Collective dynamics and long-range order in thermal neuristor networks

Yuan-Hang Zhang, Chesson Sipling, Erbin Qiu, Ivan K. Schuller, Massimiliano Di Ventra
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Abstract

In the pursuit of scalable and energy-efficient neuromorphic devices, recent research has unveiled a novel category of spiking oscillators, termed ``thermal neuristors." These devices function via thermal interactions among neighboring vanadium dioxide resistive memories, closely mimicking the behavior of biological neurons. Here, we show that the collective dynamical behavior of networks of these neurons showcases a rich phase structure, tunable by adjusting the thermal coupling and input voltage. Notably, we have identified phases exhibiting long-range order that, however, does not arise from criticality, but rather from the time non-local response of the system. In addition, we show that these thermal neuristor arrays achieve high accuracy in image recognition tasks through reservoir computing, without taking advantage of this long-range order. Our findings highlight a crucial aspect of neuromorphic computing with possible implications on the functioning of the brain: criticality may not be necessary for the efficient performance of neuromorphic systems in certain computational tasks.
热神经元网络中的集体动力学和长程秩序
为了追求可扩展和高能效的神经形态设备,最近的研究揭示了一种新型尖峰振荡器,称为 "热神经元"。这些器件通过相邻二氧化钒电阻存储器之间的热相互作用发挥作用,近似模仿生物神经元的行为。在这里,我们展示了这些神经元网络的集体动力学行为展现了丰富的相位结构,可通过调整热耦合和输入电压进行调谐。值得注意的是,我们发现了表现出长程有序性的相位,但这种有序性并非源于临界性,而是源于系统的时间非局部响应。此外,我们还表明,这些热神经元阵列通过蓄水池计算在图像识别任务中实现了高准确度,而没有利用这种长程有序。我们的发现凸显了超形态计算的一个重要方面,可能会对大脑的功能产生影响:在某些计算任务中,临界性可能并不是超形态系统高效执行任务的必要条件。
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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