深度学习在特定航空航天系统中的应用

Q3 Earth and Planetary Sciences Aerospace Systems Pub Date : 2024-04-08 DOI:10.1007/s42401-024-00287-0
Hossain Noman, Guorui Sun
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引用次数: 0

摘要

远距离空间系统会产生大量的大数据。这些大数据可用于生成智能数据,帮助我们更好地理解空间系统的行为。目前还没有这样的工具来精确理解和预测航空航天系统的行为。本研究分析了三种不同的航空航天系统,以建立相应的人工智能(AI)模型,利用深度学习(DL)生态系统来理解和预测其空间行为。我们研究了脉冲等离子推进器(PPT)--一种电动太空推进系统;ARTEMIS-P1 航天器传感器阵列;以及无人机电池系统。我们进行了三组比较分析,以评估模型的准确性。此外,还利用一系列测试来评估和预测确切的物理行为。比较和测试结果表明,基于 DL 的人工模型有足够的能力(99%)模仿精确的系统行为。这种基于 DL 的方法为理解和预测航空航天系统的真实行为提供了一种新的手段。
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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Applications of deep learning to selected aerospace systems

Long-distance space systems generate enormous amounts of bigdata. These bigdata can be used to generate intelligent that can help us better understand the behavior of space systems. There is currently no such tool for precisely understanding and predicting the behavior of aerospace systems. In this study, three different aerospace systems are analyzed to build the respective artificial intelligence (AI) models to understand and predict their space behavior using the deep learning (DL) ecosystem. We studied the pulsed plasma thruster (PPT), an electric space propulsion system; the ARTEMIS-P1 spacecraft sensor array; and the UAV battery system. Three sets of comparative analyses are carried out to assess the model accuracy. A number of tests are utilized to assess and predict the exact physical behavior. The comparison and test results show that DL-based artificial models are capable enough (> 99%) to mimic the exact system behaviors. This DL-based approach provides a novel means of understanding and predicting the real behavior of the aerospace systems.

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来源期刊
Aerospace Systems
Aerospace Systems Social Sciences-Social Sciences (miscellaneous)
CiteScore
1.80
自引率
0.00%
发文量
53
期刊介绍: Aerospace Systems provides an international, peer-reviewed forum which focuses on system-level research and development regarding aeronautics and astronautics. The journal emphasizes the unique role and increasing importance of informatics on aerospace. It fills a gap in current publishing coverage from outer space vehicles to atmospheric vehicles by highlighting interdisciplinary science, technology and engineering. Potential topics include, but are not limited to: Trans-space vehicle systems design and integration Air vehicle systems Space vehicle systems Near-space vehicle systems Aerospace robotics and unmanned system Communication, navigation and surveillance Aerodynamics and aircraft design Dynamics and control Aerospace propulsion Avionics system Opto-electronic system Air traffic management Earth observation Deep space exploration Bionic micro-aircraft/spacecraft Intelligent sensing and Information fusion
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