Solving ordinary differential equations using an optimization technique based on training improved artificial neural networks
From MaRDI portal
Publication:2099861
DOI10.1007/S00500-020-05401-WzbMath1498.65124OpenAlexW3094786200WikidataQ115387901 ScholiaQ115387901MaRDI QIDQ2099861
Publication date: 21 November 2022
Published in: Soft Computing (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/s00500-020-05401-w
differential equationsimproved artificial neural networksjoint cost functionreformulate Levenberg-Marquardt algorithm
Applications of mathematical programming (90C90) Numerical solution of boundary value problems involving ordinary differential equations (65L10)
Cites Work
- Unnamed Item
- Unnamed Item
- Unnamed Item
- Regression-based neural network training for the solution of ordinary differential equations
- One-point pseudospectral collocation for the one-dimensional Bratu equation
- Numerical solution for high order differential equations using a hybrid neural network-optimization method
- Variational iteration method for solving nonlinear boundary value problems
- Solutions of singular IVPs of Lane-Emden type by the variational iteration method
- A simple approach to a sensitive two-point boundary value problem
- Rational Runge-Kutta methods for solving systems of ordinary differential equations
- A nonlinear shooting method for two-point boundary value problems
- Multilayer feedforward networks are universal approximators
- A novel improved extreme learning machine algorithm in solving ordinary differential equations by Legendre neural network methods
- An algorithm for solving boundary value problems
- Artificial neural network approach for solving fuzzy differential equations
- Simulation and evaluation of second-order fuzzy boundary value problems
- An efficient algorithm for solving Troesch's problem
- The LS-SVM algorithms for boundary value problems of high-order ordinary differential equations
- Neural algorithm for solving differential equations
- Neural network solution of pantograph type differential equations
- On Predictor-Corrector Methods for Nonlinear Parabolic Differential Equations
- The Hilber–Hughes–Taylor-α (HHT-α) method compared with an implicit Runge–Kutta for second-order systems
This page was built for publication: Solving ordinary differential equations using an optimization technique based on training improved artificial neural networks
