Analytically solvable model of spreading dynamics with Non-Poissonian processes

Hang Hyun Jo, Juan I. Perotti, Kimmo Kaski, János Kertész

Research output: Contribution to journalArticlepeer-review

Abstract (may include machine translation)

Non-Poissonian bursty processes are ubiquitous in natural and social phenomena, yet little is known about their effects on the large-scale spreading dynamics. In order to characterize these effects, we devise an analytically solvable model of susceptible-infected spreading dynamics in infinite systems for arbitrary inter-event time distributions and for the whole time range. Our model is stationary from the beginning, and the role of the lower bound of inter-event times is explicitly considered. The exact solution shows that for early and intermediate times, the burstiness accelerates the spreading as compared to a Poisson-like process with the same mean and same lower bound of inter-event times. Such behavior is opposite for late-time dynamics in finite systems, where the power-law distribution of inter-event times results in a slower and algebraic convergence to a fully infected state in contrast to the exponential decay of the Poisson-like process. We also provide an intuitive argument for the exponent characterizing algebraic convergence.

Original languageEnglish
Article number011041
JournalPhysical Review X
Volume4
Issue number1
DOIs
StatePublished - 2014

Keywords

  • Complex systems

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