Optimal control of networked reaction-diffusion systems

Shupeng Gao; Lili Chang; Ivan Romic; Zhen Wang; Marko Jusup; Petter Holme

doi:10.1098/rsif.2021.0739

Optimal control of networked reaction-diffusion systems

Shupeng Gao, Lili Chang, Ivan Romic, Zhen Wang, Marko Jusup, Petter Holme

School of Cybersecurity

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

23 Scopus citations

Abstract

Patterns in nature are fascinating both aesthetically and scientifically. Alan Turing's celebrated reaction-diffusion model of pattern formation from the 1950s has been extended to an astounding diversity of applications: from cancer medicine, via nanoparticle fabrication, to computer architecture. Recently, several authors have studied pattern formation in underlying networks, but thus far, controlling a reaction-diffusion system in a network to obtain a particular pattern has remained elusive. We present a solution to this problem in the form of an analytical framework and numerical algorithm for optimal control of Turing patterns in networks. We demonstrate our method's effectiveness and discuss factors that affect its performance. We also pave the way for multidisciplinary applications of our framework beyond reaction-diffusion models.

Original language	English
Article number	20210739
Journal	Journal of the Royal Society Interface
Volume	19
Issue number	188
DOIs	https://doi.org/10.1098/rsif.2021.0739
State	Published - 2022

Keywords

discrete systems
instability analysis
network theory
optimal control
pattern formation
reaction-diffusion systems

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1098/rsif.2021.0739

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abstract = "Patterns in nature are fascinating both aesthetically and scientifically. Alan Turing's celebrated reaction-diffusion model of pattern formation from the 1950s has been extended to an astounding diversity of applications: from cancer medicine, via nanoparticle fabrication, to computer architecture. Recently, several authors have studied pattern formation in underlying networks, but thus far, controlling a reaction-diffusion system in a network to obtain a particular pattern has remained elusive. We present a solution to this problem in the form of an analytical framework and numerical algorithm for optimal control of Turing patterns in networks. We demonstrate our method's effectiveness and discuss factors that affect its performance. We also pave the way for multidisciplinary applications of our framework beyond reaction-diffusion models.",

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AU - Gao, Shupeng

AU - Chang, Lili

AU - Romic, Ivan

AU - Wang, Zhen

AU - Jusup, Marko

AU - Holme, Petter

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KW - instability analysis

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Optimal control of networked reaction-diffusion systems

Abstract

Keywords

UN SDGs

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