Your search keyword '"Irrelevant vertex technique"' showing total 15 results

1. COMBING A LINKAGE IN AN ANNULUS.

Author

GOLOVACH, PETR A., STAMOULIS, GIANNOS, and THILIKOS, DIMITRIOS M.

Abstract

A linkage in a graph G of size k is a subgraph L of G whose connected components are k paths. The pattern of a linkage of size k is the set of k pairs formed by the endpoints of these paths. A consequence of the Unique Linkage Theorem is the following: there exists a function f: N rightarrow N such that if a plane graph G contains a sequence\scrC of at least f(k) nested cycles and a linkage of size at most k whose pattern vertices lay outside the outer cycle of scrC, then G contains a linkage with the same pattern avoiding the inner cycle of\scrC. In this paper we prove the following variant of this result: Assume that all the cycles in\scrC are "orthogonally" traversed by a linkage P and L is a linkage whose pattern vertices may lay either outside the outer cycle or inside the inner cycle of scrC := [C1,...,Cp, . . ., C2p-1]. We prove that there are two functions g, f: Nrightarrow N, such that if L has size at most k, P has size at least f(k), and | scrC | geq g(k), then there is a linkage with the same pattern as L that is "internally combed" by P, in the sense that L cap Cp subseteq P\cap Cp. This result applies to any graph that is partially embedded on a disk (wherescrC is also embedded). In fact, we prove this result in the most general version where the linkage L is s-scattered: every two vertices of distinct paths are within a distance bigger than s. We deduce several variants of this result in the cases where s = 0 and s > 0. These variants permit the application of the Unique Linkage Theorem on several path routing problems on embedded graphs. [ABSTRACT FROM AUTHOR]

Published

2023

2. k-apices of minor-closed graph classes. I. Bounding the obstructions.

Author

Sau, Ignasi, Stamoulis, Giannos, and Thilikos, Dimitrios M.

Subjects

*MINORS, *POLYNOMIALS, *MATROIDS

Abstract

Let G be a minor-closed graph class. We say that a graph G is a k-apex of G if G contains a set S of at most k vertices such that G ∖ S belongs to G. We denote by A k (G) the set of all graphs that are k -apices of G. We prove that every graph in the obstruction set of A k (G) , i.e., the minor-minimal set of graphs not belonging to A k (G) , has order at most 2 2 2 2 poly (k) , where poly is a polynomial function whose degree depends on the order of the minor-obstructions of G. This bound drops to 2 2 poly (k) when G excludes some apex graph as a minor. [ABSTRACT FROM AUTHOR]

Published

2023

3. Hitting Topological Minor Models in Planar Graphs is Fixed Parameter Tractable.

Author

GOLOVACH, PETR A., STAMOULIS, GIANNOS, and THILIKOS, DIMITRIOS M.

Subjects

MINORS, PLANAR graphs, INTEGERS

Abstract

For a finite collection of graphs F, the F -TM-Deletion problem has as input an n-vertex graph G and an integer k and asks whether there exists a set S = V (G) with | S | = k such that G \ S does not contain any of the graphs in F as a topological minor. We prove that for every such F, F -TM-Deletion is fixed parameter tractable on planar graphs. Our algorithm runs in a 2 O(k 2) · n² time, or, alternatively, in 2 O(k) · n4 time. Our techniques can easily be extended to graphs that are embeddable on any fixed surface. [ABSTRACT FROM AUTHOR]

Published

2023

4. k-apices of Minor-closed Graph Classes. II. Parameterized Algorithms.

Author

SAU, IGNASI, STAMOULIS, GIANNOS, and THILIKOS, DIMITRIOS M.

Subjects

ALGORITHMS, CHARTS, diagrams, etc., MINORS, POLYNOMIALS

Abstract

Let G be a minor-closed graph class. We say that a graph G is a k-apex of G if G contains a set S of at most k vertices such that G\S belongs to G. We denote by Ak (G) the set of all graphs that are k-apices of G. In the first paper of this series, we obtained upper bounds on the size of the graphs in the minor-obstruction set of Ak (G), i.e., the minor-minimal set of graphs not belonging to Ak (G). In this article, we provide an algorithm that, given a graph G on n vertices, runs in time 2poly(k) · n3 and either returns a set S certifying that G ∈ Ak (G), or reports that G ∉ Ak (G). Here poly is a polynomial function whose degree depends on the maximum size of a minor-obstruction of G. In the special case where G excludes some apex graph as a minor, we give an alternative algorithm running in 2poly(k) · n²-time. [ABSTRACT FROM AUTHOR]

Published

2022

5. Compound Logics for Modification Problems

Author

Fedor V. Fomin and Petr A. Golovach and Ignasi Sau and Giannos Stamoulis and Dimitrios M. Thilikos, Fomin, Fedor V., Golovach, Petr A., Sau, Ignasi, Stamoulis, Giannos, Thilikos, Dimitrios M., Fedor V. Fomin and Petr A. Golovach and Ignasi Sau and Giannos Stamoulis and Dimitrios M. Thilikos, Fomin, Fedor V., Golovach, Petr A., Sau, Ignasi, Stamoulis, Giannos, and Thilikos, Dimitrios M.

