Destroying Bicolored $P_3$s by Deleting Few Edges

January 11, 2019 Β· Declared Dead Β· πŸ› Conference on Computability in Europe

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Authors Niels GrΓΌttemeier, Christian Komusiewicz, Jannik Schestag, Frank Sommer arXiv ID 1901.03627 Category cs.DS: Data Structures & Algorithms Cross-listed cs.DM, math.CO Citations 3 Venue Conference on Computability in Europe Last Checked 4 months ago
Abstract
We introduce and study the Bicolored $P_3$ Deletion problem defined as follows. The input is a graph $G=(V,E)$ where the edge set $E$ is partitioned into a set $E_r$ of red edges and a set $E_b$ of blue edges. The question is whether we can delete at most $k$ edges such that $G$ does not contain a bicolored $P_3$ as an induced subgraph. Here, a bicolored $P_3$ is a path on three vertices with one blue and one red edge. We show that Bicolored $P_3$ Deletion is NP-hard and cannot be solved in $2^{o(|V|+|E|)}$ time on bounded-degree graphs if the ETH is true. Then, we show that Bicolored $P_3$ Deletion is polynomial-time solvable when $G$ does not contain a bicolored $K_3$, that is, a triangle with edges of both colors. Moreover, we provide a polynomial-time algorithm for the case that $G$ contains no blue $P_3$, red $P_3$, blue $K_3$, and red $K_3$. Finally, we show that Bicolored $P_3$ Deletion can be solved in $ O(1.84^k\cdot |V| \cdot |E|)$ time and that it admits a kernel with $ O(kΞ”\min(k,Ξ”))$ vertices, where $Ξ”$ is the maximum degree of $G$.
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