Kevin McFall scite author profile

A method for solving boundary value problems (BVPs) is introduced using artificial neural networks (ANNs) for irregular domain boundaries with mixed Dirichlet/Neumann boundary conditions (BCs). The approximate ANN solution automatically satisfies BCs at all stages of training, including before training commences. This method is simpler than other ANN methods for solving BVPs due to its unconstrained nature and because automatic satisfaction of Dirichlet BCs provides a good starting approximate solution for significant portions of the domain. Automatic satisfaction of BCs is accomplished by the introduction of an innovative length factor. Several examples of BVP solution are presented for both linear and nonlinear differential equations in two and three dimensions. Error norms in the approximate solution on the order of 10(-4) to 10(-5) are reported for all example problems.

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A Blockchain and AutoML Approach for Open and Automated Customer Service

Guo

Wang

et al. 2019

IEEE Trans. Ind. Inf.

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Automated design parameter selection for neural networks solving coupled partial differential equations with discontinuities

McFall

2013

Journal of the Franklin Institute

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Artificial Neural Networks in Radiation Heat Transfer Analysis

Yarahmadi

Mahan

McFall

2020

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Abstract In the Monte Carlo ray-trace (MCRT) method, millions of rays are emitted and traced throughout an enclosure following the laws of geometrical optics. Each ray represents the path of a discrete quantum of energy emitted from surface element i and eventually absorbed by surface element j. The distribution of rays absorbed by the n surface elements making up the enclosure is interpreted in terms of a radiation distribution factor matrix whose elements represent the probability that energy emitted by element i will be absorbed by element j. Once obtained, the distribution factor matrix may be used to compute the net heat flux distribution on the walls of an enclosure corresponding to a specified surface temperature distribution. It is computationally very expensive to obtain high accuracy in the heat transfer calculation when high spatial resolution is required. This is especially true if a manifold of emissivities is to be considered in a parametric study in which each value of surface emissivity requires a new ray-trace to determine the corresponding distribution factor matrix. Artificial neural networks (ANNs) offer an alternative approach whose computational cost is greatly inferior to that of the traditional MCRT method. Significant computational efficiency is realized by eliminating the need to perform a new ray trace for each value of emissivity. The current contribution introduces and demonstrates through case studies estimation of radiation distribution factor matrices using ANNs and their subsequent use in radiation heat transfer calculations.

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Software Effort Estimation Using a Neural Network Ensemble

Pai

McFall

Subramanian

2013

Journal of Computer Information Systems

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Kevin McFall

Artificial Neural Network Method for Solution of Boundary Value Problems With Exact Satisfaction of Arbitrary Boundary Conditions

A Blockchain and AutoML Approach for Open and Automated Customer Service

Automated design parameter selection for neural networks solving coupled partial differential equations with discontinuities

Artificial Neural Networks in Radiation Heat Transfer Analysis

Software Effort Estimation Using a Neural Network Ensemble

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