Your search keyword '"Köhler, Noleen"' showing total 20 results

1. Core Stability in Additively Separable Hedonic Games of Low Treewidth

Author

Hanaka, Tesshu, Köhler, Noleen, and Lampis, Michael

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Computer Science and Game Theory

Abstract

Additively Separable Hedonic Game (ASHG) are coalition-formation games where we are given a graph whose vertices represent $n$ selfish agents and the weight of each edge $uv$ denotes how much agent $u$ gains (or loses) when she is placed in the same coalition as agent $v$. We revisit the computational complexity of the well-known notion of core stability of ASHGs, where the goal is to construct a partition of the agents into coalitions such that no group of agents would prefer to diverge from the given partition and form a new (blocking) coalition. Since both finding a core stable partition and verifying that a given partition is core stable are intractable problems ($\Sigma_2^p$-complete and coNP-complete respectively) we study their complexity from the point of view of structural parameterized complexity, using standard graph-theoretic parameters, such as treewidth.

Published

2024

2. Bandwidth Parameterized by Cluster Vertex Deletion Number

Author

Gima, Tatsuya, Kim, Eun Jung, Köhler, Noleen, Melissinos, Nikolaos, and Vasilakis, Manolis

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity

Abstract

Given a graph $G$ and an integer $b$, Bandwidth asks whether there exists a bijection $\pi$ from $V(G)$ to $\{1, \ldots, |V(G)|\}$ such that $\max_{\{u, v \} \in E(G)} | \pi(u) - \pi(v) | \leq b$. This is a classical NP-complete problem, known to remain NP-complete even on very restricted classes of graphs, such as trees of maximum degree 3 and caterpillars of hair length 3. In the realm of parameterized complexity, these results imply that the problem remains NP-hard on graphs of bounded pathwidth, while it is additionally known to be W[1]-hard when parameterized by the treedepth of the input graph. In contrast, the problem does become FPT when parameterized by the vertex cover number of the input graph. In this paper, we make progress towards the parameterized (in)tractability of Bandwidth. We first show that it is FPT when parameterized by the cluster vertex deletion number cvd plus the clique number $\omega$ of the input graph, thus generalizing the previously mentioned result for vertex cover. On the other hand, we show that Bandwidth is W[1]-hard when parameterized only by cvd. Our results generalize some of the previous results and narrow some of the complexity gaps., Comment: An extended abstract of this article was presented at IPEC 2023

Published

2023

3. On Testability of First-Order Properties in Bounded-Degree Graphs and Connections to Proximity-Oblivious Testing

Author

Adler, Isolde, Köhler, Noleen, and Peng, Pan

Subjects

Computer Science - Logic in Computer Science, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms, Mathematics - Combinatorics

Abstract

We study property testing of properties that are definable in first-order logic (FO) in the bounded-degree graph and relational structure models. We show that any FO property that is defined by a formula with quantifier prefix $\exists^*\forall^*$ is testable (i.e., testable with constant query complexity), while there exists an FO property that is expressible by a formula with quantifier prefix $\forall^*\exists^*$ that is not testable. In the dense graph model, a similar picture is long known (Alon, Fischer, Krivelevich, Szegedy, Combinatorica 2000), despite the very different nature of the two models. In particular, we obtain our lower bound by an FO formula that defines a class of bounded-degree expanders, based on zig-zag products of graphs. We expect this to be of independent interest. We then use our class of FO definable bounded-degree expanders to answer a long-standing open problem for proximity-oblivious testers (POTs). POTs are a class of particularly simple testing algorithms, where a basic test is performed a number of times that may depend on the proximity parameter, but the basic test itself is independent of the proximity parameter. In their seminal work, Goldreich and Ron [STOC 2009; SICOMP 2011] show that the graph properties that are constant-query proximity-oblivious testable in the bounded-degree model are precisely the properties that can be expressed as a generalised subgraph freeness (GSF) property that satisfies the non-propagation condition. It is left open whether the non-propagation condition is necessary. We give a negative answer by showing that our property is a GSF property which is propagating. Hence in particular, our property does not admit a POT. For this result we establish a new connection between FO properties and GSF-local properties via neighbourhood profiles., Comment: Preliminary version of this article appeared in SODA'21 (arXiv:2008.05800) and CCC'21 (arXiv:2105.08490)