Abstract

We introduce a novel model-theoretic framework inspired from graph modification and based on the interplay between model theory and algorithmic graph minors. The core of our framework is a new compound logic operating with two types of sentences, expressing graph modification: the modulator sentence, defining some property of the modified part of the graph, and the target sentence, defining some property of the resulting graph. In our framework, modulator sentences are in counting monadic second-order logic (CMSOL) and have models of bounded treewidth, while target sentences express first-order logic (FOL) properties along with minor-exclusion. Our logic captures problems that are not definable in first-order logic and, moreover, may have instances of unbounded treewidth. Also, it permits the modeling of wide families of problems involving vertex/edge removals, alternative modulator measures (such as elimination distance or G-treewidth), multistage modifications, and various cut problems. Our main result is that, for this compound logic, model-checking can be done in quadratic time. All derived algorithms are constructive and this, as a byproduct, extends the constructibility horizon of the algorithmic applications of the Graph Minors theorem of Robertson and Seymour. The proposed logic can be seen as a general framework to capitalize on the potential of the irrelevant vertex technique. It gives a way to deal with problem instances of unbounded treewidth, for which Courcelle’s theorem does not apply.

Published

2023

6. Graph Minors and Parameterized Algorithm Design

Author

Thilikos, Dimitrios M., 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, Nierstrasz, Oscar, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Sudan, Madhu, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Vardi, Moshe Y., Series editor, Weikum, Gerhard, Series editor, Bodlaender, Hans L., editor, Downey, Rod, editor, Fomin, Fedor V., editor, and Marx, Dániel, editor

Published

2012

7. Faster Parameterized Algorithms for Modification Problems to Minor-Closed Classes

Author

Morelle, Laure, Sau, Ignasi, Stamoulis, Giannos, and Thilikos, Dimitrios M.

Subjects

FOS: Computer and information sciences, F.2.2, G.2.2, Elimination distance, 05C85, 68R10, 05C75, 05C83, 05C75, 05C69, Obstructions, Graph minors, Computational Complexity (cs.CC), Vertex deletion, Irrelevant vertex technique, Computer Science - Computational Complexity, Parameterized algorithms, Computer Science - Data Structures and Algorithms, FOS: Mathematics, Mathematics - Combinatorics, Theory of computation → Parameterized complexity and exact algorithms, Data Structures and Algorithms (cs.DS), Flat Wall Theorem, Combinatorics (math.CO), Graph modification problems

Abstract

Let G be a minor-closed graph class and let G be an n-vertex graph. We say that G is a k-apex of G if G contains a set S of at most k vertices such that G⧵S belongs to G. Our first result is an algorithm that decides whether G is a k-apex of G in time 2^poly(k)⋅n². This algorithm improves the previous one, given by Sau, Stamoulis, and Thilikos [ICALP 2020, TALG 2022], whose running time was 2^poly(k)⋅n³. The elimination distance of G to G, denoted by ed_G(G), is the minimum number of rounds required to reduce each connected component of G to a graph in G by removing one vertex from each connected component in each round. Bulian and Dawar [Algorithmica 2017] proved the existence of an FPT-algorithm, with parameter k, to decide whether ed_G(G) ≤ k. This algorithm is based on the computability of the minor-obstructions and its dependence on k is not explicit. We extend the techniques used in the first algorithm to decide whether ed_G(G) ≤ k in time 2^{2^{2^poly(k)}}⋅n². This is the first algorithm for this problem with an explicit parametric dependence in k. In the special case where G excludes some apex-graph as a minor, we give two alternative algorithms, one running in time 2^{2^O(k²log k)}⋅n² and one running in time 2^{poly(k)}⋅n³. As a stepping stone for these algorithms, we provide an algorithm that decides whether ed_G(G) ≤ k in time 2^O(tw⋅ k + tw log tw)⋅n, where tw is the treewidth of G. This algorithm combines the dynamic programming framework of Reidl, Rossmanith, Villaamil, and Sikdar [ICALP 2014] for the particular case where G contains only the empty graph (i.e., for treedepth) with the representative-based techniques introduced by Baste, Sau, and Thilikos [SODA 2020]. In all the algorithmic complexities above, poly is a polynomial function whose degree depends on G, while the hidden constants also depend on G. Finally, we provide explicit upper bounds on the size of the graphs in the minor-obstruction set of the class of graphs E_k(G) = {G ∣ ed_G(G) ≤ k}., LIPIcs, Vol. 261, 50th International Colloquium on Automata, Languages, and Programming (ICALP 2023), pages 93:1-93:19

