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52. The Role of Planarity in Connectivity Problems Parameterized by Treewidth

Author

Baste, Julien, Sau, Ignasi, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Cygan, Marek, editor, and Heggernes, Pinar, editor

Published
2014
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54. Non-monotone target sets for threshold values restricted to $0$, $1$, and the vertex degree

Author

Baste, Julien, Ehard, Stefan, Rautenbach, Dieter, Operational Research, Knowledge And Data (ORKAD), Centre de Recherche en Informatique, Signal et Automatique de Lille - UMR 9189 (CRIStAL), Centrale Lille-Université de Lille-Centre National de la Recherche Scientifique (CNRS)-Centrale Lille-Université de Lille-Centre National de la Recherche Scientifique (CNRS), and Universität Ulm - Ulm University [Ulm, Allemagne]

Subjects
FOS: Computer and information sciences, Discrete Mathematics (cs.DM), General Computer Science, [INFO.INFO-DS]Computer Science [cs]/Data Structures and Algorithms [cs.DS], FOS: Mathematics, Discrete Mathematics and Combinatorics, Mathematics - Combinatorics, Combinatorics (math.CO), Theoretical Computer Science, Computer Science - Discrete Mathematics
Abstract

International audience; We consider a non-monotone activation process $(X_t)_{t\in\{ 0,1,2,\ldots\}}$ on a graph $G$, where $X_0\subseteq V(G)$, $X_t=\{ u\in V(G):|N_G(u)\cap X_{t-1}|\geq \tau(u)\}$ for every positive integer $t$, and $\tau:V(G)\to \mathbb{Z}$ is a threshold function. The set $X_0$ is a so-called non-monotone target set for $(G,\tau)$ if there is some $t_0$ such that $X_t=V(G)$ for every $t\geq t_0$. Ben-Zwi, Hermelin, Lokshtanov, and Newman [Discrete Optimization 8 (2011) 87-96] asked whether a target set of minimum order can be determined efficiently if $G$ is a tree. We answer their question in the affirmative for threshold functions $\tau$ satisfying $\tau(u)\in \{ 0,1,d_G(u)\}$ for every vertex~$u$. For such restricted threshold functions, we give a characterization of target sets that allows to show that the minimum target set problem remains NP-hard for planar graphs of maximum degree $3$ but is efficiently solvable for graphs of bounded treewidth.

Published
2022
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58. γ-Cluster Edge Modification Problems

Author

Castillon, Antoine, Baste, Julien, Dhaenens, Clarisse, Haddad, Mohammed, Seba, Hamida, Operational Research, Knowledge And Data (ORKAD), Centre de Recherche en Informatique, Signal et Automatique de Lille - UMR 9189 (CRIStAL), Centrale Lille-Université de Lille-Centre National de la Recherche Scientifique (CNRS)-Centrale Lille-Université de Lille-Centre National de la Recherche Scientifique (CNRS), Graphes, AlgOrithmes et AppLications (GOAL), Laboratoire d'InfoRmatique en Image et Systèmes d'information (LIRIS), Université Lumière - Lyon 2 (UL2)-École Centrale de Lyon (ECL), Université de Lyon-Université de Lyon-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS)-Université Lumière - Lyon 2 (UL2)-École Centrale de Lyon (ECL), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS), and ANR-20-CE23-0002,COREGRAPHIE,COmpression de REseaux et de GRAPHes pour une Informatique Efficace(2020)

Subjects
[INFO.INFO-CC]Computer Science [cs]/Computational Complexity [cs.CC], [INFO.INFO-DS]Computer Science [cs]/Data Structures and Algorithms [cs.DS], [INFO.INFO-DM]Computer Science [cs]/Discrete Mathematics [cs.DM]
Abstract

International audience

Published
2022

66. Non-monotone target sets for threshold values restricted to 0, 1, and the vertex degree.

Author

Baste, Julien, Ehard, Stefan, and Rautenbach, Dieter

Subjects
*PLANAR graphs, *INTEGERS, *MATHEMATICAL models, *MATHEMATICAL analysis, *PROBLEM solving
Abstract

