Development and testing of a UAV laser scanner and multispectral camera system for eco-geomorphic applications
Development and testing of a UAV laser scanner and multispectral camera system for eco-geomorphic applications
While Uncrewed Aerial Vehicle (UAV) systems and camera sensors are routinely deployed in conjunction with Structure from Motion (SfM) techniques to derive 3D models of fluvial systems, in the presence of vegetation these techniques are subject to large errors. This is because of the high structural complexity of vegetation and inability of processing techniques to identify bare earth points in vegetated areas. Furthermore, for eco-geomorphic applications where characterization of the vegetation is an important aim when collecting fluvial survey data, the issues are compounded, and an alternative survey method is required. Laser Scanning techniques have been shown to be a suitable technique for discretizing both bare earth and vegetation, owing to the high spatial density of collected data and the ability of some systems to deliver dual (e.g., first and last) returns. Herein we detail the development and testing of a UAV mounted LiDAR and Multispectral camera system and processing workflow, with application to a specific river field location and reference to eco-hydraulic research generally. We show that the system and data processing workflow has the ability to detect bare earth, vegetation structure and NDVI type outputs which are superior to SfM outputs alone, and which are shown to be more accurate and repeatable, with a level of detection of under 0.1 m. These characteristics of the developed sensor package and workflows offer great potential for future eco-geomorphic research.
Tomsett, Christopher
5b0ab386-98e3-4ba9-bca6-41f058a3ad0e
Leyland, Julian
6b1bb9b9-f3d5-4f40-8dd3-232139510e15
19 November 2021
Tomsett, Christopher
5b0ab386-98e3-4ba9-bca6-41f058a3ad0e
Leyland, Julian
6b1bb9b9-f3d5-4f40-8dd3-232139510e15
Tomsett, Christopher and Leyland, Julian
(2021)
Development and testing of a UAV laser scanner and multispectral camera system for eco-geomorphic applications.
Sensors, 21 (22).
(doi:10.3390/s21227719).
Abstract
While Uncrewed Aerial Vehicle (UAV) systems and camera sensors are routinely deployed in conjunction with Structure from Motion (SfM) techniques to derive 3D models of fluvial systems, in the presence of vegetation these techniques are subject to large errors. This is because of the high structural complexity of vegetation and inability of processing techniques to identify bare earth points in vegetated areas. Furthermore, for eco-geomorphic applications where characterization of the vegetation is an important aim when collecting fluvial survey data, the issues are compounded, and an alternative survey method is required. Laser Scanning techniques have been shown to be a suitable technique for discretizing both bare earth and vegetation, owing to the high spatial density of collected data and the ability of some systems to deliver dual (e.g., first and last) returns. Herein we detail the development and testing of a UAV mounted LiDAR and Multispectral camera system and processing workflow, with application to a specific river field location and reference to eco-hydraulic research generally. We show that the system and data processing workflow has the ability to detect bare earth, vegetation structure and NDVI type outputs which are superior to SfM outputs alone, and which are shown to be more accurate and repeatable, with a level of detection of under 0.1 m. These characteristics of the developed sensor package and workflows offer great potential for future eco-geomorphic research.
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sensors-21-07719-v3
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Accepted/In Press date: 11 November 2021
Published date: 19 November 2021
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Local EPrints ID: 455696
URI: http://eprints.soton.ac.uk/id/eprint/455696
ISSN: 1424-8220
PURE UUID: 4d2cd8bd-052b-4a2a-b7ea-e8b32a468cb6
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Date deposited: 30 Mar 2022 16:59
Last modified: 17 Mar 2024 04:10
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Christopher Tomsett
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