Fault-tolerant FADS system development for a hypersonic vehicle via neural network algorithms

IF 3.2 3区工程技术 Q2 MECHANICS

Theoretical and Applied Mechanics Letters Pub Date : 2023-09-01 DOI:10.1016/j.taml.2023.100464

Qian Wan , Minjie Zhang , Guang Zuo , Tianbo Xie

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引用次数: 0

Abstract

Hypersonic vehicles suffer from extreme aerodynamic heating during flights, especially around the area of leading edge due to its small curvature. Therefore, flush air data sensing (FADS) system has been developed to perform accurate measurement of the air data parameters. In the present study, the method to develop the FADS algorithms with fail-operational capability for a sharp-nosed hypersonic vehicle is provided. To be specific, the FADS system implemented with 16 airframe-integrated pressure ports is used as a case study. Numerical simulations of different freestream conditions have been conducted to generate the database for the FADS targeting in $2 \leq M a \leq 5$ and $0 km \leq H \leq 30 km$ . Four groups of neural network algorithms have been developed based on four different pressure port configurations, and the accuracy has been validated by 280 groups of simulations. Particularly, the algorithms based on the 16-port configuration show an excellent ability to serve as the main solver of the FADS, where $99.5 %$ of the angle-of-attack estimations are within the error band $\pm 0 . 2^{\circ}$ . The accuracy of the algorithms is discussed in terms of port configuration. Furthermore, diagnosis of the system health is present in the paper. A fault-tolerant FADS system architecture has been designed, which is capable of continuously sensing the air data in the case that multi-port failure occurs, with a reduction in the system accuracy.

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基于神经网络算法的高超声速飞行器FADS容错系统开发

高超音速飞行器在飞行过程中会受到极端的空气动力学加热，尤其是在前缘区域，因为其曲率较小。因此，开发了冲洗空气数据传感（FADS）系统来执行空气数据参数的精确测量。在本研究中，提供了为尖鼻高超音速飞行器开发具有故障操作能力的FADS算法的方法。具体地说，使用了由16个机身集成压力端口实现的FADS系统作为案例研究。对不同的自由流条件进行了数值模拟，以生成FADS在2≤Ma≤5和0km≤H≤30km内瞄准的数据库。基于四种不同的压力端口配置，开发了四组神经网络算法，并通过280组仿真验证了算法的准确性。特别是，基于16端口配置的算法显示出作为FADS的主要求解器的出色能力，其中99.5%的迎角估计在±0.2∘的误差带内。从端口配置的角度讨论了算法的准确性。此外，本文还对系统健康状况进行了诊断。设计了一种容错FADS系统架构，该架构能够在发生多端口故障的情况下连续感测空中数据，从而降低系统精度。

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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来源期刊

Theoretical and Applied Mechanics Letters MECHANICS-

CiteScore

6.20

自引率

2.90%

发文量

545

审稿时长

12 weeks

期刊介绍： An international journal devoted to rapid communications on novel and original research in the field of mechanics. TAML aims at publishing novel, cutting edge researches in theoretical, computational, and experimental mechanics. The journal provides fast publication of letter-sized articles and invited reviews within 3 months. We emphasize highlighting advances in science, engineering, and technology with originality and rapidity. Contributions include, but are not limited to, a variety of topics such as: • Aerospace and Aeronautical Engineering • Coastal and Ocean Engineering • Environment and Energy Engineering • Material and Structure Engineering • Biomedical Engineering • Mechanical and Transportation Engineering • Civil and Hydraulic Engineering Theoretical and Applied Mechanics Letters (TAML) was launched in 2011 and sponsored by Institute of Mechanics, Chinese Academy of Sciences (IMCAS) and The Chinese Society of Theoretical and Applied Mechanics (CSTAM). It is the official publication the Beijing International Center for Theoretical and Applied Mechanics (BICTAM).