Abstract
Abstract. Unmanned aerial vehicle laser scanning (ULS) has recently become available for operational mapping and monitoring (e.g. for forestry applications or erosion studies). It combines advantages of terrestrial and airborne laser scanning, but there is still little proof of ULS accuracy. For the detection and monitoring of small-magnitude surfaces changes with multitemporal point clouds, an estimate of the level of detection (LOD) is required. The LOD is a threshold applied on distance measurements to separate real surface change (e.g. due to erosion or deposition by geomorphic processes) from errors. This paper investigates key components of the error budget for two ULS point clouds acquired for erosion monitoring at a grassland site in the Alps. In addition to the registration error and effects of the local surface roughness, we assess the positional uncertainties of each point that result from laser footprint effects, which are a function of the scanning geometry (including range, incidence angle and beam divergence). By removing erroneous points with an increasingly stricter point error criterion, we illustrate that the positional point errors strongly affect the LOD and discuss how this type of error can be mitigated. Moreover, our experimental results with three different surface classes (bare earth and rock, buildings and grassland) show that the level of detection tends to be slightly better for areas with bare earth and rock than for grass-covered areas (due to their roughness). For all these surface types reliable distance measurements are possible with sub-decimetre levels of detection.
Highlights
Today, laser scanning is an operational method in environmental monitoring and geomorphic applications (e.g. Höfle and Rutzinger, 2011; Telling et al, 2017; Hooke, 2020)
This paper demonstrates the estimation of an level of detection (LOD) for unmanned aerial vehicle laser scanning (ULS) point clouds for an Alpine grassland site, aiming to assess the suitability of ULS data for shallow erosion studies
The presented study shows that sub-decimetre 3D change detection by multitemporal unmanned aerial vehicle laser scanning (ULS) is feasible over areas with tens hectares and with complex terrain
Summary
Laser scanning is an operational method in environmental monitoring and geomorphic applications (e.g. Höfle and Rutzinger, 2011; Telling et al, 2017; Hooke, 2020). The striking advantage of ULS is that it can acquire detailed data of larger areas with a minimum of flight strips and with better viewing angles, smaller ranges (and smaller footprint sizes), more homogeneous point distributions and less object shadow effects compared to TLS. For the detection and monitoring of small-magnitude surfaces changes with multitemporal ULS point clouds, an estimate of the level of detection (LOD) is required. This LOD can be applied as a threshold on distance measurements to separate systematic errors and noise from actual changes and, obtain more reliable estimates for geomorphic process magnitudes and frequencies The determination of LODs requires detailed knowledge of the error budgets of acquired data sets (Schär et al, 2007; Glennie, 2007)
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