Identification of criticality in neuronal avalanches: I. A theoretical investigation of the non-driven case

Timothy J. Taylor, Caroline Hartley, Péter L. Simon, Istvan Z. Kiss, Luc Berthouze

Research output: Contribution to journalArticle

12 Citations (Scopus)


In this paper, we study a simple model of a purely excitatory neural network that, by construction, operates at a critical point. This model allows us to consider various markers of criticality and illustrate how they should perform in a finitesize system. By calculating the exact distribution of avalanche sizes, we are able to show that, over a limited range of avalanche sizes which we precisely identify, the distribution has scale free properties but is not a power law. This suggests that it would be inappropriate to dismiss a system as not being critical purely based on an inability to rigorously fit a power law distribution as has been recently advocated. In assessing whether a system, especially a finite-size one, is critical it is thus important to consider other possible markers. We illustrate one of these by showing the divergence of susceptibility as the critical point of the system is approached. Finally, we provide evidence that power laws may underlie other observables of the system that may be more amenable to robust experimental assessment.

Original languageEnglish
Article number5
Pages (from-to)1-26
Number of pages26
JournalJournal of Mathematical Neuroscience
Issue number1
Publication statusPublished - Jan 1 2013


ASJC Scopus subject areas

  • Neuroscience (miscellaneous)

Cite this