16 research outputs found
Transforming planar graph drawings while maintaining height
There are numerous styles of planar graph drawings, notably straight-line
drawings, poly-line drawings, orthogonal graph drawings and visibility
representations. In this note, we show that many of these drawings can be
transformed from one style to another without changing the height of the
drawing. We then give some applications of these transformations
B-VPG Representation of AT-free Outerplanar Graphs
B-VPG graphs are intersection graphs of axis-parallel line segments in
the plane. In this paper, we show that all AT-free outerplanar graphs are
B-VPG. We first prove that every AT-free outerplanar graph is an induced
subgraph of a biconnected outerpath (biconnected outerplanar graphs whose weak
dual is a path) and then we design a B-VPG drawing procedure for
biconnected outerpaths. Our proofs are constructive and give a polynomial time
B-VPG drawing algorithm for the class.
We also characterize all subgraphs of biconnected outerpaths and name this
graph class "linear outerplanar". This class is a proper superclass of AT-free
outerplanar graphs and a proper subclass of outerplanar graphs with pathwidth
at most 2. It turns out that every graph in this class can be realized both as
an induced subgraph and as a spanning subgraph of (different) biconnected
outerpaths.Comment: A preliminary version, which did not contain the characterization of
linear outerplanar graphs (Section 3), was presented in the
International Conference on Algorithms and Discrete Applied Mathematics
(CALDAM) 2022. The definition of linear outerplanar graphs in this paper
differs from that in the preliminary version and hence Section 4 is ne
A Polynomial-time Algorithm for Outerplanar Diameter Improvement
The Outerplanar Diameter Improvement problem asks, given a graph and an
integer , whether it is possible to add edges to in a way that the
resulting graph is outerplanar and has diameter at most . We provide a
dynamic programming algorithm that solves this problem in polynomial time.
Outerplanar Diameter Improvement demonstrates several structural analogues to
the celebrated and challenging Planar Diameter Improvement problem, where the
resulting graph should, instead, be planar. The complexity status of this
latter problem is open.Comment: 24 page
Straightening out planar poly-line drawings
We show that any -monotone poly-line drawing can be straightened out while
maintaining -coordinates and height. The width may increase much, but we
also show that on some graphs exponential width is required if we do not want
to increase the height. Likewise -monotonicity is required: there are
poly-line drawings (not -monotone) that cannot be straightened out while
maintaining the height. We give some applications of our result.Comment: The main result turns out to be known (Pach & Toth, J. Graph Theory
2004, http://onlinelibrary.wiley.com/doi/10.1002/jgt.10168/pdf
Upward and Orthogonal Planarity are W[1]-hard Parameterized by Treewidth
Upward planarity testing and Rectilinear planarity testing are central
problems in graph drawing. It is known that they are both NP-complete, but XP
when parameterized by treewidth. In this paper we show that these two problems
are W[1]-hard parameterized by treewidth, which answers open problems posed in
two earlier papers. The key step in our proof is an analysis of the
All-or-Nothing Flow problem, a generalization of which was used as an
intermediate step in the NP-completeness proof for both planarity testing
problems. We prove that the flow problem is W[1]-hard parameterized by
treewidth on planar graphs, and that the existing chain of reductions to the
planarity testing problems can be adapted without blowing up the treewidth. Our
reductions also show that the known -time algorithms cannot be
improved to run in time unless ETH fails.Comment: Appears in the Proceedings of the 31st International Symposium on
Graph Drawing and Network Visualization (GD 2023