Birds both avoid and control collisions by harnessing visually guided force vectoring

Diana D. Chin; David Lentink

doi:10.1098/rsif.2021.0947

Birds both avoid and control collisions by harnessing visually guided force vectoring

Diana D. Chin^*, David Lentink^*

^*Corresponding author for this work

Biomimetics

Research output: Contribution to journal › Article › Academic › peer-review

2 Citations (Scopus)

89 Downloads (Pure)

Abstract

Birds frequently manoeuvre around plant clutter in complex-structured habitats. To understand how they rapidly negotiate obstacles while flying between branches, we measured how foraging Pacific parrotlets avoid horizontal strings obstructing their preferred flight path. Informed by visual cues, the birds redirect forces with their legs and wings to manoeuvre around the obstacle and make a controlled collision with the goal perch. The birds accomplish aerodynamic force vectoring by adjusting their body pitch, stroke plane angle and lift-to-drag ratios beat-by-beat, resulting in a range of about 100° relative to the horizontal plane. The key role of drag in force vectoring revises earlier ideas on how the avian stroke plane and body angle correspond to aerodynamic force direction-providing new mechanistic insight into avian manoeuvring-and how the evolution of flight may have relied on harnessing drag.

Original language	English
Article number	20210947
Journal	Journal of the Royal Society Interface
Volume	19
Issue number	191
DOIs	https://doi.org/10.1098/rsif.2021.0947
Publication status	Published - 15-Jun-2022

Keywords

Bird flight
Drag-based flight
Force vectoring
Obstacle avoidance
Visual control

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10.1098/rsif.2021.0947

Birds both avoid and control collisions by harnessing visually guided force vectoringFinal publisher's version, 2.67 MBLicence: Taverne

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title = "Birds both avoid and control collisions by harnessing visually guided force vectoring",

abstract = "Birds frequently manoeuvre around plant clutter in complex-structured habitats. To understand how they rapidly negotiate obstacles while flying between branches, we measured how foraging Pacific parrotlets avoid horizontal strings obstructing their preferred flight path. Informed by visual cues, the birds redirect forces with their legs and wings to manoeuvre around the obstacle and make a controlled collision with the goal perch. The birds accomplish aerodynamic force vectoring by adjusting their body pitch, stroke plane angle and lift-to-drag ratios beat-by-beat, resulting in a range of about 100° relative to the horizontal plane. The key role of drag in force vectoring revises earlier ideas on how the avian stroke plane and body angle correspond to aerodynamic force direction-providing new mechanistic insight into avian manoeuvring-and how the evolution of flight may have relied on harnessing drag.",

keywords = "Bird flight, Drag-based flight, Force vectoring, Obstacle avoidance, Visual control",

author = "Chin, \{Diana D.\} and David Lentink",

note = "Funding Information: This work was supported by NSF Faculty Early Career Development (CAREER) Award 1552419 and the Human Frontier Science Program. D.D.C. was supported by a Stanford Graduate Fellowship and a National Defense Science and Engineering Graduate Fellowship. Acknowledgements Publisher Copyright: {\textcopyright} 2022 Royal Society Publishing. All rights reserved.",

year = "2022",

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doi = "10.1098/rsif.2021.0947",

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AU - Chin, Diana D.

AU - Lentink, David

N1 - Funding Information: This work was supported by NSF Faculty Early Career Development (CAREER) Award 1552419 and the Human Frontier Science Program. D.D.C. was supported by a Stanford Graduate Fellowship and a National Defense Science and Engineering Graduate Fellowship. Acknowledgements Publisher Copyright: © 2022 Royal Society Publishing. All rights reserved.

PY - 2022/6/15

Y1 - 2022/6/15

N2 - Birds frequently manoeuvre around plant clutter in complex-structured habitats. To understand how they rapidly negotiate obstacles while flying between branches, we measured how foraging Pacific parrotlets avoid horizontal strings obstructing their preferred flight path. Informed by visual cues, the birds redirect forces with their legs and wings to manoeuvre around the obstacle and make a controlled collision with the goal perch. The birds accomplish aerodynamic force vectoring by adjusting their body pitch, stroke plane angle and lift-to-drag ratios beat-by-beat, resulting in a range of about 100° relative to the horizontal plane. The key role of drag in force vectoring revises earlier ideas on how the avian stroke plane and body angle correspond to aerodynamic force direction-providing new mechanistic insight into avian manoeuvring-and how the evolution of flight may have relied on harnessing drag.

AB - Birds frequently manoeuvre around plant clutter in complex-structured habitats. To understand how they rapidly negotiate obstacles while flying between branches, we measured how foraging Pacific parrotlets avoid horizontal strings obstructing their preferred flight path. Informed by visual cues, the birds redirect forces with their legs and wings to manoeuvre around the obstacle and make a controlled collision with the goal perch. The birds accomplish aerodynamic force vectoring by adjusting their body pitch, stroke plane angle and lift-to-drag ratios beat-by-beat, resulting in a range of about 100° relative to the horizontal plane. The key role of drag in force vectoring revises earlier ideas on how the avian stroke plane and body angle correspond to aerodynamic force direction-providing new mechanistic insight into avian manoeuvring-and how the evolution of flight may have relied on harnessing drag.

KW - Bird flight

KW - Drag-based flight

KW - Force vectoring

KW - Obstacle avoidance

KW - Visual control

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DO - 10.1098/rsif.2021.0947

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SN - 1742-5689

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JO - Journal of the Royal Society Interface

JF - Journal of the Royal Society Interface

IS - 191

M1 - 20210947

ER -

Birds both avoid and control collisions by harnessing visually guided force vectoring

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