Application of Neural Networks to Steady-State Oscillations

Introduction. In recent years, the field of mathematics specializing in the application of artificial neural networks has been rapidly developing. In this work, a new method for constructing a neural network for solving wave differential equations is proposed. This method is particularly effective in solving boundary value problems for domains of complex geometric shapes.

Materials and Methods. A method is proposed for constructing a neural network designed to solve the wave equation in a planar domain G bounded by an arbitrary closed curve. It is assumed that the boundary conditions are periodic functions of time t, and the steady-state regime is considered. When constructing the neural network, the activation functions are taken as derivatives of singular solutions of the Helmholtz equation. The singular points of these solutions are uniformly distributed along closed curves surrounding the domain boundary. The training set consists of a set of particular solutions of the Helmholtz equation.

Results. Results were obtained for the solution of the first boundary value problem in various domains of complex geometric shape and under different boundary conditions. The results are presented in tables containing both the exact solutions of the problem and the solutions obtained using the neural network. A graphical comparison is also provided between the exact solution and the solution obtained with the constructed neural network.

Discussion. The presented computational results demonstrate the efficiency of the proposed method for constructing neural networks that solve boundary value problems of partial differential equations in domains of complex geometry.

Conclusion. The further development of the proposed method may be applied to solving boundary value problems for the wave equation in exterior domains. Of particular interest is the application of this method to diffraction problems.

1. Kolmogorov A.N. On the representation of continuous functions of several variables in the form of superpositions of continuous functions of one variable and addition. Reports of the USSR Academy of Sciences. 1957;114(5):953–956. (In Russ.)

2. Varshavchik E.A., Galyautdinova A.R., Sedova Yu.S., Tarkhov D.A. Solving partial differential equations for regions with constant boundaries. In: “Artificial intelligence in solving urgent social and economic problems of the 21st century”. Perm: Publishing House of Perm State National Research University; 2018. P. 294. (In Russ.)

3. Tyurin K.A., Bragunets V.V., Svetlov D.D. Solution of the Laplace Differential Equation Using a Modified Neural Network. Young Scientist. 2019;27(265):10–12.

4. Epifanov A.A. Application of deep learning methods for solving partial differential equations. Russian Journal of Cybernetics. 2020;1(4):22–28. (In Russ.) https://doi.org/10.51790/2712-9942-2020-1-4-3

5. Zrelova D.P., Ulyanov S.V. Physics-informed classical Lagrange / Hamilton neural networks in deep learning. Modern information technologies and IT-education. 2022;18(2):310–325. https://doi.org/10.25559/SITITO.18.202202.310-325

6. Kansa E.J. Motivation for using radial basis functions to solve PDEs. URL: http://uahtitan.uah.edu/kansaweb.html (дата обращения: 12.08.2025).

7. Kansa E.J. Multiquadrics – A scattered data approximation scheme with applications to computational fluiddynamics. II. Solutions to parabolic, hyperbolic and elliptic partial differential equations. Computers & Mathematics with Applications.1990;19(8–9):147–161. https://doi.org/10.1016/0898-1221(90)90271-K

8. Almajid M., Abu-Alsaud M. Prediction of porous media fluid flow using physics informed neural networks. Journal of Petroleum Science and Engineering. 2021;208:109205. https://doi.org/10.1016/j.petrol.2021.109205

9. Eivazi H.,Tahani M., Schlatter P., Vinuesa R. Physics-informed neural networks for solving Reynolds-averaged Navier-Stokes equations. Physics of Fluids. 2022;34:075117. https://doi.org/10.1063/5.0095270

10. Shevkun S.A., Samoylov N.S. Application of the neural network approach for solution of direct and inverse problems of scattering. FEFU: School of Engineering Bulletin. 2021;2(47):66‒74. (In Russ.) https://doi.org/10.24866/2227-6858/2021-2-7

11. Galaburdin A.V. Application of neural networks to solve the Dirichlet problem for areas of complex shape. Computational Mathematics and Information Technologies. 2024;8(2):68‒79. (In Russ.) https://doi.org/10.23947/2587-8999-2024-8-2-68-79

12. Galaburdin A.V. Application of neural networks to solve nonlinear boundary value problems for areas of complex shape. Computational Mathematics and Information Technologies. 2024;8(4):35‒42. https://doi.org/10.23947/2587-8999-2024-8-4-35-42

13. Galaburdin A.V. Application of Neural Networks for Solving Elliptic Equations in Domains with Complex Geometries. Computational Mathematics and Information Technologies. 2025;9(2):44‒51. https://doi.org/10.23947/2587-8999-2025-9-2-44-51