Abstract
Model-based trajectory tracking has become a widely used technique for automated driving system applications. A critical design decision is the proper selection of a vehicle model that achieves the best trade-off between real-time capability and robustness. Blending different types of vehicle models is a recent practice to increase the operating range of model-based trajectory tracking control applications. However, current approaches focus on the use of longitudinal speed as the blending parameter, with a formal procedure to tune and select its parameters still lacking. This work presents a novel approach based on lateral accelerations, along with a formal procedure and criteria to tune and select blending parameters, for its use on model-based predictive controllers for autonomous driving. An electric passenger bus traveling at different speeds over urban routes is proposed as a case study. Results demonstrate that the lateral acceleration, which is proportional to the lateral forces that differentiate kinematic and dynamic models, is a more appropriate model-switching enabler than the currently used longitudinal velocity. Moreover, the advanced procedure to define blending parameters is shown to be effective. Finally, a smooth blending method offers better tracking results versus sudden model switching ones and non-blending techniques.
Highlights
Trajectory tracking is a crucial task in high driving automation developments
The performance evaluation of vehicle models and switching methods employed are detailed
Pure kinematic and dynamic methods are considered for comparison
Summary
Trajectory tracking is a crucial task in high driving automation developments. proper control methods must be designed to safely follow the desired reference path and speed. MPC approaches use the vehicle and tire models to predict the future behavior of the vehicle and compute the optimum control sequence to be applied. A critical design decision in MPC-based methods is the selection of a proper model to predict the behavior of the vehicle, as the controller performance will depend heavily on its accuracy and real-time capability. This selection is not a trivial task, as covering a broad range of speeds, even the limits of handling, while maintaining real-time capabilities, represents a current engineering challenge [2]
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