Published

2023

4. Odd Chromatic Number of Graph Classes

Author

Belmonte, Rémy, Harutyunyan, Ararat, Köhler, Noleen, and Melissinos, Nikolaos

Subjects

Computer Science - Discrete Mathematics, Mathematics - Combinatorics

Abstract

A graph is called odd (respectively, even) if every vertex has odd (respectively, even) degree. Gallai proved that every graph can be partitioned into two even induced subgraphs, or into an odd and an even induced subgraph. We refer to a partition into odd subgraphs as an odd colouring of G. Scott [Graphs and Combinatorics, 2001] proved that a graph admits an odd colouring if and only if it has an even number of vertices. We say that a graph G is k-odd colourable if it can be partitioned into at most k odd induced subgraphs. We initiate the systematic study of odd colouring and odd chromatic number of graph classes. In particular, we consider for a number of classes whether they have bounded odd chromatic number. Our main results are that interval graphs, graphs of bounded modular-width and graphs of bounded maximum degree all have bounded odd chromatic number., Comment: 21 pages, 3 figures

Published

2023

5. Twin-width VIII: delineation and win-wins

Author

Bonnet, Édouard, Chakraborty, Dibyayan, Kim, Eun Jung, Köhler, Noleen, Lopes, Raul, and Thomassé, Stéphan

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Discrete Mathematics, Computer Science - Logic in Computer Science, Mathematics - Combinatorics, 05C85, 05C75, F.2.2

Abstract

We introduce the notion of delineation. A graph class $\mathcal C$ is said delineated if for every hereditary closure $\mathcal D$ of a subclass of $\mathcal C$, it holds that $\mathcal D$ has bounded twin-width if and only if $\mathcal D$ is monadically dependent. An effective strengthening of delineation for a class $\mathcal C$ implies that tractable FO model checking on $\mathcal C$ is perfectly understood: On hereditary closures $\mathcal D$ of subclasses of $\mathcal C$, FO model checking is fixed-parameter tractable (FPT) exactly when $\mathcal D$ has bounded twin-width. Ordered graphs [BGOdMSTT, STOC '22] and permutation graphs [BKTW, JACM '22] are effectively delineated, while subcubic graphs are not. On the one hand, we prove that interval graphs, and even, rooted directed path graphs are delineated. On the other hand, we show that segment graphs, directed path graphs, and visibility graphs of simple polygons are not delineated. In an effort to draw the delineation frontier between interval graphs (that are delineated) and axis-parallel two-lengthed segment graphs (that are not), we investigate the twin-width of restricted segment intersection classes. It was known that (triangle-free) pure axis-parallel unit segment graphs have unbounded twin-width [BGKTW, SODA '21]. We show that $K_{t,t}$-free segment graphs, and axis-parallel $H_t$-free unit segment graphs have bounded twin-width, where $H_t$ is the half-graph or ladder of height $t$. In contrast, axis-parallel $H_4$-free two-lengthed segment graphs have unbounded twin-width. Our new results, combined with the known FPT algorithm for FO model checking on graphs given with $O(1)$-sequences, lead to win-win arguments. For instance, we derive FPT algorithms for $k$-Ladder on visibility graphs of 1.5D terrains, and $k$-Independent Set on visibility graphs of simple polygons., Comment: 51 pages, 19 figures

Published

2022

6. An Algorithmic Framework for Locally Constrained Homomorphisms

Author

Bulteau, Laurent, Dabrowski, Konrad K., Köhler, Noleen, Ordyniak, Sebastian, and Paulusma, Daniël

