Physics-informed neural networks for inverse problems in nano-optics and metamaterials
YCYuyao ChenLLLu LuGEGeorge Em KarniadakisLDLuca Dal Negro
Indexed inarxivcrossrefdoajpubmed
Abstract
In this paper, we employ the emerging paradigm of physics-informed neural networks (PINNs) for the solution of representative inverse scattering problems in photonic metamaterials and nano-optics technologies. In particular, we successfully apply mesh-free PINNs to the difficult task of retrieving the effective permittivity parameters of a number of finite-size scattering systems that involve many interacting nanostructures as well as multi-component nanoparticles. Our methodology is fully validated by numerical simulations based on the finite element method (FEM). The development of physics-informed deep learning techniques for inverse scattering can enable the design of novel functional nanostructures and…
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622
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Authors
4- YCYuyao ChenCorresponding
- LLLu Lu
- GEGeorge Em Karniadakis
- LDLuca Dal Negro
Topics & keywords
Topics
Keywords
- Metamaterial
- Inverse problem
- Inverse scattering problem
- Artificial neural network
- Scattering
- Photonics
- Photonic metamaterial
- Permittivity
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