English

T$^{\star}$-Lite: A Fast Time-Risk Optimal Motion Planning Algorithm for Multi-Speed Autonomous Vehicles

Robotics 2021-08-04 v1 Artificial Intelligence Systems and Control Systems and Control

Abstract

In this paper, we develop a new algorithm, called T^{\star}-Lite, that enables fast time-risk optimal motion planning for variable-speed autonomous vehicles. The T^{\star}-Lite algorithm is a significantly faster version of the previously developed T^{\star} algorithm. T^{\star}-Lite uses the novel time-risk cost function of T^{\star}; however, instead of a grid-based approach, it uses an asymptotically optimal sampling-based motion planner. Furthermore, it utilizes the recently developed Generalized Multi-speed Dubins Motion-model (GMDM) for sample-to-sample kinodynamic motion planning. The sample-based approach and GMDM significantly reduce the computational burden of T^{\star} while providing reasonable solution quality. The sample points are drawn from a four-dimensional configuration space consisting of two position coordinates plus vehicle heading and speed. Specifically, T^{\star}-Lite enables the motion planner to select the vehicle speed and direction based on its proximity to the obstacle to generate faster and safer paths. In this paper, T^{\star}-Lite is developed using the RRT^{\star} motion planner, but adaptation to other motion planners is straightforward and depends on the needs of the planner

Keywords

Cite

@article{arxiv.2008.13048,
  title  = {T$^{\star}$-Lite: A Fast Time-Risk Optimal Motion Planning Algorithm for Multi-Speed Autonomous Vehicles},
  author = {James P. Wilson and Zongyuan Shen and Shalabh Gupta and Thomas A. Wettergren},
  journal= {arXiv preprint arXiv:2008.13048},
  year   = {2021}
}
R2 v1 2026-06-23T18:11:04.166Z