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, Mathematics - Combinatorics

Abstract

A homomorphism $f$ from a guest graph $G$ to a host graph $H$ is locally bijective, injective or surjective if for every $u\in V(G)$, the restriction of $f$ to the neighbourhood of $u$ is bijective, injective or surjective, respectively. The corresponding decision problems, LBHOM, LIHOM and LSHOM, are well studied both on general graphs and on special graph classes. Apart from complexity results when the problems are parameterized by the treewidth and maximum degree of the guest graph, the three problems still lack a thorough study of their parameterized complexity. This paper fills this gap: we prove a number of new FPT, W[1]-hard and para-NP-complete results by considering a hierarchy of parameters of the guest graph $G$. For our FPT results, we do this through the development of a new algorithmic framework that involves a general ILP model. To illustrate the applicability of the new framework, we also use it to prove FPT results for the Role Assignment problem, which originates from social network theory and is closely related to locally surjective homomorphisms.

Published

2022

7. GSF-locality is not sufficient for proximity-oblivious testing

Author

Adler, Isolde, Köhler, Noleen, and Peng, Pan

Subjects

Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms, Computer Science - Logic in Computer Science, F.4.1, G.2.2

Abstract

In Property Testing, proximity-oblivious testers (POTs) form a class of particularly simple testing algorithms, where a basic test is performed a number of times that may depend on the proximity parameter, but the basic test itself is independent of the proximity parameter. In their seminal work, Goldreich and Ron [STOC 2009; SICOMP 2011] show that the graph properties that allow constant-query proximity-oblivious testing in the bounded-degree model are precisely the properties that can be expressed as a generalised subgraph freeness (GSF) property that satisfies the non-propagation condition. It is left open whether the non-propagation condition is necessary. Indeed, calling properties expressible as a generalised subgraph freeness property GSF-local properties, they ask whether all GSF-local properties are non-propagating. We give a negative answer by exhibiting a property of graphs that is GSF-local and propagating. Hence in particular, our property does not admit a POT, despite being GSF-local. We prove our result by exploiting a recent work of the authors which constructed a first-order (FO) property that is not testable [SODA 2021], and a new connection between FO properties and GSF-local properties via neighbourhood profiles., Comment: 28 pages, 3 figures

Published

2021

8. On Testability of First-Order Properties in Bounded-Degree Graphs

Author

Adler, Isolde, Köhler, Noleen, and Peng, Pan

Subjects

Computer Science - Logic in Computer Science, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms, Mathematics - Combinatorics, F.4.1, G.2.2

Abstract

We study property testing of properties that are definable in first-order logic (FO) in the bounded-degree graph and relational structure models. We show that any FO property that is defined by a formula with quantifier prefix $\exists^*\forall^*$ is testable (i.e., testable with constant query complexity), while there exists an FO property that is expressible by a formula with quantifier prefix $\forall^*\exists^*$ that is not testable. In the dense graph model, a similar picture is long known (Alon, Fischer, Krivelevich, Szegedy, Combinatorica 2000), despite the very different nature of the two models. In particular, we obtain our lower bound by a first-order formula that defines a class of bounded-degree expanders, based on zig-zag products of graphs. We expect this to be of independent interest. We then prove testability of some first-order properties that speak about isomorphism types of neighbourhoods, including testability of $1$-neighbourhood-freeness, and $r$-neighbourhood-freeness under a mild assumption on the degrees., Comment: 37 pages, 4 figures

Published

2020

9. An explicit construction of graphs of bounded degree that are far from being Hamiltonian

Author

Adler, Isolde and Köhler, Noleen

Subjects

Computer Science - Discrete Mathematics, Computer Science - Computational Complexity, Computer Science - Data Structures and Algorithms, G.2.2

