Abstract
In this paper, motivated by applications of vertex connectivity of digraphs or graphs, we consider the cycle-connected mixed graph (CCMG, for short) problem, which is in essence different from the connected mixed graph (CMG, for short) problem, and it is modelled as follows. Given a mixed graph \(G=(V,A\cup E)\), for each pair \( \{u, v\}\) of two distinct vertices in G, we are asked to determine whether there exists a mixed cycle C in G to contain such two vertices u and v, where C passes through its arc (x, y) along the direction only from x to y and its edge xy along one direction either from x to y or from y to x. Particularly, when the CCMG problem is specialized to either digraphs or graphs, we refer to the related version of the CCMG problem as either the cycle-connected digraph (CCD, for short) problem or the cycle-connected graph (CCG, for short) problem, respectively, where such a graph in the CCG problem is called as a cycle-connected graph. Similarly, we consider the weakly cycle-connected (in other words, circuit-connected) mixed graph (WCCMG, for short) problem, only substituting a mixed circuit for a mixed cycle in the CCMG problem. Moreover, given a graph \(G=(V,E)\), we define the cycle-connectivity \(\kappa _c(G)\) of G to be the smallest number of vertices (in G) whose deletion causes the reduced subgraph either not to be a cycle-connected graph or to become an isolated vertex; Furthermore, for each pair \(\{s, t\}\) of two distinct vertices in G, we denote by \(\kappa _{sc}(s,t)\) the maximum number of internally vertex-disjoint cycles in G to only contain such two vertices s and t in common, then we define the strong cycle-connectivity \(\kappa _{sc}(G)\) of G to be the smallest of these numbers \(\kappa _{sc}(s,t)\) among all pairs \(\{s, t\}\) of distinct vertices in G. We obtain the following three results. (1) Using a transformation from the directed 2-linkage problem, which is NP-complete, to the CCD problem, we prove that the CCD problem is NP-complete, implying that the CCMG problem still remains NP-complete, and however, we design a combinatorial algorithm in time \(O(n^2m)\) to solve the CCG problem, where n is the number of vertices and m is the number of edges of a graph \(G=(V,E)\); (2) We provide a combinatorial algorithm in time O(m) to solve the WCCMG problem, where m is the number of edges of a mixed graph \(G=(V,A\cup E)\); (3) Given a graph \(G=(V,E)\), we present twin combinatorial algorithms to compute cycle-connectivity \(\kappa _c(G)\) and strong cycle-connectivity \(\kappa _{sc}(G)\), respectively.
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Acknowledgements
The author is indeed grateful to the reviewers for their insightful comments and for their suggested changes that improve the presentation greatly.
Funding
This paper is fully supported by the National Natural Science Foundation of China [Nos.11861075, 12101593] and Fundamental Research Funds for the Central Universities [No.buctrc202219].
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Lichen, J. Cycle-connected mixed graphs and related problems. J Comb Optim 45, 53 (2023). https://doi.org/10.1007/s10878-022-00979-3
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DOI: https://doi.org/10.1007/s10878-022-00979-3