Your search keyword '"Zeman, Peter"' showing total 171 results

1. NPA Hierarchy for Quantum Isomorphism and Homomorphism Indistinguishability

Author

Kar, Prem Nigam, Roberson, David E., Seppelt, Tim, and Zeman, Peter

Subjects

Quantum Physics, Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms, Mathematics - Combinatorics, Mathematics - Optimization and Control

Abstract

Man\v{c}inska and Roberson~[FOCS'20] showed that two graphs are quantum isomorphic if and only if they are homomorphism indistinguishable over the class of planar graphs. Atserias et al.~[JCTB'19] proved that quantum isomorphism is undecidable in general. The NPA hierarchy gives a sequence of semidefinite programming relaxations of quantum isomorphism. Recently, Roberson and Seppelt~[ICALP'23] obtained a homomorphism indistinguishability characterization of the feasibility of each level of the Lasserre hierarchy of semidefinite programming relaxations of graph isomorphism. We prove a quantum analogue of this result by showing that each level of the NPA hierarchy of SDP relaxations for quantum isomorphism of graphs is equivalent to homomorphism indistinguishability over an appropriate class of planar graphs. By combining the convergence of the NPA hierarchy with the fact that the union of these graph classes is the set of all planar graphs, we are able to give a new proof of the result of Man\v{c}inska and Roberson~[FOCS'20] that avoids the use of the theory of quantum groups. This homomorphism indistinguishability characterization also allows us to give a randomized polynomial-time algorithm deciding exact feasibility of each fixed level of the NPA hierarchy of SDP relaxations for quantum isomorphism., Comment: 34 Pages, 5 Figures

Published

2024

2. Quantum Sabidussi's Theorem

Author

Árnadóttir, Arnbjörg Soffía, de Bruyn, Josse van Dobben, Kar, Prem Nigam, Roberson, David E., and Zeman, Peter

Subjects

Mathematics - Quantum Algebra, Mathematics - Combinatorics, Mathematics - Operator Algebras, 46L67 (Primary), 05C25, 05C76, 46L85 (Secondary)

Abstract

Sabidussi's theorem [Duke Math. J. 28, 1961] gives necessary and sufficient conditions under which the automorphism group of a lexicographic product of two graphs is a wreath product of the respective automorphism groups. We prove a quantum version of Sabidussi's theorem for finite graphs, with the automorphism groups replaced by quantum automorphism groups and the wreath product replaced by the free wreath product of quantum groups. This extends the result of Chassaniol [J. Algebra 456, 2016], who proved it for regular graphs. Moreover, we apply our result to lexicographic products of quantum vertex transitive graphs, determining their quantum automorphism groups even when Sabidussi's conditions do not apply., Comment: 21 pages, 2 figures. Minor changes, mostly improvements to the exposition

Published

2024

3. Quantum automorphism groups of trees

Author

de Bruyn, Josse van Dobben, Kar, Prem Nigam, Roberson, David E., Schmidt, Simon, and Zeman, Peter

Subjects

Mathematics - Quantum Algebra, Mathematics - Combinatorics

Abstract

We give a characterisation of quantum automorphism groups of trees. In particular, for every tree, we show how to iteratively construct its quantum automorphism group using free products and free wreath products. This can be considered a quantum version of Jordan's theorem for the automorphism groups of trees. This is one of the first characterisations of quantum automorphism groups of a natural class of graphs with quantum symmetry.

Published

2023

4. On the Weisfeiler-Leman dimension of some polyhedral graphs

Author

Li, Haiyan, Ponomarenko, Ilia, and Zeman, Peter

Subjects

Mathematics - Combinatorics

Abstract

Let $m$ be a positive integer, $X$ a graph with vertex set $\Omega$, and ${\rm WL}_m(X)$ the coloring of the Cartesian $m$-power $\Omega^m$, obtained by the $m$-dimensional Weisfeiler-Leman algorithm. The ${\rm WL}$-dimension of the graph $X$ is defined to be the smallest $m$ for which the coloring ${\rm WL}_m(X)$ determines $X$ up to isomorphism. It is known that the ${\rm WL}$-dimension of any planar graph is $2$ or $3$, but no planar graph of ${\rm WL}$-dimension $3$ is known. We prove that the ${\rm WL}$-dimension of a polyhedral (i.e., $3$-connected planar) graph $X$ is at most $2$ if the color classes of the coloring ${\rm WL}_2(X)$ are the orbits of the componentwise action of the group ${\rm Aut}(X)$ on $\Omega^2$.

