A Multiscale Analysis of Multi-Agent Coverage Control Algorithms
Abstract
This paper presents a theoretical framework for the design and analysis of gradient descent-based algorithms for coverage control tasks involving robot swarms. We adopt a multiscale approach to analysis and design to ensure consistency of the algorithms in the large-scale limit. First, we represent the macroscopic configuration of the swarm as a probability measure and formulate the macroscopic coverage task as the minimization of a convex objective function over probability measures. We then construct a macroscopic dynamics for swarm coverage, which takes the form of a proximal descent scheme in the -Wasserstein space. Our analysis exploits the generalized geodesic convexity of the coverage objective function, proving convergence in the -Wasserstein sense to the target probability measure. We then obtain a consistent gradient descent algorithm in the Euclidean space that is implementable by a finite collection of agents, via a "variational" discretization of the macroscopic coverage objective function. We establish the convergence properties of the gradient descent and its behavior in the continuous-time and large-scale limits. Furthermore, we establish a connection with well-known Lloyd-based algorithms, seen as a particular class of algorithms within our framework, and demonstrate our results via numerical experiments.
Cite
@article{arxiv.2102.11411,
title = {A Multiscale Analysis of Multi-Agent Coverage Control Algorithms},
author = {Vishaal Krishnan and Sonia Martínez},
journal= {arXiv preprint arXiv:2102.11411},
year = {2022}
}
Comments
26 pages, 3 figures, 1 table