Your search keyword '"Benedikt Imbach"' showing total 7 results

1. Impact of a tropical forest blowdown on aboveground carbon balance

Author

K. C. Cushman, John T. Burley, Benedikt Imbach, Sassan S. Saatchi, Carlos E. Silva, Orlando Vargas, Carlo Zgraggen, and James R. Kellner

Subjects

Medicine, Science

Abstract

Abstract Field measurements demonstrate a carbon sink in the Amazon and Congo basins, but the cause of this sink is uncertain. One possibility is that forest landscapes are experiencing transient recovery from previous disturbance. Attributing the carbon sink to transient recovery or other processes is challenging because we do not understand the sensitivity of conventional remote sensing methods to changes in aboveground carbon density (ACD) caused by disturbance events. Here we use ultra-high-density drone lidar to quantify the impact of a blowdown disturbance on ACD in a lowland rain forest in Costa Rica. We show that the blowdown decreased ACD by at least 17.6%, increased the number of canopy gaps, and altered the gap size-frequency distribution. Analyses of a canopy-height transition matrix indicate departure from steady-state conditions. This event will initiate a transient sink requiring an estimated 24–49 years to recover pre-disturbance ACD. Our results suggest that blowdowns of this magnitude and extent can remain undetected by conventional satellite optical imagery but are likely to alter ACD decades after they occur.

Published

2021

2. New Opportunities for Forest Remote Sensing Through Ultra-High-Density Drone Lidar

Author

James R. Kellner, John Armston, Markus Birrer, K. C. Cushman, Laura Duncanson, Christoph Eck, Christoph Falleger, Benedikt Imbach, Kamil Král, Martin Krůček, Jan Trochta, Tomáš Vrška, and Carlo Zgraggen

Published

2019

3. Impact of a tropical forest blowdown on aboveground carbon balance

Author

C. E. Silva, Orlando Vargas, Sassan Saatchi, Benedikt Imbach, James R. Kellner, K. C. Cushman, Carlo Zgraggen, and John T. Burley

Subjects

0106 biological sciences, Canopy, 010504 meteorology & atmospheric sciences, Science, Rainforest, Atmospheric sciences, 01 natural sciences, Sink (geography), Article, Carbon cycle, Forest ecology, Boiler blowdown, 0105 earth and related environmental sciences, geography, Multidisciplinary, geography.geographical_feature_category, Carbon sink, Tropical ecology, Disturbance (ecology), Environmental science, Medicine, 010606 plant biology & botany

Abstract

Field measurements demonstrate a carbon sink in the Amazon and Congo basins, but the cause of this sink is uncertain. One possibility is that forest landscapes are experiencing transient recovery from previous disturbance. Attributing the carbon sink to transient recovery or other processes is challenging because we do not understand the sensitivity of conventional remote sensing methods to changes in aboveground carbon density (ACD) caused by disturbance events. Here we use ultra-high-density drone lidar to quantify the impact of a blowdown disturbance on ACD in a lowland rain forest in Costa Rica. We show that the blowdown decreased ACD by at least 17.6%, increased the number of canopy gaps, and altered the gap size-frequency distribution. Analyses of a canopy-height transition matrix indicate departure from steady-state conditions. This event will initiate a transient sink requiring an estimated 24–49 years to recover pre-disturbance ACD. Our results suggest that blowdowns of this magnitude and extent can remain undetected by conventional satellite optical imagery but are likely to alter ACD decades after they occur.

