Your search keyword '"Wiederrecht, Sebastian"' showing total 112 results

1. Bounds on treewidth via excluding disjoint unions of cycles

Author

Hatzel, Meike, Liu, Chun-Hung, Reed, Bruce, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics

Abstract

One of the fundamental results in graph minor theory is that for every planar graph~$H$, there is a minimum integer~$f(H)$ such that graphs with no minor isomorphic to~$H$ have treewidth at most~$f(H)$. The best known bound for an arbitrary planar $H$ is ${O(|V(H)|^9\operatorname{poly~log} |V(H)|)}$. We show that if $H$ is the disjoint union of cycles, then $f(H)$ is $O(|V(H)|\log^2 |V(H)|)$, which is a $\log|V(H)|$ factor away being optimal.

Published

2025

2. Twin-width one

Author

Ahn, Jungho, Jacob, Hugo, Köhler, Noleen, Paul, Christophe, Reinald, Amadeus, and Wiederrecht, Sebastian

Subjects

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

Abstract

We investigate the structure of graphs of twin-width at most $1$, and obtain the following results: - Graphs of twin-width at most $1$ are permutation graphs. In particular they have an intersection model and a linear structure. - There is always a $1$-contraction sequence closely following a given permutation diagram. - Based on a recursive decomposition theorem, we obtain a simple algorithm running in linear time that produces a $1$-contraction sequence of a graph, or guarantees that it has twin-width more than $1$. - We characterise distance-hereditary graphs based on their twin-width and deduce a linear time algorithm to compute optimal sequences on this class of graphs., Comment: Accepted to STACS 2025

Published

2025

3. Generating strongly 2-connected digraphs

Author

Hatzel, Meike, Kreutzer, Stephan, Protopapas, Evangelos, Reich, Florian, Stamoulis, Giannos, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, 05C20, 05C75

Abstract

We prove that there exist four operations such that given any two strongly $2$-connected digraphs $H$ and $D$ where $H$ is a butterfly-minor of $D$, there exists a sequence $D_0,\dots, D_n$ where $D_0=H$, $D_n=D$ and for every $0\leq i\leq n-1$, $D_i$ is a strongly $2$-connected butterfly-minor of $D_{i+1}$ which is obtained by a single application of one of the four operations. As a consequence of this theorem, we obtain that every strongly $2$-connected digraph can be generated from a concise family of strongly $2$-connected digraphs by using these four operations., Comment: 42 pages

Published

2024

4. Matching minors in bipartite graphs

Author

Wiederrecht, Sebastian

Subjects

matching minor, structural graph theory, bipartite, perfect matching, bic Book Industry Communication::U Computing & information technology::UM Computer programming / software development::UMB Algorithms & data structures

Abstract

In this thesis we adapt fundamental parts of the Graph Minors series of Robertson and Seymour for the study of matching minors and investigate a connection to the study of directed graphs. We develope matching theoretic to established results of graph minor theory: We characterise the existence of a cross over a conformal cycle by means of a topological property. Furthermore, we develope a theory for perfect matching width, a width parameter for graphs with perfect matchings introduced by Norin. here we show that the disjoint alternating paths problem can be solved in polynomial time on graphs of bounded width. Moreover, we show that every bipartite graph with high perfect matching width must contain a large grid as a matching minor. Finally, we prove an analogue of the we known Flat Wall theorem and provide a qualitative description of all bipartite graphs which exclude a fixed matching minor.

Published

2022

5. Treewidth, Hadwiger Number, and Induced Minors

Author

Campbell, Rutger, Davies, James, Distel, Marc, Frederickson, Bryce, Gollin, J. Pascal, Hendrey, Kevin, Hickingbotham, Robert, Wiederrecht, Sebastian, Wood, David R., and Yepremyan, Liana

Subjects

Mathematics - Combinatorics, 05C99, G.2.2

Abstract

Treewidth and Hadwiger number are two of the most important parameters in structural graph theory. This paper studies graph classes in which large treewidth implies the existence of a large complete graph minor. To formalise this, we say that a graph class $\mathcal{G}$ is (tw,had)-bounded if there is a function $f$ (called the (tw,had)-bounding function) such that tw$(G)$ $\leq$ $f$(had$(G)$) for every graph $G \in \mathcal{G}$. We characterise (tw,had)-bounded graph classes as those that exclude some planar graph as an induced minor, and use this characterisation to show that every proper vertex-minor-closed class is (tw,had)-bounded. Furthermore, we demonstrate that any (tw,had)-bounded graph class has a (tw,had)-bounding function in O(had$(G)^9$polylog(had$(G)$)). Our bound comes from the bound for the Grid Minor Theorem given by Chuzhoy and Tan, and any quantitative improvement to their result will lead directly to an improvement to our result. More strongly, we conjecture that every (tw,had)-bounded graph class has a linear (tw,had)-bounding function. In support of this conjecture, we show that it holds for the class of outer-string graphs, and for a natural generalisation of outer-string graphs: intersection graphs of strings rooted at the boundary of a fixed surface. We also verify our conjecture for low-rank perturbations of circle graphs, which is an important step towards verifying it for all proper vertex-minor-closed classes., Comment: 26 pages, 6 Figures

Published

2024

6. A note on the 2-Factor Hamiltonicity Conjecture

Author

Gorsky, Maximilian, Johanni, Theresa, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, 05C38, 05C45, 05C70, 05C75, G.2.2

Abstract

The 2-factor Hamiltonicity Conjecture by Funk, Jackson, Labbate, and Sheehan [JCTB, 2003] asserts that all cubic, bipartite graphs in which all 2-factors are Hamiltonian cycles can be built using a simple operation starting from $K_{3,3}$ and the Heawood graph. We discuss the link between this conjecture and matching theory, in particular by showing that this conjecture is equivalent to the statement that the two exceptional graphs in the conjecture are the only 2-factor Hamiltonian, cubic braces, where braces are connected, bipartite graphs in which every matching of size at most two is contained in a perfect matching. In the context of matching theory this conjecture is especially noteworthy as $K_{3,3}$ and the Heawood graph are both strongly tied to the important class of Pfaffian graphs, with $K_{3,3}$ being the canonical non-Pfaffian graph and the Heawood graph being one of the most noteworthy Pfaffian graphs. Our main contribution is a proof that the Heawood graph is the only 2-factor Hamiltonian, Pfaffian, cubic brace. This is shown by establishing that, aside from the Heawood graph, all Pfaffian braces contain a cycle of length four, which may be of independent interest., Comment: 17 pages, 6 figures, added an independent proof of the reduction of the conjecture to braces and an appendix on the behaviour of the star product in v2

