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Nonlinear state-feedback design for vehicle lateral control using sum-of-squares programming

Alexandre M. Ribeiro, André R. Fioravanti, Alexandra Moutinho, Ely C. de Paiva

2020Vehicle System Dynamics35 citationsDOI

Abstract

This work addresses the lateral stabilisation problem of four-wheels ground vehicles. The objective is to estimate the largest state-space region such that the closed-loop vehicle lateral stability can be guaranteed. Sum-of-squares (SOS) programming technique is applied to find these maximum invariant sets while accounting for steering and yaw moment input saturations. The algorithm allows the region of attraction (RoA) to be approximated by a level set of a Lyapunov function (LF) and the computation of polynomial state feedback control laws. The method is applied for both straight-line motion and cornering manoeuver. Finally, a Monte-Carlo analysis is presented to show that the proposed SOS-based methodology can be used as a valid analysis and design tool considering a real vehicle application.

Topics & Concepts

Lyapunov functionControl theory (sociology)Explained sum of squaresNonlinear systemPolynomialComputationMoment (physics)Semidefinite programmingEngineeringVehicle dynamicsLeast-squares function approximationState spaceInvariant (physics)Monte Carlo methodMathematicsComputer scienceMathematical optimizationControl (management)AlgorithmEstimatorMathematical analysisArtificial intelligenceStatisticsClassical mechanicsAutomotive engineeringPhysicsMathematical physicsQuantum mechanicsVehicle Dynamics and Control SystemsMechanical Engineering and Vibrations ResearchHydraulic and Pneumatic Systems