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Robust Reinforcement Learning for Risk-Sensitive Linear Quadratic Gaussian Control

Leilei Cui, Tamer Başar, Zhong‐Ping Jiang

2024IEEE Transactions on Automatic Control13 citationsDOI

Abstract

This paper proposes a novel robust reinforcement learning framework for discrete-time linear systems with model mismatch that may arise from the sim-to-real gap. A key strategy is to invoke advanced techniques from control theory. Using the formulation of the classical risk-sensitive linear quadratic Gaussian control, a dual-loop policy optimization algorithm is proposed to generate a robust optimal controller. The dual-loop policy optimization algorithm is shown to be globally and uniformly convergent, and robust against disturbances during the learning process. This robustness property is called small-disturbance input-to-state stability and guarantees that the proposed policy optimization algorithm converges to a small neighborhood of the optimal controller as long as the disturbance at each learning step is relatively small. In addition, when the system dynamics is unknown, a novel model-free off-policy policy optimization algorithm is proposed. Finally, numerical examples are provided to illustrate the proposed algorithm.

Topics & Concepts

Linear-quadratic-Gaussian controlReinforcement learningControl theory (sociology)Robust controlGaussianQuadratic equationComputer scienceLinear control systemsGaussian processMathematicsControl (management)Linear systemArtificial intelligenceMathematical optimizationControl systemEngineeringMathematical analysisPhysicsElectrical engineeringGeometryQuantum mechanicsAdvanced Control Systems OptimizationAdaptive Dynamic Programming ControlStability and Control of Uncertain Systems