SwitchNet: A Neural Network Model for Forward and Inverse Scattering Problems

Khoo, Yuehaw; Ying, Lexing

doi:10.1137/18m1222399

Cited by 111 publications

(82 citation statements)

References 32 publications

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“…An interesting extension of the method described will be to the analysis of the attraction of parabolic pulses towards a selfsimilar state in normally dispersive nonlinear fibers with linear gain [4]. Furthermore, although demonstrated here in a fiber optics context, the principle of using NN architectures to solve wave equation-based inverse problems is expected to apply to many physical systems [30,31].…”

Section: Discussionmentioning

confidence: 99%

Artificial neural networks for nonlinear pulse shaping in optical fibers

Boscolo

Finot

2020

Optics & Laser Technology

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We use a supervised machine-learning model based on a neural network to predict the temporal and spectral intensity profiles of the pulses that form upon nonlinear propagation in optical fibers with both normal and anomalous second-order dispersion. We also show that the model is able to retrieve the parameters of the nonlinear propagation from the pulses observed at the output of the fiber. Various initial pulse shapes as well as initially chirped pulses are investigated.

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Section: Discussionmentioning

confidence: 99%

Artificial neural networks for nonlinear pulse shaping in optical fibers

Boscolo

Finot

2020

Optics & Laser Technology

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“…A second main direction focuses on the low-dimensional parameterized PDE problems, by using the DNNs to represent the nonlinear map from the high-dimensional parameters of the PDE solution [52,36,43,25,24,23,51,7]. Applying DNNs to inverse problems [45,40,41,2,53,61,26,56] can be viewed as a particularly important case of this direction. This paper applies the deep learning approach to the two-dimensional OT problems by representing both the forward and inverse maps using neural network architectures.…”

Section: Introductionmentioning

confidence: 99%

Solving electrical impedance tomography with deep learning

Fan

Ying

2020

Journal of Computational Physics

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This paper presents a neural network approach for solving two-dimensional optical tomography (OT) problems based on the radiative transfer equation. The mathematical problem of OT is to recover the optical properties of an object based on the albedo operator that is accessible from boundary measurements. Both the forward map from the optical properties to the albedo operator and the inverse map are high-dimensional and nonlinear. For the circular tomography geometry, a perturbative analysis shows that the forward map can be approximated by a vectorized convolution operator in the angular direction. Motivated by this, we propose effective neural network architectures for the forward and inverse maps based on convolution layers, with weights learned from training datasets. Numerical results demonstrate the efficiency of the proposed neural networks.

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“…Physical knowledge and its mathematical properties can also be exploited to design desirable architecture of NNs. In [31], the NN still provides a map between the scatterers and the scattered field, but it introduces a novel switching layer with sparse connections. The new NN architecture, named the SwitchNet, uses far fewer parameters and facilitates the training process.…”

Section: Physics-assisted Learning Approachmentioning

confidence: 99%

“…The paper carefully analyzes the inherent low-rank structure of the scattering problems, which motivates the introduction of a novel switching layer with sparse connections. It is pointed in [31] that if a NN still provides a map between the scatterers and the scattered field, then a typical CNN with local connections is usually inapplicable since a scatterer has a global impact on the scattered wave field.…”

Section: Physics-assisted Learning Approachmentioning

confidence: 99%

A Review of Deep Learning Approaches for Inverse Scattering Problems (Invited Review)

Chen¹,

Wei²,

Li³

et al. 2020

PIER

216

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In recent years, deep learning (DL) is becoming an increasingly important tool for solving inverse scattering problems (ISPs). This paper reviews methods, promises, and pitfalls of deep learning as applied to ISPs. More specifically, we review several state-of-the-art methods of solving ISPs with DL, and we also offer some insights on how to combine neural networks with the knowledge of the underlying physics as well as traditional non-learning techniques. Despite the successes, DL also has its own challenges and limitations in solving ISPs. These fundamental questions are discussed, and possible suitable future research directions and countermeasures will be suggested.

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SwitchNet: A Neural Network Model for Forward and Inverse Scattering Problems

Cited by 111 publications

References 32 publications

Artificial neural networks for nonlinear pulse shaping in optical fibers

Artificial neural networks for nonlinear pulse shaping in optical fibers

Solving electrical impedance tomography with deep learning

A Review of Deep Learning Approaches for Inverse Scattering Problems (Invited Review)

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