Phase Transitions in Biased Opinion Dynamics with 2-choices Rule

Abstract

We consider a model of binary opinion dynamics where one opinion is inherently 'superior' than the other and social agents exhibit a 'bias' towards the superior alternative. Specifically, it is assumed that an agent updates its choice to the superior alternative with probability α >0 irrespective of its current opinion and the opinions of the other agents. With probability 1-α it adopts the majority opinion among two randomly sampled neighbours and itself. We are interested in the time it takes for the network to converge to a consensus state where all the agents adopt the superior alternative. In a fully connected network of size n, we show that irrespective of the initial configuration of the network, the average time to reach consensus scales as (n n) when the bias parameter α is sufficiently high, i.e., α > αc where αc is a threshold parameter that is uniquely characterised. When the bias is low, i.e., when α ∈ (0,αc], we show that the same rate of convergence can only be achieved if the initial proportion of agents with the superior opinion is above certain threshold pc(α). If this is not the case, then we show that the network takes (((n))) time on average to reach consensus. Through numerical simulations we observe similar behaviour for other classes of graphs.