Individual mapping of large polymorphic shrubs in high mountains using satellite images and deep learning
Metadatos
Mostrar el registro completo del ítemAutor
Khaldi, Rohaifa; Tabik, Siham; Puertas-Ruíz, Sergio; Peñas De Giles, Julio; Hodar Correa, José Antonio; Zamora Rodríguez, Regino Jesús; Alcaraz Segura, DomingoEditorial
Elsevier
Materia
Vegetation mapping Remote sensing Deep learning
Fecha
2024-10-11Referencia bibliográfica
Khaldi, R. et. al. International Journal of Applied Earth Observation and Geoinformation 134 (2024) 104191. [https://doi.org/10.1016/j.jag.2024.104191]
Patrocinador
Project ‘‘Plan Complementario de I+D+i en el área de Biodiversidad (PCBIO)’’ funded by the European Union within the framework of the Recovery, Transformation and Resilience Plan - NextGenerationEU; Regional Government of Andalusia (BIOD22_002); Project SmartFoRest (TED2021-129690B-I00, funded by MCIN/AEI/ 10.13039/501100011033 and by the European Union NextGenerationEU/ PRTR); Project DETECTOR (ARNM- 256-UGR18 Universidad de Granada/FEDER) and LifeWatch-ERIC SmartEcomountains (LifeWatch-2019-10-UGR-01 Ministerio de Ciencia e Innovación/Universidad de Granada/FEDER); DeepL-ISCO (A-TIC-458-UGR18 Ministerio de Ciencia e Innovación/ FEDER), and BigDDL-CET (P18-FR-4961 Ministerio de Ciencia e Innovación/ Universidad de Granada/FEDER); H2020 project ‘‘ECOPOTENTIAL: Improving Future Ecosystem Benefits Through Earth Observations’’; European Union’s Horizon 2020 research and innovation programme under grant agreement No 641762Resumen
Monitoring the distribution and size of long-living large shrubs, such as junipers, is crucial for assessing the
long-term impacts of global change on high-mountain ecosystems. While deep learning models have shown
remarkable success in object segmentation, adapting these models to detect shrub species with polymorphic
nature remains challenging. In this research, we release a large dataset of individual shrub delineations on
freely available satellite imagery and use an instance segmentation model to map all junipers over the treeline
for an entire biosphere reserve (Sierra Nevada, Spain). To optimize performance, we introduced a novel dual
data construction approach: using photo-interpreted (PI) data for model development and fieldwork (FW) data
for validation. To account for the polymorphic nature of junipers during model evaluation, we developed a
soft version of the Intersection over Union metric. Finally, we assessed the uncertainty of the resulting map in
terms of canopy cover and density of shrubs per size class. Our model achieved an F1-score in shrub delineation
of 87.87% on the PI data and 76.86% on the FW data. The R2 and RMSE of the observed versus predicted
relationship were 0.63 and 6.67% for canopy cover, and 0.90 and 20.62 for shrub density. The greater density
of larger shrubs in lower altitudes and smaller shrubs in higher altitudes observed in the model outputs was also
present in the PI and FW data, suggesting an altitudinal uplift in the optimal performance of the species. This
study demonstrates that deep learning applied on freely available high-resolution satellite imagery is useful
to detect medium to large shrubs of high ecological value at the regional scale, which could be expanded to
other high-mountains worldwide and to historical and fothcoming imagery.