Coloring Graphs with Constraints on Connectivity |
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| Authors: | Pierre Aboulker Nick Brettell Frédéric Havet Dániel Marx Nicolas Trotignon |
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| Affiliation: | 1. DEPARTAMENTO DE INGENIERíA MATEMáTICA, UNIVERSIDAD ANDRES BELLO, SANTIAGO, CHILE;2. CNRS, LIP, ENS DE LYON;3. PROJECT COATI,, I3S (CNRS, UNS) AND INRIA,, SOPHIA ANTIPOLIS, France;4. INSTITUTE FOR COMPUTER SCIENCE AND CONTROL,HUNGARIAN ACADEMY OF SCIENCES (MTA SZTAKI) |
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| Abstract: | A graph G has maximal local edge‐connectivity k if the maximum number of edge‐disjoint paths between every pair of distinct vertices x and y is at most k. We prove Brooks‐type theorems for k‐connected graphs with maximal local edge‐connectivity k, and for any graph with maximal local edge‐connectivity 3. We also consider several related graph classes defined by constraints on connectivity. In particular, we show that there is a polynomial‐time algorithm that, given a 3‐connected graph G with maximal local connectivity 3, outputs an optimal coloring for G. On the other hand, we prove, for  , that k‐colorability is NP‐complete when restricted to minimally k‐connected graphs, and 3‐colorability is NP‐complete when restricted to  ‐connected graphs with maximal local connectivity k. Finally, we consider a parameterization of k‐colorability based on the number of vertices of degree at least  , and prove that, even when k is part of the input, the corresponding parameterized problem is FPT. |
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| Keywords: | coloring local connectivity local edge‐connectivity Brooks’ theorem minimally k‐connected vertex degree |
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, that k‐colorability is NP‐complete when restricted to minimally k‐connected graphs, and 3‐colorability is NP‐complete when restricted to 
‐connected graphs with maximal local connectivity k. Finally, we consider a parameterization of k‐colorability based on the number of vertices of degree at least 
, and prove that, even when k is part of the input, the corresponding parameterized problem is FPT.