TY - GEN
T1 - Parameterized complexity of conflict-free graph coloring
AU - Bodlaender, Hans L.
AU - Kolay, Sudeshna
AU - Pieterse, Astrid
PY - 2019/1/1
Y1 - 2019/1/1
N2 - Given a graph G, a q-open neighborhood conflict-free coloring or q-ONCF-coloring is a vertex coloring c: V(G) → { 1, 2, …, q} such that for each vertex v∈ V(G) there is a vertex in N(v) that is uniquely colored from the rest of the vertices in N(v). When we replace N(v) by the closed neighborhood N[v], then we call such a coloring a q-closed neighborhood conflict-free coloring or simply q-CNCF-coloring. In this paper, we study the NP-hard decision questions of whether for a constant q an input graph has a q-ONCF-coloring or a q-CNCF-coloring. We will study these two problems in the parameterized setting. First of all, we study running time bounds on FPT-algorithms for these problems, when parameterized by treewidth. We improve the existing upper bounds, and also provide lower bounds on the running time under ETH and SETH. Secondly, we study the kernelization complexity of both problems, using vertex cover as the parameter. We show that both (q≥ 2) -ONCF-coloring and (q≥ 3) -CNCF-coloring cannot have polynomial kernels when parameterized by the size of a vertex cover unless NP⊆ coNP/poly. On the other hand, we obtain a polynomial kernel for 2-CNCF-coloring parameterized by vertex cover. We conclude the study with some combinatorial results. Denote χON(G) and χCN(G) to be the minimum number of colors required to ONCF-color and CNCF-color G, respectively. Upper bounds on χCN(G) with respect to structural parameters like minimum vertex cover size, minimum feedback vertex set size and treewidth are known. To the best of our knowledge only an upper bound on χON(G) with respect to minimum vertex cover size was known. We provide tight bounds for χON(G) with respect to minimum vertex cover size. Also, we provide the first upper bounds on χON(G) with respect to minimum feedback vertex set size and treewidth.
AB - Given a graph G, a q-open neighborhood conflict-free coloring or q-ONCF-coloring is a vertex coloring c: V(G) → { 1, 2, …, q} such that for each vertex v∈ V(G) there is a vertex in N(v) that is uniquely colored from the rest of the vertices in N(v). When we replace N(v) by the closed neighborhood N[v], then we call such a coloring a q-closed neighborhood conflict-free coloring or simply q-CNCF-coloring. In this paper, we study the NP-hard decision questions of whether for a constant q an input graph has a q-ONCF-coloring or a q-CNCF-coloring. We will study these two problems in the parameterized setting. First of all, we study running time bounds on FPT-algorithms for these problems, when parameterized by treewidth. We improve the existing upper bounds, and also provide lower bounds on the running time under ETH and SETH. Secondly, we study the kernelization complexity of both problems, using vertex cover as the parameter. We show that both (q≥ 2) -ONCF-coloring and (q≥ 3) -CNCF-coloring cannot have polynomial kernels when parameterized by the size of a vertex cover unless NP⊆ coNP/poly. On the other hand, we obtain a polynomial kernel for 2-CNCF-coloring parameterized by vertex cover. We conclude the study with some combinatorial results. Denote χON(G) and χCN(G) to be the minimum number of colors required to ONCF-color and CNCF-color G, respectively. Upper bounds on χCN(G) with respect to structural parameters like minimum vertex cover size, minimum feedback vertex set size and treewidth are known. To the best of our knowledge only an upper bound on χON(G) with respect to minimum vertex cover size was known. We provide tight bounds for χON(G) with respect to minimum vertex cover size. Also, we provide the first upper bounds on χON(G) with respect to minimum feedback vertex set size and treewidth.
KW - Combinatorial bounds
KW - Conflict-free coloring
KW - Fixed-parameter tractability
KW - Kernelization
UR - http://www.scopus.com/inward/record.url?scp=85070641615&partnerID=8YFLogxK
U2 - 10.1007/978-3-030-24766-9_13
DO - 10.1007/978-3-030-24766-9_13
M3 - Conference contribution
AN - SCOPUS:85070641615
SN - 9783030247652
T3 - Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
SP - 168
EP - 180
BT - Algorithms and Data Structures - 16th International Symposium, WADS 2019, Proceedings
A2 - Friggstad, Zachary
A2 - Salavatipour, Mohammad R.
A2 - Sack, Jörg-Rüdiger
PB - Springer
T2 - 16th International Symposium on Algorithms and Data Structures, WADS 2019
Y2 - 5 August 2019 through 7 August 2019
ER -