Global Majority Consensus by Local Majority Polling on Graphs of a Given Degree Sequence

Abstract

Suppose in a graph G vertices can be either red or blue. Let k be odd. At each time step, each vertex v in G polls k random neighbours and takes the majority colour. If it doesn't have k neighbours, it simply polls all of them, or all less one if the degree of v is even. We study this protocol on graphs of a given degree sequence, in the following setting: initially each vertex of G is red independently with probability α < 12, and is otherwise blue. We show that if α is sufficiently biased, then with high probability consensus is reached on the initial global majority within O(k k n) steps if 5 ≤ k ≤ d, and O(d d n) steps if k > d. Here, d≥ 5 is the effective minimum degree, the smallest integer which occurs (n) times in the degree sequence. We further show that on such graphs, any local protocol in which a vertex does not change colour if all its neighbours have that same colour, takes time at least (d d n), with high probability. Additionally, we demonstrate how the technique for the above sparse graphs can be applied in a straightforward manner to get bounds for the Erdos-R\'enyi random graphs in the connected regime.