Your search keyword '"BASTE, JULIEN"' showing total 2 results

1. HITTING MINORS ON BOUNDED TREEWIDTH GRAPHS. IV. AN OPTIMAL ALGORITHM.

Author

BASTE, JULIEN, SAU, IGNASI, and THILIKOS, DIMITRIOS M.

Subjects

*INTERSECTION graph theory, *MINORS, *DYNAMIC programming, *ALGORITHMS, *GRAPH connectivity

Abstract

For a fixed finite collection of graphs F, the F-M-DELETION problem is as follows: given an n-vertex input graph G, find the minimum number of vertices that intersect all minor models in G of the graphs in F. by Courcelle's Theorem, this problem can be solved in time fF(tw) - n°(1), where tw is the treewidth of G for some function ƒ depending on F. In a recent series of articles, we have initiated the program of optimizing asymptotically the function ff. Here we provide an algorithm showing that fF(tw) = 2° (tw.log tw) for every collection F. Prior to this work, the best known function ƒ was double- exponential in tw. In particular, our algorithm vastly extends the results of Jansen, Lokshtanov, and Saurabh [Proc. of the 25th Annual ACM-SIAM Symposium on Discrete Algorithms (SODA), SIAM, 2014, pp. 1802-1811] for the particular case F = {K5, K3,3} and of Kociumaka and Pilipczuk [Algorithmica, 81 (2019), pp. 3655-3691] for graphs of bounded genus, and answers an open problem posed by Cygan et al. [Inform. Comput., 256 (2017), pp. 62-82]. We combine several ingredients such as the machinery of boundaried graphs in dynamic programming via representatives, the Flat Wall Theorem, bidimensionality, the irrelevant vertex technique, treewidth modulators, and protrusion replacement. Together with our previous results providing single-exponential algorithms for particular collections F [J. Baste, I. Sau, and D. M. Thilikos, Theoret. Comput. Sci., 814 (2020), pp. 135-152] and general lower bounds [J. Baste, I. Sau, and D. M. Thilikos, J. Comput. Syst. Sci., 109 (2020), pp. 56-77], our algorithm yields the following complexity dichotomy when F = {H} contains a single connected graph H, assuming the Exponential Time Hypothesis: ƒH(tw) = 2Θ(tw) if H is a contraction of the chair or the banner, and fH(tw) = 2Θ(tw-log tw) otherwise. [ABSTRACT FROM AUTHOR]

Published

2023

2. HITTING MINORS ON BOUNDED TREEWIDTH GRAPHS. I. GENERAL UPPER BOUNDS.

Author

BASTE, JULIEN, SAU, IGNASI, and THILIKOS, DIMITRIOS M.

Subjects

*MINORS

Abstract

For a finite collection of graphs F, the F-M-DELETION problem consists in, given a graph G and an integer k, deciding whether there exists S ⊆ V (G) with |S| ≤ k such that G\S does not contain any of the graphs in F as a minor. We are interested in the parameterized complexity of F-M-Deletion when the parameter is the treewidth of G, denoted by tw. Our objective is to determine, for a fixed F, the smallest function fF such that F-M-DELETION can be solved in time fF(tw) . nO(1) on n-vertex graphs. We prove that fF(tw) = 2²O(tw.logtw) for every collection F, that fF(tw) = 2O(tw.log tw) if F contains a planar graph, and that fF(tw) = 2O(tw) if in addition the input graph G is planar or embedded in a surface. We also consider the version of the problem where the graphs in F are forbidden as topological minors, called F-TM-Deletion. We prove similar results for this problem, except that in the last two algorithms, instead of requiring F to contain a planar graph, we need it to contain a subcubic planar graph. This is the first of a series of articles on this topic. [ABSTRACT FROM AUTHOR]

Published

2020