Published

2024

7. Obstructions to Erd\H{o}s-P\'osa Dualities for Minors

Author

Paul, Christophe, Protopapas, Evangelos, Thilikos, Dimitrios M., and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Data Structures and Algorithms, 05C83, 05C85, 05C10, 05C75, 68R10, G.2.2

Abstract

Let ${\cal G}$ and ${\cal H}$ be minor-closed graph classes. The pair $({\cal H},{\cal G})$ is an Erd\H{o}s-P\'osa pair (EP-pair) if there is a function $f$ where, for every $k$ and every $G\in{\cal G},$ either $G$ has $k$ pairwise vertex-disjoint subgraphs not belonging to ${\cal H},$ or there is a set $S\subseteq V(G)$ where $|S|\leq f(k)$ and $G-S\in{\cal H}.$ The classic result of Erd\H{o}s and P\'osa says that if $\mathcal{F}$ is the class of forests, then $({\cal F},{\cal G})$ is an EP-pair for every ${\cal G}$. The class ${\cal G}$ is an EP-counterexample for ${\cal H}$ if ${\cal G}$ is minimal with the property that $({\cal H},{\cal G})$ is not an EP-pair. We prove that for every ${\cal H}$ the set $\mathfrak{C}_{\cal H}$ of all EP-counterexamples for ${\cal H}$ is finite. In particular, we provide a complete characterization of $\mathfrak{C}_{\cal H}$ for every ${\cal H}$ and give a constructive upper bound on its size. Each class ${\cal G}\in \mathfrak{C}_{\cal H}$ can be described as all minors of a sequence of grid-like graphs $\langle \mathscr{W}_{k} \rangle_{k\in \mathbb{N}}.$ Moreover, each $\mathscr{W}_{k}$ admits a half-integral packing: $k$ copies of some $H\not\in{\cal H}$ where no vertex is used more than twice. This gives a complete delineation of the half-integrality threshold of the Erd\H{o}s-P\'osa property for minors and yields a constructive proof of Thomas' conjecture on the half-integral Erd\H{o}s-P\'osa property for minors (recently confirmed, non-constructively, by Liu). Let $h$ be the maximum size of a graph in ${\cal H}.$ For every class ${\cal H},$ we construct an algorithm that, given a graph $G$ and a $k,$ either outputs a half-integral packing of $k$ copies of some $H \not\in {\cal H}$ or outputs a set of at most ${2^{k^{\cal O}_h(1)}}$ vertices whose deletion creates a graph in ${\cal H}$ in time $2^{2^{k^{{\cal O}_h(1)}}}\cdot |G|^4\log |G|.$, Comment: Accepted to FOCS 2024

Published

2024

8. Delineating Half-Integrality of the Erd\H{o}s-P\'osa Property for Minors: the Case of Surfaces

Author

Paul, Christophe, Protopapas, Evangelos, Thilikos, Dimitrios M., and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C83, 05C75, 05C10, 05C85, 68R10, G.2.2

Abstract

In 1986 Robertson and Seymour proved a generalization of the seminal result of Erd\H{o}s and P\'osa on the duality of packing and covering cycles: A graph has the Erd\H{o}s-P\'osa property for minors if and only if it is planar. In particular, for every non-planar graph $H$ they gave examples showing that the Erd\H{o}s-P\'osa property does not hold for $H.$ Recently, Liu confirmed a conjecture of Thomas and showed that every graph has the half-integral Erd\H{o}s-P\'osa property for minors. Liu's proof is non-constructive and to this date, with the exception of a small number of examples, no constructive proof is known. In this paper, we initiate the delineation of the half-integrality of the Erd\H{o}s-P\'osa property for minors. We conjecture that for every graph $H,$ there exists a unique (up to a suitable equivalence relation) graph parameter ${\textsf{EP}}_H$ such that $H$ has the Erd\H{o}s-P\'osa property in a minor-closed graph class $\mathcal{G}$ if and only if $\sup\{\textsf{EP}_H(G) \mid G\in\mathcal{G}\}$ is finite. We prove this conjecture for the class $\mathcal{H}$ of Kuratowski-connected shallow-vortex minors by showing that, for every non-planar $H\in\mathcal{H},$ the parameter ${\sf EP}_H(G)$ is precisely the maximum order of a Robertson-Seymour counterexample to the Erd\H{o}s-P\'osa property of $H$ which can be found as a minor in $G.$ Our results are constructive and imply, for the first time, parameterized algorithms that find either a packing, or a cover, or one of the Robertson-Seymour counterexamples, certifying the existence of a half-integral packing for the graphs in $\mathcal{H}.$

Published

2024

9. Unavoidable induced subgraphs in graphs with complete bipartite induced minors

Author

Chudnovsky, Maria, Hatzel, Meike, Korhonen, Tuukka, Trotignon, Nicolas, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C75, 05C85, G.2.2

Abstract

We prove that if a graph contains the complete bipartite graph $K_{134, 12}$ as an induced minor, then it contains a cycle of length at most~12 or a theta as an induced subgraph. With a longer and more technical proof, we prove that if a graph contains $K_{3, 4}$ as an induced minor, then it contains a triangle or a theta as an induced subgraph. Here, a \emph{theta} is a graph made of three internally vertex-disjoint chordless paths $P_1 = a \dots b$, $P_2 = a \dots b$, $P_3 = a \dots b$, each of length at least two, such that no edges exist between the paths except the three edges incident to $a$ and the three edges incident to $b$. A consequence is that excluding a grid and a complete bipartite graph as induced minors is not enough to guarantee a bounded tree-independence number, or even that the treewidth is bounded by a function of the size of the maximum clique, because the existence of graphs with large treewidth that contain no triangles or thetas as induced subgraphs is already known (the so-called layered wheels)., Comment: 25 pages, 12 figures