Published

2021

4. Aboveground biomass density models for NASA's Global Ecosystem Dynamics Investigation (GEDI) lidar mission

Author

Laura Duncanson, James R. Kellner, John Armston, Ralph Dubayah, David M. Minor, Steven Hancock, Sean P. Healey, Paul L. Patterson, Svetlana Saarela, Suzanne Marselis, Carlos E. Silva, Jamis Bruening, Scott J. Goetz, Hao Tang, Michelle Hofton, Bryan Blair, Scott Luthcke, Lola Fatoyinbo, Katharine Abernethy, Alfonso Alonso, Hans-Erik Andersen, Paul Aplin, Timothy R. Baker, Nicolas Barbier, Jean Francois Bastin, Peter Biber, Pascal Boeckx, Jan Bogaert, Luigi Boschetti, Peter Brehm Boucher, Doreen S. Boyd, David F.R.P. Burslem, Sofia Calvo-Rodriguez, Jérôme Chave, Robin L. Chazdon, David B. Clark, Deborah A. Clark, Warren B. Cohen, David A. Coomes, Piermaria Corona, K.C. Cushman, Mark E.J. Cutler, James W. Dalling, Michele Dalponte, Jonathan Dash, Sergio de-Miguel, Songqiu Deng, Peter Woods Ellis, Barend Erasmus, Patrick A. Fekety, Alfredo Fernandez-Landa, Antonio Ferraz, Rico Fischer, Adrian G. Fisher, Antonio García-Abril, Terje Gobakken, Jorg M. Hacker, Marco Heurich, Ross A. Hill, Chris Hopkinson, Huabing Huang, Stephen P. Hubbell, Andrew T. Hudak, Andreas Huth, Benedikt Imbach, Kathryn J. Jeffery, Masato Katoh, Elizabeth Kearsley, David Kenfack, Natascha Kljun, Nikolai Knapp, Kamil Král, Martin Krůček, Nicolas Labrière, Simon L. Lewis, Marcos Longo, Richard M. Lucas, Russell Main, Jose A. Manzanera, Rodolfo Vásquez Martínez, Renaud Mathieu, Herve Memiaghe, Victoria Meyer, Abel Monteagudo Mendoza, Alessandra Monerris, Paul Montesano, Felix Morsdorf, Erik Næsset, Laven Naidoo, Reuben Nilus, Michael O’Brien, David A. Orwig, Konstantinos Papathanassiou, Geoffrey Parker, Christopher Philipson, Oliver L. Phillips, Jan Pisek, John R. Poulsen, Hans Pretzsch, Christoph Rüdiger, Sassan Saatchi, Arturo Sanchez-Azofeifa, Nuria Sanchez-Lopez, Robert Scholes, Carlos A. Silva, Marc Simard, Andrew Skidmore, Krzysztof Stereńczak, Mihai Tanase, Chiara Torresan, Ruben Valbuena, Hans Verbeeck, Tomas Vrska, Konrad Wessels, Joanne C. White, Lee J.T. White, Eliakimu Zahabu, Carlo Zgraggen, Department of Natural Resources, UT-I-ITC-FORAGES, Faculty of Geo-Information Science and Earth Observation, University of Maryland [College Park], University of Maryland System, Brown University, University of Edinburgh, USDA Forest Service Rocky Mountain Forest and Range Experiment Station, United States Department of Agriculture (USDA), Swedish University of Agricultural Sciences (SLU), Botanique et Modélisation de l'Architecture des Plantes et des Végétations (UMR AMAP), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud])-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Gembloux Agro-Bio Tech [Gembloux], and Université de Liège

Subjects

0106 biological sciences, CANOPY STRUCTURE, LiDAR, 010504 meteorology & atmospheric sciences, Soil Science, [SDV.BID.SPT]Life Sciences [q-bio]/Biodiversity/Systematics, Phylogenetics and taxonomy, Geological & Geomatics Engineering, 010603 evolutionary biology, 01 natural sciences, Physical Geography and Environmental Geoscience, CARBON, Remote Sensing, ITC-HYBRID, BOREAL FOREST, HEIGHT, [SDV.EE.ECO]Life Sciences [q-bio]/Ecology, environment/Ecosystems, Settore BIO/07 - ECOLOGIA, GEDI, Waveform, Forest, Aboveground biomass, Modeling, ddc:630, INVERSION, Computers in Earth Sciences, 0105 earth and related environmental sciences, GROUND BIOMASS, Geology, VDP::Matematikk og Naturvitenskap: 400, 15. Life on land, [SDV.BV.BOT]Life Sciences [q-bio]/Vegetal Biology/Botanics, REGIONS, ddc, Geomatic Engineering, 13. Climate action, AIRBORNE LIDAR, Earth and Environmental Sciences, ITC-ISI-JOURNAL-ARTICLE, TROPICAL FOREST BIOMASS, cavelab, VEGETATION, [SDE.BE]Environmental Sciences/Biodiversity and Ecology

Abstract

© 2021 The Authors. Published by Elsevier Inc. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/). 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.

