In network science, the activity-driven model is a temporal network model in which each node has a randomly-assigned "activity potential",[1] which governs how it links to other nodes over time.
Each node (out of total) has its activity potential drawn from a given distribution . A sequence of timesteps unfolds, and in each timestep each node forms ties to random other nodes at rate (more precisely, it does so with probability per timestep). All links are then deleted after each timestep.
Properties of time-aggregated network snapshots are able to be studied in terms of . For example, since each node after timesteps will have on average outgoing links, the degree distribution after timesteps in the time-aggregated network will be related to the activity-potential distribution by
Spreading behavior according to the SIS epidemic model was investigated on activity-driven networks, and the following condition was derived for large-scale outbreaks to be possible:
where is the per-contact transmission probability, is the per-timestep recovery probability, and (, ) are the first and second moments of the random activity-rate .
Extensions
editA variety of extensions to the activity-driven model have been studied. One example is activity-driven networks with attractiveness,[2] in which the links that a given node forms do not attach to other nodes at random, but rather with a probability proportional to a variable encoding nodewise attractiveness. Another example is activity-driven networks with memory,[3] in which activity-levels change according to a self-excitation mechanism.
References
edit- ^ Perra, Nicola; B. Gonçalves; R. Pastor-Satorras; A. Vespignani (2012-06-25). "Activity driven modeling of time varying networks".
- ^ Pozzana, Iacopo; K. Sun; N. Perra (2017-10-26). "Epidemic spreading on activity-driven networks with attractiveness". Physical Review E. Vol. 96, no. 4. doi:10.1103/PhysRevE.96.042310.
- ^ Zino, Lorenzo; A. Rizzo; M. Porfiri (2018-12-11). "Modeling Memory Effects in Activity-Driven Networks". SIAM Journal on Applied Dynamical Systems. 17 (4): 2830–2854. doi:10.1137/18M1171485. S2CID 102354985.