Phase Transition for the Maki–Thompson Rumour Model on a Small-World Network

We consider the Maki–Thompson model for the stochastic propagation of a rumour within a population. In this model the population is made up of “spreaders”, “ignorants” and “stiflers”; any spreader attempts to pass the rumour to the other individuals via pair-wise interactions and in case the other i...

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Bibliographic Details
Published in:Journal of statistical physics 2017-11, Vol.169 (4), p.846-875
Main Authors: Agliari, Elena, Pachon, Angelica, Rodriguez, Pablo M., Tavani, Flavia
Format: Article
Language:English
Subjects:
Computer simulation
Mathematical and Computational Physics
Mathematical models
Numerical analysis
Phase transitions
Physical Chemistry
Physics
Physics and Astronomy
Population
Propagation
Quantum Physics
Spreaders
Statistical Physics and Dynamical Systems
Theoretical
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Summary:We consider the Maki–Thompson model for the stochastic propagation of a rumour within a population. In this model the population is made up of “spreaders”, “ignorants” and “stiflers”; any spreader attempts to pass the rumour to the other individuals via pair-wise interactions and in case the other individual is an ignorant, it becomes a spreader, while in the other two cases the initiating spreader turns into a stifler. In a finite population the process will eventually reach an equilibrium situation where individuals are either stiflers or ignorants. We extend the original hypothesis of homogenously mixed population by allowing for a small-world network embedding the model, in such a way that interactions occur only between nearest-neighbours. This structure is realized starting from a k -regular ring and by inserting, in the average, c additional links in such a way that k and c are tuneable parameters for the population architecture. We prove that this system exhibits a transition between regimes of localization (where the final number of stiflers is at most logarithmic in the population size) and propagation (where the final number of stiflers grows algebraically with the population size) at a finite value of the network parameter c . A quantitative estimate for the critical value of c is obtained via extensive numerical simulations.
ISSN:0022-4715
1572-9613
DOI:10.1007/s10955-017-1892-x