Graph Coloring via Locally-Active Memristor Oscillatory Networks

IF 1.6 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Journal of Low Power Electronics and Applications Pub Date : 2022-04-18 DOI:10.3390/jlpea12020022

A. Ascoli, M. Weiher, M. Herzig, S. Slesazeck, T. Mikolajick, R. Tetzlaff

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引用次数: 10

Abstract

This manuscript provides a comprehensive tutorial on the operating principles of a bio-inspired Cellular Nonlinear Network, leveraging the local activity of NbOx memristors to apply a spike-based computing paradigm, which is expected to deliver such a separation between the steady-state phases of its capacitively-coupled oscillators, relative to a reference cell, as to unveal the classification of the nodes of the associated graphs into the least number of groups, according to the rules of a non-deterministic polynomial-hard combinatorial optimization problem, known as vertex coloring. Besides providing the theoretical foundations of the bio-inspired signal-processing paradigm, implemented by the proposed Memristor Oscillatory Network, and presenting pedagogical examples, illustrating how the phase dynamics of the memristive computing engine enables to solve the graph coloring problem, the paper further presents strategies to compensate for an imbalance in the number of couplings per oscillator, to counteract the intrinsic variability observed in the electrical behaviours of memristor samples from the same batch, and to prevent the impasse appearing when the array attains a steady-state corresponding to a local minimum of the optimization goal. The proposed Memristor Cellular Nonlinear Network, endowed with ad hoc circuitry for the implementation of these control strategies, is found to classify the vertices of a wide set of graphs in a number of color groups lower than the cardinality of the set of colors identified by traditional either software or hardware competitor systems. Given that, under nominal operating conditions, a biological system, such as the brain, is naturally capable to optimise energy consumption in problem-solving activities, the capability of locally-active memristor nanotechnologies to enable the circuit implementation of bio-inspired signal processing paradigms is expected to pave the way toward electronics with higher time and energy efficiency than state-of-the-art purely-CMOS hardware.

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基于局部有源忆阻器振荡网络的图着色

这篇手稿提供了一个关于生物启发的细胞非线性网络的操作原理的全面教程，利用NbOx忆阻器的局部活动来应用基于尖峰的计算范式，该范式有望在其电容耦合振荡器的稳态相位之间实现这种分离，相对于参考细胞，根据一个非确定性多项式硬组合优化问题的规则，将关联图的节点分类为最少的组，称为顶点着色。除了提供由所提出的忆阻振荡网络实现的生物启发信号处理范式的理论基础，并提供教学实例，说明忆阻计算引擎的相位动力学如何能够解决图着色问题，本文进一步提出了补偿每个振荡器耦合数量不平衡的策略，以抵消在同一批次的忆阻器样品的电学行为中观察到的固有可变性，并防止当阵列达到与优化目标的局部最小值相对应的稳态时出现僵局。所提出的Memristor蜂窝非线性网络，被赋予了用于实现这些控制策略的特设电路，被发现可以将大量图的顶点分类为多个颜色组，这些颜色组低于传统软件或硬件竞争对手系统识别的颜色集的基数。假设在标称操作条件下，生物系统（如大脑）自然能够优化解决问题活动中的能量消耗，局部有源忆阻器纳米技术实现生物启发信号处理范例的电路实现的能力有望为实现比最先进的纯CMOS硬件具有更高时间和能量效率的电子器件铺平道路。

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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