2021
DOI: 10.3390/e23010095
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Deep Neural Network Model for Approximating Eigenmodes Localized by a Confining Potential

Abstract: We study eigenmode localization for a class of elliptic reaction-diffusion operators. As the prototype model problem we use a family of Schrödinger Hamiltonians parametrized by random potentials and study the associated effective confining potential. This problem is posed in the finite domain and we compute localized bounded states at the lower end of the spectrum. We present several deep network architectures that predict the localization of bounded states from a sample of a potential. For tackling higher dim… Show more

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Cited by 10 publications
(7 citation statements)
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“…In the contribution by Grubišić et al [8], "Deep Neural Network Model for Approximating Eigenmodes Localized by a Confining Potential," a class of physics-informed deep dense neural networks is used to learn the mapping from potential to ground eigenstate for the Schrödinger equation for several confining potentials. The authors present an approach that combines the expressivity of the set of neural network realizations with the standard error indicators.…”
Section: Contributions To Intelligence Augmentationmentioning
confidence: 99%
“…In the contribution by Grubišić et al [8], "Deep Neural Network Model for Approximating Eigenmodes Localized by a Confining Potential," a class of physics-informed deep dense neural networks is used to learn the mapping from potential to ground eigenstate for the Schrödinger equation for several confining potentials. The authors present an approach that combines the expressivity of the set of neural network realizations with the standard error indicators.…”
Section: Contributions To Intelligence Augmentationmentioning
confidence: 99%
“…They extend this model to a Bayesian framework to quantify both epistemic and aleatoric uncertainty. Finally, Grubišić et al [54] also used an encoder-decoder fully convolutional neural network.…”
Section: Convolutional Encoder-decoder Networkmentioning
confidence: 99%
“…VPINN Kharazmi et al (2019) is also used to solve Schrödinger Hamiltonians, i.e. an elliptic reaction-diffusion operator (Grubišić et al, 2021).…”
Section: Steady State Pdementioning
confidence: 99%
“…They extend this model to a Bayesian framework to quantify both epistemic and aleatoric uncertainty. Finally, Grubišić et al (2021) also used an encoder-decoder fully convolutional neural network.…”
Section: Convolutional Encoder-decoder Networkmentioning
confidence: 99%