14 research outputs found
Note on the number of edges in families with linear union-complexity
We give a simple argument showing that the number of edges in the
intersection graph of a family of sets in the plane with a linear
union-complexity is . In particular, we prove for intersection graph of a family of
pseudo-discs, which improves a previous bound.Comment: background and related work is now more complete; presentation
improve
Coloring translates and homothets of a convex body
We obtain improved upper bounds and new lower bounds on the chromatic number
as a linear function of the clique number, for the intersection graphs (and
their complements) of finite families of translates and homothets of a convex
body in \RR^n.Comment: 11 pages, 2 figure
Triangle-free geometric intersection graphs with large chromatic number
Several classical constructions illustrate the fact that the chromatic number
of a graph can be arbitrarily large compared to its clique number. However,
until very recently, no such construction was known for intersection graphs of
geometric objects in the plane. We provide a general construction that for any
arc-connected compact set in that is not an axis-aligned
rectangle and for any positive integer produces a family of
sets, each obtained by an independent horizontal and vertical scaling and
translation of , such that no three sets in pairwise intersect
and . This provides a negative answer to a question of
Gyarfas and Lehel for L-shapes. With extra conditions, we also show how to
construct a triangle-free family of homothetic (uniformly scaled) copies of a
set with arbitrarily large chromatic number. This applies to many common
shapes, like circles, square boundaries, and equilateral L-shapes.
Additionally, we reveal a surprising connection between coloring geometric
objects in the plane and on-line coloring of intervals on the line.Comment: Small corrections, bibliography updat
Coloring intersection graphs of x-monotone curves in the plane
A class of graphs G is χ-bounded if the chromatic number of the graphs in G is bounded by some function of their clique number. We show that the class of intersection graphs of simple families of x-monotone curves in the plane intersecting a vertical line is χ-bounded. As a corollary, we show that the class of intersection graphs of rays in the plane is χ-bounded, and the class of intersection graphs of unit segments in the plane is χ-bounded.National Science Foundation (U.S.) (Postdoctoral Fellowship
Density of Range Capturing Hypergraphs
For a finite set of points in the plane, a set in the plane, and a
positive integer , we say that a -element subset of is captured
by if there is a homothetic copy of such that ,
i.e., contains exactly elements from . A -uniform -capturing
hypergraph has a vertex set and a hyperedge set consisting
of all -element subsets of captured by . In case when and
is convex these graphs are planar graphs, known as convex distance function
Delaunay graphs.
In this paper we prove that for any , any , and any convex
compact set , the number of hyperedges in is at most , where is the number of -element
subsets of that can be separated from the rest of with a straight line.
In particular, this bound is independent of and indeed the bound is tight
for all "round" sets and point sets in general position with respect to
.
This refines a general result of Buzaglo, Pinchasi and Rote stating that
every pseudodisc topological hypergraph with vertex set has
hyperedges of size or less.Comment: new version with a tight result and shorter proo
Coloring Kk-free intersection graphs of geometric objects in the plane
AbstractThe intersection graph of a collection C of sets is the graph on the vertex set C, in which C1,C2∈C are joined by an edge if and only if C1∩C2≠0̸. Erdős conjectured that the chromatic number of triangle-free intersection graphs of n segments in the plane is bounded from above by a constant. Here we show that it is bounded by a polylogarithmic function of n, which is the first nontrivial bound for this problem. More generally, we prove that for any t and k, the chromatic number of every Kk-free intersection graph of n curves in the plane, every pair of which have at most t points in common, is at most (ctlognlogk)clogk, where c is an absolute constant and ct only depends on t. We establish analogous results for intersection graphs of convex sets, x-monotone curves, semialgebraic sets of constant description complexity, and sets that can be obtained as the union of a bounded number of sets homeomorphic to a disk.Using a mix of results on partially ordered sets and planar separators, for large k we improve the best known upper bound on the number of edges of a k-quasi-planar topological graph with n vertices, that is, a graph drawn in the plane with curvilinear edges, no k of which are pairwise crossing. As another application, we show that for every ε>0 and for every positive integer t, there exist δ>0 and a positive integer n0 such that every topological graph with n≥n0 vertices, at least n1+ε edges, and no pair of edges intersecting in more than t points, has at least nδ pairwise intersecting edges
Outerstring graphs are -bounded
An outerstring graph is an intersection graph of curves that lie in a common
half-plane and have one endpoint on the boundary of that half-plane. We prove
that the class of outerstring graphs is -bounded, which means that their
chromatic number is bounded by a function of their clique number. This
generalizes a series of previous results on -boundedness of outerstring
graphs with various additional restrictions on the shape of curves or the
number of times the pairs of curves can cross. The assumption that each curve
has an endpoint on the boundary of the half-plane is justified by the known
fact that triangle-free intersection graphs of straight-line segments can have
arbitrarily large chromatic number.Comment: Introduction extended by a survey of results on (outer)string graphs,
some minor correction