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Physics-informed recurrent neural network modeling for predictive control of nonlinear processes

Yingzhe Zheng, Cheng Hu, Xiaonan Wang, Zhe Wu

2023Journal of Process Control85 citationsDOIOpen Access PDF

Abstract

In this work, we present a physics-informed recurrent neural network (PIRNN) modeling approach, and a PIRNN-based predictive control scheme for a general class of nonlinear dynamic systems. Specifically, we first develop a hybrid data-driven and physics-guided modeling framework that integrates measurement data and mechanistic mathematical models to construct high-fidelity RNN models. Then, we derive a generalization error bound of the PIRNN model based on a nominal system model via the Rademacher complexity technique from statistical machine learning theory. Subsequently, the PIRNN model is utilized in Lyapunov-based model predictive controllers and applied to a chemical reactor example with Gaussian measurement noise to demonstrate its improved noise rejection and generalization performance in comparison to the purely data-driven and the purely physics-guided RNN-based predictive control schemes.

Topics & Concepts

GeneralizationModel predictive controlArtificial neural networkRecurrent neural networkNonlinear systemComputer scienceMachine learningArtificial intelligenceFidelityNoise (video)Control theory (sociology)Control (management)MathematicsPhysicsQuantum mechanicsImage (mathematics)TelecommunicationsMathematical analysisModel Reduction and Neural NetworksNeural Networks and ApplicationsFault Detection and Control Systems