1,286 research outputs found
Partitioning 3-colored complete graphs into three monochromatic cycles
We show in this paper that in every 3-coloring of the edges of Kn all but o(n)
of its vertices can be partitioned into three monochromatic cycles. From this, using
our earlier results, actually it follows that we can partition all the vertices into at
most 17 monochromatic cycles, improving the best known bounds. If the colors of
the three monochromatic cycles must be different then one can cover ( 3
4 â o(1))n
vertices and this is close to best possible
Minimum degree conditions for monochromatic cycle partitioning
A classical result of Erd\H{o}s, Gy\'arf\'as and Pyber states that any
-edge-coloured complete graph has a partition into
monochromatic cycles. Here we determine the minimum degree threshold for this
property. More precisely, we show that there exists a constant such that
any -edge-coloured graph on vertices with minimum degree at least has a partition into monochromatic cycles. We also
provide constructions showing that the minimum degree condition and the number
of cycles are essentially tight.Comment: 22 pages (26 including appendix
Problems and memories
I state some open problems coming from joint work with Paul Erd\H{o}sComment: This is a paper form of the talk I gave on July 5, 2013 at the
centennial conference in Budapest to honor Paul Erd\H{o}
Vertex covering with monochromatic pieces of few colours
In 1995, Erd\H{o}s and Gy\'arf\'as proved that in every -colouring of the
edges of , there is a vertex cover by monochromatic paths of
the same colour, which is optimal up to a constant factor. The main goal of
this paper is to study the natural multi-colour generalization of this problem:
given two positive integers , what is the smallest number
such that in every colouring of the edges of with
colours, there exists a vertex cover of by
monochromatic paths using altogether at most different colours? For fixed
integers and as , we prove that , where is the chromatic number of
the Kneser gr aph . More generally, if one replaces by
an arbitrary -vertex graph with fixed independence number , then we
have , where this time around is the
chromatic number of the Kneser hypergraph . This
result is tight in the sense that there exist graphs with independence number
for which . This is in sharp
contrast to the case , where it follows from a result of S\'ark\"ozy
(2012) that depends only on and , but not on
the number of vertices. We obtain similar results for the situation where
instead of using paths, one wants to cover a graph with bounded independence
number by monochromatic cycles, or a complete graph by monochromatic
-regular graphs
Monochromatic cycle covers in random graphs
A classic result of Erd\H{o}s, Gy\'arf\'as and Pyber states that for every
coloring of the edges of with colors, there is a cover of its vertex
set by at most vertex-disjoint monochromatic cycles. In
particular, the minimum number of such covering cycles does not depend on the
size of but only on the number of colors. We initiate the study of this
phenomena in the case where is replaced by the random graph . Given a fixed integer and , we
show that with high probability the random graph has
the property that for every -coloring of the edges of , there is a
collection of monochromatic cycles covering all the
vertices of . Our bound on is close to optimal in the following sense:
if , then with high probability there are colorings of
such that the number of monochromatic cycles needed to
cover all vertices of grows with .Comment: 24 pages, 1 figure (minor changes, added figure
Coloring Hypergraphs Induced by Dynamic Point Sets and Bottomless Rectangles
We consider a coloring problem on dynamic, one-dimensional point sets: points
appearing and disappearing on a line at given times. We wish to color them with
k colors so that at any time, any sequence of p(k) consecutive points, for some
function p, contains at least one point of each color.
We prove that no such function p(k) exists in general. However, in the
restricted case in which points appear gradually, but never disappear, we give
a coloring algorithm guaranteeing the property at any time with p(k)=3k-2. This
can be interpreted as coloring point sets in R^2 with k colors such that any
bottomless rectangle containing at least 3k-2 points contains at least one
point of each color. Here a bottomless rectangle is an axis-aligned rectangle
whose bottom edge is below the lowest point of the set. For this problem, we
also prove a lower bound p(k)>ck, where c>1.67. Hence for every k there exists
a point set, every k-coloring of which is such that there exists a bottomless
rectangle containing ck points and missing at least one of the k colors.
Chen et al. (2009) proved that no such function exists in the case of
general axis-aligned rectangles. Our result also complements recent results
from Keszegh and Palvolgyi on cover-decomposability of octants (2011, 2012).Comment: A preliminary version was presented by a subset of the authors to the
European Workshop on Computational Geometry, held in Assisi (Italy) on March
19-21, 201
Coloring half-planes and bottomless rectangles
We prove lower and upper bounds for the chromatic number of certain
hypergraphs defined by geometric regions. This problem has close relations to
conflict-free colorings. One of the most interesting type of regions to
consider for this problem is that of the axis-parallel rectangles. We
completely solve the problem for a special case of them, for bottomless
rectangles. We also give an almost complete answer for half-planes and pose
several open problems. Moreover we give efficient coloring algorithms
On some partitioning problems for two-colored point sets
Let S be a two-colored set of n points in general position in the plane. We show that S admits
at least 2 n
17 pairwise disjoint monochromatic triangles with vertices in S and empty of points
of S. We further show that S can be partitioned into 3 n
11 subsets with pairwise disjoint convex
hull such that within each subset all but at most one point have the same color. A lower bound
on the number of subsets needed in any such partition is also given.Postprint (published version
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