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Predictive Direct Yaw Moment Control Based on the Koopman Operator

Marko Švec, Šandor Ileš, Jadranko Matuško

2023IEEE Transactions on Control Systems Technology31 citationsDOI

Abstract

In this brief, we propose a predictive algorithm for direct yaw moment control (DYC) in which a vehicle model is identified by a finite-dimensional approximation of the Koopman operator. The Koopman operator is a linear predictor for nonlinear dynamical systems based on raising the nonlinear dynamics into a higher-dimensional space where its evolution is linear. A novel method for the finite-dimensional numerical approximation of the Koopman operator is proposed, called enhanced extended dynamic mode decomposition (E 2DMD). This method allows the reduction of the basis dimension, determined by a user-defined dictionary of observable functions, to achieve a trade-off between model complexity and accuracy. The E 2DMD Koopman vehicle model was obtained from the dataset generated by simulating different scenarios using the nonlinear vehicle model and was then used to develop a Koopman operator model predictive control (KMPC) algorithm. KMPC was compared to a linear time variant (LTV) and a nonlinear model predictive control (NMPC), which are widely used in the literature, and showed better performance in some cases and a reduction in computational complexity in all cases.

Topics & Concepts

Operator (biology)Model predictive controlControl theory (sociology)Nonlinear systemMoment (physics)Dynamic mode decompositionDimension (graph theory)MathematicsReduction (mathematics)Computer scienceApplied mathematicsControl (management)Artificial intelligenceMachine learningPhysicsQuantum mechanicsChemistryTranscription factorGeometryClassical mechanicsRepressorBiochemistryGenePure mathematicsFuel Cells and Related MaterialsCardiovascular Function and Risk FactorsModel Reduction and Neural Networks
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