Published

2024

10. Approximating Branchwidth on Parametric Extensions of Planarity

Author

Thilikos, Dimitrios M., Wiederrecht, Sebastian, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Kráľ, Daniel, editor, and Milanič, Martin, editor

Published

2025

11. Treewidth versus clique number. IV. Tree-independence number of graphs excluding an induced star

Author

Dallard, Clément, Krnc, Matjaž, Kwon, O-joung, Milanič, Martin, Munaro, Andrea, Štorgel, Kenny, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms, 05C75 (Primary), 05C69, 05C76, 05C85 (Secondary)

Abstract

Many recent works address the question of characterizing induced obstructions to bounded treewidth. In 2022, Lozin and Razgon completely answered this question for graph classes defined by finitely many forbidden induced subgraphs. Their result also implies a characterization of graph classes defined by finitely many forbidden induced subgraphs that are $(tw,\omega)$-bounded, that is, treewidth can only be large due to the presence of a large clique. This condition is known to be satisfied for any graph class with bounded tree-independence number, a graph parameter introduced independently by Yolov in 2018 and by Dallard, Milani\v{c}, and \v{S}torgel in 2024. Dallard et al. conjectured that $(tw,\omega)$-boundedness is actually equivalent to bounded tree-independence number. We address this conjecture in the context of graph classes defined by finitely many forbidden induced subgraphs and prove it for the case of graph classes excluding an induced star. We also prove it for subclasses of the class of line graphs, determine the exact values of the tree-independence numbers of line graphs of complete graphs and line graphs of complete bipartite graphs, and characterize the tree-independence number of $P_4$-free graphs, which implies a linear-time algorithm for its computation. Applying the algorithmic framework provided in a previous paper of the series leads to polynomial-time algorithms for the Maximum Weight Independent Set problem in an infinite family of graph classes., Comment: 26 pages

Published

2024

12. Packing even directed circuits quarter-integrally

Author

Gorsky, Maximilian, Kawarabayashi, Ken-ichi, Kreutzer, Stephan, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C20, 05C38, 05C83, 05C85, 68R10, G.2.2

Abstract

We prove the existence of a computable function $f\colon\mathbb{N}\to\mathbb{N}$ such that for every integer $k$ and every digraph $D$ either contains a collection $\mathcal{C}$ of $k$ directed cycles of even length such that no vertex of $D$ belongs to more than four cycles in $\mathcal{C}$, or there exists a set $S\subseteq V(D)$ of size at most $f(k)$ such that $D-S$ has no directed cycle of even length. Moreover, we provide an algorithm that finds one of the two outcomes of this statement in time $g(k)n^{\mathcal{O}(1)}$ for some computable function $g\colon \mathbb{N}\to\mathbb{N}$. Our result unites two deep fields of research from the algorithmic theory for digraphs: The study of the Erd\H{o}s-P\'osa property of digraphs and the study of the Even Dicycle Problem. The latter is the decision problem which asks if a given digraph contains an even dicycle and can be traced back to a question of P\'olya from 1913. It remained open until a polynomial time algorithm was finally found by Robertson, Seymour, and Thomas (Ann. of Math. (2) 1999) and, independently, McCuaig (Electron. J. Combin. 2004; announced jointly at STOC 1997). The Even Dicycle Problem is equivalent to the recognition problem of Pfaffian bipartite graphs and has applications even beyond discrete mathematics and theoretical computer science. On the other hand, Younger's Conjecture (1973), states that dicycles have the Erd\H{o}s-P\'osa property. The conjecture was proven more than two decades later by Reed, Robertson, Seymour, and Thomas (Combinatorica 1996) and opened the path for structural digraph theory as well as the algorithmic study of the directed feedback vertex set problem. Our approach builds upon the techniques used to resolve both problems and combines them into a powerful structural theorem that yields further algorithmic applications for other prominent problems., Comment: 144 pages, 13 figures

Published

2023

13. Excluding Surfaces as Minors in Graphs

Author

Thilikos, Dimitrios M. and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, 05C10, 05C83, 05C75, 68R10, G.2.2

Abstract

The Graph Minors Structure Theorem (GMST) of Robertson and Seymour states that for every graph $H,$ any $H$-minor-free graph $G$ has a tree-decomposition of bounded adhesion such that the torso of every bag embeds in a surface $\Sigma$ where $H$ does not embed after removing a small number of apex vertices and confining some vertices into a bounded number of bounded depth vortices. However, the functions involved in the original form of this statement were not explicit. In an enormous effort Kawarabayashi, Thomas, and Wollan proved a similar statement with explicit (and single-exponential in $|V(H)|$) bounds. However, their proof replaces the statement ``a surface where $H$ does not embed'' with `` a surface of Euler-genus in $\mathcal{O}(|H|^2)$''. In this paper we close this gap and prove that the bounds of Kawarabayashi, Thomas, and Wollan can be achieved with a tight bound on the Euler-genus. Moreover, we provide a more refined version of the GMST focussed exclusively on excluding, instead of a single graph, grid-like graphs that are minor-universal for a given set of surfaces. This allows us to give a description, in the style of Robertson and Seymour, of graphs excluding a graph of fixed Euler-genus as a minor, rather than focussing on the size of the graph., Comment: We split the article into two volumes. The first volume, concerned with extracting surfaces from the GMST, has become the new version of this article, while the second volume will be a different upload. arXiv admin note: text overlap with arXiv:2304.04517

Published

2023

14. Approximating branchwidth on parametric extensions of planarity

Author

Thilikos, Dimitrios M. and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C83, 05C85, 05C75, 68R10, 68Q27, G.2.2

