Rainfall–runoff modelling using Long Short-Term Memory (LSTM) networks
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Published:2018-11-22
Issue:11
Volume:22
Page:6005-6022
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ISSN:1607-7938
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Container-title:Hydrology and Earth System Sciences
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language:en
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Short-container-title:Hydrol. Earth Syst. Sci.
Author:
Kratzert FrederikORCID, Klotz DanielORCID, Brenner ClaireORCID, Schulz KarstenORCID, Herrnegger MathewORCID
Abstract
Abstract. Rainfall–runoff modelling is one of the key
challenges in the field of hydrology. Various approaches exist, ranging from
physically based over conceptual to fully data-driven models. In this paper,
we propose a novel data-driven approach, using the Long Short-Term Memory
(LSTM) network, a special type of recurrent neural network. The advantage of
the LSTM is its ability to learn long-term dependencies between the provided
input and output of the network, which are essential for modelling storage
effects in e.g. catchments with snow influence. We use 241 catchments of the
freely available CAMELS data set to test our approach and also compare the
results to the well-known Sacramento Soil Moisture Accounting Model (SAC-SMA)
coupled with the Snow-17 snow routine. We also show the potential of the LSTM
as a regional hydrological model in which one model predicts the discharge
for a variety of catchments. In our last experiment, we show the possibility
to transfer process understanding, learned at regional scale, to individual
catchments and thereby increasing model performance when compared to a LSTM
trained only on the data of single catchments. Using this approach, we were
able to achieve better model performance as the SAC-SMA + Snow-17, which
underlines the potential of the LSTM for hydrological modelling applications.
Publisher
Copernicus GmbH
Subject
General Earth and Planetary Sciences,General Engineering,General Environmental Science
Reference86 articles.
1. Abadi, M., Agarwal, A., Barham, P., Brevdo, E., Chen, Z., Citro, C., Corrado,
G. S., Davis, A., Dean, J., Devin, M., Ghemawat, S., Goodfellow, I., Harp,
A., Irving, G., Isard, M., Jia, Y., Jozefowicz, R., Kaiser, L., Kudlur, M.,
Levenberg, J., Mane, D., Monga, R., Moore, S., Murray, D., Olah, C.,
Schuster, M., Shlens, J., Steiner, B., Sutskever, I., Talwar, K., Tucker, P.,
Vanhoucke, V., Vasudevan, V., Viegas, F., Vinyals, O., Warden, P.,
Wattenberg, M., Wicke, M., Yu, Y., and Zheng, X.: TensorFlow: Large-Scale Machine Learning on Heterogeneous Systems, available at: https://www.tensorflow.org/ (last access: 21 November 2018), 2016. a 2. Abrahart, R. J., Anctil, F., Coulibaly, P., Dawson, C. W., Mount, N. J., See,
L. M., Shamseldin, A. Y., Solomatine, D. P., Toth, E., and Wilby, R. L.: Two
decades of anarchy? Emerging themes and outstanding challenges for neural
network river forecasting, Prog. Phys. Geog., 36, 480–513,
2012. a 3. Adams, T. E. and Pagaon, T. C. (Eds.): Flood Forecasting: A Global
Perspective, Academic Press, Boston, MA, USA, 2016. a 4. Addor, N., Newman, A. J., Mizukami, N., and Clark, M. P.: The CAMELS data
set: catchment attributes and meteorology for large-sample studies, Hydrol.
Earth Syst. Sci., 21, 5293–5313, https://doi.org/10.5194/hess-21-5293-2017,
2017a. a, b, c 5. Addor, N., Newman, A. J., Mizukami, N., and Clark, M. P.: Catchment
attributes for large-sample studies, UCAR/NCAR, Boulder, CO, USA,
https://doi.org/10.5065/D6G73C3Q, 2017b. a, b
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