Fabrication-conscious neural network based inverse design of single-material variable-index multilayer films

Yeşilyurt, Ömer; Peana, Samuel; Mkhitaryan, Vahagn; Pagadala, Karthik; Shalaev, Vladimir M.; Kildishev, Alexander V.; Boltasseva, Alexandra

doi:10.1515/nanoph-2022-0537

Cited by 6 publications

(3 citation statements)

References 42 publications

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“…During this iterative optimization process, the device is simulated using the transfer matrix method (TMM), and local gradients are calculated by autodifferentiating the TMM expressions. Analytic TMM autodifferentiation has been previously used for various thin-film stack design tasks and provides a straightforward way to calculate gradients in high-dimensional optimization landscapes. , Once the initial thin-film stack is optimized, it is duplicated, vertically stacked, and used as a starting point for further local gradient-based optimization. These duplication, stacking, and local optimization steps are repeated until the desired number of layers is achieved.…”

Section: Methodsmentioning

confidence: 99%

Multifunctional Spaceplates for Optical Aberration Correction

Shao,

Lupoiu,

Jiang

et al. 2024

ACS Photonics

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Spaceplates are nonlocal optical devices with the potential to reduce the form factor of optical systems, but current implementations are limited in performance and ability to correct for optical aberrations. We introduce a new class of multifunctional spaceplates, designed using gradient-based freeform optimization, which exhibit exceptional efficiencies, compression ratios, and aberration correcting capabilities. We show that such spaceplates can serve as correctors for metasurfaces and refractive optical elements, and we demonstrate that multifunctional spaceplates can extend to support multispectral, Petzval field curvature, and spherical aberration correction. We anticipate that these spaceplate concepts will enable the realization of ultracompact optical systems.

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Section: Methodsmentioning

confidence: 99%

Multifunctional Spaceplates for Optical Aberration Correction

Shao,

Lupoiu,

Jiang

et al. 2024

ACS Photonics

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“…Deep learning based on multilayer artificial neural networks (Figure a) has recently attracted significant attention from the photonics’ community . Deep learning that brings substantial acceleration capability and forth a feasible avenue for global optimization, has been introduced in metasurface design problems, including multilayer perceptrons, , convolutional neural networks, generative adversarial networks, and variational autoencoders. − The method allows combination with other optimization techniques such as genetic algorithms, , topology optimization, , or adjoint optimization , to enable high-performance, large-scale metasurface designs.…”

Section: Methods Of Metasurface Designmentioning

confidence: 99%

Designing Metasurfaces for Efficient Solar Energy Conversion

Mascaretti,

Chen,

Henrotte

et al. 2023

ACS Photonics

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“…An inverse modeling approach avoids the need for coupling a forward model with an optimizer and directly performs the prediction of the optimal design parameters values. This paper focuses on the Mixture Density Network (MDN) architecture for inverse modeling [4], [9], [15], which is based on the composition of a Gaussian Mixture Model and a Neural Network. The output space of an MDN contains the mean and standard deviation values of multiple Gaussian probability distribution functions (pdfs) and the mixing coefficients that denote some weights (importance) associated with the Gaussian pdfs.…”

Section: Introductionmentioning

confidence: 99%

Transfer Learning-Assisted Inverse Modeling in Nanophotonics Based on Mixture Density Networks

Cheng,

Singh,

Ferranti

2024

IEEE Access

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The simulation of nanophotonic structures relies on electromagnetic solvers, which play a crucial role in understanding their behavior. However, these solvers often come with a significant computational cost, making their application in design tasks, such as optimization, impractical. To address this challenge, machine learning techniques have been explored for accurate and efficient modeling and design of photonic devices. Deep neural networks, in particular, have gained considerable attention in this field. They can be used to create both forward and inverse models. An inverse modeling approach avoids the need for coupling a forward model with an optimizer and directly performs the prediction of the optimal design parameters values. In this paper, we propose an inverse modeling method for nanophotonic structures, based on a mixture density network model enhanced by transfer learning. Mixture density networks can predict multiple possible solutions at a time including their respective importance as Gaussian distributions. However, multiple challenges exist for mixture density network models. An important challenge is that an upper bound on the number of possible simultaneous solutions needs to be specified in advance. Also, another challenge is that the model parameters must be jointly optimized, which can result computationally expensive. Moreover, optimizing all parameters simultaneously can be numerically unstable and can lead to degenerate predictions. The proposed approach allows overcoming these limitations using transfer learning-based techniques, while preserving a high accuracy in the prediction capability of the design solutions given an optical response as an input. A dimensionality reduction step is also explored. Numerical results validate the proposed method.INDEX TERMS Machine learning, mixed density network, inverse modeling, transfer learning, photonics.

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Fabrication-conscious neural network based inverse design of single-material variable-index multilayer films

Cited by 6 publications

References 42 publications

Multifunctional Spaceplates for Optical Aberration Correction

Multifunctional Spaceplates for Optical Aberration Correction

Designing Metasurfaces for Efficient Solar Energy Conversion

Transfer Learning-Assisted Inverse Modeling in Nanophotonics Based on Mixture Density Networks

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