Temporal Sequence Learning in Winner-take-all Networks of Spiking Neurons Demonstrated in a Brain-based Device

Overview

Journal Front Neurorobot

Date 2013 Jun 14

PMID 23760804

Citations 3

Authors

Jeffrey L McKinstry

Gerald M Edelman

Affiliations

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Abstract

Animal behavior often involves a temporally ordered sequence of actions learned from experience. Here we describe simulations of interconnected networks of spiking neurons that learn to generate patterns of activity in correct temporal order. The simulation consists of large-scale networks of thousands of excitatory and inhibitory neurons that exhibit short-term synaptic plasticity and spike-timing dependent synaptic plasticity. The neural architecture within each area is arranged to evoke winner-take-all (WTA) patterns of neural activity that persist for tens of milliseconds. In order to generate and switch between consecutive firing patterns in correct temporal order, a reentrant exchange of signals between these areas was necessary. To demonstrate the capacity of this arrangement, we used the simulation to train a brain-based device responding to visual input by autonomously generating temporal sequences of motor actions.

Citing Articles

Winner-take-all in a phase oscillator system with adaptation.

Burylko O, Kazanovich Y, Borisyuk R Sci Rep. 2018; 8(1):416.

PMID: 29323149 PMC: 5765106. DOI: 10.1038/s41598-017-18666-3.

Imagery May Arise from Associations Formed through Sensory Experience: A Network of Spiking Neurons Controlling a Robot Learns Visual Sequences in Order to Perform a Mental Rotation Task.

McKinstry J, Fleischer J, Chen Y, Gall W, Edelman G PLoS One. 2016; 11(9):e0162155.

PMID: 27653977 PMC: 5031450. DOI: 10.1371/journal.pone.0162155.

Spike-Based Bayesian-Hebbian Learning of Temporal Sequences.

Tully P, Linden H, Hennig M, Lansner A PLoS Comput Biol. 2016; 12(5):e1004954.

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