Bayesian Optimization Framework for Efficient Fleet Design in Autonomous Multi-Robot Exploration
Concha, David Molina, Li, Jiping, Yin, Haoran, Park, Kyeonghyeon, Lee, Hyun-Rok, Lee, Taesik, Sirohi, Dhruv, Lee, Chi-Guhn
–arXiv.org Artificial Intelligence
This study addresses the challenge of fleet design optimization in the context of heterogeneous multi-robot fleets, aiming to obtain feasible designs that balance performance and costs. In the domain of autonomous multi-robot exploration, reinforcement learning agents play a central role, offering adaptability to complex terrains and facilitating collaboration among robots. However, modifying the fleet composition results in changes in the learned behavior, and training multi-robot systems using multi-agent reinforcement learning is expensive. Therefore, an exhaustive evaluation of each potential fleet design is infeasible. To tackle these hurdles, we introduce Bayesian Optimization for Fleet Design (BOFD), a framework leveraging multi-objective Bayesian Optimization to explore fleets on the Pareto front of performance and cost while accounting for uncertainty in the design space. Moreover, we establish a sub-linear bound for cumulative regret, supporting BOFD's robustness and efficacy. Extensive benchmark experiments in synthetic and simulated environments demonstrate the superiority of our framework over state-of-the-art methods, achieving efficient fleet designs with minimal fleet evaluations.
arXiv.org Artificial Intelligence
Aug-21-2024
- Country:
- South America > Chile (0.04)
- Oceania > Australia
- South Australia > Adelaide (0.04)
- North America > Canada
- Europe
- Italy (0.04)
- United Kingdom > England
- Cambridgeshire > Cambridge (0.04)
- Asia > South Korea
- Genre:
- Research Report > Promising Solution (0.66)
- Technology: