TY - JOUR
T1 - Non-destructive estimation of individual tree biomass
T2 - Allometric models, terrestrial and UAV laser scanning
AU - Brede, Benjamin
AU - Terryn, Louise
AU - Barbier, Nicolas
AU - Bartholomeus, Harm M.
AU - Bartolo, Renée
AU - Calders, Kim
AU - Derroire, Géraldine
AU - Krishna Moorthy, Sruthi M.
AU - Lau, Alvaro
AU - Levick, Shaun R.
AU - Raumonen, Pasi
AU - Verbeeck, Hans
AU - Wang, Di
AU - Whiteside, Tim
AU - van der Zee, Jens
AU - Herold, Martin
N1 - Funding Information:
Kim Calders was funded by the European Union's Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No 835398 . Sruthi M. Krishna Moorthy was funded by BELSPO (Belgian Science Policy Office) in the frame of the STEREO III programme – project 3D-FOREST (SR/02/355). Di Wang was supported by the National Key R&D Program of China (2021YFF0704600) and the National Natural Science Foundation of China under Grant No. 42101330.
Funding Information:
This work was carried out as part of the IDEAS-QA4EO and ForestScan contracts funded by ESA-ESRIN. Fieldwork at the Speulderbos site was funded by the IDEAS+ contract funded by ESA-ESRIN. The Australian fieldwork was funded by BELSPO (Belgian Science Policy Office) in the frame of the STEREO III programme - project 3D-FOREST (SR/02/355). Kim Calders was funded by the European Union's Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No 835398. Sruthi M. Krishna Moorthy was funded by BELSPO (Belgian Science Policy Office) in the frame of the STEREO III programme – project 3D-FOREST (SR/02/355). Di Wang was supported by the National Key R&D Program of China (2021YFF0704600) and the National Natural Science Foundation of China under Grant No. 42101330. The authors want to thank Diego Marcos Gonzalez for helpful discussions on modelling paradigms. The access to the RiCOPTER was made possible by Shared Research Facilities of Wageningen University Research. The authors thank the Dutch Forestry Service (Staatsbosbeheer) for granting access to the Speulderbos site. This work was supported by the use of Terrestrial Ecosystem Research Network (TERN) infrastructure, which is enabled by the Australian Government's National Collaborative Research Infrastructure Strategy (NCRIS). The authors thank three anonymous reviewers for critical and constructive remarks that helped to improve the quality of the manuscript.
Funding Information:
This work was carried out as part of the IDEAS-QA4EO and ForestScan contracts funded by ESA-ESRIN . Fieldwork at the Speulderbos site was funded by the IDEAS+ contract funded by ESA-ESRIN . The Australian fieldwork was funded by BELSPO (Belgian Science Policy Office) in the frame of the STEREO III programme - project 3D-FOREST (SR/02/355).
Publisher Copyright:
© 2022 The Authors
PY - 2022/10
Y1 - 2022/10
N2 - Calibration and validation of aboveground biomass (AGB) (AGB) products retrieved from satellite-borne sensors require accurate AGB estimates across hectare scales (1 to 100 ha). Recent studies recommend making use of non-destructive terrestrial laser scanning (TLS) based techniques for individual tree AGB estimation that provide unbiased AGB predictors. However, applying these techniques across large sites and landscapes remains logistically challenging. Unoccupied aerial vehicle laser scanning (UAV-LS) has the potential to address this through the collection of high density point clouds across many hectares, but estimation of individual tree AGB based on these data has been challenging so far, especially in dense tropical canopies. In this study, we investigated how TLS and UAV-LS can be used for this purpose by testing different modelling strategies with data availability and modelling framework requirements. The study included data from four forested sites across three biomes: temperate, wet tropical, and tropical savanna. At each site, coincident TLS and UAV-LS campaigns were conducted. Diameter at breast height (DBH) and tree height were estimated from TLS point clouds. Individual tree AGB was estimated for ≥170 trees per site based on TLS tree point clouds and quantitative structure modelling (QSM), and treated as the best available, non-destructive estimate of AGB in the absence of direct, destructive measurements. Individual trees were automatically segmented from the UAV-LS point clouds using a shortest-path algorithm on the full 3D point cloud. Predictions were evaluated in terms of individual tree root mean square error (RMSE) and population bias, the latter being the absolute difference between total tree sample population TLS QSM estimated AGB and predicted AGB. The application of global allometric scaling models (ASM) at local scale and across data modalities, i.e., field-inventory and light detection and ranging LiDAR metrics, resulted in individual tree prediction errors in the range of reported studies, but relatively high population bias. The use of adjustment factors should be considered to translate between data modalities. When calibrating local models, DBH was confirmed as a strong predictor of AGB, and useful when scaling AGB estimates with field inventories. The combination of UAV-LS derived tree metrics with non-parametric modelling generally produced high individual tree RMSE, but very low population bias of ≤5% across sites starting from 55 training samples. UAV-LS has the potential to scale AGB estimates across hectares with reduced fieldwork time. Overall, this study contributes to the exploitation of TLS and UAV-LS for hectare scale, non-destructive AGB estimation relevant for the calibration and validation of space-borne missions targeting AGB estimation.
