Publications des scientifiques de l'IRD

Rousset G., Despinoy Marc, Schindler K., Mangeas Morgan. (2021). Assessment of deep learning techniques for land use land cover classification in Southern New Caledonia. Remote Sensing, 13 (12), 2257 [22 p.].

Titre du document
Assessment of deep learning techniques for land use land cover classification in Southern New Caledonia
Année de publication
2021
Type de document
Article référencé dans le Web of Science WOS:000666374300001
Auteurs
Rousset G., Despinoy Marc, Schindler K., Mangeas Morgan
Source
Remote Sensing, 2021, 13 (12), 2257 [22 p.]
Land use (LU) and land cover (LC) are two complementary pieces of cartographic information used for urban planning and environmental monitoring. In the context of New Caledonia, a biodiversity hotspot, the availability of up-to-date LULC maps is essential to monitor the impact of extreme events such as cyclones and human activities on the environment. With the democratization of satellite data and the development of high-performance deep learning techniques, it is possible to create these data automatically. This work aims at determining the best current deep learning configuration (pixel-wise vs. semantic labelling architectures, data augmentation, image prepossessing, horizontal ellipsis ), to perform LULC mapping in a complex, subtropical environment. For this purpose, a specific data set based on SPOT6 satellite data was created and made available for the scientific community as an LULC benchmark in a tropical, complex environment using five representative areas of New Caledonia labelled by a human operator: four used as training sets, and the fifth as a test set. Several architectures were trained and the resulting classification was compared with a state-of-the-art machine learning technique: XGboost. We also assessed the relevance of popular neo-channels derived from the raw observations in the context of deep learning. The deep learning approach showed comparable results to XGboost for LC detection and over-performed it on the LU detection task (61.45% vs. 51.56% of overall accuracy). Finally, adding LC classification output of the dedicated deep learning architecture to the raw channels input significantly improved the overall accuracy of the deep learning LU classification task (63.61% of overall accuracy). All the data used in this study are available on line for the remote sensing community and for assessing other LULC detection techniques.
Plan de classement
Sciences du milieu [021] ; Informatique [122] ; Télédétection [126]
Description Géographique
NOUVELLE CALEDONIE
Localisation
Fonds IRD [F B010082188]
Identifiant IRD
fdi:010082188
Contact