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Design of optical meta-structures with applications to beam engineering using deep learning

Engineering and Technology

Design of optical meta-structures with applications to beam engineering using deep learning

R. Singh, A. Agarwal, et al.

This groundbreaking research by Robin Singh, Anu Agarwal, and Brian W. Anthony delves into an innovative machine learning approach to reverse engineer meta-optical structures. It harnesses data-driven techniques to generate focused and collimated excitation beams for cutting-edge lab-on-chip applications, achieving remarkable accuracy with a high correlation coefficient in predicting diffraction profiles, significantly outpacing traditional optimization methods.

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Playback language: English
Abstract
This paper explores a machine learning (ML)-based method for the inverse design of meta-optical structures for photonic beam engineering. A data-driven approach models a grating meta-structure to create Gaussian, focused, and collimated excitation beams for lab-on-chip applications. Using feedforward deep neural networks (DNNs) and convolutional neural networks (CNNs), the model predicts meta-surface design parameters (repetition period, height, and size of scatterers) based on a desired electromagnetic field outcome. The trained neural network achieves a high correlation coefficient (0.996) in predicting diffraction profiles, offering a faster alternative to conventional optimization methods.
Publisher
Scientific Reports
Published On
Nov 16, 2020
Authors
Robin Singh, Anu Agarwal, Brian W. Anthony
Tags
machine learning
meta-optical structures
photonic beam engineering
deep neural networks
convolutional neural networks
data-driven approach
lab-on-chip

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