Statistical processing of forecasts for hydrological ensemble prediction: a comparative study of different bias correction strategies

Zalachori, I.; Ramos, Maria‐Helena; Garçon, Rémy; Mathevet, Thibault; Gailhard, Joël

doi:10.5194/asr-8-135-2012

Cited by 67 publications

(55 citation statements)

References 24 publications

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“…In hydrologic ensemble prediction systems, post-processing has become more and more popular in the last decade, particularly for medium-range ensemble forecasting (e.g. Weerts et al, 2011;Zalachori et al, 2012;Verkade et al, 2013;Madadgar et al, 2014;Roulin and Vannitsem, 2015). In seasonal forecasting, two popular bias correction methods are linear scaling and distribution mapping (Yuan et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Bias correcting precipitation forecasts to improve the skill of seasonal streamflow forecasts

Crochemore

Ramos²,

Pappenberger

2016

Hydrol. Earth Syst. Sci.

193

167

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Abstract. Meteorological centres make sustained efforts to provide seasonal forecasts that are increasingly skilful, which has the potential to benefit streamflow forecasting. Seasonal streamflow forecasts can help to take anticipatory measures for a range of applications, such as water supply or hydropower reservoir operation and drought risk management. This study assesses the skill of seasonal precipitation and streamflow forecasts in France to provide insights into the way bias correcting precipitation forecasts can improve the skill of streamflow forecasts at extended lead times. We apply eight variants of bias correction approaches to the precipitation forecasts prior to generating the streamflow forecasts. The approaches are based on the linear scaling and the distribution mapping methods. A daily hydrological model is applied at the catchment scale to transform precipitation into streamflow. We then evaluate the skill of raw (without bias correction) and bias-corrected precipitation and streamflow ensemble forecasts in 16 catchments in France. The skill of the ensemble forecasts is assessed in reliability, sharpness, accuracy and overall performance. A reference prediction system, based on historical observed precipitation and catchment initial conditions at the time of forecast (i.e. ESP method) is used as benchmark in the computation of the skill. The results show that, in most catchments, raw seasonal precipitation and streamflow forecasts are often more skilful than the conventional ESP method in terms of sharpness. However, they are not significantly better in terms of reliability. Forecast skill is generally improved when applying bias correction. Two bias correction methods show the best performance for the studied catchments, each method being more successful in improving specific attributes of the forecasts: the simple linear scaling of monthly values contributes mainly to increasing forecast sharpness and accuracy, while the empirical distribution mapping of daily values is successful in improving forecast reliability.

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Section: Introductionmentioning

confidence: 99%

Bias correcting precipitation forecasts to improve the skill of seasonal streamflow forecasts

Crochemore

Ramos²,

Pappenberger

2016

Hydrol. Earth Syst. Sci.

193

167

View full text Add to dashboard Cite

show abstract

“…Our results confirm the findings of Wetterhall et al [39], who investigated the bias-correcting ECMWF System 4 seasonal precipitation forecast with the quantile method to improve the skill of forecasts. Zalachori et al [26] also demonstrated that applying a bias correction method for streamflow forecasts caused significant improvements in forecast reliability. Scatterplots of four deterministic scores, the Nash-Sutcliffe efficiency (NSE), the relative mean error (RME), the coefficient of variation of the root mean squared error (CV) and the correlation coefficient (CC) for different lead times.…”

Section: Forecast Accuracymentioning

confidence: 99%

Section: Forecast Accuracymentioning

confidence: 99%

Comparison of Precipitation and Streamflow Correcting for Ensemble Streamflow Forecasts

Jiang

Lei

et al. 2018

Water

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Meteorological centers constantly make efforts to provide more skillful seasonal climate forecast, which has the potential to improve streamflow forecasts. A common approach is to bias-correct the general circulation model (GCM) forecasts prior to generating the streamflow forecasts. Less attention has been paid to the issue of bias-corrected streamflow forecasts that were generated by GCM forecasts. This study compares the effect of bias-corrected GCM forecasts and bias-corrected streamflow outputs on the improvement of streamflow forecast efficiency. Based on the Upper Hanjiang River Basin (UHRB), the authors compare three forecasting scenarios: original forecasts, bias-corrected precipitation forecasts and bias-corrected streamflow forecasts. We apply the quantile mapping method to bias-correct precipitation forecasts and the linear scaling method to bias-correct the original streamflow forecasts. A semi-distributed hydrological model, namely the Tsinghua Representative Elementary Watershed (THREW) model, is employed to transform precipitation into streamflow. The effects of bias-corrected precipitation and bias-corrected streamflow are assessed in terms of accuracy, reliability, sharpness and overall performance. The results show that both bias-corrected precipitation and bias-corrected streamflow can considerably increase the overall forecast skill in comparison to the original streamflow forecasts. Bias-corrected precipitation contributes mainly to improving the forecast reliability and sharpness, while bias-corrected streamflow is successful in increasing the forecast accuracy and overall performance of the ensemble forecasts.

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“…MORDOR is a conceptual lumped model developed in the early 1990s at EDF (Garçon, 1996), where it is used in operational hydrology in tasks as diverse as water resources forecasting, hydrological analysis, flood forecasting, low-flow forecasting, flood frequency estimation, and design of water regulation structures (see e.g., Mathevet et al, 2009;Bourqui et al, 2011;Zalachori et al, 2012;Paquet and Lawrence, 2013;Nicolle et al, 2014). The model represents the different components of the hydrological cycle through four reservoirs: superficial storage (contributes to actual evapotranspiration and direct runoff, and simulates soil moisture), evaporation matic stations for the mean elevation was only 5.4°C, with mean summer and winter temperatures of 14.5°C and -3.9°C, respectively.…”

Section: Hydrological Modellingmentioning

confidence: 99%

An Application of a Stochastic Semi-Continuous Simulation Method for Flood Frequency Analysis: A Case Study in Slovakia

Valent

Paquet

2017

Slovak Journal of Civil Engineering

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Statistical processing of forecasts for hydrological ensemble prediction: a comparative study of different bias correction strategies

Cited by 67 publications

References 24 publications

Bias correcting precipitation forecasts to improve the skill of seasonal streamflow forecasts

Bias correcting precipitation forecasts to improve the skill of seasonal streamflow forecasts

Comparison of Precipitation and Streamflow Correcting for Ensemble Streamflow Forecasts

An Application of a Stochastic Semi-Continuous Simulation Method for Flood Frequency Analysis: A Case Study in Slovakia

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