Abstract

Hamiltonian cycles in graphs were first studied in the 1850s. Since then, an impressive amount of research has been dedicated to identifying classes of graphs that allow Hamiltonian cycles, and to related questions. The corresponding decision problem, that asks whether a given graph is Hamiltonian (i.\,e.\ admits a Hamiltonian cycle), is one of Karp's famous NP-complete problems. In this paper we study graphs of bounded degree that are \emph{far} from being Hamiltonian, where a graph $G$ on $n$ vertices is \emph{far} from being Hamiltonian, if modifying a constant fraction of $n$ edges is necessary to make $G$ Hamiltonian. We give an explicit deterministic construction of a class of graphs of bounded degree that are locally Hamiltonian, but (globally) far from being Hamiltonian. Here, \emph{locally Hamiltonian} means that every subgraph induced by the neighbourhood of a small vertex set appears in some Hamiltonian graph. More precisely, we obtain graphs which differ in $\Theta(n)$ edges from any Hamiltonian graph, but non-Hamiltonicity cannot be detected in the neighbourhood of $o(n)$ vertices. Our class of graphs yields a class of hard instances for one-sided error property testers with linear query complexity. It is known that any property tester (even with two-sided error) requires a linear number of queries to test Hamiltonicity (Yoshida, Ito, 2010). This is proved via a randomised construction of hard instances. In contrast, our construction is deterministic. So far only very few deterministic constructions of hard instances for property testing are known. We believe that our construction may lead to future insights in graph theory and towards a characterisation of the properties that are testable in the bounded-degree model., Comment: 19 pages, 4 figures

Published

2020

10. Logical methods for property testing in the bounded degree model

Author

Köhler, Noleen, Adler, Isolde, and Vuskovic, Kristina

Abstract

Property testers are randomised sublinear time algorithms which infer global structure from a local view of an input. In the context of bounded degree graphs, testability of a property is tightly linked to the question of whether an approximate distribution of r-neighbourhood types of a graph is sufficient to capture whether the graph has the property or is "far" from having the property. Our understanding of when this is the case is limited. The central open question in the field of property testing is to characterise testable properties of bounded degree graphs. Towards a characterisation of testable properties in the bounded degree model, we study property testing of properties definable in first-order logic (FO) in the bounded degree model. By Gaifman's locality theorem it is known that FO can only express local properties. On the other hand, testers can explore only local neighbourhoods and hence locality is necessary for testability. We prove however, that the notion of locality imposed by being definable in FO is not sufficient for property testing. More precisely, we show that there is a non-testable property defined by an FO-sentence whose quantifier prefix contains only one quantifier alternation of the form "∀∃". We complement this by proving that every FO-sentence not containing a quantifier alternation of the form "∀∃" can be tested with a constant number of queries. We further identify some classes of FO-sentences which yield testable properties and contain quantifier alternations of the form "∀∃". These sentences express that the distribution of r-neighbourhood types is of a particular, simple form. We explore the connection between the notion of locality imposed by FO and the notion of locality necessary for testability further. We establish links between FO definability and a generalised notion of subgraph freeness. This notion was introduced in the context of character- ising one-sided error proximity oblivious testers, a particularly simple type of testers. Using a variation of our non-testable FO definable property we show that generalised subgraph freeness does equally not capture the locality needed for testability, which answers an open question regarding the characterisation of testable properties in the bounded degree model. Going beyond FO definability, we explore hardness of property testing problems in connec- tion with classical complexity theory. We obtain a deterministic construction of hard instances for property testing Hamiltonicity, which is a known non-testable property. This construc- tion is interesting from the perspective of exploring links between structural properties and non-testability. We further utilise the lower bound technique developed in the context of our non-testable FO definable property to prove non-testability of having treewidth logarithmic in the number of vertices.

