半机械昆虫揭示了自由飞行时肌肉的功能

IF 10.5 Q1 ENGINEERING, BIOMEDICAL Cyborg and bionic systems (Washington, D.C.) Pub Date : 2022-05-04 DOI:10.34133/2022/9780504

T. Vo-Doan, V. T. Dung, Hirotaka Sato

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引用次数: 6

摘要

虽然工程师们投入了大量的精力、资源和时间来制造像昆虫一样飞行的昆虫微型飞行器(MAVs)，但昆虫本身才是真正的飞行大师。如果我们用活体昆虫作为MAV的平台呢?在这里，我们报道了通过电刺激昆虫-计算机混合机器人的飞行肌肉来控制飞行，这是一个可安装的无线背包控制器和一只活甲虫的界面。甲虫使用间接飞行肌肉驱动翅膀拍打，三个主要的直接飞行肌肉(基底肌、翼下肌和第三腋肌)控制翅膀的运动以进行飞行机动。虽然已经通过刺激基底肌和3Ax肌实现了转向控制，但在飞行中对翼下肌的电刺激可以实现制动和高度控制。我们还通过刺激个别的颚下肌肉，演示了大约20度的对侧偏航和侧滚。刺激翼下肌肉会导致俯仰增加20度，飞行减速1.5 m/s2，并诱导高度上升2 m/s2。

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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A Cyborg Insect Reveals a Function of a Muscle in Free Flight

While engineers put lots of effort, resources, and time in building insect scale micro aerial vehicles (MAVs) that fly like insects, insects themselves are the real masters of flight. What if we would use living insect as platform for MAV instead? Here, we reported a flight control via electrical stimulation of a flight muscle of an insect-computer hybrid robot, which is the interface of a mountable wireless backpack controller and a living beetle. The beetle uses indirect flight muscles to drive wing flapping and three major direct flight muscles (basalar, subalar, and third axilliary (3Ax) muscles) to control the kinematics of the wings for flight maneuver. While turning control was already achieved by stimulating basalar and 3Ax muscles, electrical stimulation of subalar muscles resulted in braking and elevation control in flight. We also demonstrated around 20 degrees of contralateral yaw and roll by stimulating individual subalar muscle. Stimulating both subalar muscles lead to an increase of 20 degrees in pitch and decelerate the flight by 1.5 m/s2 as well as an induce in elevation of 2 m/s2.

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