Abstract

The branchwidth of a graph has been introduced by Roberson and Seymour as a measure of the tree-decomposability of a graph, alternative to treewidth. Branchwidth is polynomially computable on planar graphs by the celebrated ``Ratcatcher''-algorithm of Seymour and Thomas. We investigate an extension of this algorithm to minor-closed graph classes, further than planar graphs, as follows: Let $H_{1}$ be a graph embeddable in the torus and $H_{2}$ be a graph embeddable in the projective plane. We prove that every $\{H_{1},H_{2}\}$-minor free graph $G$ contains a subgraph $G'$ where the difference between the branchwidth of $G$ and the branchwidth of $G'$ is bounded by some constant, depending only on $H_{1}$ and $H_{2}$. Moreover, the graph $G'$ admits a tree decomposition where all torsos are planar. This decomposition can be used for deriving a constant-additive approximation for branchwidth: For $\{H_{1},H_{2}\}$-minor free graphs, there is a constant $c$ (depending on $H_{1}$ and $H_{2}$) and an $\Ocal(|V(G)|^{3})$-time algorithm that, given a graph $G$, outputs a value $b$ such that the branchwidth of $G$ is between $b$ and $b+c$., Comment: Accepted to WG 2024

Published

2023

15. Structure and algorithms for graphs excluding grids with small parity breaks as odd-minors

Author

Gollin, J. Pascal and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C83, 05C85, 05C75, 68R10, 68Q27

Abstract

We investigate a structural generalisation of treewidth we call $\mathcal{A}$-blind-treewidth where $\mathcal{A}$ denotes an annotated graph class. This width parameter is defined by evaluating only the size of those bags $B$ of tree-decompositions for a graph $G$ where ${(G,B) \notin \mathcal{A}}$. For the two cases where $\mathcal{A}$ is (i) the class $\mathcal{B}$ of all pairs ${(G,X)}$ such that no odd cycle in $G$ contains more than one vertex of ${X \subseteq V(G)}$ and (ii) the class $\mathcal{B}$ together with the class $\mathcal{P}$ of all pairs ${(G,X)}$ such that the "torso" of $X$ in $G$ is planar. For both classes, $\mathcal{B}$ and ${\mathcal{B} \cup \mathcal{P}}$, we obtain analogues of the Grid Theorem by Robertson and Seymour and FPT-algorithms that either compute decompositions of small width or correctly determine that the width of a given graph is large. Moreover, we present FPT-algorithms for Maximum Independent Set on graphs of bounded $\mathcal{B}$-blind-treewidth and Maximum Cut on graphs of bounded ${(\mathcal{B}\cup\mathcal{P})}$-blind-treewidth.

Published

2023

16. Excluding Single-Crossing Matching Minors in Bipartite Graphs

Author

Giannopoulou, Archontia C., Thilikos, Dimitrios M., and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Data Structures and Algorithms, 05C83, 05C85, 68R05, 68R10, F.2.2, G.2.2

Abstract

\noindent By a seminal result of Valiant, computing the permanent of $(0,1)$-matrices is, in general, $\#\mathsf{P}$-hard. In 1913 P\'olya asked for which $(0,1)$-matrices $A$ it is possible to change some signs such that the permanent of $A$ equals the determinant of the resulting matrix. In 1975, Little showed these matrices to be exactly the biadjacency matrices of bipartite graphs excluding $K_{3,3}$ as a \{matching minor}. This was turned into a polynomial time algorithm by McCuaig, Robertson, Seymour, and Thomas in 1999. However, the relation between the exclusion of some matching minor in a bipartite graph and the tractability of the permanent extends beyond $K_{3,3}.$ Recently it was shown that the exclusion of any planar bipartite graph as a matching minor yields a class of bipartite graphs on which the {permanent} of the corresponding $(0,1)$-matrices can be computed efficiently. In this paper we unify the two results above into a single, more general result in the style of the celebrated structure theorem for single-crossing-minor-free graphs. We identify a class of bipartite graphs strictly generalising planar bipartite graphs and $K_{3,3}$ which includes infinitely many non-Pfaffian graphs. The exclusion of any member of this class as a matching minor yields a structure that allows for the efficient evaluation of the permanent. Moreover, we show that the evaluation of the permanent remains $\#\mathsf{P}$-hard on bipartite graphs which exclude $K_{5,5}$ as a matching minor. This establishes a first computational lower bound for the problem of counting perfect matchings on matching minor closed classes., Comment: Accepted in SODA 2023

Published

2022

17. Kernelization for Graph Packing Problems via Rainbow Matching

Author

Bessy, Stéphane, Bougeret, Marin, Thilikos, Dimitrios M., and Wiederrecht, Sebastian

Subjects

Computer Science - Data Structures and Algorithms, 05C35, 05C83, 05C85, 68R10, 68W25, F.2.2, G.2.2

Abstract

We introduce a new kernelization tool, called rainbow matching technique}, that is appropriate for the design of polynomial kernels for packing problems and their hitting counterparts. Our technique capitalizes on the powerful combinatorial results of [Graf, Harris, Haxell, SODA 2021]. We apply the rainbow matching technique on four (di)graph packing or hitting problems, namely the Triangle-Packing in Tournament problem (TPT), where we ask for a packing of $k$ directed triangles in a tournament, Directed Feedback Vertex Set in Tournament problem (FVST), where we ask for a (hitting) set of at most $k$ vertices which intersects all triangles of a tournament, the Induced 2-Path-Packing (IPP) where we ask for a packing of $k$ induced paths of length two in a graph and Induced 2-Path Hitting Set problem (IPHS), where we ask for a (hitting) set of at most $k$ vertices which intersects all induced paths of length two in a graph. The existence of a sub-quadratic kernels for these problems was proven for the first time in [Fomin, Le, Lokshtanov, Saurabh, Thomass\'e, Zehavi. ACM Trans. Algorithms, 2019], where they gave a kernel of $O(k^{3/2})$ vertices for the two first problems and $O(k^{5/3})$ vertices for the two last. In the same paper it was questioned whether these bounds can be (optimally) improved to linear ones. Motivated by this question, we apply the rainbow matching technique and prove that TPT and FVST admit (almost linear) kernels of $k^{1+\frac{O(1)}{\sqrt{\log{k}}}}$ vertices and that IPP and IPHS admit kernels of $O(k)$ vertices., Comment: Accepted to SODA 2023

