Quantification of predictive uncertainty in hydrological modelling by harnessing the wisdom of the crowd: A large-sample experiment at monthly timescale

Papacharalampous, Georgia; Tyralis, Hristos; Koutsoyiannis, Demetris; Montanari, Alberto

doi:10.1016/j.advwatres.2019.103470

Cited by 27 publications

(26 citation statements)

References 155 publications

(218 reference statements)

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“…Therefore, some concessions should be accepted, since there is no free lunch in modelling [64], so that one obtains a model that provides acceptable predictions and is interpretable simultaneously. For instance, one could combine multiple models and obtain more accurate points [65,66] or probabilistic [67,68] pre- To understand Figure 6, we note that attributes in the vertical axis are reported with regards to their type, i.e., topographic characteristics, climatic indices, land cover characteristics, soil characteristics and geological characteristics (from lower to upper). In general, topographic characteristics and climatic indices seem to be most important when predicting hydrological signatures.…”

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Explanation and Probabilistic Prediction of Hydrological Signatures with Statistical Boosting Algorithms

et al. 2021

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Hydrological signatures, i.e., statistical features of streamflow time series, are used to characterize the hydrology of a region. A relevant problem is the prediction of hydrological signatures in ungauged regions using the attributes obtained from remote sensing measurements at ungauged and gauged regions together with estimated hydrological signatures from gauged regions. The relevant framework is formulated as a regression problem, where the attributes are the predictor variables and the hydrological signatures are the dependent variables. Here we aim to provide probabilistic predictions of hydrological signatures using statistical boosting in a regression setting. We predict 12 hydrological signatures using 28 attributes in 667 basins in the contiguous US. We provide formal assessment of probabilistic predictions using quantile scores. We also exploit the statistical boosting properties with respect to the interpretability of derived models. It is shown that probabilistic predictions at quantile levels 2.5% and 97.5% using linear models as base learners exhibit better performance compared to more flexible boosting models that use both linear models and stumps (i.e., one-level decision trees). On the contrary, boosting models that use both linear models and stumps perform better than boosting with linear models when used for point predictions. Moreover, it is shown that climatic indices and topographic characteristics are the most important attributes for predicting hydrological signatures.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Explanation and Probabilistic Prediction of Hydrological Signatures with Statistical Boosting Algorithms

et al. 2021

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“…We are explicitly interested in probabilistic hydrological post-processing methodologies whose models are estimated sequentially in more than one stage (see also Section 2.1; hereafter referred to as "multi-stage probabilistic hydrological post-processing methodologies") and machine-learning quantile regression algorithms, since the former can accommodate the latter naturally and effectively. The effectiveness of this accommodation has already been proven, for example, with the large-scale results by Papacharalampous et al [45] and Tyralis et al [46] for the monthly and daily timescales, respectively. Aiming at combining the advantages from both the above-outlined "streams of thought" in predictive hydrological modelling, these studies and a few earlier ones (to the best of our knowledge, those mentioned in Table 1) have integrated process-based hydrological models and data-driven algorithmic approaches (spanning from conditional distribution modelling approaches to regression algorithms) within multi-stage probabilistic hydrological post-processing methodologies for predictive uncertainty quantification purposes.…”

Section: Introductionmentioning

confidence: 83%

“…Advancing the implementation of machine-learning regression algorithms by conducting large-sample (and in-depth) hydrological investigations has been gaining prominence recently (see, e.g., references [42][43][44][45][46]), perhaps following a more general tendency for embracing large-scale hydrological analyses and model evaluations (see, e.g., references [47][48][49][50][51]). The key significance of such studies in improving the modelling of hydrological phenomena, especially when the modelling is data-driven, has been emphasized by several experts in the field (see, e.g., references [16,[52][53][54][55]).…”

Section: Introductionmentioning

confidence: 99%

“…In the present study, we exploit a large dataset for advancing the use of machine-learning algorithms within broader methodological approaches for quantifying the predictive uncertainty in hydrology. The hydrological modelling and hydro-meteorological forecasting literatures include a large variety of such methodologies (see, e.g., references [45,46,[56][57][58][59][60][61][62][63][64][65][66][67][68][69]), reviewed in detail by Montanari [9] and Li et al [70]. Deterministic "process-based" hydrological models are usually and preferably a core ingredient of probabilistic approaches of this family.…”

Section: Introductionmentioning

confidence: 99%

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Probabilistic Hydrological Post-Processing at Scale: Why and How to Apply Machine-Learning Quantile Regression Algorithms

Papacharalampous

Tyralis

Langousis

et al. 2019

Water

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We conduct a large-scale benchmark experiment aiming to advance the use of machine-learning quantile regression algorithms for probabilistic hydrological post-processing “at scale” within operational contexts. The experiment is set up using 34-year-long daily time series of precipitation, temperature, evapotranspiration and streamflow for 511 catchments over the contiguous United States. Point hydrological predictions are obtained using the Génie Rural à 4 paramètres Journalier (GR4J) hydrological model and exploited as predictor variables within quantile regression settings. Six machine-learning quantile regression algorithms and their equal-weight combiner are applied to predict conditional quantiles of the hydrological model errors. The individual algorithms are quantile regression, generalized random forests for quantile regression, generalized random forests for quantile regression emulating quantile regression forests, gradient boosting machine, model-based boosting with linear models as base learners and quantile regression neural networks. The conditional quantiles of the hydrological model errors are transformed to conditional quantiles of daily streamflow, which are finally assessed using proper performance scores and benchmarking. The assessment concerns various levels of predictive quantiles and central prediction intervals, while it is made both independently of the flow magnitude and conditional upon this magnitude. Key aspects of the developed methodological framework are highlighted, and practical recommendations are formulated. In technical hydro-meteorological applications, the algorithms should be applied preferably in a way that maximizes the benefits and reduces the risks from their use. This can be achieved by (i) combining algorithms (e.g., by averaging their predictions) and (ii) integrating algorithms within systematic frameworks (i.e., by using the algorithms according to their identified skills), as our large-scale results point out.

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Evaluating Catchment Models as Multiple Working Hypotheses: on the Role of Error Metrics, Parameter Sampling, Model Structure, and Data Information Content

Peterson

Peel

Western

2020

Preprint

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Quantification of predictive uncertainty in hydrological modelling by harnessing the wisdom of the crowd: A large-sample experiment at monthly timescale

Cited by 27 publications

References 155 publications

Explanation and Probabilistic Prediction of Hydrological Signatures with Statistical Boosting Algorithms

Explanation and Probabilistic Prediction of Hydrological Signatures with Statistical Boosting Algorithms

Probabilistic Hydrological Post-Processing at Scale: Why and How to Apply Machine-Learning Quantile Regression Algorithms

Evaluating Catchment Models as Multiple Working Hypotheses: on the Role of Error Metrics, Parameter Sampling, Model Structure, and Data Information Content

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