Published

2023

5. Beyond circular-arc graphs -- recognizing lollipop graphs and medusa graphs

Author

Çağırıcı, Deniz Ağaoğlu, Çağırıcı, Onur, Derbisz, Jan, Hartmann, Tim A., Hliněný, Petr, Kratochvíl, Jan, Krawczyk, Tomasz, and Zeman, Peter

Subjects

Computer Science - Data Structures and Algorithms

Abstract

In 1992 Bir\'{o}, Hujter and Tuza introduced, for every fixed connected graph $H$, the class of $H$-graphs, defined as the intersection graphs of connected subgraphs of some subdivision of $H$. Recently, quite a lot of research has been devoted to understanding the tractability border for various computational problems, such as recognition or isomorphism testing, in classes of $H$-graphs for different graphs $H$. In this work we undertake this research topic, focusing on the recognition problem. Chaplick, T\"{o}pfer, Voborn\'{\i}k, and Zeman showed, for every fixed tree $T$, a polynomial-time algorithm recognizing $T$-graphs. Tucker showed a polynomial time algorithm recognizing $K_3$-graphs (circular-arc graphs). On the other hand, Chaplick at al. showed that recognition of $H$-graphs is $NP$-hard if $H$ contains two different cycles sharing an edge. The main two results of this work narrow the gap between the $NP$-hard and $P$ cases of $H$-graphs recognition. First, we show that recognition of $H$-graphs is $NP$-hard when $H$ contains two different cycles. On the other hand, we show a polynomial-time algorithm recognizing $L$-graphs, where $L$ is a graph containing a cycle and an edge attached to it ($L$-graphs are called lollipop graphs). Our work leaves open the recognition problems of $M$-graphs for every unicyclic graph $M$ different from a cycle and a lollipop. Other results of this work, which shed some light on the cases that remain open, are as follows. Firstly, the recognition of $M$-graphs, where $M$ is a fixed unicyclic graph, admits a polynomial time algorithm if we restrict the input to graphs containing particular holes (hence recognition of $M$-graphs is probably most difficult for chordal graphs). Secondly, the recognition of medusa graphs, which are defined as the union of $M$-graphs, where $M$ runs over all unicyclic graphs, is $NP$-complete.

Published

2022

6. Recognition and Isomorphism of Proper in FPT-Time

Author

Ağaoğlu Çağırıcı, Deniz, Zeman, Peter, Goos, Gerhard, Founding 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, Uehara, Ryuhei, editor, Yamanaka, Katsuhisa, editor, and Yen, Hsu-Chun, editor

Published

2024

7. Recognition and Isomorphism of Proper $\boldsymbol{U}$-graphs in FPT-time

Author

Çağırıcı, Deniz Ağaoğlu and Zeman, Peter

Subjects

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

Abstract

An $H$-graph is an intersection graph of connected subgraphs of a suitable subdivision of a fixed graph $H$. Many important classes of graphs, including interval graphs, circular-arc graphs, and chordal graphs, can be expressed as $H$-graphs, and, in particular, every graph is an $H$-graph for a suitable graph $H$. An $H$-graph is called proper if it has a representation where no subgraph properly contains another. We consider the recognition and isomorphism problems for proper $U$-graphs where $U$ is a unicylic graph. We prove that testing whether a graph is a (proper) $U$-graph, for some $U$, is NP-hard. On the positive side, we give an FPT-time recognition algorithm, parametrized by $\vert U \vert$. As an application, we obtain an FPT-time isomorphism algorithm for proper $U$-graphs, parametrized by $\vert U \vert$. To complement this, we prove that the isomorphism problem for (proper) $H$-graphs, is as hard as the general isomorphism problem for every fixed $H$ which is not unicyclic.

Published

2022

8. Extending Partial Representations of Circular-Arc Graphs

Author

Fiala, Jiří, Rutter, Ignaz, Stumpf, Peter, and Zeman, Peter

Subjects

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

Abstract

The partial representation extension problem generalizes the recognition problem for classes of graphs defined in terms of vertex representations. We exhibit circular-arc graphs as the first example of a graph class where the recognition is polynomially solvable while the representation extension problem is NP-complete. In this setting, several arcs are predrawn and we ask whether this partial representation can be completed. We complement this hardness argument with tractability results of the representation extension problem on various subclasses of circular-arc graphs, most notably on all variants of Helly circular-arc graphs. In particular, we give linear-time algorithms for extending normal proper Helly and proper Helly representations. For normal Helly circular-arc representations we give an $O(n^3)$-time algorithm. Surprisingly, for Helly representations, the complexity hinges on the seemingly irrelevant detail of whether the predrawn arcs have distinct or non-distinct endpoints: In the former case the previous algorithm can be extended, whereas the latter case turns out to be NP-complete. We also prove that representation extension problem of unit circular-arc graphs is NP-complete.

