Maxwell's equations govern light propagation and its interaction with matter. Therefore, the solution of Maxwell's equations using computational electromagnetic simulations plays a critical role in understanding light-matter interaction and designing optical elements. Such simulations are often time-consuming, and recent activities have been described to replace or supplement them with trained deep neural networks (DNNs). Such DNNs typically require extensive, computationally demanding simulations using conventional electromagnetic solvers to compose the training dataset. In this paper, we present a novel scheme to train a DNN that solves Maxwell's equations speedily and accurately without relying on other computational electromagnetic solv...
Metasurface has demonstrated potential and novel optical properties in previous research. The prevai...
Neural operators have emerged as a powerful tool for solving partial differential equations in the c...
Deep learning is a promising, ultra-fast approach for inverse design in nano-optics, but despite fas...
We propose and demonstrate the first end-to-end artificial neural network (ANN) modeler for the auto...
Heterogeneous materials such as biological tissue scatter light in random, yet deterministic, ways. ...
Heterogeneous materials such as biological tissue scatter light in random, yet deterministic, ways. ...
Deep learning has become the dominant approach in artificial intelligence to solve complex data-driv...
Data inconsistency leads to a slow training process when deep neural networks are used for the inver...
© 2018 SPIE. We propose a method to use artificial neural networks to approximate light scattering b...
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
We present our work on using deep neural networks for the prediction of the optical properties of na...
10 pages, 9 figuresDeep learning is a promising, ultra-fast approach for inverse design in nano-opti...
Artificial neural networks (ANNs) have been recognized as a fast and flexible tool for microwave mod...
Metasurfaces are composed of a two-dimensional array of carefully engineered subwavelength structure...
Metasurface has demonstrated potential and novel optical properties in previous research. The prevai...
Neural operators have emerged as a powerful tool for solving partial differential equations in the c...
Deep learning is a promising, ultra-fast approach for inverse design in nano-optics, but despite fas...
We propose and demonstrate the first end-to-end artificial neural network (ANN) modeler for the auto...
Heterogeneous materials such as biological tissue scatter light in random, yet deterministic, ways. ...
Heterogeneous materials such as biological tissue scatter light in random, yet deterministic, ways. ...
Deep learning has become the dominant approach in artificial intelligence to solve complex data-driv...
Data inconsistency leads to a slow training process when deep neural networks are used for the inver...
© 2018 SPIE. We propose a method to use artificial neural networks to approximate light scattering b...
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
Many phenomena in physics, including light, water waves, and sound, are described by wave equations....
We present our work on using deep neural networks for the prediction of the optical properties of na...
10 pages, 9 figuresDeep learning is a promising, ultra-fast approach for inverse design in nano-opti...
Artificial neural networks (ANNs) have been recognized as a fast and flexible tool for microwave mod...
Metasurfaces are composed of a two-dimensional array of carefully engineered subwavelength structure...
Metasurface has demonstrated potential and novel optical properties in previous research. The prevai...
Neural operators have emerged as a powerful tool for solving partial differential equations in the c...
Deep learning is a promising, ultra-fast approach for inverse design in nano-optics, but despite fas...