Paper detail

Parameterized and Exact Algorithms for Class Domination Coloring

A class domination coloring (also called cd-Coloring or dominated coloring) of a graph is a proper coloring in which every color class is contained in the neighbourhood of some vertex. The minimum number of colors required for any cd-coloring of $G$, denoted by $χ_{cd}(G)$, is called the class domination chromatic number (cd-chromatic number) of $G$. In this work, we consider two problems associated with the cd-coloring of a graph in the context of exact exponential-time algorithms and parameterized complexity. (1) Given a graph $G$ on $n$ vertices, find its cd-chromatic number. (2) Given a graph $G$ and integers $k$ and $q$, can we delete at most $k$ vertices such that the cd-chromatic number of the resulting graph is at most $q$? For the first problem, we give an exact algorithm with running time $\Oh(2^n n^4 \log n)$. Also, we show that the problem is \FPT\ with respect to the number $q$ of colors as the parameter on chordal graphs. On graphs of girth at least 5, we show that the problem also admits a kernel with $\Oh(q^3)$ vertices. For the second (deletion) problem, we show \NP-hardness for each $q \geq 2$. Further, on split graphs, we show that the problem is \NP-hard if $q$ is a part of the input and \FPT\ with respect to $k$ and $q$ as combined parameters. As recognizing graphs with cd-chromatic number at most $q$ is \NP-hard in general for $q \geq 4$, the deletion problem is unlikely to be \FPT\ when parameterized by the size of the deletion set on general graphs. We show fixed parameter tractability for $q \in \{2,3\}$ using the known algorithms for finding a vertex cover and an odd cycle transversal as subroutines.