Interpreting Deep Machine Learning for Streamflow Modeling Across Glacial, Nival, and Pluvial Regimes in Southwestern Canada

The interpretation of deep learning (DL) hydrological models is a key challenge in data-driven modeling of streamflow, as the DL models are often seen as “black box” models despite often outperforming process-based models in streamflow prediction. Here we explore the interpretability of a convolutio...

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Bibliographic Details
Published in:Frontiers in Water
Main Authors: Anderson, Sam, Radić, Valentina
Format: Article in Journal/Newspaper
Language:unknown
Published: Frontiers Media SA 2022
Subjects:
Water Science and Technology
glacier*
Online Access:http://dx.doi.org/10.3389/frwa.2022.934709
https://www.frontiersin.org/articles/10.3389/frwa.2022.934709/full
id crfrontiers:10.3389/frwa.2022.934709
record_format openpolar
spelling crfrontiers:10.3389/frwa.2022.934709 2024-04-28T08:20:18+00:00 Interpreting Deep Machine Learning for Streamflow Modeling Across Glacial, Nival, and Pluvial Regimes in Southwestern Canada Anderson, Sam Radić, Valentina 2022 http://dx.doi.org/10.3389/frwa.2022.934709 https://www.frontiersin.org/articles/10.3389/frwa.2022.934709/full unknown Frontiers Media SA https://creativecommons.org/licenses/by/4.0/ Frontiers in Water volume 4 ISSN 2624-9375 Water Science and Technology journal-article 2022 crfrontiers https://doi.org/10.3389/frwa.2022.934709 2024-04-08T06:45:06Z The interpretation of deep learning (DL) hydrological models is a key challenge in data-driven modeling of streamflow, as the DL models are often seen as “black box” models despite often outperforming process-based models in streamflow prediction. Here we explore the interpretability of a convolutional long short-term memory network (CNN-LSTM) previously trained to successfully predict streamflow at 226 stream gauge stations across southwestern Canada. To this end, we develop a set of sensitivity experiments to characterize how the CNN-LSTM model learns to map spatiotemporal fields of temperature and precipitation to streamflow across three streamflow regimes (glacial, nival, and pluvial) in the region, and we uncover key spatiotemporal patterns of model learning. The results reveal that the model has learned basic physically-consistent principles behind runoff generation for each streamflow regime, without being given any information other than temperature, precipitation, and streamflow data. In particular, during periods of dynamic streamflow, the model is more sensitive to perturbations within/nearby the basin where streamflow is being modeled, than to perturbations far away from the basins. The sensitivity of modeled streamflow to the magnitude and timing of the perturbations, as well as the sensitivity of day-to-day increases in streamflow to daily weather anomalies, are found to be specific for each streamflow regime. For example, during summer months in the glacial regime, modeled daily streamflow is increasingly generated by warm daily temperature anomalies in basins with a larger fraction of glacier coverage. This model's learning of “glacier runoff” contributions to streamflow, without any explicit information given about glacier coverage, is enabled by a set of cell states that learned to strongly map temperature to streamflow only in glacierized basins in summer. Our results demonstrate that the model's decision making, when mapping temperature and precipitation to streamflow, is consistent with a ... Article in Journal/Newspaper glacier* Frontiers (Publisher) Frontiers in Water 4
institution Open Polar
collection Frontiers (Publisher)
op_collection_id crfrontiers
language unknown
topic Water Science and Technology
spellingShingle Water Science and Technology
Anderson, Sam
Radić, Valentina
Interpreting Deep Machine Learning for Streamflow Modeling Across Glacial, Nival, and Pluvial Regimes in Southwestern Canada
topic_facet Water Science and Technology
description The interpretation of deep learning (DL) hydrological models is a key challenge in data-driven modeling of streamflow, as the DL models are often seen as “black box” models despite often outperforming process-based models in streamflow prediction. Here we explore the interpretability of a convolutional long short-term memory network (CNN-LSTM) previously trained to successfully predict streamflow at 226 stream gauge stations across southwestern Canada. To this end, we develop a set of sensitivity experiments to characterize how the CNN-LSTM model learns to map spatiotemporal fields of temperature and precipitation to streamflow across three streamflow regimes (glacial, nival, and pluvial) in the region, and we uncover key spatiotemporal patterns of model learning. The results reveal that the model has learned basic physically-consistent principles behind runoff generation for each streamflow regime, without being given any information other than temperature, precipitation, and streamflow data. In particular, during periods of dynamic streamflow, the model is more sensitive to perturbations within/nearby the basin where streamflow is being modeled, than to perturbations far away from the basins. The sensitivity of modeled streamflow to the magnitude and timing of the perturbations, as well as the sensitivity of day-to-day increases in streamflow to daily weather anomalies, are found to be specific for each streamflow regime. For example, during summer months in the glacial regime, modeled daily streamflow is increasingly generated by warm daily temperature anomalies in basins with a larger fraction of glacier coverage. This model's learning of “glacier runoff” contributions to streamflow, without any explicit information given about glacier coverage, is enabled by a set of cell states that learned to strongly map temperature to streamflow only in glacierized basins in summer. Our results demonstrate that the model's decision making, when mapping temperature and precipitation to streamflow, is consistent with a ...
format Article in Journal/Newspaper
author Anderson, Sam
Radić, Valentina
author_facet Anderson, Sam
Radić, Valentina
author_sort Anderson, Sam
title Interpreting Deep Machine Learning for Streamflow Modeling Across Glacial, Nival, and Pluvial Regimes in Southwestern Canada
title_short Interpreting Deep Machine Learning for Streamflow Modeling Across Glacial, Nival, and Pluvial Regimes in Southwestern Canada
title_full Interpreting Deep Machine Learning for Streamflow Modeling Across Glacial, Nival, and Pluvial Regimes in Southwestern Canada
title_fullStr Interpreting Deep Machine Learning for Streamflow Modeling Across Glacial, Nival, and Pluvial Regimes in Southwestern Canada
title_full_unstemmed Interpreting Deep Machine Learning for Streamflow Modeling Across Glacial, Nival, and Pluvial Regimes in Southwestern Canada
title_sort interpreting deep machine learning for streamflow modeling across glacial, nival, and pluvial regimes in southwestern canada
publisher Frontiers Media SA
publishDate 2022
url http://dx.doi.org/10.3389/frwa.2022.934709
https://www.frontiersin.org/articles/10.3389/frwa.2022.934709/full
genre glacier*
genre_facet glacier*
op_source Frontiers in Water
volume 4
ISSN 2624-9375
op_rights https://creativecommons.org/licenses/by/4.0/
op_doi https://doi.org/10.3389/frwa.2022.934709
container_title Frontiers in Water
container_volume 4
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