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Topological Properties of Neuromorphic Nanowire Networks

Alon Loeffler, Ruomin Zhu, Joel Hochstetter, Mike Li, Kaiwei Fu, Adrian Diaz‐Alvarez, Tomonobu Nakayama, James M. Shine, Zdenka Kuncic

2020Frontiers in Neuroscience64 citationsDOIOpen Access PDF

Abstract

Graph theory has been extensively applied to the topological mapping of complex networks, ranging from social networks to biological systems. Graph theory has increasingly been applied to neuroscience as a method to explore the fundamental structural and functional properties of human neural networks. Here, we apply graph theory to models of a novel neuromorphic system constructed from self-assembled nanowires, whose structure and function mimic that of human neural networks. Simulations of neuromorphic nanowire networks allow us to directly examine their topology at the individual nanowire-node scale. This type of investigation is currently extremely difficult experimentally. We then apply network cartographic approaches to compare neuromorphic nanowire networks with: random networks (including an untrained artificial neural network); grid-like networks and the structural network of C. Elegans. Our results demonstrate that neuromorphic nanowire networks exhibit a small-world architecture similar to biological system of C. Elegans, and significantly different from random and grid-like networks. Furthermore, neuromorphic nanowire networks appear more segregated and modular than random, grid-like and simple biological networks and more clustered than artificial neural networks. Given the inextricable link between structure and function in neural networks, these results may have important implications for mimicking cognitive functions in neuromorphic nanowire networks.

Topics & Concepts

Neuromorphic engineeringComputer scienceNanowireArtificial neural networkTopology (electrical circuits)Modular designNervous system network modelsNode (physics)Biological networkNetwork topologyGraphGridGraph theoryTheoretical computer scienceArtificial intelligenceNanotechnologyTypes of artificial neural networksMaterials scienceRecurrent neural networkPhysicsComputer networkEngineeringMathematicsBiologyBioinformaticsCombinatoricsElectrical engineeringOperating systemQuantum mechanicsGeometryAdvanced Memory and Neural ComputingNeural dynamics and brain functionComplex Network Analysis Techniques
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