Abstract
Snowmelt from mountain forests is critically important for water resources and hydropower generation. More than 75% of surface water supply originates as snowmelt in mountainous regions, such as the western U.S. Remote sensing has the potential to measure snowpack in these areas accurately. In this research, we combine light detection and ranging (lidar) from crewed aircraft (currently, the most reliable way of measuring snow depth in mountain forests) and structure from motion (SfM) remotely piloted aircraft systems (RPAS) for cost-effective multi-temporal monitoring of snowpack in mountain forests. In sparsely forested areas, both technologies give similar snow depth maps, with a comparable agreement with ground-based snow depth observations (RMSE ~10 cm). In densely forested areas, airborne lidar is better able to represent snow depth than RPAS-SfM (RMSE ~10 cm vs ~10–20 cm). In addition, we find the relationship between RPAS-SfM and previous lidar snow depth data can be used to estimate snow depth conditions outside of relatively small RPAS-SfM monitoring plots, with RMSE’s between these observed and estimated snow depths on the order of 10–15 cm for the larger lidar coverages. This suggests that when a single airborne lidar snow survey exists, RPAS-SfM may provide useful multi-temporal snow monitoring that can estimate basin-scale snowpack, at a much lower cost than multiple airborne lidar surveys. Doing so requires a pre-existing mid-winter or peak-snowpack airborne lidar snow survey, and subsequent well-designed paired SfM and field snow surveys that accurately capture substantial snow depth variability.
Highlights
Snowpack in mountain forests is a major source of water for reservoirs that provide water and hydropower for many urban and agricultural communities [1,2,3]
We show how remotely piloted aircraft systems (RPAS)-structure from motion (SfM) and airborne lidar can be used in a complementary fashion to attain regular snowpack monitoring data that can lead to seasonal large area snow depth and snow water equivalent (SWE) fields in complex forested environments
We show that RPAS-SfM monitoring of snowpack can be a useful tool to provide temporal snowpack monitoring
Summary
Snowpack in mountain forests is a major source of water for reservoirs that provide water and hydropower for many urban and agricultural communities [1,2,3]. Monitoring and assessing the snowpack response to environmental changes requires multi-scale and multi-sensor monitoring that takes advantage of field data in combination with multiple observing platforms (e.g., remotely piloted aircraft systems (RPAS), airplanes and satellites) and payloads (e.g., visible, multispectral and lidar sensors) [21,23,24]. These snow monitoring platforms and payloads all have advantages and disadvantages that relate to spatial and spectral resolutions, geolocation, extent, cloud cover, wind, reliability, timeliness, terrain accessibility, resources and training, and government regulations [25,26]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
