English

Bi-Level Route Optimization and Path Planning with Hazard Exploration

Optimization and Control 2026-01-22 v1

Abstract

Effective risk monitoring in dynamic environments such as disaster zones requires an adaptive exploration strategy to detect hidden threats. We propose a bi-level unmanned aerial vehicle (UAV) monitoring strategy that efficiently integrates high-level route optimization with low-level path planning for known and unknown hazards. At the high level, we formulate the route optimization as a vehicle routing problem (VRP) to determine the optimal sequence for visiting known hazard locations. To strategically incorporate exploration efficiency, we introduce an edge-based centroidal Voronoi tessellation (CVT), which refines baseline routes using pseudo-nodes and allocates path budgets based on the UAV's battery capacity using a line segment Voronoi diagram. At the low level, path planning maximizes information gain within the allocated path budget by generating kinematically feasible B-spline trajectories. Bayesian inference is applied to dynamically update hazard probabilities, enabling the UAVs to prioritize unexplored regions. Simulation results demonstrate that edge-based CVT improves spatial coverage and route uniformity compared to the node-based method. Additionally, our optimized path planning consistently outperforms baselines in hazard discovery rates across a diverse set of scenarios.

Keywords

Cite

@article{arxiv.2503.24044,
  title  = {Bi-Level Route Optimization and Path Planning with Hazard Exploration},
  author = {Jimin Choi and Grant Stagg and Cameron K. Peterson and Max Z. Li},
  journal= {arXiv preprint arXiv:2503.24044},
  year   = {2026}
}
R2 v1 2026-06-28T22:40:31.297Z