Published

2023

8. Compound Logics for Modification Problems

Author

Fomin, Fedor V., Golovach, Petr A., Sau, Ignasi, Stamoulis, Giannos, and Thilikos, Dimitrios M.

Subjects

FOS: Computer and information sciences, Flat Wall theorem, Computer Science - Logic in Computer Science, Mathematics of computing → Graph algorithms, G.2.2, Theory of computation → Logic, Irrelevant vertex technique, 05C83, 05C85, 68R10, 68Q19, 68Q27, 68Q25, Computer Science - Data Structures and Algorithms, FOS: Mathematics, Theory of computation → Parameterized complexity and exact algorithms, Mathematics - Combinatorics, Data Structures and Algorithms (cs.DS), Graph minors, F.2.2, F.4.1, Logic in Computer Science (cs.LO), Model-checking, TheoryofComputation_MATHEMATICALLOGICANDFORMALLANGUAGES, Algorithmic meta-theorems, Monadic second-order logic, Combinatorics (math.CO), First-order logic, Graph modification problems, MathematicsofComputing_DISCRETEMATHEMATICS

Abstract

We introduce a novel model-theoretic framework inspired from graph modification and based on the interplay between model theory and algorithmic graph minors. The core of our framework is a new compound logic operating with two types of sentences, expressing graph modification: the modulator sentence, defining some property of the modified part of the graph, and the target sentence, defining some property of the resulting graph. In our framework, modulator sentences are in counting monadic second-order logic (CMSOL) and have models of bounded treewidth, while target sentences express first-order logic (FOL) properties along with minor-exclusion. Our logic captures problems that are not definable in first-order logic and, moreover, may have instances of unbounded treewidth. Also, it permits the modeling of wide families of problems involving vertex/edge removals, alternative modulator measures (such as elimination distance or G-treewidth), multistage modifications, and various cut problems. Our main result is that, for this compound logic, model-checking can be done in quadratic time. All derived algorithms are constructive and this, as a byproduct, extends the constructibility horizon of the algorithmic applications of the Graph Minors theorem of Robertson and Seymour. The proposed logic can be seen as a general framework to capitalize on the potential of the irrelevant vertex technique. It gives a way to deal with problem instances of unbounded treewidth, for which Courcelle’s theorem does not apply., LIPIcs, Vol. 261, 50th International Colloquium on Automata, Languages, and Programming (ICALP 2023), pages 61:1-61:21

Published

2021

9. An FPT-Algorithm for Recognizing k-Apices of Minor-Closed Graph Classes

Author

Sau, Ignasi, Stamoulis, Giannos, 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), National and Kapodistrian University of Athens (NKUA), Artur Czumaj, Anuj Dawar, Emanuela Merelli, ANR-16-CE40-0028,DE-MO-GRAPH,Décomposition de Modèles Graphiques(2016), and ANR-17-CE23-0010,ESIGMA,Efficacité et structure pour les applications de la fouille de graphes(2017)

Subjects

irrelevant vertex technique, parameterized algorithms, Theory of computation → Parameterized complexity and exact algorithms, [MATH]Mathematics [math], graph minors, Graph modification problems

Abstract

International audience; Let G be a graph class. We say that a graph G is a k-apex of G if G contains a set S of at most k vertices such that G \ S belongs to G. We prove that if G is minor-closed, then there is an algorithm that either returns a set S certifying that G is a k-apex of G or reports that such a set does not exist, in 2 poly(k) n 3 time. Here poly is a polynomial function whose degree depends on the maximum size of a minor-obstruction of G, i.e., the minor-minimal set of graphs not belonging to G. In the special case where G excludes some apex graph as a minor, we give an alternative algorithm running in 2 poly(k) n 2 time.

Published

2020

10. Induced packing of odd cycles in planar graphs

Author

Golovach, Petr A., Kamiński, Marcin, Paulusma, Daniël, and Thilikos, Dimitrios M.

