Emergence of winner-takes-all connectivity paths in random nanowire networks

Hugh G. Manning; Fabio Niosi; Claudia Gomes da Rocha; Allen T. Bellew; Colin O’Callaghan; Subhajit Biswas; Patrick F. Flowers; Benjamin J. Wiley; Justin D. Holmes; Mauro S. Ferreira; John J. Boland

doi:10.1038/s41467-018-05517-6

Emergence of winner-takes-all connectivity paths in random nanowire networks

Hugh G. Manning
, Fabio Niosi
, Claudia Gomes da Rocha
, Allen T. Bellew
, Colin O’Callaghan
, Subhajit Biswas
, Patrick F. Flowers
, Benjamin J. Wiley
, Justin D. Holmes
, Mauro S. Ferreira
, John J. Boland

School of Chemistry

Research output: Contribution to journal › Article › peer-review

Abstract

Nanowire networks are promising memristive architectures for neuromorphic applications due to their connectivity and neurosynaptic-like behaviours. Here, we demonstrate a self-similar scaling of the conductance of networks and the junctions that comprise them. We show this behavior is an emergent property of any junction-dominated network. A particular class of junctions naturally leads to the emergence of conductance plateaus and a “winner-takes-all” conducting path that spans the entire network, and which we show corresponds to the lowest-energy connectivity path. The memory stored in the conductance state is distributed across the network but encoded in specific connectivity pathways, similar to that found in biological systems. These results are expected to have important implications for development of neuromorphic devices based on reservoir computing.

Original language	English
Article number	3219
Journal	Nature Communications
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s41467-018-05517-6
Publication status	Published - 1 Dec 2018

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10.1038/s41467-018-05517-6

https://hdl.handle.net/10468/6765Licence: CC BY

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title = "Emergence of winner-takes-all connectivity paths in random nanowire networks",

abstract = "Nanowire networks are promising memristive architectures for neuromorphic applications due to their connectivity and neurosynaptic-like behaviours. Here, we demonstrate a self-similar scaling of the conductance of networks and the junctions that comprise them. We show this behavior is an emergent property of any junction-dominated network. A particular class of junctions naturally leads to the emergence of conductance plateaus and a “winner-takes-all” conducting path that spans the entire network, and which we show corresponds to the lowest-energy connectivity path. The memory stored in the conductance state is distributed across the network but encoded in specific connectivity pathways, similar to that found in biological systems. These results are expected to have important implications for development of neuromorphic devices based on reservoir computing.",

author = "Manning, \{Hugh G.\} and Fabio Niosi and \{da Rocha\}, \{Claudia Gomes\} and Bellew, \{Allen T.\} and Colin O{\textquoteright}Callaghan and Subhajit Biswas and Flowers, \{Patrick F.\} and Wiley, \{Benjamin J.\} and Holmes, \{Justin D.\} and Ferreira, \{Mauro S.\} and Boland, \{John J.\}",

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doi = "10.1038/s41467-018-05517-6",

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AU - Manning, Hugh G.

AU - Niosi, Fabio

AU - da Rocha, Claudia Gomes

AU - Bellew, Allen T.

AU - O’Callaghan, Colin

AU - Biswas, Subhajit

AU - Flowers, Patrick F.

AU - Wiley, Benjamin J.

AU - Holmes, Justin D.

AU - Ferreira, Mauro S.

AU - Boland, John J.

PY - 2018/12/1

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N2 - Nanowire networks are promising memristive architectures for neuromorphic applications due to their connectivity and neurosynaptic-like behaviours. Here, we demonstrate a self-similar scaling of the conductance of networks and the junctions that comprise them. We show this behavior is an emergent property of any junction-dominated network. A particular class of junctions naturally leads to the emergence of conductance plateaus and a “winner-takes-all” conducting path that spans the entire network, and which we show corresponds to the lowest-energy connectivity path. The memory stored in the conductance state is distributed across the network but encoded in specific connectivity pathways, similar to that found in biological systems. These results are expected to have important implications for development of neuromorphic devices based on reservoir computing.

AB - Nanowire networks are promising memristive architectures for neuromorphic applications due to their connectivity and neurosynaptic-like behaviours. Here, we demonstrate a self-similar scaling of the conductance of networks and the junctions that comprise them. We show this behavior is an emergent property of any junction-dominated network. A particular class of junctions naturally leads to the emergence of conductance plateaus and a “winner-takes-all” conducting path that spans the entire network, and which we show corresponds to the lowest-energy connectivity path. The memory stored in the conductance state is distributed across the network but encoded in specific connectivity pathways, similar to that found in biological systems. These results are expected to have important implications for development of neuromorphic devices based on reservoir computing.

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Emergence of winner-takes-all connectivity paths in random nanowire networks

Abstract

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