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Signatures of Motion: Decomposition of Adaptive Morphing Flight in Harris’ Hawks
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ABSTRACTBirds outperform engineered aircraft with exceptional maneuverability, achieved by continuously morphing their wings and tails in flight. Yet the coordination and control of these shape changes remain poorly understood. Using high-speed motion capture of Harris’ hawks, we analyzed 289,000 wing-tail configurations in over 2000 flights and identified four fundamental shape change patterns, or “morphing shape modes”, that capture over 96% of wing and tail variation. Further modes reflect subtle but critical fine-tuning, in line with known morphing control mechanics. The hawks’ morphing flight is highly structured yet flexible, and we find adaptive strategies in response to obstacles, added weight, with maturity, while each individual shows unique morphing signatures. Our approach defines a shared kinematic morphospace for hawk flight, and more broadly a framework that enables future comparative biomechanics, bio-inspired design, and for interpreting high-dimensional natural motion.
Cold Spring Harbor Laboratory
Title: Signatures of Motion: Decomposition of Adaptive Morphing Flight in Harris’ Hawks
Description:
ABSTRACTBirds outperform engineered aircraft with exceptional maneuverability, achieved by continuously morphing their wings and tails in flight.
Yet the coordination and control of these shape changes remain poorly understood.
Using high-speed motion capture of Harris’ hawks, we analyzed 289,000 wing-tail configurations in over 2000 flights and identified four fundamental shape change patterns, or “morphing shape modes”, that capture over 96% of wing and tail variation.
Further modes reflect subtle but critical fine-tuning, in line with known morphing control mechanics.
The hawks’ morphing flight is highly structured yet flexible, and we find adaptive strategies in response to obstacles, added weight, with maturity, while each individual shows unique morphing signatures.
Our approach defines a shared kinematic morphospace for hawk flight, and more broadly a framework that enables future comparative biomechanics, bio-inspired design, and for interpreting high-dimensional natural motion.
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