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Published in:
Tire Dynamics Read chapter Read first chapter

2019 | OriginalPaper | Chapter

4. Road Dynamics

Author : Reza N. Jazar

Published in: Advanced Vehicle Dynamics

Publisher: Springer International Publishing

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Abstract

Passenger cars are developed to move on smooth paved pre-designed roads. To keep vehicles on road, we need a steering mechanism to provide steer angle as an input to the vehicle dynamic system. Ideally, all wheels of a vehicle should be able to steer independently such that the vehicle follows the desired path at the given speed. In this chapter we review steer and road dynamics.
Roads are made by continuously connecting straight and circular paths by proper transition turning sections. Having a continuous and well-behaved curvature is a necessary criterion in road design. The clothoid spiral is the best smooth transition connecting curve in road design which is expressed by parametric equations called Fresnel Integrals. The curvature of the clothoid curve varies linearly with arc length and this linearity makes clothoid the smoothest driving transition curve. Having a road with linearly increasing curvature is equivalent to entering the path with a steering wheel at the neutral position and turning the steering wheel with a constant angular velocity. This is a desirable and natural driving action.
Ideally, perpendicular lines to all wheels of a vehicle intersect at a single point called the kinematic center of rotation. When a vehicle is moving very slowly, we may assume the velocity vector of each wheel is in their tire plane. Therefore, the perpendicular lines to the tire planes intersect at the kinematic center of rotation of the vehicle, somewhere on the rear axis. However, when the vehicle moves faster, the actual center of rotation will move away from the kinematic center of rotation. Steering mechanism relates the last and right steerable wheels and provide a mathematical relationship to calculate all steer angles based on the angle of the steering wheel or the steer angle one of the wheels.

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previous chapter Vehicle Roll Dynamics
Literature
Bourmistrova, A., Simic, M., Hoseinnezhad, R., & Jazar, R. N. (2011). Autodriver algorithm. Journal of Systemics, Cybernetics and Informatics, 9(1), 56–66.
Genta, G. (2007). Motor vehicle dynamics, modeling and simulation. Singapore: World Scientific.MATH
Hunt, K. H. (1978). Kinematic geometry of mechanisms. London: Oxford University Press.MATH
Jazar, R. N. (2010b). Mathematical theory of autodriver for autonomous vehicles. Journal of Vibration and Control, 16(2), 253–279.MathSciNetCrossRef
Jazar, R. N. (2011). Advanced dynamics: Rigid body, multibody, and aerospace applications. New York: Wiley.CrossRef
Jazar, R. N., Subic A., & Zhong N. (2012). Kinematics of a smart variable caster mechanism for a vehicle steerable wheel. Vehicle System Dynamics, 50(12), 1861–1875.CrossRef
Jazar, R. N. (2017). Vehicle dynamics: Theory and application (3rd ed.). New York: Springer.CrossRef
Marzbani, H., Simic, M., Fard, M., & Jazar, R.N. (2015). Better road design for autonomous vehicles using clothoids. In E. Damiani, R. Howlett, L. Jain, L. Gallo & G. De Pietro (Eds.), Intelligent interactive multimedia systems and services. Smart innovation, systems and technologies (Vol. 40). Cham: Springer.
Soni, A. H. (1974). Mechanism synthesis and analysis. New York: McGraw-Hill.
Metadata
Title
Road Dynamics
Author
Reza N. Jazar
Copyright Year
2019
Book
Advanced Vehicle Dynamics

Print ISBN: 978-3-030-13060-2

Electronic ISBN: 978-3-030-13062-6

Copyright Year: 2019

DOI
https://doi.org/10.1007/978-3-030-13062-6_4

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