Published

2022

18. Killing a Vortex

Author

Thilikos, Dimitrios M. and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms, 05C83, 05C85, 68R05, 68R10, G.2.2, G.2.1

Abstract

The Graph Minors Structure Theorem of Robertson and Seymour asserts that, for every graph $H,$ every $H$-minor-free graph can be obtained by clique-sums of ``almost embeddable'' graphs. Here a graph is ``almost embeddable'' if it can be obtained from a graph of bounded Euler-genus by pasting graphs of bounded pathwidth in an ``orderly fashion'' into a bounded number of faces, called the \textit{vortices}, and then adding a bounded number of additional vertices, called \textit{apices}, with arbitrary neighborhoods. Our main result is a {full classification} of all graphs $H$ for which the use of vortices in the theorem above can be avoided. To this end we identify a (parametric) graph $\mathscr{S}_{t}$ and prove that all $\mathscr{S}_{t}$-minor-free graphs can be obtained by clique-sums of graphs embeddable in a surface of bounded Euler-genus after deleting a bounded number of vertices. We show that this result is tight in the sense that the appearance of vortices cannot be avoided for $H$-minor-free graphs, whenever $H$ is not a minor of $\mathscr{S}_{t}$ for some $t\in\mathbb{N}.$ Using our new structure theorem, we design an algorithm that, given an $\mathscr{S}_{t}$-minor-free graph $G,$ computes the generating function of all perfect matchings of $G$ in polynomial time. Our results, combined with known complexity results, imply a complete characterization of minor-closed graph classes where the number of perfect matchings is polynomially computable: They are exactly those graph classes that do not contain every $\mathscr{S}_{t}$ as a minor. This provides a \textit{sharp} complexity dichotomy for the problem of counting perfect matchings in minor-closed classes., Comment: An earlier version of this paper has appeared at FOCS 2022 We also changed the term "vga-hierarchy" with the more appropriate term "vga-lattice". arXiv admin note: text overlap with arXiv:2010.12397 by other authors

Published

2022

19. Matching Theory and Barnette's Conjecture

Author

Gorsky, Maximilian, Steiner, Raphael, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C10, 68R10, 05C45, 05C70, G.2.2, F.2.2

Abstract

Barnette's Conjecture claims that all cubic, 3-connected, planar, bipartite graphs are Hamiltonian. We give a translation of this conjecture into the matching-theoretic setting. This allows us to relax the requirement of planarity to give the equivalent conjecture that all cubic, 3-connected, Pfaffian, bipartite graphs are Hamiltonian. A graph, other than the path of length three, is a brace if it is bipartite and any two disjoint edges are part of a perfect matching. Our perspective allows us to observe that Barnette's Conjecture can be reduced to cubic, planar braces. We show a similar reduction to braces for cubic, 3-connected, bipartite graphs regarding four stronger versions of Hamiltonicity. Note that in these cases we do not need planarity. As a practical application of these results, we provide some supplements to a generation procedure for cubic, 3-connected, planar, bipartite graphs discovered by Holton et al. [Hamiltonian Cycles in Cubic 3-Connected Bipartite Planar Graphs, JCTB, 1985]. These allow us to check whether a graph we generated is a brace., Comment: 26 pages, 5 figures, v3 includes the answer to a question posed in v1 and v2

Published

2022

20. Killing a Vortex.

Author

Thilikos, Dimitrios M. and Wiederrecht, Sebastian

Subjects

POLYNOMIAL time algorithms, GRAPH algorithms, GENERATING functions, MINORS, COUNTING, BIPARTITE graphs

Abstract

The Graph Minors Structure Theorem of Robertson and Seymour asserts that, for every graph H, every H-minor-free graph can be obtained by clique-sums of "almost embeddable" graphs. Here a graph is "almost embeddable" if it can be obtained from a graph of bounded Euler-genus by pasting graphs of bounded pathwidth in an "orderly fashion" into a bounded number of faces, called the vortices, and then adding a bounded number of additional vertices, called apices, with arbitrary neighborhoods. Our main result is a full classification of all graphs H for which the use of vortices in the theorem above can be avoided. To this end, we identify a (parametric) graph \(\mathscr{S}_{t}\) and prove that all \(\mathscr{S}_{t}\) -minor-free graphs can be obtained by clique-sums of graphs embeddable in a surface of bounded Euler-genus after deleting a bounded number of vertices. We show that this result is tight in the sense that the appearance of vortices cannot be avoided for H-minor-free graphs, whenever H is not a minor of \(\mathscr{S}_{t}\) for some \(t\in \mathbb {N}\). Using our new structure theorem, we design an algorithm that, given an \(\mathscr{S}_{t}\) -minor-free graph G, computes the generating function of all perfect matchings of G in polynomial time. Our results, combined with known complexity results, imply a complete characterization of minor-closed graph classes where the number of perfect matchings is polynomially computable: They are exactly those graph classes that do not contain every \(\mathscr{S}_{t}\) as a minor. This provides a sharp complexity dichotomy for the problem of counting perfect matchings in minor-closed classes. [ABSTRACT FROM AUTHOR]

Published

2024

21. A Flat Wall Theorem for Matching Minors in Bipartite Graphs

Author

Giannopoulou, Archontia C. and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C20, 05C75, 05C83, G.2.2

Abstract

A major step in the graph minors theory of Robertson and Seymour is the transition from the Grid Theorem which, in some sense uniquely, describes areas of large treewidth within a graph, to a notion of local flatness of these areas in form of the existence of a large flat wall within any huge grid of an H-minor free graph. In this paper, we prove a matching theoretic analogue of the Flat Wall Theorem for bipartite graphs excluding a fixed matching minor. Our result builds on a a tight relationship between structural digraph theory and matching theory and allows us to deduce a Flat Wall Theorem for digraphs which substantially differs from a previously established directed variant of this theorem.

