Using Inertial Control to Improve Maneuverability of Propeller-Assisted Flapping Wing Aerial Vehicle

Volume 5B: 43rd Mechanisms and Robotics Conference Pub Date : 2019-11-25 DOI:10.1115/detc2019-97854

A. Holness, H. Solheim, Hugh Alan Bruck, S. K. Gupta

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Abstract

Biological creatures demonstrate tremendous feats of maneuverability and dexterity. Some of these feats are achieved by intelligent usage of mass and inertia. For example, lizards use their tail mass and inertia to change body pose during jumping to self-right in mid-air. In a similar fashion, having shown passive mass position effects during flight tests of both flapping only and propeller-assisted flapping platforms, usage of an actuated reaction mass is proposed as a means of improving the maneuverability of a propeller-assisted flapping wing aerial vehicle. A simplified model for equations of motion, utilized successfully for autonomous diving, is presented and adapted to describe the aerodynamic forces on the wings and other surfaces. A model to approximate the change in the center of mass to be used with the equations of motion is also described. A design using a linear actuator in concert with the platform battery as a reaction mass system was prototyped and flight tested. Using the prototype design, flight characteristics for improved maneuverability were demonstrated via both video footage and data gathered by an inertial measurement unit during the same flight.

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利用惯性控制提高螺旋桨辅助扑翼飞行器的机动性

生物表现出极大的机动性和灵巧性。其中一些壮举是通过巧妙地利用质量和惯性来实现的。例如，蜥蜴在半空中跳跃时，利用它们的尾巴质量和惯性来改变身体姿势。以类似的方式，已经显示了被动质量位置效应的飞行试验中，无论是纯扑翼和螺旋桨辅助扑翼平台，使用一个驱动的反应质量被提议作为一种手段，提高机动性的螺旋桨辅助扑翼飞行器。提出了一种简化的运动方程模型，成功地应用于自主潜水，并适用于描述机翼和其他表面的气动力。本文还描述了用于运动方程的近似质心变化的模型。一种使用线性执行器和平台电池作为反应质量系统的设计进行了原型设计和飞行测试。使用原型设计，通过视频片段和在同一次飞行中由惯性测量单元收集的数据演示了改进的机动性的飞行特性。

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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Volume 5B: 43rd Mechanisms and Robotics Conference

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