Subjects

*PLANAR graphs, *GRAPH theory, *CIRCLE packing, *ALGEBRAIC cycles, *NP-complete problems, *COMPUTATIONAL mathematics

Abstract

Abstract: An induced packing of odd cycles in a graph is a packing such that there is no edge in the graph between any two odd cycles in the packing. We prove that an induced packing of odd cycles in an -vertex graph can be found (if it exists) in time (for any constant ) when the input graph is planar. We also show that deciding if a graph has an induced packing of two odd induced cycles is NP-complete. [Copyright &y& Elsevier]

Published

2012

11. Hitting Topological Minor Models in Planar Graphs is Fixed Parameter Tractable

Author

Petr A. Golovach, Giannos Stamoulis, Dimitrios M. Thilikos, Department of Informatics [Bergen] (UiB), University of Bergen (UiB), National and Kapodistrian University of Athens (NKUA), 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), ANR-16-CE40-0028,DE-MO-GRAPH,Décomposition de Modèles Graphiques(2016), and ANR-17-CE23-0010,ESIGMA,Efficacité et structure pour les applications de la fouille de graphes(2017)

Subjects

FOS: Computer and information sciences, [INFO.INFO-DS]Computer Science [cs]/Data Structures and Algorithms [cs.DS], Topological minors, G.2.2, vertex deletion problems, irrelevant vertex technique, Mathematics (miscellaneous), Computer Science - Data Structures and Algorithms, treewidth, FOS: Mathematics, Mathematics - Combinatorics, Data Structures and Algorithms (cs.DS), 05C85, Combinatorics (math.CO), Graph algorithms, Design and analysis of algorithms

Abstract

For a finite collection of graphs ${\cal F}$, the \textsc{${\cal F}$-TM-Deletion} problem has as input an $n$-vertex graph $G$ and an integer $k$ and asks whether there exists a set $S \subseteq V(G)$ with $|S| \leq k$ such that $G \setminus S$ does not contain any of the graphs in ${\cal F}$ as a topological minor. We prove that for every such ${\cal F}$, \textsc{${\cal F}$-TM-Deletion} is fixed parameter tractable on planar graphs. Our algorithm runs in a $2^{\mathcal{O}(k^2)}\cdot n^{2}$ time or, alternatively in $2^{\mathcal{O}(k)}\cdot n^{4}$ time. Our techniques can easily be extended to graphs that are embeddable on any fixed surface., Comment: A preliminary version of these results appeared in [Petr A. Golovach, Giannos Stamoulis, Dimitrios M. Thilikos: Hitting Topological Minor Models in Planar Graphs is Fixed Parameter Tractable. SODA 2020: 931-950]

Published

2020

12. An Algorithmic Meta-Theorem for Graph Modification to Planarity and FOL

Author

Fedor V. Fomin, Petr A. Golovach, Giannos Stamoulis, Dimitrios M. Thilikos, Department of Informatics [Bergen] (UiB), University of Bergen (UiB), National and Kapodistrian University of Athens (NKUA), 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), Fabrizio Grandoni, Grzegorz Herman, Peter Sanders, ANR-16-CE40-0028,DE-MO-GRAPH,Décomposition de Modèles Graphiques(2016), and ANR-17-CE23-0010,ESIGMA,Efficacité et structure pour les applications de la fouille de graphes(2017)

Subjects

FOS: Computer and information sciences, Computer Science - Logic in Computer Science, Discrete Mathematics (cs.DM), Mathematics of computing → Graph algorithms, [INFO.INFO-DS]Computer Science [cs]/Data Structures and Algorithms [cs.DS], Graph modification Problems, 05C85, 68R10, 05C75, 05C83, 05C75, 05C69, Planar graphs, G.2.2, F.2.2, First Order Logic, Logic in Computer Science (cs.LO), Theoretical Computer Science, Surface embeddable graphs, Irrelevant vertex technique, Computational Theory and Mathematics, Computer Science - Data Structures and Algorithms, Algorithmic meta-theorems, Theory of computation → Parameterized complexity and exact algorithms, Data Structures and Algorithms (cs.DS), Computer Science - Discrete Mathematics