Published

2021

22. Two Disjoint Alternating Paths in Bipartite Graphs

Author

Giannopoulou, Archontia C. and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C10, 05C38, 05C83, F.2.2

Abstract

A bipartite graph B is called a brace if it is connected and every matching of size at most two in B is contained in some perfect matching of B and a cycle C in B is called conformal if B-V(C) has a perfect matching. We show that there do not exist two disjoint alternating paths that form a cross over a conformal cycle C in a brace B if and only if one can reduce B, by an application of a matching theoretic analogue of small clique sums, to a planar brace H in which C bounds a face. We then utilise this result and provide a polynomial time algorithm which solves the 2-linkage problem for alternating paths in bipartite graphs with perfect matchings.

Published

2021

23. Excluding a Planar Matching Minor in Bipartite Graphs

Author

Giannopoulou, Archontia C, Kreutzer, Stephan, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics

Abstract

Matching minors are a specialisation of minors fit for the study of graph with perfect matchings. The notion of matching minors has been used to give a structural description of bipartite graphs on which the number of perfect matchings can becomputed efficiently, based on a result of Little, by McCuaig et al. in 1999.In this paper we generalise basic ideas from the graph minor series by Robertson and Seymour to the setting of bipartite graphs with perfect matchings. We introducea version of Erdos-Posa property for matching minors and find a direct link between this property and planarity. From this, it follows that a class of bipartite graphs withperfect matchings has bounded perfect matching width if and only if it excludes aplanar matching minor. We also present algorithms for bipartite graphs of bounded perfect matching width for a matching version of the disjoint paths problem, matching minor containment, and for counting the number of perfect matchings. From our structural results, we obtain that recognising whether a bipartite graphGcontains afixed planar graphHas a matching minor, and that counting the number of perfect matchings of a bipartite graph that excludes a fixed planar graph as a matching minor are both polynomial time solvable.

Published

2021

24. Even circuits in oriented matroids

Author

Heuer, Karl, Steiner, Raphael, and Wiederrecht, Sebastian

Subjects

Oriented matroids, circuits, even cycle problem, regular matroids

Abstract

In this paper we generalise the even directed cycle problem, which asks whether a given digraph contains a directed cycle of even length, to orientations of regular matroids. We define non-even oriented matroids generalising non-even digraphs, which played a central role in resolving the computational complexity of the even dicycle problem. Then we show that the problem of detecting an even directed circuit in a regular matroid is polynomially equivalent to the recognition of non-even oriented matroids. Our main result is a precise characterisation of the class of non-even oriented cographic matroids in terms of forbidden minors, which complements an existing characterisation of non-even oriented graphic matroids by Seymour and Thomassen.Mathematics Subject Classifications: 05B35, 05C20, 05C70, 05C75, 05C83, 05C85, 52C40

Published

2022

25. Even Circuits in Oriented Matroids

Author

Heuer, Karl, Steiner, Raphael, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05B35, 05C20, 05C70, 05C75, 05C83, 05C85, 52C40

Abstract

In this paper we generalise the even directed cycle problem, which asks whether a given digraph contains a directed cycle of even length, to orientations of regular matroids. We define non-even oriented matroids generalising non-even digraphs, which played a central role in resolving the computational complexity of the even dicycle problem. Then we show that the problem of detecting an even directed circuit in a regular matroid is polynomially equivalent to the recognition of non-even oriented matroids. Our main result is a precise characterisation of the class of non-even oriented bond matroids in terms of forbidden minors, which complements an existing characterisation of non-even oriented graphic matroids by Seymour and Thomassen., Comment: 30 pages, no figures

Published

2020

26. Excluding a planar matching minor in bipartite graphs

Author

Giannopoulou, Archontia C., Kreutzer, Stephan, and Wiederrecht, Sebastian

Published

2024

27. A Note on Directed Treewidth

Author

Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C20, 05C65, 05C75, 05C83

Abstract

We characterise digraphs of directed treewidth one in terms of forbidden butterfly minors. Moreover, we show that there is a linear relation between the hypertree-width of the dual of the cycle hypergraph of D, i. e. the hypergraph with vertices V (D) where every hyperedge corresponds to a directed cycle in D, and the directed treewidth of D. Based on this we show that a digraph has directed treewidth one if and only if its cycle hypergraph is a hypertree.

Published

2019

28. Parametrised Algorithms for Directed Modular Width

Author

Steiner, Raphael and Wiederrecht, Sebastian

Subjects

Computer Science - Discrete Mathematics, Mathematics - Combinatorics, 05C85, 05C20, 68R05

Abstract

Many well-known NP-hard algorithmic problems on directed graphs resist efficient parametrisations with most known width measures for directed graphs, such as directed treewidth, DAG-width, Kelly-width and many others. While these focus on measuring how close a digraph is to an oriented tree resp. a directed acyclic graph, in this paper, we investigate directed modular width as a parameter, which is closer to the concept of clique-width. We investigate applications of modular decompositions of directed graphs to a wide range of algorithmic problems and derive FPT-algorithms for several well-known digraph-specific NP-hard problems, namely minimum (weight) directed feedback vertex set, minimum (weight) directed dominating set, digraph colouring, directed Hamiltonian path/cycle, partitioning into paths, (capacitated) vertex-disjoint directed paths, and the directed subgraph homeomorphism problem. The latter yields a polynomial-time algorithm for detecting topological minors in digraphs of bounded directed modular width. Finally we illustrate that also other structural digraph parameters, such as the directed pathwidth and the cycle-rank can be computed efficiently using directed modular width as a parameter., Comment: 69 pages, 3 figures

Published

2019

29. Colouring Non-Even Digraphs

Author

Millani, Marcelo Garlet, Steiner, Raphael, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C15, 05C20, 05C38, 05C75, 05C83

