Your search keyword '"Faqeeh, Ali"' showing total 3 results

1. Epidemic Spreading and Digital Contact Tracing: Effects of Heterogeneous Mixing and Quarantine Failures

Author

Rizi, Abbas K., Faqeeh, Ali, Badie-Modiri, Arash, and Kivelä, Mikko

Subjects

Physics - Physics and Society, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Computer Science - Social and Information Networks, Mathematics - Probability

Abstract

Contact tracing via digital tracking applications installed on mobile phones is an important tool for controlling epidemic spreading. Its effectivity can be quantified by modifying the standard methodology for analyzing percolation and connectivity of contact networks. We apply this framework to networks with varying degree distributions, numbers of application users, and probabilities of quarantine failures. Further, we study structured populations with homophily and heterophily and the possibility of degree-targeted application distribution. Our results are based on a combination of explicit simulations and mean-field analysis. They indicate that there can be major differences in the epidemic size and epidemic probabilities which are equivalent in the normal SIR processes. Further, degree heterogeneity is seen to be especially important for the epidemic threshold but not as much for the epidemic size. The probability that tracing leads to quarantines is not as important as the application adoption rate. Finally, both strong homophily and especially heterophily with regard to application adoption can be detrimental. Overall, epidemic dynamics are very sensitive to all of the parameter values we tested out, which makes the problem of estimating the effect of digital contact tracing an inherently multidimensional problem.

Published

2021

2. Emergence of coexisting percolating clusters in networks

Author

Faqeeh, Ali, Melnik, Sergey, Colomer-de-Simón, Pol, and Gleeson, James P.

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Physics - Physics and Society

Abstract

It is commonly assumed in percolation theories that at most one percolating cluster can exist in a network. We introduce sausage-like networks (SLNs), an ensemble of synthetic modular networks in which more than one percolating cluster can appear. We show that coexisting percolating clusters (CPCs) emerge in such networks due to limited mixing, i.e., a small number of interlinks between pairs of modules. We develop an approach called modular message passing (MMP) to describe and verify these observations. We demonstrate that the appearance of CPCs is an important source of inaccuracy in the previously introduced percolation theories, such as the message passing (MP) approach. Moreover, we show that the MMP theory improves significantly over the predictions of MP for percolation on synthetic networks with limited mixing and also on several real-world networks. These findings have important implications for understanding the robustness of networks and in quantifying epidemic outbreaks in the susceptible-infected-recovered (SIR) model of disease spread., Comment: 5 pages, 3 figures

Published

2015

3. Epidemic spreading and digital contact tracing: Effects of heterogeneous mixing and quarantine failures

Author

Rizi, Abbas K., Faqeeh, Ali, Badie-Modiri, Arash, Kivelä, Mikko, Department of Computer Science, Professorship Kivelä Mikko, Computer Science Professors, Aalto-yliopisto, and Aalto University

Subjects

Social and Information Networks (cs.SI), FOS: Computer and information sciences, Physics - Physics and Society, Statistical Mechanics (cond-mat.stat-mech), Probability (math.PR), FOS: Mathematics, FOS: Physical sciences, Computer Science - Social and Information Networks, Physics and Society (physics.soc-ph), Disordered Systems and Neural Networks (cond-mat.dis-nn), Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Mathematics - Probability

Abstract

Funding Information: The simulations presented above were performed using computer resources within the Aalto University School of Science “Science-IT” project. A.F. acknowledges funding by Science Foundation Ireland Grant No. 16/IA/4470. Publisher Copyright: © 2022 American Physical Society. Contact tracing via digital tracking applications installed on mobile phones is an important tool for controlling epidemic spreading. Its effectivity can be quantified by modifying the standard methodology for analyzing percolation and connectivity of contact networks. We apply this framework to networks with varying degree distributions, numbers of application users, and probabilities of quarantine failures. Further, we study structured populations with homophily and heterophily and the possibility of degree-targeted application distribution. Our results are based on a combination of explicit simulations and mean-field analysis. They indicate that there can be major differences in the epidemic size and epidemic probabilities which are equivalent in the normal susceptible-infectious-recovered (SIR) processes. Further, degree heterogeneity is seen to be especially important for the epidemic threshold but not as much for the epidemic size. The probability that tracing leads to quarantines is not as important asthe application adoption rate. Finally, both strong homophily and especially heterophily with regard to application adoption can be detrimental. Overall, epidemic dynamics are very sensitive to all of the parameter values we tested out, which makes the problem of estimating the effect of digital contact tracing an inherently multidimensional problem.

Published

2022