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Learning-based Adaptive Control using Contraction Theory

Hiroyasu Tsukamoto, Soon‐Jo Chung, Jean-Jacques Slotine

20212021 60th IEEE Conference on Decision and Control (CDC)15 citationsDOIOpen Access PDF

Abstract

Adaptive control is subject to stability and performance issues when a learned model is used to enhance its performance. This paper thus presents a deep learning-based adaptive control framework for nonlinear systems with multiplicatively-separable parametrization, called adaptive Neural Contraction Metric (aNCM). The aNCM approximates real-time optimization for computing a differential Lyapunov function and a corresponding stabilizing adaptive control law by using a Deep Neural Network (DNN). The use of DNNs permits real-time implementation of the control law and broad applicability to a variety of nonlinear systems with parametric and nonparametric uncertainties. We show using contraction theory that the aNCM ensures exponential boundedness of the distance between the target and controlled trajectories in the presence of parametric uncertainties of the model, learning errors caused by aNCM approximation, and external disturbances. Its superiority to the existing robust and adaptive control methods is demonstrated using a cart-pole balancing model.

Topics & Concepts

Adaptive controlControl theory (sociology)Artificial neural networkParametric statisticsNonlinear systemComputer scienceLyapunov functionContraction (grammar)Exponential stabilityParametrization (atmospheric modeling)Lyapunov stabilityAdaptive systemArtificial intelligenceMathematicsControl (management)StatisticsInternal medicinePhysicsRadiative transferMedicineQuantum mechanicsControl and Stability of Dynamical SystemsAdaptive Control of Nonlinear SystemsModel Reduction and Neural Networks
Learning-based Adaptive Control using Contraction Theory | Litcius