On $(t,r)$ broadcast domination of certain grid graphs

TL;DR

This paper investigates the $(t,r)$ broadcast domination number in specific graphs, extending classical domination concepts by incorporating signal decay and multiple towers, with results on paths, grid graphs, and lattice structures.

Contribution

It introduces new bounds and exact values for the $(t,r)$ broadcast domination number in various graph classes, expanding understanding of broadcast domination.

Findings

Derived bounds for grid graphs and paths

Computed exact $(t,r)$ broadcast domination numbers for specific lattices

Extended classical domination concepts with signal decay models

Abstract

Let $G=( V(G), E(G) )$ be a connected graph with vertex set $V(G)$ and edge set $E(G)$. We say a subset $D$ of $V(G)$ dominates $G$ if every vertex in $V \setminus D$ is adjacent to a vertex in $D$. A generalization of this concept is $(t,r)$ broadcast domination. We designate certain vertices to be towers of signal strength $t$, which send out signal to neighboring vertices with signal strength decaying linearly as the signal traverses the edges of the graph. We let $\mathbb{T}$ be the set of all towers, and we define the signal received by a vertex $v\in V(G)$ from a tower $w \in \mathbb T$ to be $f(v)=\sum_{w\in \mathbb{T}}max(0,t-d(v,w))$. Blessing, Insko, Johnson, Mauretour (2014) defined a $(t,r)$ broadcast dominating set, or a $(t,r) $ broadcast, on $G$ as a set $\mathbb{T} \subseteq V(G) $ such that $f(v)\geq r$ for all $v\in V(G)$. The minimal cardinality of a $(t, r)$ broadcast on $G$ is called the $(t, r)$ broadcast domination number of $G$. In this paper, we present our research on the $(t,r)$ broadcast domination number for certain graphs including paths, grid graphs, the slant lattice, and the king's lattice.