An Erdős-Pósa theorem for cycles and faces of distinct lengths
Abstract
We show that for every k ∈ N, every graph G contains k vertex-disjoint cycles of different lengths, or there exists a set X ⊂eq V(G) with |X| ∈ O(k6polylog(k)) such that G-X has at most k-1 cycle lengths. We also prove analogous results for facial lengths of embedded graphs. Let G be a graph with a closed 2-cell embedding ψ on a surface Σ of Euler genus g, let c be a colouring of the faces F(ψ) of ψ, and let R(G,ψ) be the radial graph of (G, ψ). Then there exist k faces F1, … , Fk ∈ F(ψ) that are given pairwise distinct colours by c and are pairwise at distance at least d in ψ, or there exists a set X ⊂eq V(G) of order at most O(k2dg) such that |\ c(F) F ∈ F(ψ) and V(F) x ∈ X NdR(G,ψ)(x) = \| ≤ k(k+2). Finally, using a result from additive combinatorics, we show that there are subdivided ladders with only a small number of cycle lengths. This suggests that it may be difficult to improve our bounds.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.