AB - Calibration and validation of aboveground biomass (AGB) (AGB) products retrieved from satellite-borne sensors require accurate AGB estimates across hectare scales (1 to 100 ha). Recent studies recommend making use of non-destructive terrestrial laser scanning (TLS) based techniques for individual tree AGB estimation that provide unbiased AGB predictors. However, applying these techniques across large sites and landscapes remains logistically challenging. Unoccupied aerial vehicle laser scanning (UAV-LS) has the potential to address this through the collection of high density point clouds across many hectares, but estimation of individual tree AGB based on these data has been challenging so far, especially in dense tropical canopies. In this study, we investigated how TLS and UAV-LS can be used for this purpose by testing different modelling strategies with data availability and modelling framework requirements. The study included data from four forested sites across three biomes: temperate, wet tropical, and tropical savanna. At each site, coincident TLS and UAV-LS campaigns were conducted. Diameter at breast height (DBH) and tree height were estimated from TLS point clouds. Individual tree AGB was estimated for ≥170 trees per site based on TLS tree point clouds and quantitative structure modelling (QSM), and treated as the best available, non-destructive estimate of AGB in the absence of direct, destructive measurements. Individual trees were automatically segmented from the UAV-LS point clouds using a shortest-path algorithm on the full 3D point cloud. Predictions were evaluated in terms of individual tree root mean square error (RMSE) and population bias, the latter being the absolute difference between total tree sample population TLS QSM estimated AGB and predicted AGB. The application of global allometric scaling models (ASM) at local scale and across data modalities, i.e., field-inventory and light detection and ranging LiDAR metrics, resulted in individual tree prediction errors in the range of reported studies, but relatively high population bias. The use of adjustment factors should be considered to translate between data modalities. When calibrating local models, DBH was confirmed as a strong predictor of AGB, and useful when scaling AGB estimates with field inventories. The combination of UAV-LS derived tree metrics with non-parametric modelling generally produced high individual tree RMSE, but very low population bias of ≤5% across sites starting from 55 training samples. UAV-LS has the potential to scale AGB estimates across hectares with reduced fieldwork time. Overall, this study contributes to the exploitation of TLS and UAV-LS for hectare scale, non-destructive AGB estimation relevant for the calibration and validation of space-borne missions targeting AGB estimation.
KW - Aboveground biomass (AGB)
KW - Allometric scaling model (ASM)
KW - Forest
KW - Quantitative structure modelling (QSM)
KW - Terrestrial laser scanning (TLS)
KW - Unoccupied aerial vehicle laser scanning (UAV-LS)
U2 - 10.1016/j.rse.2022.113180
DO - 10.1016/j.rse.2022.113180
M3 - Article
AN - SCOPUS:85135869116
SN - 0034-4257
VL - 280
JO - Remote Sensing of Environment
JF - Remote Sensing of Environment
M1 - 113180
ER -