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Uncertainty Estimation with Deep Learning for Rainfall–Runoff Modelling

Daniel Klotz, Frederik Kratzert, Martin Gauch, Alden Keefe Sampson, J. Brandstetter, Günter Klambauer, Sepp Hochreiter, Grey Nearing

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Abstract

Abstract. Deep Learning is becoming an increasingly important way to produce accurate hydrological predictions across a wide range of spatial and temporal scales. Uncertainty estimations are critical for actionable hydrological forecasting, and while standardized community benchmarks are becoming an increasingly important part of hydrological model development and research, similar tools for benchmarking uncertainty estimation are lacking. This contributions demonstrates that accurate uncertainty predictions can be obtained with Deep Learning. We establish an uncertainty estimation benchmarking procedure and present four Deep Learning baselines. Three baselines are based on Mixture Density Networks and one is based on Monte Carlo dropout. The results indicate that these approaches constitute strong baselines, especially the former ones. Additionaly, we provide a post-hoc model analysis to put forward some qualitative understanding of the resulting models. This analysis extends the notion of performance and show that learn nuanced behaviors in different situations.

Topics & Concepts

BenchmarkingComputer scienceDeep learningRange (aeronautics)Dropout (neural networks)Machine learningEstimationArtificial intelligenceData scienceData miningEconomicsMaterials scienceMarketingManagementBusinessComposite materialHydrology and Watershed Management StudiesHydrological Forecasting Using AIFlood Risk Assessment and Management