# Consequences of Dale's law on the stability-complexity relationship of   random neural networks

**Authors:** J. R. Ipsen, A. D. H. Peterson

arXiv: 1907.07293 · 2020-06-24

## TL;DR

This paper explores how Dale's law influences the stability and complexity of random neural networks, revealing effects on phase transitions and equilibria in heterogeneous brain-like structures.

## Contribution

It introduces a novel analysis of heterogeneous networks obeying Dale's law using random matrix theory and Kac-Rice formalism, linking network structure to brain state transitions.

## Key findings

- Heterogeneous Dale's law networks alter phase transition points.
- Outliers in eigenspectrum affect network stability.
- Heterogeneity impacts the number of equilibria.

## Abstract

In the study of randomly connected neural network dynamics there is a phase transition from a `simple' state with few equilibria to a `complex' state characterised by the number of equilibria growing exponentially with the neuron population. Such phase transitions are often used to describe pathological brain state transitions observed in neurological diseases such as epilepsy. In this paper we investigate how more realistic heterogeneous network structures affect these phase transitions using techniques from random matrix theory. Specifically, we parameterise the network structure according to Dale's Law and use the Kac-Rice formalism to compute the change in the number of equilibria when a phase transition occurs. We also examine the condition where the network is not balanced between excitation and inhibition causing outliers to appear in the eigenspectrum. This enables us to compute the effects of different heterogeneous network connectivities on brain state transitions, which can provide new insights into pathological brain dynamics.

## Full text

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## Figures

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## References

28 references — full list in the complete paper: https://tomesphere.com/paper/1907.07293/full.md

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Source: https://tomesphere.com/paper/1907.07293