Vertex-disjoint directed and undirected cycles in general digraphs

Bang‐Jensen, Jørgen; Kriesell, Matthias; Maddaloni, Alessandro; Simonsen, Sven

doi:10.1016/j.jctb.2013.10.005

Cited by 9 publications

(14 citation statements)

References 9 publications

(22 reference statements)

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“…As an example, in [2,3] the problem of deciding for a digraph D the existence of a directed cycle C in D and a cycle C ′ in U G(D) which are vertex disjoint was studied. It was shown that this problem is polynomially decidable for the class of digraphs with a bounded number of cycle transversals of size 1 (vertices whose removal eliminates all directed cycles) and N P-complete if we allow arbitrarily many transversal vertices.…”

Section: Problem 13 Semi-directed 2-factors Of Bipartite Digraphsmentioning

confidence: 99%

“…It follows from (B.2) and (B.3) that B 3 = B ′′ [W \ {w 1 , w 2 } ∪ V 2 \ X] and B 4 = B ′′ [V 1 \ W ∪ X \ {x 1 , x 2 }] are balanced bipartite graphs with parts of size n/2 − 1 where each vertex has degree at least n/2 − 2. Hence, B 3 has a perfect matchingM 3 and B 4 has a perfect matchingM 4 . ThenM 3 ∪M 4 ∪ {x 1 w 1 , x 2 w 2 } is a perfect matching in B ′′ , contradicting that Problem 1.2 has a negative answer.…”

Section: A Polynomial Instance Of Problem 12mentioning

confidence: 99%

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Restricted cycle factors and arc-decompositions of digraphs

Bang‐Jensen

Casselgren

2015

Discrete Applied Mathematics

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Abstract. We study the complexity of finding 2-factors with various restrictions as well as edge-decompositions in (the underlying graphs of) digraphs. In particular we show that it is N P-complete to decide whether the underlying undirected graph of a digraph D has a 2-factor with cycles C 1 , C 2 , . . . , C k such that at least one of the cycles C i is a directed cycle in D (while the others may violate the orientation back in D). This solves an open problem from [J. Bang-Jensen et al., Vertex-disjoint directed and undirected cycles in general digraphs, JCT B 106 (2014), 1-14]. Our other main result is that it is also N P-complete to decide whether a 2-edge-coloured bipartite graph has two edge-disjoint perfect matchings such that one of these is monochromatic (while the other does not have to be). We also study the complexity of a number of related problems. In particular we prove that for every even k ≥ 2, the problem of deciding whether a bipartite digraph of girth k has a k-cycle-free cycle factor is N P-complete. Some of our reductions are based on connections to Latin squares and so-called avoidable arrays.

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Section: Problem 13 Semi-directed 2-factors Of Bipartite Digraphsmentioning

confidence: 99%

Section: A Polynomial Instance Of Problem 12mentioning

confidence: 99%

Restricted cycle factors and arc-decompositions of digraphs

Bang‐Jensen

Casselgren

2015

Discrete Applied Mathematics

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“…Since a digraph with at least two nontrivial strong components of size greater than one has two disjoint dicycles and the dicyle transversal number of any digraph D is the sum of the dicycle transversal numbers of its strong components, we may assume that D has precisely one nontrivial strong component

D^{'}

that is a no‐instance of Problem and since every digraph D with

τ (D) \geq 3

is a yes‐instance of Problem and hence also of Problem we can assume that

τ (D^{'}) \in {1, 2}

.…”

Section: The Case Of Nonstrong Digraphsmentioning

confidence: 99%

“…In we completely characterized the complexity of the following problem that can be seen as lying in‐between the two problems of two disjoint cycles in a graph and two disjoint dicycles in a digraph. Problem Given a digraph D , decide if there is a dicycle B in D and a cycle C in

UG (D)

with

V (B) \cap V (C) = \emptyset

.…”

Section: Introductionmentioning

confidence: 99%

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Arc‐Disjoint Directed and Undirected Cycles in Digraphs

