Your search keyword '"Maxwell, Reed M."' showing total 9 results

1. Simulation-based inference for parameter estimation of complex watershed simulators.

Author

Hull, Robert, Leonarduzzi, Elena, De La Fuente, Luis, Viet Tran, Hoang, Bennett, Andrew, Melchior, Peter, Maxwell, Reed M., and Condon, Laura E.

Subjects

CONDITIONAL probability, THERMAL conductivity, PARAMETER estimation, HYDRAULIC conductivity, DEEP learning

Abstract

High-resolution, spatially distributed process-based (PB) simulators are widely employed in the study of complex catchment processes and their responses to a changing climate. However, calibrating these PB simulators using observed data remains a significant challenge due to several persistent issues, including the following: (1) intractability stemming from the computational demands and complex responses of simulators, which renders infeasible calculation of the conditional probability of parameters and data, and (2) uncertainty stemming from the choice of simplified representations of complex natural hydrologic processes. Here, we demonstrate how simulation-based inference (SBI) can help address both of these challenges with respect to parameter estimation. SBI uses a learned mapping between the parameter space and observed data to estimate parameters for the generation of calibrated simulations. To demonstrate the potential of SBI in hydrologic modeling, we conduct a set of synthetic experiments to infer two common physical parameters – Manning's coefficient and hydraulic conductivity – using a representation of a snowmelt-dominated catchment in Colorado, USA. We introduce novel deep-learning (DL) components to the SBI approach, including an "emulator" as a surrogate for the PB simulator to rapidly explore parameter responses. We also employ a density-based neural network to represent the joint probability of parameters and data without strong assumptions about its functional form. While addressing intractability, we also show that, if the simulator does not represent the system under study well enough, SBI can yield unreliable parameter estimates. Approaches to adopting the SBI framework for cases in which multiple simulator(s) may be adequate are introduced using a performance-weighting approach. The synthetic experiments presented here test the performance of SBI, using the relationship between the surrogate and PB simulators as a proxy for the real case. [ABSTRACT FROM AUTHOR]

Published

2024

2. Spatio‐Temporal Machine Learning for Regional to Continental Scale Terrestrial Hydrology

Author

Bennett, Andrew, primary, Tran, Hoang, additional, De la Fuente, Luis, additional, Triplett, Amanda, additional, Ma, Yueling, additional, Melchior, Peter, additional, Maxwell, Reed M., additional, and Condon, Laura E., additional

Published

2024

3. A scalable and modular reservoir implementation for large scale integrated hydrologic simulations

Author

West, Benjamin D., primary, Maxwell, Reed M., additional, and Condon, Laura E., additional

Published

2024

4. Soil moisture downscaling based on physics-based hydrological simulations: a downscaling playground and a novel high-resolution downscaling product for the continental USA

Author

Leonarduzzi, Elena, primary and Maxwell, Reed M., additional

Published

2024

5. Simulation-Based Inference for Parameter Estimation of Complex Watershed Simulators

Author

Hull, Robert, primary, Leonarduzzi, Elena, additional, De La Fuente, Luis, additional, Viet Tran, Hoang, additional, Bennett, Andrew, additional, Melchior, Peter, additional, Maxwell, Reed M., additional, and Condon, Laura E., additional

Published

2024

6. Water Table Depth Estimates over the Contiguous United States Using a Random Forest Model.

Author

Ma, Yueling, Leonarduzzi, Elena, Defnet, Amy, Melchior, Peter, Condon, Laura E., and Maxwell, Reed M.

Subjects

WATER table, RANDOM forest algorithms, WATER depth, QUANTILE regression, STANDARD deviations, PEARSON correlation (Statistics)

Abstract

Water table depth (WTD) has a substantial impact on the connection between groundwater dynamics and land surface processes. Due to the scarcity of WTD observations, physically‐based groundwater models are growing in their ability to map WTD at large scales; however, they are still challenged to represent simulated WTD compared to well observations. In this study, we develop a purely data‐driven approach to estimating WTD at continental scale. We apply a random forest (RF) model to estimate WTD over most of the contiguous United States (CONUS) based on available WTD observations. The estimated WTD are in good agreement with well observations, with a Pearson correlation coefficient (r) of 0.96 (0.81 during testing), a Nash‐Sutcliffe efficiency (NSE) of 0.93 (0.65 during testing), and a root mean square error (RMSE) of 6.87 m (15.31 m during testing). The location of each grid cell is rated as the most important feature in estimating WTD over most of the CONUS, which might be a surrogate for spatial information. In addition, the uncertainty of the RF model is quantified using quantile regression forests. High uncertainties are generally associated with locations having a shallow WTD. Our study demonstrates that the RF model can produce reasonable WTD estimates over most of the CONUS, providing an alternative to physics‐based modeling for modeling large‐scale freshwater resources. Since the CONUS covers many different hydrologic regimes, the RF model trained for the CONUS may be transferrable to other regions with a similar hydrologic regime and limited observations. [ABSTRACT FROM AUTHOR]

Published

2024

7. Continental Scale Hydrostratigraphy: Basin‐Scale Testing of Alternative Data‐Driven Approaches.

Author

Tijerina‐Kreuzer, Danielle, Swilley, Jackson S., Tran, Hoang V., Zhang, Jun, West, Benjamin, Yang, Chen, Condon, Laura E., and Maxwell, Reed M.

