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Learning-Based Predictive Path Following Control for Nonlinear Systems Under Uncertain Disturbances

Rui Yang, Lei Zheng, Jiesen Pan, Hui Cheng

2021IEEE Robotics and Automation Letters35 citationsDOIOpen Access PDF

Abstract

Accurate path following is challenging for autonomous robots operating in uncertain environments. Adaptive and predictive control strategies are crucial for a nonlinear robotic system to achieve high-performance path following control. In this letter, we propose a novel learning-based predictive control scheme that couples a high-level model predictive path following controller (MPFC) with a low-level learning-based feedback linearization controller (LB-FBLC) for nonlinear systems under uncertain disturbances. The low-level LB-FBLC utilizes Gaussian Processes to learn the uncertain environmental disturbances online and tracks the reference state accurately with a probabilistic stability guarantee. Meanwhile, the high-level MPFC exploits the linearized system model augmented with a virtual linear path dynamics model to optimize the evolution of path reference targets, and provides the reference states and controls for the low-level LB-FBLC. Simulation results illustrate the effectiveness of the proposed control strategy on a quadrotor path following task under unknown wind disturbances.

Topics & Concepts

Model predictive controlControl theory (sociology)Computer scienceController (irrigation)Path (computing)Nonlinear systemFeedback linearizationProbabilistic logicStability (learning theory)LinearizationControl engineeringControl (management)Artificial intelligenceEngineeringMachine learningPhysicsQuantum mechanicsBiologyProgramming languageAgronomyAdvanced Control Systems OptimizationFault Detection and Control SystemsControl Systems and Identification