Bang‐Jensen

Kriesell

Maddaloni

et al. 2015

Journal of Graph Theory

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The dicycle transversal number τ(D) of a digraph D is the minimum size of a dicycle transversal of D, that is a set of vertices of D, whose removal from D makes it acyclic. An arc a of a digraph D with at least one cycle is a transversal arc if a is in every directed cycle of D (making D−a acyclic). In [3] and [4], we completely characterized the complexity of following problem: Given a digraph D, decide if there is a dicycle B in D and a cycle C in its underlying undirected graph UG(D) such that V(B)∩V(C)=∅. It turns out that the problem is polynomially solvable for digraphs with a constantly bounded number of transversal vertices (including cases where τ(D)≥2). In the remaining case (allowing arbitrarily many transversal vertices) the problem is NP‐complete. In this article, we classify the complexity of the arc‐analog of this problem, where we ask for a dicycle B and a cycle C that are arc‐disjoint, but not necessarily vertex‐disjoint. We prove that the problem is polynomially solvable for strong digraphs and for digraphs with a constantly bounded number of transversal arcs (but possibly an unbounded number of transversal vertices). In the remaining case (allowing arbitrarily many transversal arcs) the problem is NP‐complete.

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Vertex-disjoint directed and undirected cycles in general digraphs

Bang‐Jensen¹,

Kriesell

Maddaloni

et al. 2014

Journal of Combinatorial Theory, Series B

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6The dicycle transversal number τ (D) of a digraph D is the minimum 7 size of a dicycle transversal of D, i. e. a set T ⊆ V (D) such that D − T 8 is acyclic. We study the following problem: Given a digraph D, decide 9 if there is a dicycle B in D and a cycle C in its underlying undirected 10 graph UG(D) such that V (B) ∩ V (C) = ∅. It is known that there is a 11 polynomial time algorithm for this problem when restricted to strongly 12 connected graphs, which actually finds B, C if they exist. We generalize 13 this to any class of digraphs D with either τ (D) = 1 or τ (D) = 1 and 14 a bounded number of dicycle transversals, and show that the problem is 15 N P-complete for a special class of digraphs D with τ (D) = 1 and, hence, 16 in general. 17 All graphs and digraphs are supposed to be finite, and they may contain loops 22 or multiple arcs or edges. Notation follows [1], and we recall the most relevant 23 concepts here. In order to distinguish between directed cycles in a digraph D 24 and cycles in its underlying graph UG(D) we use the name dicycle for a directed 25 cycle in D and cycle for a cycle in UG(D). Whenever we consider a (directed) 26 path P containing vertices a, b such that a precedes b on P , we denote by 27 P [a, b] the subpath of P which starts in a and ends in b. Similarly, we denote by 28 P (a, b], P [a, b), and P (a, b), respectively, the subpath that starts in the successor 29 of a on P and ends in b, starts in a and ends in the predecessor of b, and starts 30 in the successor of a on P and ends in the predecessor of b, respectively. The 31 same notation applies to dicycles. 32 arXiv:1106.5885v1 [math.CO]An in-tree (out-tree) rooted at a vertex r in a digraph D is a tree in UG(D) 1 whose arcs are oriented towards (away from) the root in D. 2A digraph D is acyclic if it does not contain a dicycle, and it is intercyclic if 3 it does not contain two disjoint dicycles. A dicycle transversal of D is a set S 4 of vertices of D such that D − S is acyclic, and the dicycle transversal number 5 τ (D) is defined to be the size of a smallest dicycle transversal. McCuaig 6 characterized the intercyclic digraphs of minimal in-and out-degree at least 2 7 in terms of their dicycle transversal number and designed a polynomial time 8 algorithm that, for any digraph, either finds two disjoint cycles or a structural 9 certificate for being intercyclic [7]. 10Theorem 1 [7] There exists a polynomial time algorithm which decides whether 11 a given digraph is intercyclic and finds two disjoint cycles if it is not. 12The undirected graphs without two disjoint cycles have been characterized by 13 Lovász [6], generalizing earlier statements of Dirac for the 3-connected case 14 [4]. The characterization again implies a polynomial algorithm for finding such 15 cycles if they exists.16Here we are concerned with the following problem. 17 Problem 1 Given a digraph D, decide if there is a dicycle B in D and a cycle 18 C in UG(D) with V (B) ∩ V (C) = ∅. 19 The motivation for studying this problem comes from [2] where ...

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Vertex-disjoint directed and undirected cycles in general digraphs

Cited by 9 publications

References 9 publications

Restricted cycle factors and arc-decompositions of digraphs

Restricted cycle factors and arc-decompositions of digraphs

Arc‐Disjoint Directed and Undirected Cycles in Digraphs

Vertex-disjoint directed and undirected cycles in general digraphs

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