Neural operators have emerged as a powerful tool for solving partial differential equations in the context of scientific machine learning. Here, we implement and train a modified Fourier neural operator as a surrogate solver for electromagnetic scattering problems and compare its data efficiency to existing methods. We further demonstrate its application to the gradient-based nanophotonic inverse design of free-form, fully three-dimensional electromagnetic scatterers, an area that has so far eluded the application of deep learning techniques
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
LGEP 2011 ID = 808International audienceThis paper presents a technique for solving inverse problems...
Abstract Inferring the properties of a scattering objective by analyzing the optical far-field respo...
Deep learning has become the dominant approach in artificial intelligence to solve complex data-driv...
© 2018 SPIE. We propose a method to use artificial neural networks to approximate light scattering b...
Data inconsistency leads to a slow training process when deep neural networks are used for the inver...
10 pages, 9 figuresDeep learning is a promising, ultra-fast approach for inverse design in nano-opti...
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
Machine learning offers the potential to revolutionize the inverse design of complex nanophotonic co...
We show that the free-form inverse design of nanophotonic matasurfaces can be solved with a modified...
Solution to inverse problems is of interest in many fields of science and engineering. In nondestruc...
We present our work on using deep neural networks for the prediction of the optical properties of na...
Maxwell's equations govern light propagation and its interaction with matter. Therefore, the solutio...
Metasurfaces are subwavelength-structured artificial media that can shape and localize electromagnet...
The inverse problems in electromagnetic system design, optimization, and identification received lat...
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
LGEP 2011 ID = 808International audienceThis paper presents a technique for solving inverse problems...
Abstract Inferring the properties of a scattering objective by analyzing the optical far-field respo...
Deep learning has become the dominant approach in artificial intelligence to solve complex data-driv...
© 2018 SPIE. We propose a method to use artificial neural networks to approximate light scattering b...
Data inconsistency leads to a slow training process when deep neural networks are used for the inver...
10 pages, 9 figuresDeep learning is a promising, ultra-fast approach for inverse design in nano-opti...
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
Machine learning offers the potential to revolutionize the inverse design of complex nanophotonic co...
We show that the free-form inverse design of nanophotonic matasurfaces can be solved with a modified...
Solution to inverse problems is of interest in many fields of science and engineering. In nondestruc...
We present our work on using deep neural networks for the prediction of the optical properties of na...
Maxwell's equations govern light propagation and its interaction with matter. Therefore, the solutio...
Metasurfaces are subwavelength-structured artificial media that can shape and localize electromagnet...
The inverse problems in electromagnetic system design, optimization, and identification received lat...
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
LGEP 2011 ID = 808International audienceThis paper presents a technique for solving inverse problems...
Abstract Inferring the properties of a scattering objective by analyzing the optical far-field respo...