Abstract
This study investigates the potential of unmanned aerial vehicles (UAVs) to measure and monitor structural properties of forests. Two remote sensing techniques, airborne laser scanning (ALS) and structure from motion (SfM) were tested to capture three-dimensional structural information from a small multi-rotor UAV platform. A case study is presented through the analysis of data collected from a 30 × 50 m plot in a dry sclerophyll eucalypt forest with a spatially varying canopy cover. The study provides an insight into the capabilities of both technologies for assessing absolute terrain height, the horizontal and vertical distribution of forest canopy elements, and information related to individual trees. Results indicate that both techniques are capable of providing information that can be used to describe the terrain surface and canopy properties in areas of relatively low canopy closure. However, the SfM photogrammetric technique underperformed ALS in capturing the terrain surface under increasingly denser canopy cover, resulting in point density of less than 1 ground point per m2 and mean difference from ALS terrain surface of 0.12 m. This shortcoming caused errors that were propagated into the estimation of canopy properties, including the individual tree height (root mean square error of 0.92 m for ALS and 1.30 m for SfM). Differences were also seen in the estimates of canopy cover derived from the SfM (50%) and ALS (63%) pointclouds. Although ALS is capable of providing more accurate estimates of the vertical structure of forests across the larger range of canopy densities found in this study, SfM was still found to be an adequate low-cost alternative for surveying of forest stands.
Highlights
Forest structure refers to the spatial arrangement of the components of a forest ecosystem, and describes properties such as the horizontal and vertical distribution and abundance of vegetative elements [1]
The objective of this study is to provide a comparison of airborne laser scanning (ALS) and structure from motion (SfM) point clouds captured from a small-unmanned aerial vehicles (UAVs) platform across a case study forest plot with varying levels of canopy cover
This study demonstrates that two 3D point cloud techniques, Structure-from-Motion (SfM) and airborne laser scanning (ALS), deployed on-board a mini-unmanned aerial vehicle are capable of detailed 3D mapping of forested landscape features
Summary
Forest structure refers to the spatial arrangement of the components of a forest ecosystem, and describes properties such as the horizontal and vertical distribution and abundance of vegetative elements [1]. Capturing the variability of structural properties across a forested landscape has conventionally employed on-ground measurements conducted within a small set of sample plots. These measurements are, labour intensive and their ability to characterise. Remote sensing can complement existing ground-based techniques, providing spatially representative characteristics of investigated forest stands in a more efficient manner. Data captured over varying spatial, spectral, and temporal scales has been shown to contain information, which can be used to measure and monitor various aspects of a complex forest structure [4,5,6]. Advances in acquisition of this information have led to high spatial resolution three-dimensional (3D) remote sensing becoming an important tool in forest modelling [5,6,7,8,9]
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