Connected Partitions via Connected Dominating Sets
Abstract
The classical theorem due to Gy\H{o}ri and Lov\'{a}sz states that any -connected graph admits a partition into connected subgraphs, where each subgraph has a prescribed size and contains a prescribed vertex, as long as the total size of target subgraphs is equal to the size of . However, this result is notoriously evasive in terms of efficient constructions, and it is still unknown whether such a partition can be computed in polynomial time, even for . We make progress towards an efficient constructive version of the Gy\H{o}ri--Lov\'{a}sz theorem by considering a natural strengthening of the -connectivity requirement. Specifically, we show that the desired connected partition can be found in polynomial time, if contains disjoint connected dominating sets. As a consequence of this result, we give several efficient approximate and exact constructive versions of the original Gy\H{o}ri--Lov\'{a}sz theorem: 1. On general graphs, a Gy\H{o}ri--Lov\'{a}sz partition with parts can be computed in polynomial time when the input graph has connectivity ; 2. On convex bipartite graphs, connectivity of is sufficient; 3. On biconvex graphs and interval graphs, connectivity of is sufficient, meaning that our algorithm gives a ``true'' constructive version of the theorem on these graph classes.
Cite
@article{arxiv.2503.13112,
title = {Connected Partitions via Connected Dominating Sets},
author = {Aikaterini Niklanovits and Kirill Simonov and Shaily Verma and Ziena Zeif},
journal= {arXiv preprint arXiv:2503.13112},
year = {2025}
}