Solving differential equations with unsupervised neural networks

A recent method for solving differential equations using feedforward neural networks was applied to a non-steady fixed bed non-catalytic solid-gas reactor. As neural networks have universal approximation capabilities, it is possible to postulate them as solutions for a given DE problem that defines...

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Autores principales: Parisi, D.R., Mariani, M.C., Laborde, M.A.
Formato: JOUR
Materias:
Neural networks differential equations
Non-catalytic solid-gas reactor simulations
Approximation theory
Computational complexity
Error analysis
Genetic algorithms
Problem solving
Solid-gas reactors
Feedforward neural networks
computer modeling
differential equation
neural network
reactor
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_02552701_v42_n8-9_p715_Parisi
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_02552701_v42_n8-9_p715_Parisi
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spelling todo:paper_02552701_v42_n8-9_p715_Parisi2023-10-03T15:11:37Z Solving differential equations with unsupervised neural networks Parisi, D.R. Mariani, M.C. Laborde, M.A. Neural networks differential equations Non-catalytic solid-gas reactor simulations Approximation theory Computational complexity Error analysis Genetic algorithms Problem solving Solid-gas reactors Feedforward neural networks computer modeling differential equation neural network reactor A recent method for solving differential equations using feedforward neural networks was applied to a non-steady fixed bed non-catalytic solid-gas reactor. As neural networks have universal approximation capabilities, it is possible to postulate them as solutions for a given DE problem that defines an unsupervised error. The training was performed using genetic algorithms and the gradient descent method. The solution was found with uniform accuracy (MSE ∼ 10-9) and the trained neural network provides a compact expression for the analytical solution over the entire finite domain. The problem was also solved with a traditional numerical method. In this case, solution is known only over a discrete grid of points and its computational complexity grows rapidly with the size of the grid. Although solutions in both cases are identical, the neural networks approach to the DE problem is qualitatively better since, once the network is trained, it allows instantaneous evaluation of solution at any desired number of points spending negligible computing time and memory. © 2003 Elsevier Science B.V. All rights reserved. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_02552701_v42_n8-9_p715_Parisi
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Neural networks differential equations
Non-catalytic solid-gas reactor simulations
Approximation theory
Computational complexity
Error analysis
Genetic algorithms
Problem solving
Solid-gas reactors
Feedforward neural networks
computer modeling
differential equation
neural network
reactor
spellingShingle Neural networks differential equations
Non-catalytic solid-gas reactor simulations
Approximation theory
Computational complexity
Error analysis
Genetic algorithms
Problem solving
Solid-gas reactors
Feedforward neural networks
computer modeling
differential equation
neural network
reactor
Parisi, D.R.
Mariani, M.C.
Laborde, M.A.
Solving differential equations with unsupervised neural networks
topic_facet Neural networks differential equations
Non-catalytic solid-gas reactor simulations
Approximation theory
Computational complexity
Error analysis
Genetic algorithms
Problem solving
Solid-gas reactors
Feedforward neural networks
computer modeling
differential equation
neural network
reactor
description A recent method for solving differential equations using feedforward neural networks was applied to a non-steady fixed bed non-catalytic solid-gas reactor. As neural networks have universal approximation capabilities, it is possible to postulate them as solutions for a given DE problem that defines an unsupervised error. The training was performed using genetic algorithms and the gradient descent method. The solution was found with uniform accuracy (MSE ∼ 10-9) and the trained neural network provides a compact expression for the analytical solution over the entire finite domain. The problem was also solved with a traditional numerical method. In this case, solution is known only over a discrete grid of points and its computational complexity grows rapidly with the size of the grid. Although solutions in both cases are identical, the neural networks approach to the DE problem is qualitatively better since, once the network is trained, it allows instantaneous evaluation of solution at any desired number of points spending negligible computing time and memory. © 2003 Elsevier Science B.V. All rights reserved.
format JOUR
author Parisi, D.R.
Mariani, M.C.
Laborde, M.A.
author_facet Parisi, D.R.
Mariani, M.C.
Laborde, M.A.
author_sort Parisi, D.R.
title Solving differential equations with unsupervised neural networks
title_short Solving differential equations with unsupervised neural networks
title_full Solving differential equations with unsupervised neural networks
title_fullStr Solving differential equations with unsupervised neural networks
title_full_unstemmed Solving differential equations with unsupervised neural networks
title_sort solving differential equations with unsupervised neural networks
url http://hdl.handle.net/20.500.12110/paper_02552701_v42_n8-9_p715_Parisi
work_keys_str_mv AT parisidr solvingdifferentialequationswithunsupervisedneuralnetworks
AT marianimc solvingdifferentialequationswithunsupervisedneuralnetworks
AT labordema solvingdifferentialequationswithunsupervisedneuralnetworks
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