Improving UAV‐SfM photogrammetry for modelling high‐relief terrain: Image collection strategies and ground control quantity
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Version: Author's accepted manuscript
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State: Public
Version: Author's accepted manuscript
License: Not specified
Serval ID
serval:BIB_20D9EEA2868E
Type
Article: article from journal or magazin.
Collection
Publications
Institution
Title
Improving UAV‐SfM photogrammetry for modelling high‐relief terrain: Image collection strategies and ground control quantity
Journal
Earth Surface Processes and Landforms
ISSN
0197-9337
1096-9837
1096-9837
Publication state
Published
Issued date
11/2023
Peer-reviewed
Oui
Volume
48
Number
14
Pages
2884-2899
Language
english
Abstract
Image collection strategies and ground control points (GCPs) are of particular importance for uncrewed aerial vehicle combined with Structure-from-Motion (UAV–SfM) photogrammetry, and the generalization of their effects has proved elusive. This study designed various photogrammetric scenarios to investigate the effects of image collection strategies, ground control quantity, and their interaction on digital elevation model (DEM) errors and their spatial structure in high-relief terrain. The results of 1.77 × 105 UAV–SfM scenarios provide insights for improving UAV–SfM practices. A high image capture angle (20–40°) enhances camera calibration quality decreasing the magnitude and spatial correlation of errors. High camera inclination reduces the sensitivity of mean and standard deviation of error to flying height but not the spatial correlation of error. Including additional data (e.g. supplemented convergent images; images captured at multiple flying heights) has only a minor effect if imagery is highly inclined. GCPs provide more effective constraints than image collection strategies. The mean error and standard error decline quickly with a small number of GCPs and then become stable in all scenarios, but the spatial correlation of error can be further improved with increasing GCPs. However, the effects of GCP quantity do interact with image collection strategies. High camera inclination reduces requirements for GCPs, whilst strategies combining different flying heights and image orientations have little effect on necessary GCP quantity. The distribution of GCPs still affects the errors, but the effect of GCP distribution becomes less important with an increase in the number of GCPs. Finally, we show that UAV–SfM photogrammetric quality assessment should routinely assess the spatial dependence of error using a statistic like Moran's I.
Keywords
combination datasets, ground control points, oblique photography, terrain modelling, UAV-SfM photogrammetry
Web of science
Funding(s)
University of Lausanne
Create date
04/10/2023 8:28
Last modification date
05/04/2024 7:14