2012
DOI: 10.5194/tc-6-1323-2012
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Simulating snow maps for Norway: description and statistical evaluation of the seNorge snow model

Abstract: Abstract. Daily maps of snow conditions have been produced in Norway with the seNorge snow model since 2004. The seNorge snow model operates with 1 × 1 km resolution, uses gridded observations of daily temperature and precipitation as its input forcing, and simulates, among others, snow water equivalent (SWE), snow depth (SD), and the snow bulk density (ρ). In this paper the set of equations contained in the seNorge model code is described and a thorough spatiotemporal statistical evaluation of the model perfo… Show more

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Cited by 86 publications
(87 citation statements)
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“…The seNorge snow model (Saloranta, 2012(Saloranta, , 2014(Saloranta, , 2016) is a temperature-index model which requires only data of air temperature and precipitation. In addition, the seNorge snow model includes a compaction module that can be used to assimilate and validate snow depth rather than snow cover only.…”
Section: Modified Senorge Modelmentioning
confidence: 99%
See 1 more Smart Citation
“…The seNorge snow model (Saloranta, 2012(Saloranta, , 2014(Saloranta, , 2016) is a temperature-index model which requires only data of air temperature and precipitation. In addition, the seNorge snow model includes a compaction module that can be used to assimilate and validate snow depth rather than snow cover only.…”
Section: Modified Senorge Modelmentioning
confidence: 99%
“…The aim of this study is to estimate SWE and snowmelt runoff in a Himalayan catchment by assimilating remotely sensed snow cover and in situ snow depth observations into a modified version of the seNorge snow model (Saloranta, 2012(Saloranta, , 2014(Saloranta, , 2016. Climate sensitivity tests are subsequently performed to investigate the change of SWE and snowmelt runoff as result of changing air temperature and precipitation.…”
Section: Introductionmentioning
confidence: 99%
“…In the south-western region, however, DDD_LN performs better than DDD_G, which underestimates SCA. This region is characterized by a very rugged topography, which may influence both the estimates of SCA derived from the MODIS satellite and the quality of the meteorological grid, as very few meteorological observations are located at high altitudes (Dyrrdal et al, 2012;Saloranta, 2012). Further investigations relating the errors in estimating SCA to other CCs, such as catchment gradients, may explain the difference in results between DDD_LN and DDD_G.…”
Section: Discussionmentioning
confidence: 97%
“…This meteorological grid is denoted V1. Recently, a new, improved meteorological grid was developed, denoted V2 (Lussana et al 2014a, b), which reduced much of the positive bias in precipitation characteristic of V1 (see Saloranta, 2012). The new meteorological grid (V2) in DDD gives reasonable simulated values of runoff without the need for a calibrated correction of the amount of precipitation (θ Pc ; see Table 1 for parameters of the DDD model).…”
Section: Test Of Sd_g In Dddmentioning
confidence: 99%
“…Daily updated maps of snow conditions have been produced for Norway since 2004 by using the seNorge snow model (www.seNorge.no; Tveito et al, 2002;Engeset et al, 2004;Saloranta, 2012Saloranta, , 2014aSaloranta, , b, 2016 and the seNorge conventional climatological datasets as model forcing data. The simulated snow maps are used among others by the avalanche and flood forecasting services, hydropower energy situation analysis, as well as the general public.…”
Section: Impact On the Senorge Snow Model Simulationsmentioning
confidence: 99%