Published

2021

11. Odd Chromatic Number of Graph Classes

Author

Belmonte, Rémy, primary, Harutyunyan, Ararat, additional, Köhler, Noleen, additional, and Melissinos, Nikolaos, additional

Published

2023

12. An Algorithmic Framework for Locally Constrained Homomorphisms

Author

Bulteau, Laurent, primary, Dabrowski, Konrad K., additional, Köhler, Noleen, additional, Ordyniak, Sebastian, additional, and Paulusma, Daniël, additional

Published

2022

13. ON TESTABILITY OF FIRST-ORDER PROPERTIES IN BOUNDED-DEGREE GRAPHS AND CONNECTIONS TO PROXIMITY-OBLIVIOUS TESTING.

Author

ADLER, ISOLDE, KÖHLER, NOLEEN, and PAN PENG

Subjects

*FIRST-order logic, *DENSE graphs, *SUFFIXES & prefixes (Grammar), *NEIGHBORHOODS, *ALGORITHMS

Abstract

We study property testing of properties that are definable in first-order logic (FO) in the bounded-degree graph and relational structure models. We show that any FO property that is defined by a formula with quantifier prefix ∃∗∀∗ is testable (i.e., testable with constant query complexity), while there exists an FO property that is expressible by a formula with quantifier prefix ∀∗∃∗ that is not testable. In the dense graph model, a similar picture is long known (Alon, Fischer, Krivelevich, Szegedy, Combinatorica 2000), despite the very different nature of the two models. In particular, we obtain our lower bound by an FO formula that defines a class of bounded-degree expanders, based on zig-zag products of graphs. We expect this to be of independent interest. We then use our class of FO definable bounded-degree expanders to answer a long-standing open problem for proximity-oblivious testers (POTs). POTs are a class of particularly simple testing algorithms, where a basic test is performed a number of times that may depend on the proximity parameter, but the basic test itself is independent of the proximity parameter. In their seminal work, Goldreich and Ron [STOC 2009; SICOMP 2011] show that the graph properties that are constant-query proximity-oblivious testable in the bounded-degree model are precisely the properties that can be expressed as a generalised subgraph freeness (GSF) property that satisfies the non-propagation condition. It is left open whether the non-propagation condition is necessary. We give a negative answer by showing that our property is a GSF property which is propagating. Hence in particular, our property does not admit a POT. For this result we establish a new connection between FO properties and GSF-local properties via neighbourhood profiles. [ABSTRACT FROM AUTHOR]

Published

2024

14. On Testability of First-Order Properties in Bounded-Degree Graphs

Author

Adler, Isolde, primary, Köhler, Noleen, additional, and Peng, Pan, additional

Published

2021

15. AN ALGORITHMIC FRAMEWORK FOR LOCALLY CONSTRAINED HOMOMORPHISMS.

Author

BULTEAU, LAURENT, DABROWSKI, KONRAD K., KÖHLER, NOLEEN, ORDYNIAK, SEBASTIAN, and PAULUSMA, DANIËL

Subjects

HOMOMORPHISMS, SOCIAL network theory, ASSIGNMENT problems (Programming), STATISTICAL decision making

Abstract

A homomorphism φ from a guest graph G to a host graph H is locally bijective, injective, or surjective if for every u ∈ V(G), the restriction of φ to the neighbourhood ofu is bijective, injective, or surjective, respectively. We prove a number of new FPT (fixed-parameter tractable), W[1]-hard, and paraNP-complete results for the corresponding decision problems LBHOM, LIHOM, and LSHOM by considering a hierarchy of parameters of the guest graph G. In this way we strengthen several existing results. For our FPT results, we develop a new algorithmic framework that involves a general ILP (integer linear program) model. We also use our framework to prove FPT results for the Role Assignment problem, which originates from social network theory and is closely related to locally surjective homomorphisms. [ABSTRACT FROM AUTHOR]

