S
Steven H. Strogatz
Researcher at Cornell University
Publications - 227
Citations - 92888
Steven H. Strogatz is an academic researcher from Cornell University. The author has contributed to research in topics: Josephson effect & Kuramoto model. The author has an hindex of 79, co-authored 219 publications receiving 85750 citations. Previous affiliations of Steven H. Strogatz include Boston College & Purdue University.
Papers
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Solvable model of spiral wave chimeras.
TL;DR: This work provides the first analytical description of such a spiral wave chimera and uses perturbation theory to calculate its rotation speed and the size of its incoherent core.
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Coupled nonlinear oscillators below the synchronization threshold: Relaxation by generalized Landau damping.
Steven H. Strogatz,Steven H. Strogatz,Steven H. Strogatz,Renato Mirollo,Renato Mirollo,Renato Mirollo,Paul C. Matthews,Paul C. Matthews,Paul C. Matthews +8 more
TL;DR: This work analyzes a model of globally coupled nonlinear oscillators with randomly distributed frequencies and proves that, for coupling strengths below a certain threshold, this system would always relax to an incoherent state.
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The spectrum of the locked state for the Kuramoto model of coupled oscillators
TL;DR: In this paper, the authors analyzed the linear stability of the phase-locked state in the Kuramoto model of coupled oscillators and provided a rigorous characterization of the spectrum and its associated eigenvectors, for any finite number of oscillators.
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Dynamics of a large system of coupled nonlinear oscillators
TL;DR: In this article, the interaction of a large number of limit-cycle oscillators with linear, all-to-all coupling and a distribution of natural frequencies is considered and the stability boundaries of amplitude death and incoherence are found explicitly.
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Phase diagram for the collective behavior of limit-cycle oscillators.
TL;DR: A large dynamical system of limit-cycle oscillators with mean-field coupling and randomly distributed natural frequencies exhibits frequency locking, amplitude death, and incoherence, as well as novel unsteady behavior characterized by periodic, quasiperiodic, or chaotic evolution of the system s order parameter.