English

Multi-Vehicle Collision Avoidance via Hamilton-Jacobi Reachability and Mixed Integer Programming

Systems and Control 2016-10-05 v2 Multiagent Systems

Abstract

Multi-agent differential games are important and useful tools for analyzing many practical problems. With the recent surge of interest in using UAVs for civil purposes, the importance and urgency of developing tractable multi-agent analysis techniques that provide safety and performance guarantees is at an all-time high. Hamilton-Jacobi (HJ) reachability has successfully provided safety guarantees to small-scale systems and is flexible in terms of system dynamics. However, the exponential complexity scaling of HJ reachability prevents its direct application to large scale problems when the number of vehicles is greater than two. In this paper, we overcome the scalability limitations of HJ reachability by using a mixed integer program that exploits the properties of HJ solutions to provide higher-level control logic. Our proposed method provides safety guarantee for three-vehicle systems -- a previously intractable task for HJ reachability -- without incurring significant additional computation cost. Furthermore, our method is scalable beyond three vehicles and performs significantly better by several metrics than an extension of pairwise collision avoidance to multi-vehicle collision avoidance. We demonstrate our proposed method in simulations.

Keywords

Cite

@article{arxiv.1603.05200,
  title  = {Multi-Vehicle Collision Avoidance via Hamilton-Jacobi Reachability and Mixed Integer Programming},
  author = {Mo Chen and Jennifer C. Shih and Claire J. Tomlin},
  journal= {arXiv preprint arXiv:1603.05200},
  year   = {2016}
}

Comments

To Appear in IEEE Conference in Decision and Control 2016

R2 v1 2026-06-22T13:12:31.911Z