Published

2024

16. Twin-Width VIII: Delineation and Win-Wins

Author

Édouard Bonnet and Dibyayan Chakraborty and Eun Jung Kim and Noleen Köhler and Raul Lopes and Stéphan Thomassé, Bonnet, Édouard, Chakraborty, Dibyayan, Kim, Eun Jung, Köhler, Noleen, Lopes, Raul, Thomassé, Stéphan, Édouard Bonnet and Dibyayan Chakraborty and Eun Jung Kim and Noleen Köhler and Raul Lopes and Stéphan Thomassé, Bonnet, Édouard, Chakraborty, Dibyayan, Kim, Eun Jung, Köhler, Noleen, Lopes, Raul, and Thomassé, Stéphan

Abstract

We introduce the notion of delineation. A graph class C is said delineated by twin-width (or simply, delineated) if for every hereditary closure D of a subclass of C, it holds that D has bounded twin-width if and only if D is monadically dependent. An effective strengthening of delineation for a class C implies that tractable FO model checking on C is perfectly understood: On hereditary closures of subclasses D of C, FO model checking on D is fixed-parameter tractable (FPT) exactly when D has bounded twin-width. Ordered graphs [BGOdMSTT, STOC '22] and permutation graphs [BKTW, JACM '22] are effectively delineated, while subcubic graphs are not. On the one hand, we prove that interval graphs, and even, rooted directed path graphs are delineated. On the other hand, we observe or show that segment graphs, directed path graphs (with arbitrarily many roots), and visibility graphs of simple polygons are not delineated. In an effort to draw the delineation frontier between interval graphs (that are delineated) and axis-parallel two-lengthed segment graphs (that are not), we investigate the twin-width of restricted segment intersection classes. It was known that (triangle-free) pure axis-parallel unit segment graphs have unbounded twin-width [BGKTW, SODA '21]. We show that K_{t,t}-free segment graphs, and axis-parallel H_t-free unit segment graphs have bounded twin-width, where H_t is the half-graph or ladder of height t. In contrast, axis-parallel H₄-free two-lengthed segment graphs have unbounded twin-width. We leave as an open question whether unit segment graphs are delineated. More broadly, we explore which structures (large bicliques, half-graphs, or independent sets) are responsible for making the twin-width large on the main classes of intersection and visibility graphs. Our new results, combined with the FPT algorithm for first-order model checking on graphs given with O(1)-sequences [BKTW, JACM '22], give rise to a variety of algorithmic win-win arguments. They al

Published

2022

17. An explicit construction of graphs of bounded degree that are far from being Hamiltonian

Author

Adler, Isolde and Köhler, Noleen

Subjects

FOS: Computer and information sciences, Computer Science - Computational Complexity, Discrete Mathematics (cs.DM), General Computer Science, Computer Science - Data Structures and Algorithms, Discrete Mathematics and Combinatorics, Data Structures and Algorithms (cs.DS), G.2.2, Computational Complexity (cs.CC), Theoretical Computer Science, Computer Science - Discrete Mathematics

Abstract

Hamiltonian cycles in graphs were first studied in the 1850s. Since then, an impressive amount of research has been dedicated to identifying classes of graphs that allow Hamiltonian cycles, and to related questions. The corresponding decision problem, that asks whether a given graph is Hamiltonian (i.\,e.\ admits a Hamiltonian cycle), is one of Karp's famous NP-complete problems. In this paper we study graphs of bounded degree that are \emph{far} from being Hamiltonian, where a graph $G$ on $n$ vertices is \emph{far} from being Hamiltonian, if modifying a constant fraction of $n$ edges is necessary to make $G$ Hamiltonian. We give an explicit deterministic construction of a class of graphs of bounded degree that are locally Hamiltonian, but (globally) far from being Hamiltonian. Here, \emph{locally Hamiltonian} means that every subgraph induced by the neighbourhood of a small vertex set appears in some Hamiltonian graph. More precisely, we obtain graphs which differ in $\Theta(n)$ edges from any Hamiltonian graph, but non-Hamiltonicity cannot be detected in the neighbourhood of $o(n)$ vertices. Our class of graphs yields a class of hard instances for one-sided error property testers with linear query complexity. It is known that any property tester (even with two-sided error) requires a linear number of queries to test Hamiltonicity (Yoshida, Ito, 2010). This is proved via a randomised construction of hard instances. In contrast, our construction is deterministic. So far only very few deterministic constructions of hard instances for property testing are known. We believe that our construction may lead to future insights in graph theory and towards a characterisation of the properties that are testable in the bounded-degree model., Comment: 19 pages, 4 figures

