Your search keyword '"Büngener, Aaron"' showing total 5 results

1. Improving the Crossing Lemma by Characterizing Dense 2-Planar and 3-Planar Graphs

Author

Büngener, Aaron and Kaufmann, Michael

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, G.2.2, F.2.2

Abstract

The classical Crossing Lemma by Ajtai et al.~and Leighton from 1982 gave an important lower bound of $c \frac{m^3}{n^2}$ for the number of crossings in any drawing of a given graph of $n$ vertices and $m$ edges. The original value was $c= 1/100$, which then has gradually been improved. Here, the bounds for the density of $k$-planar graphs played a central role. Our new insight is that for $k=2,3$ the $k$-planar graphs have substantially fewer edges if specific local configurations that occur in drawings of $k$-planar graphs of maximum density are forbidden. Therefore, we are able to derive better bounds for the crossing number $\text{cr}(G)$ of a given graph $G$. In particular, we achieve a bound of $\text{cr}(G) \ge \frac{37}{9}m-\frac{155}{9}(n-2)$ for the range of $5n < m \le 6n$, while our second bound $\text{cr}(G) \ge 5m - \frac{203}{9}(n-2)$ is even stronger for larger $m>6n$. For $m > 6.77n$, we finally apply the standard probabilistic proof from the BOOK and obtain an improved constant of $c>1/27.48$ in the Crossing Lemma. Note that the previous constant was $1/29$. Although this improvement is not too impressive, we consider our technique as an important new tool, which might be helpful in various other applications.

Published

2024

2. On $k$-planar Graphs without Short Cycles

Author

Bekos, Michael A., Bose, Prosenjit, Büngener, Aaron, Dujmović, Vida, Hoffmann, Michael, Kaufmann, Michael, Morin, Pat, Odak, Saeed, and Weinberger, Alexandra

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics

Abstract

We study the impact of forbidding short cycles to the edge density of $k$-planar graphs; a $k$-planar graph is one that can be drawn in the plane with at most $k$ crossings per edge. Specifically, we consider three settings, according to which the forbidden substructures are $3$-cycles, $4$-cycles or both of them (i.e., girth $\ge 5$). For all three settings and all $k\in\{1,2,3\}$, we present lower and upper bounds on the maximum number of edges in any $k$-planar graph on $n$ vertices. Our bounds are of the form $c\,n$, for some explicit constant $c$ that depends on $k$ and on the setting. For general $k \geq 4$ our bounds are of the form $c\sqrt{k}n$, for some explicit constant $c$. These results are obtained by leveraging different techniques, such as the discharging method, the recently introduced density formula for non-planar graphs, and new upper bounds for the crossing number of $2$-- and $3$-planar graphs in combination with corresponding lower bounds based on the Crossing Lemma., Comment: Appears in the Proceedings of the 32nd International Symposium on Graph Drawing and Network Visualization (GD 2024)

Published

2024

3. Min-$k$-planar Drawings of Graphs

Author

Binucci, Carla, Büngener, Aaron, Di Battista, Giuseppe, Didimo, Walter, Dujmović, Vida, Hong, Seok-Hee, Kaufmann, Michael, Liotta, Giuseppe, Morin, Pat, and Tappini, Alessandra

Subjects

Computer Science - Computational Geometry

Abstract

The study of nonplanar drawings of graphs with restricted crossing configurations is a well-established topic in graph drawing, often referred to as beyond-planar graph drawing. One of the most studied types of drawings in this area are the $k$-planar drawings $(k \geq 1)$, where each edge cannot cross more than $k$ times. We generalize $k$-planar drawings, by introducing the new family of min-$k$-planar drawings. In a min-$k$-planar drawing edges can cross an arbitrary number of times, but for any two crossing edges, one of the two must have no more than $k$ crossings. We prove a general upper bound on the number of edges of min-$k$-planar drawings, a finer upper bound for $k=3$, and tight upper bounds for $k=1,2$. Also, we study the inclusion relations between min-$k$-planar graphs (i.e., graphs admitting min-$k$-planar drawings) and $k$-planar graphs. In our setting we only allow simple drawings, that is, any two edges cross at most once, no two adjacent edges cross, and no three edges intersect at a common crossing point., Comment: Appears in the Proceedings of the 31st International Symposium on Graph Drawing and Network Visualization (GD 2023)

Published

2023

4. Min-k-planar Drawings of Graphs

Author

Binucci, Carla, Büngener, Aaron, Di Battista, Giuseppe, Didimo, Walter, Dujmović, Vida, Hong, Seok-Hee, Kaufmann, Michael, Liotta, Giuseppe, Morin, Pat, Tappini, Alessandra, 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 Chimani, Markus, editor

Published

2023

5. Min-$k$-planar Drawings of Graphs

Author

Binucci, Carla, primary, Büngener, Aaron, additional, Di Battista, Giuseppe, additional, Didimo, Walter, additional, Dujmović, Vida, additional, Hong, Seok-Hee, additional, Kaufmann, Michael, additional, Liotta, Giuseppe, additional, Morin, Pat, additional, and Tappini, Alessandra, additional

Published

2024