Large scale multi-layer fuel load characterization in tropical savanna using GEDI spaceborne lidar data

Large scale multi-layer fuel load characterization in tropical savanna using GEDI spaceborne lidar data

Quantifying fuel load over large areas is essential to support integrated fire management initiatives in fire-prone regions to preserve carbon stock, biodiversity and ecosystem functioning. It also allows a better understanding of global climate regulation as a potential carbon sink or source. Large...

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Bibliographic Details
Published in:Remote sensing of environment Vol. 268; p. 112764
Main Authors: Leite, Rodrigo Vieira, Silva, Carlos Alberto, Broadbent, Eben North, Amaral, Cibele Hummel do, Liesenberg, Veraldo, Almeida, Danilo Roberti Alves de, Mohan, Midhun, Godinho, Sérgio, Cardil, Adrian, Hamamura, Caio, Faria, Bruno Lopes de, Brancalion, Pedro H.S., Hirsch, André, Marcatti, Gustavo Eduardo, Dalla Corte, Ana Paula, Zambrano, Angelica Maria Almeyda, Costa, Máira Beatriz Teixeira da, Matricardi, Eraldo Aparecido Trondoli, Silva, Anne Laura da, Goya, Lucas Ruggeri Ré Y., Valbuena, Ruben, Mendonça, Bruno Araujo Furtado de, Silva Junior, Celso H.L., Aragão, Luiz E.O.C., García, Mariano, Liang, Jingjing, Merrick, Trina, Hudak, Andrew T., Xiao, Jingfeng, Hancock, Steven, Duncason, Laura, Ferreira, Matheus Pinheiro, Valle, Denis, Saatchi, Sassan, Klauberg, Carine
Format: Journal Article
Language:English
Published: New York Elsevier Inc 01-01-2022
Elsevier BV
Subjects:
Active remote sensing
Biodiversity
Carbon
Carbon sinks
Cerrado
Ecosystem dynamics
Fire
Fuels
Global climate
Grasslands
Learning algorithms
Lidar
Load
Machine learning
Modeling
Multilayers
Remote sensors
Savannahs
Shrubs
Spaceborne lidar
Three dimensional models
UAV-lidar
Unmanned aerial vehicles
Vegetation
Vegetation structure
Waveforms
Cerrado Biome
Fire
Machine learning
Cerrado
Modeling
Vegetation structure
Active remote sensing
UAV-lidar
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Summary:Quantifying fuel load over large areas is essential to support integrated fire management initiatives in fire-prone regions to preserve carbon stock, biodiversity and ecosystem functioning. It also allows a better understanding of global climate regulation as a potential carbon sink or source. Large area assessments usually require data from spaceborne remote sensors, but most of them cannot measure the vertical variability of vegetation structure, which is required for accurately measuring fuel loads and defining management interventions. The recently launched NASA's Global Ecosystem Dynamics Investigation (GEDI) full-waveform lidar sensor holds potential to meet this demand. However, its capability for estimating fuel load has yet not been evaluated. In this study, we developed a novel framework and tested machine learning models for predicting multi-layer fuel load in the Brazilian tropical savanna (i.e., Cerrado biome) using GEDI data. First, lidar data were collected using an unnamed aerial vehicle (UAV). The flights were conducted over selected sample plots in distinct Cerrado vegetation formations (i.e., grassland, savanna, forest) where field measurements were conducted to determine the load of surface, herbaceous, shrubs and small trees, woody fuels and the total fuel load. Subsequently, GEDI-like full-waveforms were simulated from the high-density UAV-lidar 3-D point clouds from which vegetation structure metrics were calculated and correlated to field-derived fuel load components using Random Forest models. From these models, we generate fuel load maps for the entire Cerrado using all on-orbit available GEDI data. Overall, the models had better performance for woody fuels and total fuel loads (R2 = 0.88 and 0.71, respectively). For components at the lower stratum, models had moderate to low performance (R2 between 0.15 and 0.46) but still showed reliable results. The presented framework can be extended to other fire-prone regions where accurate measurements of fuel components are needed. We hope this study will contribute to the expansion of spaceborne lidar applications for integrated fire management activities and supporting carbon monitoring initiatives in tropical savannas worldwide. •GEDI allows large scale multi-layer characterization of fuels in tropical savannas.•A novel framework for fuel load modeling from simulated GEDI data is developed.•Random Forest models are derived for estimating multi-layer fuel loads.•Models performed better for woody and total than surface fuel loads.•A step change toward large scale fuel load mapping from space in tropical savanna.
ISSN:0034-4257
1879-0704
DOI:10.1016/j.rse.2021.112764