Real Time Crowd Navigation from First Principles of Probability Theory

Authors

  • Peter Trautman Honda Research Institute
  • Karankumar Patel Honda Research Institute

DOI:

https://doi.org/10.1609/icaps.v30i1.6741

Abstract

Constructing realistic and real time human-robot interaction models is a core challenge in crowd navigation. In this paper we derive a robot-agent interaction density from first principles of probability theory; we call our approach “first order interacting Gaussian processes” (foIGP). Furthermore, we compute locally optimal solutions—with respect to multi-faceted agent “intent” and “flexibility”—in near real time on a laptop CPU. We test on challenging scenarios from the ETH crowd dataset and show that the safety and efficiency statistics of foIGP is competitive with human safety and efficiency statistics. Further, we compute the safety and efficiency statistics of dynamic window avoidance, a physics based model variant of foIGP, a Monte Carlo inference based approach, and the best performing deep reinforcement learning algorithm; foIGP outperforms all of them.

Downloads

Published

2020-06-01

How to Cite

Trautman, P., & Patel, K. (2020). Real Time Crowd Navigation from First Principles of Probability Theory. Proceedings of the International Conference on Automated Planning and Scheduling, 30(1), 459-467. https://doi.org/10.1609/icaps.v30i1.6741