Hummingbirds rapidly respond to the removal of visible light and control a sequence of rate-commanded escape manoeuvres in milliseconds.

IF 3.8 1区 生物学 Q1 BIOLOGY
Md Zafar Anwar, Bret W Tobalske, Suyash Agrawal, Jean-Michel Mongeau, Haoxiang Luo, Bo Cheng
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引用次数: 0

Abstract

Hummingbirds routinely execute a variety of stunning aerobatic feats, which continue to challenge current notions of aerial agility and controlled stability in biological systems. Indeed, the control of these amazing manoeuvres is not well understood. Here, we examined how hummingbirds control a sequence of manoeuvres within milliseconds, and tested whether and when they use vision during this rapid process. We repeatedly elicited escape flights in calliope hummingbirds, removed visible light during each manoeuvre at various instants and quantified their flight kinematics and responses. We show that the escape manoeuvres were composed of rapidly controlled sequential modules including evasion, reorientation, nose-down dive, forward flight and nose-up to hover. The hummingbirds did not respond to the light removal during evasion and reorientation until a critical light-removal time; afterwards, they showed two categories of luminance-based responses that rapidly altered manoeuvring modules to terminate the escape. We also show that hummingbird manoeuvres were rate-commanded and required no active braking (i.e. their body angular velocities were proportional to the change of wing motion patterns, a trait that probably alleviates the computational demand on flight control). This work uncovers key traits of hummingbird agility, which can also inform and inspire designs for next-generation agile aerial systems.

蜂鸟对可见光的消失迅速做出反应,并在几毫秒内控制一连串以速率为指令的逃逸动作。
蜂鸟经常做出各种令人惊叹的特技飞行动作,这些动作不断挑战着当前关于空中灵活性和生物系统可控稳定性的概念。事实上,人们对这些惊人动作的控制并不十分了解。在这里,我们研究了蜂鸟如何在几毫秒内控制一连串的动作,并测试了蜂鸟在这一快速过程中是否以及何时使用视觉。我们反复诱导蜂鸟进行逃逸飞行,在每个动作的不同时刻移除可见光,并对它们的飞行运动学和反应进行量化。结果表明,蜂鸟的逃逸动作由快速控制的连续模块组成,包括躲避、调整方向、机头向下俯冲、向前飞行和机头向上盘旋。蜂鸟在躲避和调整方向的过程中不会对光的消失做出反应,直到光消失的临界时间;之后,蜂鸟会表现出两类基于亮度的反应,迅速改变操纵模块以终止逃逸。我们还发现,蜂鸟的机动是由速率指令控制的,不需要主动制动(即蜂鸟的身体角速度与翅膀运动模式的变化成正比,这一特性可能减轻了飞行控制的计算需求)。这项工作揭示了蜂鸟敏捷性的关键特征,也为下一代敏捷航空系统的设计提供了信息和灵感。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.90
自引率
4.30%
发文量
502
审稿时长
1 months
期刊介绍: Proceedings B is the Royal Society’s flagship biological research journal, accepting original articles and reviews of outstanding scientific importance and broad general interest. The main criteria for acceptance are that a study is novel, and has general significance to biologists. Articles published cover a wide range of areas within the biological sciences, many have relevance to organisms and the environments in which they live. The scope includes, but is not limited to, ecology, evolution, behavior, health and disease epidemiology, neuroscience and cognition, behavioral genetics, development, biomechanics, paleontology, comparative biology, molecular ecology and evolution, and global change biology.
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