Subjects

HYDROLOGIC cycle, HYDRAULIC conductivity, WATER table, WATER supply, HYDROLOGIC models, HYDROGEOLOGY

Abstract

Integrated hydrological modeling is an effective method for understanding interactions between parts of the hydrologic cycle, quantifying water resources, and furthering knowledge of hydrologic processes. However, these models are dependent on robust and accurate datasets that physically represent spatial characteristics as model inputs. This study evaluates multiple data‐driven approaches for estimating hydraulic conductivity and subsurface properties at the continental‐scale, constructed from existing subsurface dataset components. Each subsurface configuration represents upper (unconfined) hydrogeology, lower (confined) hydrogeology, and the presence of a vertical flow barrier. Configurations are tested in two large‐scale U.S. watersheds using an integrated model. Model results are compared to observed streamflow and steady state water table depth (WTD). We provide model results for a range of configurations and show that both WTD and surface water partitioning are important indicators of performance. We also show that geology data source, total subsurface depth, anisotropy, and inclusion of a vertical flow barrier are the most important considerations for subsurface configurations. While a range of configurations proved viable, we provide a recommended Selected National Configuration 1 km resolution subsurface dataset for use in distributed large‐and continental‐scale hydrologic modeling. [ABSTRACT FROM AUTHOR]

Published

2024

8. Continental Scale Hydrostratigraphy: Comparing Geologically Informed Data Products to Analytical Solutions.

Author

Swilley, Jackson S., Tijerina‐Kreuzer, Danielle, Tran, Hoang V., Zhang, Jun, Yang, Chen, Condon, Laura E., and Maxwell, Reed M.

Subjects

ANALYTICAL solutions, HYDRAULIC conductivity, HYDROLOGIC models, WATERSHEDS, STREAMFLOW

Abstract

This study synthesizes two different methods for estimating hydraulic conductivity (K) at large scales. We derive analytical approaches that estimate K and apply them to the contiguous United States. We then compare these analytical approaches to three‐dimensional, national gridded K data products and three transmissivity (T) data products developed from publicly available sources. We evaluate these data products using multiple approaches: comparing their statistics qualitatively and quantitatively and with hydrologic model simulations. Some of these datasets were used as inputs for an integrated hydrologic model of the Upper Colorado River Basin and the comparison of the results with observations was used to further evaluate the K data products. Simulated average daily streamflow was compared to daily flow data from 10 USGS stream gages in the domain, and annually averaged simulated groundwater depths are compared to observations from nearly 2000 monitoring wells. We find streamflow predictions from analytically informed simulations to be similar in relative bias and Spearman's rho to the geologically informed simulations. R‐squared values for groundwater depth predictions are close between the best performing analytically and geologically informed simulations at 0.68 and 0.70 respectively, with RMSE values under 10 m. We also show that the analytical approach derived by this study produces estimates of K that are similar in spatial distribution, standard deviation, mean value, and modeling performance to geologically‐informed estimates. The results of this work are used to inform a follow‐on study that tests additional data‐driven approaches in multiple basins within the contiguous United States. [ABSTRACT FROM AUTHOR]

Published

2024

9. Groundwater Modeling in a Changing World: MODFLOW‐and‐More 2022 Special Issue.

Author

Hill, Mary C., Maxwell, Reed M., and Tonkin, Matthew

Subjects

*GROUNDWATER, *PERFLUOROOCTANOIC acid, *GROUNDWATER quality, *QUANTUM computing, *HYDRAULIC conductivity

Abstract

The "MODFLOW-and-More" conference series, which began in 1998, recently held its 10th rendition at Princeton University in 2022. Despite the challenges posed by COVID-19, the conference was successful in bringing together scientists from various sectors to share research and development on groundwater modeling. The conference focused on the theme of a changing world and emphasized advances in computational methods and codes for evaluating groundwater data. Topics discussed included quantum computing, model inputs, groundwater quality concerns, hydrostratigraphy, and software advancements. The conference attendees expressed joy at being able to connect with others in person and engage with the authors. The next conference is scheduled for June 2024 at Princeton University. [Extracted from the article]

Published

2024