Stability and chaos in the classical three rotor problem

arXiv: Chaotic Dynamics Pub Date : 2018-10-02 DOI:10.29195/iascs.02.01.0020

G. Krishnaswami, Himalaya Senapati

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引用次数: 3

Abstract

We study the equal-mass classical three rotor problem, a variant of the three body problem of celestial mechanics. The quantum $N$-rotor problem has been used to model chains of coupled Josephson junctions and also arises via a partial continuum limit of the Wick-rotated XY model. In units of the coupling, the energy serves as a control parameter. We find periodic 'pendulum' and 'breather' orbits at all energies and choreographies at relatively low energies. They furnish analogs of the Euler-Lagrange and figure-8 solutions of the planar three body problem. Integrability at very low energies gives way to a rather marked transition to chaos at $E_c \approx 4$, followed by a gradual return to regularity as $E \to \infty$. We find four signatures of this transition: (a) the fraction of the area of Poincare surfaces occupied by chaotic sections rises sharply at $E_c$, (b) discrete symmetries are spontaneously broken at $E_c$, (c) $E=4$ is an accumulation point of stable to unstable transitions in pendulum solutions and (d) the Jacobi-Maupertuis curvature goes from being positive to having both signs above $E=4$. Moreover, Poincare plots also reveal a regime of global chaos slightly above $E_c$.

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经典三转子问题的稳定性和混沌性

我们研究了等质量经典三转子问题，这是天体力学三体问题的一个变体。量子$N$ -转子问题已被用于模拟耦合约瑟夫森结链，也通过wick旋转XY模型的部分连续体极限出现。在耦合单元中，能量作为控制参数。我们发现周期性的“钟摆”和“呼吸”轨道在所有能量和舞蹈编排在相对较低的能量。它们提供了类似于平面三体问题的欧拉-拉格朗日和图8解法。在极低能量处的可积性在$E_c \approx 4$处让位于一个相当明显的过渡到混沌状态，随后在$E \to \infty$处逐渐恢复到规则状态。我们发现了这种转变的四个特征:(a)混沌部分占据的庞加莱曲面面积的比例在$E_c$处急剧上升，(b)离散对称性在$E_c$处自发地被打破，(c) $E=4$是钟摆解中稳定到不稳定转变的累积点，(d) Jacobi-Maupertuis曲率从正变为在$E=4$以上同时具有两个符号。此外，庞加莱图还揭示了一个略高于$E_c$的全球混乱政权。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv: Chaotic Dynamics

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