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A Dendritic Neuron Model with Adaptive Synapses Trained by Differential Evolution Algorithm

Zhe Wang, Shangce Gao, Jiaxin Wang, Haichuan Yang, Yuki Todo

2020Computational Intelligence and Neuroscience41 citationsDOIOpen Access PDF

Abstract

A dendritic neuron model with adaptive synapses (DMASs) based on differential evolution (DE) algorithm training is proposed. According to the signal transmission order, a DNM can be divided into four parts: the synaptic layer, dendritic layer, membrane layer, and somatic cell layer. It can be converted to a logic circuit that is easily implemented on hardware by removing useless synapses and dendrites after training. This logic circuit can be designed to solve complex nonlinear problems using only four basic logical devices: comparators, AND (conjunction), OR (disjunction), and NOT (negation). To obtain a faster and better solution, we adopt the most popular DE for DMAS training. We have chosen five classification datasets from the UCI Machine Learning Repository for an experiment. We analyze and discuss the experimental results in terms of the correct rate, convergence rate, ROC curve, and the cross-validation and then compare the results with a dendritic neuron model trained by the backpropagation algorithm (BP-DNM) and a neural network trained by the backpropagation algorithm (BPNN). The analysis results show that the DE-DMAS shows better performance in all aspects.

Topics & Concepts

BackpropagationComputer scienceAlgorithmArtificial neural networkPerceptronBiological neuron modelArtificial intelligenceConvergence (economics)Layer (electronics)ComparatorRate of convergencePattern recognition (psychology)Key (lock)VoltageOrganic chemistryPhysicsQuantum mechanicsEconomicsChemistryComputer securityEconomic growthNeural Networks and Reservoir ComputingNeural Networks and ApplicationsAdvanced Memory and Neural Computing
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