Optimal design via polynomial Euler function for UAV applications

The Journal of Navigation Pub Date : 2024-09-13 DOI:10.1017/s0373463324000146

Z. Y. Chen, Yahui Meng, Ruei-Yuan Wang, Timothy Chen

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引用次数: 0

Abstract

Unmanned aerial vehicles (UAVs) have recently been widely applied in a comprehensive realm. By enhancing computer photography and artificial intelligence, UAVs can automatically discriminate against environmental objectives and detect events that occur in the real scene. The application of collaborative UAVs will offer diverse interpretations which support a multiperspective view of the scene. Due to the diverse interpretations of UAVs usually deviating, UAVs require a consensus interpretation for the scenario. This study presents an original consensus-based method to pilot multi-UAV systems for achieving consensus on their observation as well as constructing a group situation-based depiction of the scenario. Taylor series are used to describe the fuzzy nonlinear plant and derive the stability analysis using polynomial functions, which have the representations $V(x )={m_{\textrm{1} \le l \le N}}({{V_\textrm{l}}(x )} )$ Abstract Image and ${V_l}(x )={x^T}{P_l}(x )x$. Due to the fact that the ${\dot{P}_l}(x )$ in ${\dot{V}_l}(x )={\dot{x}^T}{P_l}(x )x + {x^T}{\dot{P}_l}(x )x + {x^T}{P_l}(x )\dot{x}$ will yield intricate terms to ensure a stability criterion, we aim to avoid these kinds of issues by proposing a polynomial homogeneous framework and using Euler's functions for homogeneous systems. First, this method permits each UAV to establish high-level conditions from the probed events via a fuzzy-based aggregation event. The evaluated consensus indicates how suitable is the scenario collective interpretation for every UAV perspective.

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通过多项式欧拉函数为无人机应用进行优化设计

无人驾驶飞行器（UAV）近来已被广泛应用于综合领域。通过增强计算机摄影和人工智能，无人飞行器可以自动判别环境目标，并探测真实场景中发生的事件。协作式无人机的应用将提供多样化的解释，从而支持对场景的多视角观察。由于无人机的不同解释通常会出现偏差，因此无人机需要对场景进行共识解释。本研究提出了一种基于共识的原创方法，用于引导多架无人机系统就其观察结果达成共识，并构建基于群组情况的场景描述。泰勒级数被用来描述模糊非线性工厂，并利用多项式函数得出稳定性分析，其表示为 $V(x )={m_{\textrm{1}\le l \le N}}({{V_\textrm{l}}(x )} )$ 和 ${V_l}(x )={x^T}{P_l}(x )x$ 。由于${\dot{V}_l}(x )={\dot{x}^T}{P_l}(x )x + {x^T}{\dot{P}_l}(x )x + {x^T}{P_l}(x )\dot{x}$ 中的${\dot{P}_l}(x )$ 会产生错综复杂的项来确保稳定准则、为了避免这类问题，我们提出了多项式同构框架，并使用欧拉函数来处理同构系统。首先，这种方法允许每个无人飞行器通过基于模糊的聚合事件，从探测事件中建立高层条件。经过评估的共识表明了每个无人机视角的情景集体解释的合适程度。

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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The Journal of Navigation

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