Controlled Flight of a Biologically Inspired, Insect-Scale Robot

Kevin Y. Ma; Pakpong Chirarattananon; Sawyer B. Fuller; Robert J. Wood

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Controlled Flight of a Biologically Inspired, Insect-Scale Robot

机译：受生物启发的昆虫规模机器人的受控飞行

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Flies are among the most agile flying creatures on Earth. To mimic this aerial prowess in a similarly sized robot requires tiny, high-efficiency mechanical components that pose miniaturization challenges governed by force-scaling laws, suggesting unconventional solutions for propulsion, actuation, and manufacturing. To this end, we developed high-power-density piezoelectric flight muscles and a manufacturing methodology capable of rapidly prototyping articulated, flexure-based sub-millimeter mechanisms. We built an 80-milligram, insect-scale, flapping-wing robot modeled loosely on the morphology of flies. Using a modular approach to flight control that relies on limited information about the robot's dynamics, we demonstrated tethered but unconstrained stable hovering and basic controlled flight maneuvers. The result validates a sufficient suite of innovations for achieving artificial, insect-like flight.

机译：苍蝇是地球上最敏捷的飞行生物之一。为了在类似大小的机器人中模仿这种空中技巧，需要微型，高效的机械部件，这些机械部件提出了受力缩放定律支配的小型化挑战，提出了推进，驱动和制造的非常规解决方案。为此，我们开发了高功率密度的压电飞行肌肉和一种制造方法，能够快速制作基于铰接，基于弯曲的亚毫米机构的原型。我们建立了一个80毫克，昆虫大小的拍打翼机器人，以苍蝇的形态为模型。使用依赖于机器人动力学的有限信息的模块化飞行控制方法，我们演示了受束缚但不受约束的稳定悬停和基本受控的飞行操作。结果证明了有足够的创新套件可以实现人工的，类似昆虫的飞行。

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《Science》 |2013年第6132期|603-607|共5页
作者
Kevin Y. Ma; Pakpong Chirarattananon; Sawyer B. Fuller; Robert J. Wood;
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作者单位

School of Engineering and Applied Sciences and the Wyss Institute for Biologically Inspired Engineering, Harvard University, Cambridge, MA 02138, USA;

School of Engineering and Applied Sciences and the Wyss Institute for Biologically Inspired Engineering, Harvard University, Cambridge, MA 02138, USA;

School of Engineering and Applied Sciences and the Wyss Institute for Biologically Inspired Engineering, Harvard University, Cambridge, MA 02138, USA;

School of Engineering and Applied Sciences and the Wyss Institute for Biologically Inspired Engineering, Harvard University, Cambridge, MA 02138, USA;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);美国《化学文摘》(CA);
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正文语种 eng
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1. First controlled vertical flight of a biologically inspired microrobot [J] . Pérez-Arancibia N.O., Ma K.Y., Galloway K.C., Bioinspiration & biomimetics . 2011,第3期

机译：受到生物启发的微型机器人的首次受控垂直飞行
2. Stabilizing air dampers for hovering aerial robotics: design, insect-scale flight tests, and scaling [J] . Fuller Sawyer B., Teoh Zhi Ern, Chirarattananon Pakpong, Autonomous robots . 2017,第8期

机译：用于悬停空中机器人的空气阻尼器：设计，昆虫级飞行试验和缩放
3. Honeybees as a model for the study of visually guided flight, navigation, and biologically inspired robotics. [J] . Srinivasan MV Physiological Reviews . 2011,第2期

机译：蜜蜂是研究视觉引导飞行，导航和受生物启发的机器人的模型。
4. A Bio-inspired Wing Driver for the Study of Insect-Scale Flight Aerodynamics [C] . Nick Gravish, Stacey Combes, Robert J. Wood International conference on biomimetic and biohybrid systems . 2014

机译：用于昆虫规模飞行空气动力学研究的生物启发机翼驱动器
5. Design of Hybrid Passive and Active Mechanisms for Control of Insect-Scale Flapping-Wing Robots [D] . Teoh, Zhi Ern. 2015

机译：用于控制昆虫型扑翼机器人的混合动力源与有源机制的设计
6. Controlling free flight of a robotic fly using an onboard vision sensor inspired by insect ocelli [O] . Sawyer B. Fuller, Michael Karpelson, Andrea Censi, 2014

机译：使用受昆虫触觉启发的机载视觉传感器控制机器人苍蝇的自由飞行
7. Biologically-Inspired Locomotion Controller for a Quadruped Walking Robot Paper: Biologically-Inspired Locomotion Controller for a Quadruped Walking Robot: Analog IC Implementation of a CPG-Based Controller [O] . Kazuki Nakada, Tetsuya Asai, Yoshihito Amemiya 2004

机译：四足步行机器人的生物启发运动控制器论文：四足步行机器人的生物启发运动控制器：基于CPG的控制器的模拟IC实现

Controlled Flight of a Biologically Inspired, Insect-Scale Robot

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