Numerical performance using the neural networks to solve the nonlinear biological quarantined based COVID-19 model
Abstract
The current study provides the solutions of the mathematical model based on the coronavirus including the effects of vaccination and quarantine. The numerical stochastic process relying on Levenberg-Marquardt backpropagation technique (L-MB) neural networks (NN), i.e., L-MBNNs, is presented to solve the model. The entire dynamics of the proposed model depends upon the human population, which is represented by N and is further divided into multiple subgroups. The detail of these subgroups is presented in the form of susceptible population (S), exposed population (E), and infected people (I). Likewise, Q represents the quarantined and R shows the recovered or deceased individuals. Those who have been immunized are symbolized by V. All these categories make the model SEIQRV, that is based on a system of nonlinear differential equations. The statistics that is used to provide the numerical solutions of the SEIQRV model is 76% for training, 10% for testing and 14% for authorization. The correctness of the L-MBNNs is tested by using the comparison of the proposed and reference solutions (Adam method). The statistical representations are provided in order to check the reliability, competence and validity of L-MBNNs using the procedures of error histograms (EH), state transitions (ST), regression and correlation.
Keywords
COVID-19 model; neural networks; Levenberg-Marquardt back propagation scheme; Adams-Bashforth-Moulton
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PDFDOI: https://doi.org/10.1478/AAPP.1011A10
Copyright (c) 2023 Zulqurnain Sabir, Muhammad Asif Zahoor Raja, Haci Mehmet Baskonus, Armando Ciancio
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