2019
DOI: 10.1007/s00500-019-03944-1
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Neural network algorithm based on Legendre improved extreme learning machine for solving elliptic partial differential equations

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Cited by 43 publications
(26 citation statements)
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“…It is proven that the ELM's origin is based on Random Vector Functional Link (RVLF) [51,52], leading to the ultra-fast learning and outstanding generalization capability [53,54]. Literature survey shows that ELM has been broadly utilized in many engineering applications [55][56][57]. Although various kinds of ELMs are now accessible for image detection and classification tasks, it confronts serious issues such as the need for many hidden nodes for better generalization and Cite as: Chao Wu, Mohammad Khishe, Mokhtar Mohammadi, Sarkhel H. Taher Karim & Tarik A. Rashid (2021).…”
Section: Introductionmentioning
confidence: 99%
“…It is proven that the ELM's origin is based on Random Vector Functional Link (RVLF) [51,52], leading to the ultra-fast learning and outstanding generalization capability [53,54]. Literature survey shows that ELM has been broadly utilized in many engineering applications [55][56][57]. Although various kinds of ELMs are now accessible for image detection and classification tasks, it confronts serious issues such as the need for many hidden nodes for better generalization and Cite as: Chao Wu, Mohammad Khishe, Mokhtar Mohammadi, Sarkhel H. Taher Karim & Tarik A. Rashid (2021).…”
Section: Introductionmentioning
confidence: 99%
“…Suppose that the approximate solution to (27) is y = ω T φ(x) + b, the original optimal problem is described as follows: min ω,b,e i J(ω, e) = 1 2 ω T ω + 1 2 γ e T e (28) subject to…”
Section: Linear Ordinary Differential Equations For Multi-point Boundmentioning
confidence: 99%
“…Neural network, which is one of machine intelligence techniques, has universal function approximation capabilities [20][21][22], and the solution obtained from the neural network is differentiable and in closed analytic form. Neural network has been widely used for solving ordinary differential equations [23,24], partial differential equations [25][26][27], fractional differential equations [28][29][30], and integro-differential equations [31,32]. Chakraverty and Mall [33] analyzed a regression-based neural network algorithm to solve two-point boundary value problems of fourth-order linear ordinary differential equations.…”
Section: Introductionmentioning
confidence: 99%
“…Under certain conditions, the alternating minimum algorithm used is convergent [7]. Yang et al proposed an image segmentation algorithm based on the global positive radial basis function by combining the method of global positive radial basis function and partial differential equation [8]. This algorithm integrates the global positive radial basis function difference method into the level set function image segmentation model.…”
Section: Introductionmentioning
confidence: 99%