不对称鳍形改变了远古海洋爬行动物软机器人物理模型的游泳动力学。

IF 3.1 3区 计算机科学 Q1 ENGINEERING, MULTIDISCIPLINARY
Hadrien Sprumont, Federico Allione, Fabian Schwab, Bingcheng Wang, Claudio Mucignat, Ivan Lunati, Torsten Scheyer, Auke Ijspeert, Ardian Jusufi
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引用次数: 0

摘要

动物在陆地、空中和水生环境中进化出了高效的运动能力。在生命的历史长河中,大规模的灭绝消灭了具有特殊 适应能力的独特动物物种,使得古生物学家不得不通过化石分析来重建它们的运动能力。尽管研究取得了进展,但人们对已灭绝的巨型动物(如最成功的海洋爬行动物鱼龙类)如何利用其不同的形态游泳知之甚少。传统的机器人技术难以有效地模仿已灭绝的动物的运动方式,但新兴的软机器人技术领域为克服这一挑战提供了一个很有前途的选择。本文旨在弥合这一差距,结合材料建模和生物力学的物理 实验验证,利用软机器人技术研究 混血龙的运动。本研究中描述的软机器人平台将软体与软气动致动器相结合,通过再现已灭绝的游泳动物产生的俯仰力矩,研究了不对称鳍与浮力之间的相关性。我们对卡索龙、乌塔特龙、混合龙、贵州鱼龙和眼龙尾鳍在水槽中产生的推力和扭矩进行了比较分析。实验结果表明,在贵州鱼龙、杂色龙和乌塔萨龙的模型系统中发现的下螯鳍形状对躯干产生的俯仰力矩产生了明显的腹侧身体俯仰效应,能够减轻动物的非中性浮力。这种身体俯仰控制效应在贵州鱼龙中尤为明显,研究结果表明,贵州鱼龙能够在躯干上产生较高的腹侧俯仰力矩,以补偿其正浮力。相比之下,同螯鳍的形状可能不利于这种浮力补偿,例如,躯干的俯仰控制只能由胸鳍来完成。在测试的尾鳍驱动频率范围内,会产生振荡模式,这反过来又会影响产生的艉轴推力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Asymmetric fin shape changes swimming dynamics of ancient marine reptiles' soft robophysical models.

Animals have evolved highly effective locomotion capabilities in terrestrial, aerial, and aquatic environments. Over life's history, mass extinctions have wiped out unique animal species with specialized adaptations, leaving paleontologists to reconstruct their locomotion through fossil analysis. Despite advancements, little is known about how extinct megafauna, such as the Ichthyosauria one of the most successful lineages of marine reptiles, utilized their varied morphologies for swimming. Traditional robotics struggle to mimic extinct locomotion effectively, but the emerging soft robotics field offers a promising alternative to overcome this challenge. This paper aims to bridge this gap by studyingMixosauruslocomotion with soft robotics, combining material modeling and biomechanics in physical experimental validation. Combining a soft body with soft pneumatic actuators, the soft robotic platform described in this study investigates the correlation between asymmetrical fins and buoyancy by recreating the pitch torque generated by extinct swimming animals. We performed a comparative analysis of thrust and torque generated byCarthorhyncus,Utatsusaurus,Mixosaurus,Guizhouichthyosaurus, andOphthalmosaurustail fins in a flow tank. Experimental results suggest that the pitch torque on the torso generated by hypocercal fin shapes such as found in model systems ofGuizhouichthyosaurus,MixosaurusandUtatsusaurusproduce distinct ventral body pitch effects able to mitigate the animal's non-neutral buoyancy. This body pitch control effect is particularly pronounced inGuizhouichthyosaurus, which results suggest would have been able to generate high ventral pitch torque on the torso to compensate for its positive buoyancy. By contrast, homocercal fin shapes may not have been conducive for such buoyancy compensation, leaving torso pitch control to pectoral fins, for example. Across the range of the actuation frequencies of the caudal fins tested, resulted in oscillatory modes arising, which in turn can affect the for-aft thrust generated.

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来源期刊
Bioinspiration & Biomimetics
Bioinspiration & Biomimetics 工程技术-材料科学:生物材料
CiteScore
5.90
自引率
14.70%
发文量
132
审稿时长
3 months
期刊介绍: Bioinspiration & Biomimetics publishes research involving the study and distillation of principles and functions found in biological systems that have been developed through evolution, and application of this knowledge to produce novel and exciting basic technologies and new approaches to solving scientific problems. It provides a forum for interdisciplinary research which acts as a pipeline, facilitating the two-way flow of ideas and understanding between the extensive bodies of knowledge of the different disciplines. It has two principal aims: to draw on biology to enrich engineering and to draw from engineering to enrich biology. The journal aims to include input from across all intersecting areas of both fields. In biology, this would include work in all fields from physiology to ecology, with either zoological or botanical focus. In engineering, this would include both design and practical application of biomimetic or bioinspired devices and systems. Typical areas of interest include: Systems, designs and structure Communication and navigation Cooperative behaviour Self-organizing biological systems Self-healing and self-assembly Aerial locomotion and aerospace applications of biomimetics Biomorphic surface and subsurface systems Marine dynamics: swimming and underwater dynamics Applications of novel materials Biomechanics; including movement, locomotion, fluidics Cellular behaviour Sensors and senses Biomimetic or bioinformed approaches to geological exploration.
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