Radio Number for the Cartesian Product of Two Trees

02/28/2022

∙

Let G be a simple connected graph. For any two vertices u and v, let d(u,v) denote the distance between u and v in G, and let diam(G) denote the diameter of G. A radio-labeling of G is a function f which assigns to each vertex a non-negative integer (label) such that for every distinct vertices u and v in G, it holds that |f(u)-f(v)| ≥ diam(G) - d(u,v) +1. The span of f is the difference between the largest and smallest labels of f(V). The radio number of G, denoted by rn(G), is the smallest span of a radio labeling admitted by G. In this paper, we give a lower bound for the radio number of the Cartesian product of two trees. Moreover, we present three necessary and sufficient conditions, and three sufficient conditions for the product of two trees to achieve this bound. Applying these results, we determine the radio number of the Cartesian product of two stars as well as a path and a star.

READ FULL TEXT

Radio Number for the Cartesian Product of Two Trees

Optimal radio labelings of the Cartesian product of the generalized Peterson graph and tree

Sidorenko-Type Inequalities for Pairs of Trees

Optimal radio labelings of graphs

Hamiltonian chromatic number of trees

Binary scalar products

Arc-disjoint strong spanning subdigraphs in compositions and products of digraphs

Radio labelling of two-branch trees

Radio Number for the Cartesian Product of Two Trees

Related Research

Optimal radio labelings of the Cartesian product of the generalized Peterson graph and tree

Sidorenko-Type Inequalities for Pairs of Trees

Optimal radio labelings of graphs

Hamiltonian chromatic number of trees

Binary scalar products

Arc-disjoint strong spanning subdigraphs in compositions and products of digraphs

Radio labelling of two-branch trees