Parameterized Algorithms on Perfect Graphs for deletion to $(r,\ell)$-graphs
Abstract
For fixed integers , a graph is called an {\em -graph} if the vertex set can be partitioned into independent sets and cliques. The class of graphs generalizes -colourable graphs (when and hence not surprisingly, determining whether a given graph is an -graph is \NP-hard even when or in general graphs. When and are part of the input, then the recognition problem is NP-hard even if the input graph is a perfect graph (where the {\sc Chromatic Number} problem is solvable in polynomial time). It is also known to be fixed-parameter tractable (FPT) on perfect graphs when parameterized by and . I.e. there is an algorithm on perfect graphs on vertices where is some (exponential) function of and . In this paper, we consider the parameterized complexity of the following problem, which we call {\sc Vertex Partization}. Given a perfect graph and positive integers decide whether there exists a set of size at most such that the deletion of from results in an -graph. We obtain the following results: \begin{enumerate} \item {\sc Vertex Partization} on perfect graphs is FPT when parameterized by . \item The problem does not admit any polynomial sized kernel when parameterized by . In other words, in polynomial time, the input graph can not be compressed to an equivalent instance of size polynomial in . In fact, our result holds even when . \item When are universal constants, then {\sc Vertex Partization} on perfect graphs, parameterized by , has a polynomial sized kernel. \end{enumerate}
Cite
@article{arxiv.1512.04200,
title = {Parameterized Algorithms on Perfect Graphs for deletion to $(r,\ell)$-graphs},
author = {Sudeshna Kolay and Fahad Panolan and Venkatesh Raman and Saket Saurabh},
journal= {arXiv preprint arXiv:1512.04200},
year = {2015}
}