Aerial photogrammetry of seabirds from digital aerial video images using relative change in size to estimate flight height

Calculating the height at which birds fly over the sea is a challenging task, but remains important to assessing collision risk in proposed offshore wind farm areas for consenting purposes. This could be done by several methods (e.g. GPS or laser rangefinders), but each have biases that make it diff...

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Bibliographic Details
Published in:Marine biology 2023-02, Vol.170 (2), p.18, Article 18
Main Authors: Humphries, Grant R. W., Fail, Tom, Watson, Megan, Houghton, Wil, Peters-Grundy, Ruth, Scott, Martin, Thomson, Rory, Keogan, Katharine, Webb, Andy
Format: Article
Language:English
Subjects:
Aerial photogrammetry
Aerial photography
Aerial surveying
Aerial surveys
Air gaps
Aquatic birds
Behavior
Biological research
Biology, Experimental
Biomedical and Life Sciences
Birds
Buildings and facilities
Collision mortality
Digital imaging
Digital video
Dimensions
Distribution
Flight
Freshwater & Marine Ecology
Height
Laser range finders
Lasers
Lidar
Life Sciences
Marine & Freshwater Sciences
Marine biology
Marine ecosystems
Methods
Microbiology
Oceanography
Offshore
Offshore energy sources
Original Paper
Photogrammetry
Protection and preservation
Risk assessment
Sea birds
Sea surface
Seabirds
Spatial distribution
Turbines
Wind
Wind farms
Wind power
Zoology
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Summary:Calculating the height at which birds fly over the sea is a challenging task, but remains important to assessing collision risk in proposed offshore wind farm areas for consenting purposes. This could be done by several methods (e.g. GPS or laser rangefinders), but each have biases that make it difficult to generate site-wide assessments. Digital video aerial surveys, which quickly cover large areas, were used to assess flight heights of northern gannets and black-legged kittiwakes using a photogrammetric technique combined with a semi-automated measurement tool. The lengths of birds known to be at sea surface, as identified by reflection on the water, were compared to lengths of birds at unknown height to generate individual flight height profiles. Validation of the method on kittiwake found that LiDAR produced mean flights that were not significantly different to the photogrammetry approach. Validation of the flight height method using man-made objects of known dimensions and heights suggested a 9–18% error (3–6 m at ~ 30 m height). However, the profiles of mean flight height distribution matched patterns in previous work. This method was able to estimate the flying heights of 65% and 75% of flying gannets and kittiwakes, respectively, in this case study. The annual percentage of gannets at collision risk height for a set of turbines with a 30 m air gap was estimated at 29.8%, and 16.1% for kittiwake. This technique can greatly improve our knowledge of the spatial distribution of flight height patterns in marine ecosystems, but also allows stakeholders to assess collision risk more easily within the sphere of offshore wind for the consenting process.
ISSN:0025-3162
1432-1793
DOI:10.1007/s00227-022-04161-5