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Domination and its variations are widely studied graph optimization problems. In a graph
G = (V;E), a set D V is called a dominating set if every vertex not in D has a neighbour
in D. The MI N IMUM D OMI NAT I O N problem requires to compute a minimum cardinality
dominating set of G. In this thesis, we studied the algorithmic results for five variants of
domination. The variants of domination studied in this thesis are based on pairing each vertex
of a dominating set with some vertex at distance at most 2. The variants of domination studied
in the thesis are (i) paired domination, (ii) semipaired domination, (iii) disjunctive paired
domination, (iv) semitotal domination, and (v) defensive domination.
Let G = (V;E) be a graph and D be a subset of V . Then D is called (i) a paired dominating
set if D is a dominating set and G[D] has a perfect matching; (ii) a semipaired dominating set
if D is a dominating set and D can be partitioned into 2 elements subsets such that distance
between vertices in each two element set is at most 2; (iii) a disjunctive paired dominating
set if every vertex v =2 D is either adjacent to a vertex of D or there are two vertices in D at
distance two from v in G and G[D] has a perfect matching; (iv) a semitotal dominating set
if D is a dominating set and for each vertex x 2 D, there exists another vertex y 2 D such
that the distance between x and y is at most 2 in G; (v) a k-defensive dominating set if for a
positive integer k, any k distinct vertices of V can be mapped to k distinct vertices of D, so
that each vertex v is mapped to a vertex in the closed neighbourhood of v.
Unfortunately, all these five variants of domination are NP-hard for general graphs and some
restricted graph classes. Some of these variants are well studied in the literature, but there
are many gaps which need filling. In this thesis, we obtain various algorithmic results for
these variants of domination. For each of these variants, we identify graph classes where
these problems remain NP-hard and designed efficient algorithms for these problems in some
graph classes. We also study the approximation algorithm and approximation hardness of
these problems and obtain various results. |
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