766 research outputs found
Perfect Graphs
This chapter is a survey on perfect graphs with an algorithmic flavor. Our emphasis is on important classes of perfect graphs for which there are fast and efficient recognition and optimization algorithms. The classes of graphs we discuss in this chapter are chordal, comparability, interval, perfectly orderable, weakly chordal, perfectly contractile, and chi-bound graphs. For each of these classes, when appropriate, we discuss the complexity of the recognition algorithm and algorithms for finding a minimum coloring, and a largest clique in the graph and its complement
Coloring Artemis graphs
We consider the class A of graphs that contain no odd hole, no antihole, and
no ``prism'' (a graph consisting of two disjoint triangles with three disjoint
paths between them). We show that the coloring algorithm found by the second
and fourth author can be implemented in time O(n^2m) for any graph in A with n
vertices and m edges, thereby improving on the complexity proposed in the
original paper
Precoloring co-Meyniel graphs
The pre-coloring extension problem consists, given a graph and a subset
of nodes to which some colors are already assigned, in finding a coloring of
with the minimum number of colors which respects the pre-coloring
assignment. This can be reduced to the usual coloring problem on a certain
contracted graph. We prove that pre-coloring extension is polynomial for
complements of Meyniel graphs. We answer a question of Hujter and Tuza by
showing that ``PrExt perfect'' graphs are exactly the co-Meyniel graphs, which
also generalizes results of Hujter and Tuza and of Hertz. Moreover we show
that, given a co-Meyniel graph, the corresponding contracted graph belongs to a
restricted class of perfect graphs (``co-Artemis'' graphs, which are
``co-perfectly contractile'' graphs), whose perfectness is easier to establish
than the strong perfect graph theorem. However, the polynomiality of our
algorithm still depends on the ellipsoid method for coloring perfect graphs
Even and odd pairs in comparability and in P4-comparability graphs
AbstractWe characterize even and odd pairs in comparability and in P4-comparability graphs. The characterizations lead to simple algorithms for deciding whether a given pair of vertices forms an even or odd pair in these classes of graphs. The complexities of the proposed algorithms are O(n + m) for comparability graphs and O(n2m) for P4-comparability graphs. The former represents an improvement over a recent algorithm of complexity O(nm)
Contractions in perfect graph
In this paper, we characterize the class of {\em contraction perfect} graphs
which are the graphs that remain perfect after the contraction of any edge set.
We prove that a graph is contraction perfect if and only if it is perfect and
the contraction of any single edge preserves its perfection. This yields a
characterization of contraction perfect graphs in terms of forbidden induced
subgraphs, and a polynomial algorithm to recognize them. We also define the
utter graph which is the graph whose stable sets are in bijection with
the co-2-plexes of , and prove that is perfect if and only if is
contraction perfect.Comment: 11 pages, 4 figure
Detecting wheels
A \emph{wheel} is a graph made of a cycle of length at least~4 together with
a vertex that has at least three neighbors in the cycle. We prove that the
problem whose instance is a graph and whose question is "does contains
a wheel as an induced subgraph" is NP-complete. We also settle the complexity
of several similar problems
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Graph Theory
This is the report on an Oberwolfach conference on graph theory, held 16-22 January 2005. There were three main components to the event: 5-minute presentations, lectures, and workshops. All participants were asked to give a 5-minute presentation of their interests on the first day, and subsequent days were divided into lectures and workshops. The latter ranged over many different topics, but the main three topics were: infinite graphs, topological methods and their use to prove theorems in graph theory, and Rota’s conjecture for matroids
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