Min-Sum Uniform Coverage Problem by Autonomous Mobile Robots

Abstract

We study the min-sum uniform coverage problem for a swarm of n 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 Look-Compute-Move (LCM) model with 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 line-segment setting, the 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 circle setting for this problem, the robots have to arrange themselves uniformly around the given circle to form a regular n-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 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.