A Game-Theoretical Network Formation Model for Neural Network

Overview

Journal Front Comput Neurosci

Specialty Biology

Date 2019 Jul 30

PMID 31354463

Citations 1

Authors

Mohamad Khajezade

Sama Goliaei

Hadi Veisi

Affiliations

Soon will be listed here.

Abstract

Studying and understanding human brain structures and functions have become one of the most challenging issues in neuroscience today. However, the mammalian nervous system is made up of hundreds of millions of neurons and billions of synapses. This complexity made it impossible to reconstruct such a huge nervous system in the laboratory. So, most researchers focus on neural network. The neural network is the only biological neural network that is fully mapped. This nervous system is the simplest neural network that exists. However, many fundamental behaviors like movement emerge from this basic network. These features made a convenient case to study the nervous systems. Many studies try to propose a network formation model for neural network. However, these studies could not meet all characteristics of neural network, such as significant factors that play a role in the formation of neural network. Thus, new models are needed to be proposed in order to explain all aspects of neural network. In this paper, a new model based on game theory is proposed in order to understand the factors affecting the formation of nervous systems, which meet the frontal neural network characteristics. In this model, neurons are considered to be agents. The strategy for each neuron includes either making or removing links to other neurons. After choosing the basic network, the utility function is built using structural and functional factors. In order to find the coefficients for each of these factors, linear programming is used. Finally, the output network is compared with frontal neural network and previous models. The results implicate that the game-theoretical model proposed in this paper can better predict the influencing factors in the formation of neural network compared to previous models.

Citing Articles

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Alicea B Front Cell Neurosci. 2020; 14:524791.

PMID: 33100971 PMC: 7522492. DOI: 10.3389/fncel.2020.524791.

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