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10 results on '"Bridgman, Wyatt"'

1. Detecting Outbreaks Using a Latent Field: Part II -- Scalable Estimation

Author

Bridgman, Wyatt, Safta, Cosmin, and Ray, Jaideep

Subjects
Statistics - Applications
Abstract

In this paper, we explore whether the infection-rate of a disease can serve as a robust monitoring variable in epidemiological surveillance algorithms. The infection-rate is dependent on population mixing patterns that do not vary erratically day-to-day; in contrast, daily case-counts used in contemporary surveillance algorithms are corrupted by reporting errors. The technical challenge lies in estimating the latent infection-rate from case-counts. Here we devise a Bayesian method to estimate the infection-rate across multiple adjoining areal units, and then use it, via an anomaly detector, to discern a change in epidemiological dynamics. We extend an existing model for estimating the infection-rate in an areal unit by incorporating a Markov random field model, so that we may estimate infection-rates across multiple areal units, while preserving spatial correlations observed in the epidemiological dynamics. To carry out the high-dimensional Bayesian inverse problem, we develop an implementation of mean-field variational inference specific to the infection model and integrate it with the random field model to incorporate correlations across counties. The method is tested on estimating the COVID-19 infection-rates across all 33 counties in New Mexico using data from the summer of 2020, and then employing them to detect the arrival of the Fall 2020 COVID-19 wave. We perform the detection using a temporal algorithm that is applied county-by-county. We also show how the infection-rate field can be used to cluster counties with similar epidemiological dynamics.

Published
2024

2. Detecting Outbreaks Using a Latent Field: Part I -- Spatial Modeling

Author

Safta, Cosmin, Bridgman, Wyatt, and Ray, Jaideep

Subjects
Statistics - Applications
Abstract

In this paper, we develop a method to estimate the infection-rate of a disease, over a region, as a field that varies in space and time. To do so, we use time-series of case-counts of symptomatic patients as observed in the areal units that comprise the region. We also extend an epidemiological model, initially developed to represent the temporal dynamics in a single areal unit, to encompass multiple areal units. This is done using a (parameterized) Gaussian random field, whose structure is modeled using the dynamics in the case-counts, and which serves as a spatial prior, in the estimation process. The estimation is performed using an adaptive Markov chain Monte Carlo method, using COVID-19 case-count data collected from three adjacent counties in New Mexico, USA. We find that we can estimate both the temporal and spatial variation of the infection with sufficient accuracy to be useful in forecasting. Further, the ability to "borrow" information from neighboring areal units allows us to regularize the estimation in areal units with high variance ("poor quality") data. The ability to forecast allows us to check whether the estimated infection-rate can be used to detect a change in the epidemiological dynamics e.g., the arrival of a new wave of infection, such as the fall wave of 2020 which arrived in New Mexico in mid-September 2020. We fashion a simple anomaly detector, conditioned on the estimated infection-rate and find that it performs better than a conventional surveillance algorithm that uses case-counts (and not the infection-rate) to detect the arrival of the same wave., Comment: 26 pages

Published
2024

3. Enhancing Polynomial Chaos Expansion Based Surrogate Modeling using a Novel Probabilistic Transfer Learning Strategy

Author

Bridgman, Wyatt, Balakrishnan, Uma, Jones, Reese, Chen, Jiefu, Wu, Xuqing, Safta, Cosmin, Huang, Yueqin, and Khalil, Mohammad

Subjects
Statistics - Machine Learning, Computer Science - Machine Learning
Abstract

In the field of surrogate modeling, polynomial chaos expansion (PCE) allows practitioners to construct inexpensive yet accurate surrogates to be used in place of the expensive forward model simulations. For black-box simulations, non-intrusive PCE allows the construction of these surrogates using a set of simulation response evaluations. In this context, the PCE coefficients can be obtained using linear regression, which is also known as point collocation or stochastic response surfaces. Regression exhibits better scalability and can handle noisy function evaluations in contrast to other non-intrusive approaches, such as projection. However, since over-sampling is generally advisable for the linear regression approach, the simulation requirements become prohibitive for expensive forward models. We propose to leverage transfer learning whereby knowledge gained through similar PCE surrogate construction tasks (source domains) is transferred to a new surrogate-construction task (target domain) which has a limited number of forward model simulations (training data). The proposed transfer learning strategy determines how much, if any, information to transfer using new techniques inspired by Bayesian modeling and data assimilation. The strategy is scrutinized using numerical investigations and applied to an engineering problem from the oil and gas industry.

Published
2023

4. Robust scalable initialization for Bayesian variational inference with multi-modal Laplace approximations

Author

Bridgman, Wyatt, Jones, Reese, and Khalil, Mohammad

Subjects
Statistics - Methodology, Computer Science - Computational Engineering, Finance, and Science, Statistics - Computation, Statistics - Machine Learning
Abstract

For predictive modeling relying on Bayesian inversion, fully independent, or ``mean-field'', Gaussian distributions are often used as approximate probability density functions in variational inference since the number of variational parameters is twice the number of unknown model parameters. The resulting diagonal covariance structure coupled with unimodal behavior can be too restrictive when dealing with highly non-Gaussian behavior, including multimodality. High-fidelity surrogate posteriors in the form of Gaussian mixtures can capture any distribution to an arbitrary degree of accuracy while maintaining some analytical tractability. Variational inference with Gaussian mixtures with full-covariance structures suffers from a quadratic growth in variational parameters with the number of model parameters. Coupled with the existence of multiple local minima due to nonconvex trends in the loss functions often associated with variational inference, these challenges motivate the need for robust initialization procedures to improve the performance and scalability of variational inference with mixture models. In this work, we propose a method for constructing an initial Gaussian mixture model approximation that can be used to warm-start the iterative solvers for variational inference. The procedure begins with an optimization stage in model parameter space in which local gradient-based optimization, globalized through multistart, is used to determine a set of local maxima, which we take to approximate the mixture component centers. Around each mode, a local Gaussian approximation is constructed via the Laplace method. Finally, the mixture weights are determined through constrained least squares regression. Robustness and scalability are demonstrated using synthetic tests. The methodology is applied to an inversion problem in structural dynamics involving unknown viscous damping coefficients.

Published
2023

5. A heteroencoder architecture for prediction of failure locations in porous metals using variational inference

Author

Bridgman, Wyatt, Zhang, Xiaoxuan, Teichert, Greg, Khalil, Mohammad, Garikipati, Krishna, and Jones, Reese

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science, Computer Science - Machine Learning
Abstract

In this work we employ an encoder-decoder convolutional neural network to predict the failure locations of porous metal tension specimens based only on their initial porosities. The process we model is complex, with a progression from initial void nucleation, to saturation, and ultimately failure. The objective of predicting failure locations presents an extreme case of class imbalance since most of the material in the specimens do not fail. In response to this challenge, we develop and demonstrate the effectiveness of data- and loss-based regularization methods. Since there is considerable sensitivity of the failure location to the particular configuration of voids, we also use variational inference to provide uncertainties for the neural network predictions. We connect the deterministic and Bayesian convolutional neural networks at a theoretical level to explain how variational inference regularizes the training and predictions. We demonstrate that the resulting predicted variances are effective in ranking the locations that are most likely to fail in any given specimen., Comment: 40 pages, 12 figures

Published
2022
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