Published

2022

5. New Opportunities for Forest Remote Sensing Through Ultra-High-Density Drone Lidar

Author

K. C. Cushman, Carlo Zgraggen, Christoph Eck, Martin Krůček, Tomáš Vrška, James R. Kellner, John Armston, Laura Duncanson, Christoph Falleger, Markus Birrer, Jan Trochta, Kamil Král, and Benedikt Imbach

Subjects

Global Ecosystem Dynamics Investigation (GEDI), Lidar, 010504 meteorology & atmospheric sciences, Laser scanning, UAV, Elevation, Point cloud, Remote sensing, 010502 geochemistry & geophysics, 01 natural sciences, Article, Drone, Space exploration, Geolocation, Geophysics, Geochemistry and Petrology, Remote sensing (archaeology), Environmental science, 0105 earth and related environmental sciences

Abstract

Current and planned space missions will produce aboveground biomass density data products at varying spatial resolution. Calibration and validation of these data products is critically dependent on the existence of field estimates of aboveground biomass and coincident remote sensing data from airborne or terrestrial lidar. There are few places that meet these requirements, and they are mostly in the northern hemisphere and temperate zone. Here we summarize the potential for low-altitude drones to produce new observations in support of mission science. We describe technical requirements for producing high-quality measurements from autonomous platforms and highlight differences among commercially available laser scanners and drone aircraft. We then describe a case study using a heavy-lift autonomous helicopter in a temperate mountain forest in the southern Czech Republic in support of calibration and validation activities for the NASA Global Ecosystem Dynamics Investigation. Low-altitude flight using drones enables the collection of ultra-high-density point clouds using wider laser scan angles than have been possible from traditional airborne platforms. These measurements can be precise and accurate and can achieve measurement densities of thousands of points · m−2. Analysis of surface elevation measurements on a heterogeneous target observed 51 days apart indicates that the realized range accuracy is 2.4 cm. The single-date precision is 2.1–4.5 cm. These estimates are net of all processing artifacts and geolocation errors under fully autonomous flight. The 3D model produced by these data can clearly resolve branch and stem structure that is comparable to terrestrial laser scans and can be acquired rapidly over large landscapes at a fraction of the cost of traditional airborne laser scanning.

Published

2019

6. UAV-based LiDAR acquisition for the derivation of high-resolution forest and ground information

Author

Felix Morsdorf, Carlo Zgraggen, Fabian D. Schneider, Benedikt Imbach, Christoph Eck, Daniel Kükenbrink, University of Zurich, and Morsdorf, Felix

Subjects

010504 meteorology & atmospheric sciences, Laser scanning, Meteorology, Point cloud, Geology, Terrain, Ranging, TOPS, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Altitude, Flight planning, Lidar, 10122 Institute of Geography, Environmental science, 910 Geography & travel, 1908 Geophysics, 1907 Geology, 0105 earth and related environmental sciences, Remote sensing

Abstract

Laser scanning of forested areas helps in analyzing and understanding various aspects of forest conditions, including distribution of plants and trees, height distribution of trees, tree density, size and volume of wood, as well as ground surface properties. However, laser scanning of forest areas is also very challenging for many reasons. The best time for scanning is before trees leaf out in the spring or after trees cast their leaves in autumn before snowfall so an unmanned aerial vehicle (UAV) laser scanner can penetrate the forest from the tops of the trees down to the ground surface. To receive highly accurate laser data and high point density, the flight planning must be adjusted judiciously. Flight planning will be even more complex in steep terrain where the UAV cannot operate at a constant altitude. This paper discusses a UAV-based 3D laser data recording — light detection and ranging (LiDAR) scanning — of a forestry area with high accuracy and point cloud resolution. In addition, the point cloud of airborne laser scanning is compared with local terrestrial laser-scanning results. The forest area consists of mixed forests containing varying tree sizes and branch deformation. This paper summarizes our latest results in UAV-based LiDAR acquisition over a forest area to extract detailed forest and ground information and finds that UAV-based laser scanning is well suited for provision of both high-quality forest structural and terrain elevation information.

Published

2017

7. Mission Planning and Flight Precision Analysis for Autonomous Aerial Magnetic Scanning

Author

Benedikt Imbach, Erich Styger, Johannes B. Stoll, and Christoph Eck

Subjects

business.industry, Computer science, Aerospace engineering, business

Published

2011