Published

2021

9. Testing isomorphism of chordal graphs of bounded leafage is fixed-parameter tractable

Author

Arvind, Vikraman, Nedela, Roman, Ponomarenko, Ilia, and Zeman, Peter

Subjects

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

Abstract

The computational complexity of the graph isomorphism problem is considered to be a major open problem in theoretical computer science. It is known that testing isomorphism of chordal graphs is polynomial-time equivalent to the general graph isomorphism problem. Every chordal graph can be represented as the intersection graph of some subtrees of a representing tree, and the leafage of a chordal graph is defined to be the minimum number of leaves in a representing tree for it. We prove that chordal graph isomorphism is fixed parameter tractable with leafage as parameter. In the process we introduce the problem of isomorphism testing for higher-order hypergraphs and show that finding the automorphism group of order-$k$ hypergraphs with vertex color classes of size $b$ is fixed parameter tractable for any constant $k$ and $b$ as fixed parameter.

Published

2021

10. Automorphism groups of maps in linear time

Author

Kawarabayashi, Ken-ichi, Mohar, Bojan, Nedela, Roman, and Zeman, Peter

Subjects

Mathematics - Combinatorics, Computer Science - Data Structures and Algorithms

Abstract

By a map we mean a $2$-cell decomposition of a closed compact surface, i.e., an embedding of a graph such that every face is homeomorphic to an open disc. Automorphism of a map can be thought of as a permutation of the vertices which preserves the vertex-edge-face incidences in the embedding. When the underlying surface is orientable, every automorphism of a map determines an angle-preserving homeomorphism of the surface. While it is conjectured that there is no "truly subquadratic" algorithm for testing map isomorphism for unconstrained genus, we present a linear-time algorithm for computing the generators of the automorphism group of a map, parametrized by the genus of the underlying surface. The algorithm applies a sequence of local reductions and produces a uniform map, while preserving the automorphism group. The automorphism group of the original map can be reconstructed from the automorphism group of the uniform map in linear time. We also extend the algorithm to non-orientable surfaces by making use of the antipodal double-cover., Comment: Added funding information

Published

2020

11. Circle Graph Isomorphism in Almost Linear Time

Author

Kalisz, Vít, Klavík, Pavel, and Zeman, Peter

Subjects

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

Abstract

Circle graphs are intersection graphs of chords of a circle. In this paper, we present a new algorithm for the circle graph isomorphism problem running in time $O((n+m)\alpha(n+m))$ where $n$ is the number of vertices, $m$ is the number of edges and $\alpha$ is the inverse Ackermann function. Our algorithm is based on the minimal split decomposition [Cunnigham, 1982] and uses the state-of-art circle graph recognition algorithm [Gioan, Paul, Tedder, Corneil, 2014] in the same running time. It improves the running time $O(nm)$ of the previous algorithm [Hsu, 1995] based on a similar approach.

Published

2019

12. Discrete and Fast Fourier Transform Made Clear

Author

Zeman, Peter

Subjects

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

Abstract

Fast Fourier transform was included in the Top 10 Algorithms of 20th Century by Computing in Science & Engineering. In this paper, we provide a new simple derivation of both the discrete Fourier transform and fast Fourier transform by means of elementary linear algebra. We start the exposition by introducing the convolution product of vectors, represented by a circulant matrix, and derive the discrete Fourier transform as the change of basis matrix that diagonalizes the circulant matrix. We also generalize our approach to derive the Fourier transform on any finite abelian group, where the case of Fourier transform on the Boolean cube is especially important for many applications in theoretical computer science.