We consider a non-monotone activation process (Xt)t2{0,1,2,...} on a graph G, where X0 = V (G), Xt = {u 2 V (G): |NG(u) \ Xt-1| = = (u)} for every positive integer t, and =: V (G) ! Z is a threshold function. The set X0 is a so-called non-monotone target set for (G, ι) if there is some t0 such that Xt = V (G) for every t = t0. Ben-Zwi, Hermelin, Lokshtanov, and Newman [Discrete Optimization 8 (2011) 87-96] asked whether a target set of minimum order can be determined efficiently if G is a tree. We answer their question in the affirmative for threshold functions ι satisfying ι (u) 2 {0, 1, dG(u)} for every vertex u. For such restricted threshold functions, we give a characterization of target sets that allows to show that the minimum target set problem remains NP-hard for planar graphs of maximum degree 3 but is efficiently solvable for graphs of bounded treewidth. [ABSTRACT FROM AUTHOR]

Published
2022

68. A Complexity Dichotomy for Hitting Small Planar Minors Parameterized by Treewidth

Author

Baste, Julien, Sau, Ignasi, Thilikos, Dimitrios M., École normale supérieure - Cachan, antenne de Bretagne (ENS Cachan Bretagne), École normale supérieure - Cachan (ENS Cachan), Algorithmes, Graphes et Combinatoire (ALGCO), Laboratoire d'Informatique de Robotique et de Microélectronique de Montpellier (LIRMM), Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM), Christophe Paul, and Michal Pilipczuk

Subjects
000 Computer science, knowledge, general works, Treewidth, [INFO.INFO-DS]Computer Science [cs]/Data Structures and Algorithms [cs.DS], Graph minors, 0102 computer and information sciences, 02 engineering and technology, Topological minors, [INFO.INFO-DM]Computer Science [cs]/Discrete Mathematics [cs.DM], Dynamic programming, 01 natural sciences, Parameterized complexity, 010201 computation theory & mathematics, Hitting minors, Computer Science, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Exponential Time Hypothesis
Abstract

International audience; For a fixed graph H, we are interested in the parameterized complexity of the following problem, called {H}-M-Deletion, parameterized by the treewidth tw of the input graph: given an n-vertex graph G and an integer k, decide whether there exists S ⊆ V (G) with |S| ≤ k such that G\S does not contain H as a minor. In previous work [IPEC, 2017] we proved that if H is planar and connected, then the problem cannot be solved in time 2 o(tw) · n O(1) under the ETH, and can be solved in time 2 O(tw·log tw) · n O(1). In this article we manage to classify the optimal asymptotic complexity of {H}-M-Deletion when H is a connected planar graph on at most 5 vertices. Out of the 29 possibilities (discarding the trivial case H = K 1), we prove that 9 of them are solvable in time 2 Θ(tw) · n O(1) , and that the other 20 ones are solvable in time 2 Θ(tw·log tw) · n O(1). Namely, we prove that K 4 and the diamond are the only graphs on at most 4 vertices for which the problem is solvable in time 2 Θ(tw·log tw) · n O(1) , and that the chair and the banner are the only graphs on 5 vertices for which the problem is solvable in time 2 Θ(tw) · n O(1). For the version of the problem where H is forbidden as a topological minor, the case H = K 1,4 can be solved in time 2 Θ(tw) · n O(1). This exhibits, to the best of our knowledge, the first difference between the computational complexity of both problems. 2012 ACM Subject Classification Mathematics of computing → Graph algorithms, Theory of computation → Parameterized complexity and exact algorithms

Published
2018
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72. A Complexity Dichotomy for Hitting Small Planar Minors Parameterized by Treewidth

Author

Baste, Julien, Sau, Ignasi, Thilikos, Dimitrios M., Baste, Julien, Sau, Ignasi, and Thilikos, Dimitrios M.

