Long cycles, heavy cycles and cycle decompositions in digraphs
Copyright policy )Long cycles, heavy cycles and cycle decompositions in digraphs
Haj��s conjectured in 1968 that every Eulerian \(n\)-vertex graph can be decomposed into at most $\lfloor (n-1)/2\rfloor$ edge-disjoint cycles. This has been confirmed for some special graph classes, but the general case remains open. In a sequence of papers by Bienia and Meyniel (1986), Dean (1986), and Bollob��s and Scott (1996) it was analogously conjectured that every \emph{directed} Eulerian graph can be decomposed into $O(n)$ cycles. In this paper, we show that every directed Eulerian graph can be decomposed into $O(n \log ��)$ disjoint cycles, thus making progress towards the conjecture by Bollob��s and Scott. Our approach is based on finding heavy cycles in certain edge-weightings of directed graphs. As a further consequence of our techniques, we prove that for every edge-weighted digraph in which every vertex has out-weight at least $1$, there exists a cycle with weight at least $��(\log \log n/{\log n})$, thus resolving a question by Bollob��s and Scott.
- ETH Zurich Switzerland
Distance in graphs, Probability (math.PR), Directed graphs (digraphs), tournaments, decomposition of digraphs, random walk, long cycles, Random walks on graphs, Hajós' conjecture, Edge subsets with special properties (factorization, matching, partitioning, covering and packing, etc.), FOS: Mathematics, Mathematics - Combinatorics, cycle decomposition, Combinatorics (math.CO), Paths and cycles, Mathematics - Probability
Distance in graphs, Probability (math.PR), Directed graphs (digraphs), tournaments, decomposition of digraphs, random walk, long cycles, Random walks on graphs, Hajós' conjecture, Edge subsets with special properties (factorization, matching, partitioning, covering and packing, etc.), FOS: Mathematics, Mathematics - Combinatorics, cycle decomposition, Combinatorics (math.CO), Paths and cycles, Mathematics - Probability
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