Mutual information and information gating in synfire chains

Zhuocheng Xiao, Binxu Wang, Andrew T. Sornborger, Louis Tao

Research output: Contribution to journalArticlepeer-review

9 Scopus citations

Abstract

Coherent neuronal activity is believed to underlie the transfer and processing of information in the brain. Coherent activity in the form of synchronous firing and oscillations has been measured in many brain regions and has been correlated with enhanced feature processing and other sensory and cognitive functions. In the theoretical context, synfire chains and the transfer of transient activity packets in feedforward networks have been appealed to in order to describe coherent spiking and information transfer. Recently, it has been demonstrated that the classical synfire chain architecture, with the addition of suitably timed gating currents, can support the graded transfer of mean firing rates in feedforward networks (called synfire-gated synfire chains-SGSCs). Here we study information propagation in SGSCs by examining mutual information as a function of layer number in a feedforward network. We explore the effects of gating and noise on information transfer in synfire chains and demonstrate that asymptotically, two main regions exist in parameter space where information may be propagated and its propagation is controlled by pulse-gating: a large region where binary codes may be propagated, and a smaller region near a cusp in parameter space that supports graded propagation across many layers.

Original languageEnglish
Article number102
JournalEntropy
Volume20
Issue number2
DOIs
StatePublished - 1 Feb 2018
Externally publishedYes

Keywords

  • Channel capacity
  • Feedforward networks
  • Neural coding
  • Neural information propagation
  • Pulse-gating

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