Abstract
Abstract. Snow is a critical contributor to Ontario's water-energy budget, with impacts on water resource management and flood forecasting. Snow water equivalent (SWE) describes the amount of water stored in a snowpack and is important in deriving estimates of snowmelt. However, only a limited number of sparsely distributed snow survey sites (n=383) exist throughout Ontario. The SNOw Data Assimilation System (SNODAS) is a daily, 1 km gridded SWE product that provides uniform spatial coverage across this region; however, we show here that SWE estimates from SNODAS display a strong positive mean bias of 50 % (16 mm SWE) when compared to in situ observations from 2011 to 2018. This study evaluates multiple statistical techniques of varying complexity, including simple subtraction, linear regression and machine learning methods to bias-correct SNODAS SWE estimates using absolute mean bias and RMSE as evaluation criteria. Results show that the random forest (RF) algorithm is most effective at reducing bias in SNODAS SWE, with an absolute mean bias of 0.2 mm and RMSE of 3.64 mm when compared with in situ observations. Other methods, such as mean bias subtraction and linear regression, are somewhat effective at bias reduction; however, only the RF method captures the nonlinearity in the bias and its interannual variability. Applying the RF model to the full spatio-temporal domain shows that the SWE bias is largest before 2015, during the spring melt period, north of 44.5∘ N and east (downwind) of the Great Lakes. As an independent validation, we also compare estimated snowmelt volumes with observed hydrographs and demonstrate that uncorrected SNODAS SWE is associated with unrealistically large volumes at the time of the spring freshet, while bias-corrected SWE values are highly consistent with observed discharge volumes.
Highlights
Snowmelt is an important factor for determining flood risk in many regions within both northern latitudes and higher elevation across Europe and North America (Berghuijs et al, 2016, 2019; Buttle et al, 2016)
Since the random forest (RF) is composed of an ensemble of decision trees (DT) models, it is not surprising that both methods perform when run with the same predictor set, with RF slightly outperforming a single DT, because the ensemble is more robust and reduces systematic model error caused by overfitting
We demonstrate the skill of a variety of bias-correction techniques and find that more sophisticated, nonlinear models offer enhancements in precision and accuracy to traditional statistical methods of bias correction
Summary
Snowmelt is an important factor for determining flood risk in many regions within both northern latitudes and higher elevation across Europe and North America (Berghuijs et al, 2016, 2019; Buttle et al, 2016). Predicting the impact of snowmelt on flooding is contingent on having reasonable spatially distributed estimates of the snowpack snow water equivalent (SWE). In Canada, large-scale snowmelt is often a key driver of flooding across much of the southern, and more populated, parts of the country (Buttle et al, 2016), and one can posit that an improved ability to characterize snowpack SWE would allow better characterization of flood risk, propagation, and duration. Regional flood danger was realized in a 2017 flood across southern Quebec which damaged over 4000 homes and led to approximately CAD 200 million worth of insured damages
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