Abstract

For a fixed graph H, we are interested in the parameterized complexity of the following problem, called {H}-M-Deletion, parameterized by the treewidth tw of the input graph: given an n-vertex graph G and an integer k, decide whether there exists S subseteq V(G) with |S| <= k such that G setminus S does not contain H as a minor. In previous work [IPEC, 2017] we proved that if H is planar and connected, then the problem cannot be solved in time 2^{o(tw)} * n^{O(1)} under the ETH, and can be solved in time 2^{O(tw * log tw)} * n^{O(1)}. In this article we manage to classify the optimal asymptotic complexity of {H}-M-Deletion when H is a connected planar graph on at most 5 vertices. Out of the 29 possibilities (discarding the trivial case H = K_1), we prove that 9 of them are solvable in time 2^{Theta (tw)} * n^{O(1)}, and that the other 20 ones are solvable in time 2^{Theta (tw * log tw)} * n^{O(1)}. Namely, we prove that K_4 and the diamond are the only graphs on at most 4 vertices for which the problem is solvable in time 2^{Theta (tw * log tw)} * n^{O(1)}, and that the chair and the banner are the only graphs on 5 vertices for which the problem is solvable in time 2^{Theta (tw)} * n^{O(1)}. For the version of the problem where H is forbidden as a topological minor, the case H = K_{1,4} can be solved in time 2^{Theta (tw)} * n^{O(1)}. This exhibits, to the best of our knowledge, the first difference between the computational complexity of both problems.

Published
2019
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73. A Complexity Dichotomy for Hitting Small Planar Minors Parameterized by Treewidth

Author

Julien Baste and Ignasi Sau and Dimitrios M. Thilikos, Baste, Julien, Sau, Ignasi, Thilikos, Dimitrios M., Julien Baste and Ignasi Sau and Dimitrios M. Thilikos, Baste, Julien, Sau, Ignasi, and Thilikos, Dimitrios M.

Abstract

For a fixed graph H, we are interested in the parameterized complexity of the following problem, called {H}-M-Deletion, parameterized by the treewidth tw of the input graph: given an n-vertex graph G and an integer k, decide whether there exists S subseteq V(G) with |S| <= k such that G setminus S does not contain H as a minor. In previous work [IPEC, 2017] we proved that if H is planar and connected, then the problem cannot be solved in time 2^{o(tw)} * n^{O(1)} under the ETH, and can be solved in time 2^{O(tw * log tw)} * n^{O(1)}. In this article we manage to classify the optimal asymptotic complexity of {H}-M-Deletion when H is a connected planar graph on at most 5 vertices. Out of the 29 possibilities (discarding the trivial case H = K_1), we prove that 9 of them are solvable in time 2^{Theta (tw)} * n^{O(1)}, and that the other 20 ones are solvable in time 2^{Theta (tw * log tw)} * n^{O(1)}. Namely, we prove that K_4 and the diamond are the only graphs on at most 4 vertices for which the problem is solvable in time 2^{Theta (tw * log tw)} * n^{O(1)}, and that the chair and the banner are the only graphs on 5 vertices for which the problem is solvable in time 2^{Theta (tw)} * n^{O(1)}. For the version of the problem where H is forbidden as a topological minor, the case H = K_{1,4} can be solved in time 2^{Theta (tw)} * n^{O(1)}. This exhibits, to the best of our knowledge, the first difference between the computational complexity of both problems.

Published
2019
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74. Contraction-Bidimensionality of Geometric Intersection Graphs

Author

Baste, Julien, Thilikos, Dimitrios M., Algorithmes, Graphes et Combinatoire (ALGCO), Laboratoire d'Informatique de Robotique et de Microélectronique de Montpellier (LIRMM), Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM), Department of Mathematics [Athens], National and Kapodistrian University of Athens (NKUA), and ANR-16-CE40-0028,DE-MO-GRAPH,Décomposition de Modèles Graphiques(2016)