Published

2019

13. Testing isomorphism of circular-arc graphs in polynomial time

Author

Nedela, Roman, Ponomarenko, Ilia, and Zeman, Peter

Subjects

Computer Science - Data Structures and Algorithms, Mathematics - Combinatorics, 68Q25

Abstract

A graph is said to be circular-arc if the vertices can be associated with arcs of a circle so that two vertices are adjacent if and only if the corresponding arcs overlap. It is proved that the isomorphism of circular-arc graphs can be tested by the Weisfeiler-Leman algorithm after individualization of two vertices., Comment: Dear reader, recently we have found a problem in the proof of the main theorem. It seems that we will be able to fill in the gap in the arguments, and we are doing our best to do this as soon as possible. We appologize for publishing an unfinished work. The authors

Published

2019

14. Circle Graph Isomorphism in Almost Linear Time

Author

Kalisz, Vít, Klavík, Pavel, Zeman, Peter, Goos, Gerhard, Founding 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, Du, Ding-Zhu, editor, Du, Donglei, editor, Wu, Chenchen, editor, and Xu, Dachuan, editor

Published

2022

15. Testing Isomorphism of Chordal Graphs of Bounded Leafage is Fixed-Parameter Tractable (Extended Abstract)

Author

Arvind, Vikraman, Nedela, Roman, Ponomarenko, Ilia, Zeman, Peter, Goos, Gerhard, Founding 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, Bekos, Michael A., editor, and Kaufmann, Michael, editor

Published

2022

16. Extending Partial Representations of Circular-Arc Graphs

Author

Fiala, Jiří, Rutter, Ignaz, Stumpf, Peter, Zeman, Peter, Goos, Gerhard, Founding 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, Bekos, Michael A., editor, and Kaufmann, Michael, editor

Published

2022

17. Jordan-like characterization of automorphism groups of planar graphs

Author

Klavík, Pavel, Nedela, Roman, and Zeman, Peter

Published

2022

18. Extending Partial Representations of Unit Circular-arc Graphs

Author

Zeman, Peter

Subjects

Computer Science - Discrete Mathematics

Abstract

The partial representation extension problem, introduced by Klav\'{i}k et al. (2011), generalizes the recognition problem. In this short note we show that this problem is NP-complete for unit circular-arc graphs.

Published

2017

19. Combinatorial Problems on $H$-graphs

Author

Chaplick, Steven and Zeman, Peter

Subjects

Computer Science - Discrete Mathematics

Abstract

Bir\'{o}, Hujter, and Tuza introduced the concept of $H$-graphs (1992), intersection graphs of connected subgraphs of a subdivision of a graph $H$. They naturally generalize many important classes of graphs, e.g., interval graphs and circular-arc graphs. We continue the study of these graph classes by considering coloring, clique, and isomorphism problems on $H$-graphs. We show that for any fixed $H$ containing a certain 3-node, 6-edge multigraph as a minor that the clique problem is APX-hard on $H$-graphs and the isomorphism problem is isomorphism-complete. We also provide positive results on $H$-graphs. Namely, when $H$ is a cactus the clique problem can be solved in polynomial time. Also, when a graph $G$ has a Helly $H$-representation, the clique problem can be solved in polynomial time. Finally, we observe that one can use treewidth techniques to show that both the $k$-clique and list $k$-coloring problems are FPT on $H$-graphs. These FPT results apply more generally to treewidth-bounded graph classes where treewidth is bounded by a function of the clique number.

Published

2017

20. Graph Isomorphism Restricted by Lists

Author

Klavík, Pavel, Knop, Dušan, Zeman, Peter, 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, Adler, Isolde, editor, and Müller, Haiko, editor

