| Affiliation: | 1. Water Mission Area, U.S. Geological Survey, Pittsburgh, Pennsylvania, USA;2. Water Mission Area, U.S. Geological Survey, Madison, Wisconsin, USA;3. Water Mission Area, U.S. Geological Survey, Davis, California, USA;4. Water Mission Area, U.S. Geological Survey, State College, Pennsylvania, USA;5. Department of Computer Science, University of Pittsburgh, Pittsburgh, Pennsylvania, USA;6. Department of Computer Science and Engineering, University of Minnesota, Minneapolis, Minnesota, USA
Contribution: Supervision, Writing - review & editing |
| Abstract: | Deep learning (DL) models are increasingly used to make accurate hindcasts of management-relevant variables, but they are less commonly used in forecasting applications. Data assimilation (DA) can be used for forecasts to leverage real-time observations, where the difference between model predictions and observations today is used to adjust the model to make better predictions tomorrow. In this use case, we developed a process-guided DL and DA approach to make 7-day probabilistic forecasts of daily maximum water temperature in the Delaware River Basin in support of water management decisions. Our modeling system produced forecasts of daily maximum water temperature with an average root mean squared error (RMSE) from 1.1 to 1.4°C for 1-day-ahead and 1.4 to 1.9°C for 7-day-ahead forecasts across all sites. The DA algorithm marginally improved forecast performance when compared with forecasts produced using the process-guided DL model alone (0%–14% lower RMSE with the DA algorithm). Across all sites and lead times, 65%–82% of observations were within 90% forecast confidence intervals, which allowed managers to anticipate probability of exceedances of ecologically relevant thresholds and aid in decisions about releasing reservoir water downstream. The flexibility of DL models shows promise for forecasting other important environmental variables and aid in decision-making. |