Subjects
000 Computer science, knowledge, general works, Geometric intersection graphs, 010201 computation theory & mathematics, Bidimensionality, Computer Science, [INFO.INFO-DS]Computer Science [cs]/Data Structures and Algorithms [cs.DS], 0102 computer and information sciences, Grid exlusion theorem, [INFO.INFO-DM]Computer Science [cs]/Discrete Mathematics [cs.DM], 01 natural sciences, String Graphs
Abstract

International audience; Given a graph G, we define bcg(G) as the minimum k for which G can be contracted to the uniformly triangulated grid Γ k. A graph class G has the SQGC property if every graph G ∈ G has treewidth O(bcg(G) c) for some 1 ≤ c < 2. The SQGC property is important for algorithm design as it defines the applicability horizon of a series of meta-algorithmic results, in the framework of bidimensionality theory, related to fast parameterized algorithms, kernelization, and approximation schemes. These results apply to a wide family of problems, namely problems that are contraction-bidimensional. Our main combinatorial result reveals a general family of graph classes that satisfy the SQGC property and includes bounded-degree string graphs. This considerably extends the applicability of bidimensionality theory for several intersection graph classes of 2-dimensional geometrical objects.

Published
2017
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75. Optimal Algorithms for Hitting (Topological) Minors on Graphs of Bounded Treewidth

Author

Baste , Julien, Sau , Ignasi, Thilikos , Dimitrios M., Algorithmes, Graphes et Combinatoire ( ALGCO ), Laboratoire d'Informatique de Robotique et de Microélectronique de Montpellier ( LIRMM ), Université de Montpellier ( UM ) -Centre National de la Recherche Scientifique ( CNRS ) -Université de Montpellier ( UM ) -Centre National de la Recherche Scientifique ( CNRS ), ANR-16-CE40-0028,DEMOGRAPH,Décomposition de Modèles Graphiques ( 2016 ), Algorithmes, Graphes et Combinatoire (ALGCO), Laboratoire d'Informatique de Robotique et de Microélectronique de Montpellier (LIRMM), Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM), and ANR-16-CE40-0028,DE-MO-GRAPH,Décomposition de Modèles Graphiques(2016)

Subjects
[ MATH ] Mathematics [math], Parameterized complexity, 000 Computer science, knowledge, general works, [ INFO ] Computer Science [cs], Treewidth, Hitting minors, Computer Science, [INFO]Computer Science [cs], Graph minors, Topological minors, [MATH]Mathematics [math], Dynamic programming, Exponential Time Hypothesis
Abstract

International audience; For a fixed collection of graphs F, the F-M-DELETION problem consists in, given a graph G and an integer k, decide whether there exists a subset S of V(G) of size at most 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 f_F such that F-M-DELETION can be solved in time f_F(tw)n^{O(1)} on n-vertex graphs. Using and enhancing the machinery of boundaried graphs and small sets of representatives introduced by Bodlaender et al. [J ACM, 2016], we prove that when all the graphs in F are connected and at least one of them is planar, then f_F(w) = 2^{O(wlog w)}. When F is a singleton containing a clique, a cycle, or a path on i vertices, we prove the following asymptotically tight bounds: - f_{K_4}(w) = 2^{Theta(wlog w)}. - f_{C_i}(w) = 2^{Theta(w)} for every i4. - f_{P_i}(w) = 2^{Theta(w)} for every i5. The lower bounds hold unless the Exponential Time Hypothesis fails, and the superexponential ones are inspired by a reduction of Marcin Pilipczuk [Discrete Appl Math, 2016]. The single-exponential algorithms use, in particular, the rank-based approach introduced by Bodlaender et al. [Inform Comput, 2015]. We also consider the version of the problem where the graphs in F are forbidden as topological minors, and prove essentially the same set of results holds.

Published
2017
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76. Parameterized complexity of finding a spanning tree with minimum reload cost diameter.

Author

Baste, Julien, Gözüpek, Didem, Paul, Christophe, Sau, Ignasi, Shalom, Mordechai, and Thilikos, Dimitrios M.