Published

2020

21. On H-Topological Intersection Graphs

Author

Chaplick, Steven, Töpfer, Martin, Voborník, Jan, and Zeman, Peter

Published

2021

22. On $H$-Topological Intersection Graphs

Author

Chaplick, Steven, Töpfer, Martin, Voborník, Jan, and Zeman, Peter

Subjects

Computer Science - Discrete Mathematics, Mathematics - Combinatorics

Abstract

Bir\'{o} et al. (1992) introduced $H$-graphs, intersection graphs of connected subgraphs of a subdivision of a graph $H$. They are related to many classes of geometric intersection graphs, e.g., interval graphs, circular-arc graphs, split graphs, and chordal graphs. We negatively answer the 25-year-old question of Bir\'{o} et al. which asks if $H$-graphs can be recognized in polynomial time, for a fixed graph $H$. We prove that it is NP-complete if $H$ contains the diamond graph as a minor. We provide a polynomial-time algorithm recognizing $T$-graphs, for each fixed tree $T$. When $T$ is a star $S_d$ of degree $d$, we have an $O(n^{3.5})$-time algorithm. We give FPT- and XP-time algorithms solving the minimum dominating set problem on $S_d$-graphs and $H$-graphs parametrized by $d$ and the size of $H$, respectively. The algorithm for $H$-graphs adapts to an XP-time algorithm for the independent set and the independent dominating set problems on $H$-graphs. If $H$ contains the double-triangle as a minor, we prove that $H$-graphs are GI-complete and that the clique problem is APX-hard. The clique problem can be solved in polynomial time if $H$ is a cactus graph. When a graph $G$ has a Helly $H$-representation, the clique problem can be solved in polynomial time. We show that both the $k$-clique and the list $k$-coloring problems are solvable in FPT-time on $H$-graphs (parameterized by $k$ and the treewidth of $H$). In fact, these results apply to classes of graphs with treewidth bounded by a function of the clique number. We observe that $H$-graphs have at most $n^{O(\|H\|)}$ minimal separators which allows us to apply the meta-algorithmic framework of Fomin et al. (2015) to show that for each fixed $t$, finding a maximum induced subgraph of treewidth $t$ can be done in polynomial time. When $H$ is a cactus, we improve the bound to $O(\|H\|n^2)$.

Published

2016

23. Graph Isomorphism Restricted by Lists

Author

Klavik, Pavel, Knop, Dušan, and Zeman, Peter

Subjects

Computer Science - Discrete Mathematics, Mathematics - Combinatorics

Abstract

The complexity of graph isomorphism (GraphIso) is a famous unresolved problem in theoretical computer science. For graphs $G$ and $H$, it asks whether they are the same up to a relabeling of vertices. In 1981, Lubiw proved that list restricted graph isomorphism (ListIso) is NP-complete: for each $u \in V(G)$, we are given a list ${\mathfrak L}(u) \subseteq V(H)$ of possible images of $u$. After 35 years, we revive the study of this problem and consider which results for GraphIso translate to ListIso. We prove the following: 1) When GraphIso is GI-complete for a class of graphs, it translates into NP-completeness of ListIso. 2) Combinatorial algorithms for GraphIso translate into algorithms for ListIso: for trees, planar graphs, interval graphs, circle graphs, permutation graphs, bounded genus graphs, and bounded treewidth graphs. 3) Algorithms based on group theory do not translate: ListIso remains NP-complete for cubic colored graphs with sizes of color classes bounded by 8. Also, ListIso allows to classify results for the graph isomorphism problem. Some algorithms are robust and translate to ListIso. A fundamental problem is to construct a combinatorial polynomial-time algorithm for cubic graph isomorphism, avoiding group theory. By the 3rd result, ListIso is NP-hard for them, so no robust algorithm for cubic graph isomorphism exists, unless P = NP.

Published

2016

24. Extending Partial Representations of Circular-Arc Graphs

Author

Fiala, Jiří, primary, Rutter, Ignaz, additional, Stumpf, Peter, additional, and Zeman, Peter, additional

Published

2022

25. Testing Isomorphism of Chordal Graphs of Bounded Leafage is Fixed-Parameter Tractable (Extended Abstract)

Author

Arvind, Vikraman, primary, Nedela, Roman, additional, Ponomarenko, Ilia, additional, and Zeman, Peter, additional

Published

2022

26. Jordan-like characterization of automorphism groups of planar graphs

Author

Klavík, Pavel, Nedela, Roman, and Zeman, Peter

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, Mathematics - Group Theory

Abstract

We investigate automorphism groups of planar graphs. The main result is a complete recursive description of all abstract groups that can be realized as automorphism groups of planar graphs. The characterization is formulated in terms of inhomogeneous wreath products. In the proof, we combine techniques from combinatorics, group theory, and geometry. This significantly improves the Babai's description (1975)., Comment: Some citations were added

Published

2015

27. Automorphism Groups of Comparability Graphs

Author

Klavík, Pavel and Zeman, Peter

Subjects

Computer Science - Discrete Mathematics, Mathematics - Combinatorics

Abstract

Comparability graphs are graphs which have transitive orientations. The dimension of a poset is the least number of linear orders whose intersection gives this poset. The dimension ${\rm dim}(X)$ of a comparability graph $X$ is the dimension of any transitive orientation of X, and by $k$-DIM we denote the class of comparability graphs $X$ with ${\rm dim}(X) \le k$. It is known that the complements of comparability graphs are exactly function graphs and permutation graphs equal 2-DIM. In this paper, we characterize the automorphism groups of permutation graphs similarly to Jordan's characterization for trees (1869). For permutation graphs, there is an extra operation, so there are some extra groups not realized by trees. For $k \ge 4$, we show that every finite group can be realized as the automorphism group of some graph in $k$-DIM, and testing graph isomorphism for $k$-DIM is GI-complete.

