Evaluation of spatial variability in snow water equivalent for a high mountain catchment

## Abstract Soil is a critical intermediary of water flux between precipitation and stream flow. Characterization of soil water content (θ, m^3^ m^−3^) may be especially difficult in mountainous, snow‐dominated catchments due to highly variable water inputs, topography, soils and vegetation. Howeve

## Abstract The USGS precipitation‐runoff modelling system (PRMS) hydrologic model was used to evaluate experimental, gridded, 1 km^2^ snow‐covered area (SCA) and snow water equivalent (SWE) products for two headwater basins within the Rio Grande (i.e. upper Rio Grande River basin) and Salt River (

We describe an objective method for evaluating the spatial distribution of water equivalents of the snow cover within a small catchment. Regression analysis is used to quantify the relationship between elevation, presence or absence of forest, and potential direct solar radiation as independent vari

Many methods developed for calibration and validation of physically based distributed hydrological models are time consuming and computationally intensive. Only a small set of input parameters can be optimized, and the optimization often results in unrealistic values. In this study we adopted a mult

An approach to model distributed snow water equivalence (SWE) that merges ®eld measurements of depth and density with remotely sensed snow-covered area (SCA) is described. In 1993, two teams conducted an intensive snow survey in the 92 . 8 km 2 Blackcap Basin of the Kings River. Snow depth was measu

We investigated the eect of increasing spatial and temporal resolutions on modelled distributions of snow water equivalence (SWE) and snowmelt in the Emerald Lake Watershed (ELW) of the Sierra Nevada of California, USA. We used a coupled remote sensing/distributed energy balance snowmelt model (SNOD