Low-complexity learning of Linear Quadratic Regulators from noisy data
Claudio De Persis, Pietro Tesi
Abstract
This paper considers the Linear Quadratic Regulator problem for linear systems with unknown dynamics, a central problem in data-driven control and reinforcement learning. We propose a method that uses data to directly return a controller without estimating a model of the system. Sufficient conditions are given under which this method returns a stabilizing controller with guaranteed relative error when the data used to design the controller are affected by noise. This method has low complexity as it only requires a finite number of samples of the system response to a sufficiently exciting input, and can be efficiently implemented as a semi-definite programme.
Topics & Concepts
Linear-quadratic regulatorControl theory (sociology)Reinforcement learningController (irrigation)Noise (video)Linear systemQuadratic equationComputer scienceMathematicsMathematical optimizationOptimal controlControl (management)Artificial intelligenceMathematical analysisGeometryAgronomyBiologyImage (mathematics)Control Systems and IdentificationAdvanced Control Systems OptimizationFault Detection and Control Systems