Electronic versions

  • Danilo Roberti Alves de Almeida
    University of Sao PauloUniversity of Florida
  • Eben North Broadbent
    University of Florida
  • Matheus Pinheiro Ferreira
    Military Institute of Engineering (IME)
  • Paula Meli
    Universidad de La Frontera
  • Angelica Maria Almeyda Zambrano
    University of Florida
  • Eric Bastos Gorgens
    Federal University of Jequitinhonha and Mucuri Valleys
  • Angelica Faria Resende
    University of Sao Paulo
  • Catherine Torres de Almeida
    University of Sao Paulo
  • Cibele Hummel do Amaral
    Federal University of Viçosa
  • Ana Paula Dalla Corte
    Federal University of Paraná
  • Carlos Alberto Silva
    University of Florida
  • João P. Romanelli
    University of Florida
  • Gabriel Atticciati Prata
    University of Florida
  • Daniel de Almeida Papa
    Embrapa Acre
  • Scott C. Stark
    Michigan State University
  • Ruben Valbuena
  • Bruce Walker Nelson
    National Institute for Amazon Research (INPA)
  • Joannes Guillemot
    University of Sao Paulo
  • Jean-Baptiste Féret
    Université de Montpellier
  • Robin Chazdon
    University of the Sunshine Coast
  • Pedro H.S. Brancalion
    University of Sao Paulo
Remote sensors, onboard orbital platforms, aircraft, or unmanned aerial vehicles (UAVs) have emerged as a promising technology to enhance our understanding of changes in ecosystem composition, structure, and function of forests, offering multi-scale monitoring of forest restoration. UAV systems can generate high-resolution images that provide accurate information on forest ecosystems to aid decision-making in restoration projects. However, UAV technological advances have outpaced practical application; thus, we explored combining UAV-borne lidar and hyperspectral data to evaluate the diversity and structure of restoration plantings. We developed novel analytical approaches to assess twelve 13-year-old restoration plots experimentally established with 20, 60 or 120 native tree species in the Brazilian Atlantic Forest. We assessed (1) the congruence and complementarity of lidar and hyperspectral-derived variables, (2) their ability to distinguish tree richness levels and (3) their ability to predict aboveground biomass (AGB). We analyzed three structural attributes derived from lidar data—canopy height, leaf area index (LAI), and understory LAI—and eighteen variables derived from hyperspectral data—15 vegetation indices (VIs), two components of the minimum noise fraction (related to spectral composition) and the spectral angle (related to spectral variability). We found that VIs were positively correlated with LAI for low LAI values, but stabilized for LAI greater than 2 m2/m2. LAI and structural VIs increased with increasing species richness, and hyperspectral variability was significantly related to species richness. While lidar-derived canopy height better predicted AGB than hyperspectral-derived VIs, it was the fusion of UAV-borne hyperspectral and lidar data that allowed effective co-monitoring of both forest structural attributes and tree diversity in restoration plantings. Furthermore, considering lidar and hyperspectral data together more broadly supported the expectations of biodiversity theory, showing that diversity enhanced biomass capture and canopy functional attributes in restoration. The use of UAV-borne remote sensors can play an essential role during the UN Decade of Ecosystem Restoration, which requires detailed forest monitoring on an unprecedented scale.

Keywords

  • Forest landscape restoration, Tropical forests, Drones, Lidar remote sensing, Hyperspectral remote sensing, Leaf area density, Vegetation indices
Original languageEnglish
Article number112582
Number of pages1
JournalRemote Sensing of Environment
Volume264
Early online date23 Jul 2021
DOIs
Publication statusPublished - Oct 2021

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