Published

2015

28. Kernelization of Graph Hamiltonicity: Proper H-Graphs

Author

Chaplick, Steven, Fomin, Fedor V., Golovach, Petr A., Knop, Dušan, Zeman, Peter, 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, Friggstad, Zachary, editor, Sack, Jörg-Rüdiger, editor, and Salavatipour, Mohammad R, editor

Published

2019

29. In vivo functional brain mapping using ultra-high-field fMRI in awake common marmosets

Author

Zanini, Alessandro, primary, Dureux, Audrey, additional, Jafari, Azadeh, additional, Gilbert, Kyle M., additional, Zeman, Peter, additional, Bellyou, Miranda, additional, Li, Alex, additional, Tuin, Cheryl Vander, additional, and Everling, Stefan, additional

Published

2023

30. Automorphism Groups of Geometrically Represented Graphs

Author

Klavík, Pavel and Zeman, Peter

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C62, 08A35, 20D45

Abstract

We describe a technique to determine the automorphism group of a geometrically represented graph, by understanding the structure of the induced action on all geometric representations. Using this, we characterize automorphism groups of interval, permutation and circle graphs. We combine techniques from group theory (products, homomorphisms, actions) with data structures from computer science (PQ-trees, split trees, modular trees) that encode all geometric representations. We prove that interval graphs have the same automorphism groups as trees, and for a given interval graph, we construct a tree with the same automorphism group which answers a question of Hanlon [Trans. Amer. Math. Soc 272(2), 1982]. For permutation and circle graphs, we give an inductive characterization by semidirect and wreath products. We also prove that every abstract group can be realized by the automorphism group of a comparability graph/poset of the dimension at most four.

Published

2014

31. Simultaneous functional MRI of two awake marmosets

Author

Gilbert, Kyle M., Cléry, Justine C., Gati, Joseph S., Hori, Yuki, Johnston, Kevin D., Mashkovtsev, Alexander, Selvanayagam, Janahan, Zeman, Peter, Menon, Ravi S., Schaeffer, David J., and Everling, Stefan

Published

2021

32. Graph Isomorphism Restricted by Lists

Author

Klavík, Pavel, primary, Knop, Dušan, additional, and Zeman, Peter, additional

Published

2020

33. On H-Topological Intersection Graphs

Author

Chaplick, Steven, Töpfer, Martin, Voborník, Jan, Zeman, Peter, 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, Bodlaender, Hans L., editor, and Woeginger, Gerhard J., editor

Published

2017

34. Concentric radiofrequency arrays to increase the statistical power of resting-state maps in monkeys

Author

Gilbert, Kyle M., Schaeffer, David J., Zeman, Peter, Diedrichsen, Jörn, Everling, Stefan, Martinez-Trujillo, Julio C., Pruszynski, J. Andrew, and Menon, Ravi S.

Published

2018

35. A geometrically adjustable receive array for imaging marmoset cohorts

Author

Gilbert, Kyle M., Gati, Joseph S., Klassen, L. Martyn, Zeman, Peter, Schaeffer, David J., Everling, Stefan, and Menon, Ravi S.

Published

2017

36. Layer Dependence of Monocular and Binocular Responses in Human Ocular Dominance Columns at 7T using VASO and BOLD

Author

Akbari, Atena, primary, Gati, Joseph S, additional, Zeman, Peter, additional, Liem, Brett T, additional, and Menon, Ravi S, additional

Published

2023

37. Zeman, Peter

Author

Zeman, Peter and Zeman, Peter

Published

2023

38. Recognizing H-Graphs - Beyond Circular-Arc Graphs

Author

Derbisz, Jan, Hartmann, Tim A., Krawczyk, Tomasz, Zeman, Peter, Derbisz, Jan, Hartmann, Tim A., Krawczyk, Tomasz, and Zeman, Peter

Published

2023

39. Recognizing H-Graphs - Beyond Circular-Arc Graphs

Author

Çagirici, Deniz Agaoglu, Çagirici, Onur, Derbisz, Jan, Hartmann, Tim A., Hliněný, Petr, Kratochvil, Jan, Krawczyk, Tomasz, Zeman, Peter, Çagirici, Deniz Agaoglu, Çagirici, Onur, Derbisz, Jan, Hartmann, Tim A., Hliněný, Petr, Kratochvil, Jan, Krawczyk, Tomasz, and Zeman, Peter

