Abstract
In Alleyne (1996) several vehicle control options were considered for Unintended Roadway Departure (URD) prevention and conclusions were drawn as to the efficacy of each method. This companion paper investigates the use of several different inputs for the control of a vehicle, in the context of Obstacle Avoidance for autonomous vehicles. In this investigation, the goal of the controller is to provide an intervention in the event of the vehicle detecting an obstacle in its path. The five types of inputs that will be considered are (i) Four Wheel Steering; (ii) Front Wheel Steering; (iii) Four Wheel Brake Steering; (iv) Front Wheel Brake Steering; and (v) Rear Wheel Brake Steering. The controller design is an LQ controller based on the simplified dynamics of a 2 degree of freedom bicycle model. However the analysis of the different strategies are performed on a more complete, nonlinear vehicle model. A key contribution of this paper is the quantitative evaluation of the relative efficiencies of each of these input strategies being examined. Unlike most control schemes, an important metric of performance is the ratio of peak tire force used versus available tire force. The conclusions reached in this paper shed additional light on appropriate input actuator methods for vehicle guidance and control.
Original language | English (US) |
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Pages (from-to) | 371-392 |
Number of pages | 22 |
Journal | Vehicle System Dynamics |
Volume | 27 |
Issue number | 5-6 |
DOIs | |
State | Published - Jun 1997 |
Externally published | Yes |
Bibliographical note
Funding Information:The author would like to thank S. Sivashankar, T. Pilutti, J. Engelman, and D. Hrovat of the Ford Scientific Research Laboratory for their input to this work. This work was partially supported by a Ford Motor Co. Faculty Internship.