Comparing Global Sentinel-2 Land Cover Maps for Regional Species Distribution Modeling

Zander S. Venter; Ruben E. Roos; Megan S. Nowell; Graciela M. Rusch; Gunnar M. Kvifte; Markus A. K. Sydenham

doi:10.3390/rs15071749

Remote Sensing (Mar 2023)

Comparing Global Sentinel-2 Land Cover Maps for Regional Species Distribution Modeling

Zander S. Venter,
Ruben E. Roos,
Megan S. Nowell,
Graciela M. Rusch,
Gunnar M. Kvifte,
Markus A. K. Sydenham

Affiliations

Zander S. Venter: Norwegian Institute for Nature Research, Sognsveien 68, N-0855 Oslo, Norway
Ruben E. Roos: Norwegian Institute for Nature Research, Sognsveien 68, N-0855 Oslo, Norway
Megan S. Nowell: Norwegian Institute for Nature Research, Sognsveien 68, N-0855 Oslo, Norway
Graciela M. Rusch: Norwegian Institute for Nature Research, Sognsveien 68, N-0855 Oslo, Norway
Gunnar M. Kvifte: Faculty of Biosciences and Aquaculture, Nord University, N-7729 Steinkjer, Norway
Markus A. K. Sydenham: Norwegian Institute for Nature Research, Sognsveien 68, N-0855 Oslo, Norway

DOI: https://doi.org/10.3390/rs15071749
Journal volume & issue: Vol. 15, no. 7
p. 1749

Abstract

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Mapping the spatial and temporal dynamics of species distributions is necessary for biodiversity conservation land-use planning decisions. Recent advances in remote sensing and machine learning have allowed for high-resolution species distribution modeling that can inform landscape-level decision-making. Here we compare the performance of three popular Sentinel-2 (10-m) land cover maps, including dynamic world (DW), European land cover (ELC10), and world cover (WC), in predicting wild bee species richness over southern Norway. The proportion of grassland habitat within 250 m (derived from the land cover maps), along with temperature and distance to sandy soils, were used as predictors in both Bayesian regularized neural network and random forest models. Models using grassland habitat from DW performed best (RMSE = 2.8 ± 0.03; average ± standard deviation across models), followed by ELC10 (RMSE = 2.85 ± 0.03) and WC (RMSE = 2.87 ± 0.02). All satellite-derived maps outperformed a manually mapped Norwegian land cover dataset called AR5 (RMSE = 3.02 ± 0.02). When validating the model predictions of bee species richness against citizen science data on solitary bee occurrences using generalized linear models, we found that ELC10 performed best (AIC = 2278 ± 4), followed by WC (AIC = 2367 ± 3), and DW (AIC = 2376 ± 3). While the differences in RMSE we observed between models were small, they may be significant when such models are used to prioritize grassland patches within a landscape for conservation subsidies or management policies. Partial dependencies in our models showed that increasing the proportion of grassland habitat is positively associated with wild bee species richness, thereby justifying bee conservation schemes that aim to enhance semi-natural grassland habitat. Our results confirm the utility of satellite-derived land cover maps in supporting high-resolution species distribution modeling and suggest there is scope to monitor changes in species distributions over time given the dense time series provided by products such as DW.

Published in Remote Sensing

ISSN: 2072-4292 (Online)
Publisher: MDPI AG
Country of publisher: Switzerland
LCC subjects: Science
Website: http://www.mdpi.com/journal/remotesensing/

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