Sky-Hook Control and Kalman Filtering in Nonlinear Model of Tracked Vehicle Suspension System

Jurkiewicz, Andrzej; Kowal, Janusz; Zając, Kamil

doi:10.1515/ama-2017-0034

Abstract

The essence of the undertaken topic is application of the continuous sky-hook control strategy and the Extended Kalman Filter as the state observer in the 2S1 tracked vehicle suspension system. The half-car model of this suspension system consists of seven logarithmic spiral springs and two magnetorheological dampers which has been described by the Bingham model. The applied continuous sky-hook control strategy considers nonlinear stiffness characteristic of the logarithmic spiral springs. The control is determined on estimates generated by the Extended Kalman Filter. Improve of ride comfort is verified by comparing simulation results, under the same driving conditions, of controlled and passive vehicle suspension systems.

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Sky-Hook Control and Kalman Filtering in Nonlinear Model of Tracked Vehicle Suspension System

Abstract

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