Author: Azizi, Asma; Montalvo, Cesar; Espinoza, Baltazar; Kang, Yun; Castillo-Chavez, Carlos
Title: Epidemics on networks: Reducing disease transmission using health emergency declarations and peer communication Document date: 2019_12_11
ID: 4uy1w3oj_25
Snippet: The spread of infection on Scale-free network G S is faster than for the other two network topologies. Moreno et al. (Moreno et al., 2002) , modeled infection with immunity on Scale-free and Small-world networks, they observed that the spread of infection on Scale-free complex networks is faster than that of Small-world networks due to a lack of epidemic threshold for network G S ; large connectivity fluctuations (heterogeneity in degree) on this.....
Document: The spread of infection on Scale-free network G S is faster than for the other two network topologies. Moreno et al. (Moreno et al., 2002) , modeled infection with immunity on Scale-free and Small-world networks, they observed that the spread of infection on Scale-free complex networks is faster than that of Small-world networks due to a lack of epidemic threshold for network G S ; large connectivity fluctuations (heterogeneity in degree) on this network causes stronger outbreak incidence (Moreno et al., 2002) . Our result is also related to (Chowell & Castillo-Chavez, 2003) , in which Chowell et al. tested the severity of an outbreak using an SIR model over a family of Small-world networks and an Scale-free network found out that the worst case scenarios (highest infection rate) are observed in the most heterogeneous network, namely, Scale-free networks.
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