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Intelligent-Critic-Based Tracking Control of Discrete-Time Input-Affine Systems and Approximation Error Analysis With Application Verification

Ding Wang, Ning Gao, Mingming Ha, Mingming Zhao, Junlong Wu, Junfei Qiao

2023IEEE Transactions on Cybernetics10 citationsDOI

Abstract

In recent years, the application of function approximators, such as neural networks and polynomials, has ushered in a new stage of development in solving optimal control problems. However, considering the existence of approximation errors, the stability of the controlled system cannot be guaranteed. Therefore, in view of the prevalence of approximation errors, we investigate optimal tracking control problems for discrete-time systems. First, a novel value function is introduced into the intelligent critic framework. Second, an implicit method is utilized to demonstrate the boundedness of the iterative value functions with approximation errors. An explicit method is applied to prove the stability of the system with approximation errors. Furthermore, an evolving policy is designed to iteratively tackle the optimal tracking control problem and demonstrate the stability of the system. Finally, the effectiveness of the developed method is verified through numerical as well as practical examples.

Topics & Concepts

Function approximationStability (learning theory)Tracking errorComputer scienceApproximation errorArtificial neural networkBellman equationAffine transformationOptimal controlControl theory (sociology)Function (biology)Mathematical optimizationDiscrete time and continuous timeTracking (education)Control (management)MathematicsAlgorithmArtificial intelligenceMachine learningPsychologyPure mathematicsEvolutionary biologyPedagogyStatisticsBiologyAdaptive Dynamic Programming ControlReinforcement Learning in RoboticsViral Infections and Vectors
Intelligent-Critic-Based Tracking Control of Discrete-Time Input-Affine Systems and Approximation Error Analysis With Application Verification | Litcius