Avian surface reconstruction in free flight with application to flight stability analysis of a barn owl and peregrine falcon

Birds primarily create and control the forces necessary for flight through changing the shape and orientation of their wings and tail. Their wing geometry is characterised by complex variation in parameters such as camber, twist, sweep and dihedral. To characterise this complexity, a multi-view ster...

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Bibliographic Details
Published in:Journal of Experimental Biology
Main Authors: Durston, NE, Wan, X, Liu, WG, Windsor, SP
Format: Article in Journal/Newspaper
Language:English
Published: Company of Biologists 2019
Subjects:
Science & Technology
Life Sciences & Biomedicine
Biology
Life Sciences & Biomedicine - Other Topics
Bird flight
Stereo-photogrammetry
Flight dynamics
Flight control
Wing geometry
Tyto alba
Falco peregrinus
DELTA-WING THEORY
GLIDING FLIGHT
ANIMAL FLIGHT
BIRDS TAILS
AERODYNAMICS
BIOPHYSICS
KINEMATICS
DYNAMICS
PREDICT
SPAN
06 Biological Sciences
11 Medical and Health Sciences
Physiology
Camber
peregrine falcon
Online Access:http://hdl.handle.net/10044/1/71955
https://doi.org/10.1242/jeb.185488
id ftimperialcol:oai:spiral.imperial.ac.uk:10044/1/71955
record_format openpolar
spelling ftimperialcol:oai:spiral.imperial.ac.uk:10044/1/71955 2023-05-15T16:09:55+02:00 Avian surface reconstruction in free flight with application to flight stability analysis of a barn owl and peregrine falcon Durston, NE Wan, X Liu, WG Windsor, SP 2019-03-21 http://hdl.handle.net/10044/1/71955 https://doi.org/10.1242/jeb.185488 English eng Company of Biologists Journal of Experimental Biology 0022-0949 http://hdl.handle.net/10044/1/71955 https://doi.org/10.1242/jeb.185488 © 2019. Published by The Company of Biologists Ltd. Science & Technology Life Sciences & Biomedicine Biology Life Sciences & Biomedicine - Other Topics Bird flight Stereo-photogrammetry Flight dynamics Flight control Wing geometry Tyto alba Falco peregrinus DELTA-WING THEORY GLIDING FLIGHT ANIMAL FLIGHT BIRDS TAILS AERODYNAMICS BIOPHYSICS KINEMATICS DYNAMICS PREDICT SPAN 06 Biological Sciences 11 Medical and Health Sciences Physiology Journal Article 2019 ftimperialcol https://doi.org/10.1242/jeb.185488 2020-05-14T22:38:22Z Birds primarily create and control the forces necessary for flight through changing the shape and orientation of their wings and tail. Their wing geometry is characterised by complex variation in parameters such as camber, twist, sweep and dihedral. To characterise this complexity, a multi-view stereo-photogrammetry setup was developed for accurately measuring surface geometry in high resolution during free flight. The natural patterning of the birds was used as the basis for phase correlation-based image matching, allowing indoor or outdoor use while being non-intrusive for the birds. The accuracy of the method was quantified and shown to be sufficient for characterising the geometric parameters of interest, but with a reduction in accuracy close to the wing edge and in some localised regions. To demonstrate the method's utility, surface reconstructions are presented for a barn owl (Tyto alba) and peregrine falcon (Falco peregrinus) during three instants of gliding flight per bird. The barn owl flew with a consistent geometry, with positive wing camber and longitudinal anhedral. Based on flight dynamics theory, this suggests it was longitudinally statically unstable during these flights. The peregrine falcon flew with a consistent glide angle, but at a range of air speeds with varying geometry. Unlike the barn owl, its glide configuration did not provide a clear indication of longitudinal static stability/instability. Aspects of the geometries adopted by both birds appeared to be related to control corrections and this method would be well suited for future investigations in this area, as well as for other quantitative studies into avian flight dynamics. Article in Journal/Newspaper Falco peregrinus peregrine falcon Imperial College London: Spiral Camber ENVELOPE(-63.300,-63.300,-64.680,-64.680) Journal of Experimental Biology 222 9
institution Open Polar
collection Imperial College London: Spiral
op_collection_id ftimperialcol
language English
topic Science & Technology
Life Sciences & Biomedicine
Biology
Life Sciences & Biomedicine - Other Topics
Bird flight
Stereo-photogrammetry
Flight dynamics
Flight control
Wing geometry
Tyto alba
Falco peregrinus
DELTA-WING THEORY
