S
Stefano Boccaletti
Researcher at Moscow Institute of Physics and Technology
Publications - 361
Citations - 29686
Stefano Boccaletti is an academic researcher from Moscow Institute of Physics and Technology. The author has contributed to research in topics: Complex network & Synchronization (computer science). The author has an hindex of 60, co-authored 348 publications receiving 25776 citations. Previous affiliations of Stefano Boccaletti include King Juan Carlos University & Istituto Nazionale di Fisica Nucleare.
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Growing scale-free simplices
K. Kovalenko,Irene Sendiña-Nadal,Irene Sendiña-Nadal,Nagi Khalil,Alex Dainiak,Daniil Musatov,Daniil Musatov,Daniil Musatov,Andrei Mikhailovich Raigorodskii,K. Alfaro-Bittner,K. Alfaro-Bittner,Baruch Barzel,Stefano Boccaletti +12 more
TL;DR: In this article, the authors introduce a model to grow simplicial complexes of order two, i.e., nodes, links, and triangles, that can be straightforwardly extended to structures containing hyperedges of larger order.
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Chaotic spreading of epidemics in complex networks of excitable units.
TL;DR: The bifurcation scenario leading to chaotic states of an epidemiological disease spreading within a complex network of individuals is described, and the relevance of the observed chaotic dynamics for the description of the spreading mechanisms of epidemics inside complex networks is discussed.
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Awaking and sleeping of a complex network
TL;DR: In this article, a mean-field multiplicative coupling among first-neighbor nodes is proposed to characterize the bistability of a network with a logistic-like local dynamics.
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Frequency entrainment of nonautonomous chaotic oscillators.
TL;DR: Evidence of frequency entrainment of dominant peaks in the chaotic spectra of two coupled chaotic nonautonomous oscillators is given, characterized by the vanishing of a previously positive Lyapunov exponent in the spectrum.
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Node vulnerability under finite perturbations in complex networks.
TL;DR: A measure to quantify vulnerability under perturbations in ensembles (nets) of coupled dynamical systems is proposed, referring to the robustness of a collective dynamical state to perturbing events occurring over a fixed topology.