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High‐resolution snow depth prediction using Random Forest algorithm with topographic parameters: A case study in the Greiner watershed, Nunavut

Julien Meloche, Alexandre Langlois, Nick Rutter, Donald McLennan, Alain Royer, Paul Billecocq, Serguei Ponomarenko

2022Hydrological Processes45 citationsDOI

Abstract

Abstract Increased surface temperatures (0.7°C per decade) in the Arctic affects polar ecosystems by reducing the extent and duration of annual snow cover. Monitoring of these important ecosystems needs detailed information on snow cover properties at resolutions (<100 m) that influence ecological habitats and permafrost thaw. A machine learning method using topographic parameters with the Random Forest (RF) algorithm previously developed in alpine environments was applied over an arctic landscape for the first time. The topographic parameters used in the RF algorithm were Topographic Position Index (TPI) and up‐wind slope index ( S x ), which were estimated from the freely available Arctic DEM at 2 m resolution. Addition of an ecotype parameter (proxy for vegetation height) showed minimal predictive improvement. Using RF, snow depth distributions were predicted from topographic parameters with a root mean square error = 8 cm (23%) ( R 2 = 0.79) at 10 m resolution for an arctic watershed (1500 km 2 ) in western Nunavut, Canada.

Topics & Concepts

PermafrostArcticSnowWatershedEnvironmental sciencePhysical geographyHydrology (agriculture)GeologyRemote sensingGeomorphologyGeographyOceanographyMachine learningComputer scienceGeotechnical engineeringClimate change and permafrostCryospheric studies and observationsLandslides and related hazards
High‐resolution snow depth prediction using Random Forest algorithm with topographic parameters: A case study in the Greiner watershed, Nunavut | Litcius