Abstract
Dense three-dimensional (3D) point cloud data sets generated by Terrestrial Laser Scanning (TLS) and Unmanned Aircraft System based Structure-from-Motion (UAS-SfM) photogrammetry have different characteristics and provide different representations of the underlying land cover. While there are differences, a common challenge associated with these technologies is how to best take advantage of these large data sets, often several hundred million points, to efficiently extract relevant information. Given their size and complexity, the data sets cannot be efficiently and consistently separated into homogeneous features without the use of automated segmentation algorithms. This research aims to evaluate the performance and generalizability of an unsupervised clustering method, originally developed for segmentation of TLS point cloud data in marshes, by extending it to UAS-SfM point clouds. The combination of two sets of features are extracted from both datasets: “core” features that can be extracted from any 3D point cloud and “sensor specific” features unique to the imaging modality. Comparisons of segmented results based on producer’s and user’s accuracies allow for identifying the advantages and limitations of each dataset and determining the generalization of the clustering method. The producer’s accuracies suggest that UAS-SfM (94.7%) better represents tidal flats, while TLS (99.5%) is slightly more suitable for vegetated areas. The users’ accuracies suggest that UAS-SfM outperforms TLS in vegetated areas with 98.6% of those points identified as vegetation actually falling in vegetated areas whereas TLS outperforms UAS-SfM in tidal flat areas with 99.2% user accuracy. Results demonstrate that the clustering method initially developed for TLS point cloud data transfers well to UAS-SfM point cloud data to enable consistent and accurate segmentation of marsh land cover via an unsupervised method.
Highlights
Given the level of precision required to measure minute changes in marsh elevation over time, survey methods have to be adapted to improve the measurements’ accuracy while minimizing the impact on the marsh itself
Geodetic remote sensing techniques based on lidar, such as Airborne Lidar Scanning (ALS) or Terrestrial Laser Scanning (TLS), employ active laser ranging to provide a dense sampling of the terrain and land cover
Three-dimensional point clouds of a marsh environment produced with TLS and Unmanned Aircraft System based Structure-from-Motion (UAS-SfM) were partitioned using an unsupervised clustering method
Summary
Given the level of precision required to measure minute changes in marsh elevation over time, survey methods have to be adapted to improve the measurements’ accuracy while minimizing the impact on the marsh itself. Spatial characterization of marsh surface elevation change is typically based on intensive field surveys of relatively small areas. Examples of such techniques include a surface elevation table (SET), which can provide a very precise and accurate measurement of sediment elevation (cm to mm scale) in wetlands [1,2]. Geodetic remote sensing techniques based on lidar, such as Airborne Lidar Scanning (ALS) or Terrestrial Laser Scanning (TLS), employ active laser ranging to provide a dense sampling of the terrain and land cover. Three-dimensional (3D) point cloud data produced by these various scanning methods will provide a different representation of the underlying terrain and land cover. The resultant point cloud data can be used to geometrically characterize marsh topography and land cover features based on this representation. Numerous studies have demonstrated this potential with airborne lidar data [3,4,5,6]
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