Aboveground Biomass Estimation in Amazonian Tropical Forests: a Comparison of Aircraft- and GatorEye UAV-borne LiDAR Data in the Chico Mendes Extractive Reserve in Acre, Brazil

Aboveground Biomass Estimation in Amazonian Tropical Forests: a Comparison of Aircraft- and GatorEye UAV-borne LiDAR Data in the Chico Mendes Extractive Reserve in Acre, Brazil

Tropical forests are often located in difficult-to-access areas, which make high-quality forest structure information difficult and expensive to obtain by traditional field-based approaches. LiDAR (acronym for Light Detection And Ranging) data have been used throughout the world to produce time-effi...

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Main Authors: Marcus V. N. d’Oliveira, Eben N. Broadbent, Luis C. Oliveira, Danilo R. A. Almeida, Daniel A. Papa, Manuel E. Ferreira, Angelica M. Almeyda Zambrano, Carlos A. Silva, Felipe S. Avino, Gabriel A. Prata, Ricardo A. Mello, Evandro O. Figueiredo, Lúcio A. de Castro Jorge, Leomar Junior, Rafael W. Albuquerque, Pedro H. S. Brancalion, Ben Wilkinson, Marcelo Oliveira-da-Costa
Format: Article
Language:English
Published: MDPI AG 2020-05-01
Series:Remote Sensing
Subjects:
forest inventory
forest monitoring
forest structure
remote sensing
Online Access:https://www.mdpi.com/2072-4292/12/11/1754
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author Marcus V. N. d’Oliveira
Eben N. Broadbent
Luis C. Oliveira
Danilo R. A. Almeida
Daniel A. Papa
Manuel E. Ferreira
Angelica M. Almeyda Zambrano
Carlos A. Silva
Felipe S. Avino
Gabriel A. Prata
Ricardo A. Mello
Evandro O. Figueiredo
Lúcio A. de Castro Jorge
Leomar Junior
Rafael W. Albuquerque
Pedro H. S. Brancalion
Ben Wilkinson
Marcelo Oliveira-da-Costa
spellingShingle Marcus V. N. d’Oliveira
Eben N. Broadbent
Luis C. Oliveira
Danilo R. A. Almeida
Daniel A. Papa
Manuel E. Ferreira
Angelica M. Almeyda Zambrano
Carlos A. Silva
Felipe S. Avino
Gabriel A. Prata
Ricardo A. Mello
Evandro O. Figueiredo
Lúcio A. de Castro Jorge
Leomar Junior
Rafael W. Albuquerque
Pedro H. S. Brancalion
Ben Wilkinson
Marcelo Oliveira-da-Costa
Aboveground Biomass Estimation in Amazonian Tropical Forests: a Comparison of Aircraft- and GatorEye UAV-borne LiDAR Data in the Chico Mendes Extractive Reserve in Acre, Brazil
Remote Sensing
forest inventory
forest monitoring
forest structure
remote sensing
author_facet Marcus V. N. d’Oliveira
Eben N. Broadbent
Luis C. Oliveira
Danilo R. A. Almeida
Daniel A. Papa
Manuel E. Ferreira
Angelica M. Almeyda Zambrano
Carlos A. Silva
Felipe S. Avino
Gabriel A. Prata
Ricardo A. Mello
Evandro O. Figueiredo
Lúcio A. de Castro Jorge
Leomar Junior
Rafael W. Albuquerque
Pedro H. S. Brancalion
Ben Wilkinson
Marcelo Oliveira-da-Costa
author_sort Marcus V. N. d’Oliveira
title Aboveground Biomass Estimation in Amazonian Tropical Forests: a Comparison of Aircraft- and GatorEye UAV-borne LiDAR Data in the Chico Mendes Extractive Reserve in Acre, Brazil
title_short Aboveground Biomass Estimation in Amazonian Tropical Forests: a Comparison of Aircraft- and GatorEye UAV-borne LiDAR Data in the Chico Mendes Extractive Reserve in Acre, Brazil
title_full Aboveground Biomass Estimation in Amazonian Tropical Forests: a Comparison of Aircraft- and GatorEye UAV-borne LiDAR Data in the Chico Mendes Extractive Reserve in Acre, Brazil
title_fullStr Aboveground Biomass Estimation in Amazonian Tropical Forests: a Comparison of Aircraft- and GatorEye UAV-borne LiDAR Data in the Chico Mendes Extractive Reserve in Acre, Brazil
