Aging transitions of multimodal oscillators in multilayer networks

Uroš Barać, Matjaž Perc, Marko Gosak
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Abstract

When individual oscillators age and become inactive, the collective dynamics of coupled oscillators is often affected as well. Depending on the fraction of inactive oscillators or cascading failures that percolate from crucial information exchange points, the critical shift toward macroscopic inactivity in coupled oscillator networks is known as the aging transition. Here, we study this phenomenon in two overlayed square lattices that together constitute a multilayer network, whereby one layer is populated with slow Poincaré oscillators and the other with fast Rulkov neurons. Moreover, in this multimodal setup, the excitability of fast oscillators is influenced by the phase of slow oscillators that are gradually inactivated toward the aging transition in the fast layer. Through extensive numerical simulations, we find that the progressive inactivation of oscillators in the slow layer nontrivially affects the collective oscillatory activity and the aging transitions in the fast layer. Most counterintuitively, we show that it is possible for the intensity of oscillatory activity in the fast layer to progressively increase to up to 100%, even when up to 60% of units in the slow oscillatory layer are inactivated. We explain our results with a numerical analysis of collective behavior in individual layers, and we discuss their implications for biological systems.

Abstract Image

多层网络中多模态振荡器的老化转换
当单个振荡器老化并变得不活跃时,耦合振荡器的集体动力学通常也会受到影响。根据不活跃振荡器的比例或从关键信息交换点渗透出来的级联故障,耦合振荡器网络向宏观不活跃的临界转变被称为老化转变。在这里,我们在两个重叠的方形晶格中研究了这一现象,它们共同构成了一个多层网络,其中一层布满了慢速波恩卡雷振荡器,而另一层则布满了快速鲁尔科夫神经元。此外,在这种多模态设置中,快速振荡器的兴奋性受到慢速振荡器相位的影响,而慢速振荡器在快速层的老化转换过程中逐渐失活。通过大量的数值模拟,我们发现慢速层振荡器的逐渐失活会对快速层的集体振荡活动和老化转换产生非对称的影响。与直觉相反的是,我们发现即使慢速振荡层中多达 60% 的振荡器失活,快速振荡层中的振荡活动强度也有可能逐渐增加到 100%。我们通过对单个层的集体行为进行数值分析来解释我们的结果,并讨论它们对生物系统的影响。
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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CiteScore
8.60
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