Cycles of Well-Linked Sets I: an Elementary Bound for Directed Cycle Packing

TL;DR

This paper establishes an elementary upper bound for the feedback vertex set size in directed graphs lacking k disjoint cycles, using novel concepts inspired by undirected graph theory, with potential broader applications.

Contribution

It introduces the concept of paths of well-linked sets and proves a large PWS contains a large fence, providing the first elementary bound for directed cycle packing.

Findings

Bound for feedback vertex set is a tower of height 8.

Large directed treewidth implies existence of large PWS.

Framework may improve bounds in the Directed Grid Theorem.

Abstract

In 1996, Reed, Robertson, Seymour and Thomas [Combinatorica 1996] proved Younger's Conjecture, which states that, for all directed graphs $D$, there exists a function $f$ such that, if $D$ does not contain $k$ disjoint cycles, then $D$ contains a feedback vertex set, i.e.~a subset of vertices whose deletion renders the graph acyclic, of size bounded by $f(k)$. However, the function obtained by Reed, Robertson, Seymour and Thomas in their paper is enormous and, in fact, not even elementary. We prove the first elementary upper bound for the function $f$ above, showing it is upper-bounded by a power tower of height 8. Our proof is inspired by the breakthrough result of Chekuri and Chuzhoy [J. ACM 2016], who proved a polynomial bound for the Excluded Grid Theorem for undirected graphs. We translate a key concept of their proof to directed graphs by introducing paths of well-linked sets (PWS), and show that any digraph of large directed treewidth contains a large PWS, which in turn contains a large fence. We believe that the theoretical tools developed in this work may find applications beyond the results above, in a similar way as the path-of-sets-system framework due to Chekuri and Chuzhoy [J. ACM 2016] did for undirected graphs (see, for example, Hatzel, Komosa, Pilipczuk and Sorge [Discret. Math. Theor. Comput. Sci. 2022], Chekuri and Chuzhoy [SODA 2015] and Chuzhoy and Nimavat [arXiv 2019]). Indeed, in a follow-up paper, we apply this framework to improve the bounds of the Directed Grid Theorem.