title_full_unstemmed Aboveground Biomass Estimation in Amazonian Tropical Forests: a Comparison of Aircraft- and GatorEye UAV-borne LiDAR Data in the Chico Mendes Extractive Reserve in Acre, Brazil
title_sort aboveground biomass estimation in amazonian tropical forests: a comparison of aircraft- and gatoreye uav-borne lidar data in the chico mendes extractive reserve in acre, brazil
publisher MDPI AG
series Remote Sensing
issn 2072-4292
publishDate 2020-05-01
description Tropical forests are often located in difficult-to-access areas, which make high-quality forest structure information difficult and expensive to obtain by traditional field-based approaches. LiDAR (acronym for Light Detection And Ranging) data have been used throughout the world to produce time-efficient and wall-to-wall structural parameter estimates for monitoring in native and commercial forests. In this study, we compare products and aboveground biomass (AGB) estimations from LiDAR data acquired using an aircraft-borne system in 2015 and data collected by the unmanned aerial vehicle (UAV)-based GatorEye Unmanned Flying Laboratory in 2017 for ten forest inventory plots located in the Chico Mendes Extractive Reserve in Acre state, southwestern Brazilian Amazon. The LiDAR products were similar and comparable among the two platforms and sensors. Principal differences between derived products resulted from the GatorEye system flying lower and slower and having increased returns per second than the aircraft, resulting in a much higher point density overall (11.3 ± 1.8 vs. 381.2 ± 58 pts/m<sup>2</sup>). Differences in ground point density, however, were much smaller among the systems, due to the larger pulse area and increased number of returns per pulse of the aircraft system, with the GatorEye showing an approximately 50% higher ground point density (0.27 ± 0.09 vs. 0.42 ± 0.09). The LiDAR models produced by both sensors presented similar results for digital elevation models and estimated AGB. Our results validate the ability for UAV-borne LiDAR sensors to accurately quantify AGB in dense high-leaf-area tropical forests in the Amazon. We also highlight new possibilities using the dense point clouds of UAV-borne systems for analyses of detailed crown structure and leaf area density distribution of the forest interior.
topic forest inventory
forest monitoring
forest structure
remote sensing
url https://www.mdpi.com/2072-4292/12/11/1754
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spelling doaj-bc8b69f6001a4e49a3e4ca26d5c656b52020-11-25T03:10:41ZengMDPI AGRemote Sensing2072-42922020-05-01121754175410.3390/rs12111754Aboveground Biomass Estimation in Amazonian Tropical Forests: a Comparison of Aircraft- and GatorEye UAV-borne LiDAR Data in the Chico Mendes Extractive Reserve in Acre, BrazilMarcus V. N. d’Oliveira0Eben N. Broadbent1Luis C. Oliveira2Danilo R. A. Almeida3Daniel A. Papa4Manuel E. Ferreira5Angelica M. Almeyda Zambrano6Carlos A. Silva7Felipe S. Avino8Gabriel A. Prata9Ricardo A. Mello10Evandro O. Figueiredo11Lúcio A. de Castro Jorge12Leomar Junior13Rafael W. Albuquerque14Pedro H. S. Brancalion15Ben Wilkinson16Marcelo Oliveira-da-Costa17Embrapa Acre, Rodovia BR-364, km 14, CEP 69900-056 Rio Branco, Acre, BrazilSpatial Ecology and Conservation (SPEC) Lab, School of Forest Resources and Conservation, University of Florida, Gainesville, FL 32611, USAEmbrapa Acre, Rodovia BR-364, km 14, CEP 69900-056 Rio Branco, Acre, BrazilSpatial Ecology and Conservation (SPEC) Lab, School