Fractal Solitons, Arbitrary Function Solutions, Exact Periodic Wave and Breathers for a Nonlinear Partial Differential Equation by Using Bilinear Neural Network Method

Fractal Solitons, Arbitrary Function Solutions, Exact Periodic Wave and Breathers for a Nonlinear Partial Differential Equation by Using Bilinear Neural Network Method

This paper extends a method, called bilinear neural network method (BNNM), to solve exact solutions to nonlinear partial differential equation. New, test functions are constructed by using this method. These test functions are composed of specific activation functions of single-layer model, specific...

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Bibliographic Details
Published in:Journal of systems science and complexity Vol. 34; no. 1; pp. 122 - 139
Main Authors: Zhang, Runfa, Bilige, Sudao, Chaolu, Temuer
Format: Journal Article
Language:English
Published: Beijing Academy of Mathematics and Systems Science, Chinese Academy of Sciences 01-02-2021
Springer Nature B.V
Subjects:
Breathers
Complex Systems
Control
Exact solutions
Fractals
Mathematics
Mathematics and Statistics
Mathematics of Computing
Neural networks
Nonlinear differential equations
Operations Research/Decision Theory
Partial differential equations
Self-similarity
Solitary waves
Statistics
Systems Theory
Three dimensional models
Arbitrary function solutions
breather
Lump solitons waves
solitons
bilinear neural network method
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Summary:This paper extends a method, called bilinear neural network method (BNNM), to solve exact solutions to nonlinear partial differential equation. New, test functions are constructed by using this method. These test functions are composed of specific activation functions of single-layer model, specific activation functions of “2-2” model and arbitrary functions of “2-2-3” model. By means of the BNNM, nineteen sets of exact analytical solutions and twenty-four arbitrary function solutions of the dimensionally reduced p -gBKP equation are obtained via symbolic computation with the help of Maple. The fractal solitons waves are obtained by choosing appropriate values and the self-similar characteristics of these waves are observed by reducing the observation range and amplifying the partial picture. By giving a specific activation function in the single layer neural network model, exact periodic waves and breathers are obtained. Via various three-dimensional plots, contour plots and density plots, the evolution characteristic of these waves are exhibited.
ISSN:1009-6124
1559-7067
DOI:10.1007/s11424-020-9392-5