Published

2022

18. An explicit construction of graphs of bounded degree that are far from being Hamiltonian

Author

Adler, Isolde, primary and Köhler, Noleen, additional

Published

2022

19. GSF-Locality Is Not Sufficient For Proximity-Oblivious Testing

Author

Isolde Adler and Noleen Köhler and Pan Peng, Adler, Isolde, Köhler, Noleen, Peng, Pan, Isolde Adler and Noleen Köhler and Pan Peng, Adler, Isolde, Köhler, Noleen, and Peng, Pan

Abstract

In Property Testing, proximity-oblivious testers (POTs) form a class of particularly simple testing algorithms, where a basic test is performed a number of times that may depend on the proximity parameter, but the basic test itself is independent of the proximity parameter. In their seminal work, Goldreich and Ron [STOC 2009; SICOMP 2011] show that the graph properties that allow constant-query proximity-oblivious testing in the bounded-degree model are precisely the properties that can be expressed as a generalised subgraph freeness (GSF) property that satisfies the non-propagation condition. It is left open whether the non-propagation condition is necessary. Indeed, calling properties expressible as a generalised subgraph freeness property GSF-local properties, they ask whether all GSF-local properties are non-propagating. We give a negative answer by exhibiting a property of graphs that is GSF-local and propagating. Hence in particular, our property does not admit a POT, despite being GSF-local. We prove our result by exploiting a recent work of the authors which constructed a first-order (FO) property that is not testable [SODA 2021], and a new connection between FO properties and GSF-local properties via neighbourhood profiles.

Published

2021

20. Odd chromatic number of graph classes.

Author

Belmonte, Rémy, Harutyunyan, Ararat, Köhler, Noleen, and Melissinos, Nikolaos

Subjects

*ODD numbers, *GRAPH connectivity, *SUBGRAPHS, *INTEGERS

Abstract

A graph is called odd (respectively, even) if every vertex has odd (respectively, even) degree. Gallai proved that every graph can be partitioned into two even induced subgraphs, or into an odd and an even induced subgraph. We refer to a partition into odd subgraphs as an odd colouring of G $G$. Scott proved that a connected graph admits an odd colouring if and only if it has an even number of vertices. We say that a graph G $G$ is k $k$‐odd colourable if it can be partitioned into at most k $k$ odd induced subgraphs. The odd chromatic number of G $G$, denoted by χ odd( G ) ${\chi }_{\text{odd}}(G)$, is the minimum integer k $k$ for which G $G$ is k $k$‐odd colourable. We initiate the systematic study of odd colouring and odd chromatic number of graph classes. We first consider a question due to Scott, which states that every graph G $G$ of even order n $n$ has χ odd( G ) ≤ c n ${\chi }_{\text{odd}}(G)\le c\sqrt{n}$, for some positive constant c $c$, by proving that this is indeed the case if G $G$ is restricted to having girth at least seven. We also show that any graph G $G$ whose all components have even order satisfies χ odd( G ) ≤ 2 Δ − 1 ${\chi }_{\text{odd}}(G)\le 2{\rm{\Delta }}-1$, where Δ ${\rm{\Delta }}$ is the maximum degree of G $G$. Next, we show that certain interesting classes have bounded odd chromatic number. Our main results in this direction are that interval graphs, graphs of bounded modular‐width all have bounded odd chromatic number. In particular, every even interval graph is 6‐odd colourable, and every even graph is 3 m w $3mw$‐odd colourable, where m w $mw$ is the modular width of a graph. [ABSTRACT FROM AUTHOR]

Published

2024