On electrical gates on fungal colony

Alexander Beasley; Phil Ayres; Martin Tegelaar; Michail-Antisthenis Tsompanas; Andrew Adamatzky

doi:10.1016/j.biosystems.2021.104507

On electrical gates on fungal colony

Alexander Beasley, Phil Ayres, Martin Tegelaar, Michail-Antisthenis Tsompanas, Andrew Adamatzky

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

Abstract

Mycelium networks are promising substrates for designing unconventional computing devices providing rich topologies and geometries where signals propagate and interact. Fulfilling our long-term objectives of prototyping electrical analog computers from living mycelium networks, including networks hybridised with nanoparticles, we explore the possibility of implementing Boolean logical gates based on electrical properties of fungal colonies. We converted a 3D image-data stack of Aspergillus niger fungal colony to an Euclidean graph and modelled the colony as resistive and capacitive (RC) networks, where electrical parameters of edges were functions of the edges’ lengths. We found that and, or and and-not gates are implementable in RC networks derived from the geometrical structure of the real fungal colony.

Originalsprog	Engelsk
Artikelnummer	104507
Tidsskrift	BioSystems
Vol/bind	209
ISSN	0303-2647
DOI	https://doi.org/10.1016/j.biosystems.2021.104507
Status	Udgivet - 14 aug. 2021

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https://www.researchgate.net/publication/353911441

FUNGAR: Fungal Architectures
Ayres, P., Rigobello, A. & Buchwald, E. F.
01/12/2019 → 31/05/2023
Projekter: Projekt › Forskning

Citationsformater

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abstract = "Mycelium networks are promising substrates for designing unconventional computing devices providing rich topologies and geometries where signals propagate and interact. Fulfilling our long-term objectives of prototyping electrical analog computers from living mycelium networks, including networks hybridised with nanoparticles, we explore the possibility of implementing Boolean logical gates based on electrical properties of fungal colonies. We converted a 3D image-data stack of Aspergillus niger fungal colony to an Euclidean graph and modelled the colony as resistive and capacitive (RC) networks, where electrical parameters of edges were functions of the edges{\textquoteright} lengths. We found that and, or and and-not gates are implementable in RC networks derived from the geometrical structure of the real fungal colony.",

keywords = "Mycelium network, Boolean gates, Uncoventional computing",

author = "Alexander Beasley and Phil Ayres and Martin Tegelaar and Michail-Antisthenis Tsompanas and Andrew Adamatzky",

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doi = "10.1016/j.biosystems.2021.104507",

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T1 - On electrical gates on fungal colony

AU - Beasley, Alexander

AU - Ayres, Phil

AU - Tegelaar, Martin

AU - Tsompanas, Michail-Antisthenis

AU - Adamatzky, Andrew

PY - 2021/8/14

Y1 - 2021/8/14

N2 - Mycelium networks are promising substrates for designing unconventional computing devices providing rich topologies and geometries where signals propagate and interact. Fulfilling our long-term objectives of prototyping electrical analog computers from living mycelium networks, including networks hybridised with nanoparticles, we explore the possibility of implementing Boolean logical gates based on electrical properties of fungal colonies. We converted a 3D image-data stack of Aspergillus niger fungal colony to an Euclidean graph and modelled the colony as resistive and capacitive (RC) networks, where electrical parameters of edges were functions of the edges’ lengths. We found that and, or and and-not gates are implementable in RC networks derived from the geometrical structure of the real fungal colony.

AB - Mycelium networks are promising substrates for designing unconventional computing devices providing rich topologies and geometries where signals propagate and interact. Fulfilling our long-term objectives of prototyping electrical analog computers from living mycelium networks, including networks hybridised with nanoparticles, we explore the possibility of implementing Boolean logical gates based on electrical properties of fungal colonies. We converted a 3D image-data stack of Aspergillus niger fungal colony to an Euclidean graph and modelled the colony as resistive and capacitive (RC) networks, where electrical parameters of edges were functions of the edges’ lengths. We found that and, or and and-not gates are implementable in RC networks derived from the geometrical structure of the real fungal colony.

KW - Mycelium network

KW - Boolean gates

KW - Uncoventional computing

UR - https://www.researchgate.net/publication/353911441

U2 - 10.1016/j.biosystems.2021.104507

DO - 10.1016/j.biosystems.2021.104507

M3 - Journal article

SN - 0303-2647

VL - 209

JO - BioSystems

JF - BioSystems

M1 - 104507

ER -

On electrical gates on fungal colony

Abstract

Kunstnerisk udviklingsvirksomhed (KUV)

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FUNGAR: Fungal Architectures

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