English

Bound on shortest cycle covers

Combinatorics 2025-01-07 v2

Abstract

Assume GG is a bridgeless graph. A cycle cover of GG is a collection of cycles of GG such that each edge of GG is contained in at least one of the cycles. The length of a cycle cover of GG is the sum of the lengths of the cycles in the cover. The minimum length of a cycle cover of GG is denoted by cc(G)cc(G). It was proved independently by Alon and Tarsi and by Bermond, Jackson, and Jaeger that cc(G)53mcc(G)\le \frac{5}{3}m for every bridgeless graph GG with mm edges. This remained the best-known upper bound for cc(G)cc(G) for 40 years. In this paper, we prove that if GG is a bridgeless graph with mm edges and n2n_2 vertices of degree 22, then cc(G)<2918m+118n2cc(G) < \frac{29}{18}m+ \frac 1{18}n_2. As a consequence, we show that cc(G)53m142logmcc(G) \le \frac 53 m - \frac 1{42} \log m. The upper bound cc(G)<2918m1.6111m cc(G) < \frac{29}{18}m \approx 1.6111 m for bridgeless graphs GG of minimum degree at least 3 improves the previous known upper bound 1.6258m1.6258m. A key lemma used in the proof confirms Fan's conjecture that if CC is a circuit of GG and G/CG/C admits a nowhere zero 4-flow, then GG admits a 4-flow ff such that E(G)E(C)supp(f)E(G)-E(C)\subseteq \text{supp} (f) and supp(f)E(C)>34E(C)|\textrm{supp}(f)\cap E(C)|>\frac{3}{4}|E(C)|.

Keywords

Cite

@article{arxiv.2412.20874,
  title  = {Bound on shortest cycle covers},
  author = {Deping Song and Xuding Zhu},
  journal= {arXiv preprint arXiv:2412.20874},
  year   = {2025}
}

Comments

7 pages, no figure

R2 v1 2026-06-28T20:51:58.961Z