We model the COVID-19 spreading by running SIR Monte-Carlo simulations in four real face-to-face contact networks. We evaluate the effectiveness of the ‘facemask use’ and ‘vaccination policies’ to curb epidemic spreading. We model the facemask use policy by assuming a lower individual infection probability ββ. We found that while this strategy can delay the disease spreading, it does not significantly reduce the total number of infected individuals (TI), as 80% of the total population still is infected at the end of the epidemic. We model vaccination by setting individual’s infection probability β=0, which is equivalent to remove nodes/individuals from the network. The vaccination was found to be very effective. Even with a partial vaccination of 30% of the population nodes selected considering their centrality measure ranking, such as degree, betweenness, or PageRank, it was possible to reduce the TI of 14%. Finally, yet importantly, random partial vaccination is not effective at all, meaning that most of the unvaccinated population will be infected.
Effective node vaccination and containing strategies to halt SIR epidemic spreading in real-world face-to-face contact networks / Nguyen, Ngoc-Kim-Khanh; Nguyen, Thanh-Trung; Nguyen, Tuan-Anh; Sartori, Fabio; Turchetto, Massimiliano; Scotognella, Francesco; Alfieri, Roberto; Cassi, Davide; Nguyen, Quang; Bellingeri, Michele. - (2022), pp. 1-6. (Intervento presentato al convegno International Conference on Computing and Communication Technologies tenutosi a Ho Chi Minh City, Vietnam nel 20 December – 22 December, 2022) [10.1109/RIVF55975.2022.10013812].
Effective node vaccination and containing strategies to halt SIR epidemic spreading in real-world face-to-face contact networks
Turchetto, Massimiliano;Alfieri, Roberto;Cassi, Davide;Bellingeri, Michele
2022-01-01
Abstract
We model the COVID-19 spreading by running SIR Monte-Carlo simulations in four real face-to-face contact networks. We evaluate the effectiveness of the ‘facemask use’ and ‘vaccination policies’ to curb epidemic spreading. We model the facemask use policy by assuming a lower individual infection probability ββ. We found that while this strategy can delay the disease spreading, it does not significantly reduce the total number of infected individuals (TI), as 80% of the total population still is infected at the end of the epidemic. We model vaccination by setting individual’s infection probability β=0, which is equivalent to remove nodes/individuals from the network. The vaccination was found to be very effective. Even with a partial vaccination of 30% of the population nodes selected considering their centrality measure ranking, such as degree, betweenness, or PageRank, it was possible to reduce the TI of 14%. Finally, yet importantly, random partial vaccination is not effective at all, meaning that most of the unvaccinated population will be infected.| File | Dimensione | Formato | |
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