Reprint

UAV Photogrammetry and Remote Sensing

Edited by
July 2021
258 pages
  • ISBN978-3-0365-1454-3 (Hardback)
  • ISBN978-3-0365-1453-6 (PDF)

This is a Reprint of the Special Issue UAV Photogrammetry and Remote Sensing that was published in

Engineering
Environmental & Earth Sciences
Summary

Remote sensing has, until recently, been exclusively focused on the use of Earth observation satellites.The emergence of unmanned aerial vehicles (UAV) with Global Navigation Satellite System (GNSS) controlled navigation and sensor-carrying capabilities has increased the number of publications related to new remote sensing from much closer distances. Previous knowledge about Remote Sensing has been successfully applied to a large amount of data recorded from UAVs. More specifically, the ability of UAVs to be positioned at pre-programmed coordinate points; to track flight paths; and in any case, to record the coordinates and angles of the sensor position at the time of the shot have opened an interesting field of applications for low-altitude aerial photogrammetry, known as UAV photogrammetry. In addition, photogrammetric data processing has been improved thanks to the combination of new algorithms, e.g., structure from motion (SfM), which solves the collinearity equations without the need for any control point, producing a cloud of points referenced to an arbitrary coordinate system and a full camera calibration, and the multi-view stereopsis (MVS) algorithm, which applies an expanding procedure of sparse set of matched keypoints in order to obtain a dense point cloud. The set of technical advances described above allows for geometric modeling of terrain surfaces with high accuracy, minimizing the need for georeferencing of such products. This Special Issue aims to compile some applications realized thanks to the synergies established between new remote sensing from close distances and UAV photogrammetry.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
unmanned aerial vehicle; urban LULC; GEOBIA; multiscale classification; unmanned aircraft system (UAS); deep learning; super-resolution (SR); convolutional neural network (CNN); generative adversarial network (GAN); structure-from-motion; photogrammetry; remote sensing; UAV; photogrammetry; 3D-model; surveying; vertical wall; snow; remotely piloted aircraft systems; structure from motion; lidar; forests; photogrammetry; orthophotography; construction planning; sustainable construction; urbanism; BIM; building maintenance; UAV; unmanned aerial vehicle; unmanned aerial vehicle (UAV); structure-from-motion (SfM); ground control points (GCP); accuracy assessment; point clouds; corridor mapping; UAV photogrammetry; terrain modeling; vegetation removal; deep learning; unmanned aerial vehicles; power lines; image-based reconstruction; 3D reconstruction; unmanned aerial systems; unmanned aerial vehicle; time series; accuracy; reproducibility; orthomosaic; validation; photogrammetry; drone; GNSS RTK; UAV; photogrammetry; precision; accuracy; elevation; multispectral imaging; vegetation indices; nutritional analysis; correlation; photogrammetry; optimal harvest time; UAV; UAV images; monoscopic mapping; stereoscopic plotting; image overlap; optimal image selection; n/a