Bursty communication patterns facilitate spreading in a threshold-based epidemic dynamics

Bursty communication patterns facilitate spreading in a threshold-based epidemic dynamics

Records of social interactions provide us with new sources of data for understanding how interaction patterns affect collective dynamics. Such human activity patterns are often bursty, i.e., they consist of short periods of intense activity followed by long periods of silence. This burstiness has be...

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Veröffentlicht in:PloS one 2013-07, Vol.8 (7), p.e68629-e68629
Hauptverfasser: Takaguchi, Taro, Masuda, Naoki, Holme, Petter
Format: Artikel
Sprache:eng
Schlagworte:
Activity patterns
Algorithms
Analysis
Biology
Bursting
Communicable Disease Control
Communicable Diseases - epidemiology
Communicable Diseases - transmission
Communication
Communication equipment
Computer Simulation
Disease susceptibility
Epidemics
Health aspects
Human Activities
Humans
Infection
Infectious diseases
Informatics
Interpersonal Relations
Mathematical models
Mathematics
Medicine
Models, Theoretical
Network analysis
Numerical analysis
Numerical simulations
Pathogen
Pathogens
Physics
Silence
Simulation and modeling
Social aspects
Social behavior
Social communication
Social epidemiology
Social factors
Social interactions
Spreading
Studies
Verbal communication
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Beschreibung
Zusammenfassung:Records of social interactions provide us with new sources of data for understanding how interaction patterns affect collective dynamics. Such human activity patterns are often bursty, i.e., they consist of short periods of intense activity followed by long periods of silence. This burstiness has been shown to affect spreading phenomena; it accelerates epidemic spreading in some cases and slows it down in other cases. We investigate a model of history-dependent contagion. In our model, repeated interactions between susceptible and infected individuals in a short period of time is needed for a susceptible individual to contract infection. We carry out numerical simulations on real temporal network data to find that bursty activity patterns facilitate epidemic spreading in our model.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0068629