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Paper detail

Machine Learning Approach for Transforming Scattering Parameters to Complex Permittivity

This study investigates the application of an artificial neural network to predict the complex dielectric properties of granular catalysts commonly used in microwave reaction chemistry. The study utilizes finite element electromagnetic simulations and two-dimensional convolutional neural networks to solve for a large solution space of varying dielectrics. This convolutional neural network was trained using a supervised learning approach and a common backpropagation. The frequency range of interest was between 0.1 to 13.5 GHz with the real part of the dielectric constants ranging from 1 to 100 and the imaginary part ranging from 0.0 to 0.2. The network was double validated using experimental data collected from a coaxial airline. The model was demonstrated to convert either experimental or computational derived scattering parameter to complex permittivities. Moreover, the model eliminates the need for iterative solutions that often have difficulty with the piecewise continuous nature of frequency dependent scattering parameters.

preprint2020arXivOpen access
Robert TempkeLiam ThomasChristina WildfireDushyant ShekhawatTerence Musho
physics.app-ph
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Robert TempkeLiam ThomasChristina WildfireDushyant ShekhawatTerence Musho

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