An evaluation of terrain‐based downscaling of fractional snow covered area data sets based on LiDAR‐derived snow data and orthoimagery

Cristea, Nicoleta; Breckheimer, Ian; Raleigh, M. S.; HilleRisLambers, Janneke; Lundquist, Jessica D.

doi:10.1002/2017wr020799

Cited by 36 publications

(36 citation statements)

References 84 publications

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“…The goal of the present study was to assess specifically the added-value of accounting for topography-driven radiative effects (topographical shadowing), which the distributed approach allows, in contrast to the semi-distributed approach. Further studies will explore in more detail how more sophisticated model approaches could further improve the performance of distributed simulations, which is deliberately beyond the scope of the present study [31,80,81].…”

Section: Overview Of Safran-crocus Performancementioning

confidence: 99%

Multi-Criteria Evaluation of Snowpack Simulations in Complex Alpine Terrain Using Satellite and In Situ Observations

et al. 2018

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Abstract:This work presents an extensive evaluation of the Crocus snowpack model over a rugged and highly glacierized mountain catchment (Arve valley, Western Alps, France) from 1989 to 2015. The simulations were compared and evaluated using in-situ point snow depth measurements, in-situ seasonal and annual glacier surface mass balance, snow covered area evolution based on optical satellite imagery at 250 m resolution (MODIS sensor), and the annual equilibrium-line altitude of glaciers, derived from satellite images (Landsat, SPOT, and ASTER). The snowpack simulations were obtained using the Crocus snowpack model driven by the same, originally semi-distributed, meteorological forcing (SAFRAN) reanalysis using the native semi-distributed configuration, but also a fully distributed configuration. The semi-distributed approach addresses land surface simulations for discrete topographic classes characterized by elevation range, aspect, and slope. The distributed approach operates on a 250-m grid, enabling inclusion of terrain shadowing effects, based on the same original meteorological dataset. Despite the fact that the two simulations use the same snowpack model, being potentially subjected to same potential deviation from the parametrization of certain physical processes, the results showed that both approaches accurately reproduced the snowpack distribution over the study period. Slightly (although statistically significantly) better results were obtained by using the distributed approach. The evaluation of the snow cover area with MODIS sensor has shown, on average, a reduction of the Root Mean Squared Error (RMSE) from 15.2% with the semi-distributed approach to 12.6% with the distributed one. Similarly, surface glacier mass balance RMSE decreased from 1.475 m of water equivalent (W.E.) for the semi-distributed simulation to 1.375 m W.E. for the distribution. The improvement, observed with a much higher computational time, does not justify the recommendation of this approach for all applications; however, for simulations that require a precise representation of snowpack distribution, the distributed approach is suggested.

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Section: Overview Of Safran-crocus Performancementioning

confidence: 99%

Multi-Criteria Evaluation of Snowpack Simulations in Complex Alpine Terrain Using Satellite and In Situ Observations

et al. 2018

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“…Evaluating the credibility of simulated climate and snow dynamics through a decision‐relevant lens and attributing sources of bias across multiple processes, scales of analysis, and models poses a significant challenge to the scientific community. The WUS is a well‐studied region with a vast literature in observed snowpack dynamics (Bales et al, ; Cristea et al, ; Henn et al, ; Kapnick & Hall, ; Margulis, Cortés, Girotto, & Durand, ; Mote, ; Mote et al, ; Painter et al, ; Serreze et al, ; Trujillo & Molotch, ) and modeling approaches (Ashfaq et al, , ; Giorgi et al, ; Huang et al, ; Liu et al, ; McCrary et al, ; Minder et al, ; Naz et al, ; Pierce & Cayan, ; Rasmussen et al, ; Rhoades et al, , , ; Sun et al, ; Wu et al, ) dating back decades (Anderson, ; Palmer, ). Consequently, a staggering growth in publicly available observational and regional climate data sets have been produced, yet a lag in expert direction regarding their applicability for regional planning (Hall, ).…”

Section: Introductionmentioning

confidence: 99%

Assessing Mountains as Natural Reservoirs With a Multimetric Framework

2018

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Anthropogenic climate change will continue to diminish the unique role that mountains perform as natural reservoirs and alter long‐held assumptions of water management. Climate models are important tools to help constrain uncertainty and understand processes that shape this decline. To ensure that climate model estimates provide stakeholder relevant information, the formulation of multimetric model evaluation frameworks informed by stakeholder interactions are critical. In this study, we present one such multimetric framework to evaluate snowpack data sets in the California Sierra Nevada: the snow water equivalent (SWE) triangle. SWE triangle metrics help to describe snowpack characteristics associated with total water volume buildup, peak water availability, and the rate of water release. This approach highlights compensating errors that would not be reflected in conventional large‐scale spatiotemporal analysis. To test our multimetric evaluation framework, we evaluate several publicly available snow products including the Sierra Nevada Snow Reanalysis, Livneh (L15), and the North American Land Data Assimilation System version 2 data sets. We then evaluate regional climate model skill within the North American Coordinated Regional Climate Downscaling Experiment. All data sets analyzed show variation across the various SWE triangle metrics, even within observationally constrained snow products. This spread was especially shown in spring season melt rates. Melt rate biases were prevalent throughout most regional climate model simulations, regardless of snow accumulation dynamics, and will need to be addressed to improve their utility for water stakeholders.

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“…However, most of the works which studied the snow covered area over large domains use a threshold for considering a pixel as snow covered or not , regardless the spatial scale(e.g. Cristea et al, 2017 at the very high resolution of 3 m, Gascoin et al, 2015 at the resolution of 500 m). Furthermore, we demonstrate in our paper that the strict validity of this relationship is secondary in the context of the evaluations performed in this paper.…”

Section: Figure 1 Caption (Complete): Glacier Winter Surface Massmentioning

confidence: 99%

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An evaluation of terrain‐based downscaling of fractional snow covered area data sets based on LiDAR‐derived snow data and orthoimagery

Cited by 36 publications

References 84 publications

Multi-Criteria Evaluation of Snowpack Simulations in Complex Alpine Terrain Using Satellite and In Situ Observations

Multi-Criteria Evaluation of Snowpack Simulations in Complex Alpine Terrain Using Satellite and In Situ Observations

Assessing Mountains as Natural Reservoirs With a Multimetric Framework

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