Abstract

A colouring of a digraph as defined by Erdos and Neumann-Lara in 1980 is a vertex-colouring such that no monochromatic directed cycles exist. The minimal number of colours required for such a colouring of a loopless digraph is defined to be its dichromatic number. This quantity has been widely studied in the last decades and can be considered as a natural directed analogue of the chromatic number of a graph. A digraph D is called even if for every 0-1-weighting of the edges it contains a directed cycle of even total weight. We show that every non-even digraph has dichromatic number at most 2 and an optimal colouring can be found in polynomial time. We strengthen a previously known NP-hardness result by showing that deciding whether a directed graph is 2-colourable remains NP-hard even if it contains a feedback vertex set of bounded size., Comment: minor changes in section 5 added a section on list colourings

Published

2019

30. Braces of Perfect Matching Width 2

Author

Giannopoulou, Archontia C., Hatzel, Meike, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C83, 05C75

Abstract

Perfect matching width is a treewidth-like parameter designed for graphs with perfect matchings. The concept was originally introduced by Norine for the study of non-bipartite Pfaffian graphs. Additionally, perfect matching width appears to be a useful structural tool for investigating matching minors, a specialised version of minors related to perfect matchings. In this paper we lay the groundwork for understanding the interaction of perfect matching width and matching minors by establishing tight connections between the perfect matching width of any matching covered graph $G$ and the perfect matching width of its bricks and braces (a matching theoretic version of blocks) and proving that perfect matching width is almost monotone under the matching minor relation. As an application, we give several characterisations for braces of perfect matching width two, including one that allows for a polynomial time recognition algorithm.

Published

2019

31. Cyclewidth and the Grid Theorem for Perfect Matching Width of Bipartite Graphs

Author

Hatzel, Meike, Rabinovich, Roman, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C83, 05C75

Abstract

A connected graph G is called matching covered if every edge of G is contained in a perfect matching. Perfect matching width is a width parameter for matching covered graphs based on a branch decomposition. It was introduced by Norine and intended as a tool for the structural study of matching covered graphs, especially in the context of Pfaffian orientations. Norine conjectured that graphs of high perfect matching width would contain a large grid as a matching minor, similar to the result on treewidth by Robertson and Seymour. In this paper we obtain the first results on perfect matching width since its introduction. For the restricted case of bipartite graphs, we show that perfect matching width is equivalent to directed treewidth and thus the Directed Grid Theorem by Kawarabayashi and Kreutzer for directed \treewidth implies Norine's conjecture., Comment: Manuscript

Published

2019

32. Matching theory and Barnette's conjecture

Author

Gorsky, Maximilian, Steiner, Raphael, and Wiederrecht, Sebastian

Published

2023

33. The Tight Cut Decomposition of Matching Covered Uniformable Hypergraphs

Author

Beckenbach, Isabel, Hatzel, Meike, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, 05C65, 05C70

Abstract

The perfect matching polytope, i.e. the convex hull of (incidence vectors of) perfect matchings of a graph is used in many combinatorial algorithms. Kotzig, Lov\'asz and Plummer developed a decomposition theory for graphs with perfect matchings and their corresponding polytopes known as the tight cut decomposition which breaks down every graph into a number of indecomposable graphs, so called bricks. For many properties that are of interest on graphs with perfect matchings, including the description of the perfect matching polytope, it suffices to consider these bricks. A key result by Lov\'asz on the tight cut decomposition is that the list of bricks obtained is the same independent of the choice of tight cuts made during the tight cut decomposition procedure. This implies that finding a tight cut decomposition is polynomial time equivalent to finding a single tight cut. We generalise the notions of a tight cut, a tight cut contraction and a tight cut decomposition to hypergraphs. By providing an example, we show that the outcome of the tight cut decomposition on general hypergraphs is no longer unique. However, we are able to prove that the uniqueness of the tight cut decomposition is preserved on a slight generalisation of uniform hypergraphs. Moreover, we show how the tight cut decomposition leads to a decomposition of the perfect matching polytope of uniformable hypergraphs and that the recognition problem for tight cuts in uniformable hypergraphs is polynomial time solvable.

Published

2018

34. Short Schedules for Fast Flow Rerouting

Author

Amiri, Saeed Akhoondian, Dudycz, Szymon, Parham, Mahmoud, Schmid, Stefan, and Wiederrecht, Sebastian

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Networking and Internet Architecture

Abstract

This paper studies the fundamental problem of how to reroute $k$ unsplittable flows of a certain demand in a capacitated network from their current paths to their respective new paths, in a congestion-free manner and fast. This scheduling problem has applications in traffic engineering in communication networks and has recently received much attention in software-defined networks, in which updates are distributed over an asynchronous network by a software controller. However, existing algorithms for this problem either have a super-polynomial runtime or only compute feasible schedules, which do not provide any guarantees on the length of the rerouting schedule. This paper presents the first polynomial-time algorithm for computing shortest update schedules to reroute flows in a congestion-free manner. We contribute an almost tight characterization of the polynomial-time tractability of the problem: We present the first polynomial-time solution for this problem for two flows, but also show that even the question whether a feasible update schedule exists, is already NP-hard for six flows. In fact, the presented algorithm runs in linear time and is hence not only optimal in terms of scheduling but also asymptotically optimal in terms of runtime., Comment: arXiv admin note: text overlap with arXiv:1611.09296

Published

2018

35. Excluding Single-Crossing Matching Minors in Bipartite Graphs

Author

Giannopoulou, Archontia C., primary, Thilikos, Dimitrios M., additional, and Wiederrecht, Sebastian, additional

Published

2023

36. Kernelization for Graph Packing Problems via Rainbow Matching

Author

Bessy, Stéphane, primary, Bougeret, Marin, additional, Thilikos, Dimitrios M., additional, and Wiederrecht, Sebastian, additional

Published

2023

37. The Strong Colors of Flowers - The Structure of Graphs with Chordal Squares

Author

Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, 05C12, 05C15, 05C17, 05C38, 05C75, 05C76, 05C85

