DocumentCode
185120
Title
Geometric abstractions of vehicle dynamical models for intelligent autonomous motion
Author
Cowlagi, Raghvendra V. ; Kordonowy, David N.
Author_Institution
Aerosp. Eng. Program, Worcester Polytech. Inst., Worcester, MA, USA
fYear
2014
fDate
4-6 June 2014
Firstpage
4840
Lastpage
4845
Abstract
Motion-planning for autonomous vehicles involves a two-level planning hierarchy: a high-level task-planning algorithm and a lower-level trajectory generation algorithm. The task planner operates on a discrete structure, such as a graph, whereas the trajectory generator operates on a dynamical system with a continuous state space. The problem of ensuring “compatibility” between these two planners has been approached in the literature by constructing discrete abstractions of continuous systems. However, such abstractions do not always exist, especially for nonholonomic vehicle dynamical models. We propose abstractions for such models based on geometric analysis of the vehicle´s motion. The proposed motion-planning approach ensures that the task planner operates independently of the trajectory generation algorithm while maintaining a guarantee of “compatibility”, and also provides significant reductions in overall execution time.
Keywords
continuous systems; mobile robots; path planning; state-space methods; trajectory control; autonomous vehicle; continuous state space; discrete structure; geometric abstraction; high-level task-planning algorithm; intelligent autonomous motion; motion-planning; nonholonomic vehicle dynamical models; trajectory generation algorithm; trajectory generator; two-level planning hierarchy; Atmospheric modeling; Computational modeling; Load modeling; Motion-planning; Trajectory; Vehicles; Aerospace; Autonomous systems; Hybrid systems;
fLanguage
English
Publisher
ieee
Conference_Titel
American Control Conference (ACC), 2014
Conference_Location
Portland, OR
ISSN
0743-1619
Print_ISBN
978-1-4799-3272-6
Type
conf
DOI
10.1109/ACC.2014.6859475
Filename
6859475
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