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Nonlinear Model Learning for Compensation and Feedforward Control of Real-World Hydraulic Actuators Using Gaussian Processes

Abdolreza Taheri, Pelle Gustafsson, Marcus Rösth, Reza Ghabcheloo, Joni Pajarinen

2022IEEE Robotics and Automation Letters17 citationsDOIOpen Access PDF

Abstract

This paper presents a robust machine learning framework for modeling and control of hydraulic actuators. We identify several important challenges concerning learning accurate models of the dynamics for real machines, including noise and uncertainty in state measurements, nonlinear effects, input delays, and data-efficiency. In particular, we propose a dual-Gaussian process (GP) model architecture to learn a surrogate dynamics model of the actuator, and showcase the accuracy of predictions against the piecewise and neural network models that have been widely used in the literature. In addition, we provide robust techniques for learning neural network inverse models and controllers by batch GP inference in an automated, seamless and computationally fast manner. Finally, we demonstrate the performance of the trained controllers in real-world feedforward and tracking control applications.

Topics & Concepts

Feed forwardComputer scienceActuatorNonlinear systemArtificial neural networkControl engineeringControl theory (sociology)Artificial intelligenceGaussian processFeedforward neural networkMachine learningInferenceHydraulic cylinderGaussianEngineeringControl (management)Mechanical engineeringPhysicsQuantum mechanicsHydraulic and Pneumatic SystemsControl Systems and IdentificationReal-time simulation and control systems
Nonlinear Model Learning for Compensation and Feedforward Control of Real-World Hydraulic Actuators Using Gaussian Processes | Litcius