Abstract

A proper vertex coloring of a graph is a mapping of its vertices on a set of colors, such that two adjacent vertices are not mapped to the same color. This constraint may be interpreted in terms of the distance between to vertices and so a more general coloring concept can be defined: The strong coloring of a graph. So a k-strong coloring is a coloring where two vertices may not have the same color if their distance to each other is at most k. The 2-strong coloring of the line graph is known as the strong edge coloring. Coloring the kth power G^k of a graph G is the same as finding a k-strong coloring of G itself. In order to obtain a graph class on which the 2-strong coloring becomes efficiently solvable we are looking for a structure that produces induced cycles in the square of G, so that by excluding this structure we obtain a graph class with chordal squares, where a chordal graph is a graph without any induced cycles of length at least 4. Such a structure is called a flower. Another structure will be found and explained, which is responsible for flowers to appear in the line graph of G: The sprouts. With this graphs with chordal line graph squares are described as well. Some attempts in generalizing those structures to obtain perfect graph squares are being made and the general concept of chordal graph powers, i.e. the existence of a smallest power for which a graph becomes chordal, the power of chordality is introduced in order to solve some coloring related NP-hard problems on graphs with parameterized algorithms. Some connections to the famous parameter treewidth arise alongside with some deeper connections between edge and vertex coloring., Comment: Master Thesis

Published

2017

38. On Chordal Graph and Line Graph Squares

Author

Scheidweiler, Robert and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, 05C12, 05C38, 05C75, 05C76

Abstract

In this work we investigate the chordality of squares and line graph squares of graphs. We prove a sufficient condition for the chordality of squares of graphs not containing induced cycles of length at least five. Moreover, we characterize the chordality of graph squares by forbidden subgraphs. Transferring that result to line graphs allows us to characterize the chordality of line graph squares.

Published

2017

39. Matching Connectivity: On the Structure of Graphs with Perfect Matchings

Author

Giannopoulou, Archontia C., Kreutzer, Stephan, and Wiederrecht, Sebastian

Subjects

Mathematics - Combinatorics, 05C38, 05C40, 05C70

Abstract

We introduce the concept of matching connectivity as a notion of connectivity in graph admitting perfect matchings which heavily relies on the structural properties of those matchings. We generalise a result of Robertson, Seymour and Thomas for bipartite graphs with perfect matchings (see [Neil Roberts, Paul D Seymour, and Robin Thomas. Permanents, pfaffian orientations, and even directed curcuits. Annals of Mathematics, 150(2):929-975, 1999]) in order to obtain a concept of alternating paths that turns out to be sufficient for the description of our connectivity parameter. We introduce some basic properties of matching connectivity and prove a Menger-type result for matching n-connected graphs. Furthermore, we show that matching connectivity fills a gap in the investigation of n-extendable graphs and their connectivity properties. To be more precise we show that every n-extendable graph is matching n-connected and for the converse every matching (n+1)-connected graph either is n-extendable, or belongs to a well described class of graphs: the brace h-critical graphs., Comment: Error in main proof

Published

2017

40. Directed Width Parameters on Semicomplete Digraphs

Author

Gurski, Frank, Komander, Dominique, Rehs, Carolin, Wiederrecht, Sebastian, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Du, Ding-Zhu, editor, Du, Donglei, editor, Wu, Chenchen, editor, and Xu, Dachuan, editor

Published

2021

41. The Flat Wall Theorem for Bipartite Graphs with Perfect Matchings

Author

Giannopoulou, Archontia C., Wiederrecht, Sebastian, Nešetřil, Jaroslav, editor, Perarnau, Guillem, editor, Rué, Juanjo, editor, and Serra, Oriol, editor

Published

2021

42. Strongly Pfaffian Graphs

Author

Gorsky, Maximilian, Steiner, Raphael, Wiederrecht, Sebastian, Nešetřil, Jaroslav, editor, Perarnau, Guillem, editor, Rué, Juanjo, editor, and Serra, Oriol, editor

Published

2021

43. A Flat Wall Theorem for Matching Minors in Bipartite Graphs

Author

Giannopoulou, Archontia C., primary and Wiederrecht, Sebastian, additional

Published

2024

44. Packing Even Directed Circuits Quarter-Integrally

Author

Gorsky, Maximilian, primary, Kawarabayashi, Ken-ichi, additional, Kreutzer, Stephan, additional, and Wiederrecht, Sebastian, additional

Published

2024

45. Congestion-Free Rerouting of Flows on DAGs

Author

Amiri, Saeed Akhoondian, Dudycz, Szymon, Schmid, Stefan, and Wiederrecht, Sebastian

Subjects

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

Abstract

Changing a given configuration in a graph into another one is known as a re- configuration problem. Such problems have recently received much interest in the context of algorithmic graph theory. We initiate the theoretical study of the following reconfiguration problem: How to reroute $k$ unsplittable flows of a certain demand in a capacitated network from their current paths to their respective new paths, in a congestion-free manner? This problem finds immediate applications, e.g., in traffic engineering in computer networks. We show that the problem is generally NP-hard already for $k = 2$ flows, which motivates us to study rerouting on a most basic class of flow graphs, namely DAGs. Interestingly, we find that for general $k$, deciding whether an unsplittable multi-commodity flow rerouting schedule exists, is NP-hard even on DAGs. Both NP-hardness proofs are non-trivial. Our main contribution is a polynomial-time (fixed parameter tractable) algorithm to solve the route update problem for a bounded number of flows on DAGs. At the heart of our algorithm lies a novel decomposition of the flow network that allows us to express and resolve reconfiguration dependencies among flows.

Published

2016

46. Parameterized Algorithms for Directed Modular Width

Author

Steiner, Raphael, Wiederrecht, Sebastian, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Changat, Manoj, editor, and Das, Sandip, editor

Published

2020

47. Digraphs of directed treewidth one

Author

Wiederrecht, Sebastian

Published

2020

48. Directed Width Parameters on Semicomplete Digraphs

Author

Gurski, Frank, primary, Komander, Dominique, additional, Rehs, Carolin, additional, and Wiederrecht, Sebastian, additional

Published

2021

49. On Perfect Linegraph Squares

Author

Hatzel, Meike, Wiederrecht, Sebastian, 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, Brandstädt, Andreas, editor, Köhler, Ekkehard, editor, and Meer, Klaus, editor

Published

2018

50. On chordal graph and line graph squares

Author

Scheidweiler, Robert and Wiederrecht, Sebastian

Published

2018