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Supervisor-Based Hierarchical Adaptive MPC for Yaw Stabilization of FWID-EVs Under Extreme Conditions

Jing Zhao, Renbin Li, Genge Zhang, Chao Huang, Zhongchao Liang, Zhengtao Ding

2024IEEE Transactions on Intelligent Transportation Systems19 citationsDOI

Abstract

This work focuses on the yaw stabilization of the four-wheel-independent-drive electric vehicle (FWID-EV) with the constrained active front steering (AFS) and direct yaw-moment control (DYC). First, a modified tire model is employed in the design of the unscented Kalman filter to realize the estimation of the tire-road friction coefficient (TRFC), and a backpropagation neural network is developed to online estimate the tire cornering stiffness; Second, a yaw stabilization supervisor is designed to solve the conflicts between the AFS and DYC systems, and the mode-boundary maps of the tire operating regions are utilized to generate the triggered signals so as to activate the systems; Third, a hierarchical adaptive model predictive control (MPC), including the estimation, activation, compensation, and distribution layers is proposed for yaw stabilization of the FWID-EV under the extreme conditions. Emergency maneuvers under big path curvature, low TRFC, and high vehicle speed are designed. Both software-in-the-loop and hardware-in-the-loop tests are performed to examine the effectiveness and practicability of the proposed methods, respectively.

Topics & Concepts

SupervisorControl theory (sociology)YawComputer scienceControl engineeringAutomotive engineeringEngineeringArtificial intelligenceControl (management)LawPolitical scienceIterative Learning Control SystemsAdaptive Control of Nonlinear SystemsHydraulic and Pneumatic Systems
Supervisor-Based Hierarchical Adaptive MPC for Yaw Stabilization of FWID-EVs Under Extreme Conditions | Litcius