Stability of Spreading Processes over Time-Varying Large-Scale Networks

In this paper, we analyze the dynamics of spreading processes taking place over time-varying networks. A common approach to model time-varying networks is via Markovian random graph processes. This modeling approach presents the following limitation: Markovian random graphs can only replicate switching patterns with exponential inter-switching times, while in real applications these times are usually far from exponential. In this paper, we introduce a flexible and tractable extended family of processes able to replicate, with arbitrary accuracy, any distribution of inter-switching times. We then study the stability of spreading processes in this extended family. We first show that a direct analysis based on Itô's formula provides stability conditions in terms of the eigenvalues of a matrix whose size grows exponentially with the number of edges. To overcome this limitation, we derive alternative stability conditions involving the eigenvalues of a matrix whose size grows linearly with the number of nodes. Based on our results, we also show that heuristics based on aggregated static networks approximate the epidemic threshold more accurately as the number of nodes grows, or the temporal volatility of the random graph process is reduced. Finally, we illustrate our findings via numerical simulations.

[1]  Donald F. Towsley,et al.  Modeling malware spreading dynamics , 2003, IEEE INFOCOM 2003. Twenty-second Annual Joint Conference of the IEEE Computer and Communications Societies (IEEE Cat. No.03CH37428).

[2]  N. Harris STOCHASTIC CONTROL , 2011 .

[3]  Alain Barrat,et al.  How memory generates heterogeneous dynamics in temporal networks , 2014, Physical review. E, Statistical, nonlinear, and soft matter physics.

[4]  Francesco De Pellegrini,et al.  Not always sparse: Flooding time in partially connected mobile ad hoc networks , 2014, 2014 12th International Symposium on Modeling and Optimization in Mobile, Ad Hoc, and Wireless Networks (WiOpt).

[5]  Fan Chung Graham,et al.  On the Spectra of General Random Graphs , 2011, Electron. J. Comb..

[6]  Jari Saramäki,et al.  Small But Slow World: How Network Topology and Burstiness Slow Down Spreading , 2010, Physical review. E, Statistical, nonlinear, and soft matter physics.

[7]  D. Hinrichsen,et al.  Robust Stability of positive continuous time systems , 1996 .

[8]  D. Cox A use of complex probabilities in the theory of stochastic processes , 1955, Mathematical Proceedings of the Cambridge Philosophical Society.

[9]  Ren Asmussen,et al.  Fitting Phase-type Distributions via the EM Algorithm , 1996 .

[10]  Pierre Fraigniaud,et al.  Parsimonious flooding in dynamic graphs , 2009, PODC '09.

[11]  Chinwendu Enyioha,et al.  Optimal vaccine allocation to control epidemic outbreaks in arbitrary networks , 2013, 52nd IEEE Conference on Decision and Control.

[12]  Piet Van Mieghem,et al.  Epidemic processes in complex networks , 2014, ArXiv.

[13]  Luc Berthouze,et al.  Modelling approaches for simple dynamic networks and applications to disease transmission models , 2012, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[14]  George J. Pappas,et al.  Analysis and Control of Epidemics: A Survey of Spreading Processes on Complex Networks , 2015, IEEE Control Systems.

[15]  M. Fragoso,et al.  Continuous-Time Markov Jump Linear Systems , 2012 .

[16]  Christos Faloutsos,et al.  Epidemic thresholds in real networks , 2008, TSEC.

[17]  Attila Rákos,et al.  Epidemic spreading in evolving networks. , 2010, Physical review. E, Statistical, nonlinear, and soft matter physics.

[18]  P. Holme,et al.  Predicting and controlling infectious disease epidemics using temporal networks , 2013, F1000prime reports.

[19]  M. A. Rami,et al.  Stability Criteria for SIS Epidemiological Models under Switching Policies , 2013, 1306.0135.

[20]  P. Van Mieghem,et al.  Virus Spread in Networks , 2009, IEEE/ACM Transactions on Networking.

[21]  Christos Faloutsos,et al.  Epidemic spreading in real networks: an eigenvalue viewpoint , 2003, 22nd International Symposium on Reliable Distributed Systems, 2003. Proceedings..

[22]  Ciro Cattuto,et al.  Dynamics of Person-to-Person Interactions from Distributed RFID Sensor Networks , 2010, PloS one.

[23]  G. Nicolao,et al.  On almost sure stability of discrete-time Markov jump linear systems , 2004, 2004 43rd IEEE Conference on Decision and Control (CDC) (IEEE Cat. No.04CH37601).

