Abstract

Active rear steering has been used in many research work to enhance ground vehicles’ lateral stability. However, there is a shortage in the published research studies that consider the incorporation of active rear steering for autonomous vehicles applications, especially in case of multi-axle combat vehicles. In this paper, various H∞ controllers are developed to actively steer rear axles of a multi-axle combat vehicle using a linearized bicycle model. The proposed controllers are incorporated with a 22 degrees of Freedom nonlinear Trucksim full vehicle model to study and compare the developed controllers’ performance on a hard surface. Moreover, a frequency-domain analysis is conducted to investigate the influence of the active rear steering on the path-following controllers’ robustness in terms of stability and performance. Three path-following controllers are designed, where the first controller is applied on the front two axles of the vehicle, while the rear two axles are fixed. The second is applied to all-wheel steering vehicle. The third controller is an integration between the designed front steering path-following controller and a developed lateral stability active rear steering controller. Eventually, a series of virtual maneuvers are performed to evaluate the effectiveness of the intended controllers to present the advantages and limitations of each controller at different driving conditions.

Highlights

  • IntroductionSeveral safety controllers have been introduced to meet this requirement

  • In the past two decades, safety demand has been increased in automotive engineering

  • The value 0.5 present driving the vehicle on wet asphalt, while the 0.85 presents driving on dry asphalt[46]

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Summary

Introduction

Several safety controllers have been introduced to meet this requirement. Examples of these systems are anti-lock braking systems, electronic stability control, lane-keeping assist, active suspension, and torque vectoring control. The vehicle’s lateral, longitudinal, and vertical dynamics are controlled by these systems. In case of avoiding a crash or performing severe maneuvers, controlling the lateral stability is more beneficial. The first is direct yaw moment control[1,2,3,4,5], while the second is active steering control, which can be performed using active front steering[6,7,8,9] and/or active rear steering (ARS) systems[10,11]

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