Creating vegetation density profiles for a diverse range of ecological habitats using terrestrial laser scanning

Abstract: Vegetation structure is an important determinant of species habitats and diversity. It is often represented by simple metrics, such as canopy cover, height and leaf area index, which do not fully capture three-dimensional variations in density. Terrestrial laser scanning (TLS) is a technology that can better capture vegetation structure, but methods developed to process scans have been biased towards forestry applications. The aim of this study was to develop a methodology for processing TLS data to produce ve… Show more

“…Along with information about crown base height of adjacent trees and understory density, such data may provide an indicator for potential (physical) growing space available for regeneration. TLS data can be used to efficiently represent space-occupation (e.g., Seidel et al, 2013), including density profiles (e.g., Ashcroft et al, 2014). A detailed 3D-description of gap shape would also allow the calculation of light availability for any point inside the gap.…”

Describing forest canopy gaps efficiently, accurately, and objectively: New prospects through the use of terrestrial laser scanning

“…Along with information about crown base height of adjacent trees and understory density, such data may provide an indicator for potential (physical) growing space available for regeneration. TLS data can be used to efficiently represent space-occupation (e.g., Seidel et al, 2013), including density profiles (e.g., Ashcroft et al, 2014). A detailed 3D-description of gap shape would also allow the calculation of light availability for any point inside the gap.…”

Describing forest canopy gaps efficiently, accurately, and objectively: New prospects through the use of terrestrial laser scanning

“…However, system-specific challenges remain in survey design, data processing and interpretation. With terrestrial laser scanning in complex environments, line-of-sight obstructions and moving vegetation combined with the spatial characteristics of the point cloud data generates challenges for interpretation and analysis [49,73,74]. While the moving vantage aspect of structure-from-motion data capture means more homogenous data coverage, repeatability of coral reef rugosity measurements were impacted by high habitat complexity, environmental conditions and variation in methods [75].…”

Three-dimensional digital mapping of ecosystems: a new era in spatial ecology

“…The introduction of ALS into phenology monitoring has emerged (Rinaldi et al, 2013), but this technology is often restricted to its inefficiency in the derivations of tree structural variables at fine scales. For fine-scale tree structure representation, static terrestrial LiDAR (also referred to as static terrestrial laser scanning, TLS) mostly capable of characterizing structure details, such as vegetation density profiles (Ashcroft et al, 2014), was attempted to quantify and monitor ecosystem structural dynamics (Eitel et al, 2013). Portillo-Quintero et al (2014) utilized a TLS system to in-situ measure the dynamics of phenology.…”

Reflecting conifer phenology using mobile terrestrial LiDAR: A case study of Pinus sylvestris growing under the Mediterranean climate in Perth, Australia