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Neuro-computing solution for Lorenz differential equations through artificial neural networks integrated with PSO-NNA hybrid meta-heuristic algorithms: a comparative study

Muhammad Naeem Aslam, Muhammad Waheed Aslam, Muhammad Sarmad Arshad, Zeeshan Afzal, Murad Khan Hassani, Ahmed M. Zidan, Ali Akgül

2024Scientific Reports21 citationsDOIOpen Access PDF

Abstract

In this article, examine the performance of a physics informed neural networks (PINN) intelligent approach for predicting the solution of non-linear Lorenz differential equations. The main focus resides in the realm of leveraging unsupervised machine learning for the prediction of the Lorenz differential equation associated particle swarm optimization (PSO) hybridization with the neural networks algorithm (NNA) as ANN-PSO-NNA. In particular embark on a comprehensive comparative analysis employing the Lorenz differential equation for proposed approach as test case. The nonlinear Lorenz differential equations stand as a quintessential chaotic system, widely utilized in scientific investigations and behavior of dynamics system. The validation of physics informed neural network (PINN) methodology expands to via multiple independent runs, allowing evaluating the performance of the proposed ANN-PSO-NNA algorithms. Additionally, explore into a comprehensive statistical analysis inclusive metrics including minimum (min), maximum (max), average, standard deviation (S.D) values, and mean squared error (MSE). This evaluation provides found observation into the adeptness of proposed AN-PSO-NNA hybridization approach across multiple runs, ultimately improving the understanding of its utility and efficiency.

Topics & Concepts

Particle swarm optimizationLorenz systemArtificial neural networkComputer scienceHeuristicAlgorithmNonlinear systemMean squared errorDifferential equationDifferential evolutionArtificial intelligenceMathematicsMathematical optimizationChaoticStatisticsMathematical analysisPhysicsQuantum mechanicsModel Reduction and Neural NetworksNeural Networks and ApplicationsFluid Dynamics and Turbulent Flows