拍打
翼
运动学
鸟类飞行
机器人
地面运动
计算机科学
水下
模拟
声学
刚度
海洋工程
仿生学
地质学
航空航天工程
折叠(DSP实现)
平衡(能力)
微型飞行器
攻角
物理
动平衡
昆虫飞行
工程类
推进
控制理论(社会学)
作者
Raphael Zufferey,Simon Jeger,Moritz Hüsser,Fernando Ruíz,Anthony B. Lapsansky,Auke Jan Ijspeert,Dario Floreano
出处
期刊:Science
[American Association for the Advancement of Science]
日期:2026-07-09
卷期号:393 (6807): 207-211
标识
DOI:10.1126/science.aeb6744
摘要
Wing-propelled diving birds flap their wings to move through air and water, yet the wing morphology and kinematics that enable this behavior remain poorly understood because of the difficulty of collecting in situ data. The impact of flapping frequency, wing size, and stiffness on locomotion in-and transition between-the two media are still unknown. We compared data from diving birds against experiments using a flapping-wing robot capable of flying, swimming, plunge diving, and exiting the water. We show that frequency adaptation, flexible wings, and powerful actuation enable seamless transitions without folding wings or legs, that large wings enhance flight without substantially reducing underwater efficiency, and that tail-body distance and egress angle affect water exit. These results clarify how birds (and robots) balance multifluid locomotion constraints.
科研通智能强力驱动
Strongly Powered by AbleSci AI