GLIDING FLIGHT
ANIMAL FLIGHT
BIRDS TAILS
AERODYNAMICS
BIOPHYSICS
KINEMATICS
DYNAMICS
PREDICT
SPAN
06 Biological Sciences
11 Medical and Health Sciences
Physiology
spellingShingle Science & Technology
Life Sciences & Biomedicine
Biology
Life Sciences & Biomedicine - Other Topics
Bird flight
Stereo-photogrammetry
Flight dynamics
Flight control
Wing geometry
Tyto alba
Falco peregrinus
DELTA-WING THEORY
GLIDING FLIGHT
ANIMAL FLIGHT
BIRDS TAILS
AERODYNAMICS
BIOPHYSICS
KINEMATICS
DYNAMICS
PREDICT
SPAN
06 Biological Sciences
11 Medical and Health Sciences
Physiology
Durston, NE
Wan, X
Liu, WG
Windsor, SP
Avian surface reconstruction in free flight with application to flight stability analysis of a barn owl and peregrine falcon
topic_facet Science & Technology
Life Sciences & Biomedicine
Biology
Life Sciences & Biomedicine - Other Topics
Bird flight
Stereo-photogrammetry
Flight dynamics
Flight control
Wing geometry
Tyto alba
Falco peregrinus
DELTA-WING THEORY
GLIDING FLIGHT
ANIMAL FLIGHT
BIRDS TAILS
AERODYNAMICS
BIOPHYSICS
KINEMATICS
DYNAMICS
PREDICT
SPAN
06 Biological Sciences
11 Medical and Health Sciences
Physiology
description Birds primarily create and control the forces necessary for flight through changing the shape and orientation of their wings and tail. Their wing geometry is characterised by complex variation in parameters such as camber, twist, sweep and dihedral. To characterise this complexity, a multi-view stereo-photogrammetry setup was developed for accurately measuring surface geometry in high resolution during free flight. The natural patterning of the birds was used as the basis for phase correlation-based image matching, allowing indoor or outdoor use while being non-intrusive for the birds. The accuracy of the method was quantified and shown to be sufficient for characterising the geometric parameters of interest, but with a reduction in accuracy close to the wing edge and in some localised regions. To demonstrate the method's utility, surface reconstructions are presented for a barn owl (Tyto alba) and peregrine falcon (Falco peregrinus) during three instants of gliding flight per bird. The barn owl flew with a consistent geometry, with positive wing camber and longitudinal anhedral. Based on flight dynamics theory, this suggests it was longitudinally statically unstable during these flights. The peregrine falcon flew with a consistent glide angle, but at a range of air speeds with varying geometry. Unlike the barn owl, its glide configuration did not provide a clear indication of longitudinal static stability/instability. Aspects of the geometries adopted by both birds appeared to be related to control corrections and this method would be well suited for future investigations in this area, as well as for other quantitative studies into avian flight dynamics.
format Article in Journal/Newspaper
author Durston, NE
Wan, X
Liu, WG
Windsor, SP
author_facet Durston, NE
Wan, X
Liu, WG
Windsor, SP
author_sort Durston, NE
title Avian surface reconstruction in free flight with application to flight stability analysis of a barn owl and peregrine falcon
title_short Avian surface reconstruction in free flight with application to flight stability analysis of a barn owl and peregrine falcon
title_full Avian surface reconstruction in free flight with application to flight stability analysis of a barn owl and peregrine falcon
title_fullStr Avian surface reconstruction in free flight with application to flight stability analysis of a barn owl and peregrine falcon
title_full_unstemmed Avian surface reconstruction in free flight with application to flight stability analysis of a barn owl and peregrine falcon
title_sort avian surface reconstruction in free flight with application to flight stability analysis of a barn owl and peregrine falcon
publisher Company of Biologists
publishDate 2019
url http://hdl.handle.net/10044/1/71955
https://doi.org/10.1242/jeb.185488
long_lat ENVELOPE(-63.300,-63.300,-64.680,-64.680)
geographic Camber
geographic_facet Camber
genre Falco peregrinus
peregrine falcon
genre_facet Falco peregrinus
peregrine falcon
op_relation Journal of Experimental Biology
0022-0949
http://hdl.handle.net/10044/1/71955
https://doi.org/10.1242/jeb.185488
op_rights © 2019. Published by The Company of Biologists Ltd.
op_doi https://doi.org/10.1242/jeb.185488
container_title Journal of Experimental Biology
container_volume 222
container_issue 9
_version_ 1765995175055720448

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