Paired dominating set

In graph theory, a paired dominating set of a graph $G=(V,E)$ is a dominating set $S$ of vertices such that the induced subgraph $G[S]$ contains at least one perfect matching.^[1] The concept was introduced by Teresa W. Haynes and Peter J. Slater in 1998. The paired domination number, denoted $\gamma _{p}(G)$ , is the minimum cardinality of a paired dominating set of $G$ .

The concept models a situation in which guards are placed at vertices of a graph to dominate (protect) all vertices, with the additional constraint that each guard is assigned another adjacent guard as a backup. This is equivalent to finding a set $M$ of independent edges (a matching) whose endpoints form a dominating set.^[2]

Properties and bounds

Since every paired dominating set is a dominating set, and every dominating set whose induced subgraph has a perfect matching is necessarily a total dominating set, the following chain of inequalities holds for any graph $G$ without isolated vertices:^[1]

\gamma (G)\leq \gamma _{t}(G)\leq \gamma _{p}(G)

where $\gamma (G)$ is the domination number and $\gamma _{t}(G)$ is the total domination number.

Haynes and Slater characterized the triples $(a,b,c)$ of positive integers with $a\leq b\leq c$ for which there exists a graph $G$ satisfying $\gamma (G)=a$ , $\gamma _{t}(G)=b$ , and $\gamma _{p}(G)=c$ .^[1]

Because the endpoints of any maximal matching form a paired dominating set, the paired domination number is bounded above by twice the size of any maximal matching of the graph:^[2]

\gamma _{p}(G)\leq 2\,\nu (G)

where $\nu (G)$ denotes the size of a maximum matching.

Define the family ${\mathcal {F}}$ as the set of graphs obtainable from three nonempty sets of parallel edges, $\{u_{r}v_{r}:r=1,\ldots ,k\}$ , $\{w_{s}x_{s}:s=1,\ldots ,l\}$ , and $\{y_{t}z_{t}:t=1,\ldots ,m\}$ , by connecting each pair of vertices $(v_{r},w_{s})$ , $(x_{s},y_{t})$ , and $(z_{t},u_{r})$ with a path of length two (introducing a new vertex of degree two for each such pair). The original $k+l+m$ edges are called the associated matching of the resulting graph. When $k=l=m=1$ , the resulting graph is the cycle graph $C_{9}$ .

A connected, leafless graph of girth at least seven has a maximal matching whose endpoints form a minimum paired dominating set if and only if it belongs to the family ${\mathcal {F}}$ .^[2]

A consequence of this characterization is that any such graph containing an 8-cycle must contain a specific 18-vertex graph, denoted $P_{18}$ , as an induced subgraph; this occurs precisely when at least two of the parameters $k,l,m$ are at least 2.^[2]

Computational complexity

The problem of determining the paired domination number of a graph is NP-complete.^[1]

Paired dominating set

Properties and bounds

Computational complexity

References

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