Juan Balzer, Rico Berner, Kathy Lüdge, Sebastian Wieczorek, Jürgen Kurths, Serhiy Yanchuk
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引用次数: 0
Abstract
Canard cascading (CC) is observed in dynamical networks with global adaptive
coupling. It is a fast-slow phenomenon characterized by a recurrent sequence of
fast transitions between distinct and slowly evolving quasi-stationary states.
In this letter, we uncover the dynamical mechanisms behind CC, using an
illustrative example of globally and adaptively coupled semiconductor lasers,
where CC represents sequential switching on and off the lasers. Firstly, we
show that CC is a robust and truly adaptive network effect that is scalable
with network size and does not occur without adaptation. Secondly, we uncover
multiple saddle slow manifolds (unstable quasi-stationary states) linked by
heteroclinic orbits (fast transitions) in the phase space of the system. This
allows us to identify CC with a novel heteroclinic canard orbit that organises
different unstable quasi-stationary states into an intricate fast-slow limit
cycle. Although individual quasi-stationary states are unstable (saddles), the
CC cycle as a whole is attractive and robust to parameter changes.
在具有全局自适应耦合的动力学网络中可以观察到卡纳德级联(CC)现象。在这封信中,我们以全局自适应耦合半导体激光器为例,揭示了 CC 背后的动力学机制。首先,我们证明了 CC 是一种稳健的、真正的自适应网络效应,它可以随着网络规模的扩大而扩展,并且在没有自适应的情况下不会发生。其次,我们在系统的相空间中发现了多个鞍慢流形(不稳定的准稳态),这些鞍慢流形由外折线轨道(快速转换)连接。这使我们能够识别出 CC 具有一种新的异折线卡纳轨道,它将不同的不稳定准稳态组织成一个错综复杂的快慢极限循环。虽然单个准稳态是不稳定的(鞍状),但 CC 循环作为一个整体对参数变化具有吸引力和稳健性。
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