Nonlinear optimal control of a mean-field model of neural population dynamics

Salfenmoser, Lena; Obermayer, Klaus

doi:10.3389/fncom.2022.931121

Cited by 2 publications

(1 citation statement)

References 50 publications

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“…Complex network theory provides a good framework for studying the structure and dynamics of complex interactive systems, can effectively demonstrate the essential characteristics of real-world social systems, demonstrates excellent mathematical performance, and is capable of performing rigorous mathematical calculations [4][5][6][7]. In 2001, Pastor-Satorras et al…”

Section: Introductionmentioning

confidence: 99%

Immunization strategies for simplicial irreversible epidemic on simplicial complex

Zhang

et al. 2022

Front. Phys.

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Higher-order networks can be used to describe the interaction of multiple entities in real-world collective behaviors such as dining, conference attendance, and public transportation use. Collective behavior is often one of the main reasons for “super-spreading events” during epidemics. How to propose effective immunization strategies is a Frontier research topic in network science and public health. To the best of our knowledge, there is a lack of systematic research on immunization strategies for epidemics on higher-order networks. We use synthetic networks and real-world networks as underlying structures to construct simplicial complexes to describe higher-order interaction networks, including pairwise and group interactions, and then propose a simplicial irreversible epidemic spreading model (i.e., simplicial Susceptible-Infected-Removed model). The temporal evolution process of nodes in different states in the system is described by extending the Microscopic Markov Chain Approach. Based on the node degree index and betweenness index, immunization strategies are proposed on the higher-order networks. Through theoretical analysis and numerical simulations, we discuss the effects of different higher-order infection rates, immunization ratios, and immunization strategies on the simplicial irreversible epidemic spread. Under some specific parameter configurations, we observe continuous growth, discontinuous growth, reduction of outbreak threshold, etc.

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Section: Introductionmentioning

confidence: 99%

Immunization strategies for simplicial irreversible epidemic on simplicial complex

Zhang

et al. 2022

Front. Phys.

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Optimal control of a Wilson–Cowan model of neural population dynamics

Salfenmoser

Obermayer

2023

Chaos: An Interdisciplinary Journal of Nonlinear Science

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Nonlinear dynamical systems describe neural activity at various scales and are frequently used to study brain functions and the impact of external perturbations. Here, we explore methods from optimal control theory (OCT) to study efficient, stimulating “control” signals designed to make the neural activity match desired targets. Efficiency is quantified by a cost functional, which trades control strength against closeness to the target activity. Pontryagin’s principle then enables to compute the cost-minimizing control signal. We then apply OCT to a Wilson–Cowan model of coupled excitatory and inhibitory neural populations. The model exhibits an oscillatory regime, low- and high-activity fixed points, and a bistable regime where low- and high-activity states coexist. We compute an optimal control for a state-switching (bistable regime) and a phase-shifting task (oscillatory regime) and allow for a finite transition period before penalizing the deviation from the target state. For the state-switching task, pulses of limited input strength push the activity minimally into the target basin of attraction. Pulse shapes do not change qualitatively when varying the duration of the transition period. For the phase-shifting task, periodic control signals cover the whole transition period. Amplitudes decrease when transition periods are extended, and their shapes are related to the phase sensitivity profile of the model to pulsed perturbations. Penalizing control strength via the integrated 1-norm yields control inputs targeting only one population for both tasks. Whether control inputs drive the excitatory or inhibitory population depends on the state-space location.

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Nonlinear optimal control of a mean-field model of neural population dynamics

Cited by 2 publications

References 50 publications

Immunization strategies for simplicial irreversible epidemic on simplicial complex

Immunization strategies for simplicial irreversible epidemic on simplicial complex

Optimal control of a Wilson–Cowan model of neural population dynamics

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