Please use this identifier to cite or link to this item: http://hdl.handle.net/2067/46608
Title: Aboveground biomass density models for NASA's Global Ecosystem Dynamics Investigation (GEDI) lidar mission
Authors: Duncanson, Laura
Kellner, James R.
Armston, John
Dubayah, Ralph
Minor, David M.
Hancock, Steven
Healey, Sean P.
Patterson, Paul L.
Saarela, Svetlana
Marselis, Suzanne
Silva, Carlos E.
Bruening, Jamis
Goetz, Scott J.
Tang, Hao
Hofton, Michelle
Blair, Bryan
Luthcke, Scott
Fatoyinbo, Lola
Abernethy, Katharine
Alonso, Alfonso
Andersen, Hans Erik
Aplin, Paul
Baker, Timothy R.
Barbier, Nicolas
Bastin, Jean Francois
Biber, Peter
Boeckx, Pascal
Bogaert, Jan
Boschetti, Luigi
Boucher, Peter Brehm
Boyd, Doreen S.
Burslem, David F.R.P.
Calvo-Rodriguez, Sofia
Chave, Jérôme
Chazdon, Robin L.
Clark, David B.
Clark, Deborah A.
Cohen, Warren B.
Coomes, David A.
Corona, Piermaria 
Cushman, K. C.
Cutler, Mark E.J.
Dalling, James W.
Dalponte, Michele
Dash, Jonathan
de-Miguel, Sergio
Deng, Songqiu
Ellis, Peter Woods
Erasmus, Barend
Fekety, Patrick A.
Fernandez-Landa, Alfredo
Ferraz, Antonio
Fischer, Rico
Fisher, Adrian G.
García-Abril, Antonio
Gobakken, Terje
Hacker, Jorg M.
Heurich, Marco
Hill, Ross A.
Hopkinson, Chris
Huang, Huabing
Hubbell, Stephen P.
Hudak, Andrew T.
Huth, Andreas
Imbach, Benedikt
Jeffery, Kathryn J.
Katoh, Masato
Kearsley, Elizabeth
Kenfack, David
Kljun, Natascha
Knapp, Nikolai
Král, Kamil
Krůček, Martin
Labrière, Nicolas
Lewis, Simon L.
Longo, Marcos
Lucas, Richard M.
Main, Russell
Manzanera, Jose A.
Martínez, Rodolfo Vásquez
Mathieu, Renaud
Memiaghe, Herve
Meyer, Victoria
Mendoza, Abel Monteagudo
Monerris, Alessandra
Montesano, Paul
Morsdorf, Felix
Næsset, Erik
Naidoo, Laven
Nilus, Reuben
O'Brien, Michael
Orwig, David A.
Papathanassiou, Konstantinos
Parker, Geoffrey
Philipson, Christopher
Phillips, Oliver L.
Pisek, Jan
Poulsen, John R.
Pretzsch, Hans
Rüdiger, Christoph
Journal: REMOTE SENSING OF ENVIRONMENT 
Issue Date: 2022
Abstract: 
NASA's Global Ecosystem Dynamics Investigation (GEDI) is collecting spaceborne full waveform lidar data with a primary science goal of producing accurate estimates of forest aboveground biomass density (AGBD). This paper presents the development of the models used to create GEDI's footprint-level (~25 m) AGBD (GEDI04_A) product, including a description of the datasets used and the procedure for final model selection. The data used to fit our models are from a compilation of globally distributed spatially and temporally coincident field and airborne lidar datasets, whereby we simulated GEDI-like waveforms from airborne lidar to build a calibration database. We used this database to expand the geographic extent of past waveform lidar studies, and divided the globe into four broad strata by Plant Functional Type (PFT) and six geographic regions. GEDI's waveform-to-biomass models take the form of parametric Ordinary Least Squares (OLS) models with simulated Relative Height (RH) metrics as predictor variables. From an exhaustive set of candidate models, we selected the best input predictor variables, and data transformations for each geographic stratum in the GEDI domain to produce a set of comprehensive predictive footprint-level models. We found that model selection frequently favored combinations of RH metrics at the 98th, 90th, 50th, and 10th height above ground-level percentiles (RH98, RH90, RH50, and RH10, respectively), but that inclusion of lower RH metrics (e.g. RH10) did not markedly improve model performance. Second, forced inclusion of RH98 in all models was important and did not degrade model performance, and the best performing models were parsimonious, typically having only 1-3 predictors. Third, stratification by geographic domain (PFT, geographic region) improved model performance in comparison to global models without stratification. Fourth, for the vast majority of strata, the best performing models were fit using square root transformation of field AGBD and/or height metrics. There was considerable variability in model performance across geographic strata, and areas with sparse training data and/or high AGBD values had the poorest performance. These models are used to produce global predictions of AGBD, but will be improved in the future as more and better training data become available.
URI: http://hdl.handle.net/2067/46608
ISSN: 0034-4257
DOI: 10.1016/j.rse.2021.112845
Rights: CC0 1.0 Universal
Appears in Collections:A1. Articolo in rivista

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