English

Makespan Trade-offs for Visiting Triangle Edges

Discrete Mathematics 2025-02-19 v3

Abstract

We study a primitive vehicle routing-type problem in which a fleet of nnunit speed robots start from a point within a non-obtuse triangle Δ\Delta, where n{1,2,3}n \in \{1,2,3\}. The goal is to design robots' trajectories so as to visit all edges of the triangle with the smallest visitation time makespan. We begin our study by introducing a framework for subdividing Δ\Deltainto regions with respect to the type of optimal trajectory that each point PP admits, pertaining to the order that edges are visited and to how the cost of the minimum makespan Rn(P)R_n(P) is determined, for n{1,2,3}n\in \{1,2,3\}. These subdivisions are the starting points for our main result, which is to study makespan trade-offs with respect to the size of the fleet. In particular, we define Rn,m(Δ)=maxPΔRn(P)/Rm(P) R_{n,m} (\Delta)= \max_{P \in \Delta} R_n(P)/R_m(P), and we prove that, over all non-obtuse triangles Δ\Delta: (i) R1,3(Δ)R_{1,3}(\Delta) ranges from 10\sqrt{10} to 44, (ii) R2,3(Δ)R_{2,3}(\Delta) ranges from 2\sqrt{2} to 22, and (iii) R1,2(Δ)R_{1,2}(\Delta) ranges from 5/25/2 to 33. In every case, we pinpoint the starting points within every triangle Δ\Delta that maximize Rn,m(Δ)R_{n,m} (\Delta), as well as we identify the triangles that determine all infΔRn,m(Δ)\inf_\Delta R_{n,m}(\Delta) and supΔRn,m(Δ)\sup_\Delta R_{n,m}(\Delta) over the set of non-obtuse triangles.

Cite

@article{arxiv.2105.01191,
  title  = {Makespan Trade-offs for Visiting Triangle Edges},
  author = {Konstantinos Georgiou and Somnath Kundu and Pawel Pralat},
  journal= {arXiv preprint arXiv:2105.01191},
  year   = {2025}
}

Comments

47 pages, 27 figures

R2 v1 2026-06-24T01:45:01.235Z