English

Connected Partitions via Connected Dominating Sets

Combinatorics 2025-05-16 v2 Data Structures and Algorithms

Abstract

The classical theorem due to Gy\H{o}ri and Lov\'{a}sz states that any kk-connected graph GG admits a partition into kk 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 GG. 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 k=5k = 5. 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 kk-connectivity requirement. Specifically, we show that the desired connected partition can be found in polynomial time, if GG contains kk 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 kk parts can be computed in polynomial time when the input graph has connectivity Ω(klog2n)\Omega(k \cdot \log^2 n); 2. On convex bipartite graphs, connectivity of 4k4k is sufficient; 3. On biconvex graphs and interval graphs, connectivity of kk is sufficient, meaning that our algorithm gives a ``true'' constructive version of the theorem on these graph classes.

Keywords

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}
}
R2 v1 2026-06-28T22:23:30.350Z