Land cover classification and mapping of a polar desert in the Canadian Arctic Archipelago

The use of remote sensing for developing land cover maps in the Arctic has grown considerably in the last two decades, especially for monitoring the effects of climate change. The main challenge is to link information extracted from satellite imagery to ground covers due to the fine-scale spatial he...

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Bibliographic Details
Main Authors: Desjardins, Émilie, Lai, Sandra, Houle, Laurent, Caron, Alain, Thériault, Véronique, Tam, Andrew, Vézina, François, Berteaux, Dominique
Format: Software
Language:unknown
Published: 2023
Subjects:
Remote sensing
Satellite image
predictor selection
majority voting
ensemble model
Snow
vegetation
water
Arctic
Nunavut
Ellesmere Island
Canadian Arctic Archipelago
Canada
Canadian Forces Station Alert
Arctic Archipelago
Climate change
polar desert
Online Access:https://zenodo.org/record/7689322
https://doi.org/10.5281/zenodo.7689322
Description
Summary:The use of remote sensing for developing land cover maps in the Arctic has grown considerably in the last two decades, especially for monitoring the effects of climate change. The main challenge is to link information extracted from satellite imagery to ground covers due to the fine-scale spatial heterogeneity of Arctic ecosystems. There is currently no commonly accepted methodological scheme for high-latitude land cover mapping, but the use of remote sensing in Arctic ecosystem mapping would benefit from a coordinated sharing of lessons learned and best practices. Here, we aimed to produce a highly accurate land cover map of the surroundings of the Canadian Forces Station Alert, a polar desert on the northeastern tip of Ellesmere Island (Nunavut, Canada) by testing different predictors and classifiers. To account for the effect of the bare soil background and water limitations that are omnipresent at these latitudes, we included as predictors soil-adjusted vegetation indices and several hydrological predictors related to waterbodies and snowbanks. We compared the results obtained from an ensemble classifier based on a majority voting algorithm to eight commonly used classifiers. The distance to the nearest snowbank and soil-adjusted indices were the top predictors allowing the discrimination of land cover classes in our study area. The overall accuracy of the classifiers ranged between 75 and 88%, with the ensemble classifier also yielding a high accuracy (85%) and producing less bias than the individual classifiers. Some challenges remained, such as shadows created by boulders and snow covered by soil material. We provide recommendations for further improving classification methodology in the High Arctic, which is important for the monitoring of Arctic ecosystems exposed to ongoing polar amplification. The dataset includes a shapefile named reference.shp, which consists of a collection of files with a common filename prefix, stored in the same directory. The shapefile stores the location, shape (point in ...

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