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Perceptron Learning and Classification in a Modeled Cortical Pyramidal Cell

Toviah Moldwin, Idan Segev

2020Frontiers in Computational Neuroscience34 citationsDOIOpen Access PDF

Abstract

The perceptron learning algorithm and its multiple-layer extension, the backpropagation algorithm, are the foundations of the present-day machine learning revolution. However, these algorithms utilize a highly simplified mathematical abstraction of a neuron; it is not clear to what extent real biophysical neurons with morphologically-extended non-linear dendritic trees and conductance-based synapses can realize perceptron-like learning. Here we implemented the perceptron learning algorithm in a realistic biophysical model of a layer 5 cortical pyramidal cell with a full complement of non-linear dendritic channels. We tested this biophysical perceptron (BP) on a classification task, where it needed to correctly binarily classify 100, 1,000, or 2,000 patterns, and a generalization task, where it was required to discriminate between two "noisy" patterns. We show that the BP performs these tasks with an accuracy comparable to that of the original perceptron, though the classification capacity of the apical tuft is somewhat limited. We concluded that cortical pyramidal neurons can act as powerful classification devices.

Topics & Concepts

PerceptronComputer scienceMemorizationArtificial intelligenceBackpropagationGeneralizationPattern recognition (psychology)Multilayer perceptronPyramidal cellMachine learningTask (project management)Artificial neural networkNeuroscienceMathematicsPsychologyMathematical analysisEconomicsHippocampal formationMathematics educationManagementNeural dynamics and brain functionNeural Networks and ApplicationsAdvanced Memory and Neural Computing