Design Space Reparameterization Enforces Hard Geometric Constraints in Inverse-Designed Nanophotonic Devices

Chen, Mingkun; Jiang, Jiaqi; Fan, Jonathan A.

doi:10.1021/acsphotonics.0c01202

Cited by 40 publications

(36 citation statements)

References 42 publications

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“…Therefore, the observation that all three models perform similarly in terms of robustness is not surprising. Although we only consider two specific inverse design problems, these neural networks models and introduced evaluation metrics are applicable for many other nanophotonic inverse design problems with different structures and materials, including the multilayer thin films 35 , plasmonic nanostructures 56 , and metasurfaces 37 , etc, where their structures can be described either by a vector or an image when processed by appropriate neural networks. Therefore, our conclusions are generalizable to a wide range of nanophotonic inverse design problems.…”

Section: Resultsmentioning

confidence: 99%

Benchmarking deep learning-based models on nanophotonic inverse design problems

Ma¹,

Tobah²,

Wang³

et al. 2022

OES

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Photonic inverse design concerns the problem of finding photonic structures with target optical properties. However, traditional methods based on optimization algorithms are time-consuming and computationally expensive. Recently, deep learning-based approaches have been developed to tackle the problem of inverse design efficiently. Although most of these neural network models have demonstrated high accuracy in different inverse design problems, no previous study has examined the potential effects under given constraints in nanomanufacturing. Additionally, the relative strength of different deep learning-based inverse design approaches has not been fully investigated. Here, we benchmark three commonly used deep learning models in inverse design: Tandem networks, Variational Auto-Encoders, and Generative Adversarial Networks. We provide detailed comparisons in terms of their accuracy, diversity, and robustness. We find that tandem networks and Variational Auto-Encoders give the best accuracy, while Generative Adversarial Networks lead to the most diverse predictions. Our findings could serve as a guideline for researchers to select the model that can best suit their design criteria and fabrication considerations. In addition, our code and data are publicly available, which could be used for future inverse design model development and benchmarking.

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Section: Resultsmentioning

confidence: 99%

Benchmarking deep learning-based models on nanophotonic inverse design problems

Ma¹,

Tobah²,

Wang³

et al. 2022

OES

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“…We note that the 𝐿 = 1 geometry already achieves good overlap with a Gaussian mode, and expect that this could be improved with direct optimization of the grating structure for this particular figure of merit. Other optimization procedures could be used, such as inverse design [28,29], to numerical evaluation based on the analytical proposal described here. The VLDMoRt can also be designed to enhance 𝜂 of diamond group-IV emitters and even other solid-state defects such as rare-earth ions and quantum dots.…”

Section: Discussionmentioning

confidence: 99%

A vertically-loaded diamond microdisk resonator spin-photon interface

Duan,

Chen,

Englund

et al. 2021

Preprint

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We propose and optimize a vertically-loaded diamond microdisk resonator (VLD-MoRt) coupled to a nitrogen-vacancy (NV) center in diamond for efficient collection of fluorescence emission into low numerical aperture (NA) free-space modes. The VLDMoRt achieves a Purcell enhancement of 172 with 39% of the emitted light collected within a NA of 0.6, leading to a total external spin-photon collection efficiency of 0.33. As the design is compatible with established nanofabrication techniques and couples to low-NA modes accessible by cryogenic free-space optical systems, it is a promising avenue for increasing the efficiency and scalability of quantum devices based on diamond quantum emitters.

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“…Recently growing attention has focused on the hybrid tactics to customize metagratings [97], e.g., to combine NN with conventional optimizers. Besides the above-noted contributions [87], another seminal work of Liu et al [88] proposed a fusion scheme connecting compositional pattern-producing network and a cooperative coevolution to tailor molecule-resembled meta-surfaces (see the algorithm diagram in Fig.…”

Section: Meta-gratingmentioning

confidence: 99%

Intelligent designs in nanophotonics: from optimization towards inverse creation

Wang

Yan

et al. 2021

PhotoniX

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Applying intelligence algorithms to conceive nanoscale meta-devices becomes a flourishing and extremely active scientific topic over the past few years. Inverse design of functional nanostructures is at the heart of this topic, in which artificial intelligence (AI) furnishes various optimization toolboxes to speed up prototyping of photonic layouts with enhanced performance. In this review, we offer a systemic view on recent advancements in nanophotonic components designed by intelligence algorithms, manifesting a development trend from performance optimizations towards inverse creations of novel designs. To illustrate interplays between two fields, AI and photonics, we take meta-atom spectral manipulation as a case study to introduce algorithm operational principles, and subsequently review their manifold usages among a set of popular meta-elements. As arranged from levels of individual optimized piece to practical system, we discuss algorithm-assisted nanophotonic designs to examine their mutual benefits. We further comment on a set of open questions including reasonable applications of advanced algorithms, expensive data issue, and algorithm benchmarking, etc. Overall, we envision mounting photonic-targeted methodologies to substantially push forward functional artificial meta-devices to profit both fields.

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Design Space Reparameterization Enforces Hard Geometric Constraints in Inverse-Designed Nanophotonic Devices

Cited by 40 publications

References 42 publications

Benchmarking deep learning-based models on nanophotonic inverse design problems

Benchmarking deep learning-based models on nanophotonic inverse design problems

A vertically-loaded diamond microdisk resonator spin-photon interface

Intelligent designs in nanophotonics: from optimization towards inverse creation

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