Abstract

In general, a graph modification problem is defined by a graph modification operation ⊠ and a target graph property 𝒫. Typically, the modification operation ⊠ may be vertex deletion , edge deletion , edge contraction , or edge addition and the question is, given a graph G and an integer k , whether it is possible to transform G to a graph in 𝒫 after applying the operation ⊠ k times on G . This problem has been extensively studied for particular instantiations of ⊠ and 𝒫. In this article, we consider the general property 𝒫 𝛗 of being planar and, additionally, being a model of some First-Order Logic (FOL) sentence 𝛗 (an FOL-sentence). We call the corresponding meta-problem Graph ⊠-Modification to Planarity and 𝛗 and prove the following algorithmic meta-theorem: there exists a function f : ℕ 2 → ℕ such that, for every ⊠ and every FOL-sentence 𝛗, the Graph ⊠-Modification to Planarity and 𝛗 is solvable in f ( k,|𝛗| )⋅ n 2 time. The proof constitutes a hybrid of two different classic techniques in graph algorithms. The first is the irrelevant vertex technique that is typically used in the context of Graph Minors and deals with properties such as planarity or surface-embeddability (that are not FOL-expressible) and the second is the use of Gaifman’s locality theorem that is the theoretical base for the meta-algorithmic study of FOL-expressible problems.

Published

2020

13. Modification to Planarity is Fixed Parameter Tractable

Author

Fedor V. Fomin and Petr A. Golovach and Dimitrios M. Thilikos, Fomin, Fedor V., Golovach, Petr A., Thilikos, Dimitrios M., Fedor V. Fomin and Petr A. Golovach and Dimitrios M. Thilikos, Fomin, Fedor V., Golovach, Petr A., and Thilikos, Dimitrios M.

Abstract

A replacement action is a function L that maps each k-vertex labeled graph to another k-vertex graph. We consider a general family of graph modification problems, called L-Replacement to C, where the input is a graph G and the question is whether it is possible to replace in G some k-vertex subgraph H of it by L(H) so that the new graph belongs to the graph class C. L-Replacement to C can simulate several modification operations such as edge addition, edge removal, edge editing, and diverse completion and superposition operations. In this paper, we prove that for any action L, if C is the class of planar graphs, there is an algorithm that solves L-Replacement to C in O(|G|^{2}) steps. We also present several applications of our approach to related problems.

Published

2019

14. Modification to planarity is fixed parameter tractable

Author

Fomin, Fedor V., Golovach, Petr A., Thilikos, Dimitrios M., Department of Informatics [Bergen] (UiB), University of Bergen (UiB), School of Engineering and Computing Sciences, Durham University, 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), Rolf Niedermeier, and Christophe Paul

Subjects

Irrelevant vertex technique, 000 Computer science, knowledge, general works, Modification problems, [INFO.INFO-DS]Computer Science [cs]/Data Structures and Algorithms [cs.DS], Computer Science, Planar graphs, [INFO.INFO-DM]Computer Science [cs]/Discrete Mathematics [cs.DM], MathematicsofComputing_DISCRETEMATHEMATICS

Abstract

International audience; A replacement action is a function L that maps each k-vertex labeled graph to another k-vertex graph. We consider a general family of graph modification problems, called L-Replacement to C, where the input is a graph G and the question is whether it is possible to replace in G some k-vertex subgraph H of it by L(H) so that the new graph belongs to the graph class C. L-Replacement to C can simulate several modification operations such as edge addition, edge removal, edge editing, and diverse completion and superposition operations. In this paper, we prove that for any action L, if C is the class of planar graphs, there is an algorithm that solves L-Replacement to C in O(|G| 2) steps. We also present several applications of our approach to related problems.

Published

2019

15. Subexponential Algorithms for Partial Cover Problems

Author

Fedor V. Fomin and Daniel Lokshtanov and Venkatesh Raman and Saket Saurabh, Fomin, Fedor V., Lokshtanov, Daniel, Raman, Venkatesh, Saurabh, Saket, Fedor V. Fomin and Daniel Lokshtanov and Venkatesh Raman and Saket Saurabh, Fomin, Fedor V., Lokshtanov, Daniel, Raman, Venkatesh, and Saurabh, Saket

Abstract

Partial Cover problems are optimization versions of fundamental and well studied problems like {\sc Vertex Cover} and {\sc Dominating Set}. Here one is interested in covering (or dominating) the maximum number of edges (or vertices) using a given number ($k$) of vertices, rather than covering all edges (or vertices). In general graphs, these problems are hard for parameterized complexity classes when parameterized by $k$. It was recently shown by Amini et. al. [{\em FSTTCS 08}\,] that {\sc Partial Vertex Cover} and {\sc Partial Dominating Set} are fixed parameter tractable on large classes of sparse graphs, namely $H$-minor free graphs, which include planar graphs and graphs of bounded genus. In particular, it was shown that on planar graphs both problems can be solved in time $2^{\cO(k)}n^{\cO(1)}$.

Published

2009