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Multi-fidelity Bayesian neural networks: Algorithms and applications

Journal Article · · Journal of Computational Physics
 [1];  [2];  [3]
  1. Brown Univ., Providence, RI (United States); Brown University
  2. Univ. of Pittsburgh, PA (United States)
  3. Brown Univ., Providence, RI (United States)
+ Show Author Affiliations

Here we propose a new class of Bayesian neural networks (BNNs) that can be trained using noisy data of variable fidelity, and we apply them to learn function approximations as well as to solve inverse problems based on partial differential equations (PDEs). These multi-fidelity BNNs consist of three neural networks: The first is a fully connected neural network, which is trained following the maximum a posteriori probability (MAP) method to fit the low-fidelity data; the second is a Bayesian neural network employed to capture the cross-correlation with uncertainty quantification between the low- and high-fidelity data; and the last one is the physics-informed neural network, which encodes the physical laws described by PDEs. For the training of the last two neural networks, we first employ the mean-field variational inference (VI) to maximize the evidence lower bound (ELBO) to obtain informative prior distributions for the hyperparameters in the BNNs, and subsequently we use the Hamiltonian Monte Carlo (HMC) method to estimate accurately the posterior distributions for the corresponding hyperparameters. We demonstrate the accuracy of the present method using synthetic data as well as real measurements. Specifically, we first approximate a one- and four-dimensional function, and then infer the reaction rates in one- and two-dimensional diffusion-reaction systems. Moreover, we infer the sea surface temperature (SST) in the Massachusetts and Cape Cod Bays using satellite images and in-situ measurements. Taken together, our results demonstrate that the present method can capture both linear and nonlinear correlation between the low- and high-fidelity data adaptively, identify unknown parameters in PDEs, and quantify uncertainties in predictions, given a few scattered noisy high-fidelity data. Finally, we demonstrate that we can effectively and efficiently reduce the uncertainties and hence enhance the prediction accuracy with an active learning approach, using as examples a specific one-dimensional function approximation and an inverse PDE problem.

Research Organization:
Brown Univ., Providence, RI (United States)
Sponsoring Organization:
USDOE; US Air Force Office of Scientific Research (AFOSR); National Institutes of Health (NIH)
Grant/Contract Number:
SC0019453
OSTI ID:
2281996
Alternate ID(s):
OSTI ID: 1781852
OSTI ID: 23206073
Journal Information:
Journal of Computational Physics, Journal Name: Journal of Computational Physics Vol. 438; ISSN 0021-9991
Publisher:
ElsevierCopyright Statement
Country of Publication:
United States
Language:
English

References (18)

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Generalized ocean color inversion model for retrieving marine inherent optical properties journal January 2013
An Adaptive Surrogate Modeling Based on Deep Neural Networks for Large-Scale Bayesian Inverse Problems journal June 2020

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Related Subjects

97 MATHEMATICS AND COMPUTING
Hamiltonian Monte Carlo
active learning
nonlinear correlation
physics-informed neural networks
satellite data
uncertainty quantification