Journal
NANOPHOTONICS
Volume 12, Issue 13, Pages 2583-2591Publisher
WALTER DE GRUYTER GMBH
DOI: 10.1515/nanoph-2022-0770
Keywords
deep neural network; inverse problem; scattering matrix
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The scattering matrix is a mathematical representation of scattering characteristics, but it lacks analytical forms for scatterers without high symmetry. We developed a deep neural network (DNN) that can calculate the scattering matrix of asymmetric scatterers thousands of times faster than finite element solvers. The DNN satisfies fundamental physical principles and enables inverse design using the gradient descent algorithm.
The scattering matrix is the mathematical representation of the scattering characteristics of any scatterer. Nevertheless, except for scatterers with high symmetry like spheres or cylinders, the scattering matrix does not have any analytical forms and thus can only be calculated numerically, which requires heavy computation. Here, we have developed a well-trained deep neural network (DNN) that can calculate the scattering matrix of scatterers without symmetry at a speed thousands of times faster than that of finite element solvers. Interestingly, the scattering matrix obtained from the DNN inherently satisfies the fundamental physical principles, including energy conservation, time reversal and reciprocity. Moreover, inverse design based on the DNN is made possible by applying the gradient descent algorithm. Finally, we demonstrate an application of the DNN, which is to design scatterers with desired scattering properties under special conditions. Our work proposes a convenient solution of deep learning for scattering problems.
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