36 research outputs found
Two-Page Book Embeddings of 4-Planar Graphs
Back in the Eighties, Heath showed that every 3-planar graph is
subhamiltonian and asked whether this result can be extended to a class of
graphs of degree greater than three. In this paper we affirmatively answer this
question for the class of 4-planar graphs. Our contribution consists of two
algorithms: The first one is limited to triconnected graphs, but runs in linear
time and uses existing methods for computing hamiltonian cycles in planar
graphs. The second one, which solves the general case of the problem, is a
quadratic-time algorithm based on the book-embedding viewpoint of the problem.Comment: 21 pages, 16 Figures. A shorter version is to appear at STACS 201
On Optimal 2- and 3-Planar Graphs
A graph is -planar if it can be drawn in the plane such that no edge is
crossed more than times. While for , optimal -planar graphs, i.e.,
those with vertices and exactly edges, have been completely
characterized, this has not been the case for . For and ,
upper bounds on the edge density have been developed for the case of simple
graphs by Pach and T\'oth, Pach et al. and Ackerman, which have been used to
improve the well-known "Crossing Lemma". Recently, we proved that these bounds
also apply to non-simple - and -planar graphs without homotopic parallel
edges and self-loops.
In this paper, we completely characterize optimal - and -planar graphs,
i.e., those that achieve the aforementioned upper bounds. We prove that they
have a remarkably simple regular structure, although they might be non-simple.
The new characterization allows us to develop notable insights concerning new
inclusion relationships with other graph classes
Four Pages Are Indeed Necessary for Planar Graphs
An embedding of a graph in a book consists of a linear order of its vertices
along the spine of the book and of an assignment of its edges to the pages of
the book, so that no two edges on the same page cross. The book thickness of a
graph is the minimum number of pages over all its book embeddings. Accordingly,
the book thickness of a class of graphs is the maximum book thickness over all
its members. In this paper, we address a long-standing open problem regarding
the exact book thickness of the class of planar graphs, which previously was
known to be either three or four. We settle this problem by demonstrating
planar graphs that require four pages in any of their book embeddings, thus
establishing that the book thickness of the class of planar graphs is four
Book Embeddings of Nonplanar Graphs with Small Faces in Few Pages
An embedding of a graph in a book, called book embedding, consists of a linear ordering of its vertices along the spine of the book and an assignment of its edges to the pages of the book, so that no two edges on the same page cross. The book thickness of a graph is the minimum number of pages over all its book embeddings. For planar graphs, a fundamental result is due to Yannakakis, who proposed an algorithm to compute embeddings of planar graphs in books with four pages. Our main contribution is a technique that generalizes this result to a much wider family of nonplanar graphs, which is characterized by a biconnected skeleton of crossing-free edges whose faces have bounded degree. Notably, this family includes all 1-planar and all optimal 2-planar graphs as subgraphs. We prove that this family of graphs has bounded book thickness, and as a corollary, we obtain the first constant upper bound for the book thickness of optimal 2-planar graphs