Subjects
SPANNING trees, UNDIRECTED graphs, POLYNOMIAL time algorithms, MAXIMA & minima, NP-hard problems
Abstract

We study the minimum diameter spanning tree problem under the reload cost model (Diameter‐Tree for short) introduced by Wirth and Steffan. In this problem, given an undirected edge‐colored graph G, reload costs on a path arise at a node where the path uses consecutive edges of different colors. The objective is to find a spanning tree of G of minimum diameter with respect to the reload costs. We initiate a systematic study of the parameterized complexity of the Diameter‐Tree problem by considering the following parameters: the cost of a solution, and the treewidth and the maximum degree Δ of the input graph. We prove that Diameter‐Tree is para‐NP‐hard for any combination of two of these three parameters, and that it is FPT parameterized by the three of them. We also prove that the problem can be solved in polynomial time on cactus graphs. This result is somehow surprising since we prove Diameter‐Tree to be NP‐hard on graphs of treewidth two, which is best possible as the problem can be trivially solved on forests. When the reload costs satisfy the triangle inequality, Wirth and Steffan proved that the problem can be solved in polynomial time on graphs with Δ = 3, and Galbiati proved that it is NP‐hard if Δ = 4. Our results show, in particular, that without the requirement of the triangle inequality, the problem is NP‐hard if Δ = 3, which is also best possible. Finally, in the case where the reload costs are polynomially bounded by the size of the input graph, we prove that Diameter‐Tree is in XP and W[1]‐hard parameterized by the treewidth plus Δ. [ABSTRACT FROM AUTHOR]

Published
2020
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78. Parameterized Complexity of Finding a Spanning Tree with Minimum Reload Cost Diameter

Author

Baste, Julien, Paul, Christophe, Sau, Ignasi, Shalom, Mordechai, Thilikos, Dimitrios M., Baste, Julien, Paul, Christophe, Sau, Ignasi, Shalom, Mordechai, and Thilikos, Dimitrios M.

Abstract

We study the minimum diameter spanning tree problem under the reload cost model (DIAMETER-TREE for short) introduced by Wirth and Steffan (2001). In this problem, given an undirected edge-colored graph G, reload costs on a path arise at a node where the path uses consecutive edges of different colors. The objective is to find a spanning tree of G of minimum diameter with respect to the reload costs. We initiate a systematic study of the parameterized complexity of the DIAMETER-TREE problem by considering the following parameters: the cost of a solution, and the treewidth and the maximum degree Delta of the input graph. We prove that DIAMETER-TREE is para-np-hard for any combination of two of these three parameters, and that it is FPT parameterized by the three of them. We also prove that the problem can be solved in polynomial time on cactus graphs. This result is somehow surprising since we prove DIAMETER-TREE to be NP-hard on graphs of treewidth two, which is best possible as the problem can be trivially solved on forests. When the reload costs satisfy the triangle inequality, Wirth and Steffan (2001) proved that the problem can be solved in polynomial time on graphs with Delta=3, and Galbiati (2008) proved that it is NP-hard if Delta=4. Our results show, in particular, that without the requirement of the triangle inequality, the problem is NP-hard if Delta=3, which is also best possible. Finally, in the case where the reload costs are polynomially bounded by the size of the input graph, we prove that DIAMETER-TREE is in XP and W[1]-hard parameterized by the treewidth plus Delta.

Published
2018
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79. Contraction-Bidimensionality of Geometric Intersection Graphs

Author

Baste, Julien, Thilikos, Dimitrios M., Baste, Julien, and Thilikos, Dimitrios M.

Abstract

Given a graph G, we define bcg(G) as the minimum k for which G can be contracted to the uniformly triangulated grid Gamma_k. A graph class G has the SQGC property if every graph G in G has treewidth O(bcg(G)c) for some 1 <= c < 2. The SQGC property is important for algorithm design as it defines the applicability horizon of a series of meta-algorithmic results, in the framework of bidimensionality theory, related to fast parameterized algorithms, kernelization, and approximation schemes. These results apply to a wide family of problems, namely problems that are contraction-bidimensional. Our main combinatorial result reveals a general family of graph classes that satisfy the SQGC property and includes bounded-degree string graphs. This considerably extends the applicability of bidimensionality theory for several intersection graph classes of 2-dimensional geometrical objects.

