Compounding Meta‐Atoms into Metamolecules with Hybrid Artificial Intelligence Techniques

Liu, Zhaocheng; Zhu, Dayu; Lee, Kyu‐Tae; Kim, Andrew S.; Raju, Lakshmi; Cai, Wenshan

doi:10.1002/adma.201904790

Cited by 104 publications

(91 citation statements)

References 45 publications

(94 reference statements)

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“…Even though no generalized and fast inverse design method has as yet been reported, rapid progress has been made in this direction over the last two years. 13,[36][37][38][39][40][41][42][43] The overall trend in these studies so far is, that for every specific inverse problem using a particular geometric model, a neural network needs to be designed in a time demanding and computationally very expensive process, involving hyper-parameter optimization, training data generation, training and extensive testing.…”

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confidence: 99%

Deep Learning Meets Nanophotonics: A Generalized Accurate Predictor for Near Fields and Far Fields of Arbitrary 3D Nanostructures

2019

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Deep artificial neural networks are powerful tools with many possible applications in nanophotonics. Here, we demonstrate how a deep neural network can be used as a fast, general purpose predictor of the full near-field and far-field response of plasmonic and dielectric nanostructures. A trained neural network is shown to infer the internal fields of arbitrary three-dimensional nanostructures many orders of magnitude faster compared to conventional numerical simulations. Secondary physical quantities are derived from the deep learning predictions and faithfully reproduce a wide variety of physical effects without requiring specific training. We discuss the strengths and limitations of the neural network approach using a number of model studies of single particles and their near-field interactions. Our approach paves the way for fast, yet universal methods for design and analysis of nanophotonic systems.

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confidence: 99%

Deep Learning Meets Nanophotonics: A Generalized Accurate Predictor for Near Fields and Far Fields of Arbitrary 3D Nanostructures

2019

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“…Therefore, this method enables efficient nanophotonic device evaluation and its design prediction. Overall, ML-assisted design approaches have already shown promising progress in developing a variety of high-performance metasurfaces [310,[314][315][316][317][318].…”

Section: Advanced Design and Optimization: Toward Multifunctional Metmentioning

confidence: 99%

Design for quality: reconfigurable flat optics based on active metasurfaces

et al. 2020

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Optical metasurfaces, planar subwavelength nanoantenna arrays with the singular ability to sculpt wavefront in almost arbitrary manners, are poised to become a powerful tool enabling compact and high-performance optics with novel functionalities. A particularly intriguing research direction within this field is active metasurfaces, whose optical response can be dynamically tuned postfabrication, thus allowing a plurality of applications unattainable with traditional bulk optics. Designing reconfigurable optics based on active metasurfaces is, however, presented with a unique challenge, since the optical quality of the devices must be optimized at multiple optical states. In this article, we provide a critical review on the active meta-optics design principles and algorithms that are applied across structural hierarchies ranging from single meta-atoms to full meta-optical devices. The discussed approaches are illustrated by specific examples of reconfigurable metasurfaces based on optical phase-change materials.

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“…sets and very long duration training are needed to ensure acceptable accuracy. A third alternative is opened up by using unsupervised learning with a deep autoencoder [25][26][27][28] (Fig. 1-D(iii)).…”

Section: Role Of Deep Learningmentioning

confidence: 99%

“…The training of generative networks is known to be problematic in the DL literature, specically, training can get into endless loops with no subsequent improvement in performance. In two subsequent contributions by Liu and coworkers, 27,28 the idea of generative networks was combined with Dimensionality Reduction (DR) 32,67,70 which obviates the difficulties associated with adversarial generative training. Using a variational autoencoder, a latent space representation of the set of feasible geometries was developed.…”

Section: Periodic Metasurfacesmentioning

confidence: 99%