| Form of presentation | Articles in international journals and collections |
| Year of publication | 2023 |
|
Galimyanov Anis Fuatovich, author
|
| Bibliographic description in the original language |
Duc, N. T. Neural network method for solving fractional differential equations with the dirichlet problem / N. T. Duc, A. F. Galimyanov, I. Z. Akhmetov // 2023 International Russian Smart Industry Conference (SmartIndustryCon) / IEEE. - 2023. - Pp. 295-300, doi: 10.1109/SmartIndustryCon57312.2023.10110785. |
| Annotation |
2023 International Russian Smart Industry Conference (SmartIndustryCon) |
| Keywords |
fractional differential equations,Dirichlet?s problem, conformable fractional derivative, artificial neural network |
| The name of the journal |
2023 International Russian Smart Industry Conference (SmartIndustryCon)
|
| Publishing house |
IEEE |
| URL |
https://ieeexplore.ieee.org/abstract/document/10110785/keywords#keywords |
| Please use this ID to quote from or refer to the card |
https://repository.kpfu.ru/eng/?p_id=280824&p_lang=2 |
Full metadata record  |
| Field DC |
Value |
Language |
| dc.contributor.author |
Galimyanov Anis Fuatovich |
ru_RU |
| dc.date.accessioned |
2023-01-01T00:00:00Z |
ru_RU |
| dc.date.available |
2023-01-01T00:00:00Z |
ru_RU |
| dc.date.issued |
2023 |
ru_RU |
| dc.identifier.citation |
Duc, N. T. Neural network method for solving fractional differential equations with the dirichlet problem / N. T. Duc, A. F. Galimyanov, I. Z. Akhmetov // 2023 International Russian Smart Industry Conference (SmartIndustryCon) / IEEE. - 2023. - Pp. 295-300, doi: 10.1109/SmartIndustryCon57312.2023.10110785. |
ru_RU |
| dc.identifier.uri |
https://repository.kpfu.ru/eng/?p_id=280824&p_lang=2 |
ru_RU |
| dc.description.abstract |
2023 International Russian Smart Industry Conference (SmartIndustryCon) |
ru_RU |
| dc.description.abstract |
In this paper, we have developed an artificial neural network (ANN) method for finding solutions to the Dirichlet problem for fractional order differential equations (FODEs) 0 <α<1 using the definition of a conformable fractional derivative. Here, we used a feedforward neural architecture, L-BFGS (Broyden ? Fletcher ? Goldfarb - Shanno) optimization method to minimize the error function and change the parameters (weights and biases). The main idea is that if the sum of the norms of the residuals of the equation on the domain of definition and the boundary conditions tends to zero when the unknown function y(x) is replaced by its neural network approximation N(x), then N(x) is an approximate solution of the differential equation. Some illustrative examples are given demonstrating the accuracy and efficiency of this method and comparing the results of the current method with mathematical results. |
ru_RU |
| dc.language.iso |
ru |
ru_RU |
| dc.publisher |
IEEE |
ru_RU |
| dc.subject |
fractional differential equations |
ru_RU |
| dc.subject |
Dirichlet?s problem |
ru_RU |
| dc.subject |
conformable fractional derivative |
ru_RU |
| dc.subject |
artificial neural network |
ru_RU |
| dc.title |
Neural network method for solving fractional differential equations \alpha with the dirichlet problem |
ru_RU |
| dc.type |
Articles in international journals and collections |
ru_RU |
|
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