Published
2018
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80. Optimal Algorithms for Hitting (Topological) Minors on Graphs of Bounded Treewidth

Author

Baste, Julien, Sau, Ignasi, Thilikos, Dimitrios M., Baste, Julien, Sau, Ignasi, and Thilikos, Dimitrios M.

Abstract

For a fixed collection of graphs F, the F-M-DELETION problem consists in, given a graph G and an integer k, decide whether there exists a subset S of V(G) of size at most 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 f_F such that F-M-DELETION can be solved in time f_F(tw)n^{O(1)} on n-vertex graphs. Using and enhancing the machinery of boundaried graphs and small sets of representatives introduced by Bodlaender et al. [J ACM, 2016], we prove that when all the graphs in F are connected and at least one of them is planar, then f_F(w) = 2^{O(wlog w)}. When F is a singleton containing a clique, a cycle, or a path on i vertices, we prove the following asymptotically tight bounds: - f_{K_4}(w) = 2^{Theta(wlog w)}. - f_{C_i}(w) = 2^{Theta(w)} for every i<5, and f_{C_i}(w) = 2^{Theta(wlog w)} for every i>4. - f_{P_i}(w) = 2^{Theta(w)} for every i<5, and f_{P_i}(w) = 2^{Theta(wlog w)} for every i>5. The lower bounds hold unless the Exponential Time Hypothesis fails, and the superexponential ones are inspired by a reduction of Marcin Pilipczuk [Discrete Appl Math, 2016]. The single-exponential algorithms use, in particular, the rank-based approach introduced by Bodlaender et al. [Inform Comput, 2015]. We also consider the version of the problem where the graphs in F are forbidden as topological minors, and prove essentially the same set of results holds.

Published
2018
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81. On the number of labeled graphs of bounded treewidth

Author

Universitat Politècnica de Catalunya. Departament de Matemàtiques, Universitat Politècnica de Catalunya. MD - Matemàtica Discreta, Baste, Julien, Noy Serrano, Marcos, Sau, Ignasi, Universitat Politècnica de Catalunya. Departament de Matemàtiques, Universitat Politècnica de Catalunya. MD - Matemàtica Discreta, Baste, Julien, Noy Serrano, Marcos, and Sau, Ignasi

Abstract

Let be Tnk the number of labeled graphs on vertices and treewidth at most (equivalently, the number o1 and some explicit absolute constant c>0. Disregarding terms depending only on k, the gap between the lower and upper bound is of order (log k)n. The upper bound is a direct consequence of the well-known formula for the number of labeled lambda-trees, while the lower bound is obtained from an explicit construction. It follows from this construction that both bounds also apply to graphs of pathwidth and proper-pathwidth at most k ., Postprint (published version)

Published
2018

82. Optimal Algorithms for Hitting (Topological) Minors on Graphs of Bounded Treewidth

Author

Julien Baste and Ignasi Sau and Dimitrios M. Thilikos, Baste, Julien, Sau, Ignasi, Thilikos, Dimitrios M., Julien Baste and Ignasi Sau and Dimitrios M. Thilikos, Baste, Julien, Sau, Ignasi, and Thilikos, Dimitrios M.

