing , 2009 .

[8]  Sandipan Mishra,et al.  Robust Iterative Learning Control: L1 adaptive feedback control in an ILC framework , 2011, Proceedings of the 2011 American Control Conference.

[9]  Kira Barton,et al.  Robust iterative learning for high precision motion control through L 1 adaptive feedback , 2014 .

[10]  Naira Hovakimyan,et al.  L1 Adaptive Controller for Attitude Control of Multirotors , 2012 .

[11]  Kira Barton,et al.  ℒ1 adaptive control in an iterative learning control framework: Stability, robustness and design trade-offs , 2013, 2013 American Control Conference.

[12]  Robert E. Skelton,et al.  Model error concepts in control design , 1989 .

[13]  Ian Postlethwaite,et al.  Multivariable Feedback Control: Analysis and Design , 1996 .