Backtracking activation impacts the criticality of excitable networks

Networks of excitable elements are widely used to model real-world biological and social systems. The dynamic range of an excitable network quantifies the range of stimulus intensities that can be robustly distinguished by the network response, and is maximized at the critical state. In this study,...

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Bibliographic Details
Published in:New journal of physics 2020-01, Vol.22 (1), p.13038
Main Authors: Zhang, Renquan, Quan, Guoyi, Wang, Jiannan, Pei, Sen
Format: Article
Language:English
Subjects:
Activation
backtracking activation
Biological models (mathematics)
Computer simulation
criticality
dynamic range
Eigenvalues
excitable networks
excitatory- inhibitory networks
Neural networks
non-backtracking matrix
Physics
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Summary:Networks of excitable elements are widely used to model real-world biological and social systems. The dynamic range of an excitable network quantifies the range of stimulus intensities that can be robustly distinguished by the network response, and is maximized at the critical state. In this study, we examine the impacts of backtracking activation on system criticality in excitable networks consisting of both excitatory and inhibitory units. We find that, for dynamics with refractory states that prohibit backtracking activation, the critical state occurs when the largest eigenvalue of the weighted non-backtracking (WNB) matrix for excitatory units, λ NB E , is close to one, regardless of the strength of inhibition. In contrast, for dynamics without refractory state in which backtracking activation is allowed, the strength of inhibition affects the critical condition through suppression of backtracking activation. As inhibitory strength increases, backtracking activation is gradually suppressed. Accordingly, the system shifts continuously along a continuum between two extreme regimes-from one where the criticality is determined by the largest eigenvalue of the weighted adjacency matrix for excitatory units, λ W E , to the other where the critical state is reached when λ NB E is close to one. For systems in between, we find that λ NB E < 1 and λ W E > 1 at the critical state. These findings, confirmed by numerical simulations using both random and synthetic neural networks, indicate that backtracking activation impacts the criticality of excitable networks.
ISSN:1367-2630
1367-2630
DOI:10.1088/1367-2630/ab6355