Abstract

For a fixed collection of graphs F, the F-M-DELETION problem consists in, given a graph G and an integer k, decide whether there exists a subset S of V(G) of size at most 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 f_F such that F-M-DELETION can be solved in time f_F(tw)n^{O(1)} on n-vertex graphs. Using and enhancing the machinery of boundaried graphs and small sets of representatives introduced by Bodlaender et al. [J ACM, 2016], we prove that when all the graphs in F are connected and at least one of them is planar, then f_F(w) = 2^{O(wlog w)}. When F is a singleton containing a clique, a cycle, or a path on i vertices, we prove the following asymptotically tight bounds: - f_{K_4}(w) = 2^{Theta(wlog w)}. - f_{C_i}(w) = 2^{Theta(w)} for every i<5, and f_{C_i}(w) = 2^{Theta(wlog w)} for every i>4. - f_{P_i}(w) = 2^{Theta(w)} for every i<5, and f_{P_i}(w) = 2^{Theta(wlog w)} for every i>5. The lower bounds hold unless the Exponential Time Hypothesis fails, and the superexponential ones are inspired by a reduction of Marcin Pilipczuk [Discrete Appl Math, 2016]. The single-exponential algorithms use, in particular, the rank-based approach introduced by Bodlaender et al. [Inform Comput, 2015]. We also consider the version of the problem where the graphs in F are forbidden as topological minors, and prove essentially the same set of results holds.

Published
2018
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83. Parameterized Complexity of Finding a Spanning Tree with Minimum Reload Cost Diameter

Author

Julien Baste and Didem Gözüpek and Christophe Paul and Ignasi Sau and Mordechai Shalom and Dimitrios M. Thilikos, Baste, Julien, Gözüpek, Didem, Paul, Christophe, Sau, Ignasi, Shalom, Mordechai, Thilikos, Dimitrios M., Julien Baste and Didem Gözüpek and Christophe Paul and Ignasi Sau and Mordechai Shalom and Dimitrios M. Thilikos, Baste, Julien, Gözüpek, Didem, Paul, Christophe, Sau, Ignasi, Shalom, Mordechai, and Thilikos, Dimitrios M.

Abstract

We study the minimum diameter spanning tree problem under the reload cost model (DIAMETER-TREE for short) introduced by Wirth and Steffan (2001). In this problem, given an undirected edge-colored graph G, reload costs on a path arise at a node where the path uses consecutive edges of different colors. The objective is to find a spanning tree of G of minimum diameter with respect to the reload costs. We initiate a systematic study of the parameterized complexity of the DIAMETER-TREE problem by considering the following parameters: the cost of a solution, and the treewidth and the maximum degree Delta of the input graph. We prove that DIAMETER-TREE is para-np-hard for any combination of two of these three parameters, and that it is FPT parameterized by the three of them. We also prove that the problem can be solved in polynomial time on cactus graphs. This result is somehow surprising since we prove DIAMETER-TREE to be NP-hard on graphs of treewidth two, which is best possible as the problem can be trivially solved on forests. When the reload costs satisfy the triangle inequality, Wirth and Steffan (2001) proved that the problem can be solved in polynomial time on graphs with Delta=3, and Galbiati (2008) proved that it is NP-hard if Delta=4. Our results show, in particular, that without the requirement of the triangle inequality, the problem is NP-hard if Delta=3, which is also best possible. Finally, in the case where the reload costs are polynomially bounded by the size of the input graph, we prove that DIAMETER-TREE is in XP and W[1]-hard parameterized by the treewidth plus Delta.

Published
2018
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84. Contraction-Bidimensionality of Geometric Intersection Graphs

Author

Julien Baste and Dimitrios M. Thilikos, Baste, Julien, Thilikos, Dimitrios M., Julien Baste and Dimitrios M. Thilikos, Baste, Julien, and Thilikos, Dimitrios M.

Abstract

Given a graph G, we define bcg(G) as the minimum k for which G can be contracted to the uniformly triangulated grid Gamma_k. A graph class G has the SQGC property if every graph G in G has treewidth O(bcg(G)c) for some 1 <= c < 2. The SQGC property is important for algorithm design as it defines the applicability horizon of a series of meta-algorithmic results, in the framework of bidimensionality theory, related to fast parameterized algorithms, kernelization, and approximation schemes. These results apply to a wide family of problems, namely problems that are contraction-bidimensional. Our main combinatorial result reveals a general family of graph classes that satisfy the SQGC property and includes bounded-degree string graphs. This considerably extends the applicability of bidimensionality theory for several intersection graph classes of 2-dimensional geometrical objects.

