Download
Cite as:
Gonzales-Jaramillo, V.; Fries, A.; Zeilinger, J.; Homeier, J.; Paladines, J. &amp; Bendix, J. (2018): <b>Estimation of Above Ground Biomass in a Tropical Mountain Forest in Southern Ecuador Using Airborne LiDAR Data</b>. <i>Remote Sensing</i> <b>10</b>, .

Resource Description
Title: Estimation of Above Ground Biomass in a Tropical Mountain Forest in Southern Ecuador Using Airborne LiDAR Data
FOR816dw ID: 1708
Publication Date: 2018-04-24
License and Usage Rights:
Resource Owner(s):
Individual: Victor Gonzales-Jaramillo
Contact:
Individual: Andreas Fries
Contact:
Individual: Joerg Zeilinger
Contact:
Individual: Jürgen Homeier
Contact:
Individual: Jhoana Paladines
Contact:
Individual: Jörg Bendix
Contact:
Abstract:
A reliable estimation of Above Ground Biomass (AGB) in Tropical Mountain Forest (TMF)<br/> is still complicated, due to fast-changing climate and topographic conditions, which modifies the<br/> forest structure within fine scales. The variations in vertical and horizontal forest structure are hardly<br/> detectable by small field plots, especially in natural TMF due to the high tree diversity and the<br/> inaccessibility of remote areas. Therefore, the present approach used remotely sensed data from a<br/> Light Detection and Ranging (LiDAR) sensor in combination with field measurements to estimate<br/> AGB accurately for a catchment in the Andes of south-eastern Ecuador. From the LiDAR data,<br/> information about horizontal and vertical structure of the TMF could be derived and the vegetation at<br/> tree level classified, differentiated between the prevailing forest types (ravine forest, ridge forest and<br/> Elfin Forest). Furthermore, topographical variables (Topographic Position Index, TPI; Morphometric<br/> Protection Index, MPI) were calculated by means of the high-resolution LiDAR data to analyse the<br/> AGB distribution within the catchment. The field measurements included different tree parameters<br/> of the species present in the plots, which were used to determine the local mean Wood Density<br/> (WD) as well as the specific height-diameter relationship to calculate AGB, applying regional scale<br/> modelling at tree level. The results confirmed that field plot measurements alone cannot capture<br/> completely the forest structure in TMF but in combination with high resolution LiDAR data, applying<br/> a classification at tree level, the AGB amount (Mg ha??1) and its distribution in the entire catchment<br/> could be estimated adequately (model accuracy at tree level: R2 > 0.91). It was found that the AGB<br/> distribution is strongly related to ridges and depressions (TPI) and to the protection of the site (MPI),<br/> because high AGB was also detected at higher elevations (up to 196.6 Mg ha??1, above 2700 m), if the<br/> site is situated in depressions (ravine forest) and protected by the surrounding terrain. In general,<br/> highest AGB is stored in the protected ravine TMF parts, also at higher elevations, which could only<br/> be detected by means of the remote sensed data in high resolution, because most of these areas are<br/> inaccessible. Other vegetation units, present in the study catchment (pasture and subpáramo) do not<br/> contain large AGB stocks, which underlines the importance of intact natural forest stands.
Keywords:
| LiDAR | AGB estimation |
Literature type specific fields:
ARTICLE
Journal: Remote Sensing
Volume: 10
Page Range:
Metadata Provider:
Individual: Jörg Bendix
Contact:
Online Distribution:
Download File: http://www.tropicalmountainforest.org/publications.do?citid=1708


Quick search

  • Publications:
  • Datasets:

Keywords:

Datasets: / Publications:
Andes Biodiversity Birds climate change ECSF Ecuador elevational gradient land use change Newsletter nitrogen NUMEX Oribatids Paramo phosphorus reforestation remote sensing South Ecuador Tabebuia Bulletins tree growth tropical montane forest

rnse logo
TMFdw raster engine

rnse logo

Radar Network Ecuador - Peru