Delayed-feedback oscillators replicate the dynamics of multiplex networks: wavefront propagation and stochastic resonance

Anna Zakharova, Vladimir V. Semenov
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Abstract

The widespread development and use of neural networks have significantly enriched a wide range of computer algorithms and promise higher speed at lower cost. However, the imitation of neural networks by means of modern computing substrates is highly inefficient, whereas physical realization of large scale networks remains challenging. Fortunately, delayed-feedback oscillators, being much easier to realize experimentally, represent promising candidates for the empirical implementation of neural networks and next generation computing architectures. In the current research, we demonstrate that coupled bistable delayed-feedback oscillators emulate a multilayer network, where one single-layer network is connected to another single-layer network through coupling between replica nodes, i.e. the multiplex network. We show that all the aspects of the multiplexing impact on wavefront propagation and stochastic resonance identified in multilayer networks of bistable oscillators are entirely reproduced in the dynamics of time-delay oscillators. In particular, varying the coupling strength allows suppressing and enhancing the effect of stochastic resonance, as well as controlling the speed and direction of both deterministic and stochastic wavefront propagation. All the considered effects are studied in numerical simulations and confirmed in physical experiments, showing an excellent correspondence and disclosing thereby the robustness of the observed phenomena.
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延迟反馈振荡器复制多路复用网络的动态:波前传播和随机共振
神经网络的广泛开发和使用极大地丰富了各种计算机算法,并有望以更低的成本实现更高的速度。然而,通过现代计算平台来模仿神经网络的效率非常低,而大型网络的物理实现仍然具有挑战性。幸运的是,延迟反馈振荡器在实验中更容易实现,是神经网络和下一代计算架构经验实现的理想候选方案。在当前的研究中,我们证明了耦合双稳态延迟反馈振荡器可以模拟多层网络,其中一个单层网络通过复制节点之间的耦合连接到另一个单层网络,即多路复用网络。我们的研究表明,在双稳态振荡器的多层网络中发现的多路复用对波面传播和随机共振的影响,在延时振荡器的动力学中得到了完全重现。特别是,改变耦合强度可以抑制和增强随机共振效应,以及控制确定性和随机波面传播的速度和方向。所有考虑到的效应都在数值模拟中进行了研究,并在物理实验中得到了证实,显示了极好的对应关系,从而揭示了观察到的现象的稳健性。
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