Deep learning in nano-photonics: inverse design and beyond
Deep learning in nano-photonics: inverse design and beyond
Deep learning in the context of nano-photonics is mostly discussed in terms of its potential for inverse design of photonic devices or nano-structures. Many of the recent works on machine-learning inverse design are highly specific, and the drawbacks of the respective approaches are often not immediately clear. In this review we want therefore to provide a critical review on the capabilities of deep learning for inverse design and the progress which has been made so far. We classify the different deep-learning-based inverse design approaches at a higher level as well as by the context of their respective applications and critically discuss their strengths and weaknesses. While a significant part of the community’s attention lies on nano-photonic inverse design, deep learning has evolved as a tool for a large variety of applications. The second part of the review will focus therefore on machine learning research in nano-photonics “beyond inverse design.” This spans from physics-informed neural networks for tremendous acceleration of photonics simulations, over sparse data reconstruction, imaging and “knowledge discovery” to experimental applications.
B182-B200
Wiecha, Peter R.
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Arbouet, Arnaud
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Girard, Christian
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Muskens, Otto L.
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14 April 2021
Wiecha, Peter R.
f297f06e-c298-4f3b-8cb9-98ccd21cd124
Arbouet, Arnaud
3c681c1a-31cf-45dc-9f7f-604b81ebde4e
Girard, Christian
85fb41ad-6753-46a1-b550-b719cf329a52
Muskens, Otto L.
2284101a-f9ef-4d79-8951-a6cda5bfc7f9
Wiecha, Peter R., Arbouet, Arnaud, Girard, Christian and Muskens, Otto L.
(2021)
Deep learning in nano-photonics: inverse design and beyond.
Photonics Research, 9 (5), .
(doi:10.1364/PRJ.415960).
Abstract
Deep learning in the context of nano-photonics is mostly discussed in terms of its potential for inverse design of photonic devices or nano-structures. Many of the recent works on machine-learning inverse design are highly specific, and the drawbacks of the respective approaches are often not immediately clear. In this review we want therefore to provide a critical review on the capabilities of deep learning for inverse design and the progress which has been made so far. We classify the different deep-learning-based inverse design approaches at a higher level as well as by the context of their respective applications and critically discuss their strengths and weaknesses. While a significant part of the community’s attention lies on nano-photonic inverse design, deep learning has evolved as a tool for a large variety of applications. The second part of the review will focus therefore on machine learning research in nano-photonics “beyond inverse design.” This spans from physics-informed neural networks for tremendous acceleration of photonics simulations, over sparse data reconstruction, imaging and “knowledge discovery” to experimental applications.
Text
prj-9-5-b182
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Accepted/In Press date: 27 January 2021
e-pub ahead of print date: 29 January 2021
Published date: 14 April 2021
Identifiers
Local EPrints ID: 491287
URI: http://eprints.soton.ac.uk/id/eprint/491287
ISSN: 2327-9125
PURE UUID: 3fa74e67-762b-40f5-a68c-13b59b3d2ed5
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Date deposited: 18 Jun 2024 17:01
Last modified: 19 Jun 2024 01:42
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Author:
Peter R. Wiecha
Author:
Arnaud Arbouet
Author:
Christian Girard
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