介绍 DAIMYO:首次正确动态设计架构及其在尾翼无人机系统开发中的应用

Jolan Wauters, Tom Lefebvre, Joris Degroote, Ivo Couckuyt, Guillaume Crevecoeur
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摘要

近年来,动态系统的各种多学科设计方法有了显著的发展。在这些方法中,一个值得注意的概念是并行概念和控制设计或协同设计。这种方法涉及在动态系统概念设计的同时,调整前馈和/或反馈控制策略。其主要目的是发现超越脱节或分离方法的综合解决方案。这种并行设计范例在混合无人机系统(UASs)(如尾翼飞行器)中尤其有前途,因为在这种系统中,多变性(由控制因素驱动)和效率(受概念设计影响)这两个目标经常会提出相互冲突的要求。然而,持续存在的挑战在于支撑设计过程的理论模型与实际操作环境之间的潜在差距,即所谓的现实差距。当设计的系统在现实中部署时,这种差距可能会导致次优性能。为了解决这个问题,本文介绍了 DAIMYO,这是一种新颖的设计架构,它将模拟真实环境的高保真环境融入到程序中,以追求 "首次正确 "的设计。这种创新方法的成果是一种设计程序,可产生多功能、高效的无人机系统设计,能够应对现实差距带来的挑战。
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Introducing DAIMYO: a first-time-right dynamic design architecture and its application to tail-sitter UAS development
In recent years, there has been a notable evolution in various multidisciplinary design methodologies for dynamic systems. Among these approaches, a noteworthy concept is that of concurrent conceptual and control design or co-design. This approach involves the tuning of feedforward and/or feedback control strategies in conjunction with the conceptual design of the dynamic system. The primary aim is to discover integrated solutions that surpass those attainable through a disjointed or decoupled approach. This concurrent design paradigm exhibits particular promise in the context of hybrid unmanned aerial systems (UASs), such as tail-sitters, where the objectives of versatility (driven by control considerations) and efficiency (influenced by conceptual design) often present conflicting demands. Nevertheless, a persistent challenge lies in the potential disparity between the theoretical models that underpin the design process and the real-world operational environment, the so-called reality gap. Such disparities can lead to suboptimal performance when the designed system is deployed in reality. To address this issue, this paper introduces DAIMYO, a novel design architecture that incorporates a high-fidelity environment, which emulates real-world conditions, into the procedure in pursuit of a `first-time-right' design. The outcome of this innovative approach is a design procedure that yields versatile and efficient UAS designs capable of withstanding the challenges posed by the reality gap.
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