Mathematical Investigation of Static Pattern Formation with a Locally Active Memristor Model

2021 17th International Workshop on Cellular Nanoscale Networks and their Applications (CNNA) Pub Date : 2021-09-29 DOI:10.1109/CNNA49188.2021.9610811

A. S. Demirkol, A. Ascoli, R. Tetzlaff

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引用次数: 2

Abstract

We present the mathematical investigation of static pattern formation in a Memristor Cellular Nonlinear Network (M -CNN), in consideration of the theory of local activity. The M-CNN has a planar grid form composed of identical memristive cells, which are purely resistively coupled to each other. The single cell contains a DC voltage source, a bias resistor, and a locally active memristor in parallel with a capacitor. The memristor model employed has a simple generic form which helps to reduce the simulation time, and has a functional AC equivalent circuit which facilitates further calculations. We adopt a circuit theoretical approach for the stability analysis of the single cell and a 3-cell ring configuration, as well as the examination of local activity, edge-of-chaos, and sharp-edge-of-chaos domains, which helps us to interpret the results in a better way. The emergence of static patterns is successfully confirmed by simulating the proposed resistively coupled M -CNN utilizing locally active memristors.

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局部有源忆阻器模型静态模式形成的数学研究

考虑到局部活动理论，我们提出了记忆电阻细胞非线性网络(M -CNN)中静态模式形成的数学研究。M-CNN具有由相同记忆单元组成的平面网格形式，这些记忆单元彼此之间是纯电阻耦合的。单个电池包含一个直流电压源、一个偏置电阻和一个与电容器并联的局部有源忆阻器。所采用的忆阻器模型具有简单的通用形式，有助于减少仿真时间，并具有功能交流等效电路，便于进一步计算。我们采用电路理论方法对单细胞和3细胞环结构进行稳定性分析，并对局部活动、混沌边缘和锐混沌边缘域进行检查，这有助于我们更好地解释结果。通过利用局部有源忆阻器模拟所提出的电阻耦合M -CNN，成功地证实了静态模式的出现。

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2021 17th International Workshop on Cellular Nanoscale Networks and their Applications (CNNA)

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