Analysis of the susceptible-infected-susceptible epidemic dynamics in networks via the non-backtracking matrix

Abstract We study the stochastic susceptible-infected-susceptible model of epidemic processes on finite directed and weighted networks with arbitrary structure. We present a new lower bound on the exponential rate at which the probabilities of nodes being infected decay over time. This bound is directly related to the leading eigenvalue of a matrix that depends on the non-backtracking and incidence matrices of the network. The dimension of this matrix is $N+M$, where $N$ and $M$ are the number of nodes and edges, respectively. We show that this new lower bound improves on an existing bound corresponding to the so-called quenched mean-field theory. Although the bound obtained from a recently developed second-order moment-closure technique requires the computation of the leading eigenvalue of an $N^2\times N^2$ matrix, we illustrate in our numerical simulations that the new bound is tighter, while being computationally less expensive for sparse networks. We also present the expression for the corresponding epidemic threshold in terms of the adjacency matrix of the line graph and the non-backtracking matrix of the given network.

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The analysis of epidemic spreading on clique-overlapping growth network

International Journal of Modern Physics B ◽

10.1142/s0217979220502355 ◽

2020 ◽

Vol 34 (26) ◽

pp. 2050235

Author(s):

Zhenzhou Lin

Keyword(s):

Theoretical Analysis ◽

Mean Field Theory ◽

Mean Field ◽

Epidemic Outbreak ◽

Epidemic Spreading ◽

Epidemic Threshold ◽

Epidemic Dynamics ◽

Immunization Strategies ◽

The Mean ◽

Real Complex

In this paper, we propose a new clique-overlapping growth network and study the epidemic spreading on it. We verify by simulation and theoretical analysis that the degree distribution follows a power-law form. Then, we have simulated the epidemic dynamics in this clique-overlapping growth network. Based on the mean-field theory, we have obtained the theoretical epidemic threshold. We find that the epidemic threshold is related to the evolution mechanism of the network model. The theoretical analysis is well consistent with the simulation results. The results in this model can help people understand the epidemic spreading of various processes, such as infectious diseases, computer viruses, gossips, and so on in real complex networks. Moreover, the appropriate immunization strategies can also be designed based on our results, to hold back the trend of epidemic outbreak.

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Model of fractal aggregates induced by shear

Thermal Science ◽

10.2298/tsci1305403w ◽

2013 ◽

Vol 17 (5) ◽

pp. 1403-1408 ◽

Cited By ~ 2

Author(s):

Zhanhong Wan ◽

Jiawang Chen ◽

Zhenjiang Youc ◽

Zhiyuan Lia

Keyword(s):

Evolution Equations ◽

Mean Field Theory ◽

Mean Field ◽

Fractal Dimensions ◽

Expansion Method ◽

Geometric Standard Deviation ◽

Order Moment ◽

Fractal Structures ◽

Powerful Approach ◽

Fractal Characteristics

It is an undoubted fact that particle aggregates from marine, aerosol, and engineering systems have fractal structures. In this study, fractal geometry is used to describe the morphology of irregular aggregates. The mean-field theory is employed to solve coagulation kinetic equation of aggregates. The Taylor-expansion method of moments in conjunction with the self-similar fractal characteristics is used to represent the particulate field. The effect of the target fractal dimensions on zeroth-order moment, second-order moment, and geometric standard deviation of the aggregates is explored. Results show that the developed moment method is an efficient and powerful approach to solving such evolution equations.

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Contagion Processes Over Temporal Networks With Time-Varying Backbones

Volume 2: Modeling and Control of Engine and Aftertreatment Systems; Modeling and Control of IC Engines and Aftertreatment Systems; Modeling and Validation; Motion Planning and Tracking Control; Multi-Agent and Networked Systems; Renewable and Smart Energy Systems; Thermal Energy Systems; Uncertain Systems and Robustness; Unmanned Ground and Aerial Vehicles; Vehicle Dynamics and Stability; Vibrations: Modeling, Analysis, and Control ◽

10.1115/dscc2019-9054 ◽

2019 ◽

Author(s):

Matthieu Nadini ◽

Alessandro Rizzo ◽

Maurizio Porfiri

Keyword(s):

Mean Field Theory ◽

Mean Field ◽

Behavioral Changes ◽

Time Varying ◽

Temporal Network ◽

Temporal Networks ◽

Epidemic Threshold ◽

Human Interactions ◽

Time Varying Networks

Abstract Predicting the diffusion of real-world contagion processes requires a simplified description of human-to-human interactions. Temporal networks offer a powerful means to develop such a mathematically-transparent description. Through temporal networks, one may analytically study the co-evolution of the contagion process and the network topology, as well as incorporate realistic feedback-loop mechanisms related to individual behavioral changes to the contagion. Despite considerable progress, the state-of-the-art does not allow for studying general time-varying networks, where links between individuals dynamically switch to reflect the complexity of social behavior. Here, we tackle this problem by considering a temporal network, in which reducible, associated with node-specific properties, and irreducible links, describing dyadic social ties, simultaneously vary over time. We develop a general mean field theory for the Susceptible-Infected-Susceptible model and conduct an extensive numerical campaign to elucidate the role of network parameters on the average degree of the temporal network and the epidemic threshold. Specifically, we describe how the interplay between reducible and irreducible links influences the disease dynamics, offering insights towards the analysis of complex dynamical networks across science and engineering.

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Epidemic Spreading with Feedback Mechanism and Time Delay under Migration in Scale-Free Networks

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.378.655 ◽

2013 ◽

Vol 378 ◽

pp. 655-661

Author(s):

Tao Li ◽

Yuan Mei Wang

Keyword(s):

Time Delay ◽

Mean Field Theory ◽

Mean Field ◽

Feedback Mechanism ◽

Critical Threshold ◽

Epidemic Spreading ◽

Scale Free ◽

Epidemic Dynamics ◽

Scale Free Networks ◽

The Mean

Taking into account the heterogeneity of the underlying networks, an epidemic model with feedback-mechanism, time delay and migrations of individuals on scale-free networks is presented. First, the epidemic dynamics is analyzed via the mean field theory. The spreading critical threshold and equilibriums are derived. The existence of endemic equilibrium is determined by the spreading threshold. Then, the influences of feedback-mechanism, time delay, migrations of individuals and the heterogeneity of the scale-free networks on the spreading threshold and the epidemic steady-state are studied in detail. Numerical simulations are presented to illustrate the results with the theoretical analysis.

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EPIDEMICS OF SIRS MODEL WITH NONUNIFORM TRANSMISSION ON SCALE-FREE NETWORKS

International Journal of Modern Physics B ◽

10.1142/s021797920905211x ◽

2009 ◽

Vol 23 (09) ◽

pp. 2203-2213 ◽

Cited By ~ 30

Author(s):

C. Y. XIA ◽

S. W. SUN ◽

Z. X. LIU ◽

Z. Q. CHEN ◽

Z. Z. YUAN

Keyword(s):

Disease Transmission ◽

Mean Field Theory ◽

Mean Field ◽

Critical Threshold ◽

Epidemic Threshold ◽

Scale Free ◽

Sirs Epidemic Model ◽

Sirs Model ◽

Scale Free Networks ◽

The Mean

We investigate the effect of nonuniform transmission on the critical threshold of susceptible–infected–recovered–susceptible (SIRS) epidemic model on scale-free networks. Based on the mean-field theory, it is observed that the epidemic threshold is not only correlated with the topology of underlying networks, but also with the disease transmission mechanism (e.g., nonuniform transmission). The current findings will significantly help us to further understand the real epidemics taking place on social and technological networks.

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