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Inverse deep learning methods and benchmarks for artificial electromagnetic material design.

Simiao Ren1, Ashwin Mahendra1, Omar Khatib1

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Summary
This summary is machine-generated.

Deep inverse models (DIMs) rapidly design artificial electromagnetic materials (AEMs) for desired scattering properties. The Neural-Adjoint model showed best performance, though conventional deep neural networks excel for well-posed problems.

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Area of Science:

  • Computational electromagnetics
  • Materials science
  • Artificial intelligence

Background:

  • Artificial electromagnetic materials (AEMs) like metamaterials, photonic crystals, and plasmonics are crucial for controlling electromagnetic wave interactions.
  • Deep inverse models (DIMs), a type of deep learning, are increasingly used for designing AEMs to achieve specific scattering properties (e.g., transmission/reflection spectra).
  • A comprehensive comparison of existing DIMs for AEM design is lacking.

Purpose of the Study:

  • To compare the performance of eight state-of-the-art deep inverse models (DIMs) for designing artificial electromagnetic materials (AEMs).
  • To introduce and evaluate two novel DIMs for AEM design.
  • To determine the optimal approach for AEM design problems, considering both ill-posed and well-posed scenarios.

Main Methods:

  • Evaluated eight state-of-the-art deep inverse models (DIMs) on three distinct artificial electromagnetic material (AEM) design challenges.
  • Introduced and assessed two novel DIMs within the context of AEM design.
  • Compared DIM performance against conventional deep neural networks for well-posed design problems.

Main Results:

  • Deep inverse models (DIMs) demonstrated the capability to rapidly generate accurate designs for achieving custom scattering properties in artificial electromagnetic materials (AEMs) across all tested problems.
  • The Neural-Adjoint DIM approach exhibited the strongest overall performance across the evaluated AEM design scenarios.
  • For well-posed AEM design problems, conventional deep neural networks outperformed specialized DIMs.

Conclusions:

  • Deep inverse models (DIMs) are effective tools for accelerating the design of artificial electromagnetic materials (AEMs) with tailored scattering characteristics.
  • The Neural-Adjoint model presents a robust option for AEM design, though problem type dictates the optimal deep learning strategy.
  • It is recommended to utilize a conventional deep neural network as a baseline for AEM design, especially when problem well-posedness is uncertain.