Design of a Hybrid Aerial Robot with Multi-Mode Structural Efficiency and Optimized Mid-Air Transition

Jun En Low, D. S. B. Shaiful, Luke Thura Soe Win, G. Soh, S. Foong
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引用次数: 5

Abstract

In this paper, we explore a novel multi-mode hybrid Unmanned Aerial Vehicle (UAV). We combine a tailless fixed-wing with a dual-wing monocopter such that the craft’s propulsion systems and aerodynamic surfaces are fully utilized in both a horizontal cruising mode and a vertical hovering mode. This maximizes the structural efficiency across the flight envelope, thereby reducing drag and unused mass while airborne in either flight mode. This UAV is also designed such that the transition between the two flight modes can be executed in mid-air, using only its existing flight actuators and sensors — there are no transition specific actuators. Using two prototypes, the foundational design and control of the system is established; the first explores the hovering mode characteristics of the unique dual-wing monocopter configuration, while the second explores the full multi-mode capabilities of the combined platform. In addition to analytical simulations, the prototypes are experimentally evaluated and assessed to demonstrate the feasibility, viability and potential of this multi-mode aerial robot design.
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具有多模态结构效率和优化半空过渡的混合航空机器人设计
本文研究了一种新型的多模式混合无人机(UAV)。我们将无尾固定翼与双翼单翼无人机结合起来,使飞行器的推进系统和空气动力学表面在水平巡航模式和垂直悬停模式下都得到充分利用。这最大限度地提高了整个飞行包线的结构效率,从而减少了阻力和未使用的质量,而在空中飞行的任何飞行模式。这种无人机也被设计成两种飞行模式之间的转换可以在半空中执行,仅使用其现有的飞行致动器和传感器-没有过渡特定的致动器。利用两个原型,建立了系统的基本设计和控制;第一项研究探索了独特的双翼单翼直升机配置的悬停模式特征,第二项研究探索了组合平台的完整多模式能力。除了分析模拟之外,还对原型进行了实验评估和评估,以证明这种多模式空中机器人设计的可行性、可行性和潜力。
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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