English

Optimal Average Disk-Inspection via Fermat's Principle

Discrete Mathematics 2026-01-07 v3

Abstract

This work resolves the optimal average-case cost of the Disk-Inspection problem, a variant of Bellman's 1955 lost-in-a-forest problem. In Disk-Inspection, a mobile agent starts at the center of a unit disk and follows a trajectory that inspects perimeter points whenever the disk does not obstruct visibility. The worst-case cost was solved optimally in 1957 by Isbell, but the average-case version remained open, with heuristic upper bounds proposed by Gluss in 1961 and improved only recently. Our approach applies Fermat's Principle of Least Time to a recently proposed discretization framework, showing that optimal solutions are captured by a one-parameter family of recurrences independent of the discretization size. In the continuum limit these recurrences give rise to a single-parameter optimal control problem, whose trajectories coincide with limiting solutions of the original Disk-Inspection problem. A crucial step is proving that the optimal initial condition generates a trajectory that avoids the unit disk, thereby validating the optics formulation and reducing the many-variable optimization to a rigorous one-parameter problem. In particular, this disproves Gluss's conjecture that optimal trajectories must touch the disk. Our analysis determines the exact optimal average-case inspection cost, equal to 3.5492593.549259\ldots and certified to at least six digits of accuracy.

Cite

@article{arxiv.2509.06334,
  title  = {Optimal Average Disk-Inspection via Fermat's Principle},
  author = {Konstantinos Georgiou},
  journal= {arXiv preprint arXiv:2509.06334},
  year   = {2026}
}

Comments

29 pages, 7 figures

R2 v1 2026-07-01T05:25:38.078Z