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Main Authors: Bergougnoux, Benjamin, Chekan, Vera, Ganian, Robert, Kanté, Mamadou Moustapha, Mnich, Matthias, Oum, Sang-il, Pilipczuk, Michał, van Leeuwen, Erik Jan
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2307.01285
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author Bergougnoux, Benjamin
Chekan, Vera
Ganian, Robert
Kanté, Mamadou Moustapha
Mnich, Matthias
Oum, Sang-il
Pilipczuk, Michał
van Leeuwen, Erik Jan
author_facet Bergougnoux, Benjamin
Chekan, Vera
Ganian, Robert
Kanté, Mamadou Moustapha
Mnich, Matthias
Oum, Sang-il
Pilipczuk, Michał
van Leeuwen, Erik Jan
contents Dynamic programming on various graph decompositions is one of the most fundamental techniques used in parameterized complexity. Unfortunately, even if we consider concepts as simple as path or tree decompositions, such dynamic programming uses space that is exponential in the decomposition's width, and there are good reasons to believe that this is necessary. However, it has been shown that in graphs of low treedepth it is possible to design algorithms which achieve polynomial space complexity without requiring worse time complexity than their counterparts working on tree decompositions of bounded width. Here, treedepth is a graph parameter that, intuitively speaking, takes into account both the depth and the width of a tree decomposition of the graph, rather than the width alone. Motivated by the above, we consider graphs that admit clique expressions with bounded depth and label count, or equivalently, graphs of low shrubdepth (sd). Here, sd is a bounded-depth analogue of cliquewidth, in the same way as td is a bounded-depth analogue of treewidth. We show that also in this setting, bounding the depth of the decomposition is a deciding factor for improving the space complexity. Precisely, we prove that on $n$-vertex graphs equipped with a tree-model (a decomposition notion underlying sd) of depth $d$ and using $k$ labels, we can solve - Independent Set in time $2^{O(dk)}\cdot n^{O(1)}$ using $O(dk^2\log n)$ space; - Max Cut in time $n^{O(dk)}$ using $O(dk\log n)$ space; and - Dominating Set in time $2^{O(dk)}\cdot n^{O(1)}$ using $n^{O(1)}$ space via a randomized algorithm. We also establish a lower bound, conditional on a certain assumption about the complexity of Longest Common Subsequence, which shows that at least in the case of IS the exponent of the parametric factor in the time complexity has to grow with $d$ if one wishes to keep the space complexity polynomial.
format Preprint
id arxiv_https___arxiv_org_abs_2307_01285
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Space-Efficient Parameterized Algorithms on Graphs of Low Shrubdepth
Bergougnoux, Benjamin
Chekan, Vera
Ganian, Robert
Kanté, Mamadou Moustapha
Mnich, Matthias
Oum, Sang-il
Pilipczuk, Michał
van Leeuwen, Erik Jan
Data Structures and Algorithms
Dynamic programming on various graph decompositions is one of the most fundamental techniques used in parameterized complexity. Unfortunately, even if we consider concepts as simple as path or tree decompositions, such dynamic programming uses space that is exponential in the decomposition's width, and there are good reasons to believe that this is necessary. However, it has been shown that in graphs of low treedepth it is possible to design algorithms which achieve polynomial space complexity without requiring worse time complexity than their counterparts working on tree decompositions of bounded width. Here, treedepth is a graph parameter that, intuitively speaking, takes into account both the depth and the width of a tree decomposition of the graph, rather than the width alone. Motivated by the above, we consider graphs that admit clique expressions with bounded depth and label count, or equivalently, graphs of low shrubdepth (sd). Here, sd is a bounded-depth analogue of cliquewidth, in the same way as td is a bounded-depth analogue of treewidth. We show that also in this setting, bounding the depth of the decomposition is a deciding factor for improving the space complexity. Precisely, we prove that on $n$-vertex graphs equipped with a tree-model (a decomposition notion underlying sd) of depth $d$ and using $k$ labels, we can solve - Independent Set in time $2^{O(dk)}\cdot n^{O(1)}$ using $O(dk^2\log n)$ space; - Max Cut in time $n^{O(dk)}$ using $O(dk\log n)$ space; and - Dominating Set in time $2^{O(dk)}\cdot n^{O(1)}$ using $n^{O(1)}$ space via a randomized algorithm. We also establish a lower bound, conditional on a certain assumption about the complexity of Longest Common Subsequence, which shows that at least in the case of IS the exponent of the parametric factor in the time complexity has to grow with $d$ if one wishes to keep the space complexity polynomial.
title Space-Efficient Parameterized Algorithms on Graphs of Low Shrubdepth
topic Data Structures and Algorithms
url https://arxiv.org/abs/2307.01285