Published
2018
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85. Parameterized complexity dichotomy for $(r,\ell)$-Vertex Deletion

Author

Baste , Julien, Faria , Luerbio, Klein , Sulamita, Sau , Ignasi, Algorithmes, Graphes et Combinatoire ( ALGCO ), Laboratoire d'Informatique de Robotique et de Microélectronique de Montpellier ( LIRMM ), Université de Montpellier ( UM ) -Centre National de la Recherche Scientifique ( CNRS ) -Université de Montpellier ( UM ) -Centre National de la Recherche Scientifique ( CNRS ), Algorithmes, Graphes et Combinatoire (ALGCO), Laboratoire d'Informatique de Robotique et de Microélectronique de Montpellier (LIRMM), and Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)

Subjects
FOS: Computer and information sciences, [ MATH ] Mathematics [math], Computer Science - Computational Complexity, 68R10, 05C85, Computer Science - Data Structures and Algorithms, Data Structures and Algorithms (cs.DS), G.2.2, F.2.2, [MATH]Mathematics [math], Computational Complexity (cs.CC)
Abstract

For two integers $r, \ell \geq 0$, a graph $G = (V, E)$ is an $(r,\ell)$-graph if $V$ can be partitioned into $r$ independent sets and $\ell$ cliques. In the parameterized $(r,\ell)$-Vertex Deletion problem, given a graph $G$ and an integer $k$, one has to decide whether at most $k$ vertices can be removed from $G$ to obtain an $(r,\ell)$-graph. This problem is NP-hard if $r+\ell \geq 1$ and encompasses several relevant problems such as Vertex Cover and Odd Cycle Transversal. The parameterized complexity of $(r,\ell)$-Vertex Deletion was known for all values of $(r,\ell)$ except for $(2,1)$, $(1,2)$, and $(2,2)$. We prove that each of these three cases is FPT and, furthermore, solvable in single-exponential time, which is asymptotically optimal in terms of $k$. We consider as well the version of $(r,\ell)$-Vertex Deletion where the set of vertices to be removed has to induce an independent set, and provide also a parameterized complexity dichotomy for this problem., Comment: After the first version of this article appeared in arXiv, we learnt that Kolay and Panolan [abs/1504.08120] obtained simultaneously and independently some of the results of this article

Published
2016

87. Upper bounds on the uniquely restricted chromatic index.

Author

Baste, Julien, Rautenbach, Dieter, and Sau, Ignasi

Subjects
*UNDIRECTED graphs, *GEOMETRIC vertices
Abstract

Golumbic, Hirst, and Lewenstein define a matching in a simple, finite, and undirected graph G to be uniquely restricted if no other matching covers exactly the same set of vertices. We consider uniquely restricted edge‐colorings of G, defined as partitions of its edge set into uniquely restricted matchings, and study the uniquely restricted chromatic index χ′ur(G) of G, defined as the minimum number of uniquely restricted matchings required for such a partition. For every graph G, χ′(G)≤a′(G)≤χ′ur(G)≤χ′s(G), where χ′(G) is the classical chromatic index, a′(G) the acyclic chromatic index, and χ′s(G) the strong chromatic index of G. While Vizing's famous theorem states that χ′(G) is either the maximum degree Δ(G) of G or Δ(G)+1, two famous open conjectures due to Alon, Sudakov, and Zaks, and to Erdős and Nešetřil concern upper bounds on a′(G) and χ′s(G) in terms of Δ(G). Since χ′ur(G) is sandwiched between these two parameters, studying upper bounds in terms of Δ(G) is a natural problem. We show that χ′ur(G)≤Δ(G)2 with equality if and only if some component of G is KΔ(G),Δ(G). If G is connected, bipartite, and distinct from KΔ(G),Δ(G), and Δ(G) is at least 4, then, adapting Lovász's elegant proof of Brooks' theorem, we show that χ′ur(G)≤Δ(G)2−Δ(G). Our proofs are constructive and yield efficient algorithms to determine the corresponding edge‐colorings. [ABSTRACT FROM AUTHOR]

Published
2019
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