2,246 research outputs found
Rainbow domination and related problems on some classes of perfect graphs
Let and let be a graph. A function is a rainbow function if, for every vertex with
, . The rainbow domination number
is the minimum of over all rainbow
functions. We investigate the rainbow domination problem for some classes of
perfect graphs
Total Domination, Separated Clusters, CD-Coloring: Algorithms and Hardness
Domination and coloring are two classic problems in graph theory. The major
focus of this paper is the CD-COLORING problem which combines the flavours of
domination and colouring. Let be an undirected graph. A proper vertex
coloring of is a if each color class has a dominating vertex
in . The minimum integer for which there exists a of
using colors is called the cd-chromatic number, . A set
is a total dominating set if any vertex in has a neighbor
in . The total domination number, of is the minimum
integer such that has a total dominating set of size . A set
is a if no two vertices in lie at a
distance 2 in . The separated-cluster number, , of is the
maximum integer such that has a separated-cluster of size .
In this paper, first we explore the connection between CD-COLORING and TOTAL
DOMINATION. We prove that CD-COLORING and TOTAL DOMINATION are NP-Complete on
triangle-free -regular graphs for each fixed integer . We also
study the relationship between the parameters and .
Analogous to the well-known notion of `perfectness', here we introduce the
notion of `cd-perfectness'. We prove a sufficient condition for a graph to
be cd-perfect (i.e. , for any induced subgraph
of ) which is also necessary for certain graph classes (like triangle-free
graphs). Here, we propose a generalized framework via which we obtain several
exciting consequences in the algorithmic complexities of special graph classes.
In addition, we settle an open problem by showing that the SEPARATED-CLUSTER is
polynomially solvable for interval graphs
Independent Sets in Asteroidal Triple-Free Graphs
An asteroidal triple (AT) is a set of three vertices such that there is a path between any pair of them avoiding the closed neighborhood of the third. A graph is called AT-free if it does not have an AT. We show that there is an O(n4 ) time algorithm to compute the maximum weight of an independent set for AT-free graphs. Furthermore, we obtain O(n4 ) time algorithms to solve the INDEPENDENT DOMINATING SET and the INDEPENDENT PERFECT DOMINATING SET problems on AT-free graphs. We also show how to adapt these algorithms such that they solve the corresponding problem for graphs with bounded asteroidal number in polynomial time. Finally, we observe that the problems CLIQUE and PARTITION INTO CLIQUES remain NP-complete when restricted to AT-free graphs
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