Activity-driven model

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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 ${\displaystyle j}$ (out of ${\displaystyle N}$ total) has its activity potential ${\displaystyle x_i}$ drawn from a given distribution ${\displaystyle F(x)}$. A sequence of timesteps unfolds, and in each timestep each node ${\displaystyle j}$ forms ties to ${\displaystyle m}$ random other nodes at rate ${\displaystyle a_i=\eta x_i}$ (more precisely, it does so with probability ${\displaystyle a_i\mathrm{\Delta }t}$ per timestep). All links are then deleted after each timestep.

Properties of time-aggregated network snapshots are able to be studied in terms of ${\displaystyle F(x)}$. For example, since each node ${\displaystyle j}$ after ${\displaystyle T}$ timesteps will have on average ${\displaystyle m\eta x_{i}T}$ outgoing links, the degree distribution after ${\displaystyle T}$ timesteps in the time-aggregated network will be related to the activity-potential distribution by

${\displaystyle P_T(k)\propto F\left(\frac{k}{m\eta T}\right).}$

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:

${\displaystyle \frac{\beta }{\lambda }>\frac{2⟨a⟩}{⟨a⟩+\sqrt{⟨a^2⟩}},}$

where ${\displaystyle \beta }$ is the per-contact transmission probability, ${\displaystyle \lambda }$ is the per-timestep recovery probability, and (${\displaystyle ⟨a⟩}$, ${\displaystyle ⟨a^2⟩}$) are the first and second moments of the random activity-rate ${\displaystyle a_j}$.

A 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.

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