of Forest Resources and Conservation, University of Florida, Gainesville, FL 32611, USAEmbrapa Acre, Rodovia BR-364, km 14, CEP 69900-056 Rio Branco, Acre, BrazilImage Processing and GIS Lab (LAPIG), Universidade Federal de Goiás, 74001-970 Goiânia-GO, BrazilSpatial Ecology and Conservation (SPEC) Lab, School of Forest Resources and Conservation, University of Florida, Gainesville, FL 32611, USADepartment of Geographical Sciences, School of Forest Resources and Conservation, University of Florida, Gainesville, FL 32611, USAWWF-Brazil, CLS 114, Bloco D-35, 70377-540 Brasília-DF, BrazilSpatial Ecology and Conservation (SPEC) Lab, School of Forest Resources and Conservation, University of Florida, Gainesville, FL 32611, USAWWF-Brazil, CLS 114, Bloco D-35, 70377-540 Brasília-DF, BrazilEmbrapa Acre, Rodovia BR-364, km 14, CEP 69900-056 Rio Branco, Acre, BrazilEmbrapa Instrumentação, Rua XV de Novembro, 1452, CEP 13564-030 São Carlos-SP, BrazilImage Processing and GIS Lab (LAPIG), Universidade Federal de Goiás, 74001-970 Goiânia-GO, BrazilInstitute of Energy and Environment, University of São Paulo, Prof. Luciano Gualberto Avenue, 1289 São Paulo-SP, BrazilDepartment of Forest Sciences, “Luiz de Queiroz” College of Agriculture, University of São Paulo (USP/ESALQ), 1289 Piracicaba-SP, BrazilDepartment of Geographical Sciences, School of Forest Resources and Conservation, University of Florida, Gainesville, FL 32611, USAWWF-Brazil, CLS 114, Bloco D-35, 70377-540 Brasília-DF, BrazilTropical forests are often located in difficult-to-access areas, which make high-quality forest structure information difficult and expensive to obtain by traditional field-based approaches. LiDAR (acronym for Light Detection And Ranging) data have been used throughout the world to produce time-efficient and wall-to-wall structural parameter estimates for monitoring in native and commercial forests. In this study, we compare products and aboveground biomass (AGB) estimations from LiDAR data acquired using an aircraft-borne system in 2015 and data collected by the unmanned aerial vehicle (UAV)-based GatorEye Unmanned Flying Laboratory in 2017 for ten forest inventory plots located in the Chico Mendes Extractive Reserve in Acre state, southwestern Brazilian Amazon. The LiDAR products were similar and comparable among the two platforms and sensors. Principal differences between derived products resulted from the GatorEye system flying lower and slower and having increased returns per second than the aircraft, resulting in a much higher point density overall (11.3 ± 1.8 vs. 381.2 ± 58 pts/m<sup>2</sup>). Differences in ground point density, however, were much smaller among the systems, due to the larger pulse area and increased number of returns per pulse of the aircraft system, with the GatorEye showing an approximately 50% higher ground point density (0.27 ± 0.09 vs. 0.42 ± 0.09). The LiDAR models produced by both sensors presented similar results for digital elevation models and estimated AGB. Our results validate the ability for UAV-borne LiDAR sensors to accurately quantify AGB in dense high-leaf-area tropical forests in the Amazon. We also highlight new possibilities using the dense point clouds of UAV-borne systems for analyses of detailed crown structure and leaf area density distribution of the forest interior.https://www.mdpi.com/2072-4292/12/11/1754forest inventoryforest monitoringforest structureremote sensing

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