Kuramoto oscillators with inertia: A fast-slow dynamical systems approach
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Publication:2950795
DOI10.1090/qam/1380zbMath1362.34059OpenAlexW1842772603MaRDI QIDQ2950795
Seung-Yeal Ha, Marshall Slemrod, Sungeun Jung, Young-Pil Choi
Publication date: 9 October 2015
Published in: Quarterly of Applied Mathematics (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1090/qam/1380
Nonlinear oscillations and coupled oscillators for ordinary differential equations (34C15) Singular perturbations for ordinary differential equations (34E15) Synchronization of solutions to ordinary differential equations (34D06)
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Cites Work
- Asymptotic formation and orbital stability of phase-locked states for the Kuramoto model
- Complete synchronization of Kuramoto oscillators with finite inertia
- A fast-slow dynamical systems theory for the Kuramoto type phase model
- Fast-slow dynamics of planar particle models for flocking and swarming
- Chemical oscillations, waves, and turbulence
- Synchronization in a pool of mutually coupled oscillators with random frequencies
- Singular perturbation methods for ordinary differential equations
- Constants of motion for superconducting Josephson arrays
- Stability of periodic solutions in series arrays of Josephson junctions with internal capacitance
- From Kuramoto to Crawford: Exploring the onset of synchronization in population of coupled oscillators
- A shocking display of synchrony
- Self-synchronization of coupled oscillators with hysteretic responses
- Singularly perturbed ordinary differential equations with dynamic limits
- On the Critical Coupling for Kuramoto Oscillators
- Slow observables of singularly perturbed differential equations
- Averaging methods in nonlinear dynamical systems
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