Using high-density UAV-Lidar for deriving tree height of Araucaria Angustifolia in an Urban Atlantic Rain Forest

•Understanding the dynamics of urban forests as carbon pools is crucial.•Tree height is relevant because it is used to predicting biomass and carbon storage.•It is relevant check the point density influence on deriving the tree height.•The UAV-Lidar provides a high density of returns, thus more tree...

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Veröffentlicht in:Urban forestry & urban greening 2021-08, Vol.63, p.127197, Article 127197
Hauptverfasser: da Cunha Neto, Ernandes Macedo, Rex, Franciel Eduardo, Veras, Hudson Franklin Pessoa, Moura, Marks Melo, Sanquetta, Carlos Roberto, Käfer, Pâmela Suélen, Sanquetta, Mateus Niroh Inoue, Zambrano, Angelica Maria Almeyda, Broadbent, Eben North, Corte, Ana Paula Dalla
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Sprache:eng
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Zusammenfassung:•Understanding the dynamics of urban forests as carbon pools is crucial.•Tree height is relevant because it is used to predicting biomass and carbon storage.•It is relevant check the point density influence on deriving the tree height.•The UAV-Lidar provides a high density of returns, thus more tree’s details.•The UAV-Lidar’s high densities have derived heights similar to moderate densities. Urban forest remnants contribute to climate change mitigation by reducing the amount of carbon dioxide in urban areas. Hence, understanding the dynamics and the potential of urban forests as carbon pools is crucial to propose effective policies addressing the ecosystem services' maintenance. Remote sensing technologies such as Light detection and ranging (Lidar) are alternatives to acquire information on urban forests accurately. In this paper, we evaluate a UAV-Lidar system's potential to derive individual tree heights of Araucaria angustifolia trees in an Urban Atlantic Forest. Additionally, the influence of point density when deriving tree heights was assessed (2500, 1000, 500, 250, 100, 50, 25, 10 and 5 returns.m−2). The UAV-Lidar data was collected with the GatorEye Unmanned Flying Laboratory ‘Generation 2’. The UAV-Lidar-derived and field-based tree heights were compared by statistical analysis. Higher densities of points allowed a better description of tree profiles. Lower densities presented gaps in the Crown Height Model (CHM). The highest agreement between UAV-Lidar-derived and field-based tree heights (r = 0.73) was noticed when using 100 returns.m−2. The lowest rRMSE was observed for 50 returns.m−2 (8.35 %). There are no explicit differences in derived tree heights using 25 to 2500 returns.m−2. UAV-Lidar data presented satisfactory performance when deriving individual tree heights of Araucaria angustifolia trees.
ISSN:1618-8667
1610-8167
DOI:10.1016/j.ufug.2021.127197