Litcius/Paper detail

Edge of Chaos and Avalanches in Neural Networks with Heavy-Tailed Synaptic Weight Distribution

Łukasz Kuśmierz, Shun Ogawa, Taro Toyoizumi

2020Physical Review Letters68 citationsDOIOpen Access PDF

Abstract

We propose an analytically tractable neural connectivity model with power-law distributed synaptic strengths. When threshold neurons with biologically plausible number of incoming connections are considered, our model features a continuous transition to chaos and can reproduce biologically relevant low activity levels and scale-free avalanches, i.e., bursts of activity with power-law distributions of sizes and lifetimes. In contrast, the Gaussian counterpart exhibits a discontinuous transition to chaos and thus cannot be poised near the edge of chaos. We validate our predictions in simulations of networks of binary as well as leaky integrate-and-fire neurons. Our results suggest that heavy-tailed synaptic distribution may form a weakly informative sparse-connectivity prior that can be useful in biological and artificial adaptive systems.

Topics & Concepts

Edge of chaosCHAOS (operating system)Artificial neural networkDistribution (mathematics)Statistical physicsWeight distributionEnhanced Data Rates for GSM EvolutionPhysicsComputer scienceArtificial intelligenceMathematicsMathematical analysisThermodynamicsComputer securityNeural dynamics and brain functionNeural Networks and Applicationsstochastic dynamics and bifurcation
Edge of Chaos and Avalanches in Neural Networks with Heavy-Tailed Synaptic Weight Distribution | Litcius