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Auteurs principaux: Yan, Jin, Ozawa, Ayumi, Sato, Yuzuru, Kori, Hiroshi
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2603.02135
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author Yan, Jin
Ozawa, Ayumi
Sato, Yuzuru
Kori, Hiroshi
author_facet Yan, Jin
Ozawa, Ayumi
Sato, Yuzuru
Kori, Hiroshi
contents We investigate the global basin structure of twisted states in nearest-neighbor coupled phase oscillators with a common phase shift $α$. As $α$ increases, basin boundaries become progressively more complex, with their fractal dimension growing toward that of the full ambient phase space. We conjecture that the basins eventually become riddled as the system approaches the limit $α\to \fracπ{2}$, where the dynamics becomes volume-preserving. We characterize the transient dynamics via the stabilization time of the winding number and demonstrate that it grows with system size. The scaling accelerates at larger phase shifts, transitioning from logarithmic to power-law behavior. We further analyze the dynamical origin of these long transients. Our results demonstrate how a single phase-shift governs fractal basin complexity and provide new insights into the global geometry and transient dynamics of multistable, yet non-chaotic, coupled phase oscillators.
format Preprint
id arxiv_https___arxiv_org_abs_2603_02135
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Basin Riddling in Coupled Phase Oscillators
Yan, Jin
Ozawa, Ayumi
Sato, Yuzuru
Kori, Hiroshi
Chaotic Dynamics
Statistical Mechanics
Dynamical Systems
Pattern Formation and Solitons
Exactly Solvable and Integrable Systems
We investigate the global basin structure of twisted states in nearest-neighbor coupled phase oscillators with a common phase shift $α$. As $α$ increases, basin boundaries become progressively more complex, with their fractal dimension growing toward that of the full ambient phase space. We conjecture that the basins eventually become riddled as the system approaches the limit $α\to \fracπ{2}$, where the dynamics becomes volume-preserving. We characterize the transient dynamics via the stabilization time of the winding number and demonstrate that it grows with system size. The scaling accelerates at larger phase shifts, transitioning from logarithmic to power-law behavior. We further analyze the dynamical origin of these long transients. Our results demonstrate how a single phase-shift governs fractal basin complexity and provide new insights into the global geometry and transient dynamics of multistable, yet non-chaotic, coupled phase oscillators.
title Basin Riddling in Coupled Phase Oscillators
topic Chaotic Dynamics
Statistical Mechanics
Dynamical Systems
Pattern Formation and Solitons
Exactly Solvable and Integrable Systems
url https://arxiv.org/abs/2603.02135