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Published in 2019 at "Scientific Reports"
DOI: 10.1038/s41598-019-38722-4
Abstract: The networked structure of contacts shapes the spreading of epidemic processes. Recent advances on network theory have improved our understanding of the epidemic processes at large scale. The relevance of several considerations still needs to… read more here.
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Published in 2022 at "Chaos"
DOI: 10.1063/5.0098384
Abstract: Optimizing the allocation of protection resources to control the spreading process in networks is a central problem in public health and network security. In this paper, we propose a comprehensive adjustable resource allocation mechanism in… read more here.
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Published in 2023 at "Chaos"
DOI: 10.1063/5.0142386
Abstract: Epidemic spreading processes on dynamic multiplex networks provide a more accurate description of natural spreading processes than those on single layered networks. To describe the influence of different individuals in the awareness layer on epidemic… read more here.
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Published in 2019 at "Chinese Physics B"
DOI: 10.1088/1674-1056/ab53ce
Abstract: Human settlements are embedded in the traffic networks with hierarchical structure. In order to understand the spreading mechanism of infectious disease and deploy control measures, the susceptible-infected-removed spreading process is studied with agents moving globally… read more here.
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Published in 2023 at "Physical review. E"
DOI: 10.1103/physreve.107.024312
Abstract: Human contact behaviors involve both dormant and active processes. The dormant (active) process goes from the disappearance (creation) to the creation (disappearance) of an edge. The dormant (active) time is the elapsed time since the… read more here.
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Published in 2017 at "Physical review letters"
DOI: 10.1103/physrevlett.118.128301
Abstract: A general formalism is introduced to allow the steady state of non-Markovian processes on networks to be reduced to equivalent Markovian processes on the same substrates. The example of an epidemic spreading process is considered… read more here.
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Published in 2023 at "IEEE Control Systems Letters"
DOI: 10.1109/lcsys.2022.3199165
Abstract: In this letter, we consider an epidemic model for two competitive viruses spreading over a metapopulation network, termed the ‘bivirus model’ for convenience. The dynamics are described by a networked continuous-time dynamical system, with each… read more here.
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Published in 2022 at "IEEE transactions on cybernetics"
DOI: 10.1109/tcyb.2022.3198732
Abstract: Understanding the feedback loop that links the spatiotemporal spread of infectious diseases and human behavior is an open problem. To study this problem, we develop a multiplex framework that couples epidemic spreading across subpopulations in… read more here.
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Published in 2022 at "International Journal of Modern Physics C"
DOI: 10.1142/s012918312250111x
Abstract: As COVID-19 spread globally in 2020, the interaction between the traffic dynamics and the spread of the epidemic has attracted much attention. However, controlling the spread of the epidemic remains a challenging issue. In this… read more here.
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Published in 2020 at "Acta Physica Polonica B"
DOI: 10.5506/aphyspolb.51.1853
Abstract: In recent time, an infectious disease spreads by making the contact with the infected agent in a population. This contact may be affected by the movement of the infected agents in any geographical region. Most… read more here.