English

Min-Sum Uniform Coverage Problem by Autonomous Mobile Robots

Distributed, Parallel, and Cluster Computing 2026-02-12 v1 Robotics

Abstract

We study the \textit{min-sum uniform coverage} problem for a swarm of nn mobile robots on a given finite line segment and on a circle having finite positive radius, where the circle is given as an input. The robots must coordinate their movements to reach a uniformly spaced configuration that minimizes the total distance traveled by all robots. The robots are autonomous, anonymous, identical, and homogeneous, and operate under the \textit{Look-Compute-Move} (LCM) model with \textit{non-rigid} motion controlled by a fair asynchronous scheduler. They are oblivious and silent, possessing neither persistent memory nor a means of explicit communication. In the \textbf{line-segment setting}, the \textit{min-sum uniform coverage} problem requires placing the robots at uniformly spaced points along the segment so as to minimize the total distance traveled by all robots. In the \textbf{circle setting} for this problem, the robots have to arrange themselves uniformly around the given circle to form a regular nn-gon. There is no fixed orientation or designated starting vertex, and the goal is to minimize the total distance traveled by all the robots. We present a deterministic distributed algorithm that achieves uniform coverage in the line-segment setting with minimum total movement cost. For the circle setting, we characterize all initial configurations for which the \textit{min-sum uniform coverage} problem is deterministically unsolvable under the considered robot model. For all the other remaining configurations, we provide a deterministic distributed algorithm that achieves uniform coverage while minimizing the total distance traveled. These results characterize the deterministic solvability of min-sum coverage for oblivious robots and achieve optimal cost whenever solvable.

Keywords

Cite

@article{arxiv.2602.11125,
  title  = {Min-Sum Uniform Coverage Problem by Autonomous Mobile Robots},
  author = {Animesh Maiti and Abhinav Chakraborty and Bibhuti Das and Subhash Bhagat and Krishnendu Mukhopadhyaya},
  journal= {arXiv preprint arXiv:2602.11125},
  year   = {2026}
}
R2 v1 2026-07-01T10:32:19.610Z