Abstract

Forest cover is a crucial factor that influences the performance of optical satellite-based snow cover monitoring algorithms. However, evaluation of such algorithms in forested landscapes is rare due to lack of reliable in situ data in such regions. In this investigation, we assessed the performance of the operational snow detection (SCA) and fractional snow cover estimation (FSC) algorithms employed by the Copernicus Land Monitoring Service for High-Resolution Snow & Ice Monitoring (HRSI) with a combination of Sentinel-2 and Landsat-7/8 satellite scenes, lidar-based, and in situ datasets. These algorithms were evaluated over test sites located in the forested mountainous landscape of the Pyrenees in Spain and the Sierra Nevada in the USA. Over the Pyrenees site, the effectiveness of snow cover detection was evaluated with respect to a time-series of in situ snow depth measurements logged over test plots with different aspects, canopy cover, and solar irradiance. Over the Sierra Nevada site, the impact of ground vegetation was assessed over the under canopy fractional snow cover retrievals using airborne lidar-derived fractional vegetation cover information. The analyses over the Pyrenees indicated a good accuracy of snow detection with the exception of plots with either dense canopy cover or insufficient solar exposure (shaded forested slope), or both. The operational HRSI algorithm yielded similar performances (25–30% RMSE) as the computationally intensive spectral unmixing approach while retrieving the subcanopy ground FSC over the Sierra Nevada site. It was observed that a more accurate lidar-derived tree cover density map did not improve the subcanopy FSC retrievals.

Highlights

  • T ERRESTRIAL snow cover is a crucial component of the global hydrological cycle and strongly influences net radiation balance [1]

  • The degradation in performance can be cumulatively attributed to the obscuring effect of the canopy cover and consistently lower subcanopy snow depth (SD) observed over all the plots (Fig. 5), which possibly caused the corresponding decrease in the accuracy and κ score

  • We investigated the performance of normalized difference snow index (NDSI)-based snow cover area (SCA) and fractional snow cover estimation (FSC) algorithms with high-resolution Sentinel-2 and Landsat7/8 data in two forested landscapes (Pyrenees and Sierra Nevada)

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Summary

Introduction

T ERRESTRIAL snow cover is a crucial component of the global hydrological cycle and strongly influences net radiation balance [1]. Earth observation satellites have been employed in such regions for monitoring the state of the global snow cover as early as the 1960s [2]. Snow cover extent information has been employed for driving hydrological forecasting models for early planning and management of winter precipitation, which is later released during the spring melt phase [4], [5]. Monitoring of snow cover extent is important for road authorities or winter tourism planning. A user survey in the recent past indicated the need for operational snow cover extent products with low latency (less than 12 h from the time of satellite acquisition) and high spatial resolution (better than 50 m) [9]

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