Abstract

In 1992 Biró, Hujter and Tuza introduced, for every fixed connected graph H, the class of H-graphs, defined as the intersection graphs of connected subgraphs of some subdivision of H. Such classes of graphs are related to many known graph classes: for example, K2-graphs coincide with interval graphs, K3-graphs with circular-arc graphs, the union of T -graphs, where T ranges over all trees, coincides with chordal graphs. Recently, quite a lot of research has been devoted to understanding the tractability border for various computational problems, such as recognition or isomorphism testing, in classes of H-graphs for different graphs H. In this work we undertake this research topic, focusing on the recognition problem. Chaplick, Töpfer, Voborník, and Zeman showed an XP-algorithm testing whether a given graph is a T -graph, where the parameter is the size of the tree T. In particular, for every fixed tree T the recognition of T -graphs can be solved in polynomial time. Tucker showed a polynomial time algorithm recognizing K3-graphs (circular-arc graphs). On the other hand, Chaplick et al. showed also that for every fixed graph H containing two distinct cycles sharing an edge, the recognition of H-graphs is NP-hard. The main two results of this work narrow the gap between the NP-hard and P cases of H-graph recognition. First, we show that the recognition of H-graphs is NP-hard when H contains two distinct cycles. On the other hand, we show a polynomial-time algorithm recognizing L-graphs, where L is a graph containing a cycle and an edge attached to it (which we call lollipop graphs). Our work leaves open the recognition problems of M -graphs for every unicyclic graph M different from a cycle and a lollipop.

Published

2023

40. A radiofrequency coil to facilitate task-based fMRI of awake marmosets

Author

Gilbert, Kyle M., primary, Dureux, Audrey, additional, Jafari, Azadeh, additional, Zanini, Alessandro, additional, Zeman, Peter, additional, Menon, Ravi S., additional, and Everling, Stefan, additional

Published

2023

41. Ältere Migrantinnen und Migranten in der Altenhilfe und kommunalen Alternspolitik

Author

Zeman, Peter, Backes, G. M., editor, Clemens, W., editor, Baykara-Krumme, Helen, editor, Schimany, Peter, editor, and Motel-Klingebiel, Andreas, editor

Published

2012

42. On H-Topological Intersection Graphs

Author

Chaplick, Steven, primary, Töpfer, Martin, additional, Voborník, Jan, additional, and Zeman, Peter, additional

Published

2017

43. Soziale Altenarbeit — Strukturen und Entwicklungslinien

Author

Zeman, Peter, Schmidt, Roland, and Deutsches Zentrum für Altersfragen

Published

2001

44. Lernen in Selbsthilfeorganisationen

Author

Zeman, Peter, Becker, Susanne, editor, Veelken, Ludger, editor, and Wallraven, Klaus Peter, editor

Published

2000

45. Probleme der Vernetzung von sozialen Diensten und Lebenswelt in häuslichen Altenpflegearrangements

Author

Zeman, Peter, Naegele, Gerhard, editor, and Schütz, Rudolf-M., editor

Published

1999

46. Testování isomorfizmu chordálních grafů s ohraničenou listnatostí je 'fixed parameter traceable'

Author

Arvind, Vikraman, Nedela, Roman, Ponomarenko, Ilia, and Zeman, Peter

Subjects

graph isomorphism, chordal graph, algorithmic complexity

Abstract

Určit algoritmickou složitost problému isomorfizmu grafů je jeden z nejdůležitejších otevřených problémů teoretické informatiky. Je známé, že testování isomorfizmu chordálních grafů je polynomiálně ekvivalentní obecnému problému isomorfizmu grafů. Každý chordální graf může být reprezentován jako průnikový graf množiny podstromů nějakého stromu T. Minimální počet listů T, v kterém je možné chordální graf G reprezentovat, se nazývá listnatost G. V našem příspěvku dokážeme, že existuje FPT algoritmus pro grafový izomorfizmus chordálních grafů s ohraničenou listnatostí. The computational complexity of the graph isomorphism problem is considered to be a major open problem in theoretical computer science. It is known that testing isomorphism of chordal graphs is polynomial-time equivalent to the general graph isomorphism problem. Every chordal graph can be represented as the intersection graph of some subtrees of a representing tree, and the leafage of a chordal graph is defined to be the minimum number of leaves in a representing tree for it. We prove that chordal graph isomorphism is fixed parameter tractable with leafage as parameter.