[24]  P. Van Mieghem,et al.  Susceptible-infected-susceptible epidemics on the complete graph and the star graph: exact analysis. , 2013, Physical review. E, Statistical, nonlinear, and soft matter physics.

[25]  C. Lanczos An iteration method for the solution of the eigenvalue problem of linear differential and integral operators , 1950 .

[26]  E. Çinlar Exceptional Paper---Markov Renewal Theory: A Survey , 1975 .

[27]  Alan M. Frieze,et al.  Random graphs , 2006, SODA '06.

[28]  A. Saberi,et al.  Designing spatially heterogeneous strategies for control of virus spread. , 2008, IET systems biology.

[29]  R. Schassberger,et al.  On the Waiting Time in the Queuing System GI/G/1 , 1970 .

[30]  Petter Holme,et al.  Birth and death of links control disease spreading in empirical contact networks , 2013, Scientific Reports.

[31]  Fan Chung Graham,et al.  The Spectra of Random Graphs with Given Expected Degrees , 2004, Internet Math..

[32]  Donald F. Towsley,et al.  The effect of network topology on the spread of epidemics , 2005, Proceedings IEEE 24th Annual Joint Conference of the IEEE Computer and Communications Societies..

[33]  R. Pastor-Satorras,et al.  Activity driven modeling of time varying networks , 2012, Scientific Reports.

[34]  Jari Saramäki,et al.  Modelling development of epidemics with dynamic small-world networks. , 2005, Journal of theoretical biology.

[35]  Istvan Z Kiss,et al.  Epidemic threshold and control in a dynamic network. , 2011, Physical review. E, Statistical, nonlinear, and soft matter physics.

[36]  A. Barabasi,et al.  Impact of non-Poissonian activity patterns on spreading processes. , 2006, Physical review letters.

[37]  Alessandro Vespignani,et al.  Random walks and search in time-varying networks. , 2012, Physical review letters.

[38]  Babak Hassibi,et al.  On the mixing time of the SIS Markov chain model for epidemic spread , 2014, 53rd IEEE Conference on Decision and Control.

[39]  John N. Tsitsiklis,et al.  An efficient curing policy for epidemics on graphs , 2014, 53rd IEEE Conference on Decision and Control.

[40]  L. Meyers,et al.  Epidemic thresholds in dynamic contact networks , 2009, Journal of The Royal Society Interface.

[41]  Chinwendu Enyioha,et al.  Optimal Resource Allocation for Network Protection Against Spreading Processes , 2013, IEEE Transactions on Control of Network Systems.

[42]  Ciro Cattuto,et al.  High-Resolution Measurements of Face-to-Face Contact Patterns in a Primary School , 2011, PloS one.

[43]  Marcelo Dias de Amorim,et al.  Performance of Opportunistic Epidemic Routing on Edge-Markovian Dynamic Graphs , 2011, IEEE Transactions on Communications.

[44]  Piet Van Mieghem,et al.  Generalized Epidemic Mean-Field Model for Spreading Processes Over Multilayer Complex Networks , 2013, IEEE/ACM Transactions on Networking.

[45]  A. Barrat,et al.  Simulation of an SEIR infectious disease model on the dynamic contact network of conference attendees , 2011, BMC medicine.

[46]  Andrea E. F. Clementi,et al.  Flooding time in edge-Markovian dynamic graphs , 2008, PODC '08.

[47]  Yuguang Fang,et al.  Stabilization of continuous-time jump linear systems , 2002, IEEE Trans. Autom. Control..

[48]  J. Vandergraft Spectral properties of matrices which have invariant cones , 1968 .

[49]  Jari Saramäki,et al.  Temporal Networks , 2011, Encyclopedia of Social Network Analysis and Mining.

[50]  Alessandro Vespignani,et al.  Time varying networks and the weakness of strong ties , 2013, Scientific Reports.

[51]  J. Rice,et al.  On aggregated Markov processes , 1986 .

[52]  Kristina Lerman,et al.  Information Contagion: An Empirical Study of the Spread of News on Digg and Twitter Social Networks , 2010, ICWSM.

[53]  Alessandro Vespignani,et al.  Real-time numerical forecast of global epidemic spreading: case study of 2009 A/H1N1pdm , 2012, BMC Medicine.

[54]  N H Fefferman,et al.  How disease models in static networks can fail to approximate disease in dynamic networks. , 2007, Physical review. E, Statistical, nonlinear, and soft matter physics.

[55]  C. Desoer,et al.  The measure of a matrix as a tool to analyze computer algorithms for circuit analysis , 1972 .