Integration of very high-resolution stereo satellite images and airborne or satellite Lidar for Eucalyptus canopy height estimation - Action, transitions et territoires
Article Dans Une Revue Science of Remote Sensing Année : 2024

Integration of very high-resolution stereo satellite images and airborne or satellite Lidar for Eucalyptus canopy height estimation

Résumé

Eucalyptus plantations cover extensive areas in tropical regions and require accurate growth monitoring for efficient management. Traditional in-situ measurements, while necessary, are labor-intensive and impractical for large-scale assessments. Very high-resolution satellite stereo imagery is playing an increasingly important role in the estimation of fine Digital Surface Models (DSMs) across landscapes. However, its ability to estimate canopy height models (CHMs) has not been widely investigated. This study investigates the integration of highresolution satellite stereo imagery from the Pleiades sensor with airborne or satellite Lidar data to estimate canopy height over eucalyptus plantations. Two study sites were selected in Brazil, representing flat and semimountainous topographies, Mato Grosso do Sul (MS) and Sao Paulo (SP), respectively. Digital Surface Models generated from Pleiades images (DSM P ) were combined with Digital Terrain Models extracted from airborne Lidar data (DTM ALS ) to create Canopy Height Models (CHM ALS ). The evaluation of the CHM ALS was based on two in situ canopy height measurements (H max and H mean ). For the SP site, the CHM ALSmax , which is the average height of top 10% pixel values within each plot, correlated well with in situ H mean , which is the average height of 10 central trees (r = 0.98), showing a bias of 1.4 m, RMSE of 3.1 m, and rRMSE of 18.5%. At the MS site, CHM ALSmax demonstrated a bias of 1.9 m, RMSE of 2.3 m, rRMSE of 17.3%, and r correlation of 0.92. Despite a tendency to underestimate heights below 20 m in young tree plantations with open canopy, the results indicate reliable canopy height estimation. The study also investigates the potential of Global Ecosystem Dynamics Investigation (GEDI) elevation data as an alternative to DTM ALS in absence of airborne Lidar data. The resulting CHM Gedi is promising but slightly less accurate than Lidar-based CHMs. The best GEDI-based CHM (CHM Gedimax ) showed a bias and rRMSE of 1.3 m and 20.5% for the SP site, and 2.2 m and 24.9% for the MS site. These findings highlight the potential for integrating Pleiades and Lidar data for efficient and accurate canopy height monitoring in eucalyptus plantations.
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hal-04746433 , version 1 (21-10-2024)

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Manizheh Rajab Pourrahmati, Nicolas Baghdadi, Henrique Ferraco Scolforo, Clayton Alcarde Alvares, Jose Luiz Stape, et al.. Integration of very high-resolution stereo satellite images and airborne or satellite Lidar for Eucalyptus canopy height estimation. Science of Remote Sensing, 2024, 10, pp.100170. ⟨10.1016/j.srs.2024.100170⟩. ⟨hal-04746433⟩
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