Published

2022

47. Right ventricular function after coronary artery bypass graft surgery—a magnetic resonance imaging study

Author

Joshi, Subodh B., Roswell, Robert O., Salah, Ali K., Zeman, Peter R., Corso, Paul J., Lindsay, Joseph, and Fuisz, Anthon R.

Published

2010

48. Extending Partial Representations of Circular-Arc Graphs

Author

Fiala, Ji����, Rutter, Ignaz, Stumpf, Peter, and Zeman, Peter

Subjects

FOS: Computer and information sciences, Discrete Mathematics (cs.DM), Computer Science - Data Structures and Algorithms, FOS: Mathematics, Mathematics - Combinatorics, Data Structures and Algorithms (cs.DS), Combinatorics (math.CO), Computer Science - Discrete Mathematics

Abstract

The partial representation extension problem generalizes the recognition problem for classes of graphs defined in terms of vertex representations. We exhibit circular-arc graphs as the first example of a graph class where the recognition is polynomially solvable while the representation extension problem is NP-complete. In this setting, several arcs are predrawn and we ask whether this partial representation can be completed. We complement this hardness argument with tractability results of the representation extension problem on various subclasses of circular-arc graphs, most notably on all variants of Helly circular-arc graphs. In particular, we give linear-time algorithms for extending normal proper Helly and proper Helly representations. For normal Helly circular-arc representations we give an $O(n^3)$-time algorithm. Surprisingly, for Helly representations, the complexity hinges on the seemingly irrelevant detail of whether the predrawn arcs have distinct or non-distinct endpoints: In the former case the previous algorithm can be extended, whereas the latter case turns out to be NP-complete. We also prove that representation extension problem of unit circular-arc graphs is NP-complete.

Published

2021

49. Automorphisms and Isomorphisms of Maps in Linear Time

Author

Kawarabayashi, Ken-ichi, Mohar, Bojan, Nedela, Roman, and Zeman, Peter

Subjects

maps on surfaces, algorithm, automorphisms, isomorphisms, Theory of computation → Design and analysis of algorithms

Abstract

A map is a 2-cell decomposition of a closed compact surface, i.e., an embedding of a graph such that every face is homeomorphic to an open disc. An automorphism of a map can be thought of as a permutation of the vertices which preserves the vertex-edge-face incidences in the embedding. When the underlying surface is orientable, every automorphism of a map determines an angle-preserving homeomorphism of the surface. While it is conjectured that there is no "truly subquadratic" algorithm for testing map isomorphism for unconstrained genus, we present a linear-time algorithm for computing the generators of the automorphism group of a map, parametrized by the genus of the underlying surface. The algorithm applies a sequence of local reductions and produces a uniform map, while preserving the automorphism group. The automorphism group of the original map can be reconstructed from the automorphism group of the uniform map in linear time. We also extend the algorithm to non-orientable surfaces by making use of the antipodal double-cover., LIPIcs, Vol. 198, 48th International Colloquium on Automata, Languages, and Programming (ICALP 2021), pages 86:1-86:15

Published

2021

50. Automorphisms and Isomorphisms of Maps in Linear Time

Author

Ken-ichi Kawarabayashi and Bojan Mohar and Roman Nedela and Peter Zeman, Kawarabayashi, Ken-ichi, Mohar, Bojan, Nedela, Roman, Zeman, Peter, Ken-ichi Kawarabayashi and Bojan Mohar and Roman Nedela and Peter Zeman, Kawarabayashi, Ken-ichi, Mohar, Bojan, Nedela, Roman, and Zeman, Peter

Abstract

A map is a 2-cell decomposition of a closed compact surface, i.e., an embedding of a graph such that every face is homeomorphic to an open disc. An automorphism of a map can be thought of as a permutation of the vertices which preserves the vertex-edge-face incidences in the embedding. When the underlying surface is orientable, every automorphism of a map determines an angle-preserving homeomorphism of the surface. While it is conjectured that there is no "truly subquadratic" algorithm for testing map isomorphism for unconstrained genus, we present a linear-time algorithm for computing the generators of the automorphism group of a map, parametrized by the genus of the underlying surface. The algorithm applies a sequence of local reductions and produces a uniform map, while preserving the automorphism group. The automorphism group of the original map can be reconstructed from the automorphism group of the uniform map in linear time. We also extend the algorithm to non-orientable surfaces by making use of the antipodal double-cover.

Published

2021